REPORT NO. 1510165

PROJECT TRIDENT

TECHNICAL REPORT

REVIEW OF MARINE NAVIGATION
SYSTEMS AND TECHNIQUES.

ARTHUR D. LITTLE, INC.
DEPARTMENT OF THE NAVY

BUREAU OF SHIPS
NObsr-81564 $S-050

JANUARY 1965

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COLLECT

REPORT NO. 1510165

PROJECT TRIDENT

TECHNICAL REPORT

REVIEW OF MARINE NAVIGATION
SYSTEMS AND TECHNIQUES.

by : a CURam,. \
JOHN CAWLEY Boe, j

ARTHUR D. LITTLE, INC.
DEPARTMENT OF THE NAVY

BUREAU OF SHIPS
NObsr-81564 $S-050

JANUARY 1965

'
Ao
sy

PREFACE

This is one of a series of Technical Reports being issued by
Arthur D. Little, Inc., under contract NObsr-81564 with the Bureau of
Ships as part of the TRIDENT Project.

Arthur A Hittle Ire.

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List of Tables

List of Figures

TABLE OF CONTENTS

I. INTRODUCTION

Il. SUMMARY

Le

B.

Go

LONG-RANGE NAVIGATION SYSTEMS

MID-RANGE NAVIGATION SYSTEMS

SHORT -RANGE NAVIGATION SYSTEMS

Ill. FUNDAMENTALS REVIEW

aX.

‘B.

16

18} ¢

GENERAL

SYSTEM CLASSIFICATION
SYSTEM METHODS

RF PROPAGATION

RANGE CONSIDERATIONS

ACCURACY

IV. LONG-RANGE NAVIGATION SYSTEMS

Jeo

Bre

Go

CELESTIAL NAVIGATION
CONSOL AND CONSOLAN

RADIO DIRECTION FINDING (RDF)
DECCA

LORAN-A

Page

1X

Arthur A. Little Ine.

TABLE OF CONTENTS (Continued)

Page
IV. LONG-RANGE NAVIGATION SYSTEMS (cont'd.)
F, LORAN-C 68
G. OMEGA VLF NAVIGATION SYSTEM 80
H. NAVIGATION SYSTEMS USING SATELLITES 86
I, INERTIAL NAVIGATION SYSTEMS 95
J. ACOUSTIC DOPPLER 99
V. MID-RANGE NAVIGATION SYSTEMS 103
A. DECCA TWO-RANGE SURVEY SYSTEM 105
B. ELECTRONIC POSITION INDICATOR (EPI) 110
Cz LORAC 117
D. RAYDIST 126
VI. SHORT-RANGE NAVIGATION SYSTEMS 133
A. RADAR 135
B. ALPINE PRECISION NAVIGATION SYSTEM
MODEL 430 138
C. AUTOTAPE 143
D. 'TELLUROMETER' - HYDRODIST MODEL MRB/2 150
E. SHORAN 156
F. HI-FIX 163

vi

Arthur D. Little Inc.

LIST OF TABLES

Table
tail Long -Range Navigation Systems 4
II -2 Mid -Range Navigation Systems 7
INE= 3} Short -Range Navigation Systems 9
INUfsIl Error Probability Contained in Circles of Varying Radius Zi)
III -2 Comparison of Statistics of Error for as a ZY
IV -1 Consol Station Characteristics BO)
IV -2 Transmission Characteristics 38
IV -3 Consol LOP Errors, 95% Confidence Level 4]
IV -4 Typical Values for Radiated and Comparison Frequencies
and Wave Lengths 53

IW 5) Lane Width on Base Lines Assuming Velocity of 299250 km/s 53

IV -6 Sky-Wave Range Data . 76

IV -7 Omega Signal Format 82

V-l Field Test Data for EPI 115
vii

Arthur A Little Inc.

LIST OF FIGURES

Figure
No. Page
III-1 Position Fix Geometry 12
nie? System Geometry 14

U3) Radio Fix Illustrating Basic Hyperbola Radio Navigation

Principle 16
Ill-4 Angle Measuring System Geometry 17
IiI-5 Ground-Wave Propagation 19
Ill -6 Sky-Wave Propagation With Reflection from Fy Layer 20
Il 7/ Average Sky-Wave Transmission Ranges 24
III-8 Maximum Range at Which Ground-Wave Transmission is

Essentially Free from Sky-Wave Interference 24
III-9 Line of Position Geometry | 26

III-10 The Minimum Errors of Fix Attainable by Three Standard
Measuring Techniques 29

IW Areas Covered by the Consol Stations Bushmills, Stavanger,

Lugo, and Seville 36
IV -2 Polar Diagram of Antenna System at Beginning of Sweep 37
IV-3 1 kw Consol Field-Strength Characteristic at F = 300 kc 40

Iv -4 Decca Navigator Chains in Europe (May 1961) Quasi-
Maximum 95% Random Fixing Errors at Sea Level in

Nautical Miles 50
IV-5 Canadian Decca Navigator Coverage (when Quebec Chain
Residedin Area of Anticosti Island) Fixing Accuracy Contours
95% Probability Level 51
ix

Arthur A. Little Inc.

LIST OF FIGURES (Continued)

Figure

_No. Page
IV -6 Decca Lattice of the English Chain 52
IV -7 Error Contours for Decca Navigator 55
IV-8 Loran-A Coverage, July 1964 59
IV -9 Loran-A Grid System 62
IV-10 Time Relationship Between Pulses Teaneeecel by Master

and Salve Stations in an Actual Loran Station Pair 63

IV-11 Loran-C Coverage, July 1964 69
IV-12 Loran-C East Coast Chain 71
IV-13 Schematic of Transit System Operation 88
IV-14 The Secor Satellite Navigation System 93
IV-15 Janus JN-400 Acoustic Doppler Operation 100

W =i Diagram of Typical Two-Range Decca Hydrographic

Survey System 106
V-2 Phase Correction vs Range for Typical Seawater Trans -

mission Path 108
V-3 Fixing Accuracy Contours for Summer Daylight Operation

for a 0.01 Lane Deviation 108
V-4 Block Diagram for EPI System ; 111

V-5 Basic Lorac System Required for One Hyperbolic Line
of Position 119

V-6 Hyperbolic Position Grid 119

Arthur DUittle Inc.

LIST OF FIGURES (Continued)

Figure
V-7 Lorac Type A (Alpha) Green Half of Switching Cycle 120
V-8 Lorac Type B (Beta) Operation LBD,
V-9 DM Raydist Lattice 127

V-10 Comparison of Areas of Equal Accuracy for Corresponding

Ranging and Hyperbolic System 130
VI-1 Typical Radar System Block Diagram 135
VI-2 Autotape Ranging Diagram 144
VI-3 Position Uncertainty Due to Random Errors 160
vI-4 Time -Sharing of Master and Slave Transmissions 164

WAISS) Typical Relative Accuracy Contours for Hyperbolic and
Circular Patterns 166

Xi

Arthur A. Little Inc.

I. INTRODUCTION

Familiarity with navigation and ship -positioning problems is a pre-
requisite for personnel concerned with ASW systems. Historically, celestial
techniques and dead-reckoning methods have been used for marine navigation.
During the past 20 years, however, various navigational aids and positional sys -
tems which permit the navigator to fix his position without regard to cloud or
weather conditions have become available. Since World War II, but particularly
since 1950, the trend in navigation equipment has been toward greater positional
accuracy, continuous position-fixing capability, and longer-range operation.
These improvements are being achieved by the use of more sophisticated elec-
tronic techniques, including celestial methods, electromagnetic and acoustical
signals, and inertial systems. Automatic computation and display equipment
has further simplified the work of the navigator. The more sophisticated naviga-
tion systems allow the computer to complete as many of the routine calculations
as possible, thus reducing the time the navigator requires to fix his position ac-
curately. Such methods also tend to reduce the incidence of human error.

The high positional accuracy of a sophisticated navigation system is
expensive, and highly trained personnel are required to operate and maintain
the equipment. Certain military and most oceanographic research and survey
problems require positional accuracies of 0.1 - 0.5 nautical mile or better.
This high precision may not be required or economically justified, however, for
the vast majority of marine navigation problems, where a vessel is interested
only in steaming from one port to another.

Navigation systems have been improved at the expense of greater
equipment complexity, sophistication, variety and cost, compared to older navi-
gation methods. System reliability and maintainability remain as problems, and
precision coverage in all ocean areas using any one system is not yet available.
The prudent marine navigator must use all navigation systems at his disposal
and compare their results in order to plot his most probable position at a given
point in time. A combination of systems is required to provide cross checking
and to satisfy the differing requirements for precision, fix renewal period, and
range.

We have divided marine navigation and ship-positioning systems into
three classes: long range, mid range, and short range. The basic capabilities
and limitations of the systems in each class are summarized in Section II. The
fundamentals of electronic navigation, propagation phenomena, and range and
accuracy considerations are discussed in Section III. In Sections IV - VI the
important characteristics of the several classes of systems are described.

Arthur A AHittle Inc.

These characteristics include useful range, positional accuracy, conditions of
operation, ease and cost of operation, maintenance requirements, reliability,
and geographical coverage. Important mechanical and electrical characteris -
tics which affect the performance of each system are tabulated.

The sources of this information were the available literature, con-
tractors' reports, and private communications. None of the material in this
report is classified. Relevant reference material is cited following each sys-
tem description.

Arthur D.Little, Inc.

Il. SUMMARY

A. LONG-RANGE NAVIGATION SYSTEMS

Long-range navigation systems (Table II-1) are defined here as having
a position fixing capability at ranges greater than about 400 miles. Celestial,
azimuthal, pulse-time, and phase-measuring systems comprise the largest
number of navigation systems in this group. Dependent upon requirements
satellite systems may use combinations of these methods to yield accurate
fixes. Inertial, and acoustic-doppler systems are essentially highly sophisti-
cated dead-reckoning systems with potential world-wide coverage and position
indicating capability. Of these only the inertial systems are completely passive
and self-contained.

The inexpensive, hand-held sextant, tables,and chronometer are still
the basic tools of the navigator and give him the possibility of a +3 mile posi-
tion fix twice daily. Recently developed star tracker and sun and moon tracker
equipment uses gyro-stabilized references, making a horizon unnecessary.
Each of these celestial systems is limited by cloud cover or by the geometry of
the sun-moon orbits. These factors limit the current world-wide availability
of fix by celestial methods to below 50%. Because of their high cost, the auto-
matic star and sun-moon tracker systems can usually be justified only for
specialized applications.

Of the several azimuth measurement systems being used, the Consol/
Consolan and the Radio Direction Finder (RDF) systems have gained the widest
acceptance. Both systems require simple and inexpensive receiving equipment
and have several stations along the coasts of North America and very good
coverage throughout most of Europe. The precision of fix is not high by today's
standards, and powerful ground stations and good operating conditions are re-
quired for the navigator to obtain a fix at ranges beyond about 300-600 miles.

Pulse-time measurement systems are capable of fixing a ship's posi-
tion by the reception and identification of pulses received in a timed sequence
from transmitting stations of known position. About 35% of the northern hemi-
sphere is effectively covered by Loran-A. The more recent Loran-C equipment
makes use of lower frequencies and uses both pulse-time and phase -measuring
techniques. Although the coverage is not yet as great as that of the earlier
Loran-A, the system is useful to ranges of 1000-2300 miles and is capable of
high accuracy. With good operating conditions system accuracy can approach
one foot per mile of range. The recent incorporation of microcircuitry into
Loran-C receiving equipment will greatly reduce its size, weight, and eventual
cost, and make it much more reliable than the present electromechanical equip -
ment.

Arthur A Little Inc.

System

Celestial

Star Tracker

Consol

Decca

Loran-A

Loran-C

Omega

Satellite

TABLE II-1

LONG-RANGE NAVIGATION SYSTEMS

Estimated

Useful Range

World-wide
World-wide

700-1200nm

300-600nm

200-300nm

700-900nm

1200-1500nm

5000nm

World-wide

Estimated

Accuracy
+ 3nm

+0.3nm.

se), SoU 0

as D0)

<= 0725-10

+0.5-3.0nm

+0Q.2-0.5nm

+0.5-1.0nm

+0.1-2.0nm

Frequency

Range

190-194 kc
257-263 kc

200-415 kc
285-325 ke

90-130 kc

1.75-2mc

90-110kc

10-15 ke

100-400 mc

Comments

Inexpensive equipment, easy to
use; limited to 2 fixes/day, af-
fected by clouds and bad weather,
which also limits fix availability
to <50%. Star Tracker equip-
ment very expensive.

Requires only a narrow-band
communications receiver to
establish LOP.

World-wide coverage. U.S.
coastal beacons. Capable of
coarse fix only.

Easy to use, insufficient
coverage, limited to about 240
mile range at night because of
sky wave interference.

Easy to use, insufficient cover-
age, subject to sky wave inter-
ference. Less accuracy with
sky wave.

Accurate, easy to use, insuf-
ficient coverage, expensive
installation. Less accuracy
with sky wave.

World-wide coverage presently
in advanced development. Will
use three frequencies to yield
both coarse and fine grids.

World-wide coverage; Transit
average fix renewal each 110
min., presently in advanced
development, possibly opera-
tional in 1965-1970 period.

Less sophisticated systems for
commercial use now under study.

Arthur DHittle Inc.

System

Inertial

Acoustic
Doppler

TABLE II-1 (Continued)

Estimated Estimated Frequency
Useful Range Accuracy Range

3-12 hours <2.0nm/hr --

< 300 ft = 1% of velocity 0.2-lmc

h
water depth — 1% of distance

travelled

Comments

Must be checked with outside
reference, accuracy decreases
in a few hours at rapid rate,
very expensive, requires ex-
pert maintenance.

Simple systems require a
manual plotting board and
complement standard dead
reckoning procedures; sophis -
ticated high-accuracy sys-
tems utilize gyro-compass,
velocity input, and automatic
track -plotting equipment.

Arthur A. Uittle Inc.

The Decca Navigator phase measurement system can provide 2-4 mile
positional information at maximum ranges of 200-500 nautical miles but is gen-
erally limited to ranges of the order of 250 nautical miles for the highest ac-
curacy on a 24-hour/day basis. Coverage is available throughout Europe and
the British Commonwealth. The Navy's developmental Omega system promises
positional accuracies of 0.5-1 nautical mile for ranges as great as 5000 nautical
miles. This system will probably use three frequencies to fix a course and a
fine position. World-wide coverage by 8-10 ground stations is promised and
could be available by the late 1960's or early 1970's.

World-wide coverage by a system of satellites and ground stations is
also expected. The Navy's passive Transit program requires a minimum of
four satellites in polar orbit and should yield positional information to better
than + 0.1 nautical mile. Several less sophisticated systems using larger num-
bers of satellites are currently being studied by other Governmental agencies
for use by commercial and scientific groups. One system under consideration
is the precision satellite tracking system, known as Secor, now in operation for
the Army Map Service. It has demonstrated a positioning capability to geodetic
accuracies of a few meters with base-line lengths greater than 2000 miles.
Less sophisticated equipment of this type would be capable of positioning ac-
curacies of 0.25-1 nautical mile when used for ship and aircraft navigation.

The inertial navigation systems in use by the Navy are passive, self-
contained, and not directly subject to enemy action. Although these systems
are highly sophisticated, they still accumulate a small error over a period of
time and require recalibration, using an external source. The first commer-
cially available inertial equipment is much less sophisticated. It will initially
be used aboard high-speed, long-range, commercial aircraft and will generate
an average error of less than two miles per hour of travel.

Acoustic Doppler navigation systems are not yet fully developed to
the point where they can be used effectively in waters greater than a few hundred
feet deep. These systems should help improve present dead-reckoning proce-
dures and also appear to be attractive for use in shallow waters or aboard deep
submersibles operating near the ocean floor. Navigation accuracies available
with these systems are of the order of 1% of velocity and 1% of distance.

B. MID-RANGE NAVIGATION SYSTEMS

Mid-range navigation systems (Table II-2) are defined here as having
ranging capabilities up to about 400 nautical miles. These systems are generally
most useful for ship-positioning and survey applications where high accuracy
and reproducibility are required. Because mid-range frequencies are used,
the range and accuracy of these systems will be limited during evening hours

Arthur D. Little Inc.

TABLE II-2

MID-RANGE NAVIGATION SYSTEMS
EEE EN POT EMS

Estimated Estimated
System Useful Range Accuracy

Decca 175nm 25-200 ft
Two -
Range
EPI 250nm 50-200 ft
Lorac 135 nm 25-100 ft

Raydist 25-200nm 25-250 ft
DM

Frequency

Range

110-170 ke

1.85 mc

1.7to2.5mc

1.6to5.0mec

Comments

Circular geometry survey
system. Night effect re-
duces range to 40 miles or
less. Continuous tracking.

Circular geometry survey
system used by USC and GS.
Requires operators at 2
Shore stations. Single-user
system. Night effect re-
duces range.

Hyperbolic geometry port-
able survey system; re-
quires 3 shore stations;
used widely for offshore
seismic work. Continuous -
tracking, multi-user cap-
ability. Night effect reduces
range.

Circular geometry survey
system; requires 2 shore
sites. Low-power buoy
equipment available. Con-
tinuous -tracking, multi-user
capability. Night effect re-
duces range.

Arthur A Little, Inc.

by sky wave effects, and the survey activities are generally restricted to peri-
ods between sunrise and sunset. Lane ambiguity problems are also troublesome
with phase comparison systems and require that the navigator know his initial
checkpoint and keep an accurate track record. For most systems automatic
track-plotting and recording equipment is available for this purpose.

The Decca Two -Range and the Raydist DM hydrographic survey sys-
tems use circular plot ranging methods which require two shore stations. Both
systems use phase comparison techniques for establishing ranges from the re-
ceiver to each shore station. The Electronic Position Indicator (EPI) system is
a pulsed-phase measuring system which sequentially measures the range from
the survey vessel to each shore station. It was designed to work at ranges as
great as 400 miles, while Decca and Raydist are limited to ranges of the order
of 150-200 miles.

The Lorac (Long-Range-Accuracy) system was developed for oil
exploration activities. It uses a cw phase comparison method which requires
three shore stations. This system is used by both commercial and Government
survey groups for near-shore control work. Working ranges are 100-150
nautical miles. Ranging accuracies of 1:50, 000 are reported as being readily
obtained with this system.

C. SHORT-RANGE NAVIGATION SYSTEMS

Short-range navigation systems (Table II-3) are defined here as being
capable of achieving a very high order of positional accuracy at ranges from
line of sight up to about 50 miles. Both pulse-time and phase comparison
methods are used, at frequencies generally in the 3-10 cm band. Because of
the high frequency and small size of the equipment in this class, most of the
shore stations are small and highly portable. Where the highest accuracy is
required, appropriate atmospheric measurements are made, and corrections
for variations in the propagation velocity are calculated.

The Shoran system is a pulse-time ship-positioning system operating
on radar principles. It has been in use for over 15 years and is a standard
method of in-shore survey control. Transponders to shape and reinforce the
return signal are placed at each of the two required shore stations and give the
system a useful range of over 50 miles.

The Alpine-429 Precision Radar Ranging Unit was developed to be
operated in conjunction with standard radar transmitting equipment. The unit
is capable of a fixed operational accuracy of +80 feet at ranges to about 50
nautical miles. A remote Electrical Track Plotter increases the over-all ac-
curacy and utility of the system.

Arthur AD Little Inc.

TABLE II-3

SHORT-RANGE NAVIGATION SYSTEMS

Estimated

System Useful Range Accuracy

Shoran 25-75 nm

Alpine Dependent
Precision upon ship's

Radar radar being
Ranging used
Unit
Radar 200 ft to
50 nm

Autotape 100mto
100 km

Hydrodist 40 km

Hi-Fix 50-100 nm

Estimated

100-250 ft

+ 80 ft

1:2500

+1-2m

+1.5m

+2 5-40 ft

Frequency
Range
210-320 mc

3-cm band

3- and 10-
cm band

10-cm
band

10-cm
band

2 mc

Comments

A high-accuracy standard
control method for near -
shore surveys, used since
1945.

System complements stand -
ard ship's radar. Includes
accurate time base, digital
readout and display, track-
plotting and transponder
equipment.

Moderate ranging accuracy.
Used for general search,
hazard warning, harbor con-
trol, etc.

2 portable shore responders
required. Automatic rang-
ing and tracking capability .
Digital output and track -plot-
ting equipment available.

2 portable shore responders
required. Since automatic
ranging, manual tracking,
digital output and track-
plotting equipment available.

2 or 3 portable shore sta-
tions required; both ranging
and hyperbolic mode avail-
able. Decimal counter dis -
play; automatic plotting
equipment available.

Arthur A. Little Inc.

The Autotape system and the Hydrodist system operate in the 10-cm
band and use cw phase comparison techniques. Two precisely positioned shore
stations are used with each system; these can operate unattended. Automatic
plotting equipment increases each system's utility and allows the survey vessel

to be positioned with a potential accuracy of 1-3 meters at maximum ranges of
25-60 miles.

The Decca Hi-Fix system utilizes cw phase comparison techniques
and ground wave transmission at frequencies in the 2-mc band. The system is
portable and may be used in either the hyperbolic or ranging mode. Automatic
track-plotting equipment is available. This system is in use for hydrographic
and survey purposes in this country and in Europe.

10

Arthur D.Little, Inc.

Ill. FUNDAMENTALS REVIEW

A. GENERAL

Most electronic navigation and precise ship -positioning systems de-
pend upon the measurement of the time it takes for radio frequency (rf) energy
to travel from the transmitter to the receiver. The transmitted energy must
be in the form of either short pulses or continuous waves (cw). Some systems
measure pulse-time difference; a second group of systems measures phase dif-
ferences, and a few systems use a combination of both techniques.

While the accuracy of the distance measurement is primarily a func-
tion of the time measurement, the characteristic velocity of the rf energy must
also be known. For most distance measurements in ship -positioning or naviga -
tion applications, a standard value of propagation velocity is used. When meas -
urements must be extremely accurate, the atmospheric index of refraction must
be measured precisely so that the corrected velocity of transmission can be
calculated. The distance as measured by the product of the velocity of propaga -
tion and the time may not be the same as the geometric distance, and further
corrections for refraction and reflection may have to be made.

Rf energy may be propagated between transmitter and receiver (1) by
direct path, (2) by reflection from the ionosphere, or (3) along the earth's sur-
face. When radio waves are refracted or reflected from the ionosphere, they
are called sky waves. Because of the instability of the ionospheric layer, cor-
rections for sky-wave paths must be computed but at best are only approxima -
tions. When sky-wave transmission can be predicted with greater accuracy and
reliable variations computed, they will be as valuable to long-range, precise
ship positioning as they are now to communications and navigation. For thepres-
ent, only the ground wave is used for the accurate ship positioning required for
hydrographic surveys. Sky-wave transmission is used at great ranges for navi-
gation purposes, but is less accurate and often is more of a hindrance than anaid.

A wide range of frequencies has been found necessary to satisfy the
many precise ship -positioning and navigation requirements for accuracy and re-
peatability. Frequencies of 30 - 3000 mc and higher are most useful for line of
sight and where precision is required. Frequencies in the range of 300kc to
3mec are used for systems operating out to distances of the order of 500 miles.
Frequencies from 10kc to 300kce are used for those navigation systems requiring
operation at ranges of several thousand miles.

For some measurements, only a range (distance) is required. How-

ever, in most navigation and near-shore hydrographic work, the direction from
the transmitter to the receiver is also required, so that a position fix may be

11

Arthur D.Aittle Inc.

established. Figure III-1 identifies three of the more common methods of es-
tablishing a position fix.

In addition to these three techniques, doppler and inertial methods of
navigation are becoming increasingly important. Both methods are capable of
continuously plotting a vessel's position with respect to a fixed reference point.

a. TWO ANGLES AND THE INCLUDED SIDE = TRIANGULATION OR DIRECTION FINDING.
b. TWO SIDES AND THE INCLUDED ANGLE = RADAR OR RHO-THETA METHOD.
c. THREE SIDES = TRILATERATION.

FIGURE III-1 POSITION FIX GEOMETRY

12

Arthur AD Little, Inc.

B. SYSTEM CLASSIFICATION

Navigation and ship -positioning systems are generally classified as
hyperbolic, ranging, or azimuthal. This classification refers to the radiation
patterns, which are illustrated in Figure III-2.

1. HYPERBOLIC POSITION-DETERMINING SYSTEMS

All hyperbolic position-determining systems define a hyperbolic line -
of-position by measuring the difference in transmission time between signals
transmitted simultaneously, or with a fixed delay, from two fixed stations; these
stations represent the foci of the hyperbolic line of position. To generate a fix,
two lines of position (LOP) must be generated, and a third station, which serves
as a master to each of two slave stations, is required. The time ~difference
error makes the actual position line indeterminate between two adjacent position
lines. This distance is called the lane width and corresponds to one-half wave
length of the transmitted frequency. Either pulsed or continuou’s wave trans-
mission is used. Some systems use a combination of the two.

The actual error of the position fix with such a system is proportional
to the largest dimension of a diamond formed by the intersection of adjacent
paired lines of position. The positional error increases as the distance from
the stations is increased. Loran-A, Loran-C, Decca Navigator, and Omega are
examples of hyperbolic navigation systems.

2. RANGING SYSTEMS

Distance -measuring (ranging) systems generate a circular pattern.
The master interrogates the shore stations; these stations respond, and the
round-trip time is measured at the master station. Either pulsed or continuous
wave may be used. It is clear from Figure III-2b that this arrangement yields
higher accuracy over a larger area than hyperbolic systems do. However, the
systems required to generate circular patterns are usually more complex, and
several frequencies are often required to generate and transfer the required in-
formation. Ranging systems such as Shoran and Raydist have found their great -
est use in hydrographic work where the ranges are 200 nautical miles or less.
Lower -frequency systems such as EPI have been found useful to ranges of 400
nautical miles.

> Ls}

Arthur 2. Little, Ire.

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‘14

FIGURE III-2

b)

3. AZIMUTHAL SYSTEMS

Azimuthal systems (angle measurement systems) do not measure a
range but measure an angle only. If the transmitter or the receiver position is
known, a hyperbolic line of position can be established. Measurements of angle
can be made either from shore stations or from a moving vessel. Thus, the
azimuthal system requires a known base line and establishes a fix by measure -
ment of two or more angles. This type of system is commonly known as radio
direction finding (RDF). Another class of azimuthal system known as Consol
(the U.S. version is known as Consolan) uses a rotating radiation pattern and
provides identification signals which permit greater angular resolution than is
possible with RDF.

Of the navigation systems in use, the angle measurement systems are
the least complicated but also are the least accurate. The uncertainty of the
azimuthal measurement of position is determined by the system geometry, the
frequency of operation, the range, and other factors.

C. SYSTEM METHODS

1. PULSE-TIME SYSTEMS

For a pulse-time measurement two transmitters are precisely timed
to transmit pulsed energy in a fixed sequence from transmitters located at end
. points on a base line. The receiver, C, may be located at some undetermined
‘point, as shown in Figure III[-3a. If the receiver C were placed nearer trans -
mitter A on base line AB it would receive pulse A before receiving pulse B.

If it were nearer B it would receive pulse B ahead of pulse A. In practice
pulse B is transmitted after pulse A and separated from it with a fixed time
delay, to eliminate ambiguity and help identify pulses A and B. A comparison
of the time of arrival -- by equalizing amplitudes and matching the received
pulses at the receiver C -- will locate the receiver on a hyperbola along which,
by definition, all points have a certain constant distance difference from two
stations. The hyperbola thus forms a navigational line of position. Another
pair of signals utilizing stations A and D could be precisely timed and identified
in the same manner to form a second hyperbola intersecting the first at the re-
ceiver and fixing the receiver's position.

2. PHASE MEASUREMENT SYSTEMS

In the second method of position measurement a continuous wave sig-
nal is transmitted simultaneously from stations A and B, as in Figure III-3b.

15

Arthur DAHittle Inc.

a)

LOP FROM AB

LOP FROM AD

b) x
it t
2 2
A By B
» y
~ AON ZG
NN a
ey we 7
C' \ Yr
C
Y

FIGURE III-3 RADIO FIX ILLUSTRATING BASIC HYPERBOLA
RADIO NAVIGATION PRINCIPLE

16

The phase of signal B is usually "phase-locked" to signal A. Thus, the phase
difference of signals A and B at receiver C is a function of the position of the
receiver with respect to each transmitter. For example, if line XY is the right
bisector of the base line AB, it follows that at any point on line XY the signals from
transmitters A and B will be in phase and a phase meter will read zero, as the
signals will have traveled equal distances, assuming their velocity to be constant.
Should receiver C be moved nearer transmitter A by a distance corresponding
to one-half wave length of the transmitting frequency, the two signals from A

and B would be 180 degrees out of phase and would have traversed one lane width.
A second station, D, also phase-locked to station A operates in like manner and
generates a second set of hyperbolic lines of position. The receiving and phase
comparison devices are duplicated to work with the two sets of coordinates, and
the observer fixes his position at any point in time by transferring the readings

of the phase meters to a chart on which numbered lanes of the two patterns are
printed. The proper reading of position is dependent upon initially setting the

two phase meter dials and recording the reading when the receiver is at a known
geographical position with respect to points A and B.

