Historic, archived document

Do not assume content reflects current
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US D A United States

=————.__ Department of
MQ Agriculture

Forest Service

Pacific Northwest
Research Station

Research Note
PNW-RN-533
December 2002

Abstract

Introduction

Site Index

What Is Site Index?

o

meen

Site Index Equations and Mean
Annual Increment Equations
for Pacific Northwest Research
Station Forest Inventory and
Analysis Inventories, 1985-2001

Erica J. Hanson, David L. Azuma, and Bruce A. Hiserote’

Site index equations and mean annual increment equations used by the Forest
Inventory and Analysis Program at the Portland Forestry Sciences Laboratory, Pacific
Northwest Research Station, Forest Service, U.S. Department of Agriculture. The
equations are for 24 tree species in California, Oregon, and Washington.

Keywords: Site index equations, mean annual increment equations.

The Forest Inventory and Analysis Program (FIA), a program within the Pacific North-
west Research Station (PNW), USDA Forest Service, is mandated to inventory, assess,
and report on several forest characteristics, traditionally timberland area and volume,
on all forested lands in the United States (public and private). This document presents
the site index equations and mean annual increment equations used for tree species
within the PNW-FIA forest inventory area of California, Oregon, and Washington in
order to document the past and present inventories.

The PNW-FIA used equations from many documents to obtain a site index value and
mean annual increment for every forested inventory plot. This set of equations has
been used since the 1980s inventories; equations used before then are no longer
used. Specifically, this set was used for periodic inventories in Oregon (1985, 1995,
and 1998), Washington (1988, 1990, and 2000), and California (1991).

Site index is a measure of a forest’s potential productivity. Site index is usually defined
as the height of the dominant or codominant trees at a specified age in a stand. It is
calculated in an equation that uses the tree’s height and age. Site index equations
differ by tree species and region.

’ Erica J. Hanson is a forestry technician, David L. Azuma is a
research forester, and Bruce A. Hiserote is a forester, Forestry
Sciences Laboratory, P.O. Box 3890, Portland, OR 97208-3890.

Using Site Index

Miscellaneous Notes
on PNW-FIA Site
Indexes

Forest mensurationists develop site index equations through fieldwork and analysis of
data. First, they establish research plots in stands of a particular tree species covering
a range of site conditions. They select representative dominant or codominant trees

and measure their heights, ages, and diameters. Site index curves are constructed by
using the tree heights at a base age, typically 50 or 100 years in the West, usually for
trees in even-aged stands. An equation is derived from the curves to estimate the site
index when an individual tree’s age is not the same as the base age. Site index equa-
tions are developed either by following a stand through time (King 1966) or comparing
several stands of different ages at a single point in time (McArdle and others 1961).

Site index can help predict timber productivity, wood volume, and potential rate of growth
of a forest. Forest managers use the site index to evaluate the quality of their land.

For PNW-FIA, the site index was used primarily as input to the mean annual increment
(MAI) equations, which in turn were used to develop the site classes: six classes of
volume growth per acre at culmination in fully stocked natural stands. The area was
reported by site class in a table, “Area of timberland, by cubic-foot site class and
owner class,” in resource bulletins for each inventory (see Waddell and Bassett 1997
for an example). Another use was to separate “timberland” plots from “other forest-low
productivity” plots (formerly called “noncommercial unproductive forest land”), based
on whether the site can produce 20 cubic feet * acre! « year’. The PNW-FIA also
used the site index to calculate annual squared diameter growth if the previous diame-
ter was unavailable (to obtain annual volume growth), and to calculate projected and
estimated tree heights (to obtain missing growth components). Other researchers used
the PNW-FIA site index of plots for growth predictions.

Some equations may have limitations owing to the method used to construct the site
index curve or equation. Discussion of the different methods, and a summary of the
modeling approach and number of trees sampled in most of these cited sources, can
be found in Hann (1995).

Mixed conifer—Large areas of California forests had no main softwood tree species
as the forest type, but instead were classified as mixed conifer. The PNW-FIA defined
a mixed-conifer site as one within a certain region and capable of greater than 70
percent conifer stocking, and that had certain tree species predominating. In general,
these plots had some mix of ponderosa pine, Jeffrey pine, sugar pine, Douglas-fir, red
fir, Shasta red fir, incense cedar, and white fir (see app. 1 “Names of Trees” for scientific
names). Mixed-conifer types grow on the east-facing slopes of the Coast Range, on the
west-facing and higher elevation east-facing slopes of the Cascade Range and Sierra
Nevada, and can extend into southern California.

Black cottonwood—No site index equation was available for black cottonwood, so a
site index value for use in MAI equations and stocking values was developed in-house
by using data from plots in cottonwood stands.

PNW-FIA Site Tree
Selection Procedures

McArdle’s and King’s site index equations—In 1930, Richard E. McArdle and
Walter H. Meyer published the first set of site index curves for Douglas-fir in the
Pacific Northwest (McArdle and others 1961). In 1966, James E. King published a
new set to account for changes since then: shorter rotations, younger trees, and
improved methods of constructing curves (King 1966). In the coastal Douglas-fir
region, PNW-FIA preferred the King site index equation for Douglas-fir. However,
King’s method required at least 25 mainstand trees within an area not larger than a
130-foot-diameter circle. If that amount of stocking was not present on or near the
plot, the field crew used the McArdle site index equation and selection method.

e McArdle selection method for PNW-FIA: Select three dominant, suppression-free
trees that were greater than 50 years old.

e King selection method for PNW-FIA: If the stand was over 30 years old, locate an
area no greater than a 130-foot-diameter circle that contains 25 mainstand trees,
not younger or shorter than the general canopy. From the 25 trees, select the 5 with
the greatest diameter at breast height. If the stand is aged 15 to 30 years old, select
the 10 with the largest diameter out of 50 trees. King’s is only used in stands less
than 130 years old and below 3,000 feet in elevation.

