Bibliography Even-aged Growth and Yield - Yale School of Forestry ...

EvenAgedGrowthYieldBiblio.pdf © 2007, Timothy G. Gregoire, Yale University
Last revised: January 2007
Bibliography
Even-aged Growth and Yield
(198 entries)
1. Frothingham, E. H. (1914) “Suitability of White Pine for Management.” U.S.
Department of Agriculture, Bulletin No. 13: 1-70.
2. Sterrett, W. D. (1914) “Loblolly Pine Adapted to Forest Management.” U.S.
Department of Agriculture, Bulletin No. 11: 1-58.
3. Frothingham, E. H. (1915) “The Eastern Hemlock.” U.S. Department of Agriculture,
Bulletin No. 152: 1-43.
4. Larsen, L. T. and T. D. Woodbury. (1916) “Sugar Pine.” U.S. Department of
Agriculture, Bulletin No. 426: 1-40.
5. Sterrett, W. D. (1921) “A Generalized Yield Table for Even-Aged Well-Stocked Stands
of Southern Upland Hardwoods.” Journal of Forestry, 19: 382-389.
6. Bruce, D. (1923) “Anamorphosis and Its Use in Forest Graphics.” Journal of Forestry,
21: 773-783.
7. Bruce, D. (1926) “A Method of Preparing Timber-Yield Tables.” Journal of
Agricultural Research, 32: 543-557.
8. Reineke, L. H. (1927) “A Modification of Bruce's Method of Preparing Timber-Yield
Tables.” Journal of Agricultural Research, 35: 843-856.
9. McArdle, R. E and W.H. Meyer. (1930) “The Yield of Douglas Fir in the Pacific
Northwest.” U.S. Department of Agriculture, Bulletin No. 201: 1-65.
10. Reineke, L. H. (1933) “Perfecting A Stand-Density Index for Even-Aged Forests.”
Journal of Agricultural Research, 46: 627-638.
11. Osborne, J. G. and F. X. Schumacher. (1935) “The Construction of Normal-Yield and
Stand Tables for Even-Aged Timber Stands.” Journal of Agricultural Research, 51:
547-564.
12. MacKinney, A. L. and F. X. Schumacher. (1937) “Construction of Yield Tables for
Nonnormal Loblolly Pine Stands.” Journal of Agricultural Research, 51: 531-545.
13. Schnur, G. L. (1937) “Yield, Stand, and Volume Tables for Even-Aged Upland Oak
Forests.” U.S. Department of Agriculture, Technical Bulletin No. 560: 1-87.

EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
14. Chaiken, L. E. (1939) “The Approach of Loblolly and Virginia Pine Stands Toward
Normal Stocking.” Journal of Forestry, 37: 866-871.
15. Schumacher, F. X. (1939) “New Growth Curve and Its Application to Timber-Yield
Studies.” Journal of Forestry, 37: 819-820.
16. Chisman, H. H. and F. X. Schumacher. (1940) “On the Tree-Area Ratio and Certain of
Its Applications.” Journal of Forestry, 38: 311-317.
17. Wellwood, R. W. (1943) “Trend Towards Normality of Stocking for Second-Growth
Loblolly Pine Stands.” Journal of Forestry, 41: 202-209.
18. Bickerstaff, A. (1946) “The Effect of Thinning Upon the Growth and Yield of Aspen
Stands.” Silvicultural Research Note No. 80, Project P-19, Dominion Forest
Service, Ottawa, Canada.
19. Westveld, M. (1953) “Empirical yield tables for Spruce-Fir cut-over lands in the
northeast.” U.S.D.A. Forest Service, Station Paper No. 55, 64 pages.
20. Spurr, S.H. (1954) “Simplified computation of volume and growth.” Journal of
Forestry, 52(12): 914-922.
21. Gingrich, S. F. and H. A. Meyer. (1955) “Construction of an Aerial Stand Volume
Table for Upland Oak.” Forest Science, 1: 140-147.
22. Wenger, K. F., T. C. Evans, T. Lotti, R. W. Cooper, and E. V. Brender. (1958) “The
Relation of Growth to Stand Density in Natural Loblolly Pine Stands.” U.S.D.A.