3. ANGLE MEASUREMENT

For this method only an angle is required to establish a line of position.
Range is not measured. Two or more lines of position can establish a navigational
IIS

Figure II-4 shows the geometry of the angle measurement system.

FIGURE III-4 ANGLE MEASURING SYSTEM GEOMETRY

In this figure, A and B represent the known locations and C represents the po-
sition to be determined by angle measurement. AC and BC are the lines of posi-
tion. The position of C may be fixed by transmitting from C and determining

V7

Arthur D.Little Inc.

the direction of the received signals at both A and B. A second method would
be to transmit signals from A and B and to measure their direction of arrival
au Ge

D. RF PROPAGATION

The velocity of propagation of radio waves, in a perfect vacuum, is
independent of frequency and is equal to the velocity of light. Recent experi -
mental determinations have shown the values of free-space velocity to be in good
agreement. A number of these values have been combined in a least squares de-
termination which yields a value for this constant of C = 299,792.9 + km/sec.

1. INDEX OF REFRACTION

Atmospheric conditions cause variations in the index of refraction and
thus in the velocity of propagation in free space. Therefore, range measure-
ments of high accuracy generally utilize a corrected velocity of propagation.
Measurements may be made over a base line of known length or the atmospheric
variables may be measured and the propagation velocity corrected with a com-
puted index of refraction:

a ae | p + 4810 (=) (1)

where n is the index of refraction, T is the temperature in aK, p is the air
pressure in millibars, and w is the partial water vapor pressure, also in milli-
bars. 0

The true velocity of propagation is then determined by the relationship:

v= POTS km/sec (2)

14+N1073

where N = refractivity = (n-1) 10°.

Atmospheric pressure, temperature, and humidity vary with location,
time, and height. However, except for the most accurate range and ship -posi-
tioning measurements, a homogeneous atmosphere and a resulting constant propa -
gation velocity are assumed. This assumption generally produces a negligible
SiTicONe

18

Arthur D. Little Inc.

2. GROUND WAVE

The ground wave travels over the transmission path near the earth's
surface. Three types of ground waves may be propagated, as illustrated in
Figure III-5.

C
TRANSMITTER RECEIVER

Qg. DIRECT WAVE
b. GROUND-REFLECTED WAVE

c. SURFACE WAVE
Y.

FIGURE III-5 GROUND-W AVE PROPAGATION

Because of the curvature of the earth's surface, only the direct and
the ground-reflected waves enter into consideration at frequencies above approxi -
mately 30 mc. At these frequencies the useful range is essentially line of sight.
For the frequencies of interest here, surface waves are the most important of
the ground waves.

Surface waves are transmitted horizontally, and the earth's atmos -
phere and ground conductivity cause the propagated wave to remain near the
earth's surfaces and follow its curvature. The rotation of the vertical plane of
polarization of the wave front, due to the finite conductivity of the earth, gives
rise to phase errors. This type of error is particularly important in long-range
navigation problems where very low frequencies (VLF) are used.

During propagation, the ground wave becomes more attenuated than in
free space. Surface wave attenuation increases as the frequency is increased,
until at a frequency of about 30 mc, the surface wave is almost totally absorbed.
At frequencies above 30 mc, only sky-wave transmission remains for long-range
navigation and communication purposes.

19

Arthur A Little Hie.

3. SKY WAVES

The index of refraction does not vary linearly with height. In addition,
ionized layers are always present in the upper atmosphere. As a result of these
effects, rf energy when propagated at a sufficient angle to the earth's surface is
refracted in the atmospheric layers and bent earthward. If conditions are favor-
able the rf wave will eventually return to earth at some distance from the point
of origin. Upon reaching the earth the wave front may be reflected again toward
the ionosphere and the process repeated until all the energy is finally attenuated.
(See Figure III-6.)

Both the altitude and density of the three most important ionized layers
vary as a function of the time of day, season, and year. Further variations occur
each solar cycle of about 11 years.

RELATIVE IONIZATION DENSITY

ws ay Fe

F.
eg al
ee oe tae
Se Y Sy
wee YY,
t

FIGURE III-6 SKY-WAVE PROPAGATION WITH REFLECTION
FROM Fo LAYER

a. Propagation at Frequencies of 30 - 300 kc

Frequencies in the range of 30 - 300 kc are known as low-frequency
(LF) waves and are only slightly attenuated when propagated as a surface wave.
With adequate amounts of power the surface wave can be propagated over dis -
tances of 500 nautical miles or more.

20

Because the frequency is low, the sky wave is heavily refracted by
the ionosphere and is bent back toward earth after penetrating only a very short
distance within the ionized layers; thus only a very small attenuation is incurred.
The wave may be reflected at the earth's surface and redirected back toward the
ionosphere. Because of the limited altitude of the layers and the curvature of the
earth's surface, which limits the maximum skip distance, the sky waves propa-
gated in this frequency range may travel over distances of 2000 miles or more.

A small energy loss occurs at each reflection. The path covered de-
pends on the distribution of ionization. The field strength at the receiver shows
both diurnal and seasonal variations. In general, propagation conditions are
more favorable in winter than in summer.

b. Propagation at Frequencies of 300 kc - 3 mc

In the medium frequency (MF) range of 300 kc - 3 mc surface-wave
propagation is less satisfactory; the wave becomes more attenuated than in the
case of long-wave propagation. The range of effective coverage by powerful
transmitters is generally less than 500 miles.

At the medium frequencies the sky wave is refracted less than at the
lower frequencies, and a greater penetration into the ionosphere takes place.
During daytime hours when the E -layer is low-lying, a large amount of absorp -
tion occurs because of the high density of this ionized layer. As a result the
sky wave becomes highly attenuated and seldom reaches the ground to complete
the first skip. During daylight hours, therefore, sky-wave transmission is not
considered reliable, and surface -wave propagation must be used. At night, how-
ever, there generally is considerable sky-wave return in this frequency range
because of the disappearance of ionization at the lower altitude. At sunset the
absorption of the sky wave rapidly decreases, because the density of the low-
altitude ionized layer decreases. A few hours after sunset ionospheric propaga -
tion as well as surface propagation takes place and continues until dawn.

During the evening hours this frequency range is characterized by
three areas of reception. The surface wave predominates at the relatively short
ranges, while at longer ranges the sky wave predominates. At the intermediate
ranges both waves have nearly equal strength, and severe interference may re-
sult. The interference is in the form of phase distortion, because the sky wave
travels varying distances as the height and strength of the ionospheric layers
shift throughout the evening hours. Field strength also varies, and signal fading
is common. Sky-wave reception is required beyond the intermediate area; re-
ception is good but not as reliable as the surface-wave reception at the short
ranges.

21

Arthur A Little Inc.

c. Propagation at Frequencies of 3 - 30 mc

In the high frequency (HF) band, attenuation of the surface wave is
more rapid than at lower frequencies, while the sky wave is attenuated less be-
cause of the higher frequency. As the frequency is increased, the refractive
index tends toward unity and the skip distance increases. Thus, for a given dis-
tance between transmitter and receiver there is an optimum frequency. The
frequency used is also determined by the state of the ionosphere. Statistical
data is available which helps determine the maximum utilizable frequency for
operation between two given points .

For long-distance communication and navigation, the sky wave may
require more than one hop to cover the required distance. In this way it is pos-
sible for the radio wave to complete one or more trips around the earth, thus
giving rise to signal interference. However, transmitted frequencies in this
range are generally less subject to atmospheric and local interference than the
medium wave field. Fading is a problem in this high-frequency range and is
often minimized by such means as automatic sensitivity control and diversity
reception.

d. Propagation at Frequencies Greater than 30 mc

Rf energy, when radiated at the VHF and higher frequencies, behaves
in the same manner as light rays. The surface wave follows an almost optically
straight path from the transmitting antenna to the receiving antenna, with only
small atmospheric refraction. Because of the high frequency, the index of re-
fraction approaches unity, and wave fronts entering the ionosphere will not be
bent sufficiently to return to earth. For this reason all communications at fre-
quencies above about 30 mc operate within line-of-sight range.

Because of the inhomogeneities in the earth's atmosphere, some re-

fraction does take place, and a direct wave can be directed to distances beyond
the line-of-sight range. The probable range of transmission R is given by the

expression:
R =k [a op [hy in miles (3)

Antennas at the transmitter of height hy and the receiver hy are generally
placed as high as possible, and a refraction factor k of 1.1 - 1.6 is used to ac-
count for the increased range due to atmospheric refractivity .

Atmospheric ducts which may make even line-of-sight transmission
within this frequency range impossible are sometimes formed. The ducts result

Dd)

Arthur A. ULittle Inc.

from anomalies in the index of refraction and are commonly formed in seashore
areas, where there may be large temperature and conductivity differentials,
often attributed to the movement of warm, dry air out over the water.

Frequencies in the range of 100 - 10,000 mc are used for the measure -
ment of ranges to geodetic accuracies. A corrected velocity of transmission is
usually required for the most precise range determinations possible.

E. RANGE CONSIDERATIONS

Several factors have been shown to affect the useful range of a radio
signal. These are the shape and electrical conductivity of the earth, the state
of ionization and noise -producing qualities of the atmosphere, the bandwidth, and
the signal frequency .

For ground-wave transmission, the ranges are essentially optical at
the shortest wave length and depend upon antenna height and line -of-sight trans -
mission. The effective operating range is greatest for the low and medium fre -
quencies and is dependent almost entirely upon wave length. At the longer wave
lengths effective antennas must be very large, and the radiation efficiency de-
creases to very low values, making it difficult to radiate large amounts of power.

Certain sky-wave factors must also be considered where high -quality
ground wave transmission and reception is contemplated. At frequencies in the
range of 30 kc to 10 mc, long-range transmission may be expected. Useful
coverage is limited to a few miles during daylight and less than 2000 miles dur-
ing evening hours at frequencies near 1 mc. For frequencies less than about
0.1 mc the stronger sky-wave component tends to invalidate the longer ground -
wave ranges possible at these frequencies, and special circuit and statistical
techniques are required to achieve these long ranges. These effects are shown
in Figures III-7 and III-8.

As indicated in Figure III-8, the continuous wave systems take advan-
tage of the characteristics of the predominating ground wave for ranges out to
400-500 miles. As distance from the transmitter increases, the ground -wave
field intensity drops off more rapidly than the sky wave, so that sky-wave inter -
ference tends to predominate at ranges of a few hundred miles. Because the
phase of the sky wave is random relative to the ground wave, the resultant signal
fades. Under these conditions the indicated phase is made random and the read-
ings bear little relation to the position of the navigator. The straight line of
Figure III-8 indicates the maximum useful range for pure ground waves.

23

Arthur A. Little Inc.

FREQUENCY (megacycles)

300 100 30 10 3 1 03 0.1 003 001
10,000

5000

2000

1000

NAVIGATIONAL 500
RANGE

(statute miles) oe

100

Pie)

1 3 10 30 100 300 1000 3000 10,000 30,000
WAVE LENGTH (meters)

FIGURE III-7 AVERAGE SKY-WAVE TRANSMISSION
RANGES

FREQUENCY (megacycles)
300 100 30 10 3 1 0.3 0.1 0.03 0.01

PULSE TRANSMISSION

LORAN

NAVIGATIONAL 50°
RANGE
(statute miles) 200

CONTINUOUS WAVE

100

TRANSMISSION RapDiO

RANG
50 E

BROADCASTING

1 3 10 30 100 300 1000 3000 10,000 30000
WAVE LENGTH (meters)

FIGURE III-8 MAXIMUM RANGE AT WHICH GROUND-

WAVE TRANSMISSION IS ESSENTIALLY
FREE FROM SKY-WAVE INTERFERENCE

24

Pulse systems in the high- and medium-frequency range have advan-
tages because when short pulses are used the ground wave may be distinguished
even with sky wave interference. However, at frequencies below about 100 kc,
this advantage tends to disappear, as pulse generation and radiation become more
difficult and pulse transmission approaches continuous-wave transmission, where
phase-difference readings must be made. Figure III-8 shows that high-accuracy
navigation systems dependent upon ground-wave transmission cannot operate ef-
fectively at ranges greater than a few hundred miles. Generally those systems
using high-precision cw phase measurement techniques are restricted to daylight
use to avoid sky-wave contamination. Combinations of pulse and continuous-wave
techniques are used for the long-range low-frequency navigation systems such as
Loran-C and Omega.

FEF. ACCURACY

The accuracy of a particular navigation system may be taken as a
measure of its performance. However, the statistical terminology for describ-
ing accuracy is not well-standardized and for many systems is not generally
available. In this report both the terms accuracy and precision are used in de-
scribing system performance. The accuracy of a system is taken to mean the
deviation of a value from the true value. The term precision indicates the sys-
tem's repeatability, expressed in suitable terms.

The accuracy of a navigation fix is a function of the accuracy and sta-
bility of each line of position and the angle at which these lines intersect. This
stability is dependent upon a number of factors, many of which are variable with
respect to time. These factors are often classed as systematic and random
errors.

1. SYSTEMATIC ERRORS

The errors grouped as systematic errors are those which are the re-
sult of system design or alignment. This class of errors is of constant value
and sign and adversely affects over-all system performance. Generally, these
errors can be calculated or measured and then allowed for in the design of the
equipment. In some cases they can be directly compensated for in the equipment's
alignment or adjustment. Some systematic errors are calibrated out in the charts
and tables provided.

2. RANDOM ERRORS

The random errors cannot be so easily accounted for because they are
unpredictable and time-dependent and vary with changing radiation parameters.

25

Arthur DHittle Inc.

propagation conditions, and operation error. Because of the random nature of
these events they must be averaged over a period of time and treated statistically .
In this manner it is possible to state the probability that the error of a given po-
sitional fix lies between zero and some upper limit. Much of the more recent
navigation literature makes use of the very important root-mean-square error of
repeatability which is discussed below.

In Figure III-9 point P is the apparent location of a navigational fix.
The individual position line errors are indicated as x and y.

FIGURE III-9 LINE-OF-POSITION GEOMETRY

The radius d is taken as the radial error or the straight-line deviation of the
probable position from the true position. The root-mean-square error d, is
often used to describe the random errors occurring in a navigation fix formed
by two intersecting lines of position. Measurement errors are calculated along
each of the two orthogonal axes, assuming they are uncorrelated and have a nor-
mal distribution. The error probability is found by first computing the standard
deviation © from the errors of a large number of observations. With equal
standard deviations of 6, = 0, a circle may be drawn with its center at the
mean value of its position coordinates. A circle of dy = 0 /2 is then defined
as the root-mean-square error. The circle defines the locus of points having

a constant probability density and encloses an area where a single measurement
will fall 63% of the time. For a circle of 2d, the probability increases to0.982.

For the case 0, # 0, a parallelogram is formed which defines an
error ellipse. However, by a proper transformation of the axis the parameter d

26

Arthur D.Aittle Inc.

may again be used to represent the spread of individual position determinations .
The error in using a circle instead of the appropriate ellipse is only a few per-

cent, as indicated in Table III-1.

TABLE I=]

ERROR PROBABILITY CONTAINED IN CIRCLES
OF VARYING RADIUS

Probability for Probability for
Radius of Circle Ce oy OF = 0
eds 0.632 0.683
2 di. 0.982 0.954
3d. F999 0.997

The use of d. to describe the navigational fix radial error distribution
is not standardized but is finding wider favor, especially among the newer sys -
tems being evaluated. However, other methods are sometimes used which are
interrelated to the root-mean-square distribution d,, as indicated in Table III-2.
By using the conversion factors of Table III-2, one can intercompare systems

using methods other than d_. SirweOre
TABLE III-2

COMPARISON OF STATISTICS OF ERROR FOR Ore
AEA DES SE ee ee a eo

Statistical Value in Terms Normalized
Measure of Oo to dy;
Root -Mean -Square Error d_. 1.41 0 1.00
Standard Deviation of d oF 0.65 o 0.463
Variance of d one 0.43.02 0.304
Circular Probable Error CEP 1.18 6 0.833
27

Arthur AD Aittle Inc.

3. ESTIMATED SYSTEM ACCURACIES

The estimated accuracies achievable under the most favorable operat-
ing conditions for the common types of measurement methods are illustrated in
Figure III-10. In this figure the curve on the left is calculated on the assump -
tion that pulse comparison measurements may be made to about one-fifth of the
pulse length. Since it is difficult to radiate a pulse whose length is less than
50 cycles of the carrier frequency, time-difference measurements between
pulses can only be made at about one-fifth the pulse length. The measurement
is therefore accurate to about 10 wave lengths in space. If we assume that two
measurements are made and two lines of position which are at right angles to
each other are established, the average error of fix will be about J/2 times the
least reading. This leads to the fix error shown.

If the two pulses to be compared are carefully made similar when
radiated and are amplitude -equalized at the receiver, then visual superposition
is accurate to within about 1% of pulse length. This makes possible a 20-fold
improvement in the accuracy as shown by the center curve in the figure.

So far as is known, the final step in accuracy improvement is phase
comparison, accurate to about 1 - 3 degrees of phase. Taking 1/200 wave length
as an average figure, this represents an accuracy 100 times that of Loran-A,
as the curve on the right in Figure III-10 indicates.

REFERENCES

J. A. Pierce, ‘Electronic Aids to Navigation, "’ in Advances in Electronics,
Academic Press, 1948, pp. 425-451.

28

Arthur D.Little Inc.

FREQUENCY (megacycles)
300 100 30 10 3 1 0.5 0.1 0.03 0.01

(statute miles) 2

0.5
MINIMUM
AVERAGE 1000
ERROR
OF FIX 500
200
(feet) 100

SOF

25
100 300 1000 3000 10,000 30,000

WAVE LENGTH (meters)

FIGURE III-10 THE MINIMUM ERRORS OF FIX
ATTAINABLE BY THREE STANDARD
MEASURING TECHNIQUES

29

:

bands
SA Tree
ie i

her
Al
mi

i ANG ol |
Pi Aa
BYE MUAY a)
hipaa ys

IV. LONG-RANGE NAVIGATION SYSTEMS

31

Arthur D Little Inc.

uy
[

oe
i

aay
Saale &
Wee

A

i

By

a

ne
jae

ith
AL

} i Mh

A. CELESTIAL NAVIGATION

The hand-held sextant and tables, historically the basic tools of the
navigator, are inexpensive and easy to use. With this equipment a navigational
fix can be established to an accuracy of about +3 nautical miles in most geo-
graphical areas throughout the world. The navigator's position can only be
established to this precision, however, under the best of conditions at sunrise
and at sunset, when the sun and horizon are clearly visible. The average us-
ability of this method on a world-wide basis is less than 50%, and in some geo-
graphical areas many days may pass before a celestial sight can be taken and a
fix established.

The Geon (Gyro Erected Optical Navigation Sanne is a develop-
mental high-accuracy celestial system which uses a Mark 19 gyrocompass to
maintain the astronomical meridian and indicate the vertical. A small equatorial
telescope is mounted on the system and sighted on a star. By setting the polar
axis the navigator determines the altitude of the pole and the latitude is found
directly. The longitude is calculated by noting the local hour angle and com-
puting the Greenwich hour angle. The method makes use of celestial coordinates
and avoids use of the visual horizon. The system requires manual setting and
computation. About three minutes are needed to establish a fix. At the present
state of development navigational accuracy is between 0.2 and 0.3 mile.

The recently developed Automatic Star Tracking equipment uses a
very accurate inertial platform as a vertical reference system. It has the
ability to lock on and continuously track a selected celestial body, thus produc -
ing position information continuously. Equipment of this type has been used
successfully on a range ship for special applications. While the Geon and
Automatic Star Tracking systems are passive and provide greater accuracy than
the hand-held sextant, they have the same limitations with respect to cloud
cover.

The Radiometric Sun and Moon Tracker is a celestial navigation sys -
tem which uses only the sun and moon as celestial reference bodies. When only
one body is available only lines ofposition maybe plotted. Although cloud cover
is not a limitation, the coverage is limited by the geometry of the moon-sun
orbits, so that world-wide availability is again below 50%. Because of their
complexity and high cost, this system and the Automatic Star Tracker system
can usually be justified only for very special applications requiring a high
degree of navigational accuracy (2

REFERENCES

1. W.S.Von Arx, "GEON: A New Navigation System, " Journal of the Institute
of Navigation, Vol. 9, No. 3, 1962.

2. B.J. Baecher, Naval Navigational Trends, paper presented at Institute of
Navigation Meeting, June 1963.

33

Arthur A Aittle Ine.

B. CONSOL AND CONSOLAN

1. GENERAL

Consol is a radio navigational aid developed by the Germans (SONNE)
during World War II and used and further developed by the British and their
allies. There are seven stations in Europe and three in the United States, as
indicated in Table IV-1. Figure IV-1 illustrates the European areas of cover-
age.

Consolan is an improved American version of Consol which uses two
transmitting antennas instead of the three required in Consol. The identical
pattern is generated in both versions. In Consolan higher power levels and
lower frequencies are used and increase the coverage area. A three-tower sys-
tem is located at Miami, andtwo-tower Consolan installations are operated by the
Federal Aviation Agency at Nantucket and San Francisco, Charts are available
from the U.S. Hydrographic Office.

The Consol system may be considered an improved version of the
RDF radio range and is also an azimuthal system generating a hyperbolic grid.
An operator using a standard communications receiver determines his LOP
aurally as the courses sweep through his position. He must recognize and in-
terpret the pattern (Figure IV-2) and plot his position on properly prepared
charts. In addition he must use either a radio direction finder or dead-reckon-
ing information to place himself in the proper sector. Thus, the Consol (or the
Consolan) serves as a vernier adjustment to his RDF bearing, giving him an
LOP to a fraction of 1° in most sectors of the pattern. These systems are use-
ful at maximum ranges of 500-1400 nautical miles.

2. DESCRIPTION

a. Transmitter

A consol ground station has three antennas mounted in line with
three -wave-length spacing. A transmitter feeds each antenna with energy of
proper phase and amplitude, generating the field pattern of Figure IV-2. The
phase in the center antenna B is taken as reference, and the currents in A and
C are made to lead and to lag B by 90°, respectively. With a spacing of three
wave lengths between antennas, the solid line curve of Figure IV-2 is generated.
If the phases of antennas A and C were interchanged, the dotted curve would
be generated.

34

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35

Arthur DUittle, Inc.

FIGURE IV-1 AREAS COVERED BY THE CONSOL STATIONS
BUSHMILLS, STAVANGER, LUGO, AND SEVILLE

36

> eae) RECHION

OF SWEEP

EQUISIGNAL

DIRECTION

Pe ee 9 OF SWEEP

CONSOL

FIGURE IV-2 POLAR DIAGRAM OF ANTENNA SYSTEM
AT BEGINNING OF SWEEP

37
Arthur A Aittle Ine. -

Each sector is of the order of 12° in width. Dot and dash signatures
are radiated in alternate sectors. Smoothly varying the phase of antennas A
and C with respect toBmakesthe equisignal lines rotate at an almost uniform
rate through one sector during the keying cycle. Rotation ceases at the end of
the cycle, and the pattern returns to its original position for the next cycle.

b. Receiver

The observer uses a standard communications receiver with an omni-
directional antenna and hears the equisignal once during each keying cycle. The
angular position in the pattern sector is determined by listening to the signal
and counting the dots or the dashes before the equisignal, which always appears
as a continuous tone. A continuous signal and an identification code are trans -
mitted between the keying cycles.

At the end of each keying cycle all the equisignal lines momentarily
disappear. They reappear in their initial positions at the beginning of the next
cycle and resume rotation as described.

Each transmission cycle lasts for a time period whose length de-

pends on whether the German or English cycle is being used. Some of the
important transmission characteristics are listed in Table IV-2.

TABLE IV -2

TRANSMISSION CHARACTERISTICS

Consol Consol Consolan

German Cycle English Cycle American Cycle
Transmitted Signal Seconds Seconds Seconds
Call Sign and DF Signal 55 26 7 ®
Silent Interval 235 2 Do)
Directional Transmission
(Dots or Dashes A n/sec) n = 60 n = 30 30
Silent Interval Pd, ) 2 25

It is evident, for example, that with a sector width of 12° and a German keying
cycle utilizing 60 dots or dashes per sector, the resolution per sector is of the
order of 1/5°.

38

Arthur A Little Inc.

Special charts are required for Consol fixes and are available from the
hydrographic establishments of England, France, Germany, Denmark, and Spain.
They are in mercator projection and contain the great circle bearings from each
station. The lines are numbered and dot-dash characteristics are noted.

3.. ACCURACY

The accuracy of Consol and Consolan fixes depends upon the distance
of the receiver from the transmitter and upon its position in the field. It is gen-
erally felt that adequate fixes can be generated within a 70° sector either side of
the normal to the line of transmitting antennas.

Receiver signal-to-noise (S/N) ratio will materially affect the useful
over-all system range. Atmospheric static noise isproportionalto the receiver
(By) ©. Because the Consol signal is single frequency cw, a narrow-band filter
can be used to improve the S/N ratio.

The polar diagrams plotted in Figure IV-2 tend to indicate reception to
an infinite range. Application of a correction for reception at infinite range shows
that the principal effect is a reduction in discrimination due to a poorer S/Nratio.
The noise between dots and dashes builds up, thus making them more difficult to
count.

eine IV-3 indicates some typical signal strength curves for a 1-kw
transmitter.(1) It should be noted that the sky wave is stronger than the ground
wave during evening hours at all but short ranges of less than 200 miles. Lower
frequencies are used in the U.S. version, and the useful range is thereby in-
creased.

An area within which the reduction of the discrimination is 30% or more
is bounded by a curve of which the radius vector is proportional to the sin of the
azimuth. The maximum vector is at right angles to the line of the masts and is
approximately equal to 12 times the mast spacing. Considering an antenna spacing
of 34 and utilizing a frequency of 300 kw, we find that within a circle of 15 - 25
miles the bearing taken with Consol will be inaccurate.

By utilizing antenna spacing of about 34, the narrowest sector generated
is 10°, giving a theoretical bearing accuracy of 10/60 or 1/6° (using German
cycles). Due tothe form of the polar diagram, accurate vectors can be obtained
over an arc of about 70° on each side of the bisector of the line of masts. Because
the width of the sectors increases as the radius vector approaches the line of the
masts, bearing accuracy deteriorates to about 1/3° at the extreme of the arc
coverage.

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Arthur A Aittle Inc.

104 c = DAY GROUND WAVE
d= NIGHT SKY WAVE

NV/M

200 400 600 800 1000
RANGE (nautical miles)

FIGURE IV-3 1 KW CONSOL FIELD STRENGTH
CHARACTERISTIC AT F = 300Kc

40

Sky wave-ground wave interference producing large LOP errors has
been noted under some conditions of operation at ranges between 150 and 600
nautical miles. At ranges shorter than 150 miles, the ground wave predominates;
at ranges greater than 600 miles, the sky wave predominates, and errors due to
interference of the two modes of propagation become negligible. The errors are
maximum when the two waves are of equal strength.

It is clear that the reliability of reception at a given range is dependent
upon taking such data under standard conditions and in large groupings, so that
statistical calculations can be made. The positional accuracy of Consol LOP have
been determined with enough data to calculate statistical error information. The
data include all random (equipment failure, etc.) as well as systematic (miscount
of dots and dashes, etc.) errors. TablelV-3 shows the 95% confidence Consol
LOP errors.

TABLE IV-3

CONSOL LOP ERRORS, 95% CONFIDENCE LEVEL

Error in Day Range Error in Night Range
Angle from Normal Over Sea Over Sea
(nm) (nm)
200 500 1000 100 300-1000 1500
On Normal 1S By dee 5 10 18
60° 3 6; 12 I 20 36
1" 6 12 24 2 40 72

Operator errors also arise from faulty sector identification or poor
counting accuracy resulting in lost counts. In practice, under less than maximum
S/N conditions the equisignal line may appear broadened, with a resultant loss of
both dots and dashes. The recommended method of counting dots and dashes is to
count both dots and dashes, subtract the sum of the two from 60 (German cycle),
and add half the difference to whichever is heard first. This method assumes an
equal number of dots and dashes are lost.

4]

Arthur A Little Inc.

4. SUMMARY

a. Type of System

(1) Azimuthal.
(2) Base line length: 3 wave lengths.
(3) Dependence of relative amplitudes:

(a) In transmission; the phase and amplitudes of transmission
from two radiators must be maintained in order to hold the
desired directivity pattern.

