Agriculture Reference
In-Depth Information
function in functional-structural plant models. New
Phytol. 166:845-857.
Rickman, R.W., and B. Klepper. 1995. The phyllochron:
Where do we go in the future? Crop Sci. 35:44-49.
Rickman, R.W., B. Klepper, and D.A. Ball. 1995. An algo-
rithm for predicting crown root axes of annual grasses.
Agron. J. 87:1182-1186.
Rickman, R.W., S.E. Waldman, and B. Klepper. 1996.
MODWht3: A development-driven wheat growth simula-
tion. Agron. J. 88:176-185.
Ritchie, J.T. 1991. Wheat phasic development. p. 31-54.
In
J. Hanks and J.T. Ritchie (ed.) Modeling plant and soil
systems. ASA-CSSA-SSSA, Madison, WI.
Ritchie, J.T., and S. Otter. 1985. Description and perfor-
mance of CERES-Wheat: A user-oriented wheat yield
model. p. 159-175.
In
W.O. Willis (ed.) ARS wheat yield
project. USDA-ARS-38. Natl. Tech. Inf. Serv., Spring-
fi eld, VA.
Robertson, M.J., I.R. Brooking, and J.T. Ritchie. 1996. The
temperature response of vernalization in wheat: Modelling
the effect on the fi nal number of mainstem leaves. Ann.
Bot. 78:371-381.
Sequeira, R.A., R.L. Olson, and J.M. McKinion. 1997.
Implementing generic, object-oriented models in biology.
Ecol. Model. 94:17-31.
Sequeira, R.A., P.J.H. Sharpe, N.D. Stone, K.M. El-Zik,
and M.E. Makela. 1991. Object-oriented simulation: Plant
growth and discrete organ to organ interactions. Ecol.
Model. 58:55-89.
Shaykewich, C.F. 1995. An appraisal of cereal crop phenol-
ogy modeling. Can. J. Plant Sci. 75:329-341.
Skinner, R.H., and C.J. Nelson. 1995. Elongation of the grass
leaf and its relationship to the phyllochron. Crop Sci.
35:4-10.
Slafer, G.A., and H.M. Rawson. 1994. Sensitivity of wheat
phasic development to major environmental factors: A re-
examination of some assumptions made by physiologists
and modelers. Aust. J. Plant Physiol. 21:393-426.
Slafer, G.A., and H.M. Rawson. 1995a. Rates and cardinal
temperatures for processes of development in wheat:
Effects of temperature and thermal amplitude. Aust. J.
Plant Physiol. 22:913-926.
Slafer, G.A., and H.M. Rawson. 1995b. Base and optimum
temperatures vary with genotype and stage of development
in wheat. Plant Cell Environ. 18:671-679.
Sofi eld, I., L.T. Evans, and I.F. Wardlaw. 1974. The effects
of temperature and light on grain fi lling in wheat. R. Soc.
N. Z. Bull. 12:909-915.
Stone, P.J., I.B. Sorensen, and P.D. Jamieson. 1999. Effect
of soil temperature on phenology, canopy development
and yield of cool-temperate maize. Field Crops Res.
63:169-178.
Streck, N.A., A. Weiss, Q. Xue, and P.S. Baenzinger. 2003.
Improving predictions of developmental stages in winter
wheat: A modifi ed Wang and Engel model. Agric. For.
Meteorol. 115:139-150.
van Keulen, H., and N.G. Seligman. 1987. Simulation of
water use, nitrogen nutrition and growth of a spring wheat
crop. Simulation Monographs. Pudoc, Wageningen, The
Netherlands.
van Laar, H.H., J. Goudriaan, H. van Keulen. 1992. Simula-
tion of crop growth for potential and water limited produc-
tion situations (as applied to spring wheat). Simulation
Reports CABO-TT, 27. CABO-DLO/TPE-WAU,
Wageningen, The Netherlands.
Vinocur, M.G., and J.T. Ritchie. 2001. Maize leaf develop-
ment biases caused by air-apex temperature differences.
Agron. J. 93:767-772.
Wang, J.Y. 1960. A critique of the heat unit approach to plant
response studies. Ecology 41:785-790.
Wardlaw, I.F., I.A. Dawson, P. Munibi, and R. Fewster.
1989. The tolerance of wheat to high temperatures
during reproductive growth: I. Survey procedures and
general response patterns. Aust. J. Agric. Res. 40:
1-13.
Weir, A.H., P.L. Bragg, J.R. Porter, and J.H. Rayner. 1984.
A winter wheat crop simulation model without water or
nutrient limitations. J. Agric. Sci. (Cambridge) 102:371-
382.
Welch, S.M., J.L. Roe, and Z. Dong. 2003. A genetic neural
network model of fl owering time control in
Arabidopsis
thaliana
. Agron. J. 95:71-81.
Weyhrich, R.A., B.F. Carver, and B.C. Martin. 1995. Pho-
tosynthesis and water-use effi ciency of awned and awnlet-
ted near-isogenic lines of hard red winter wheat. Crop Sci.
35:172-176.
Whingwiri, E.E., and D.R. Kemp. 1980. Spikelet develop-
ment and grain yield of the wheat ear in response to applied
nitrogen. Aust. J. Agric. Res. 31:637-647.
Whingwiri, E.E., and W.R. Stern. 1982. Floret survival in
wheat: Signifi cance of the time of fl oret initiation relative
to terminal spikelet formation. J. Agric. Sci. (Cambridge)
98:257-268.
White, J.W. 2006. From genome to wheat: Emerging oppor-
tunities for modeling wheat growth and development. Eur.
J. Agron. 25:79-88.
White, J.W., M. Herndl, L.A. Hunt, T.S. Payne, and G.
Hoogenboom. 2008. Simulation-based analysis of effects
of
Vrn
and
Ppd
loci on fl owering in wheat. Crop Sci.
48:678-687.
White, J.W., and G. Hoogenboom. 2003. Gene-based
approaches to crop simulation: Past experiences and future
opportunities. Agron. J. 95:52-64.
White, J.W., G.S. McMaster, and G.O. Edmeades. 2004a.
Physiology, genomics and crop response to global change.
Field Crops Res. 90:1-3.
White, J.W., G.S. McMaster, and G.O. Edmeades. 2004b.
Genomics, physiology, and global change: What have we
learned? Field Crops Res. 90:165-169.
Wiegand, C.L., and J.A. Cuellar. 1981. Duration of grain
fi lling and kernel weight of wheat as affected by tempera-
ture. Crop Sci. 21:95-101.
Wilhelm, W.W., and G.S. McMaster. 1995. The importance
of the phyllochron in studying the development of grasses.
Crop Sci. 35:1-3.
Wilhelm, W.W., and G.S. McMaster. 1996. Spikelet and
fl oret naming scheme for grasses with spike infl orescences.
Crop Sci. 36:1071-1073.
Wilhelm, W.W., G.S. McMaster, R.W. Rickman, and B.
Klepper. 1993. Above ground vegetative development and