Dunning’s site index conversion—The PNW-FIA used Dunning’s site index for
mixed-conifer plots in California. Other site index values used by PNW-FIA needed to
be converted to Dunning’s site index so they could be used as a variable in the plant
stockability factor equations (see MAI section below). The following conversion equa-
tions were used if the site index taken for the plot was not Dunning’s:

Site index equations Conversion equations
1 (King) and 5 (Wiley) DSi= 3107 x GIe?)
4 (Herman) and 8 (Barrett) IDS = 1.54b se (SE?)
7 (Krumland), 16 (M.C.), and 17 (Schumacher) ID Sit ALTE! se (SIO)
9 (Dahms) DSI = 1.75 x (SP)

where: DS/ = Dunning’s site index, and
S/ = site index in feet.

Equations from other regions—Some equations were developed outside of the
PNW-FIA region, such as site index equation no. 6 for Engelmann spruce in the north-
ern and central Rocky Mountains (Brickell 1966). Because no similar site equation
existed for Oregon or Washington, it was used for Engelmann spruce in this region.

Site trees were selected and measured on every forest land plot (10 percent or more
stocked by trees), and when possible on “western woodland types” forest (5 percent
or more stocked by juniper or other nontimber species). Since 1991, PNW-FIA
mapped and collected plot data based on the “condition class” encountered on the
plots. Although this sometimes resulted in more than one forested condition class on
a single plot, site trees were collected across the plot, and only one site index was
assigned to the plot. It was not believed that site varied over the area of the plot.

Table 1—Site index equation assignments

Site index equation

group number

1

{
1

—_,

OOWDWDWOAONDaAAARA AHA HWW PY

WOR = western Oregon.

Species Area

Douglas-fir WOR except Jackson and Josephine
Counties

Douglas-fir WWA except in silver fir zone

Douglas-fir CA except in mixed conifer

Grand fir WOR except Jackson and Josephine
Counties

Grand fir WWA, CA

Western white pine WWA

White fir

Douglas-fir

Grand fir

White fir

White fir

Noble fir

Shasta red fir
Pacific silver fir
Subalpine fir
Mountain hemlock
Western hemlock
Sitka spruce
Engelmann spruce
Redwood
Ponderosa pine
Jeffrey pine
Coulter pine
Bishop pine
Lodgepole pine
Western white pine
Western red cedar
Black cottonwood
Fremont poplar
Western larch

Red alder

Other hardwoods
Douglas-fir
Douglas-fir

Grand fir

White fir

Western larch
Western white pine
Mixed conifer

WOR except Jackson and Josephine
Counties

Jackson and Josephine Counties in WOR

Jackson and Josephine Counties in WOR

Jackson and Josephine Counties in WOR

CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, WWA, CA

All WOR, WWA, CA

All WOR, EOR, EWA, WWA

All WOR, CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, CA

CA

CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, CA

All WOR, EWA, WWA ,CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, WWA, CA

All WOR, EOR

All WOR, EOR, EWA, WWA, CA

All WOR, EOR, EWA, WWA, CA

WWVA in silver fir zone

EOR and EWA

EOR and EWA

EOR and EWA

WWA and EWA

EWA

CA

Red fir, Shasta red fir CA

WWA = western Washington.

EOR = eastern Oregon.

EWA = eastern Washington.

Site Index
Equations

On new plots, as of 2001, data from at least 3, and sometimes 5 or 10, site trees
were collected, depending on the size of the trees and the selection method used.
On western woodland types, data from at least one were collected (if the species was
juniper). When a crew revisited a plot, they measured one new site tree, and some-
times remeasured the previous site trees if they were in the lower age range, and a
new site index was calculated for the plot.

A good site tree was a tree that was classified as a dominant within the stand (unless
King’s was used, which took the five with largest diameter), had never been sup-
pressed, and had a normally formed top. The species should represent the forest
within the sampled condition, with the preferred site species in western Oregon,
western Washington, and northwestern California being Douglas-fir. Trees aged 50
years and older (King’s method: 30 years) were desirable, but it was not always possi-
ble to obtain them, and younger trees could be measured. In California, the species
and site equation also were determined by whether the plot was in the mixed-conifer
type, which depended on the county, elevation, and percentage of conifer stocking of
the stand.

Table 1 shows which site index equations were used for species and area.

For all equations:

H = height in feet,
IP = natural exponent, and
Ln = natural log.

1. Douglas-fir and grand fir in western Oregon except for Jackson and Josephine
Counties. Douglas-fir and grand fir in western Washington except in silver fir zone.
Western white pine in western Washington. Douglas-fir (except in mixed-conifer
stands) and grand fir in California (King 1966).

a. If King’s selection method was used to select site trees (only Douglas-fir and grand

2500
SI, = A?
(H — 4.5) + 0.954038 — 0.0558178A + 0.000733819A2
0.109757 + 0.00792236A + 0.000197693A2

+ 4.5,

fir could be used), use:

where
Sli, = King’s site index in feet for breast height age 50 years, and
A =_ breast-height age.

? Field instructions for the annual inventory of Oregon and
California, 2001. Version 1.5. 342 p. On file with: USDA Forest
Service, Pacific Northwest Research Station, Forest Inventory and
Analysis Program, Forestry Sciences Laboratory, P.O. Box 3890,
Portland, OR 97208-3890.

b. For Douglas-fir and grand fir, if King’s selection method was not used and trees
were < 40 years old, use the following to obtain McArdle’s site index (equation derived
from McArdle and others 1961). This equation also was used for western white pine in
western Washington when age < 40 years.

STy = [EXP {3.3 — [0.8Ln (A)]}] (0.96H — 2.66) ,

where
Sly = McArdle’s site index in feet for breast-height age 50 years, and
A = breast-height age.

c. For Douglas-fir and grand fir, if King’s selection method was not used and trees
were = 40 years old, use the following to obtain McArdle’s site index (equation derived
from McArdle and others 1961). This equation also was used for western white pine in
western Washington when age = 40 years.

STy = [EXP {2.1 — [0.47Ln (A)]}] (0.96 — 2.66) ,

where
Sly = McArdle’s site index in feet for breast-height age 50 years, and
A = breast-height age,

McArdle’s site index was converted to King’s site index by the equation from King
(1966):

ST = 21.5 — 0.18127(A + 8) + 0.72114 SI,
where
A breast-height age,

Slik = King’s site index, and
Sly McArdle’s site index.