(b) In reception: phase and amplitude measurements are not
necessary. The receiver need only cover the proper fre-
quency band and perform the standard detection and
amplification functions.

(4) Type of modulation: keyed cw.
(5) Presentation:

(a) Aural or visual: as normally used the presentation is aural;
several visual dot-dash counting devices have been tried.

(b) The Larkley Consol Indicator links dots and dashes on a
teleprinter tape and provides a reading device for changing
the equisignal value on the tape to a dot-dash count.

(c) The Veedor counter utilizes three counters, one for dot count,
one for dashes, one for equisignal divided by two.

(d) Automatic or manual: manual operation is SOP.

(e) Continuous or intermittent operation: continuous.

(£) Time to procure data and plot fix: 4-5 min approximately.
(6) Ambiguities and how resolved: by RDF or dead-reckoning procedures
(7) Number of users: unlimited.
(8) Frequencies utilized:

(a) Consol: 257kc, 266kc, 285kc, 315kc, and 319kc.

(b) Consolan: 190kc, 192kc, 194kc.

(9) Bandwidth required: not more than 20 cps.

42

Arthur D.Little, Inc.

OOS ee NCD iC

—_——

b. Reception Factors

(1)

(2)

(3)

(4)

(5)

(6)

(7)
(8)

(9)

(1)

(2)

(3)

(4)

(5)

Adaptability to auto control: development appears to be practical
but auto control not available at present.

Fail-safe feature: system is fail-safe. A failure in transmission
of the ground station is apparent at the receiver if it is properly
monitored. No system error is introduced by a malfunctioning
receiver.

Circuit types employed and circuit peculiarities: Keyed cw trans-
missions. Character count at receiver determines LOP. Com-
munications receiver only required. Specialized narrow-band
equipment would increase reliability range andutilityofthe system.

Uncertainty of LOP: 1/3 - 1° in the largest percentage of the
coverage area.

Special chart requirements: special charts which are relatively
easy to prepare and use are required.

Security: service cannot be denied and is useful to friend and foe
alike.

Adaptability to recording: strip chart recordings quite practical.

Reliability: high; only a standard communication receiver is
required,

Range: 25-50 nautical miles minimum to 1000 - 1400 nautical
miles maximum range.

c. Transmitting Factors

Transmitter power: 1-3 kw used in each of the transmitters
required per ground station.

Antenna requirements: three top-loaded vertical antennas,
300-650 feet high.

Complexity of ground equipment: transmitters are standard cw
rigs. In addition, automatic keyer phase shifter and matching
units are used.

Reliability: high degree of reliability is apparent because of lack
of complex equipment.

Station operator requirement: automatic operation possible.
Maintenance requirements similar to standard cw stations of
this power.

43

Arthur A AHittle, Inc.

Ike

REFERENCES

A. H. Jessel, ''The Range and Accuracy of Consol," The Journal of the
Institute of Navigation, London, Vol. 1, No. 3, July 1948.

"Consol Navigation System," Paper No. 15, Third Commonwealth and Empire
Conference on Radio for Civil Aviation.

C. H. Ingall, "The Evaluation of Radio Set AN/FRN-5," AF Technical Report
No. 6234.

G. J. Sonnenberg, Radar and Electronic Navigation, D. Van Nostrand Co.,
1961.

Engineering Information Miami Consol Long Range Nav. Aid, Federal
Aviation Agency Bureau of Facilities, Navigational Aids Branch, Airways

Aids Section L/MF Facilities Engineering.

W. Bauss, Radio Navigation Systems for Aviation and Maritime Use,
Macmillan Co., New York, 1963.

Maintenance of Consolan Facilities Handbook, Federal Aviation Agency,
Washington, D.C.

44

Arthur A. Little, Inc.

C. RADIO DIRECTION FINDING (RDF)

1. GENERAL

Radio direction-finding systems utilizing a non-directional transmitter
and a direction-sensitive receiving antenna system have been in use for many
years as navigational systems for both aircraft and ships at sea. The simple,
low-cost equipment makes this system extremely useful where moderate LOP ac-
curacy is satisfactory.

The RDF beacon system is an azimuthal system which measures
direction rather than distance. In its most general use, it is composed of a fixed
cw or amplitude-modulated transmitter with a non-directional antenna and a RDF
receiver with tracking antenna which may be automatic. The output of the re-
ceiver is normally used in a feedback system to orient the receiving loop antenna
so that its plane is at right angles to the direction of the arrival of the signal.
The receiving instrumentation often includes a radio magnetic indicator (RMI).
Controls are provided to select the following functions:

a. Automatic visual bearing indication of the direction of arrival of the rf
signal and the simultaneous aural reception of modulated rf energy.

b. Aural reception of rf energy, using a non-directional antenna.
c. Aural reception of rf energy using a loop antenna.

2. DESCRIPTION

The system has a short-base-line, of the order of the ratio of the
antenna loop diameter to the rf wave length. The system is useful in the
allocated frequency range of 100 - 1750 kc, which includes the broadcast band.
However, the quality of bearings decreases at frequencies above 500 kc because
of polarization errors. A channel at 500kc is reserved for international dis-
tress traffic. Maritime RDF traffic is assigned to a frequency band of 405 - 415 kc.

Transmitters installed at fixed sites are generally cw and operate at
power levels of 0.4- 10 kw. Antennas are typically 150 - 300 feet in height and
are either wire or tower type. Transmission characteristics over sea water
are excellent at frequencies used, and thus less power and antenna height are
required when the transmitters are installed on surface vessels or buoys.

45

Arthur A. Little Inc.

SpA CCURAGH

Little data is available on the accuracy of non-directional beacons. A
value widely used for 9 is + 3° when within the limits of ground-wave range. This
indicates a 6° LOP error band 95% of the time. At distances less than 80 miles
errors in LOP due to night effects are small, and errors of 2- 3° can be expected.

Night effect occurs because a horizontal component of radio energy is
generated when energy is reflected from the ionosphere and interferes with
energy transmitted in the ground plane. The horizontal component results from
the rotation of the vertical plane of polarization during propagation through the
ionosphere.

The effects of terrain--reflections off mountains and irregularities in
the coast line--decrease the accuracy by the ratio of direct to reflected energy.
Refraction can take place and produce LOP errors which may exceed 5° when
energy propagated crosses a sea-land mass obliquely.

4, SUMMARY

a. Type of System

(1) Azimuthal, measuring angles.

(2) Base line length: onthe order of ratio of antenna loop diameter to rf
wave length. LOP are obtained by use of relative bearing and
magnetic compass information.

(3) Type of modulation: modulation of the carrier is used for station
identification purposes.

(4) Presentation:

(a) Visual or aural: presentation is visual for navigation, aural
for identification.

(b) Automatic or manual: fix information requires manual tuning
and plotting. Presentation is continuous.

(c) Time to establish position: approximately 2 minutes including
plot time. Time to establish fix depends upon difference in
angle between RDF needle position when resonance is first
obtained and the final needle position when the needle is at
rest on the bearing.

46

Arthur A HLittle Inc.

(5) Ambiguities: modern equipment utilizes antenna generating a
cardioid field pattern with one maxima and one minima so that no
ambiguity exists.

(6) Limitations on number of users: none.

(7) Frequency allocation: cw carrier in band between 100 ke and
1750 kc. Marine RDF stations are allocated frequencies in the
405 - 415 ke band, the standard frequency being 410 kc. U.S.
Coast Guard radio beacons operate in the frequency range of
713) 3 BS) IE

(8) Fail-safe feature: system is not fail-safe, although it has fail-
safe features.

(9) Coverage: the coverage of a RDF is dependent upon:
(a) radiated power
(b) noise level
(c) receiver bandwidth
(d) terrain

(e) magnitude of interfering sky wave.

b. S/N Ratio

A S/N level of 6 db is considered adequate for steady readings. A
1,2/1 ratio will give values that can be averaged. A daytime LOP range of
300 - 600 miles using the ground wave is typical for a 200-ke beacon radiating
1 kw of power. This range will decrease to about 350 miles at frequencies of
the order of 1500 ke (considering over-water transmission).

c. Ground or Sky Wave

Beacons operate most reliably on ground wave. The sky wave produces
stronger signal levels at greater distances than the surface wave, especially
during the hours between sunset and sunrise and at the lower frequencies used
during the day. Sky-wave field intensity is subject to diurnal, seasonal, and
ionospheric variations. These effects decrease the reliability of the fix when
using the sky wave.

47

Arthur A Little, Inc.

d. Susceptibility to Tilt and Polarization Errors
The system is susceptible to tilt error when multiple antennas are used.
The system is also susceptible to horizontal polarization, but this problem may
be minimized by using vertical polarization. The Adcock antenna system is
widely used to reduce the effects of horizontal polarization, although it is large
for shipboard installation.
e. Susceptibility to Propagation Disturbances
The system is not susceptible to propagation disturbances in the pure
ground-wave region but is highly susceptible in the sky-wave region.
f. Susceptibility to Atmospheric Noise
The system operation is degraded by noise, both man-made and static;
thus greater field strengths are required for satisfactory operation. The gen-

erally accepted signal strength levels are 70 Uv/M in noise zones under grade 4
and 120 Uv/M in noise zones of grade 4 and above.

REFERENCES

1. Radio Direction Finding, Special Publication 39, International Hydrographic
Bureau, Monaco.

2. P. C. Sandretto, Electronic Avigation Engineering, IT&T, 67 Broad St.,
New York, 1958.

48

Arthur D. Little Inc.

D. DECCA

1. GENERAL

Standard Decca is a ship -positioning and navigation technique devel -
oped in Britain and introduced commercially in 1946 by the Decca Navigator Co.,
Ltd. It is now in extensive use throughout the British Commonwealth and in
Greenland, Sweden, the Persian Gulf, and the eastern coast of Canada. (See
Figures IV-4 and IV-5.)

Unmodulated continuous -wave transmissions occupying narrow fre-
quency bands in the range 70-130 kcps are employed to generate hyperbolic lines
of constant phase difference. Phase comparison circuits on a shipborne receiver
utilize two or more of these lines to develop a position fix. Depending on condi -
tions of season and time of day, useful maximum ranges vary between about 200
and 500 miles, while 95% rms radial errors are roughly 1/4 to 4 miles.

2. DESCRIPTION

Decca chains generally consist of a master station around which are
disposed three slave stations at distances of 60-100 nautical miles. Thus, three
intersecting hyperbolic patterns are generated, from which the user selects the
two lines intersecting at the best angle for accurate cross -fix at his location.

Conceptually, the master station and a phase-locked slave station
transmit unmodulated cw waves of the identical frequency. The shipborne
receiving equipment then phase -compares the two signals to obtain a position
line. In practice, two waves of equal frequency cannot be phase -compared, as
they would combine at the receiver into a single wave. The desired effect is
achieved by operating the two transmitters at two harmonics of a fundamental
frequency f and then comparing phases at the receiver at a common multiplied -
up frequency. (See Table IV-4.) The phase differences are displayed on three
pointer -type phase meters, known as Decometers (one for each master/slave
combination). On board ship the Decometer readings are usually plotted manu -
ally on a chart overprinted with correspondingly numbered Decca -grid lines .
Airborne equipment generally provides a continuous automatic plot of the position
fix.

The space between the two adjacent hyperbolic position lines having
the same phase difference is known as a lane. In practice, interpolation of 0.01
lane can be achieved, corresponding to a position change of several meters along
the base line where the lane is narrowest. Typical values of base-line lane width
are given in Table IV-S.

49

Arthur DAHittle Inc.

TT
lly

FIGURE IV-4 DECCA NAVIGATOR CHAINS IN EUROPE
QUASI-MAXIMUM 95% RANDOM FIXING
ERRORS AT SEA LEVEL IN NAUTICAL
MILES

50

When entering the region of coverage, a ship would have to know its
position within half a lane; thereafter, a counter would record the number of
lanes traversed. This system operates quite adequately in many cases, but is
often inconvenient. The difficulty is avoided by superimposing a coarser -scale
hyperbolic net over the basic Decca net. The transmitting stations radiate a
coarse hyperbolic pattern confocally with each fine pattern sequentially, e.g.,
red, green, purple. The coarse pattern corresponds to the fundamental frequency
f; hence, one of its lanes, called zones, corresponds to 18 green, 24 red, or 30
purple lanes. This effect is achieved in the case of the master by transmitting,
together with the 6f signal, a 5f (purple) signal once a minute during the 1/2 sec
period occupied by each identification transmission; simultaneously the normal
purple slave is shut off. An f signal can thus be obtained by subtraction at the
receiver. Similarly, momentary transmissions of 9f and 8f together from each
slave provide a signal of frequency f at the receiver.

The lanes of the fine hyperbolic grid are numbered in away that avoids
confusion between the three patterms; the zones are identified by letters of the
alphabet and are of uniform width (about 10 km on the base line). Figure IV-6
illustrates the lanes and zones of the English Decca chain.

50a

Arthur D.Little Inc.

Jet yea rer tn aly Bai,
AS ee
Fee) eh ernie

non 7 be hy, as ro

thane

THAT ALITIGVEOUd %S6 SHNOLNOO
KOVUNOOV ONIXIN (GNVISI ISOOLLNV HO VAUV NI GACISdY
NIVHO O8F9aNO NAHM) ADVYAAOOD YUOLVOIAVN VOOR NVIGVNVO

LHOIN YSWWNS
AVG Y3SLNIM

|» b/t] Ava NWNINV'S
| ‘wu 8/1] AVG Y3SWWNS

YNOLNOD
F3AAR1 ALINGVEOUd %S6 a

SYNOLNOD ADVYNIOV_ONIXIS

51

fite.

i

Arthur AD Aittle,

7
7 INTERSECTION OF
TWO POSITION
IS FIX OF POSITI

FIGURE IV-6 DECCA LATTICE OF THE ENGLISH CHAIN

52

TABLE IV-4

TYPICAL VALUES FOR RADIATED AND COMPARISON
FREQUENCIES AND WAVE LENGTHS
(f = 14.16 kcps)

Frequency Wave Length
Stations Harmonic (kcps) (™m)

Radiated Frequencies

Master of 85,000 3521
Red Slave 8f LIB), 333 2640
Green Slave Of 127 , 500 2347
Purple Slave of 70,833 4225

Comparison Frequencies

Red 24f 340 , 000 800

Green 18f 255,000 1174

Purple 30f 425,000 704
TABLE IV-5

LANE WIDTH ON BASE LINES ASSUMING
VELOCITY OF 299250 KM/S

Meters Yards

Red 440 .074 481.28

Green 586.765 641.70

Purple 352 .059 385 .02
533

Arthur DAittle Inc.

Since the transmissions are pure unmodulated cw, a very narrow
receiver bandwidth may be used- -typically + 30 cps at half-amplitude. Further -
more, a large number of stations occupy only a small part of the frequency
spectrum.

The maximum working range is generally set by the operating authority
at 240 nautical miles from the master. The principal limiting factor is a tendency
for the amplitude of the sky wave reflected from the ionosphere by night to reach
equality with the ground wave at around 240 nautical miles. However, by day
useful range may be extended by a factor of two or more, though accuracy at
these larger ranges will be low due to the large lane width and small intersection
angles.

3. ACCURACY

Random errors in the standard Decca system include errors in read-
ing the phase meter, random changes in circuit parameters, and changes in local
velocity of propagation. The standard deviation in phase readings from all such
causes amounts to less than 0.01 mean lane; a mean lane being defined as one
whose base-line width is 500 meters.

Systematic errors in Decca involve incorrect knowledge of the mean
velocity of propagation and, more important, the tendency for the sky wave
reflected from the ionosphere to reach equality with the ground wave at longer
distances. When this situation obtains, ionospheric fluctuations will produce
variations in phase-meter readings and lead to position errors. These errors
increase with range and are more serious at night than at day, and in winter
than in summer. The 95% radial errors to be expected under various conditions
are reproduced in Figure IV-7. The tabulation in the figure lists the errors
unlikely to be exceeded in one out of 20 readings.

The sky wave also has an important effect on lane identification errors.
The probability of correct lane identification is a function of range, season, and
time of day. Some typical results: During summer daylight over ground of
conductivity 10-13 e.m.u., lane identification is about 95% successful at all
working ranges; by night, the 95% probability contour extends out only some 150
miles, while the 67% probability level is at about 250 miles.

54

Arthur D.Uittle Inc.

fo) 50 100 150 200 250
oe << |

(nautical miles)

DECCA PERIOD

WINTER NIGHT

SUMMER NIGHT
DUSK
HALF LIGHT

FULL DAYLIGHT

mM hh XX XK

FIGURE IV-7 ERROR CONTOURS FOR DECCA NAVIGATOR

55
Arthur A Vittle Inc.

4. SUMMARY

a. Type of System

(1) Hyperbolic phase comparison multi-user system.

(2) Number of shore stations required; master and three
slave stations (red, green, and purple) are generally
arranged in a star pattern.

(3) Length of base line; 60-100 nautical miles (nominal).
(4) Frequency range: 70-130 kcps.

(5) Transmitted power: 1200 watts for Decca Navigator
600 watts for mobile survey equipment.

(6) Transmitter power requirements: 2 kw for mobile survey
equipment.

(7) Mobile antenna; 70 or 100 ft in tubular sections.
(8) Decca Navigator range:; 200-500 nautical miles.

(9) Receiver power requirements: 80-140 and 165-260 v,
47 -63 cps, 22-30 v de 250 watts

(10) Receiver readout: 3 dial (navigation); 2 dial (survey)
Decometer Unit - Marine Automatic Track Plotter
provides continuous position plot in rectilinear coordinates.

5. RANGE AND ACCURACY

Daytime Nighttime
Summer Winter

(1) Usable service distance

(nautical miles) 500 240 200
(2) Approx. 95% rms radial

error at maximum range 2 4 3
(3) Approx. 95% rms radial

error at 150 nautical miles 1/4 1 1-1/2

(4) Approx. 95% rms radial hy
error at 40 nautical miles 1/20

56

Arthur D.Little Inc.

REFERENCES

1. Radio Aids to Maritime Navigation and Hydrography, Supplementary Paper
No. 3 to S.P. No. 39. International Hydrographic Bureau, Monaco, 1961.

2. Radio Aids to Maritime Navigation and Hydrography, Supplementary Paper
No. 4 to S.P. No. 32, 1962, International Hydrographic Bureau, Monaco, 1962.

57

Arthur D.Little Ine.

E. LORAN-A

1. GENERAL

Standard Loran (Loran-A) was developed at M.I.T. Radiation Labora -
tories during World War II. Loran stations were established in the Atlantic
and Pacific theaters and operated under security conditions as a navigational
aid. Commercial equipment has been made available since the war and installed
world-wide to increase the system's usefulness and coverage. (See Figure IV-
8.) It now enables properly equipped ships and aircraft to plot their position
with good accuracy out to 800 miles or more.

Loran-A uses a pulsed hyperbolic method of fixing a ship's position
by the reception of pulsed radio signals in a timed sequence from transmitting
stations of known position. The time difference of arrival of two or more pairs
of signals is measured,and these measurements are transformed into radial
distances from the transmitter. The Loran-A system does not require a
knowledge of the ship's heading or dead-reckoning position and is independent
of other mechanical devices, including the compass and chronometer.

2. DESCRIPTION

Loran-A operates in the frequency band from 1800 to 2000 kc. With
present techniques the ground waves may be used to distances of 600-900 nauti-
cal miles in the daytime, and the sky waves are used out to 1400 nautical miles
at night.

In this system, radio signals consist of short pulses which are trans-
mitted in a precisely timed sequence from a pair of shore stations. The shore
stations are carefully located on a base line of known length. The pulses are
received on special receivers within the operating area of the transmitters,
and the time difference of arrival of the pulses is displayed and measured on
a cathode-ray-tube indicator. This measurement is used to determine from
Loran-A tables or charts a line of position on the earth's surface. Two or
more lines of position from two or more Loran station pairs are used to deter-
mine a position fix.

a. Ground Station Operation
A Loran position fix requires that the difference in time for pulses

to arrive from a pair of transmitting stations be measured to a precision of
+1 microsecond. One station of a Loran pair is a master station, and the

58

Arthur DLittle, Inc.

WAVE (NIGHT ONLY)

|| LIMITS OF Sky,

WS

LIMITS OF GROUND WAVE (DAY AND NIGHT)

NATO STANDBY COVERAGE

YY

Y

YY
Wa

Y
Y

LORAN A COVERAGE - JULY 1964

FIGURE IV-8

59

Lee
mai

ent
“hah

other is designated the slave station. In the system shown in Figure IV-9, the
master station is a double-pulsed station common to two shore stations.

The accuracy of Loran-A is largely dependent upon the transmitting
stations' keeping their signals correctly timed and synchronized. For this pur-
pose, the master station utilizes a stabilized 100-kc crystal oscillator and preci-
sion timer to set the pulse recurrence rate. A precisely spaced series of pulses
is thus transmitted. On reception of these pulses at the slave station, a corre-
sponding series of pulses is transmitted.

The crystal oscillator also provides precise 1-microsecond timing
pulses. Synchronization of the slave to the master is maintained by an operator
at the slave station who monitors these radiated pulses and continuously makes
the proper timing adjustments.

Loran signal pulses are approximately 40 microseconds in length.
The number of pulses per second’ from each station is the recurrence rate.
There are three basic rates, each of which is divided into seven specific rates
differing by 100 microseconds. This system provides separation of signals
from transmitters in the same area.

Figure IV-10 indicates the way in which the master and slave station
pulses are spaced in time. The coding delay inserted at the slave station is a
fixed value and insures that the time between reception of the master and slave
pulses is always greater than one-half the recurrence interval at all receiver
locations. An operator thus can distinguish between the master and slave station
pulses and make a nonambiguous identification, The synchronization of slave
to master station is presently + | microsecond and is being reduced to + 0.25
microsecond at U. S. operated stations.

When trouble occurs and the two stations are not properly synchronized,
the operator "blinks" the signal by shifting the signal to the right and left at in-
tervals of about 1 second. Blinking is a fail-safe feature of Loran and indicates
to the navigator at a receiving station that the transmitter is malfunctioning and
that readings should not be taken at that time.

b. Mobile Station Operation
Any mobile station having a Loran type A receiver can use the basic
Loran navigation system. In this receiver, the pulses from the slave and master
stations are displayed on a cathode-ray tube indicator. The display is divided

into two equal horizontal segments one above the other, so that received pulses
produce a vertical deflection on the screen. The operator matches the master

61

Arthur DHittle Inc.

2L5-5732
™ BASE LINE EXTENSION
~

me \ i / y, tes BASE LINE EXTENSION
Coa onl ee Je af 7
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/ fe.e-isoo / sl \ BLO Jee
2L5-3500 ff u | \
2L6-2000 crnieeee ernie er
2L5-3000 2L6- 2500

FIGURE IV-9 LORAN A GRID SYSTEM

62

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SGNOODSSONDIN - 31IVOS JAWIL

63

Arthur A Vittle Inc,

and slave pulses and reads the time delay ona dial and digital counter. Two
such time-difference readings from two Loran pairs furnish the information re-
quired for a Loran position fix. Loran tables and charts must be used to estab-
lish a geographical position.

3. ACCURACY,

The accuracy of a Loran-A fix is determined by the accuracy of the
individual lines of position and by their angles of intersection. The accuracy of
the individual lines of position is dependent upon the following:

a. Synchronization of transmitters

b. Operator skill in matching and identifying signals

c. Uncertainty of sky-wave correction (when sky waves are used)
d. Position of ship relative to transmitting stations

e. Accuracy of tables and charts

f. Timing and positional uncertainty.

With a reasonable signal-to-noise ratio, an operator can be expected
to equalize the amplitude and match the leading edge of the received signals with-
in 1 microsecond of the correct value.

Since the ionosphere does not maintain a constant height or angle with
respect to the earth, these corrections vary slightly from tabulated values.
Sky-wave reception is most reliable at distances greater than 800 miles from
the transmitter, where readings, with proper correction, are generally correct
to about +5 microseconds. At lesser distances, the uncertainty increases.

The relative accuracy of Loran over the coverage area is apparent
from the spacing of the lines on the Loran charts. The most favorable position
is on the base line between the transmitters. The most unfavorable positions
are adjacent to the base line extensions, where the Loran line separations can
be several miles per microsecond.

The accuracy of Loran tables and charts is of the order of a fraction
of a microsecond. Inaccuracies do occur in those areas where insufficient survey
data was available for positioning the transmitting stations. Where correction
data is available, this is included in charts provided with the Loran-A tables.
The timing uncertainty, in microseconds, results in a corresponding uncertainty

64

Arthur D. Little, Inc.

in the location of the hyperbola, which is regarded not as a sharp line but as a
band or zone.

The actual uncertainty in the location of the navigator's line of position
is the product of the timing and positional uncertainties. If three-eights of a
mile is considered a typical positional uncertainty and 2.5 microseconds a
typical timing uncertainty for a hyperbola obtained by ground-wave reception
from two Loran stations, then the actual position uncertainty for daytime opera -
tion is about 1 mile. If sky wave reception is used and three-fourths of a mile
and 8 microseconds are the corresponding quantities, then the actual nighttime
uncertainty would be about 6 miles. These figures are estimates only and not
averages of a series. This margin of uncertainty is larger than found in practice
and can be reduced by a factor of about 2 under favorable conditions. A Loran
fix is normally expected to be compared to a good celestial observation.

Over large parts of the service areas of Loran, hyperbolic line cross-
ing angles of 30° or better are obtained which allows a relatively good fix to be
obtained. At the extreme limits of sky-wave coverage (approximately 1400
miles) crossing angles may be quite small if all stations are situated along one
coast or in some similar arrangement. In this situation, positions are obtained
with relatively good accuracy ina direction perpendicular to the lines of the
position, but with relatively poor accuracy along the lines of position. Where
crossing angles are small, the practice of averaging a number of readings should
result in improved readings.

The uncertainty in plotting a position can be reduced by using three or
more Loran lines of position or by combining Loran lines with those from another

source. Careful consideration should be given to the relative accuracy of various
Loran lines.

4. SUMMARY

a. Type of System

(1) Pulsed time-difference hyperbolic plot
(2) Length of base line:
(a) average = 200 - 400 miles

(b) long = 200-700 miles

65

Arthur A Little Ine.

(3) Pulse modulation: 45 microseconds length,
21 microseconds rise time

(4) Pulse repetition rate:

(a) H rate = 33 - 34.11 pps in seven steps
Recurrence interval = 30, 000 - 29, 300 microseconds
in seven intervals

(b) L rate = 25 - 25.44 pps in seven steps
Recurrence interval = 40, 000 - 39, 000 microseconds
in seven intervals

(c) S rate = 20- 20.28 pps in seven steps
Recurrence interval = 50, 000 - 49, 300 microseconds
in seven intervals

(5) Frequency channels:

Channel 1 = 1950 kc
Channel 2 = 1850 kc
Channel 3 = 1900 kc
Channel 4 = 1750 ke

(6) Bandwidth: 40 kc
(7) Radiated power: 160 kw peak, for older installations
1000 kw peak where high-power amplifiers

have been installed

(8) Number of Loran-A stations: 69 located throughout world

b. Accuracy and Range

Daytime Ground Nighttime
Wave Sky Wave
(1) Usable service range 700-900 nm approx. 1400 nm
(2) Approximate accuracy LOP 0.5-1.0nm 3-6nm

(3) Time required to obtain LOP: 2-3 minutes

- (4) Minimum usable S/N ratio: not less than 2/1
with a manual match. Automatic tracking receiver
will track to S/N ratio of about 1/2 or 1/3

(5) Number of users: Loran-A designed for multi-user application.
66
Arthur A HLittle, Inc.

REFERENCES

1. Pierce, McKenzie, and Woodward, Loran, Rad Lab Series, Vol. IV, McGraw-
Hill Book Co., 1948.

2. Loran Supplementary Paper No. 5 to S.P. No. 39, Chapt. II, International
Hydrographic Bureau, Monaco, November 1962.

3. Joe B. Stone, “Standard Loran - Technical and Operational Advances," U. S.

Coast Guard, Sixth International Tech. Conf. on Lighthouses and Other Aids
to Navigation, 1960, Paper 9/6/4.

4. P. C. Sandretto, Electronic Avigation Engineering, IT&T, 67 Broad St.,
New York, 1958, pp. 220-277.

67

Arthur A Little Inc.

F, LORAN-C

1, GENERAL

Loran-C is a pulsed, low-frequency, long-range navigation system.
It operates in a frequency band of 90-110 kc which was allocated on a world-
wide basis for long-range radio navigation purposes by the ITU Conference of
1947. The first Loran-C installations were made and successfully tested in
1957. Coverage is now available for the greater part of the ocean areas of the
northern hemisphere. (See Figure IV-11.)