Forest Service, Southeastern Forest Experiment Station Paper No. 97.
23. Gruschow, G. F. and T. C. Evans. (1959) “The Relation of Cubic-Foot Volume Growth
To Stand Density in Young Slash Pine Stands.” Forest Science, 5: 49-55.
24. Smith, J. H. G. and J. W. Ker. (1959) “Empirical Yield Equations for Young Forest
Growth.” British Columbia Lumberman, 43: 22-25.
25. Brender, E. V. (1960) “Growth Predictions for Natural Stands of Loblolly Pine in The
Lower Piedmont.” Georgia Forest Research Council, Report No. 6.
26. Schumacher, F. X. and T. S. Coile. (1960) “Growth and Yields of Natural Stands of the
Southern Pines.” T. C. Coile Inc., Durham, NC. 1-115 pp.
27. Buckman, R. E. (1961) “Development and Use of Three Stand Volume Equations for
Minnesota.” Journal of Forestry, 59: 573-575.
28. Nelson, T. C., J. L. Clutter, and L. E. Chaiken. (1961) “Yield of Virginia Pine.”
U.S.D.A. Forest Service, Southeastern Forest Experiment Station Paper No. 124.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
29. Nelson, T. C., T. Lotti, E. V. Brender, and K. B. Trousdell. (1961) “Merchantable
Cubic-Foot Volume Growth in Natural Loblolly Pine Stands.” U.S.D.A. Forest
Service, Southeastern Forest Experiment Station Paper No. 127.
30. Buckman, R. E. (1962) “Growth and Yield of Red Pine in Minnesota.” U.S.D.A.
Forest Service, Lake States Forest Experiment Station, Technical Bulletin No. 1272.
31. Lemmon, P. E. and F. X. Schumacher. (1962) “Volume and Diameter Growth of
Ponderosa Pine Trees as Influenced by Site Index, Density, Age, and Size.” Forest
Science, 8: 237-249.
32. Ralston, C.W. and C.F. Korstian. (1962) “Prediction of pulpwood yield of Loblolly and
Shortleaf pine plantations.” Forest Science, 8(2): 149-162.
33. Clutter, J. L. (1963) “Compatible Growth and Yield Models for Loblolly Pine.” Forest
Science, 9: 354-371.
34. Moessner, K.E. (1963) “Composite aerial volume tables for conifer stands in the
mountain states.” U.S.D.A. Forest Service, Research Note INT-6, 4 pages.
35. Williamson, R. L. (1963) “Growth and Yield Records From Well-Stocked Stands of
Douglas-Fir.” U.S.D.A. Forest Service, Pacific Northwest Forest and Range
Experiment Station, Research paper PNW-4.
36. Dahms, W. G. (1964) “Gross and Net Yield Tables for Lodgepole Pine.” U.S.D.A.
Forest Service, Pacific Northwest Forest and Range Experiment Station, Research
paper PNW-8.
37. Dahms, W. G. (1966) “Relationship of Lodgepole Pine Volume Increment to Crown
Competition Factor, Basal Area, and Site Index.” Forest Science, 12: 74-82.
38. Curtis, R. O. (1967) “A Method of Estimation of Gross Yield of Douglas-fir.” Forest
Science Monograph, 13: 1-24.
39. Bennett, F. A. and J. L. Clutter. (1968) “Multiple-Product Yield Estimates for
Unthinned Slash Pine Plantations--Pulpwood, Sawtimber, Gum.” U.S.D.A. Forest
Service, Southeastern Forest Experiment Station, Research Paper SE-35.
40. Bennett, F. A. (1969) “Design Difficulties in Stand Density Studies.” U.S.D.A. Forest
Service, Southeastern Forest Experiment Station, Research Paper SE-111.
41. Bruce, D. (1969) “Potential Production in Thinned Douglas-fir Plantations.” U.S.D.A.
Forest Service, Research Paper PNW-87.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
42. Bennett, F. A. (1970) “Yields and Stand Structural Patterns for Old-Field Plantations of
Slash Pine.” U.S.D.A. Forest Service, Southwestern Forest Experiment Station,
Research Paper SE-60.