2. Douglas-fir in Jackson and Josephine Counties, Oregon (Cochran 1979b).

ST = 84.47 —-AB + B(H - 4.5) ,

where

A = _ EXP { —0.37496 + 1.36164Ln (a) — 0.00243434 [Ln (a)]*} ,
B= 0.52032 - 0.0013194 a + 222823

SI =_ site index in feet for preset Teche age 50 years, and

a = breast-height age.

3. White fir and grand fir in Jackson and Josephine Counties, Oregon (Cochran
1979c).

SI = (Hl — 4.5) EXP(X1) — EXP(X1 + X2) + 89.43 ,

where
X1 = 3.8886 - 1.8017 Ln(A) + 0.2105 [Ln(A)]/?
—0.0000002885 [Ln(A)]? + 0.000000000000000001187 [Ln(A)]*4 ,
X2 = -0.30935 + 1.2383 Ln(A) + 0.001762 [Ln(A)]*
-0.0000054 [Ln(A)]°? + 0.0000002046 [Ln(A)]"! — 0.000000000000404 [Ln(A)]!8 ,
S/ = _ site index in feet for breast-height age 50 years, and
A = breast-height age,

4. Noble fir, Shasta red fir in Oregon, subalpine fir, white fir, Pacific silver fir, and
mountain hemlock (Herman and others 1978).

Note: For California, when white fir was found in mixed-conifer stands, the mixed-
conifer site index equation was used.

a. For site trees 100 years or less:

SI = [4.5 + 0.2145 (100 — A) + 0.0089 (100 — A)?]

x 1.0 + 0.00386 (100 — A) + 1.2518 (100 — A)?

ae (H-4.5) ,
where
S/ = _ site index in feet for breast-height age 100 years, and
A = breast-height age.
b. For site trees > 100 years:
1 0.5 1 2
SI = |~ 62.755 + 672.55 a +| 0.9484 + 516.49 ee, | (H — 4.5)
+| — 0.00144 + 0.1442 (+) (H- 4.5),

where
S/ = _ site index in feet for breast-height age of 100 years, and
A = breast-height age.

5. Western hemlock and Sitka spruce (Wiley 1978).
a. For trees < 120 years in age:

[(H — 4.5) (0.1394 + 0.0137A + 0.00007A2)]
SE 2500 aan ee ee Ee
[A? — (H — 4.5) (-1.7307 — 0.0616A + 0.00192A2)]

where
SI =_ site index in feet for breast-height age 50 years, and
A =_ breast-height age.

b. For trees > 120 years old, we used the 50-year index equation derived from Barnes
(1962):

SI = 4.5 + 22.6EXP {[0.014482 — 0.001162Ln (A)] (H - 4.5)} ,

where
S/ = _ site index in feet for breast-height age 50 years, and
A = breast-height age.

6. Engelmann spruce (Brickell 1966).

SI = H + 10.717283 [Ln (A) - Ln (50)]

101°
+ 00046314777 ea 2 32]

104
+ 0.74471147H va 2 4)

— 26413.763H (A~25 — 5025)
— 0.042819823H [Ln (A) — Ln (50)?

4
_ 0.0047812062H =e = 4)

109!°
A>

+ 0.0000049254336H2 ( = 32]

101°

A>

+ 0.00000021975906H3 | : 32|
+ 5.1675949#3 (A275 — 50-275)
— 0,000000014349139H4 == ss ]

— 9.481014H4 (A+5 — 5045) ,

where

et
ll

site index in feet for total age 50 years, and
A = total age.

7. Redwood (table 2 is modified from Krumland and Wensel 1977).

Table 2—Average total height of dominant redwood sprouts by breast-height age
and site index

Breast
height Redwood site index
age 50 60 70 80 90 100 110 120 130 140 150 £160

10 17 19) 22 24 26 28 30 32 34 36 39 42
15 22 26 29 33 37 40 44 48 52 56 60 64
20 “aif 32 37 41 46 51 56 61 67 72 78 83
25 31 37 43 49 55 61 67 74 80 86 93 100
30 35 42 49 56 63 70 ah 85 92 99 107 114
35 39 47 55 63 71 78 86 Cy Oe al al) er
40 43 52 60 69 77 86 Sy 104s as) il TRIO) TIS)
45 47 56 65 "5 84 GS OSM 22 oi A oO
50 50 60 70 80 SO 00) a0 120) 130) 140" 1505 160
55 53 64 5 85 Si) IS er aesis} 4s} a) Ile)
60 56 68 79 SO WO a AB) SAP NG) Ne8) eh
65 59 71 83 CAPs OCRaOn ZOE 40 52 169) 74185
70 62 74 87 CO iil 2Se oon 4On 158.) 170) Si 193
iis 65 78 SOROS lOnei26. IOs oc O4ss On eG 99
80 67 81 QA OAs iZOme SZ 1450) 1575 169 182) 94> 9206
85 70 84 Cee OMe 2A eee SO 49, OZ smaIioON elOMun TOO) 2
90 72 3) WOO) Wiéhs a2 IAA eee ly Is IR Us eZ a70
95 uD COmmOSmem iano temtios 7 S184 197 209 222
100 We OR nlOCm COR AIS4 MAO menlO2 | ior 188) 201 214) 227
105 79 C4 60S) 129° es Se 1G WS) Se 20 is) 281
110 81 OOM iii Ome 4 OOme OSM mIoZ OO s2O9N i ACOu ogo
iS 83 38) Wi1é4s» 129 148 AES» 72 gd SS) Bile 225 ZS)
120 Soy Ol enlOnms | Cit 4OmemlOle wal /oM mG oe 203" 216 ™ 250" 9243
25 S/n OSmmadn Ole Stem 4O se lOAn me Oun lO2s 6206, i219) 233) 246
130 Some Oommen Cle OOn moll sn COMmmloll ulOom 209) 22355236) 5249
135 SQ Ov” WS Weis} e4b Gs) eis) IR IIE ela SI) ey?
140 OZR OO Rial Zone 4 eeatioGmenl “lime 166. 7200) 214, (228 (24250 7255
145 Coe Oeea ZA Swmloomeal(oem|S0.=202 8217 23) 244" 258
150 OS eei2 en Gee 4 eeiGOn 75) 190) 205) 219) 233) 2477) 7260
155 SOA CORA OnmOZemii/aun 192 20755221 235249) 9 7262
160 OSS eo2 40 G4 179°) 1945209) (223° 2375 (251 264
165 OO aooml SOM loom) Toten 190m ees eco. (239559253) 1266
170 OOD Gem So nol OY adoGumlOem, 213. 92er (241) 255° 268
7S nO2ZN henson lSormd69 wi84s, 200) 214 229 243° 257 270
ISOM OS I2ieeice lode sO) 186" 6201) 216552380 244) 258° 272
SOM O42 OOM uOOM v2 I 1Gem 20s) 2ife 8282) 1246 1260) 273
(OR OSme Zoe 400 Si li7si 169) 52049 9219) (233) 247 261) 275
ToS OOM 24 42 alos) elo 190) 2055 5220 99235)" (249) 72639276
ZOO OMauniZo lon OOM ion 92) 207 6222 | 236.) 250) 264 277