Loran-C, like Loran-A, is a pulsed, hyperbolic navigational system
which uses the time difference of arrival of rf signals from three shore-based
stations of known location to establish a navigational fix. A phase-difference
measurement system which provides a much higher degree of accuracy than is
available by the pulse-difference method alone is also used. In addition, the
Loran-C system uses a lower frequency than basic Loran, and this makes pos-
sible a large increase in range.

Under good conditions, position fixes to within 1500 feet and ranges
of 1000-1400nm can be expected 95% of the time when ground wave transmission
is used. Ranges of 1800-2300 miles and fix accuracies of 2 nautical miles or
better are generally available with sky wave reception.

2. DESCRIPTION

Loran-C stations are generally used in groups of three, a master and
two slave stations. When 360° coverage is desired, a fourth station is added,
and the system is called a star of "Y'' configuration. Pulses are transmitted in
a precisely timed sequence from the master and the slave stations, which are
located on a base line of known length. The optimum base line is a compromise
between geometry and signal strength considerations. Because of the low fre-
quency (90-110 kc) used and the long range possible, base lines as long as 800
miles are used. (See Figure IV-12.)

Both the master and slave stations transmit on the same frequency on
a shared time basis; i.e., the master station transmits its pulse group and is

followed in succession by each of the slaves. A coding delay at each slave sta-
tion eliminates ambiguity.

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Arthur A. Hittle Inc.

SKY WAVE FIX 2N.M. PER MICROSECOND
WITH CROSSING ANGLE GREATER THAN |5°

'Y GROUND WAVE FIX 2N.M. PER MICROSECOND
WL WITH CROSSING ANGLE GREATER THAN I5°

GROUND WAVE FIX ISOOFT ACCURACY
MMMM contour 95% oF THE TIME
20'

STANDARD DEVIATION 1 MICROSECOND

FIGURE IV-11 LORAN C COVERAGE - JULY 1964

69

Cae ages
Can :

=i pipe

=
i

FIGURE IV-12 LORAN C EAST COAST CHAIN

71

Arthur DAittle Ire.

The pulses are received at stations within the operating area of the
transmitters. Time-difference measurements are made by utilizing both the
pulse envelope and the phase of the carrier cycles incorporated within the en-
velope. After the envelopes are matched to within + 5 microseconds, a cycle
match is made using the 100-kc sine waves that makeup the pulse. In this man-
ner, the pulse envelope match produces a coarse time-difference reading as in
Loran-A, and the cycle match produces a fine time-difference reading. Thus,
the time-difference readings of two or more master-slave combinations estab-
lish a Loran-C fix. Special tables and charts are required to help locate the
geographic position of the mobile receiver.

a. Ground Station Operation

Loran-C transmitters utilize a peak pulse power of 250 kw - 1 mw and
transmit a.series of pulses in groups of eight with 1000 microsecond separation
between pulses. Each pulse is about 200 microseconds long. The master sta-
tion transmits a ninth pulse for identification purposes. The pulse groups are
repeated at relatively long periods of time, such as 50,000 microseconds. When
pulses are transmitted in groups the receiver integrates the pulses, thus adding
together the signal from each pulse of the group and greatly increasing the signal-
to-noise ratio. By increasing the S/N ratio at the receiver in this manner, one
may use lower power at the transmitter and may increase the area of coverage.

To permit identification of master and slave station chains certain
pulses within each pulse group are in phase opposition to others according to a
predetermined code. Also, the transmission from different stations is very
closely synchronized and a coding delay is used at each slave station as in
Loran-A. Station coding is outlined in Loran-C tables and charts.

‘Each station in a chain of three or four stations transmits one pulse
group per recurrence interval. Pulse groups are transmitted at six basic repe-
tition rates. Seven additional specific rates can be generated for each basic
rate, to provide a total of 48 different usable repetition rates. The master sta-
tion transmits first, and is.followed by the slave station. Signals are simul-
taneously displayed at the receiver as the envelope and phase-time difference
readings for the two signal pairs, i.e., master and one slave, master and the
other slave.

Each transmitter uses 100-kcps phase-coded signals from its timer
synchronizer and in turn generates a 200-microsecond pulse of 100-kc sine

waves. These pulses are amplitude-modulated, giving an envelope of the proper
rise time and shape.

72

Arthur D.Uittle, Inc.

In the event of improper transmitter operation, a standardized blink-
ing procedure is used to notify receivers in the area. The blink consists of
shifting the entire pulse group by a specified amount once each second. This
operation is visible to the receiver operator and activates automatic alarms.

Master and slave station transmitters are similar, and both feed 625-
foot antennas. Each station has a certain amount of redundancy in equipment
to minimize downtime caused by equipment failure.

b. Receiving Equipment

Specialized receiving equipment is required to take full advantage of
the Loran-C positional accuracy. A coarse position is obtained by the measure-
ment of the time difference of the envelope signals from two master-slave pairs.
This measurement is made to within +5 microseconds. A second measurement
of the phase of the signals is made to within a few hundredths of a microsecond,
thus making possible a very accurate line of position.

Sky-wave contamination is avoided by making the time-difference and
phase-difference measurements before the sky wave arrives. Thus, these
measurements are made automatically at the Loran-C receiver within the first
30 microseconds after receipt of the ground wave from the master station and
each slave station.

The coarse position measurement is made automatically within the
receiver. Only the leading edge of the envelope is used. By electronically
processing the master and slave signals the receiver establishes a precise
base line crossing at the 30 microsecond point of the leading edge for each sig-
nal and makes a time-difference measurement between them. A readout estab-
lishing a coarse line of position is automatically made on vernier dials to within
5 microseconds.

The fine measurement is made by comparing the phase of the individual
sine waves contained in the pulse of the master and slave signals with the phase
of a precisely controlled reference oscillator in the receiver. Electronically
the receiver locks the frequency of the local oscillator to the frequency and
phase of the incoming signal. A sampling gate allows the receiver to be turned
on and to "look at" the signal at the 30-microsecond sampling point, thus avoid-
ing sky-wave interference. The measurement is automatically presented ona
vernier dial which reads from 0 to 10 microseconds in increments of 0.01 micro-
second. ‘The total time difference is the sum of the envelope and phase readings.
For example, if the coarse (envelope) measurement were 19374.2 microseconds
and the fine (phase) were 1.36 microseconds, the actual measurement would be

73

Arthur A Aittle, Inc.

between 19369.2 and 19379.2 microseconds. The exact time difference measure-
ment is therefore 19371.36 microseconds.

A method of statistical signal integration which helps extract the multi-
pulse signal train from background noise is used. A series of sampling rates
with a spacing corresponding to the 1000-microsecond spacing between transmit-
ter pulses is used. In this manner only the coherent transmitter pulse train will
integrate to a value other than zero. In many areas a signal-to-noise ratio of
1/10 can provide a useful output from the receiver.

A system of automatic signal research which makes use of the phase
coding of the transmitter pulses is used in the Loran-C receiver. With this
method of synchronous phase detection, the receiver yields an integrated output
signal only when the received signal is of the same phase coding as contained
in the receiver phase coder. The receiver searches and tracks the incoming
signals automatically by maintaining the sampling gates in coincidence with the
sampling points of the signals. The phase coding is determined when the opera-
tor selects the Loran-C stations to be used.

Sky-wave discrimination or selection is provided in the receiver by
an additional sampling mechanism 30 microseconds ahead of the sampling gates.
If the search results in the setting of the receiver at a sky-wave signal, this
additional sampling mechanism causes a voltage to be generated through the
integrator; to use the ground-wave signal the operator advances the position of
the sampling mechanism.

The receiver may comprise a visual oscillographic display which
facilitates signal search and allows checking to see if the signals are correctly
followed by the receiver during its automatic operation. There are also pro-
visions for manual operation. The receiver has protection and alarm circuitry
which help the operator monitor proper operation.

3. ACCURACY

a. Ground Wave

The principal factors affecting radio-wave propagation, which in turn
affects the range and accuracy of Loran-C, in the ground-wave areas are: the
amplitude ratio of ground wave to sky wave and sky-wave delay, the S/N ratio,
and the interference from other frequencies within the 90-110 kcps band. Inter-
ference from other frequencies is minimized by the synchronous detection and
filtering techniques used in Loran-C. These tend to reduce the susceptibility
to nonsynchronous interference caused by refractivity of the earth's atmosphere
and by the conductivity of the earth.

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Arthur DA Hittle, Inc.

(1) Sky-Wave Interference

The first-hop sky wave limits the range of the useful ground wave.
At ranges of about 1300 miles the signal strength of the sky wave exceeds that
of the ground wave and varies with the time of day and season of the year. For
example, at this range during the day the sky-wave-to-ground-wave- signal ratio
is about 10/1 in winter and about 3/1 in summer. Sky waves do not affect
ground-wave reception when they are less than about 10 times ground-wave
amplitude. This is true during all seasons of the year. However, at night the
ground wave is complicated by the very large sky-wave component at distances
greater than 1000 miles during all seasons of the year.

The Loran-C receiver's ability to utilize the ground wave is largely
dependent upon this component's arriving at the receiver slightly ahead of the
sky wave. The nighttime sky-wave delay over sea is about 54 microseconds
beyond 1300 nautical miles. This provides time for the ground-wave signal to
be built up to a suitable S/N ratio before sampling. The sampling point is 30
microseconds after arrival.

(2) Atmospheric Noise Interference

The accuracy of the cycle-time-difference measurement is practically
independent of atmospheric noise for a S/N ratio greater than 1 (0 db). At lower
S/N ratios, the mean indicated cycle-time difference is little affected by noise,
even though the short-term deviations from the mean increase in magnitude.

At low values of S/N ratio the cycle accuracy can be improved by
averaging the indicated time difference for a few minutes. Reliable measure-
ments of envelope-time difference require a S/N ratio of about 3 (10 db). How-
ever, for special applications such as surveying and mapping, satisfactory re-
sults are obtained with S/N ratios of -20 db.

(3) Factors Affecting Propagation

The pulse transmission time from transmitter to receiver depends
upon the velocity of propagation. The factors affecting this are the conductivity
of the earth's surface and the index of refraction of the atmosphere. An as-
sumed constant propagation velocity is normally used. Some measurements of
propagation time over the Bermuda base lines have been made. Variations no
greater than a few hundredths of microseconds are expected over all seasons of
the year.

Arthur A. Little Ire.

The conductivity of the earth has the greatest effect on the phase of
the low-frequency ground wave. With a service area completely over water,
conductivities can be predicted with good accuracy. Service areas over land,
however, cause large variations in conductivity, which cause large distortions
in the observed lines of position.

The greatest use of Loran-C equipment is for paths over water, where
accurate prediction of conductivity can be made. Here the greatest cause of
signal-phase variation is changes in the refractivity of the atmosphere.

b. Sky Wave

Many of the factors affecting ground waves also affect sky-wave prop-
agation. A minimum S/N ratio is required for either mode of operation. There
is also the possibility of contaminating by greater and lesser modes.

(1) Mode Interference

At times overlap by sky-hop pulses causes distortion of the pulse
envelope at the receiver and malfunction of the time-difference-measuring cir-
cuits. Even small distortions will cause errors in phase measurement. The
maximum phase error occurs when the (N-1) sky hop arrives at the receiver
90° out of phase with the Nth hop. The maximum phase error in this case
would be 0.32 microsecond if the ratio of desired-to undesired signal were
20 db. For this reason, the amplitude of the Nth hop is required to be at least
10 db greater than the (N-1) hop before the Nth hop can be used.

Table IV-6 gives the minimum distance at which the amplitude of the
Nth hop sky wave is 10 db greater than the next lower mode.

TABLE IV-6

SKY-WAVE RANGE DATA

Nautical Miles

Winter Summer
No. of Hops Day Night Day Night
1 877 610 1300 610
2 2180 1900 3200 1900
3 3050 3200 4300 3200
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Arthur A Little Inc.

(2) Sky-Wave Correction

The ability of sky waves to increase the area of coverage is depend-
ent upon the stability and the predictability of the delay. In addition, the re-
ceiver must be able to identify the sky hop the receiver is using for each of the
transmitters.

Many factors must be considered and special corrections applied to
obtain good accuracy in Loran-C fixes using sine waves. Matching two one-
hop sky waves is generally preferred to matching a sky wave with a ground
wave. Sky-wave corrections can be computed or are available in tables and
graphs.

Ge Range

The maximum usable ground-wave range over water for 0 db S/N
ratio for 100 kw of radiated power is about 1400 nautical miles in the daytime
and about 900-1000 nautical miles at night. Increasing the radiated power to
1 mw increases the range an additional 260 miles. Line-of-position accuracy
at these extreme distances should be to within 0.1 microsecond plus 0.1 micro-
second for seasonal variations. Operationally the Loran-C system has recently
demonstrated an ability to supply positional information to an accuracy of
0.1-0.5 nautical mile with ground-wave transmission in the North Pacific.

The nighttime sky-wave range under the same conditions should be
about 1800 nautical miles for the first hop and 2300 nautical miles for the second
hop. Increasing the power level to | mw radiated increases both figures ap-
proximately 300-400 nautical miles.

Position fixes with sky waves can be obtained with a probable error of

1-1.5 microseconds. About a 10% decrease in range can be expected for paths
over land for both ground-wave and sky-wave operation.

4. SUMMARY

a. Type of System

(1) Pulsed time-difference hyperbolic plot plus phase-
difference measurement for high accuracy.

(2) Length of base line: 500-800 miles

TY

Arthur A ittle Inc.

(3) Pulse modulation: 200 microseconds length,
70 microseconds rise time

(4) Pulse repetition rate:

(a) 6 basic rates: 10 (SS), 12-1/2 (SL), 16-2/3 (SH),
20 (S), 25 (L), and 33-1/3 (H) groups per second.

(b) 7 additional rates are available for each basic rate
(5) Frequency: 90-110 kc.

(6) Bandwidth: 99% of total pulse power contained in band of
90-110 kcps

(7) Radiated power: 250- 1000 kw

b. Accuracy and Range

(1) Usable service range at 100 kw at 50% sampling point
and 0 db S/N ratio:

Nautical Miles

Winter Summer
No. Hops Day Night = ©‘Day —Night
Ground Wave 1300 800 1400 800
1 1800 1700 1700 1700
2 2100 2300 eo 2300

(2) Usable service range at 1000 kw at 50% sampling
point and 0 db S/N ratio: range increases approx.
15-20% over 100-kw range

(3) Approximate operational accuracy of Ground Wave
fix in nautical miles Min Max
0.1 0.5

(4) Number of users: Loran C designed for single or multi-
user applications.

78

Min
0.5

ES kyAWAMER

Max
2

Arthur D. Little, Inc.

c. Receiver Characteristics
(1) AN/APN - 145, transistorized, analog operation.
(a) Size: 2.5 cubic feet.
(b) Wt: 100 lb.
(ec) Power: 500 watts.
(d) Controls: 26 manually operated.
(e) Mtbf: approximately 500 hours.

(2) AN/ARN-76 Microcircuit, digital operation, digital readout.

(a) Size: 0.5 cubic foot, uses remote control indicator.
(b) Wt: 20 1b.

(c) Power: 155 watts.

(d) Controls: 6 manually operated.

(e) Mtbf: 1500 hours or more.

REFERENCES

1. Engineering Evaluation of Loran-C Navigation System, Final Report, Jansky

and Bailey, Sept. 1959, Prepared for U. S. Coast Guard.

2. The Loran-C System of Navigation - Jansky and Bailey, Feb. 1962, Prepared
for U. S. Coast Guard.

3. Loran-C, Supplementary Paper No. 2 to S.P. No. 39, Chapter II, Interna-
tional Hydrographic Bureau, Monaco.

4. Edward Durbin, "Current Development in the Loran-C System." Journal of

Inst. of Navigation, Vol. 9, No. 2, Summer 1962.

5. Robert L. Frank and Alan H. Phillips, "Digital Loran-C Receiver Uses
Microcircuits, Electronics, Jan. 31, 1964.

6. Proceedings of Merchant Marine Council, USCG, Vol. 19, No. 5, May 1962.

19

Arthur A. Little Inc.

G. OMEGA VLF NAVIGATION SYSTEM

1. GENERAL

The Omega VLF navigation system, undergoing evaluation tests, is
an experimental system designed to provide long-range position fixes to ships
and aircraft ona 24-hour basis. Omega presently utilizes four experimental
stations, located at Summit, Canal Zone; Haiku, Hawaii; Forestport, New York;
and Creggion, Wales. ‘The final system, designed to cover the entire globe,
will require 8-10 stations. Potential users are surface vessels and all types of
aircraft, including those with speeds beyond Mach 1.

The assigned frequencies are in the 10-14 kc band now assigned for
navigation. Omega is operating at a frequency of 10.2 kc. Hyperbolic lines of
position are established by automatic phase-difference measurements of the
carrier frequencies at the receiver. The phase-difference values are indicated
on dials and strip charts. From these values the navigator determines his
line of position from special charts.

Long base lines are practical at the low frequencies used. If base
lines of the order of 3000-5000 miles are used, lines of position will approach
parallel lines. By using three stations with base lines at near right angles, all
lines of position in the coverage area cross at near 90°, the optimum crossing
angle, giving the smallest fix error.

Coarse position measurement is not available with the developmental
Omega equipment but will be added by the spring of 1965 to two of the trans-
mitters now inuse. Improved receivers, now under development, will also be
available at that time. Position determinations to within | mile during daylight
hours, 2 miles during evening hours, and 6 miles under worst-case conditions
are possible with the present prototype equipment.

2. DESCRIPTION

An Omega experimental navigational chain is composed of three sta-
tions, a master and two synchronized slaves. At present these stations trans-
mit sequentially on a frequency of 10.2 kcps. A pulse length of 1 second (ap-
proximately) is being used. The transmitted pattern is repeated every 4
seconds. The stations are identified at the receiver by the slight difference in
pulse length characteristic at each station. After transmission the master
station stands by while the other synchronized stations transmit their pulses.

80

Arthur D. Little, Inc.

At present, 100-kw transmitters are being used. The radiated power
is dependent upon the antenna. Low antenna efficiency and lack of antenna gain
at these frequencies permits use of only 2-3 kw of radiated power. Useful
coverage of the area can be obtained at radiated power levels of about 2-10 kw.
Automatic control at the antenna maintains the constant radiated wave phase
characteristics required.

The system is designed as a hyperbolic network but may be used in
the range-range mode. When operated in this mode a highly precise frequency
standard must be carried aboard the navigating vessel but the system can estab-
lish a fix by receiving signals from only two shore stations.

Three types of receiving antenna are being used. A 35-foot whip is
the most efficient unit for surface vessels. A 10- or 12-foot probe may also be
used and can be mounted either vertically or horizontally as space permits.
The same antenna coupler is used interchangeably. A loop antenna is used
aboard submarines and requires a loop coupler.

The present Omega receivers indicate two phase-difference readings.
Each reading is shown by two dial indications, one being the cycle (or lane)
count from 0 to 99 cycles and the other the percent phase difference per cycle
(100% = 360°). A strip-chart recorder is also provided to trace the two phase
differences (neglecting the cycle count). Remote indication can also be provided.

The time differences as measured by the receiver are manually
plotted on specially prepared charts. To plot a position to an accuracy of
2-6 nautical miles, the navigator must be able to plot to an accuracy of between
0.03 and 0.1° latitude. Allowances for diurnal and seasonal phase shift, taken
from tables or charts, must be made by the operator before an accurate plot
can be made.

Computers to utilize the required information and automatically track
and plot a vessel's position in geographic coordinates are not yet available, but
are in the early development stage. Such computers appear to be particularly
necessary for use aboard high-speed aircraft, which cross one lane (7.9
nautical miles) ina very short time.

Equipment to resolve the problem of ambiguities of lane identification
is not available with the early developmental Omega equipment. Other available
navigation aids and dead-reckoning procedures must be used. The strip-chart
recorder at the receiver helps to correct lane counts that have been lost and
permits rapid recognition of anomalous propagation which might go unnoticed
on a counter-type display.

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In an effort to reduce the problem of position ambiguities, new trans-
mitting equipment will be installed by early 1965. This equipment will be capa-
ble of generating three frequencies, 10.2, 12.75, and 13.6 kc, sequentially, as
indicated in Table IV-7. New receivers using microelectronic circuitry will
simultaneously track two of these frequencies and continuously indicate fine lines
of position on 10.2 kc and coarse lines of position on the (13.6-10.2) difference
frequency. The fine lane widths will be 8 nautical miles as before, but a new
coarse lane width of 24 nautical miles will now be available to help reduce posi-
tion ambiguity problems. The new receiver will weigh approximately 75 pounds
and require about 1.5 cubic feet of space. Later versions of the receiver will
also track the third frequency being generated and yield a third coarse lane width
of 96 nautical miles.

TABLE IV-7

OMEGA SIGNAL FORMAT

Transmission
Interval j LO Lol
Station 1 : 13.6} 12.75
2 10.2)/ 13.6
3
4
5
6
7
8
0.2 sec
>

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Arthur A Little Inc.

3. ACCURACY

Extensive sea and land tests indicate that the Omega system's ac-
curacy is better during the day than during the night or during transition periods.
A statistical analysis of long-term tests at three of the fixed stations indicates
a navigational accuracy of 0.5 and 0.9 nautical mile (circular probable error)
in the daylight and the nighttime hours, respectively. Relative accuracy of
vessels for station keeping should be of the order of 0.25 mile. At present,
errors during transition periods (day/night and night/day) are less than 2 miles.
Statistical studies at NEL indicate that inherently, transition period accuracies
are capable of being intermediate between day and night values. To realize
this capability, more numerous corrections computed by more elaborate methods
may be required.

A recent analysis(4) indicates that the Omega system should be capa-
ble of an operational fix accuracy of less than 6 nautical miles. More recent
experimental data and improvements in equipment indicate this figure is con-
servative.

With present base lines NEL reports the operating range consistently
reaches 6000 nautical miles. Some estimates indicate the present system can-
not be made operational for world-wide use until the late 1960's or early 1970's.
It must first be qualified by test and accepted for use by Federal authorities.
Also the establishment of suitable transmitter sites on foreign soil requires

considerable time and preparation. A recent report 5) describes the siting
problem in some detail.

4. SUMMARY

a. Type of System

(1) Pulsed phase-difference hyperbolic plot

(2) Base line length: approximately 5000 miles

(3) Pulse duration: 1 sec (adjustable cw synchronized)
(4) Pulse repetition rate: 5 sec (adjustable up to 10 sec)
(5) Transmitter power: 1000 kw

(6) Radiated power: 2-3 kw

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(7) Frequencies: 10.2 kc, 12.75 kc, 13.6 kc

(8) Receiver: 2 channel phase-difference measuring and
indicating unit

(9) Receiver: phase-difference output indicated by
(a) Front panel digital readout
(b) Integral recorders
(c) Provisions also for remote indication

(10) Receiver size: 8" high x 15" wide x 21" long (new
versions available in spring 1965)

(11) Receiver power requirement: 115 v, 60 cps

(12) Receiver weight: 75 lb

b. Range and Accuracy |

(1) Usable service range: 6000 miles (approximately)
(2) Approximate drms fix accuracy: 0.5 mile daytime
1.0 mile nighttime

2 miles at transition periods

(3) Relative accuracy for station keeping or
rendezvous: 0.25 nautical mile

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Tis

REFERENCES

Technical Evaluation of Omega Navigation System, NEL Report 1153,

18 December 1962.

John L. Loeb, "Omega VLF Navigation System,’ BuShips Journal, Vol. 9,
No. 1, pp. 32-33, January 1960.

The Omega Long-Range Navigation System, NEL Report 958, 1 March 1960.

James O'Day et al., Study and Analysis of Selected Long-Distance Naviga -

tion Techniques, Vol. II, Inst. of Sci. and Tech., University of Michigan,
March 1963.

J. A. Pierce et al., "Omega - A World-Wide Navigational System, " BuShips,
June 1964.

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Arthur D.Little Inc.

H. NAVIGATION SYSTEMS USING SATELLITES

1. GENERAL

A number of high-precision navigation networks using earth satellites
are under study by the Navy, NASA, and FAA. To date, only the Navy's Transit
program, being carried out by the Applied Physics Laboratory of Johns Hopkins
University, under the cognizance of BuWeps, has been implemented. The more
promising systems which have so far been investigated promise true global
coverage, all-weather operation, relative immunity to interference, unlimited
traffic -handling ability, the availability of frequent fixes, and very high positional
accuracy. Mid-latitude positional accuracies exceeding 0.50 nautical miles are
predicted on the basis of an early analysis of Transit 4A experimental data.

There is some commonality to all navigation systems which would
utilize satellites. The satellite's position relative to fixed points on the earth's
surface is communicated to the navigating vessel. The navigation system then
determines the vessel's position with respect to the satellite at a given time.
This information can then be combined with the known position of the satellite,
and the vessel's longitude and latitude may be computed.

All satellite navigational systems will require precise orbital infor -
mation so that the satellite's position at any point in time may be accurately
predicted. A communication link for determining the position of the navigating
vessel with respect to the satellite in all types of weather must be available.
Also, in some cases, such as high-speed aircraft, the velocity and altitude will
be required to obtain an accurate positional fix.

2. METHODS OF MEASUREMENT

A number of satellite navigational methods are possible and may be
classified as to type of measurement made with the instantaneous position of the
satellite as a reference. In all systems the satellite follows some orbital path
around the earth. The satellite position is accurately computed in advance and
corrections are made for perturbations which occur with time. The accuracy
of the satellite position is then dependent upon how well the orbit is known and
the accuracy of the time measurement. The position of a vessel relative to the
satellite may then be found by measuring the:

altitude (elevation angle)

azimuth (bearing)

range to the satellite

rate of change of altitude, azimuth, or range.

mon

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Arthur DLittle Inc.

To establish a navigational fix two intersecting lines of position are
required. Where a single variable is being measured, such as the rate of change
of range in the Transit system, for example, a number of successive measure -
ments are required. Where two or more satellites are available simultaneously,
a measurement of the vessel's position with respect to each satellite can gener -
ate the necessary lines of position to establish a fix. Orbital correction informa -
tion is required of both satellites. In other systems which are designed to meas -
ure two variables simultaneously, only a single measurement is required to
determine a fix.

A large number of possible combinations of range, angle, and Doppler
measurements are possible for the determination of a navigational fix. How-
ever, evaluation studies have been made of only the more promising systems
directed toward both military and civilian requirements.

3. MILITARY SATELLITE NAVIGATION SYSTEM

a. Description

The Navy's navigation requirements are quite different from those of
the nonmilitary user. Since the navigator's position must not be betrayed, he
must remain passive. For this reason the Navy's original Transit satellites
were designed to give position information to vessels equipped with data -
processing and accurate inertial guidance navigation equipment. An inertial
guidance or similar system is required to supply the velocity information needed
to compute navigational fixes of high accuracy by range -rate methods.

In the Transit system the satellite orbit is determined by ground
stations and a parametric description is transferred to the satellite. (See
Figure IV-13.) This information is stored in a memory and is updated at least
once each 24 hours. It is continuously transmitted by the satellite and is re-
peated at precise two-minute intervals.

The relative motion between the satellite and the navigating vessel on
a rotating earth produces the well-known Doppler frequency shift. These fre -
quency variations are an accurate measure of the rate of change of the slant
range between the satellite and the navigator. By measuring the Doppler shift
one may obtain either of two results: (1) if the ground station position is known,
the satellite orbit may be determined, or (2) if the orbit of the satellite is known,
the position of the ground station may be calculated.

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88

A navigator who wishes to establish a position fix using Transit during
one of its passes overhead receives from the satellite:

(1) Correct time
(2) Updated orbital information
(3) Doppler frequency information.

Transit radiates two phase -modulated rf frequencies in the UHF region
which are received by the navigating vessel with an apparent variation in each
frequency. At the receiver a beat frequency is formed for each of the trans -
mitted frequencies, which are then suitably combined in a manner which reduces
errors due to atmospheric refraction.

The satellite transmits its position continuously during precisely timed
two-minute intervals. A minimum of three intervals is required for an accurate
position determination. From this information and the time that the Doppler fre-
quency crosses through zero, the latitude can be determined. By measuring the
rate of change of the Doppler frequency the longitude can be calculated. The
satellite also transmits orbital and time reference information as phase modu -
lation on the rf carrier during each interval.

A number of methods exist for computing the navigator's position
once the Doppler frequency vs time has been measured and the orbital informa -
tion received. To carry out the required calculations present plans require a
specialized receiver and computing equipment with a pre-established program.
By a precision analysis of all Doppler information the vessel can determine its
position with respect to the satellite. Evaluation of the time and orbital infor -
mation yields the vessel's position with respect to fixed references on the earth's
surface.

b. Accuracy

Reliable figures of Transit system accuracy are classified and not
readily available. However, the more important errors may be generally
classified as follows:

(1) Inaccurate orbital information
(2) Lack of knowledge of the navigator's own velocity
(3) Errors in the received frequency from the satellite.