43. Bennett, F. A. (1970) “Variable-Density Yield Tables for Managed Stands of Natural
Slash Pine.” U.S.D.A. Forest Service, Southeastern Forest Experiment Station,
Research Note SE-141.
44. Brender, E. V. and J. L. Clutter. (1970) “Yield of Even-Aged, Natural Stands of
Loblolly Pine.” Georgia Forest Research Council, Report No. 23.
45. Curtis, R. O. (1970) “Yield Tables Past and Present.” Journal of Forestry, 70: 28-32.
46. Furnival, G. M. and R. W. Wilson, Jr. (1971) “Systems of Equations for Predicting
Forest Growth and Yield.” In: Statistical Ecology, Volume 3: Many species
Populations, Ecosystems, and Systems Analysis (G. P. Patil, E. C. Pielou, W. E.
Waters, Eds.), Penn State University Press, pp. 43-57.
47. Lenhart, J. D. and J. L. Clutter. (1971) “Cubic-Foot Yield Tables for Old-Field
Loblolly Pine Plantations in the Georgia Piedmont.” Georgia Forest Research
Council, Report No. 22 - Series 3.
48. Sullivan, A. D. and J. L. Clutter. (1972) “A Simultaneous Growth and Yield Model for
Loblolly Pine.” Forest Science, 18: 76-86.
49. Pienaar, L. V. and K. J. Turnbull. (1973) “The Chapman-Richards Generalization of
Von Bertalanffy's Growth Model for Basal Area Growth and Yield in Even-Aged
Stands.” Forest Science, 19: 2-22.
50. Bruce, D. and D. J. DeMars. (1974) “Volume Equations for Second-Growth Douglas-
Fir.” U.S.D.A. Forest Service, Research Note PNW-239.
51. Clutter, J. L. and B. J. Allison. (1974) “A Growth and Yield Model for Pinus Radiata
in New Zealand.” In: Proc. Growth Models for Tree and Stand Simulation (J. Fries,
Ed.). Department of Forest Resarch, Research Notes 30, Royal College of Forestry,
Stockholm, Sweden.
52. Williston, H. L. (1975) “Selected Bibliography on Growth and Yield of the Four Major
Southern Pines.” U.S.D.A. Forest Service, Southern Area, State and Private
Forestry. Pages 1-27.
53. Evert, F. (1976) “Compatible systems for the estimation of tree and stand volume.”
The Forestry Chronicle, 52: 15-16.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
54. Bruce, D. (1977) “Yield Differences Between Research Plots and Managed Forests.”
Journal of Forestry, 75: 14-17.
55. Bruce, D., D. J. DeMars, and D. L. Reukema. (1977) “Douglas-Fir Managed Yield
Simulator -- DFIT User's Guide.” U.S.D.A. Forest Service, Pacific Northwest Forest
and Range Experiment Station, Technical Report PNW-57.
56. Reukema, D. L. and D. Bruce. (1977) “Effects of Thinning on Yield of Douglas-Fir:
Concepts and Some Estimates Obtained by Simulation.” U.S.D.A. Forest Service,
Pacific Northwest Forest and Range Experiment Station, Technical Report PNW-58.
57. Sullivan, A. D. and H. L. Williston. (1977) “Growth and Yield of Thinned Loblolly
Pine Plantations in Loessial Soil Areas.” U.S.D.A. Forest Service, Mississippi
Agricultural and Forestry Experiment Station, Technical Bulletin 86.
58. Bennett, F. A., F. T. Lloyd, B. F. Swindel, and E. W. Whitehorne. (1978) “Yields of
Veneer and Associated Products from Unthinned, Old-Field Plantations of Slash
Pine in the North Florida and South Georgia Flatwoods.” U.S.D.A. Forest Service,
Southeastern Forest Experiment Station, Research Paper SE-176.
59. Ferguson, I. S. and J. W. Leech. (1978) “Generalized Least Squares Estimation of
Yield Functions.” Forest Science, 24: 27-42.