10

8. Ponderosa pine, Jeffrey pine, Coulter pine, and Bishop pine.
Note: For California, when these species were in mixed-conifer stands, we used the
mixed-conifer equation.

a. For site trees < 130 years old breast-height age, site index was calculated from
Barrett (1978).

| {128.8952205 [1 — EXP (— 0.016959A)]!73!4}

SI= 100.43 — 1.198632 — 0.00283073A + ee |

si | 1.198632 - 0.00283073A + od ) a- 45)| £45,
where
S/ = site index in feet for breast-height age 100 years, and
A =_ breast-height age.

b. For ponderosa pine over 130 years old, we used the equation below, which approxi-
mates the site curves in Meyer (1961).

SI = [(6.328A! — 2.378) (H — 4.5)] + 4.5,

where
S/ = _ site index in feet at breast-height age 100 years, and
A = breast-height age.

9. Lodgepole pine in western Oregon, eastern Oregon, western Washington, eastern
Washington, and California; and western white pine in western Oregon and California
(Dahms 1975).

Site index was approximated from the equation:

SI = (72.68 — 8.8A°*5) + 4.5 + {2.2614 — 1.26489 [1 — EXP (— 0.08333A)]}>} (H — 4.5) ,

where
SI = __ site index in feet at breast-height age 100 years, and
A = _ breast-height age.

10. Western red cedar (Kurucz 1987).

Although western red cedar was rarely chosen for a site tree, if it was chosen, we used
the following equations adapted from Mitchell and Polsson (1987):

a. If age < 50 years, then:

pe | 2500 ] | [((H - 1.3) (0.05027 + 0.01411A + 0.000097667A7)] Es

0.3048 / | [A? — (H — 1.3) (— 3.11785 — 0.02465A + 0.00174A7)]
where
S/ = _ site index in feet for breast-height age 50 years, and
A = breast-height age.

b. If age > 50 years, then substitute H, for variable H in the site index equation above.
H, = H + 0.02379545H — 0.000475909AH ,
where
A =_ breast-height age.
11. Black cottonwood, Fremont poplar.?
Site index = 92.0
12. Western larch in western Oregon and eastern Oregon (Cochran 1985).
SI = 78:07
+ [(H — 4.5)
x (3.51412 — 0.125483A + 0.0023559A? — 0.00002028A? + 0.000000064782A*)]

— [(3.51412 — 0.125483A + 0.0023559A? — 0.00002028A? + 0.000000064782A%*)
x (1.46897A + 0.0092466A? — 0.00023957A? + 0.0000011122A%*)] ,

where
S/ = _ site index in feet for breast-height age 50 years, and
A =_ breast-height age.

3 Bolsinger, C. 1974. Cottonwood MAI and stocking percent,
California 1970-72 inventory units. Unpublished report. 6 p. On file
with: U.S. Department of Agriculture, Forest Service, Pacific North-
west Research Station, Forestry Sciences Laboratory, P.O. Box
3890, Portland, OR 97208-3890.

11

12

13. Red alder (and other hardwoods if needed except for black cottonwood) in west-
ern Oregon, eastern Oregon, western Washington, eastern Washington, and
California (Worthington and others 1960).

st = (0.60924 + 12938 \ 7,
A
where
Si = _ site index in feet for breast-height age 50 years, and
A =_ breast-height age.

14. Douglas-fir, grand fir, and white fir in eastern Oregon and eastern Washington.
Douglas-fir in silver fir Zone in western Washington (Curtis and others 1974). Silver fir
zone had a plant association where the first two characters were CF or CM and the
elevation was over 1000 meters.

a. Breast-height age 100 years or less:

GSAS #5 a soe = 5),

where

a = 0.010006 (100- A)? ,

b = 1.0 + [0.00549779 (100 — A)] + (1.46842 x 107!4) (100 — A)’,
S/ = site index in feet for breast-height age 100 years, and

A = breast-height age.

b. Breast-height age greater than 100 years:

S1=4.5+a+[b(H-455)],

where

a = 15 [exp -095 pa )]

b = 1O0= 0720243 (LOG WA =2OM | -

S/ = site index in feet for breast-height age 100,
A = breast-height age, and

LOGi9 = _ logarithm to the base 10.

15. Western larch in western Washington and eastern Washington; and western white
pine in eastern Washington (Brickell 1970).

These equations replaced Cochran (1985) equations for the same areas and species
beginning in 1990.

SI = 0.37956H EXP Teel
A+8
where
S/ = site index in feet for breast-height age 50 years, and
A = breast-height age.

16. Mixed conifer in California for all stands coded as mixed conifer. Note that as origi-
nally developed and published, this equation used a base age of 50 years, total age,
and total height. The equations below were modified to accept breast-height age, the
variable that our inventories normally measured.

Site species that could be used include: Douglas-fir, bigcone Douglas-fir, white fir,
ponderosa pine, Jeffrey pine, Shasta red fir, red fir, and Coulter pine.

Site index equation derived from Dunning and Reineke (1933).

SI = H |0.25489 + ore ’
where
S/ = site index in feet for breast-height age 100 years, and
A = breast-height age.

17. Red fir, Shasta red fir in California (Schumacher 1928).

Note that as originally developed and published, this equation used a base age of 50
years, total age, and total height. The equations below were modified to accept
breast-height age, the variable that our inventories normally measured.