The principal orbital errors arise from unpredictable short -comings
in the satellite period. Because of the earth's atmosphere and nonuniform gravi -

tational field, the satellite may advance beyond or be retarded from its predicted
position. An error in the assumed coordinates of the satellite will result in an

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Arthur D.Little Inc.

almost equal error in the computed position of a vessel. For navigation pur -
poses, the position of the satellite is predicted up to 24 hours in advance. An
analysis of test data from Transit 4A(1) indicates an error in satellite position
not greater than 0.5 nautical mile for satellite coordinate predictions made 12
hours in advance. Errors increase rapidly for periods greater than 12 hours.

A second form of error arises from poor information about the navi-
gator's own velocity. With a two-knot velocity error during a 15-minute pass
of the satellite, the estimated positional error is 0.3 - 0.5 nautical mile:
This does not appear to be a severe limitation for surface ships and submarines ,
where accurate pit-log or inertial system information is normally available.
This form of error could be of much greater importance in the case of high -
speed aircraft, where a greater error in velocity might be expected.

Navigational errors of about 1] nautical mile could be produced if the
satellite frequency or the local oscillator were to drift about one part in 108 cps.
However, recent developments indicate stabilities of one part in 1010 per hour
or better may be expected. Consequently the frequency stability of either oscil -
lator should not make any significant contribution to the navigational error, if
a constant frequency shift is monitored and corrected for in the computation.

Simplified methods of computing the navigator's position integrate
the total number of cycles of Doppler shift over a minimum of three two-minute
timing intervals. Some additional error over that experienced in the original
method of using up to 50 data points can be expected. The error produced with
data of this type, using refraction -corrected Doppler, should not exceed 1-2
nautical miles.

It has been shown that position errors due to atmospheric refraction
are reduced by the transmission of two frequencies from the satellite. With
this technique navigational errors of about 0.5 nautical mile might be expected.
By taking advantage of the higher precision (more digits) information being
transmitted, one can reduce this error to less than 0.1 nautical mile. The
higher accuracy requires more elaborate receiving and computing equipment.
Currently such data is not available to the nonmilitary navigator, because it is
coded and specialized receiving and computing equipment is required.

c. The Present Transit System
The Transit plan requires a minimum of four satellites in polar orbits
of about 600 miles with the orbital planes separated by about 45°. An orbiting

period of 108 minutes has been calculated for each satellite. To date a number
of experimental Transit satellites have been built by Johns Hopkins University

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Arthur D.Little Inc.

for the Navy Bureau of Weapons. Three of these are presently in orbit and have
been operational since July 1964. Over this period some operational units of the
fleet have made extensive use of Transit in all parts of the world and have
reported navigational fixes accurate to +0.1 nautical mile. Transit is designed
to provide this accuracy on an all-weather, 24-hour -a-day routine basis.

Westinghouse is responsible for the integration of the antenna, the
data processor, the computer, and the new special-purpose receiver to form the
"Navigational Shipboard Receiver" (AN/BRN-3). This receiver provides four
basic outputs required for the navigation solution:

(1) Vacuum Doppler frequency (corrected for refraction)

(2) Digital data that furnish the navigator with satellite
orbital information

(3) Timing pulses that provide accurate time information

(4) Imc reference and clock frequency, which through a
frequency synthesizer provides all of the system con-
version and reference frequencies.

The present Transit receiving and computing system requires several
racks of equipment (°) which, because of size and power requirement, is proba -
bly unsuitable for most aircraft use. Certain simplifications have been sug-
gested (4) which will decrease receiving equipment size and power requirements
as well as initial cost, while decreasing the fix accuracy only a modest amount.

4. NONMILITARY SATELLITE NAVIGATION

Because of probable economic requirements, the nonmilitary satellite
systems being studied will require only a minimum amount of equipment aboard
the navigating vessel. The bulk of the complex and expensive computer equip -
ment will be concentrated at properly positioned shore stations. For these sys -
tems the navigator would not need to be concermed with satellite orbit informa -
tion and the corrections required for accurate computations. An additional
advantage of the "cooperative" systems is that they permit traffic control, navi-
gation hazard warning, and aids to vessels in distress; these are made possible
by the positional information control available at the computer station.

Each vessel navigating in a given area would be assigned time slots
for satellite transmission, the frequency of which would depend upon the vessel's
requirements for position information. The satellite would be automatically
interrogated by the ground station and navigating vessel. The satellite thus
would serve as a retransmitting station to relay all measurement information to
a ground station for computation and then relay the resulting positional informa-
tion back to the vessel. In this manner one line of position could be established

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by a range measurement from the shore station to the navigating vessel. This
method would involve measuring the time difference in arrival of two signals,
one being the vessel's automatic response via the satellite to the ground station's
coded address signal and the second being the range signal from the vessel via
the satellite to the ground station. From these measurements the distance from
the satellite to the vessel is found anda line of position is established. A second
line of position would be derived from a measurement of the elevation angle or
bearing of the satellite with respect to the vessel. Other methods for finding
the second line of position are also being considered.

Such a system using a single satellite per fix would require approxi -
mately eight station -keeping satellites at about a 6000-mile altitude. Each
would require two or more microwave channels for relay purposes. A fix
accuracy of about +1 nautical mile is anticipated for general use, and a fix
accuracy of +0.1 nautical mile is predicted for special applications .

Another approach to the "cooperative" system which is under consid -
eration would use two or more satellites to generate each individual fix. Posi-
tional information offering about the same accuracy achieved with the single
satellite system would be somewhat easier to obtain. This system would require
16 -24 nonstation -keeping satellites in 6400-mile circular orbits. Digital mes -
sages and ranging pulses would be transmitted to the two satellites within the
user's view and relayed to the navigating vessel. The signals would be auto -
matically retransmitted in reverse order via the same path to the computer
station, where the range of the navigating vessel from the shore station would
be determined and one line of position would be established. An identical meas -
urement from a second satellite would generate an intersecting line of position,
and thus a navigation fix would be established. This is called the active mode of
operation.

Where the user did not wish to reveal his position, a passive mode
might be selected and a general address code utilized. At periodic intervals
the position and altitude of the satellites and then the required pulse information
would be transmitted through the satellite to all passive users in the area. Eack
navigating vessel would then compute its own location. Each user would need
pulse receiving, timing, and display equipment for passive mode operation.

Another suggested approach to using satellite systems for navigation
and ship -positioning is a modification a geodetic survey system in use by the
U.S. Army Map Service, Corps of Engineers. This system known as Secor
(Sequential Collation of Range) (6) uses a single transponder -type satellite and
three precisely positioned ground stations on base lines of 500-1000 miles in
length. (See Figure IV-14.) Accurate positioning at ranges of several thousand
miles is possible, depending on satellite altitude.

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For the Secor-type system the distance from each ground station to
the satellite is determined by phase comparison techniques. The master station
transmits frequency- modulated cw signals in bursts which are repeated by the
satellite transponder and transponded again by each of the other stations. Speed
and course information from the navigating vessel would also be transmitted to
the master station via the satellite. The resulting signals would be received
back at the master station, where phase comparison measurements would be
made and the satellite-to-ground ranges Ty tp Wee and Ty computed.

To obtain information to calculate the range error caused by iono-
spheric refraction, the satellite retransmits phase information on two or more
frequencies. With this information and the range and speed information the
coordinates of the navigating vessel would be computed at the master station
and transmitted via the satellite to the vessel.

So far the most sophisticated form of Secor has achieved geodetic
positioning accuracies of better than 10 ppm. (7) For navigational requirements
and accuracies of 0.1-0.25 nautical mile less sophisticated equipment would
be required.

REFERENCES

1. R. B. Kershner and R. R. Newton, ''The Transit System," J. Inst. of Navi-
gation, April 1962.

2. W. H. Grier and G. C. Weiffenbach, ''A Satellite Doppler Navigation
System,"’ Proc. IRE, April 1960, p. 507.

3. Radio Doppler Method of Using Satellites for Geodesy, Navigation and
Geophysics Within the Planetary System, Johns Hopkins University Applied
Physics Laboratory, Report RG-385, January 1961.

4. Study and Analysis of Selected Long-Distance Navigation Techniques, Vol. II,
Final Report, Inst. of Science and Technology, University of Michigan,

March 1963.

5. E. S. Keats, "Ship Navigation with Satellites, '' Westinghouse Engineer,
January 1963.

6. J. H. Reid, The Secor Approach to Coordinate Determination for Ships and
Aircraft, Technical Paper No. 1, Cubic Corp., San Diego, Calif, 4 June 1964.

7. Brig. Gen. T. S. Hayes, Secor for Satellite Geodesy, Tenth International
Congress of Photogrammetry, Lisbon, Portugal, September 1964.

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I, INERTIAL NAVIGATION SYSTEMS

1. GENERAL

Inertial navigation systems are ship-mounted and entirely self-con-
tained. The vast majority of marine inertial navigation systems has been in-
stalled on Polaris submarines. (Until very recently each of these ships carried
three identical systems, but the number is being reduced to two.) Similar iner-
tial systems are carried on certain aircraft carriers and nuclear attack subma-
rines and on range tracking ships. The systems are complex and expensive,
but they offer unequalled accuracy in position-tracking and, being self-contained,
are entirely independent of external sources of navigational information. They
differ from other ship-mounted systems in their greatly superior ability to main-
tain a continuous track of the ship's position. They are not, of course, absolute-
ly accurate; errors occur and, generally speaking, increase with time. The
coupling of an inertial system with another system which is capable of correcting
the inertially determined position by reference to some external object or signal
produces a composite system having a degree of continuous accuracy unmatched
by any other method of navigation.

2. DESCRIPTION

a. Typical Shipboard Inertial Navigation System

To determine the motion of a vehicle over the earth's surface an iner-
tial navigation system first measures the vehicle's motion with respect to a ref-
erence system which has some known orientation with respect to the earth and
then translates this motion into terms of earth coordinates. The reference sys-
tem is provided by a device called a "stable platform, "' by a system of gyroscopes
and by accelerometers mounted and interconnected in such a way that it maintains
one of its orthogonal axes parallel to the local vertical and another pointed north,
independent of vehicle movements. Accelerometers mounted upon this platform
can then measure vehicle acceleration with respect to the platform. Accelera-
tions are integrated to obtain velocity and distance traveled. These quantities
are translated into earth coordinates to maintain position data and to correct
platform orientation to correspond to the changing position.

To illustrate in more detail the technique of inertial navigation, we
will consider a single typical shipboard system which uses as its reference sys-

tem three orthogonal axes, one vertical, one north-south, and the third east-
west. These axes are established by three single-degree-of-freedom gyros

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Arthur A Little Inc.

orthogonally mounted to form the stable platform. The platform is supported
within three gimbals to provide independence of vehicle roll, pitch, and heading.
Means are provided to sense spurious precessions instantly and to eliminate
them by rotation of the gimbals. Upon the platform the latitude accelerometer
measures the north-south component of acceleration, and the longitude acceler-
ometer measures the east-west component. Mounting the accelerometers in the
level plane makes them insensitive to the influence of the earth's gravitational
field (except for a small component resulting from the earth's "'out-of-roundness, "
which is discussed later). The first integration of acceleration actually occurs
within the "accelerometer" itself, so that the signal delivered is a measure of
linear velocity. If the vehicle were moving along a fixed, flat surface, these
velocities could obviously be integrated to give distances traveled.

The fact that the earth is rotating and has a rounded surface compli-
cates the problem in two ways. First, the system must translate the measured
horizontal motions into their corresponding curvilinear equivalents with respect
to earth. The computer has two channels, latitude and longitude, for this pur-
pose. In the latitude channel north-south velocity is converted from linear to
angular terms to determine change of latitude. The longitude channel operates
in the same way except that two additional complications are necessary. Be-
cause the relationship between longitudinal arc-length and arc-angle is a function
of latitude, latitude must be inserted into the conversion from linear to angular
velocity. Then the angular velocity must be corrected by adding the angular
velocity of the earth, a known constant (for this purpose).

The second problem caused by the earth's shape and motion is that
the platform, which would otherwise remain fixed with relation to space, must
be constrained instead to remain fixed with respect to the earth, i.e., horizontal
and indicating the north. Provision of this constraint is another function of the
computer. In essence the computed values of ship's latitude and velocity and the
known velocity of the earth's surface are used to determine the rate at which the
platform should rotate about each of its three axes. These rates are converted
to control signals which are sent to three torquing motors, one for each gyro;
these motors in turn cause the gyros to precess at the proper rate. The platform
is then erected to make its axes correspond to those of the gyros.

The computer must correct for three other factors: First, the earth
is not actually a sphere but has, instead, a greater radius at the equator than at
the poles. Because the orientation of the stable platform is controlled on the
basis of calculations assuming a spherical earth, the latitude accelerometer
tends to incline slightly away from a normal to the gravitational axis, i.e., the
axis passing through the earth's center of mass, and thus to sense a small com-
ponent of the earth's gravitational field. Second, the rotation of the earth about
its polar axis produces a centripetal acceleration which has a component lying

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along the meridian and directed toward the equator. If not compensated, this
component and the one resulting from the earth's ablateness would combine to
produce a spurious acceleration signal from the latitude accelerometer. There-
fore, the computer supplies a correction signal based on geographical position.

The remaining operation which the computer must perform is that of
correcting for Coriolis acceleration, the phenomenon resulting when a vehicle
moves in the direction of either pole and thus encounters variation in the linear
velocity of the earth's surface. Corrections for this effect are computed and
applied to the longitudinal accelerometer.

b. Alternate Arrangements

The stable platform of the system described above was maintained in
a plane tangent to the earth's surface. Thus each of the gyros sensed a different
component of the earth's rotational velocity. It was necessary for the computer
to determine these components (as functions of latitude) and precisely to torque
each gyro accordingly. To avoid the necessity for this demanding computation,
some systems (typically not those used for ship navigation) incorporate a fourth
gimbal, known as the latitude gimbal, and maintain the platform parallel to the
equatorial plane. This orientation places the input axis of only one of the gyros
parallel to the earth's spin axis; thus the other two are insensitive to earth ro-
tation. The third gyro has its input axis parallel to the earth's spin axis. It
therefore responds to total earth rate and can be compensated through the appli-
cation of a fixed torque.

Systems have been built which employ five gimbals in such a way that
the platform remains completely fixed with respect to space.

c. Composite Systems

The principal sources of errors in inertial systems are unbalance or
bias in accelerometers and drifting of gyros. In the gravity-erected shipboard
systems described above, a constant value of accelerometer bias will result in
velocity and distance errors which vary sinusoidally with an 84-minute period.
A constant value of gyro drift produces an oscillation of the platform about the
vertical, and thus produces velocity and position errors varying sinusoidally
with an 84-minute period. However, because of consequent errors in azimuth,
a constant value of gyro drift will also bring about a distance error which in-
creases monotonically.

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The most common form of composite inertial system is one in which
velocity, measured by some external source, such as an electromagnetic log, is
used to damp platform oscillations and limit the amplitude of periodically varying
errors. However, this measure is ineffective against the cumulative distance
error caused by constant gyro drift or by random errors in velocity and distance
caused by other phenomena. To eliminate these non- periodic errors--essential-
ly to reset the inertial system--an additional system is required to obtain accu-
rate navigational fixes. Such auxiliary systems can be designed to determine
the ship's position either continuously or at discrete intervals. Use may be
made of such navigational aids as Loran or Decca, of course, but of particular
interest are systems which take advantage of the availability of the stable plat-
form and which use celestial bodies for determining the ship's position. Com-
posite systems such as these include a separate computer and an optical and/or
radiometric sextant slaved to the stable platform. In effect the computer com-
pares the actually observed altitude and azimuth of celestial bodies with those
it has computed on the basis of the ship's position and heading as determined by
the inertial navigator. Differences between the observed and computed values
are used to provide corrective signals for latitude, longitude, and heading.

3. ACCURACY

Almost all inertial navigation systems for shipboard use have been
installed on nuclear submarines and on missile range tracking ships, and data
on their performance is classified. However, some notion of the accuracy ob-
tainable can be derived from published information on airborne systems. For
example, records of a large number of recent flights indicate that one system
installed on jet airliners produces an error probability of 2.35 nautical miles
per hour. It is likely that the accuracy demanded of inertial navigation systems
(SINS) in Polaris submarines is considerably greater.

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J. ACOUSTIC DOPPLER

1, INTRODUCTION

Both the Janus JN-400 and the Raytheon AN/SQS-12 acoustic Doppler
navigation systems are self-contained active systems that operate on the Doppler
or frequency-shift principle. In operational use, sound heads are positioned on
the navigating vessel to transmit acoustic energy toward the ocean floor and to
receive energy reflected from it. A precise measurement of the frequency shift
of the reflected signal provides an accurate measure of the vessel's velocity over
the bottom. An accurate magnetic or gyro compass is required for determining
the heading reference.

These systems are capable of supplying the three basic quantities
required for accurate navigation, i.e., speed relative to the bottom, distance
traveled, and drift angle. In the Janus system, this information is displayed
in digital form, and the course and position are manually plotted. Automatic
track-following and plotting equipment has been developed for the more accurate
Raytheon AN/SQS-12,. Both systems are presently limited to operation in shallow
waters of about 250-300 feet, where measurements of velocity and distance
traveled have been demonstrated to be accurate to within 1%.

2. DESCRIPTION

a. Janus JN-400

The JN-400 equipment was developed for use on small craft in shoal
waters less than 250 feet deep. The vessel's true speed over the bottom, the
total distance traveled, and the drift angle with respect to a lubber line are dis-
played to the navigator in digital form. The true course over the bottom is found
by adding the drift angle to the compass reading. The ship's relative position with
respect to the point of departure is manually plotted by taking a digital reading
(in miles) from the distance-traveled counter. This counter may be reset as
required,

The basic track information is obtained by a fixed mounting of four
transmitting transducers which are arranged to direct acoustic energy toward the
ocean floor (see FigureIV-15). Energy striking the bottom is reflected and is re-
ceived by four separate receiving elements. When thevessel is in motion, the
received signal (A f) is Doppler-shifted from the transmitted frequency (f) by an
amount directly proportional to the velocity component (V) over the bottom and
inversely proportional to the acoustic propagation velocity (C).

99

Arthur D. Little, Inc.

prrddy
"ry
‘ty

\\
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\ “ML

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400 ACOUSTIC DOPPLER OPERATION

JANUS JN

FIGURE IV-15

100

(Doppler shift) Af = a f (1)

Two pair of beams are used, one for the fore-aft and one for the port-
starboard direction. This geometry tends to minimize the effects of vessel
motion. Processing of the Doppler frequencies is performed in a small electronic
console to yield the two velocity components and the resultant velocity over the
bottom. The velocity is integrated once to obtain the distance traveled, and its
phase relative to the fore-aft velocity components indicates the drift. Mechanical
counters display both the drift and the distance traveled to six digits with a reso-
lution of + 0.001 nautical mile (= 6 feet).

The maximum depth where over-the-bottom information may be obtained
is approximately 250 feet. This limit is set by limitations in power level and the
high frequency used. At depths greater than 250 feet, sufficient return may be
available from solid matter distributed within the water. However, velocity, in
this case, is measured relative to subsurface currents. Although these generally
have velocities between 0 and 0.5 knot, in some areas the velocity of subsurface
currents may be considerably greater than this, and will produce an error in true
velocity.

The system accuracy is 1-2% of the distance traveled. The +0.3°
drift error specified for the equipment is considerably lower than the error in
many of the heading references available. Velocity measurements have an ac-
curacy of the order of 1% with a minimum threshold of about 0.1 knot.

b. Raytheon AN/SQS- 12

The SQS-12 is a more sophisticated acoustic Doppler navigation system
which is being developed for Navy use in shallow waters. Early tests of prototype
equipment have indicated that this system can provide automatic dead-reckoning
information with an error of less than 1%.

This developmental system uses an array mounted to a fixture on the
bottom of the vessel in such a manner that the four transmitting-receiving pairs
are arranged in two mutually perpendicular vertical planes. To increase the
system accuracy, a stabilizing system can be employed to keep the 8-transducer
transmitting and receiving array oriented in the true vertical direction and inde-
pendent of small motions of the vessel. The array is also maintained in a north-
south orientation by a servo mechanism which is referenced to a Mark 19 or
the smaller, less accurate, Mark 26 gyro compass. It is the heading reference
or compass error which limits the over-all accuracy of this system.

101

Arthur A Hittle Inc.

The distance traveled is displayed by four counters which record the
distance traveled in each cardinal direction. Velocity over the bottom is also dis-
played digitally in the north-south and in the east-west directions. The ship's
heading is indicated by a gyro repeater unit.

The vessel's track is traced on standard navigational charts by an x-y
plotter to a resolution of 0.001 nautical mile on a chart scale of 1:10,000. The
direction and scale factors are set by scaling circuits as required.

REFERENCE

Correspondent and data furnished by Janus Products, Inc., of Syosset, New York,
and Raytheon Company, Submarine Signal Division, Portsmouth, Rhode Island.

102

Arthur AD. Little Inc.

V. MID-RANGE NAVIGATION SYSTEMS

103

Arthur A Little Inc.

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A. DECCA TWO-RANGE SURVEY SYSTEM

1. GENERAL

The Decca Two-Range Survey system is a more recent development
of the standard Decca Navigator system. It is used primarily for hydrographic
surveying purposes where accuracy is important and a shorter range capability
is acceptable. In this system the master transmitter is shipborne, as is the
receiver, and the two shore-based slave stations are light in weight and mobile.
Operational principles are the same as in standard Decca, but the geometry of
the system leads to circular instead of hyperbolic patterns. Under favorable
conditions, Two-Range Decca produces position fixes in error by only 25-60 feet.

2. DESCRIPTION

In 1950 there arose an operational requirement for radio navigation
to aid in a marine survey in Antarctica, where only two suitable sites for shore
stations were available. The Two-Range Decca system which was developed in
response to this need has evolved into a useful survey tool which lends itself
well to small, mobile equipment.

Figure V-1 illustrates the typical two-range layout. A master trans-
mitter on the ship radiates a cw signal of frequency 12 f. The red slave station
ashore receives this transmission and radiates a signal of frequency 8 f, in such
a manner that the slave and master signals are phase-locked at the common
multiplied-up frequency of 24 f. The lines of constant phase difference are now
circles with a center at the red slave and a lane width of about 420 meters.
Similarly, the master and green slave produce an intersecting circular net with
a lane width of about 280 meters. Fixes are obtained through the intersection
of a green and a red position line, as in standard Decca.

A notable characteristic of the system is that because the lane width
is constant with increasing range, position accuracies of 1-2 meters are
achievable. Furthermore, the angle of intersection of red and green position
lines does not deteriorate with range. Thus accurate fixes are obtainable at
ranges well in excess of 150 miles. A compensating disadvantage is the need
for a transmitting station and receiver aboard each ship which desires to use
the Two-Range Decca.

A more serious limitation is the high degree of pattern ambiguity.
Before a fix can be obtained, ship position must be known to better than +210
meters and +140 meters from the red and green slaves, respectively.

105

Arthur DHittle Inc.

RED SLAVE
STATION (8f)

‘\

is — aie
Zi Part =— 7\-- MASTER STATION
ey x Wz (12 f)

Se ie iy

og ea — YA,

ie a Vi

Ooo, ZA Vi;
Za

-sady Ye y
GREEN SLAVE :23 ie i Y,
STATION (9f) <% = yi, y
— eae Z y,

FIGURE V-1 DIAGRAM OF TYPICAL TWO-RANGE DECCA
HYDROGRAPHIC -SURVEY SYSTEM

106

The conventional Decca lane identification system does not lend itself
to mobile equipment where light weight and compactness are desired, but a
modified technique known as the Lambda method (Low Ambiguity Decca) which
overcomes this difficulty has been evolved and is incorporated in a Decca sur-
vey system operating on the two-range principle. Lane identification is
achieved as in standard Decca by superimposing on the fine grid a coarse
circular pattern with a lane width of about 10 km.

3. ACCURACY

Errors in position as obtained with the Decca Two-Range Survey
system are both systematic and random in nature. The systematic errors can
generally be corrected to the degree required. More important are the random
errors which may be caused by the instability of wave propagation and by in-
strumental variations.

Systematic errors usually involve incorrect knowledge of the mean
velocity of propagation, and corrections must be made where the highest system
accuracy is to be obtained. Corrections for variations in ground conductivity
are usually applied in high precision work. This is especially important where
part of the transmission path is over water and part over land. Figure V-2
illustrates the amount of phase correction required for the red and green sta-
tions for a typical seawater transmission path. With proper correction these
errors can be reduced to about | or 2 parts in 10,000.

An additional phase shift caused by placing the receiver in close prox-
imity to the transmitter must also be accounted for. This correction is usually
determined experimentally.

Random errors often occur because of variations in skywave inter-
ference. This type of interference generally appears during the period from
sunset to sunrise at all seasons of the year. It becomes detectable with this
equipment at ranges beyond about 40 miles and increases in magnitude as the
range increases. For this reason the survey activity is generally confined to
daytime operation. During summer daylight, 95% rms radial errors run from
25 to 60 feet as the range increases. Typical random-error contours for day-
light operation are illustrated in Figure V-3.

Arthur D.Little Inc.

LANES

O 10 100 1000

FIGURE V-2 PHASE CORRECTION VS RANGE FOR
TYPICAL SEAWATER TRANSMISSION
PATH

FIGURE V-3 FIXING ACCURACY CONTOURS FOR
SUMMER DAYLIGHT OPERATION FOR
A 0.01 LANE DEVIATION

108

4, SUMMARY

a. Type of System

Circular plot single-user system.

Number of shore stations required: master and two slaves
(xed and green).

Length of base line: 60 miles or less.

Frequency range: 112-180 kc (approximately).

Transmitted power: 350 watt cw shipboard-mounted transmitter.
Mobile antenna: 45-feet tubular sections.

Range: 6-175 nautical miles (approximately).

Receiver power requirements: 250 watts (approximately).
Shipboard and shore station power requirements: 2 kw.

Receiver readout: 4 dial Decometer Unit providing (Decca
Mark 5 shipborne set) Lambda Identification System - Marine
automatic track plotter provides continuous position plot in
rectilinear coordinates.

b. Range and Accuracy

(1)
(2)

(3)

REFERENCE

Usable service distance: 175 nautical miles.

Approximate 95% rms radial error at 40 nautical miles:
AS) = (H0) wes.

Approximate 60% rms radial error at 175 nautical miles:
300 feet.

C. Powell, "Radio Aids to Hydrography,'’ Wireless World, July, 1960.

109

Arthur D.Uittle Inc.

B. ELECTRONIC POSITION INDICATOR (EPI)

1. GENERAL

The EPI electronic method of position control for use in hydrographic
surveys was developed by the U.S.Coast & Geodetic Survey in the late 1940's.
It was designed to complement the near-shore Shoran equipment (see Sec -
tion VI E) and has a useful range of 200-500 miles, depending upon atmospheric
conditions at the time of measurement. It operates at a frequency of 1.85 mc
and is principally used for the control of a hydrographic survey on a scale of
1: 100,000 and smaller.

Like Shoran, EPI is a pulse phase-measuring system which requires
a minimum of two shore stations positioned at the ends of a fixed base line. In
place of the automatic transponder-type shore stations found in Shoran, the
EPI ship-positioning system uses interrogation and reply. It is a (rho-rho)
system which measures the distance from the ship to each ground station.
Periodic pulses are transmitted from the ship. The shore station operator ob-
serves the ship signals and his own shore station signal on a cathode-ray-tube
display. He manually makes proper adjustment so that the two signals coin-
cide. Delays of known size are incorporated in the circuits to prevent confusing
one ground station with the other. Aboard ship, the signal pips are viewed on a
similar cathode-ray tube and manually matched to the stationary ship signal
pulse. The distance is displayed in digital form in units corresponding to
microseconds of time. One unit on the dial equals about 150 meters, or 492
feet. Position fixes accurate from about 50 feet to 200 feet can be expected at
ranges of 200-250 miles.

2. DESCRIPTION

The equipment consists of a shipborne transmitter which transmits
precisely timed pulses toward the two shore stations positioned at either end of
a base line. These stations, in turn, retransmit similar pulses accurately
synchronized with those from the ship. A shipboard receiver -indicator unit
(Figure V-4) receives the two ground station pulses and displays them simul-
taneously at a rate of about 20 times per second. Distance measurements to
each ground station are then made by the shipboard operator.