60. Oliver, W. W. and R. F. Powers. (1978) “Growth Models for Ponderosa Pine: I. Yield
of unthinned plantations in northern California.” U.S.D.A. Forest Service, Pacific
Southwest Forest and Range Experiment Station, Research Paper PSW-133.
61. Arner, S. L. and D. W. Seegrist. (1979) “A Computer Program for the Maximum
Likelihood Estimator of the General Multivariate Linear Model with Correlated
Errors.” U.S.D.A. Forest Service, Northeastern Forest Experiment Station,
Technical Report NE-51.
62. Burkhart, H. E. (1979) “Growth and Yield of Southern Pines -- State of the Art.”
Presented at the Southern Forest Economists Workshop, Chapel Hill, North
Carolina. Pages 1-11.
63. Craft, E. P. and J. E. Baumgras. (1979) “Weight and Volume Yields from Thinning
Two Oak-Hickory Stands.” U.S.D.A. Forest Service, Northeastern Forest
Experiment Station, Research paper NE-448.
64. Cochran, P. H. (1979) “Gross Yields for Even-Aged Stands of Douglas-fir and White
or Grand Fir East of the Cascades in Oregon and Washington.” U.S.D.A. Forest
Service, Pacific Northwest Forest and Range Experiment Station, Research paper
PNW-263.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
65. Farrar, R. M., Jr. (1979) “Growth and Yield Predictions for Thinned Stands of Evenaged
Natural Longleaf Pine.” U.S.D.A. Forest Service, Southern Forest Experiment
Station, Research Paper SO-156.
66. Farrar, R. M., Jr. (1979) “Status of Growth and Yield Information in the South.”
Southern Journal of Applied Forestry, 3: 132-137.
67. Murphy, P. A. and H. S. Sternitzke. (1979) “Growth and Yield Estimation for Loblolly
Pine in the West Gulf.” U.S.D.A. Forest Service, Southern Forest Experiment
Station, Research Paper SO-154.
68. Schreuder, H. T., W. L. Hafley, and F. A. Bennett. (1979) “Yield Prediction for
Unthinned Natural Slash Pine Stands.” Forest Science, 25: 25-30.
69. Arner, S.L. and D.W. Seegrist. (1980) "Missing: A Computer Program for the
Maximum Likelihood Estimates of the Parameters of the Multivariate Linear Model
with Incomplete Measurements.” U.S.D.A. Forest Service, Northeastern Forest
Experiment Station, Research Paper NE-56.
70. Bennett, F. A. (1980) “Growth and Yield in Natural Stands of Slash Pine and
Suggested Management Alternatives.” U.S.D.A. Forest Service, Southeastern Forest
Experiment Station, Research Paper SE-211.
71. Burton, J. D. (1980) “Growth and Yield in Managed Natural Stands of Loblolly and
Shortleaf Pine in the West Gulf Coastal Plain.” U.S.D.A. Forest Service, Southern
Forest Experiment Station, Research Paper SO-159.
72. Clutter, J. L. and E. P. Jones, Jr. (1980) “Prediction of Growth after Thinning in Old-
Field Slash Pine Plantations.” U.S.D.A. Forest Service, Research Paper SE-217.
73. Ek, A. R. and A. Dudek. (1980) “Development of Individual Tree Based Stand Growth
Simulators: Progress and Applications.” Department of Forest Resources, Staff
Paper Series Number 20, pages 1-25.
74. Moser, J. W., Jr. (1980) “Historical Chapters in the Development of Modern Forest
Growth and Yield Theory.”
75. Burkhart, H. E., Q. V. Cao, and K. D. Ware. (1981) “A Comparison of Growth and
Yield Prediction Models for Loblolly Pine.” VPI & SU, School of Forestry and
Wildlife Resources, Publication No. FWS-2-81.
76. Curtis, R. O. (1981) “Yield Tables Past and Present.” In: Forestry Predictive Models:
Problems in Application (D.C. LeMaster, D. M. Baumgartner, and R. C. Chapman,
eds.), pages 3-8.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
77. Curtis, R. O., G. W. Clendenen, and D. J. DeMars. (1981) “A New Stand Simulator for
Coast Douglas-fir: DFSIM User's Guide.” U.S.D.A. Forest Service, Pacific
Northwest Forest and Range Experiment Station, General Technical Report PNW-
128.