Note: For California, when Shasta red fir and red fir were in mixed-conifer stands, the
mixed-conifer site index equation was used.

Site index approximated by equation derived from Schumacher (1928):

ST = H (0.1464 + 43.3273A714) ,

where
S/ = _ site index in feet for breast-height age 50 years, and
A = breast-height age.

13

Mean Annual
Increment

MAI Discount Factors

14

Foresters use MAI to describe the wood-growing capacity of a site, expressed by
PNW-FIA as the average increase in cubic-foot volume per acre per year. AS we used
the term, it was defined as the increment (increase in volume) of a timber stand aver-
aged over the period between age zero and the age at which MAI culminates, i.e.,
reaches its maximum value.

Mean annual increment equations, also called yield equations, were derived by PNW-
FIA from yield data found in published normal yield tables. These normal yield studies
were done for a particular species by taking tree measurements (diameter, height,
and age, to determine individual tree volume) from many representative sample
areas, and then computing basal area per acre, trees per acre, mean diameter, height
and diameter of average tree, and volume. The result was a set of tables of growth and
yield data representing a fully stocked stand.

The PNW-FIA bases the MAI equations on site index. This calculated MAI value is
then modified by discount factors applicable to the plot or region.

Discount factors, also called weighted or stockability discount factors, were used by
PNW-FIA when normal yield tables could overestimate productivity. This could happen
if (1) the site would never be able to support normal stocking because of environmental
factors such as poor soil types, yet the site index could imply normal productivity; (2)
the resources of the site could support more trees than were present; or (3) when
parts of the plot were nonstockable but still classed as forest land (rock outcroppings,
small streams, etc.) and so appeared to be understocked. The PNW-FIA had two
discount factors to adjust for this: plant stockability factor and nonstockable factor.

A discount factor of less than 1.0 indicated that the site was not capable of carrying
normal levels of stocking as defined by the appropriate normal yield table.

Plant stockability factor was developed by PNW-FIA for use in regions where the
potential stocking could vary widely owing to natural causes (MacLean and Bolsinger
1973). The field crew recorded the presence of certain plant species, called stockability
indicator plants, in western Oregon (Douglas, Jackson, and Josephine Counties only),
and California (except the north coast and central coast areas). In eastern Oregon
and eastern Washington, the Pacific Northwest Region Forest Service plant associa-
tion/ecoclass code was collected based on local plant association manuals classifying
the plants found on the site (Hall 1998). All other regions had the plant stockability
factor set to 1.0.

These stockability indicator plants indicated soil moisture problems and toxic (Serpen-
tine) soils. The plant data were used with other environmental variables, such as ele-
vation, to compute the plant stockability factor for these plots.

Nonstockable factor was the percentage of nonstockable land estimated by the field
crew for each subplot on the plot. Small streams, ponds, compacted landings, bedrock,
and rock outcroppings are examples of areas that can prevent full stocking. (Also
called “nonforest inclusions” and “nonstockable nonforest percent”). This was subtracted
from the total subplot area to obtain the percentage of the subplot that is capable of
full stocking.

Calculating Adjusted
MAI

Using the MAI

The Adjusted MAI

MAI Equations

After the site index was calculated for the plot, the analyst selected the appropriate
MAI equation based on the site species and geographic area (table 3) and calculated
an unadjusted (unadjusted for discounts) MAI for each subplot in timberland. Then the
nonstockable percentage was calculated and the plant stockability factor applied, if
required. (This step also was called multiplying by the weighted plot discount factor).
Finally, an adjusted MAI for the entire plot was made by averaging adjusted MAIs for
all the subplots.

Since 1991, PNW-FIA mapped and collected plot data based on the “condition class”
encountered on the plots. If there were two or more timberland condition classes, and
only one had nonstockable area, then an MAI was calculated and reported for each
condition class on the plot. If the nonstockable area occurred across the condition
classes, the MAI was averaged over subplots as usual, and only one MAI was calcu-
lated and reported for the plot.

In forestry, the MAI is used in economic analyses and determinations of forest policy
because it can be associated with value and rate of return on investment. At PNW-FIA,
the MAI was primarily used to develop the site classes: six classes of volume growth
per acre at culmination in fully stocked natural stands. The site classes were in a stand-
ard table in resource bulletins, “Area of timberland by owner and site class” (for example,
Bolsinger and others 1997).

The PNW-FIA also used the MAI to divide plots between “timberland” and “other forest
low productivity” (formerly called “noncommercial forest land”), based on whether the
site could produce 20 cubic feet * acre"! « year".

The adjusted MAI (adjusted for the two discount factors) was the MAI reported for the
plot in the FIA national database and the published tables.

The following equations express the yield in cubic feet per acre per year.

MAI = mean annual increment,

S/ =_ site index for that species and area,
EXP = natural exponent, and

Ln = natural log.

1. Douglas-fir and grand fir in western Oregon (after 1984) except for Jackson and
Josephine Counties, western Washington except in silver fir zone, California except in
mixed-conifer stands (McArdle and others 1961).

MAT = — 60 + 1.71S7 when site index < 75
MAI =— 81.3 + 2.02SI — when site index = 75, <130
MAT = 22.9 + 1.21S7 when site index > 130.

2. Douglas-fir in Jackson and Josephine Counties, Oregon (McArdle and others
1961).

MAI = 1.8SI — 57.12.

15

16

Table 3—Mean annual increment (MAI) equation assignments

MAI equation
number Species Area
1 Douglas-fir and grand fir WOR (after 1984) except Jackson
and Josephine Counties, WWA
except in silver fir zone, CA except
in mixed-conifer stands
2 Douglas-fir Jackson and Josephine Counties
in WOR
3 Grand fir and white fir Jackson and Josephine Counties
in WOR
4 Western hemlock and WOR, EOR, WWA, EWA, CA
Sitka spruce
5 Redwood WOR, CA
6 Noble fir, Shasta red fir WOR, EOR, WWA, EWA, CA
in OR, Pacific silver fir,
subalpine fir, mountain
hemlock
7 Ponderosa pine, Jeffrey WOR, EOR, WWA, EWA, CA
pine, Coulter pine,
Bishop pine
8 Douglas-fir EOR, EWA
9 White fir and grand fir EOR, EWA
10 Lodgepole pine, western EOR, WWA, CA
white pine except in EWA
11 Lodgepole pine EWA
12 Western larch EOR
13 Western larch WWA, EWA
14 Engelmann spruce EOR, WWA, EWA
15 Douglas-fir in silver WWA
fir zone
16 Western red cedar WWA, WOR, CA
7 Western white pine EWA
18 Mixed conifer CA
19 Red fir, Shasta red fir CA
in CA, white fir in CA
20 All hardwoods WOR, EOR, WWA, EWA, CA

WOR = western Oregon.
WWA = western Washington.
EOR = eastern Oregon.
EWA = eastern Washington.