Because of the low transmission frequency of 1850 kc the rise time of
the pulse at the receiver is slow, i.e., 8-12 microseconds. For this reason,
the received pulse is not used to retrigger the shore transmitter as in Shoran,
because large errors would result if the pulse were noise-modulated. A syn-
chronizing method is used in EPI which precisely sets the time at which the

110

Arthur D Little Inc.

TRANSMITTER

RECIEVER
INDICATOR
MODULATOR

ATTENUATOR

MOBILE STATION

CONTROLLER @ &

GROUND STATION B

GROUND STATION ‘A’

TRANSMITTER TRANSMITTER

MODULATOR
MODULATOR

ATTENUATOR
RECIEVER
INDICATOR

SYNCHRONIZER

ATTENUATOR

RECIEVER
INDICATOR

SYNCHRONIZER

FIGURE V-4 BLOCK DIAGRAM FOR EPI SYSTEM

111
Arthur DAittle, Inc.

ground station signal will be transmitted with respect to the time the ship
station signal was received. A constant velocity of propagation is assumed
and corrections are not normally made.

a. Shipboard Equipment

The timing of the entire system is controlled by a highly stable
100-ke crystal oscillator in the shipboard controller. Divider circuits are used
to produce signals for driving the distance-measuring circuits, gating delay
circuits and initiating pulses for the transmitter.

The 100-kc timing signal is also fed to three synchro-resolver circuits
in the range units, along with the outputs of the appropriate dividers. The sig-
nals from the three resolver circuits (10, 100, and 1000 microseconds) are used
to measure the distance between the ship and the ground stations.

A separate resolver system is used for each of the two ground stations,
so that the distance to each shore station is measured simultaneously. The
counting is done by a large vernier dial reading to 10 microseconds with a reso-
lution of 0.1 microsecond. The dial is coupled to a counter which reads tens,
hundreds, and thousands of microseconds, and thus indicates the distance to
each ground station in microseconds.

Pulses from the range resolvers are directed to the indicator, where
they initiate the cathode-ray-tube sweep. The sweep is positioned by operation
of the ranger until it occurs simultaneously with the reception of the ground
station signal. The pulse which triggers the transmitter also triggers a fixed,
stationary sweep on which the transmitter signal is displayed. By adjusting each
ranger so that its ground station signal is in coincidence with the ship pulse, one
may read out the distance between ship and ground station on the vernier dial
and counter in loop-microseconds.

The "A" ground station and ''B" ground station signals are made to
appear on the left and right sides of the vertical cathode-ray-tube sweep. The
two signals are commutated at a high rate and thus appear continuously displayed
to the operator.

Signals from both shore stations are received aboard ship on a single
receiver and a common antenna quarter-wave flat-top antenna. The incoming
signals are coupled to the receiver by an attenuator unit which amplifies the
signals from weak ground stations and shorts out those from the transmitter.
The receiver utilizes automatic gain control to equalize the strength of the sig-
nals from both ground stations.

112

Arthur D. Little Inc.

The transmitter operates at a frequency of 1.85 mc and produces
precisely spaced pulses at a peak power of 10 kw (average power about 25 watts).
The pulse width is about 60 seconds and is produced with a repetition rate of
41-2/3 pulses per second. The peak power can be raised to 18 kw when ranges
greater than 500 miles are required. The transmitter output is fed to a
quarter-wave flat-top antenna.

b. Ground Station Equipment

The ground station equipment receives rf pulses from the ship and
transmits a signal back to the ship after a definite time delay. All ground sta-
tion equipment used for this purpose is similar in operation to the shipboard
equipment except for the controller indicator.

The indicator contains a precision 100-kc oscillator which controls
the timing functions of the shore station. It is closely synchronized to the ship
crystal by appropriate AFC and synchronizer equipment and maintains a mini-
mum timing accuracy of 0.1 microsecond. The degree of synchronization is
continuously displayed for the operator.

A cathode-ray tube with horizontal sweeps is used to display the
shipboard and ground station signal pulses. The operator continuously adjusts
the shore station signal to match the time of arrival of the shipboard pulse.

A quarter-wave vertical radiator is used for both transmitting and
receiving. A ground plane consisting of radial wires approximately 100 feet
long is required for proper antenna operation.

The equipment requires about 5 kw of 115v, 60 cps, single-phase,
alternating current. This is sufficient for both equipment and station operation.
3. ACCURACY

Both systematic and random errors occur in the operation of EPI
equipment.

a. Systematic Errors

Systematic errors include such factors as:

113

Arthur DHittle Inc.

(1) Incorrect velocity of propagation

(2) Non-linearity of range circuits

(3) Initial zero correction.

A velocity of propagation of 299,690 km per second at a sea level
pressure of 760 mm is assumed. The velocity is subject to change due to

changes in barometric pressure, humidity, etc., but it is probable that the
error caused by these assumptions is not greater than 5 parts in 200,000.

The non-linearity of the range circuits can be determined in the lab-
oratory. Corrections can be applied if necessary. Generally they do not
exceed 0.1 microsecond and can be neglected in hydrographic work if the scale
is smaller than 1: 100,000.

A small initial zero correction must be applied to all distance
measurements. This error is caused by the difficulty of making the vernier read
exactly zero to correspond to zero time. The error can be determined at the
will of the operator and applied or corrected at any time. Daily calibration is
necessary to correct for normal instrument drift.

b. Random Errors
The random errors are more serious, with no way of predicting their
magnitude. They occur both in the shipboard equipment and shore station equip-
ment and are caused mainly by human error.

At the ship they are:

(1) Misalignment of local and distance pulses
(2) Careless reading of the distance verniers and dials

(3) Poor alignment of pulses.
At the ground station they are:

(1) Poor synchronization of the time fix

(2) Incorrect setting of the balance gain.

The effect of all of these possible errors in the EPI system is to cause
an uncertainty in position which is directly related to the magnitude of the error
(algebraic summation) and the angle at which the distance arcs intersect. Ex-

perience has demonstrated that negligible error is introduced when the inter-
secting arcs are kept within the limits of 30° - 150°.

114

Arthur D Hittle Inc.

Extensive field and laboratory tests have been performed by the USC
& GS to determine the EPI system's accuracy and consistency. Table V-1 lists
these data as a percentage of observations that come within the fraction of micro-
second indicated, Accurately measured distances of 45, 90, 110, and 267
nautical miles wereused. A total of 267 sets of observations were made. These
tests also indicate there is little correction required to compensate for signal
strength or distance between the ship and ground stations.

DABBLE MVE
FIELD TEST DATA FOR EPI

% Observations Within Specified Limits

Limits of Error Field Tests Laboratory Tests

+ Microseconds 267 Observations 21 Sets of Observations
0.1 (15 meters) 35 26

0.2 (30 meters) 53 53

0.3 (45 meters) V2 71

0.4 (60 meters) 83 82

4, SUMMARY

a. Type of System

(1) Pulsed phase-difference circular plot.

(2) Number of stations required: 2 shore stations, 1 shipboard
Station.

(3) Length of base line: 50-250 miles.

(4) Operators required: at ground stations and on shipboard.
(5) Transmitter pulse width: 60 microseconds.

(6) Transmitter pulse repetition rate: 41-2/3 per second.
(7) Shipboard transmitter frequency: 1.85 mc.

(8) Shore station transmitter frequency: 1.85 mc.

(9) Shipboard and ground station peak pulse power: 10-18 kw.

iL)

Arthur D. Little Inc.

(10) Shipboard antenna: one-quarter wave loaded flat top.

(11) Shore station antenna: one-quarter vertical dipole and ground
plane.

(12) Ground station transmission: time separated by a controlled
and precise delay.

(13) Number of ships handled by ground station: 1 ship or 2 ships
(time sharing).

(14) Readout: pulse matching on shipboard cathode-ray tube.
Distance is read on a vernier to 0.1 microsecond and digital
counters to 9999.9 microseconds. Time is converted to dis-
tance using C = 299,690 km per second.

b. Range and Accuracy

(1) Usable service distance: 15-500 nautical miles.

(2) Approximate accuracy of distance measurement: 50-200 feet at
distances out to 250 miles.

(3) Accuracy of LOP: dependent upon absolute magnitude of errors
and angle at which distance arcs intersect. Area of uncertainty
is negligible when angles of intersection are between 30 and 150°.

REFERENCES

1. Cmdr. Clarence A. Burmister, "Electronic Position Indicator (EPI, "Journal,
Coast and Geodetic Survey, 1953.

2. Cmdr. Clarence A. Burmister, ‘Electronics in Hydrographic Surveying, "
Journal, Coast and Geodetic Survey, Jan. 1948.

3. Capt. Gilbert R. Fish, Electronic Control Systems Used on Hydrographic
Surveys, Coast and Geodetic Survey, Dept. of Commerce.

4, Rear-Admiral Robert F. A. Studds, Coast & Geodetic Survey, ''Shoran
and EPI in Offshore Hydrographic Surveying, '' paper given at the Inter-
national Hydrographic Conference, Monaco, April-May 1952.

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Arthur D.Little Inc.

C. LORAC

1. GENERAL

The LORAC (Long Range Accuracy) ship-positioning systems were
developed by the Seismograph Service Corp. for survey work in the shelf area
of the Gulf of Mexico. The LORAC system was designed to extend survey work
beyond the line of sight distances of Shoran without sacrificing the accuracy of
position determination.

LORAC is a hyperbolic cw phase comparison system using frequencies
in the 1700-2500 ke band. At these medium frequencies rf energy tends to fol-
low the curvature of the earth, permitting a high degree of accuracy.

However, both lower and higher frequencies have been used. At 2 mc
the operating range is of the order of 135 miles during the day, but is limited to
about 50 miles at night due to sky-wave interference. Over water, accuracy
is of the order of +2.5 feet along the base line and is gradually degraded as the
mobile receiver moves away from the base line.

Both LORAC A and LORAC B are position-fixing systems, and both
supply a double hyperbolic grid. In both systems transmitting stations are set
up at fixed shore sites. The basic receiving set displays grid coordinates in
the form of dial and digital counter readings. Special indicating equipment
including a course plotter, digital printer, tape punch, and distance-heading
indicator is available.

2. DESCRIPTION

In the basic LORAC system, illustrated in Figure V-5, cw trans-
mission is used and a phase difference measurement is made at the mobile
receiver to obtain the coordinates of its position. Transmitters T, and Ty are
located at the ends of a base line and operate on frequencies f; and f, which
differ by an audio frequency. A reference signal is established at T3 by detect-
ing the heterodyne beat between T, and T,. This detection takes place at a fixed
point and, therefore, has a constant phase angle. It is transmitted to the mobile
receiver as amplitude modulation on a third rf frequency f3.

The receiving station contains two separate receivers. The direct-
heterodyne difference frequency when received at the mobile station has a phase

angle dependent upon the station position relative to the base line. The differ-
ence in phase between the direct-heterodyne difference frequency and the

IL

Arthur D. Little Inc.

reference-heterodyne frequency transmitted from T3 is measured. The measured
phase angle determines the location of the mobile station on one hyperbolic line
of position.

To obtain a second line of position, the complete system of Figure V-6
is duplicated. A second base line which results in the second LOP is formed.
The two patterns thus generated are conventionally known as the red and green
patterns.

The phase meter at the mobile receiver is geared to a revolution
counter which indicates the number of lanes traversed in both patterns. The
readings can be transferred to charts of the area on which the equiphase contours
are drawn, and a position fix can be established. Lane identification is not pro-
vided in the basic LORAC system.

The basic system requires six transmitters, six receivers, and four
frequency channels to locate one mobile station. This is a multi-user system,
and there are no limitations on the number of mobile receivers using the system
simultaneously. However, the other LORAC systems provide the same capability
and use less equipment.

a. LORAC Type "A" System

In the LORAC type "A" (Alpha) system the equipment required is re-
duced by the use of a time-sharing procedure. The system is similar to the basic
system except that the T) and T, ground stations alternate as reference stations,
as illustrated in Figure V-7. This system requires three transmitters and two
receivers to establish a hyperbolic grid system. A receiver is required at both
the red andthe green ground stations. Each mobile station using the system re-
quires two receivers and two phase meters along with the required frequency
selective equipment.

The central shore station, T9, alternately transmits two frequencies.
The transmitter and receiver at both the red and the green ground stations are
continuously energized. In this manner, aheterodyned reference signal is al-
ternately transmitted as modulation on a carrier from each ground station and
received at the mobile station. Simultaneously, aheterodyne position signal is
received on a second receiver at the mobile station. These two signals are
compared and displayed on an integrating-type phase meter. In this manner
red and green lines-of-position are alternately established, with each phase
meter operating for one-half of the complete cycle. The switching rate is suf-
ficiently rapid to produce the effect of continuous transmission at the position
indicators.

118

Arthur D Hittle, Inc.

CARRIERS WHICH
PRODUCE REFER-

° bs a [. ENCE SIGNAL

3 fo} ° fo) S f.

= 0 + Nn ve

= =,

2

aq

=} RCVR
€ AW

CARRIERS| WHICH 2

AT POINT "P”.

fo AND #; HETERODYNE TO PRODUCE ~_
THE POSITION SIGNAL, fo-f). fq,
CARRYING THE REFERENCE SIG-
NAL, fo-f,, IS DETECTED.

oe ee

FIGURE V-5 BASIC LORAC SYSTEM REQUIRED FOR ONE
HYPERBOLIC LINE OF POSITION

CARRIER MODULATED
WITH REFERENCE
sina (fp -#;)

POSITION SIGNAL

™~ om
BASE LINE EXTENSION ~~ ~~ _ BASE LINE EXTENSION
RED LANE O Tari Soo _ —*+— GREEN LANE O

COORDINATES:
GREEN LANE 30
RED LANE 250

fe}

ew lay
i
1@ Ce)
9 (>)
ee
Ss y 3
©

FIGURE V-6 HYPERBOLIC POSITION GRID

119

Arthur DAittle Ine.

CENTER STATION
PRIMARY TRANSMITTER

Fs > RED END STATION-
GREEN END STATION GREEN REFERENCE TRANSMITTER
PRIMARY TRANSMITTER ,

FIGURE V-7 LORAC TYPE A (ALPHA) GREEN HALF
OF SWITCHING CYCLE

120

b. LORAC Type ''B" System

The type "B" (Beta) system transmitters T), To, and wa establish
one-half of the positioning grid and are called green lanes. The transmitters
T 9, T3, and Ty establish the red lanes, as shown in Figure V-8. Transmitters
T), T 9, and T3 occupy precisely surveyed positions, while the receiver and
transmitter of Ty are placed ata convenient position within the grid system.

Figure V-8 indicates the frequency relationships of the complete Beta
system. Mobile receiver No.1 produces both the green position signal (f5 - f))
and the red position signal (f4-f3). Receiver No. 2 receives both the red and
green reference signals transmitted as amplitude modulation on carrier fg.

The Beta system is less complex than the basic system. Beta requires
four transmitters, one receiver, and four frequencies to establish a hyperbolic
grid. Time sharing is not required. In addition, the Beta system has a some-
what greater area of coverage than Alpha.

c. Calibration

The LORAC equipment is a differential-distance-measuring system
and for this reason must be calibrated for the particular grid system in which
it is to operate. A hyperbolic position grid is drawn 1) when the location of
transmitters T)> To, and T2 is precisely known.

The calibration is generally carried out by locating the mobile re-
ceiver at an accurately known geographic position within the grid system. The
phase counters are then adjusted to the calculated lane settings and the phase
meters set to the proper phase position within the lane. As the mobile receiver
moves from this position, the phase meters and counters track and continuously
indicate the ship's position on the grid system.

d. Transmitting and Receiving Equipment

LORAC transmitting and receiving equipment is of unitized construc-
tion, providing good portability and interchangeability. The transmitters are of
two types, depending upon their function within the LORAC system used. They
are adjustable over the frequency range of 1.7 to 2.5 mc and use a temperature-
stabilized crystal master oscillator for close frequency control.

Arthur D.Little Inc.

lS
Nig
/ 4
N We
iN yf
f, fey [FP ge
Sayan eie tp
Naa

FIGURE V-8

~_LORAC
OBILE RECEIVER

/ Veer eeeice STATION ~--~
fq -MODULATED _--

é) PRIMARY STATION-CW

f d Nb 84
/ Toa NE PRIMARY STATION-CW
IN&

34 &
3

LORAC TYPE B (BETA) OPERATION

122

The basic radio receiver is also adjustable over the frequency range
of 1.7-2.5 mc. The position indicators are part of the receiver and display the
grid coordinates as dial and counter readings. ‘The receiver also provides out-
puts to drive special indicating and course-plotting equipment.

e. Recording and Readout

The two phase meter indicators of both the Alpha and the Beta systems
provide outputs for a digital printer and tape punch unit so that a ship's course
can be recorded. Additionally, an Actrac course plotter may be used with the
indicators to provide instantaneous position and track on preplotted charts; a
distance-heading indicator also may be used to help navigate between preplotted
points.

3. ACCURACY AND RANGE

In cw phase-measuring systems such as LORAC, the one-half wave
lengths are counted and then a phase measurement is made of the remaining
fractional one-half wave length. The accuracy is a function of the frequency
employed. For a frequency of 2.0 mc, the wave length is approximately
492 feet. On the base line a lane (one-half wave length) is 246 feet, which con-
stitutes a phase-difference reading of 360°. The phase meter is calibrated to
0.01 lane or +3.6°, which is about +2.5 feet on the base line. At distances
farther from the base line, the lanes widen and the accuracy of the position fix
is reduced. Field reports have indicated accuracies of 1 : 50,000 are achieved
without difficulty. 2

Over water, operating ranges up to 135 nautical miles during the day
have been reported. At night, operation is restricted to base line lengths of
less than 55 miles, because of sky-wave interference.

Propagation effects may produce other errors where part of the
propagation path is across land masses. The magnitude of these errors has not
been completely investigated, but an error of 0.1 lane would not be unusual.
Larger errors can be expected where the propagation path is over rough terrain
or where hills produce a shadow effect. A constant velocity of propagation is as-
sumed for most LORAC navigational problems.

Because of the method of transferring a reference heterodyned signal
to the mobile station, transmitter frequency synchronization is not needed in
LORAC ship-positioning systems. However, in a cw positioning system of this
type an ambiguity does exist. The two phase measurements which are required
identify the position of the receiving station relative to the two intersecting pairs of

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hyperbolic isophase lines, but they do not indicate the pairs of lines to which the
readings are related. Thus, the geographic position of the receiving unit rela-
tive to the transmitting stations must be known at the start of the hydrographic
survey. Each successive half-wave interval must then be tabulated as the receiv-

ing station is

moved relative to the pattern of the hyperbolic grid. Digital

counters mechanically coupled to the phase meters are provided for this purpose.

4, SUMMARY

a. Type

(1)

(2),

(3)
(4)
(5)

(6)
(7)
(8)
(9)
(10)
(11)

(12)

of System

Cw phase-difference hyperbolic plot multi-user system.
Number of shore stations required:
Alpha: 3 (3 transmitters and 2 receivers required)
Beta: 4 (4 transmitters and 1 receiver required)
Length of base line: 10-50 miles.
Operators required: at ground station and on board ship.

Transmitter frequency: 1.75-2.5 mc (crystal-controlled,
adjustable).

Shore station power level: 300 watts.

Shore station transmitting antenna: one-quarter wave dipole.
Shore station receiving antenna: directional loop.

Shore station transmission: cw with no synchronization required.
Shipboard receiving antennas: one-quarter wave dipoles (2).

Mobile station readout: phase meters (2), red line and green
line. Also provisions for driving automatic track plotter,
tape punch, digital printer and distance-heading indicator.

Lane identification: digital counter follows movement from lane
to lane. Must be pre-set at known geographic position at the
start of survey.

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Arthur D Little Inc.

b. Range and Accuracy

(1) Usable service range: 55 - 135 nautical miles.

(2) Approximate accuracy of range measurement: 1: 50,000 feet,
depending upon the position of the mobile unit relative to the
shore station transmitters.

(3) Accuracy of LOP: dependent upon absolute magnitude of errors
and angle at which hyperbolic arcs intersect. Area of uncertainty
is negligible when angles of intersection are between 30 and 150°.

REFERENCES

1. LORAC - Seismograph Service Corp., Tulsa, Oklahoma - Radio Aids to
Maritime Navigation and Hydrography. S.P. 39 - Article supplied,
April 1960.

2. G. Leifson, "Hyperbolic Positioning Systems for Hydrographic Surveys,"
U.S. Hydrographic Office, International Hydrographic Review, May 1953.

3. Edward J. Crossland, ''LORAC: What It is and How It Works," Seismograph

Service Corp., Tulsa, Oklahoma. Reprinted from Philco’' Tech Rep Division
Bulletin, March 1952.

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D. RAYDIST

l. GENERAL

Raydist is the generic name of a family of radio distance-measuring
and navigation systems produced commercially by Hastings-Raydist, Inc.,
Hampton, Virginia. These systems are used extensively by the U.S.Coast
and Geodetic Survey and by a number of commercial organizations and foreign
governments.

All forms of Raydist operate on the same basic principle. Two cw
transmitters are located on a base line and separated by a distance of up to 100
miles. They are operated at frequencies in the 1.6-5 mc range, the two trans-
missions differing by about 400 cps. The 400 cps beat note is obtained at each
station and retransmitted to some convenient location where phase comparison
is performed, yielding interstation distance. The frequency range used permits
small efficient transmitters and operation to beyond line-of-sight.

Several geometric configurations are possible, depending upon the
position of the stations, and include hyperbolic and elliptic coordinates, angle
measurements, and circular or direct distance measurements. Because of the
vast superiority of direct distance measurement, this system (DM) is replacing
the others in all but a limited number of applications. It is illustrated in
Figure V-9. Its major advantages are the requirement for only two stations,
the simplified circular charts, and the much higher accuracy and area coverage
inherent in the circular geometry.

All forms of Raydist are entirely automatic in operation, the position
data being read directly from the phase meter dial or from the plot of an auto-
matic position recorder. Accuracies of one part in 5000 can normally be
expected, while one part in 50,000 or better is achievable in certain survey
operations.

2. DESCRIPTION

a. DM Raydist

This system was developed for precise two-dimensional tracking of
small cw transmitters for purposes of navigation, surveying, or position plotting.
It gives the instantaneous position of a mobile transmitter with reference to two
fixed receiving stations identified as the red and green stations. Mobile station
equipment includes a cw transmitter, and the "Navigator, '’ consisting of a spe-
cial-purpose, dual-frequency receiver anda phase comparison unit (Fig. V-9).

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Arthur A AUittle Inc.

i a
(Xin tart |

C1 Rcvr

1 LINK xmtr bot

“4
_—_—_ — se a

j C1 MULTIPLIER

@ PHASE METER

|
I
!
!
| |
Le Ss ea =I

| RCvR
lio

LINK xmtr
L

=
I
|
—)

FIGURE V-9 DM RAYDIST LATTICE

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Arthur A Little Inc.

A cw transmitter located at the red station operates at a frequency
400 cps higher or lower than the mobile station frequency. A special-purpose,
dual-frequency receiver is also used at both the red and green shore stations.
The receiver at each shore station accepts the transmission from both the mobile
station and the other shore station, doubles the lower frequency and heterodynes
it with the higher frequency to generate the 400 cps audio beat note. Separate
audio notes are then returned to the mobile station by the red and green stations
as a modulation of two additional, completely independent frequencies. The
Navigator phase-compares these signals with the beat note it produces locally.
A comparison of the red signal with the local mobile frequency yields a reading
on the phase meter of the distance to the red station. Comparing the green signal
with the local signal yields a measurement in elliptic coordinates which the phase
meter then converts into distance to the green station.

The system employed permits more than one user. A second Navigator-
equipped vessel, for example, would transmit on a slightly different frequency,
and produce therefore a slightly different beat note. A composite of both notes
appears at the two shore stations and is returned to both Navigators. However,
the local signal generated as the heterodyne of the vessel's own transmitter with
the red transmitter will be a pure tone, since each shipboard transmitter is so
close to its own receiver as to preclude reception of other transmissions on
nearby frequencies. The mobile station phase meters respond only to the tone in
the composite frequency corresponding to the pure tone and thus indicate the dis-
tance to the red and green stations.

b. Type DR Raydist
In this system, two independent DM systems are employed. Conse-
quently, it is unnecessary to make transmissions from one shore station to an-
other, an advantage when such transmissions are difficult because of a large
interstation distance or rough terrain.
c. Type R Raydist
This system corresponds to DM Raydist but employs only the red shore
station. As a consequence, two-dimensional fixes cannot be obtained; only direct
distance to the red station can be obtained.
d. Type E Raydist
A group of stations are utilized to set up an intersecting net of hyper -
bolic coordinates. The shore station-Navigator combination of Type R is

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Arthur DAittle Inc.

duplicated at several points. The chief advantage of this system is that it can be
designed so that heterodyning, phase comparison, and distance measurement
are all performed at shore stations. The tracked object then requires a mini-
mum of equipment, namely a small cwtransmitter. For certain applications
involving, say, expendable transmitters in buoys, the Type E system can prove
quite practical. It is interesting to note that this form of Raydist was used for
tracking the first satellites.

e. Other Systems

A number of other hyperbolic systems are in limited use, although
they are being gradually superseded by the distance-measuring forms. Chief
among these is the Type N Raydist, which is completely nonsaturable and finds
application where the number of simultaneous users exceeds the capabilities of
a DM system. The largest single Type N installation is a network covering the
coastal waters of the Gulf of Mexico and used largely for offshore oil exploration.

3. RANGE AND ACCURACY

Because of the circular coordinates involved, DM Raydist has substan-
tially greater potential for accurate position fixes than do the hyperbolic systems.
DM Raydist is more accurate because lane width remains constant with increas-
ing range in a circular system, while increasing very rapidly with range in
hyperbolic coordinate systems. In addition, the angle of intersection of hyper-
bolic coordinate nets increases much more rapidly with range, so that two-
dimensional fixes are subject to larger errors. Figure V-10 compares the
accuracy of a circular and a hyperbolic system on the basis of these geometric
considerations alone. It should be noted that other errors such as propagation
velocity and ionospheric effects would also be greater in hyperbolic systems than
in the distance-measuring system.

The frequencies (1.6-5 mc) employed by Raydist provide a lane width
equivalent to a one-cycle change in phase. This is equivalent to distances of
30 and 100 meters. Since the phase meter can be read to 0.01 lane, readability
of Raydist systems is 1/3 - 1 meter in the DM forms, and 1/3 - 1 meter difference
in distance with the hyperbolic types.

Other accuracy considerations include the care with which shore stations
are positioned and the system calibration. Experience has shown that accuracies

of 1 : 5000 with a probable error of the order of 3 meters can be normally ex-
pected, and that accuracies to within 1 meter are achievable.

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Arthur D.Little Jue.

30

20

SYSTEM — RANGE
SYSTEM

IDENTICAL
BASE LINES
A-B ;
IN EACH SYSTEM

30
20
10
HYPERBOLIC DM

FIGURE V-10 COMPARISON OF AREAS OF EQUAL ACCURACY
FOR CORRESPONDING RANGING AND HYPERBOLIC

SYSTEM

130

Operating ranges depend on the usual factors, including propagation
path, ambient radio noise, sky-wave interference and its variations with season
and time of day, receiver sensitivity, and transmitter power. Maximum ranges
of 100-200 miles are usual under all but the most severe conditions. The newer
miniaturized equipment is rated for 25 miles but has been operated at ranges in
excess of 60 miles.

4. SUMMARY

Big Wore

(1)
(2)
(3)
(4)
(5)

(6)

of System

Phase comparison of audio beat note.
Direct-distance (circular) or hyperbolic coordinates.
Operating frequency: 1.6 - 5.0 mc.
Provision for lane identification possible but not usual.
Operating ranges:
High-powered Raydist 100-200 nautical miles
Miniaturized (transistorized) 25- 60 nautical miles

Accuracy of 1:5000 with a probable error of 1-3 meters.

b. Equipment Characteristics (DM Raydist only)

(1) High-Powered System

RED STATION
Receiver Unit Wexellexe2ominiches 63 pounds
AM Transmitter 17 x 11 x 25 inches 95 pounds
CW Transmitter 17 x 11 x 25 inches 95 pounds
Two Antenna Loading Boxes One 2ixe2Zominches 12 pounds
Power Required 950 w, 60 cps, 110 v, ac.

GREEN STATION

Receiver Unit Wexellexd2 pinches 63 pounds
AM Transmitter Wxlxe2 Sy inche's 95 pounds
Antenna Loading Box 6 x 12 x 12 inches 12 pounds
Antennas and Accessories 225 pounds
Power Required 700 w, 60 cps, 110 v ac.

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Arthur A Hittle Inc.