78. Davis, A. W. and P. W. West. (1981) “Remarks on Generalized Least Squares
Estimation of Yield Functions by I. S. Ferguson and J. W. Leech.” Forest Science,
27: 233-239.
79. Ek, A. R. and R. A. Monserud. (1981) “Methodology for Modeling Forest Stand
Dynamics.” In: Forestry Predictive Models: Problems in Application (D.C.
LeMaster, D. M. Baumgartner, and R. C. Chapman, eds.), pages 19-31.
80. Leech, J. W. and I. S. Ferguson. (1981) “Comparison of Yield Models for Unthinned
Stands of Radiata Pine.” Australian Forest Research, 11: 231-245.
81. Murphy, P. A. and R. C. Beltz. (1981) “Growth and Yield of Shortleaf Pine In the West
Gulf Region.” U.S.D.A. Forest Service, Southern Forest Experiment Station,
Research Paper SO-169.
82. West, P. W. (1981) “Simulation of Diameter Growth and Mortality in Regrowth
Eucalypt Forest of Southern Tasmania.” Forest Science, 27: 603-616.
83. Baker, J.B. and P. A. Murphy. (1982) “Growth and Yield Following Four
Reproduction Cutting Methods in Loblolly-Shortleaf Pine Stands-A Case Study.”
South. J. Appl. For., 6: 66-74.
84. Burkhart, H. E. (1982) “Predicting Growth and Yield: Alternative Approaches and
Their Applications.” In: 31st Annual Forestry Symposium, Predicting Growth and
Yield in the Mid-South (J. E. Hotvedt and B. D. Jackson, eds.), pages 11-22.
85. Hann, D. W. and K. Riitters. (1982) “A Key to the Literature on Forest Growth and
Yield in the Pacific Northwest: 1910-1981.” Oregon State University Forest
Research Lab, Research Bulletin 39.
86. Hafley, W. L., W. D. Smith, and M. A. Buford. (1982) “A New Yield Prediction Model
for Unthinned Loblolly Pine Plantations.” Southern Forest Research Center, School
of Forest Resources, North Carolina State University, Technical Report No. 1.
87. Murphy, P. A. and R. M. Farrar. (1982) “Interim Models for Basal Area and Volume
Projection of Uneven-Aged Loblolly-Shortleaf Pine Stands.” South. J. Appl. For., 6:
115-119.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
88. Nautiyal, J. C. and L. Couto. (1982) “The use of production-function analysis in forest
management: eucalypts in Brazil, a case study.” Canadian Journal of Forest
Research, 12: 452-458.
89. Sadiq, R. A. (1982) “Estimation of stand basal area growth and yield with a reverse
logistic function.” Canadian Journal of Forest Research, 13: 289-297.
90. Seegrist, D. W. and S. L. Arner. (1982) “Variable Density Growth and Yield Models
for Spruce and Fir in Maine.” U.S.D.A. Forest Service, Northeastern Forest
Experiment Station.
91. Bailey, R. L. and K. D. Ware. (1983) “Erratum: Compatible basal-area growth and
yield model for thinned and unthinned stands.” Canadian Journal of Forest
Research, 13: 563-571.
92. Baldwin, V. C., Jr. and J. R. Saucier. (1983) “Aboveground Weight and Volume of
Unthinned, Planted Longleaf Pine on West Gulf Forest Sites.” U.S.D.A. Forest
Service, Southern Forest Experiment Station, Research Paper SO-191.
93. Murphy, P. A. (1983) “Merchantable and Sawtimber Volumes for Natural Even-Aged
Stands of Loblolly Pine in the West Gulf Region.” U.S.D.A. Forest Service,
Southern Forest Experiment Station, Research Paper SO-194.
94. Murphy, P. A. (1983) “A Nonlinear Timber Yield Equation System for Loblolly Pine.”
Forest Science, 29: 582-591.