3. Grand fir and white fir in Jackson and Josephine Counties, Oregon (Cochran
1979a).

MAI = 1.9407SI — 34 .

4.Western hemlock and Sitka spruce in western Oregon, eastern Oregon, western
Washington, eastern Washington, and California (Barnes 1962).

MAT = 2.628SI — 49.8 .
5. Redwood in western Oregon and California (Lindquist and Palley 1963).
MAI = EXP (0.2995 VSI + 2.404) .

6. Noble fir, Shasta red fir in Oregon, Pacific silver fir, subalpine fir, mountain hemlock
in western Oregon, eastern Oregon, western Washington, eastern Washington, and
California (Barnes 1962).

MAI = 1.6SI—50.

7. Ponderosa pine, Jeffrey pine, Coulter pine, and Bishop pine, in western Oregon,
eastern Oregon, western Washington, eastern Washington, and California (Meyer
1961).

MAI = EXP (0.702695S/°42 — 0.51367) .

8. Douglas-fir in eastern Oregon and eastern Washington (Cochran 1979a).
MAI = 0.00473 SP.

9. White fir and grand fir in eastern Oregon and eastern Washington (Cochran 1979a).
MAT EXP! (824227) = 2353735 Sie).

10. Lodgepole pine and western white pine in eastern Oregon, western Washington,
and California (Dahms 1964).

MAT = 0.8594ST — 22.32 .

11. Lodgepole pine in eastern Washington (Brickell 1970).
MAI = 0.0122SP — 0.2026SI + 7.4 .

12. Western larch in eastern Oregon (Cochran 1985).

72.1299

Noe ote = GSR OMGESI

+ 1.4 Ln (SI - 20)| .

13. Western larch in western Washington and eastern Washington (Brickell 1970).

1919.3157_

MAI = -126.05 + (2.7974081S7) + Gi

17

18

14. Engelmann spruce in eastern Oregon, western Washington, and eastern
Washington.?

MAT = (1.92SI — 18.4.
15. Douglas-fir in silver fir zone of western Washington (McArdle and others 1961).
MAT = 1.166S7—50.

16. Western red cedar in western Oregon, western Washington, and California (Barnes
1962).

MAT = 2.628SI — 49.8 .
17. Western white pine in eastern Washington (Brickell 1970).
MAT = 14.849891 + 1.7311563S7 .
18. Mixed conifer in California (Dunning and Reineke 1933).
MAI = EXP (0.578265S/°* + 1.8108) .
19. Red fir, Shasta red fir in California, white fir in California (Schumacher 1928).
MAI = 48.278 + 0.23638SI'° .
20. All hardwoods (Worthington and others 1960).
MAT = (1.7102SI) — 53.1279 .

* Teply, J. 1971. Mean annual increment equations. Unpublished
document originally developed for eastern Oregon Blue Mountain
inventory unit (1969), dated 12/71. 8 p. On file with: U.S. Depart-
ment of Agriculture, Forest Service, Pacific Northwest Research
Station, Forestry Sciences Laboratory, P.O. Box 3890, Portland,
OR 97208-3890.

Glossary

Codominant—The tree’s crown is part of the general level of the canopy; it receives
full light from above but little light from the sides. Crown is usually medium sized and
somewhat crowded by other trees.

Condition class—a mapped area on a plot with a distinct land class (for example,
timberland, oak woodland, nonforest) or a distinctive vegetative condition (for example,
forest type, stand size). The condition class identified at a plot center is the only condi-
tion class that is remeasured and used for the analysis of periodic change.

Discount factor—An element of the MAI equation applied if one or both of the two
PNW-FIA discount factors (plant stockability factor and nonstockable factor) are pre-
sent on the field plot. It is also called weighted or stockability discount factor.

Dominant—The tree’s crown extends above the general level of the canopy; it
receives full light from above and some direct light from the sides (includes open-
grown trees).

Forest land—A plot is established on the ground if the crew determines that the site
meets the definition of “forest land.” Forest land is land that is within the sampled area,
is accessible, can be safely visited, and meets at least one of the following two criteria:
(1) is (or has been) at least 10 percent stocked with trees of any size as well as not
subject to nonforest use that would prevent regeneration, such as mowing, grazing,
or recreation; or (2) has western woodland types (tree species not treated as timber
species by PNW-FIA) and has (or previously had) at least 5 percent crown cover by
trees of any size, and is not subject to nonforest use. In the PNW-FIA National Core
Field Guide (used in the annual inventory starting in 2000), “forest land” is one of six
kinds of condition status, which delineate the condition classes, and is the only one on
which plots are measured for the inventory.

Mainstand—The stand that is currently available for management for timber produc-
tion. All trees that are not understory seedlings or saplings, or residual overstory.

Mixed conifer—The PNW-FIA classifies some areas of California forests as mixed
conifer if there is no main softwood tree species as the forest type. A mixed-conifer
site is capable of greater than 70 percent conifer stocking, occurs in certain counties,
and is further defined by the predominance of certain tree species. In general, these
plots have some mix of ponderosa pine, Jeffrey pine, sugar pine, Douglas-fir, red fir,
Shasta red fir, incense cedar, and white fir.

Mixed-conifer types grow on the east-facing slopes of the Coast Range, on the west-
facing and higher elevation east-facing slopes of the Cascade Range and Sierra
Nevada, and can extend into southern California.