Navigator

Position Indicator
Power Supply
Position Recorder
Monitor
Transmitter
Antenna Loading Box
Power Required

MOBILE STATION

17 x 8 x 25 inches
9 x 12 x 12 inches
17 x 10 x 14 inches
21x 9x 9 inches
9x §&§x 11 inches
17 x 11 x 25 inches
6 x 12 x 12 inches

73 pounds
33 pounds
90 pounds
18-1/2 pounds
22 pounds
95 pounds
12 pounds

1.3 kw, 60 cps, 110 v, ac.

(2) Miniaturized System

Relay Unit
CW Transmitter
Whip Antenna

Power Required

Relay Unit
Whip Antenna

Power Required

REFERENCES

RED STATION

18 x 10 x 11 inches
8,5 x 10 x 11 inches
35 feet extended
(collapses to 6 feet)
24 v, dc at 2 amps

GREEN STATION

18 x 10 x 11 inches
35 feet extended
(collapses to 6 feet)
24 v, dc at 2 amps

37 pounds
19 pounds
12 pounds

37 pounds
12 pounds

1. Raydist, Supplementary Paper 2 to S. P. 39, Radio Aids to Maritime
Navigation and Hydrography, International Hydrographic Bureau, Monaco,

November 1960.

2. Radio Distance Measurement and Position Fixing,

Electronics Research

Directorate, AFCRL, Publication No. AFCRC-TR-60-191, Bedford, Mass.,

pp. 48-51.

3. G. R. Fish, Raydist on Georges Bank, U.S.Coast and Geodetic Survey,
Tech. Bull. No. 5, April 1959.

4, J. P. Comstock and C. E. Hastings, ''Raydist Measures Speed of Ships, "
Marine Engineering, June 1953.

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Arthur D.AUittle Inc.

VI. SHORT-RANGE NAVIGATION SYSTEMS

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Arthur DLittle Inc.

fon a es
Mi ay
I

my

A, RADAR

1. GENERAL

Radar as used for navigation and position fixing is a system of deter -
mining distances by measuring the time-interval between the transmission of
pulses and the return of the corresponding echoes from primary targets. In
its use of the interrogation and reply method it is similar to such systems as
Shoran.

Radar development began in England in the 1930's, and all of the more
recent types of pulse measurement systems evolved from this early work.
However, radar differs from the other pulse systems described herein in that
the reply is the wave reflected from the target point, and transponding or re-
transmitting equipment is not required to send back a reply. Thus, radar is
an entirely self-contained system suitable for multi-user application. Ranges
of from a few hundred feet to beyond the line of sight (200 feet -50 miles) and
range resolution of the order of 1 part in 1000 or better can be expected with
most classes of radar equipment.

2. DESCRIPTION

Radar systems consist of a transmitter, rotary antenna and switch,
receiver, ranging unit, plan -position -indicator display unit (PPI), and associ -
ated power supply. A typical system is diagrammed in Figure VI-1.

Aly
SWITCH RECEIVER RANGE UNIT

FIGURE VI-1 TYPICAL RADAR SYSTEM BLOCK DIAGRAM

TRANSMITTER

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Arthur A Little, Inc.

The angular accuracyin. radar is largely determined by the horizontal
radiated beam width. The antenna beam width, i.e., half-power point, is inversely
proportional to the horizontal dimensions of the antenna. It is this dimension
and the transmitted pulse width which determine the horizontal target resolution
of the system. Horizontal beam widths of 1-3° are most common for marine
radar equipment. Vertical beam widths of 15-40° are quitecommon. The larger
vertical widths are required where antenna stabilization is not used to prevent
echoes from becoming lost because of rolling and pitching of the vessel.

Radar systems display both a range to the point of interest and a map
of the surrounding area. Themap is produced by coordinating the rotation of the
sweep on the cathode -ray tube with the rotation of theantennabeam. Themap type
of display on the PPI is the equivalent of a large number of trilateration fixes if
the prominent reflection points of the area are known. In this type of operation,
a knowledge of the surroundings is used to fix the position of the radar.

The use of a meaningful PPI display requires high range resolution.
The over-all pulse length is important because it determines the minimum
spacing between discrete reflection points whichis necessary to produce separated
echoes on the screen. For PPI display purposes, radar pulses are made as
short as the rise and fall time will permit. Thus, range resolution as well as
angular resolution is important in the display of radar information on a radar
PPI. This resolution is dependent not only on the pulse length and beam width
but also on the minimum spot size on the PPI screen.

The limit of resolution attainable in radar systems depends on both the
pulse length and beam width of the system. Fast-rise-time pulses require that
the transmitter and receiver bandwidth, which is inversely proportional to the
pulse rise time, be wide.

Experimental radars with pulse lengths of a small fraction of a micro-
second, giving range resolutions of a few feet, have been built. In general,
their useful range is reduced to line of sight or less. Similarly, antennas with
beam widths of 0.1° which require an aperture of about 600 wave lengths have
been built.

The navigational use of radar generally requires a comparison of the
PPI display and an appropriate chart, whether supplemented or not by standard
radar views or photographs. A superposition or chart overlay method is prob
ably most effective in matching a chart to the screen. Generally the range rings
of the PPI display are matched to those of the chart. Some matching of chart
features to those of the PPI is also required.

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Arthur A AHittle Inc.

A second method of radar navigation and ship positioning requires the
use of transponders (as in Shoran) and reflectors positioned at known geograph-
ical points. Standard methods of triangulation are then used.

Dead reckoning is an essential factor in positioning vessels by the use
of radar, just as it is in conventional navigation.

Sea CCURAGY:

The accuracy of radar navigation is principally determined by the
characteristics of the radar set and the interpretation of its display. Navigational
aids in the form of either transponders or reflectors enhance the return signal,
making possible better signal match and interpretation. Range accuracies of 1
part in 2500 or better can be measured with modern radar equipment at ranges
out to about 50, 000 yards. Decreasing accuracy can be expected at ranges
greater than 50, 000 yards. A range precision of + 80 ft for 99.7% of the meas-
urements out to the maximum range of the parent radar equipment is practical
when a precision range unit is used. 3) Angular resolution of 1° can be expected
with most equipment if the PPI is accurately centered, parallax is avoided, and
the receiver gain is adjusted to give the narrowest bearing line.

Ranges of 10-15 miles can be expected with both 3 and 10 cm marine
radar under most conditions of use. Higher power levels and antenna height

can extend these surface ranges to 50 miles or more with some military equip-
ment.

REFERENCES

1. Radar Technique - Radio Aids to Navigation S.P. 39, Ch. 5, International
Hydrographic Bureau, Monaco.

2. L.N. Ridenour, Radar Systems Engineering, M.I.T. Radiation Laboratory
Series, Vol. I, McGraw-Hill Book Co., 1947.

3. See Alpine Precision Navigation System Model 430, pp. 138-142.

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Arthur DLittle Inc.

B. ALPINE PRECISION NAVIGATION SYSTEM MODEL 430

1. GENERAL

The Alpine Geophysical Associates Precision Radar Ranging Unit,
Remote Electrical Track Plotter, and X-band Radar Transponding Beacons were
developed for short-range precision navigation and ship-positioning problems.
This system utilizes, in conjunction with the standard shipboard radar trans -
mitter and modulator system the Model 430 precision timing and digital readout
equipment. The system is designed to operate with two or more fixed targets,
which may be prominent land features, buildings, or markers of known position.
Anchored reflector or transponder buoys may also be used. The precision
ranging unit is capable of providing accurately timed trigger pulses to the radar
transmitter and delay information to the radar PPI to provide for an expanded
display. The equipment provides ranging accuracies of + 80 ft with 99% prob-
ability at all ranges to the maximum range of the equipment.

2. DESCRIPTION

a. Precision Ranging Unit

The Alpine Model 428 Precision Radar Ranging Unit is operated in con-
junction with standard marine radar equipment such as the Decca D-11 series.
The Model 430 provides the precision timing required by utilizing a temperature-
controlled crystal oscillator with a frequency accuracy of 1 part in 10’. This
is divided down to the repetition rate of the radar by using a series of high-
stability multivibrator circuits and selection gates.

The outputs of the Model 430 are:

(1) A precision variable range marker fed to the radar display

(2) A digitally controlled step delay generating 1-mile incre-
ments for triggering the radar display

(3) A radar modulator trigger pulse
(4) Crystal-controlled markers for internal system calibration.
The Model 430 will function at ranges of standard radars from 0.75

mile to 50 miles. Its maximum accuracy is attained at the minimum ranges
indicated on most marine radar equipment.

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Arthur DHittle Inc.

The total range to target is controlled by the number of one mile incre -
ments set by switch positions on the range unit. This operation is initiated at
the Precision Ranging Unit, which introduces a delayed sweep trigger on the radar
display. For example, if the delay switch were set at 1 mile, the portion of the
sweep around the target would be linearly expanded so that a one-mile range
would cover the full radius of the radar display. This magnification reduces
the error associated with visual alignment of the target and the variable range
marker.

b. Remote Electrical Track Plotter

The Model 429 Precision Remote Electrical Plotter utilizes a pair of
synchro-controlled ball bearing mount screw boxes which change the length and
thus the position of the apex unit at the head of a set of precision lead screwrods.
The apex unit is caused to follow and mark the hydrographic or navigational track
by the operator as he follows target range changes at the ranging unit. The lead
screw boxes are set over and pivoted around points on the area chart which are
chosen as the operating targets. A solenoid-operated pointer automatically
marks the chart at a preset rate or may be manually operated.

c. Radar Transponding Beacon

The Model 427 Radar Transponding Beacon is designed primarily for
use as a precision radar target and operates in conjunction with a precision
radar surveying system. Because of its small size and low power consumption,
it is useful as a remote radar navigational beacon and aid, surface buoy trans -
ponder, etc. The transponder is capable of operating with any single pulsed
radar operating in the frequency band of 9300-9400 mc with a pulse repetition
rate of up to 2000 pulses per second.

In the quiescent mode of operation, the transponder operates in a
listening condition only. That is, the receiver is on and available to amplify
signals. In this mode the receiver draws 1/4 watt from the 12-volt dc supply.

Upon receipt of an X-band signal from an interrogating radar, a relay
circuit turns on the magnetron filaments. After a suitable warm -up time,
coded pulses are transmitted at a preset rate. After radar interrogation ceases ,
a time delay holds the transponder in an active condition for approximately 2
minutes and then allows the transponder to return to the quiescent condition .

A horizontally polarized omnidirectional antenna is used for both the
transmit and receive functions. A ferrite three-part circulator isolates the
transmitting and the receiving circuits.

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Arthur DHittle, Inc.

d. Radar Beacon Receiver

This separate receiver allows continuous viewing and variable mixing
of the radar and video signal on the PPI display. With this unit, it is practical
to operate the radar and obtain a picture of a target area and simultaneously
obtain a brightened spot on the target indicating the position of a transponding
beacon within the target area.

This system is adaptable to a standard radar. The electronic unit is
close coupled to the radar transceiver and is tied into the wave guide. A control
unit is mounted near the radar display. The control unit contains the necessary
adjustments for setting to the beacon frequency and spot brightening as required.

3. ACCURACY

The equipment has a fundamental instrumental accuracy of + 40 feet
as a maximum incremental error due to crystal characteristics and performance,
This standard of accuracy can be maintained up to maximum range, subject to
a satisfactory target being available. A fixed operation accuracy of + 80 feet
for 99.7% of cases is reported as the result of operational tests.

For radar to beacon antenna heights of 45 feet and 10 feet respectively,
strong contact can be maintained out to 10 n.m., steady response to 12 n.m.
and occasional response to 15n.m. Sea state and atmospheric conditions will
modify these ranges.

Strong contacts to beyond 30 miles have been documented. These
ranges have been repeated with no difficulty when the combined antenna heights
were 1000 feet.

4. SUMMARY

a. Precision Ranging Unit
(1) Type of system: precision ship -positioning and ranging
system utilizing ship radar equipment.

(2) Number of stations: two reflectors or transponding
beacons placed at either end of base line.

(3) Range: out to normal ranges of radar being used.

(4) Accuracy (instrumental): + 40 feet based on electronic
specifications .

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Arthur A. Little, Inc.

(5) Accuracy (operational): + 80 feet with 99% probability.
(6) Power required: 117 v,50-1000 cps, 100 watts.

Remote Electrical Track Plotter Model 429

(1) Plotter scale: 1" = 4000’ to 1" = 2000" or 1" = 8000"
by a simple gear change at the screw box. Special
ranges of 1" = 1000" are available.

(2) Accuracy of plot: + 5 feet at any range.

(3) Method of track marking: sequential dot marking,
either automatic or manual.

(4) Cable and interconnections: Plotter to control unit
requires single 12-conductor cable.

(5) Power requirements: 117 v, 60 cps, 250 watts.

Radar Transponding Beacon Model 427

(1) Frequency band: X-band,
(a) receiver = 9375 mc adj. + 50 mc.
(b) transmit = adj. 9100-9400 mc.

(2) Maximum pulse repetition rate: 2000 pps.
(3) Return pulse spacing: adjustable (3-19 millisec).
(4) Maximum peak power output: 100 watts.

(5) Antenna polorization: horizontal omnidirectional with
8° vertical beam width.

(6) Power requirements: 12 v, dc.
(a) Receiver = 1/4 watt (normal quiescent state)
(b) Transmit = 16 watts (when interrogated at 2000 pps).

(7) Warm-up time (approx.): 30 sec.

. Radar Beacon Receiver

(1) Frequency range: adjustable 9100-9400 mc to match
with transponder as required.

(2) Receiver mounting: close coupled to wave guide.

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Arthur A Little, Inc.

(3) Control unit size and mounting: 8" x 8" x 6"" mounted
near radar display.

(4) Power requirements: 110 v, 60 cps, 100 watts.

REFERENCE

Data furnished by Walter C. Beckman, President, Alpine Geophysical Associates,
Inc., Norwood, New Jersey.

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Arthur D.Aittle, Inc.

C. AUTOTAPE

Il. GENERAL

The Aeris II Autotape survey equipment was designed by the Cubic
Corp. as an outgrowth of its high-precision, electrotape, distance-measuring
equipment. The Autotape system is capable of automatic distance measuring
for both fixed and mobile situations. It uses omnidirectional or directional an-
tenna in determining distance from a mobile platform to two fixed responder
positions on a known base line. Range information accurate to 1 meter +10 ppm
times the measured range over ranges of 100 meters to 100 kilometers (62 miles)
is numerically displayed for visual monitoring by the operator. A voice com-
munication mode of operation between the Interrogator and each transponder is
used when initiating operations. A data output connection for external recording
or processing of range information is available with a BCD output suitable for
data processing. An Autotape plotter may be used at the Interrogator for a con-
tinuous plot of a moving platform in x-y coordinates.

2. DESCRIPTION

The Autotape system consists of a mobile interrogation unit and two
remote transponders located at either end of a fixed base line. (See Figure
VI-2.) In automatic operation a built-in program at the Interrogator controls
the Autotape Responders, measures the range to each Responder, and sequen-
tially presents each range on an integral digital display.

Separate carrier frequencies in the 10-cm (2900 - 3100 mc) band are
used for the Interrogator and each Responder. A precisely regulated crystal os-
cillator located at the Interrogator serves as a basic clock controlling all fre-
quencies. Responder transmissions are separated by frequency multiplexing
techniques which require only one antenna and one transmitter at the two- range
Interrogator which serves both Responders. This assures that both ranges are
measured from a single focal point at the Interrogator and allows both ranges to
be measured and displayed within 50 microseconds.

Distances are measured using electronic phase comparison techniques.
Three basic modulation frequencies are automatically sequenced, and a phase
comparison is made between transmitted and received frequencies at the Inter-
rogator. By a unique use of modulation frequencies, the Responder electronic
time delays are cancelled. The Autotape system then automatically measures
the rf propagation time, utilizes a preset average value for the index of refrac-
tion to correct the velocity of propagation, and displays the resulting range to

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Arthur D Little, Jue.

RESPONDER a

[ous
a

BASE LINE

INTERROGATOR
OMNIDIRECTIONAL
ANTENNA

FIGURE VI-2 AUTOTAPE RANGING DIAGRAM

144

each Responder station as a digital readout at the Interrogator. In this manner
positional ambiguities are eliminated when the position is initially known to with-
in 10, 000 meters.

a. Modes of Operation

Two basic modes of ranging operation are available. In the Automatic
trigger mode, the Autotape Interrogator utilizes a built-in program to measure
the range to each Responder and display it automatically. A nonambiguous range
is displayed on each of two digital readouts once each second. In the Fine, Inter-
mediate, or Coarse method of operation, the ranges will be measured and dis-
played at a rate of three times each second. At this high rate of operation, only
the last three digits of each range measured are presented:

(1) Fine = 0 to 100 meters with 10-cm resolution.
(2) Intermediate = 0 to 1000 meters with 1 meter resolution.

(3) Coarse = 0 to 10,000 meters with 10 meter resolution.

In the External mode of operation cycling times of less than one per
second are under the control of the operator. A Hold position is also available
where the display is locked to its last reading. Each of these modes has specific
applications dependent upon the conditions of operation.

b. Antenna Requirements

To provide flexibility of operation in the selection of range and area of
coverage both an omnidirectional antenna and a 60° beam horizontal horn have
been designed for use with the Autotape equipment. Operational ranges of 25 -
100 km are predicted when these antennae are used in proper combination at the
Interrogator and Responder stations. :

An rf unit is mounted integral with the antenna, making it possible to
position the antenna assembly away from the Interrogator or Responder by in-
creasing the length of the connecting cables. Equipment calibration does not
change with this arrangement.

c. Operation

All range measurements are initiated from the Interrogator unit after
the Interrogator and Responder close the radio link using the Talk Mode of oper-
ation. The operator at the Responder then tunes to receive the Interrogator

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Arthur DA Hittle, Inc.

frequency. Automatic frequency control networks integral with the equipment
maintain reception which gives continuous positional information at velocities
up to about 80 knots. Less accuracy could be expected at higher velocities.

After completing the acquisition each operator switches his unit to the
Measure Mode, where the internal program is used to range and display the data
automatically. No further operator attention or calibration is required, as the
measurement process is fully automatic. In the event of signal interruption the
measurement process automatically resumes when the signals are again available.

d. Auxiliary Output

An auxiliary data output is provided as a 20-line binary coded decimal
format which is compatible with standard data processing equipment. For in-
shore operation, a special design accessory plotter is available. This plotter
uses the two Interrogator ranges and converts them to an x-y plot for any pre-
set base line. Intermediate equipment is required for conversion of BCD to
an analog input to the plotter.

e. Power Requirements
The Autotape system is intended as a portable system. The Responders
are tripod-mounted and require 36 watts at 12 v dc. The two-range Interrogators
are table top-mounted and require 72 watts at 12 v dc. The radiated power out-
put of the Interrogator and Responder is approximately 200 mw.
3. ACCURACY
Two classes of error are inherent in the Autotape system, systematic
and random.
a. Systematic Errors
The systematic errors can be quite accurately determined and in
many cases eliminated. Errors due to variations in the propagation velocity of
rf energy and those due to reflection and refraction are in this group.
An instrumental accuracy of 50cm is achieved with omnidirectional
antennae at both the Interrogator and Responder sites at ranges out to 25 km,

provided line-of-sight transmission is maintained. The phase measurements
are converted directly to meters for an average index of refraction of 320N

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Arthur A. Aittle, Inc.

units, which is typical of most coastal areas. Using this value for the index,
one can make ranging measurements in most coastal areas with good line-of-
sight operation to an accuracy of +40 ppm. It is claimed that by making atmos-
pheric measurements at all three stations and properly averaging the computed
index of refraction, one can reduce the propagation velocity error to approxi-
mately +10 ppm. Thus the typical system accuracy achieved is +50 cm + 10
ppm times the measured range.

Errors can be caused by ground reflections and are governed by the
modulation frequency, the antenna beam width, and the ground characteristics.
Broad beam antennas increase the severity of ground reflections. The errors
which may be introduced at the lower modulation frequencies will tend to be
greater under certain conditions of high reflection. By using the more directive
antennas at the stationary sites and by using data averaging techniques, one can
reduce the errors due to reflection. For moving targets, computer data proc-
essing can provide accuracies approaching + 10 cm + 10 ppm of range.

Data averaging should be particularly useful where a mobile station
is hovering or fixed over one position for a period of time. With the Autotape
equipment locked in the Fine channel, a hover of 10 seconds will provide 30
two-range Fine readings for averaging. This is said to be sufficient to approach
a +10 cm system accuracy prior to addition of the propagation error.

b. Random Errors

Because of the digital measurement techniques used, “an increase in
measurement accuracy and long-term stability can be expected in comparison
with analog continuous display techniques. Some random errors such as oper-
ator error and instrument drift, may be minimized.

Ground reflection effects can cause readings to deviate by an amount
which is a function of the excess length of the indirect ray, the strength of the
ground reflection, and, most important, the relative phase of the microwave
carrier over the two paths. The effect is a swing or variation of readings about
the true reading, the amplitude of which is dependent upon the reflecting prop-
erties of the surface. Antenna heights of 200 ft or less should help to reduce
the swing error by reducing the grazing angle of propagated energy with the
surface of the terrain or water.

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Arthur A Little Inc.

4. SUMMARY

a. Type of System

(1) Precision ship-positioning and ranging.

(2) Number of stations required for navigation: two remote
transponder stations placed at either end of a base line.
The mobile vehicle contains a single Interrogator station
which automatically ranges to each transponder in sequen-
tial fashion.

(3) Carrier band: 3 cm (2900 - 3100 mc).
(4) Radiated power: 200 mw, all solid state circuitry.

(5) Antenna: omnidirectional or 60° beam width units integral
with equipment. Antenna and rf unit may be mounted up to
100 ft distant.

(6) Modulation frequencies (automatically sequenced):
Fine = 1.5 mc, ambiguities each 100 m
Intermediate = 150 kc, ambiguities each 1 km
Coarse = 15 kc, ambiguities each 10 km.

(7) Number of simultaneous users: single (system may be
expanded).

(8) Readout: illuminated five-digit display for each range
displayed simultaneously.

(9) Auxiliary outputs: 20-line BCD suitable for data processing
and x-y analog plotting equipment.

(10) Maximum range rate: 80 knots (for automatic operation).

(11) Integral voice transmit and receive facilities are provided
for check and calibration purposes.

(12) Power requirements:
Interrogator = 72 watts 6a @ 12 v de
Responder = 36 watts 3a @ 12 v de

(13) Operating temperature: -10 to +60°C.

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Arthur A. Hittle Inc.

b. Range and Accuracy

(1) Range: 100 m - 100 km with 60° coverage
100 m - 25 km with omnidirectional coverage.

(2) Accuracy: +50 cm -+ 10 ppm x range with correction for
the refractive index.

(3) Resolution: +10cm.

REFERENCES

1. L. G. Dameson, A New Microwave Distance-Measuring Equipment, Cubic
Corp., San Diego, California.

2. Aeris Mark II Automatic Electronic Ranging Instrumentation System, Docu-
ment P-63128A, Cubic Corp., San Diego, California.

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Arthur A. ALittle, Inc.

D. 'TELLUROMETER' - HYDRODIST MODEL MRB/2

1. GENERAL

The 'Tellurometer’ microwave system of distance measurement,
introduced in 1957, provides distance measurements to geodetic accuracy from
a relatively short range to line of sight (25 miles). These measurements can
be made under proper conditions to an accuracy of | part in 30,000. The align-
ment of the radio beams need be only approximate, and operation from a single
tower of minimum stability is practical where necessary. Problems in meas-
urement brought about by reflected radio energy are minimized both by the
relatively high frequency (10 cm band) and the specialized instrumentation
techniques utilized.

A more recently developed 'Tellurometer' type system (termed
Hydrodist) enables a fix for a moving vessel to be obtained as a function of two
continuously measured ranges. The master station is located on the moving
vessel and the remote stations are located at known points ashore. Accuracies
of + 1.5 meters at ranges out to 40, 000 meters (25 miles) are obtained under
optimum conditions.

2. DESCRIPTION

The basic 'Tellurometer' distance-measuring system was developed
principally for the measurement of useful distances to geodetic accuracy be-
tween two fixed points, the master station and a remote station. Two operators
are required, one at each instrument. The observations are made at the master
station, while the operator at the remote station performs the various switching
operations as instructed by the master station operator. A two-way voice com-
munications link is built into the equipment for this purpose. An antenna with
a parabolic reflector is located at each instrument and is directed toward the
receiving instrument. A 12-volt storage battery provides the necessary power
for portable equipment.

The Hydrodist system was developed from 'Tellurometer' for making
position measurements from a moving vessel at sea. Two master stations,
each with its own operator, are required aboard the moving vessel. Distance
measurements are continually made to each shore station (or buoys) placed at
known geographic positions within line-of-sight distances of the moving vessel.
These remote stations may be left unattended if they include a remote-controlled,
pattern-following auxiliary unit.

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Arthur A Little Inc.

The Hydrodist and the basic Tellurometer system utilize cw signals
radiated from the master stations. The signal is modulated by a pattern fre-
quency, received at the remote station, and reradiated as a similar wave with
more complex modulation.

The return waves are received at the master stations and their phase
modulations are compared with the outgoing phase. The phase is indicated ona
cathode-ray tube in the form of a circular trace in which a small break marks
the phase against a circular scale. A decimal] scale with 10 major and 100
minor divisions is used and is read to the nearest small division, which has a
value of one meter.

A cursor is attached to the cathode-ray-tube display and is manually
rotated to follow the position of the gap as a function of range. ‘The cursor is
mechanically connected to a counter which, after being set to the initial range,
will automatically follow the range in meters. A useful range of 20-25 miles
may be expected with this equipment.

3. ACCURACY

Hydrodist operates in the 10-cm band. Because this system uses
phase comparison methods to obtain the distances from the master to the remote
operating points, ambiguities must be resolved. Pattern switching is used for
this purpose. Three pattern or modulation frequencies are provided in Hydrodist.
They are manually switched, and digital counter readings are tabulated. Vernier
readings of transit time in millimicroseconds is quite practical.

The A pattern measures 100 meters for a complete rotation of the
cathode-ray-tube display. A resolution of | meter is practical. The A-C and
the A-D patterns have full scale ranges of 1,000 and 10, 000 meters, respec -
tively. No ambiguity resolution above 10,000 meters is provided, as it is re-
garded as certain that the vessel's position will be known within 10, 000 meters
(7 miles approximately). The automatic pattern-following device on the shore
stations provides a rapid check on ambiguities.

The computed transit time is based on a mean value of 1.000325 for
the refractive index of the atmosphere. A corrected value may be computed by
taking meteorological observations at both the master and remote stations.
With these corrections, the resultant accuracy of an individual line measure-
ment is almost totally a function of the instrument error plus a scale reading
error. After a number of fine readings have been taken and properly averaged
it is probable that a measurement accurate to about 1/3 meter can be achieved.

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Arthur A Aittle Inc.

For slow-moving systems of 20 knots or less manual switching of
modulation frequencies controlled by the master is satisfactory, providing the
remote switching keeps in step with the master. At higher speeds it is neces-
sary for ambiguity resolution to be achieved on a continuous recording-chart
system where the switching processes are automatically controlled from the
master. Automatic timing permits the interrogation for ambiguity resolution
to be repeated at regular adjustable time intervals and is useful to speeds in
excess of 100 knots.

Errors can be caused by ground reflections and are governed by the
modulation frequency, the antenna beam width, and the ground characteristics .
Broad beam antennas increase the severity of ground reflections. Errors intro-
duced by reflections at lower modulation frequencies will tend to be greater
under certain conditions of high reflection.

Ground reflection effects can cause readings to deviate by an amount
which is a function of the excess length of the indirect ray, the strength of the
ground reflection, and most important, the relative phase of the microwave
carrier over the two paths. The effect is a swing or variation of readings about
the true reading, the amplitude of which is quite dependent upon the reflecting
properties of the surface. Antenna heights of the order of 200 feet or less help
reduce the swing error by reducing the grazing angle of propagated energy with
the surface of the terrain or water.

4. SUMMARY

a. Hydrodist MRB/2

(1) Type of system: precision ship positioning and ranging.

(2) Number of stations required for navigation: two remote
stations at either end of a base line. Two master sta-
tions placed side by side on the vessel, each of which
continually ranges on its own remote station.

(3) Carrier band: 3 cm (2800 to 3200 mcps).

(4) Minimal frequency difference of master stations: 80 mcps.

(5) Length of base line: 10-20, 000 meters (nominal).

(6) Radiated power: 100 mw.

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Arthur A AUittle Inc.

(7)
(8)
(9)

(10)

(11)

(12)

(13)

(14)

(15)

Power requirement: 12 v or 24 vdc.

Range: 40,000 meters (25 miles).

Range (minimal): 125 meters, limited by overloading.
Accuracy: +0.33 - 0.50 meters with correction for

refractive index.

Antenna: 20° beam width conical (standard); others
available.