95. Smith, V. G. (1983) “Compatible Basal Area Growth and Yield Models Consistent
With Forest Growth Theory.” Forest Science, 29: 279-288.
96. Burkhart, H. E. and P. T. Sprinz. (1984) “A Model for Assessing Hardwood
Competition Effects on Yields of Loblolly Pine Plantations.” VPI & SU, School of
Forestry and Wildlife Resources, Publication No. FWS-3-84.
97. Burkhart, H.E. and P.T. Sprinz. (1984) “Compatible cubic volume and basal area
projection equations for thinned old-field Loblolly pine plantations.” Forest
Science, 30(1): 86-93.
98. Chang, S. J. (1984) “A simple production function model for variable density growth
and yield modeling.” Canadian Journal of Forest Research, 14: 783-788.
99. Clutter, J. L., W. R. Harms, G. H. Brister, and J. W. Rheney. (1984) “Stand Structure
and Yields of Site-Prepared Loblolly Pine Plantations in the Lower Coastal Plain of
the Carolinas, Georgia, and North Florida.” U.S.D.A. Forest Service, General
Technical Report SE-27.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
100. Garcia, O. (1984) “New Class of Growth Models for Even-Aged Stands: Pinus
Radiata in Golden Downs Forest.” New Zealand Journal of Forestry Science, 14:
65-88.
101. Hahn, J. T. and J. M. Steiman. (1984) “Empirical Yield Tables for Michigan.”
U.S.D.A. Forest Service, North Central Forest Experiment Station, General
Technical Report NC-96.
102. McClure, J. P. and H.A. Knight. (1984) “Empirical Yields of Timber and Forest
Biomass in the Southeast.” U.S.D.A. Forest Service, Southeastern Forest
Experiment Station, Research Paper SE-245.
103. Pienaar, L. V. and B. D. Shiver. (1984) “An Analysis and Models of Basal Area
Growth in 45-Year-Old Unthinned and Thinned Slash Pine Plantation Plots.
Forest Science, 30: 933-942.
104. Sloboda, B. (1984) “Possibilities of Mathematicaly Predicting Timber Production in
Commercial Forests.” Bulletin of the Nagoya University Forests, No. 7, pp. 261-
279.
105. West, P. W.,D. A. Ratkowsky, and A. W. Davis. (1984) “Problems of Hypothesis
Testing of Regressions with Multiple Measurements From Individual Sampling
Units.” Forest Ecology and Management, 7: 207-224.
106. Bailey, R. L., G. E. Grider, J.W. Rheney, and L. V. Pienaar. (1985) “Stand Structure
and Yields for Site-Prepared Loblolly Pine Plantations in the Piedmont and Upper
Coastal Plain of Alabama, Georgia, and South Carolina.” University of Georgia,
College of Agriculture Experiment Stations, Research Bulletin 328.
107. Burkhart, H. E., D. C. Cloeren, and R. L. Amateis. (1985) “Yield Relationships in
Unthinned Loblolly Pine Plantations on Cutover, Site-Prepared Lands.” Southern
Journal of Applied Forestry, 9: 84-90.
108. Dale, V. H., T. W. Doyle, and H. H. Shugart. (1985) “A Comparison of Tree Growth
Models.” Ecological Modeling, 29: 145-169.
109. Farrar, R. M., Jr. (1985) “Volume and Growth Predictions for Thinned Even-Aged
Natural Longleaf Pine Stands in the East Gulf Area.” U.S.D.A. Forest Service,
Southern Forest Experiment Station, Research Paper SO-220.
110. Pienaar, L. V., B. d. Shiver, and G. E. Grider. (1985) “Predicting Basal Area Growth in
Thinned Slash Pine Plantations.” Forest Science, 31: 731-741.
111. Ritchie, M. W. and D. W. Hann. (1985) “Equations for Predicting Basal Area
Increment in Douglas-fir and Grand Fir.” Oregon State University, Forest Research
Lab, Research Bulletin 51.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
112. Sadiq, R. A. (1985) “Comparison of Some Basal Area Growth and Yield Functions.”
Journal of Tree Science, 4: 1-12.