Other forest-low productivity—Forest land capable of growing crops of trees to
industrial roundwood quality but not able to grow wood at the rate of 20 cubic
feet ¢ acre™'* year’. Included are areas of low stocking potential or very low site index.

19

Metric Equivalents

Literature Cited

20

Silver fir zone in western Washington—The area in western Washington where the
first two digits of the Pacific Northwest Region Forest Service plant association/eco-
class code are CF (silver fir, noble fir) or CM (mountain hemlock) and the elevation is
over 1000 meters (3,000 feet).

Suppressed—A suppressed tree is completely overtopped by other trees and not
free to grow.

Timberland—Forest land that is potentially capable of producing at least 20 cubic
feeteacre ‘year! at culmination in fully stocked, natural stands of continuous crops of
trees to industrial roundwood size and quality. Industrial roundwood requires species
that grow to size and quality adequate to produce lumber and other manufactured
products (excluding fence posts and fuel wood, which are not considered manufactured).
Timberland is characterized as having no severe limitations on artificial or natural
restocking with species capable of producing industrial roundwood. “Timberland” is
one of three categories of ground land class; the other two are “other forest” and “non-
forest.”

Western woodland types—Tree species designated in the PNW-FIA National Core
Field Guide (used in the annual inventory since 2000) as those species for which
diameter is measured at root crown: juniper, pinyon pine, mountain mahogany, etc.

Yield—The volume of wood that may be contained in a particular type of forest stand.

1 foot = 0.3048 meter
1 acre = 0.405 hectare
1 cubic foot per acre = 0.07 cubic meter per hectare

Barnes, G.H. 1962. Yield of even-aged stands of western hemlock. Tech. Bull. 1273.
Washington DC: U.S. Department of Agriculture, Forest Service. 52 p.

Barrett, J.W. 1978. Height growth and site index curves for managed, even-aged
stands of ponderosa pine in the Pacific Northwest. Res. Pap. PNW-232. Portland,
OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest Forest and
Range Experiment Station. 14 p.

Bolsinger, C.L.; McKay, N.; Gedney, D.R.; Alerich, C. 1997. Washington’s public
and private forests. Resour. Bull. PNW-RB-218. Portland, OR: U.S. Department of
Agriculture, Forest Service, Pacific Northwest Research Station. 144 p.

Brickell, J.E. 1966. Site index curves for Engelmann spruce in the northern and central
Rocky Mountains. Res. Note INT-42. Ogden, UT: U.S. Department of Agriculture,
Forest Service, Intermountain Forest and Range Experiment Station. 8 p.

Brickell, J.E. 1970. Equations and computer subroutines for estimating site quality of
eight Rocky Mountain species. Res. Pap. INT-75. Ogden, UT: U.S. Department of
Agriculture, Forest Service, Intermountain Forest and Range Experiment Station. 22 p.

Cochran, P.H. 1979a. Gross yields for even-aged stands of Douglas-fir and white or
grand fir east of the Cascades in Oregon and Washington. Res. Pap. PNW-263.
Portland, OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest
Forest and Range Experiment Station. 17 p.

Cochran, P.H. 1979b. Site index and height growth curves for managed, even-aged
stands of Douglas-fir east of the Cascades in Oregon and Washington. Res. Pap.
PNW-251. Portland, OR: U.S. Department of Agriculture, Forest Service, Pacific
Northwest Forest and Range Experiment Station. 16 p.

Cochran, P.H. 1979c. Site index and height growth curves for managed, even-aged
stands of white or grand fir east of the Cascades in Oregon and Washington. Res.
Pap. PNW-252. Portland, OR: U.S. Department of Agriculture, Forest Service,
Pacific Northwest Forest and Range Experiment Station. 13 p.

Cochran, P.H. 1985. Site index, height growth, normal yields, and stocking levels for
larch in Oregon and Washington. Res. Note PNW-424. Portland, OR: U.S.
Department of Agriculture, Forest Service, Pacific Northwest Forest and Range
Experiment Station. 24 p.

Curtis, R.O.; Herman, F.R.; DeMars, D.J. 1974. Height growth and site index for
Douglas-fir in high-elevation forests of the Oregon-Washington Cascades. Forest
Science. 20(4): 307-316.

Dahms, W.G. 1964. Gross and net yield tables for lodgepole pine. Res. Pap. PNW-8.
Portland, OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest
Forest and Range Experiment Station. 14 p.

Dahms, W.G. 1975. Gross yield of central Oregon lodgepole pine. In: Baumgartner,
D.M., ed. Management of lodgepole pine ecosystems symposium proceedings.
Pullman, WA: Washington State University Cooperative Extension Service. 25 p.

Dunning, D.; Reineke, L.H. 1933. Preliminary yield tables for second-growth stands
in the California pine region. Tech. Bull. 354. Washington, DC: U.S. Department of
Agriculture. 24 p.

Hall, F.C. 1998. Pacific Northwest ecoclass codes for seral and potential natural
communities. Gen. Tech. Rep. PNW-GTR-418. Portland, OR: U.S. Department of
Agriculture, Forest Service, Pacific Northwest Research Station. 290 p.

Hann, D.W. 1995. A key to the literature presenting site-index and dominant-height-
growth curves and equations for species in the Pacific Northwest and California. Res.
Contrib. 7. Corvallis, OR: Oregon State University, Forest Research Laboratory. 26 p.

Herman, F.R.; Curtis, R.O.; DeMars, D.J. 1978. Height growth and site index esti-
mates for noble fir in high-elevation forests of the Oregon-Washington Cascades.
Res. Pap. PNW-243. Portland, OR: U.S. Department of Agriculture, Forest Service,
Pacific Northwest Forest and Range Experiment Station. 15 p.

King, J.E. 1966. Site index curves for Douglas-fir in the Pacific Northwest.
Weyerhaeuser For. Pap. 8. Centralia, WA: Weyerhaeuser Company, Weyerhaeuser
Forestry Research Center. 49 p.

Krumland, B.; Wensel, L. 1977. Height growth patterns and fifty year base age
site index curves for young growth coastal redwood. Res. Note 4. Berkeley, CA:
University of California, College of Natural Resources, Co-op Redwood Yield
Research Project. 9 p.