Pattern frequencies:

Master Remote
A pattern 1.49847 mcps A-1.49947 mcps
A+1 .49747 mcps
C pattern 1.48349 mcps 1.48249 mecps
D pattern 1.34862 mcps 1.34762 mcps

Readout: transit time in Nano seconds from master to
remote station indicated as circular trace on cathode-
ray tube and directly on mechanical or servo-driven
digital counter. Readout is provided directly in meters
and ambiguities are resolved in terms of 100, 1000, and
10,000 meters. In the A pattern one scale graduation
represents 1 meter of range and is readable to one-half
a graduation.

Auxiliary readout: digital display available (see below
MRC/12).

Integral voice transmit and receive facilities are sup-
plied at the master and remote stations and are used
as a functional part of the measurement process.

Auxiliary plotter: The Alpine Geophysical Corp. Model
429 Precision Remote Electrical Plotter may be used

and has a plotting accuracy of + 5 feet at any range.

Unit consists of Apex Unit at head of two lead screw rods.
As the operator follows the target range the screw

length and thus the position of the Apex unit properly
follows and indicates the track of the vessel. Gear

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Arthur DULittle, Inc.

changes allow the plotter scale to be changed at will
from 1" = 8000' to 1" = 4000' or 1" = 2000'. Special
gearing is available for 1’ = 1000’. A solenoid pointer
marks the chart automatically.

b. Hydrodist MRC/12

(1)

(2)

(3)

(4)

The MRC/12 is quite similar in function and operation to
its predecessor the MRC/2 and has additional digital read-
out and plotter equipment for automatic recording of
transit time.

Digital Display Unit type DDUI1: the unit is self-contained
and provides a continuous integrated readout of the two
ranges as a digital display. It is intended for table-top
mounting and may be mounted remotely from the measur -
ing instruments. Each of the Fine A readings is con-
tinuously displayed on a dial that is scaled 0-100. A
counter continuously integrates the A pattern rotations
and provides a direct readout of range.

(a) Input: 1-kc amplitude modulated sine waves
(b) Power: 1 amp at 24/27 v dc.

Recorder: the unit is two-channel thermal writing with
a polarized event marker indicating ambiguous phase
difference readings. The recorder pen moves from the
bottom to the top of the chart as, for example, the A
range changes from 0-50 meters. It moves from top

to bottom as the range increases from 50-100 meters.
An identical trace would be produced from top to bottom
as the range decreased from 50-0 meters, thus produc-
ing an ambiguous reading.

Ambiguity is resolved by direction of the relay-operated
event marker. Thus, the direction of the ambiguity pen

deflection, in combination with the reading trace, deter -
mines whether the range is increasing or decreasing.

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Arthur A Aittle Inc.

I

REFERENCES

"Radio Aids to Maritime Navigation and Hydrography, '' Ch. V, Supple-
mentary Paper No. 1, published by International Hydrographic Bureau,
Monaco.

'Hydrodist Model MRB2" Publication C-3, of Tellurometer Inc., 4435 Wis-
consin Avenue, N.W., Washington, D. C.

Comm. J. K. Mallory, "Hydrodist, '' Supplement to International Hydro-
graphic Review, Vol. 1, October 1960, pp. 57-62.

P, O. Fagerholm and A. Thunberg, ‘Some Accuracy Tests with Hydrodist
and Hi-Fix for Position Determination in Hydrographic Survey, '' Supplement

to International Hydrographic Review, Vol. 2, October 1961, pp. 9-27.

Private correspondence with Claire A. P. Duffie, Executive Vice President,
Tellurometer, Inc., Washington, D. C.

Hugh B. Loving, "Airborne Control System," Topographic Division, U. S.

Geological Survey, August 13, 1962. (Report on Hydrodist Application in
Airborne Control Survey Application. )

LSS)

Arthur DHittle, Inc.

E. SHORAN

1. GENERAL

Shoran, a navigation and positioning system developed by RCA, uses
radar principles for establishing an accurate fix. The original equipment was
designed with the intent of controlling aircraft during a bombing mission.

The inherently high accuracy of the Shoran fix has made the system
very useful as a control in hydrographic surveys at distances of 50 miles or
more from shore. It has been used at minimum ranges of the order of | mile.

The accuracy of the system has been measured by assuming a con-
stant velocity of signal propagation with a mean value of the refraction coeffi-
cient. Corrections in propagation velocity may be made by measuring the re-
fractive index and computing a corrected velocity of propagation.

The Shoran system utilizes radar transponders placed at known shore
sites at either end of a base line. Each transponder returns an amplified and
reshaped signal to the ship's radar receiver. An accurate and stable time
base converts the signal travel time to distance, which is read on a digital dial.
Returns from two or more transponders on the base line establishes a fix.

2. DESCRIPTION

A shipborne transmitter transmits precisely timed pulses toward the
shore stations. The signal is received at the shore stations, amplified, re-
shaped, and retransmitted. A shipboard receiver operating from the same
directional antenna as the transmitter demodulates and amplifies the return
signal. It is further processed in the indicator, and the elapsed time between
transmit and receive pulses is measured and converted to a one-way distance.
If the positions of the two ground stations are accurately known, then the posi-
tion of the ship can be determined. Arcs are drawn whose radii are equal to
the measured distances to the shore stations.

A single pair of intersecting arcs can give rise to ambiguity, as the
fix can fall on either side of a line bisecting the base line between the shore

stations. This ambiguity is resolved by following a known course and taking
additional fixes.

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Arthur D Little Inc.

a. Shipboard Equipment

Two distances measured simultaneously are required for a fix. The
transmitter aboard ship alternately transmits a pulse on two frequencies, one
for each ground station. The alternation rate between ground stations is about
10/second. The ground stations retransmit to the ship on a third frequency.
The ship's receiver indicator provides simultaneous and continuous indications
of the distances between the ship and the two ground stations.

The indicator unit contains circuitry for measuring the time of a
round-trip pulse and for displaying the transmitted and received pulses on the
circular sweep of a cathode-ray tube. The transmitted pulse appears as a fixed
marker pulse, and the received pulses appear at points on the circular sweep
dependent upon the distances from transmitter to receiver.

A phase-shifting method of pulse positioning is used as the measure
of the distance between the ship and the ground station. The pulses are matched
visually and read ona scale and vernier which are mechanically connected to
the phase shifter. As the ship moves away from the ground station, the phase
is advanced to permit coincidence of transmitted and received pulses. A phase
advance of 360° corresponds to a distance between transmitter and ground sta-
tion of 100 miles. Thus, the phase advance vernier repeats itself each 100
miles. It is, therefore, necessary that the observer know the ship's position
within 100 miles or so, in order to fix its position accurately.

The trace shown on the cathode-ray tube screen is circular, with a
reference pip at the top. The two shore station pips show elsewhere on the
trace. In making distance measurements, one aligns the two distance pips with
the marker pip. On the one-mile scale, for example, a circular sweep length
of about 6 inches corresponds to a distance of | statute mile. A resolution of
between 0.01 and 0.001 mile is possible using the scale and vernier. Indicator
range scales are 1, 10, and 100 miles.

b. Ground Station Equipment

The ground station equipment is designed to handle up to 20 interroga-
tions simultaneously and is, therefore, somewhat larger than the ship equip-
ment. Crystals at both ground stations are used to provide a continuous mutual
check on operations. These monitor crystals operate at a frequency of 93.109
ke, a cycle of which corresponds toa 1-mile loop time. Frequencies correspond-
ing to 1, 10, and 100 miles are also derived from this crystal.

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Arthur D.Little, Inc.

The ground station transmits a series of monitor crystal frequency
pulses which the shipboard operator uses for adjusting the ship station oscilla-
tor. These pulses appear on the indicator circular sweep as stationary or
slowly travelling pulses. The operator adjusts the pulses to a stationary posi-
tion and thus calibrates his shipboard equipment. ‘These pulses appear only on
the time base during a calibration period as selected by a panel switch.

The Operate-Monitor switch is also used to check the zero adjustment
of the ground station. Pulses originating at the ship station are received and
amplified at the ground station. The signal is divided and sent through two delay
lines, one of which is variable. By a matching process, the operator is able to
adjust the leading edge of the two pulses to coincide and thus adjusts the ground
station for the proper delay.

The transmitter at the ground station is similar to, but larger than
the shipboard transmitter. It need be capable of transmitting on only one fre-
quency (290-320 megacycles) and must be capable of answering to the pulses
from as many as 20 ships. The transmitted peak power is over 15 kw.

The ground station antenna system consists of two dipoles--one for
receiving and one for transmitting--mounted ona single 50 ft mast. Reflectors
are used to give directivity and antenna gain. This system is necessary for
working at distances greater than 50 miles.

Ground station power is normally supplied by two gasoline or diesel
engine driven generator sets. One set acts as a back-up for the other in case
of failure. The station requires 1500 watts of 400 to 2600 cycle 115-volt ac and
400 watts of 27-volt de.

3. ACCURACY AND RANGE

Two types of errors are inherent in the Shoran system: systematic
and random.

ale Systematic Errors

The systematic errors are those which can be precisely determined
and include errors resulting from the difference between Shoran and map dis-
tance and from the assumed velocity of the radio wave. Because of atmosphere
refraction and the elevation height of the antennas, the Shoran path is not a
straight line, but approximates the arc of a circle. ‘The elevation of the antenna
is the dominating factor. Usually with elevations less than 100 ft and distances
less than 100 miles the error is negligible.

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Arthur A Aittle, Ine.

A velocity of propagation is assumed to be 186, 218 statute miles/
second at 29.92 inches Hg, which is probably correct to one part in 18, 600.
While the effects of changes in barometric pressure are calculable, they are
negligible compared to other errors in Shoran equipment; a change of | inch in
pressure will change the velocity of propagation about 2 miles/second, which is
about 1 part in 100, 000.

b. Random Errors

The random errors cannot be eliminated. They are tabulated below
(in statute miles):

(1) Setting and reading mileage verniers: +0.002
(2) Nonlinearity of calibrated phase shift network: + 0.005
(3) Zero adjustment in ground station: +0.002

(4) Nonalignment of pulses due to insufficient gain
at long distances: + 0.050

It is not probable that all the errors will be accumulative at the same
time. The first and third listed are of variable sign and value and affect dis-
tance measurements within the line-of-sight distances from the ground stations.
All four affect the results when greater than line-of-sight distances are meas-
ured. Errors in excess of 0.050 statute mile have been noted in lines as long
as 100 miles. At the longer ranges the pulses are reduced in size and shape,
so that the error will be dominated by nonalignment of pulses at long distances
and the measured range will be too long.

The effects of the random errors is to give an uncertainty in position
corresponding to the magnitude of the errors and the angle at which the distance
arcs intersect. This uncertainty is illustrated in Figure VI-3.

Long experience indicates the areas of uncertainty to be negligible
when the angles of intersection are between 30 and 150°. ‘These limits are

often exceeded in surveys which extend along both sides of the base line and
its extension and at long range from shore.

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Arthur A Hittle, Inc.

Ss 'S S
' ~ » is
' — eas N
= . |
=e NN ) 3 /
I S65 ' ‘ \ :
\ = | \ | .
l >. a 1 » WY |
1 -10 METERS +10 M { -1IOM +10M HOM +10 METERS
1 Rim 1 ’ XN i] -
i Lae a a ae
1 sen OC ; ‘ \
eee ! A WA
5 |
i Wa oe
INTERSECTION ANGLE INTERSECTION ANGLE INTERSECTION ANGLE
40° 90° 120°

FIGURE VI-3 POSITION UNCERTAINTY DUE TO RANDOM ERRORS

c. Range

The range of the equipment can be accurately computed from:

BSS lly ah lly (1)

where
R = range in statute miles
h = height of transmitting and receiving antennas
k = a constant between 1.8 and 2

The constant k has been determined from experience and can be ap-
plied for all practical purposes where the distances do not exceed 100 miles
and the antenna heights do not exceed 2, 000 feet.

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Arthur A Aittle Inc.

4. SUMMARY

a. Type of System

(1) Pulsed phase-difference circular plot.

(2) Number of stations required: 2 shore stations,
l shipboard station.

(3) Length of base line: 10-50 miles.

(4) Operators required: at ground stations and on
board ship.

(5) Transmitter pulse width: 1/4 microsec.
rectangular.

(6) Transmitter pulse repetition rate: 930.09/second
(time interval between two pulses thus corresponds

to distance of 100 miles).

(7) Shipboard transmitter and antenna frequency range:
210-260 mc.

(8) Shipboard receiver and antenna frequency range:
290-320 mc.

(9) Ground station transmitter and antenna frequency
range: 290-320 mc.

(10) Ground station receiver and antenna frequency range:
210-260 mc.

(11) Shipboard and ground station peak pulse power level:
12-15 kw.

(12) Antenna systems: separate receiving and transmitting
dipoles required. Reflectors used on ground station
equipment where distances are greater than 50 miles.

(13) Frequencies generally used: 230, 250, and 310 mc.

(14) Alternating transmission rate between the two ground

stations: 10 times/second.

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Arthur DAHittle Inc.

I

(15) Number of ships handled by ground stations: up to
20 ships simultaneously per group of ground stations.

(16) Readout: cathode-ray tube with 6-inch circular sweep.
Operator superimposes pulses and reads distance on
a digital readout to a resolution of 0.01 to 0.001 statute
mile.

(17) Power requirements for transmitter and receiver:
115 v ac, 400-2600 cps, at 1500 watts
27 v de at 400 watts.

l0)< Range and Accuracy

(1) Usable service distance: 25-75 statute miles.

(2) Approximate accuracy of distance measurement: 30-60 feet
except near extreme limits of range.

(3) Accuracy of LOP: dependent upon absolute magnitude of
errors and angle at which distance arcs intersect. Area
of uncertainty is negligible when angles of intersection
are between 30 and 150°.

REFERENCES

Cmdr. Clarence A. Burmister, "Electronics in Hydrographic Surveying, "
Journal of the Coast and Geodetic Survey, January 1948.

Lt. Emerson E. Jones, “Shoran Study and Calibration, '' Journal of the Coast
and Geodetic Survey, April 1949.

Donald A. Rice, ''Geodetic Application of Shoran, " Journal of the Coast and
Geodetic Survey, April 1950.

Capt. Gilbert R. Fish, Electronic Control Systems used in Hydrographic
Surveys, Coast and Geodetic Survey.

Thomas J. Hickley, Radio Wave Propagation as Applied to Shoran, Coast
and Geodetic Survey.

162

Arthur A. Uittle, Inc.

EF. HI-FIX

1. GENERAL

The Hi-Fix system was developed by the Decca Navigator Company,
Ltd., as a high-precision, lightweight, portable, position-fixing system.\’/ It is
a single-user system designed for hydrographic, geophysical, and other survey-
ing and tracking operations where an accuracy of a few feet is required at ranges
as great as 100 nautical miles.

Hi-Fix is a phase-difference system and may be operated in either
the hyperbolic mode, which requires three transmitting stations ashore (master
and two slaves), or in the ranging mode, which uses two slave transmitters
ashore and a master timing oscillator and transmitter aboard the navigating
vessel. Time-multiplexing is used on a common carrier frequency of about
2mc. The slave stations may operate unattended in the Hi-Fix system.

The position is displayed to the navigator in digital format on two
counters. Supplementary display and automatic plotting equipment is available.

2. DESCRIPTION

This system utilizes closely synchronized, phase stable, cw frequency
transmission from the master and the two slave stations. Each station trans-
mits sequentially on the same frequency; the timing is controlled by the master
oscillator and other associated circuitry. As illustrated in Figure VI-4, the
slave 1 and slave 2 transmissions are keyed by the master trigger signal with
a 0.3 and 0.6 second delay, respectively. Using a time-sharing system and a
common frequency of operation makes it a simple matter to change the frequency
of the Hi-Fix chain. Five operating frequencies are available, and a frequency
selection is made by the operator at the master station.

a. Transmitter Unit

The master oscillator unit provides the drive signal for the master
transmitter. At the slave stations the controlling receiver provides the input
for the slave station transmitter, which is identical to the master station trans-
mitter. The transmitters are portable, are rated at 25 watts, and are gener-
ally located close to the antenna. The antenna is a guyed portable mast ap-
proximately 30 feet in height. A ground plane is generally required for each
shore station antenna to obtain stable and reliable transmission to ranges beyond
line of sight.

163

Arthur D.Little Inc.

SECONDS
[tRiccer |

f MASTER |

SLAVE |

FIGURE VI-4 HI-FIX TIME-SHARING OF MASTER AND
SLAVE TRANSMISSIONS

b. Receiver Unit

The receiver is used as a position-fixing instrument aboard the navi -
gating vessel in the hyperbolic system, which places the master and the two
slave stations ashore. In the ranging mode the master station and receiver are
placed aboard the navigating vessel and each slave station is located at the end
of a base line ashore. The slave station receiver is required to hold the phase
of the slave transmission at a constant and predetermined relationship with re-
spect to the master.

With the navigator's receiver in the operate mode, the incoming
1900 kc (approximately) signal from the master and the two slave stations is
converted to an intermediate frequency of 132 kc. In addition to the phase-
sensitive cw transmissions, the trigger signals from the master station are
also received. These pulses are extracted from the intermediate frequency
output to activate circuitry which gates the two digital display circuits. Using
master timing pulses in this manner allows the digital display for each channel
to be activated only during the proper slave transmission, as illustrated in
Figure VI-4.

164

Arthur OD. Little, Inc.

The phase comparison system uses a phase discriminator to compare
the phase of the master oscillator with that of each slave station and displays
this difference on a goniometer dial in terms of lanes and fractions of lanes.
Each of the two goniometers mounted on the receiver panel makes one revolution
per lane or phase -difference cycle, and each is capable of driving various other
displays. The goniometer has an accuracy of about | degree of phase, thus pro-
ducing little error due to nonlinearity. The two lane counts are displayed on
digital counters accommodating 999.99 lanes.

The use of an identical frequency of transmission by the master and
both slave stations frees the system from differential phase errors due to ther-
mal or other causes in the two halves of the phase-comparison circuit.

With Hi-Fix type A no means of coarse positioning is provided, and
the navigator must keep track of lanes with respect to a known Starting point.
Lane identification can be provided by a system known as Hi-Fix type B. With
this system additional receiver -transmitter units are placed at each station,
and a second grid is generated. In this manner automatic and continuous lane
identification is provided.

3. ACCURACY

The Hi-Fix system can generate either a hyperbolic or a circular
pattern. The circular coordinate system has the advantage of a constant lane
width with increasing range. The lane width of the system is about 250 feet,
and the instrument accuracy corresponds to about 0.01 lane. The patterns gen-
erated are illustrated in Figure VI-5, where the relative accuracy of the sys-
tem using the two patterns is indicated.

The working range is dependent largely upon the sight and the atmos -
pheric noise level. Typical operating distances between Hi-Fix transmitters
and receivers are 5-35 miles, but ranges of 100 - 130 miles can be obtained.

With Hi-Fix set up as a hyperbolic system, one series of tests
indicated system accuracy to be about +0.05 lane, which is equivalent to be-
tween +10 -40 feet. For this case the transmission path was across both land
and water. Rather large systematic errors can be expected for this situation
where the propagation velocity is dependent upon the electrical conductivity of
the terrain and proper corrections are not applied. When these measurements
were repeated from the same stations for paths over water, the standard devia -
tion for readings was of the order of +0.01 - 0.02 lanes which is equivalent to
a positional accuracy of between 2.5 and 7 feet.

165

Arthur A AULittle, Inc.

The system can be calibrated at any time by using an internally
generated phase datum contained in each receiver. Thus each operator can
adjust his receiver at will to obtain the same fractional lane reading at a point
of given location, without prior calibration at that point.

SLAVE

SLAVE

HYPERBOLIC CIRCULAR

FIGURE VI-5 TYPICAL RELATIVE ACCURACY CONTOURS FOR
HYPERBOLIC AND CIRCULAR PATTERNS

166

Arthur A. Little Inc.

4. SUMMARY

ae Type of System

(1) Mode of operation: hyperbolic or ranging.
(2) Frequency: one frequency per chain in 1.7 - 2.0 mc band.
(3) Operation: time-multiplexing of single frequency.

(4) Number of frequencies available: 5 in l .7 - 2.0 mc band,
selected by operator.

(5) Type of transmission: cw.
(6) Sampling rate: one/second.

(7) Time -multiplexing trigger signal: 60 cps in master trans -
mission, lasting 0.1 second.

(8) Radiated power: 10 watts (approximately).
(9) Power required: 24 v @ 300 w (approximately) .

(10) Personnel requirements: Master station can operate un-
attended, slave stations require one nontechnical attendant
each.

b. Range and Accuracy

(1) Range: 40-100 miles, dependent upon ground conductivity.

(2) Accuracy: Over water, 0 = +0.01-0.02 lane, which is
equivalent to about +2.5-7 feet. Over combination land
and water, o = £0.05 lane, which is equivalent to + 10 -

40 feet.

REFERENCES
1. Technical Data Sheet No. $4, Decca Navigator Co., Ltd., February 1960.

2. P. O. Fagerholm and A. Thunberg, "Some Accuracy Tests with Hydrodist
and Hi-Fix for Position Determination in Hydrographic Survey, "" Supplement

to the International Hydrographic Review, Volume 2, October 1961.

167

Arthur D.ULittle, Inc.

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PROJECT TRIDENT TECHNICAL REPORTS

Report No.

1011260 COLOSSUS I, December, 1960 (C)

1021260 THEORETICAL INVESTIGATION OF CROSS-FIX PROBLEMS
AND CORRELATION EFFECTS, December, 1960 (C)

1031260 THE SUBMARINE AS A SURVEILLANCE PLATFORM,
December, 1960 (S)

1041260 Title Classified, December, 1960 (S)

1051260 AIRBORNE JEZEBEL, December, 1960 (S)

1061260 SURFACE -SHIP SONARS IN OCEAN-AREA SURVEILLANCE,
December, 1960 (S)

1071260 Title Classified, December, 1960 (S)

1080361 LOW -POWER ENERGY SOURCES, March, 1961 (C)

1090561 SOLUS, May, 1961 (C)

1100561 NONACOUSTIC METHODS FOR SUBMARINE DETECTION,
May, 1961 (S)

1110561 ARTEMIS, May, 1961 (S)

1120561 COLOSSUS II, May, 1961 (S)

1130961 RELIABILITY OF UNATTENDED ELECTRONICS EQUIPMENT,
September, 1961 (U)

1141061 NUTMEG, October, 1961 (S)

1150162 DEEP JULIE, January, 1962 (S)

1160262 METHODS FOR ANALYZING THE PERFORMANCE OF DIS-
TRIBUTED FIELDS OF DETECTORS, February, 1962 (C)

1170262 MAGNETIC ANOMALY DETECTORS IN FIXED SHALLOW

WATER BARRIERS, February, 1962 (S)

169

Arthur D.Little Inc.

Report No.

1180262 ELECTRICAL CONDUCTIVITY, COMPRESSIBILITY, AND
VISCOSITY OF AQUEOUS ELECTROLYTIC SOLUTIONS,
February, 1962 (VU)

1190462 A FEASIBILITY STUDY OF THE PASSIVE DETECTION OF
QUIET SUBMARINES, April, 1962 (S)

1200562 Title Classified, May, 1962 (S)

1210562 RADIATED NOISE CHARACTERISTICS OF DIESEL -ELECTRIC
SUBMARINES, May, 1962 (C)

1220562 DIRECTIVE RECEIVING ARRAYS, May, 1962 (C)

1230662 ANALYTICAL BACKGROUNDS OF COMPUTATIONAL METHODS
FOR UNDERWATER SOUND PROPAGATION, June, 1962 (U)

1240762 MARINE CORROSION AND FOULING, July, 1962 (UV)
1250862 SURVEY ON AMBIENT SEA NOISE, August, 1962 (C)
1260862 DEEP SUBMERSIBLE WORK VEHICLES, August, 1962 (C)
1270862 THE EFFECT OF PRESSURE ON THE ELECTRICAL CON-

DUCTIVITY OF SEA WATER, August, 1962 (VU)

1281262 ENGINEERING PROPERTIES OF MARINE SEDIMENTS,
December, 1962 (U)

1291262 AN INTRODUCTION TO MODULATION, CODING, INFORMA-
| TION THEORY, AND DETECTION, December, 1962 (U)

1300363 SPHERICAL DIRECTIVE ARRAYS: A PRELIMINARY STUDY,
March, 1963 (U)

1310363 ESTIMATES OF SUBMARINE TARGET STRENGTH, March, 1963 (C)

1320363 PHYSICAL CHEMISTRY IN THE OCEAN DEPTHS: THE EFFECT
OF PRESSURE ON IONIC TRANSPORT PROCESSES AND EQUIL-
IBRIA, March, 1963 (U)

1330563 SUBMARINE CABLES AND REPEATERS, May, 1963 (C)

1340663 APPLICATION OF ADAPTIVE SAMPLING STRATEGIES TO THE
PLANNING OF SURVEYS, June, 1963 (U)

170

Arthur DHittle Inc.

Report No.

1350663

1360863

1370863

1380863

1390963
1400963

1411163
1421163
1430264
1440464

1450564
1460764

1470764
1480864
1491064

1501064

CURRENT OPTICAL DATA PROCESSING TECHNIQUES -
ASW SYSTEMS, June, 1963 (S)

ACOUSTIC SCATTERING IN THE OCEAN, August, 1963 (U)
STRESS ANALYSIS OF SHIP -SUSPENDED HEAVILY LOADED

CABLES FOR DEEP UNDERWATER EMPLACEMENTS,
August, 1963 (U)

RADIATED UNDERWATER NOISE OF SURFACE SHIPS,
August, 1963 (C)

LARGE PROJECTORS, September, 1963 (S)
APOJI, September, 1963 (S)

ANALYSIS AND EVALUATION OF PROPOSED ACTIVE/
PASSIVE FIXED, OCEAN SURVEILLANCE SONAR (RSR -Z) (S)

ENGINEERING MATERIALS FAILURES IN UNDERWATER
SONAR PROJECTORS, November, 1963 (U)

COMMAND AND CONTROL IN LARGE OCEAN AREA ASW
SURVEILLANCE SYSTEMS, February, 1964 (S)

STATISTICAL ANALYSES OF OCEAN TERRAIN AND CONTOUR
PLOTTING PROCEDURES, April, 1964 (U)

Title Classified, May, 1964 (S)
TARGET CLASSIFICATION WITH ACTIVE SONARS, July, 1964 (C)

COMPUTER PROGRAM FOR ACOUSTIC RAY TRACING,
July, 1964 (UU)

THE VERTICAL DIRECTIONALITY OF AMBIENT NOISE IN THE
DEEP OCEAN AT A SITE NEAR BERMUDA, August, 1964 (U)

TEMPORARY LIMITED AREA SURVEILLANCE WITH PASSIVE
SONOBUOYS, October, 1964 (C)

OPTIMUM SIGNAL DESIGN AND PROCESSING FOR
REVERBERATION-LIMITED ENVIRONMENTS (U)

171

Arthur D. Little Inc.

No. of Copies

10

10

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Department of the Navy
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Commanding Officer and Director

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Fort Trumbull, New London, Conn.
ATTN: Mr.H. E. Nash

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Department of the Navy
Washington 25, D.C.

Director
U.S. Naval Research Laboratory
Washington 25, D. C.

ATTN: Dr. H. Saxton

Chief, Bureau of Naval Weapons
Department of the Navy
Washington 25, D.C.

ATTN: Mr. I. H. Gatzke

Commanding Officer
U.S. Naval Air Development Center
Johnsville, Pa.

ATTN: Mr. R.I. Mason

Commanding Officer and Director
U.S. Navy Electronics Laboratory

San Diego 52, California
ATTN: Dr. D. A. Wilson

173

Arthur D. Little Inc.

No. of Copies

2

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U.S. Pacific Fleet

Navy No. 128, c/o FPO

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Institution of Oceanography
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Technical Library (Code P80962)
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Building #1, Treasure Island
San Francisco 30, California

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U.S. Atlantic Fleet
Norfolk 11, Virginia

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Research Detachment
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New York, N. Y.
ATTN: Mr. Robert Martin

Hudson Laboratories
P.O. Box 239

Dobbs Ferry, N. Y.
ATTN: Dr. Allan Berman

174

Arthur D. Little, Frc.

No. of Copies

1

President
Naval War College
Newport, Rhode Island

Commander

Destroyer Development Group
U.S. Atlantic Fleet

Newport, Rhode Island

Director of Research
Institute of Naval Studies
545 Technology Square
Cambridge 39, Mass.

Chief

Office of Naval Material

Washington, D.C. 20360
ATTN: MAT 322

Defense Documentation Center

Cameron Station
Alexandria, Virginia

175

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Arthur D.Little Inc.

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