113. Wensel, L. C. and T. A. Robards. (1985) “Revised parameter estimates for CACTOS
growth models.” University of California, Northern California Forest Yield
Cooperative, Research Note No. 23.
114. Woollons, R. C. and W. J. Hayward. (1985) “Revision of a Growth and Yield Model
for Radiata Pine in New Zealand.” Forest Ecology and Management, 11: 191-202.
115. Benjamin, L.R. and R.C. Hardwick. (1986) “Sources of Variation and Measures of
Variability in Even-aged Stands of Plants.” Annals of Botany, 58: 757-778.
116. Borders, B. E. and R. L. Bailey. (1986) “A Compatible System of Growth and Yield
Equations for Slash Pine Fitted with Restricted Three-Stage Last Squares.” Forest
Science, 32: 185-201.
117. Farrar, R. M., Jr. and P. A. Murphy. (1986) “In Search of an Improved Sawtimber
Stand Volume Function. In: Fourth Biennial Southern Silvicultureal Research
Conference.” U.S.D.A. Forest Service, General Technical Report SE-42.
118. Farrar, R. M., Jr., P. A. Murphy, and T. G. Matney. (1986) “Predicting Growth and
Yield in Natural Southern Timber Stands.” The Compiler, 3: 15-33.
119. Knoebel, B.R., H.E. Burkhart, and D.E. Beck. (1986) “A growth and yield model for
thinned stands of Yellow-poplar.” Supplement to: Forest Science, 32(2): 62 pages.
120. Pienaar, L. V. and B. D. Shiver. (1986) “Basal Area Prediction and Projection
Equations for Pine Plantations.” Forest Science, 32: 626-633.
121. Sadiqu, R. a. and A. F. Beckwith. (1986) “Modified Australian Stand Growth Formula
for Managed Plantations.” Australian Forest Research, 16: 301-312.
122. Smith, W. D. and W. L. Hafley. (1986) “Evaluation of a Loblolly Pine Plantation
Thinning Model.” Southern Journal of Applied Forestry, 10: 52-63.
123. West, P. W., A. W. Davis, and D. A. Ratkowsky. (1986) “Approaches to Regression
Analysis with Multiple Measurements from Individual Sampling Units.” Journal of
Statistical Computation and Simulation, 26: 149-175.
124. Baldwin, V. C., Jr. and D. P. Feduccia. (1987) “Loblolly Pine Growth and Yield
Prediction for Managed West Gulf Plantations.” U.S.D.A. Forest Service, Southern
Forest Experiment Station, Research Paper SO-236.
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EvenAgedGrowthYieldBiblio.doc © 2004, Timothy G. Gregoire, Yale University
125. Baldwin, V. C., Jr., D. P. Feduccia, and J. D. Haywood. (1988) “Postthinning growth
and yield of row-thinned and selectively thinned loblolly and slash pine plantations.”
Canadian Journal of Forest Research, 19: 247-256.
126. Daniels, R. F. and H. E. Burkhart. (1988) “An Integrated System of Forest Stand
Models.” Forest Ecology and Management, 23: 159-177.
127. Garcia, O. (1988) “Growth Modelling - a (Re)view.” New Zealand Forestry, 33: 14-
17.
128. Pukkala, T. and T. Kolström. (1988) “Simulation of the Development of Norway
Spruce Stands using a Transition Matrix.” Forest Ecology and Management, 25:
255-267.
129. Stage, A. R., D. L. Renner, and R. C. Chapman. (1988) “Selected Yield Tables for
Plantations and Natural Stands in Inland Northwest Forests.” U.S.D.A. Forest
Service, Intermountain Research Station, Research Paper INT-394.
130. Bailey, R. L., T. M. Burgan, and E. J. Jokela. (1989) “Fertilized Midrotation-Aged
Slash Pine Plantations - Stand Structure and Yield Prediction Models.” Southern
Journal of Applied Forestry, 13: 76-80.
131. Borders, B.E. (1989) “Systems of Equations in Forest Stand Models.” Forest Science,
35(2): 548-556.
132. Borders, B. E. and W. M. Harrison. (1989) “Comparison of Slash Pine and Loblolly
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