21

Kurucz, J.F. 1987. Metric SI tables for red cedar stands. In: Mitchell, K.J.; Polsson,
K.R., eds. Site index curves and tables for British Columbia: coastal species. FRDA
Rep. 37. Victoria, BC: BC Ministry of Forests and Lands, Research Branch: 7.

Lindquist, J.L.; Palley, M.N. 1963. Empirical yield tables for young-growth redwood.
Bull. 796. Berkeley, CA: California Agricultural Experiment Station, University of
California. 47 p.

MacLean, C.D.; Bolsinger, C.L. 1973. Estimating productivity on sites with a low
stocking capacity. Res. Pap. PNW-152. Portland, OR: U.S. Department of
Agriculture, Forest Service, Pacific Northwest Forest and Range Experiment
Station. 18 p.

McArdle, R.E.; Meyer, W.H.; Bruce, D. 1961. The yield of Douglas fir in the Pacific
Northwest. 2" rev. Tech. Bull. 201. Washington, DC: U.S. Department of Agriculture.
65 p.

Meyer, W.H. 1961. Yield of even-aged stands of ponderosa pine. Rev. Tech. Bull. 630.
Washington, DC: U.S. Department of Agriculture. 59 p.

Mitchell, K.J.; Polsson, K.R. 1987. Site index curves and tables for British Columbia:
coastal species. FRDA Rep. 37. Victoria, BC: Ministry of Forests and Lands,
Research Branch. 29 p.

Schumacher, F.X. 1928. Yield, stand and volume tables for red fir in California. Exp.
Station Bull. 456. Berkeley, CA: University of California Experiment Station. 29 p.

U.S. Department of Agriculture, Natural Resources Conservation Service
[NRCS]. 2001. The PLANTS database. Version 3.1. Baton Rouge, LA: National
Plant Data Center. http://plants.usda.gov. (3 March 2000).

Waddell, K.L.; Bassett, P.M. 1997. Timber resource statistics for the Sacramento
resource area of California. Resour. Bull. PNW-RB-220. Portland, OR: U.S. Depart-
ment of Agriculture, Forest Service, Pacific Northwest Research Station. 50 p.

Wiley, K.N. 1978. Site index tables for western hemlock in the Pacific Northwest.
Weyerhaeuser For. Pap.17. Centralia, WA: Weyerhaeuser Company, Western
Forestry Research Center. 28 p.

Worthington, N.P.; Johnson, F.A.; Staebler, G.R.; Lloyd, W.J. 1960. Normal yield
tables for red alder. Res. Pap. PNW-36. Portland, OR: U.S. Department of
Agriculture, Forest Service, Pacific Northwest Forest and Range Experiment
Station. 3 p. (plus tables).

22

Appendix 1

Names of Trees

Common name

Scientific name

Bigcone Douglas-fir
Bishop pine
Black cottonwood

Coulter pine
Douglas-fir
Engelmann spruce
Fremont poplar
Grand fir

Incense cedar
Jeffrey pine
Lodgepole pine
Mountain hemlock
Noble fir

Pacific silver fir
Ponderosa pine
Red alder

Red fir

Redwood

Shasta red fir
Sitka spruce
Subalpine fir
Sugar pine
Western hemlock
Western larch
Western red cedar
Western white pine
White fir

Pseudotsuga macrocarpa (Vasey) Mayr

Pinus muricata D. Don

Populus balsamifera ssp. trichocarpa
(Torr. & Gray ex Hook.) Brayshaw

Pinus coulteri D. Don

Pseudotsuga menziesii (Mirbel) Franco

Picea engelmannii Parry ex Engelm.

Populus fremontii S. Wats.

Abies grandis (Dougl. ex D. Don) Lindl.

Calocedrus decurrens (Torr.) Florin

Pinus jeffreyi Grev. & Balf.

Pinus contorta Doug]. ex Loud.

Tsuga mertensiana (Bong.) Carr.

Abies procera Rehd.

Abies amabilis (Dougl. ex Loud.) Doug]. ex Forbes.

Pinus ponderosa P. & C. Lawson
Alnus rubra Bong.

Abies magnifica A. Murr.

Sequoia sempervirens (Lamb. ex D. Don) Endl.
Abies shastensis (Lemmon) Lemmon
Picea sitchensis (Bong.) Carr.

Abies lasiocarpa (Hook.) Nutt.

Pinus lambertiana Doug.

Tsuga heterophylla (Raf.) Sarg.

Larix occidentalis Nutt.

Thuja plicata Donn ex D. Don

Pinus monticola Dougl. ex D. Don

Abies concolor (Gord. & Glend.) Lindl. ex Hildebr.

Source: USDA NRCS 2001.

23

Appendix 2 Base age of original site index equation (whether it was based on 50- or 100-year
age, and whether the equation was originally written with the individual tree’s total or
breast-height age [BHA)).

Table 4—Site index equation base age

Site index Original PNW-FIA
equation equation equation
number Source age Basis age
1 King 1966 50 BHA 50
McArdle and others 1961? 100 Total 50
2 Cochran 1979b 50 BHA 50
3 Cochran 1979c 50 BHA 50
4 Herman and others 1978 100 BHA 100
5 Wiley 1978 50 BHA 50
Barnes 1962? 50 BHA 50
6 Brickell 1966 50 Total 50
u Krumland and Wensel 1977 50 BHA 50
8 Barrett 1978 100 BHA 100
Meyer 1961 100 BHA 100
9 Dahms 1975 100 BHA 100
10 Kurucz 1987 50 BHA 50
11 Bolsinger 1974° 50 Total 50
12 Cochran 1985 50 BHA 50
13 Worthington and others 1960 50 BHA 50
14 Curtis and others 1974 100 BHA 100
15 Brickell 1970 50 Total 50
16 Dunning and Reineke 1933? 50 BHA 100
V7 Schumacher 1928 50 BHA 50

2 Some site index equations, for example no. 1: McArdle’s Douglas-fir (McArdle and others 1961), were
derived by PNW-FIA from the site index curves in the cited publication because there was no equation pub-
lished. In these cases, the derived equation was sometimes written by using a different base age to better
fit the available site trees. The citation reflects the publication that had the original curves.

© See footnote 3

24

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dedicated to the principle of multiple use management of the
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