IR Home
CR
Home
Editors
Forthcoming
Information
Subscribe
CR SPECIAL 1
CR SPECIAL 2
CR SPECIAL 3
CR SPECIAL 4
CR SPECIAL 5
CR SPECIAL 6
CR SPECIAL 7
CR SPECIAL 8
CR SPECIAL 9
CR SPECIAL 10
CR SPECIAL 11
Journals
Home
MEPS
AME
CR
DAO
ESEP
Search
Subscribe
Book Series
EE Books
Top Books
ESEP Books
Order
EEIU Brochures
(pdf format)
Discussion Forums
Home
Research
Endangered Species Programs
Institutions
International Ecology Institute
Eco-Ethics International Union
Foundation
Otto Kinne Foundation
 | |
CR 25:243-252 (2004)
|
Abstract
|
Predicting phenological development in winter wheat
Qingwu Xue1,3,*, Albert Weiss1, P. Stephen Baenziger2
1School of Natural Resource Sciences and
2Department of Agronomy and Horticulture, University of Nebraska-Lincoln, Lincoln, Nebraska 68583-0728, USA
3Present address: Northwestern Agricultural Research Center, Montana State University, 4570 Montana 35, Kalispell, MT 59901
*Email: qxue@montana.edu
ABSTRACT: Accurate prediction of phenological development is important in the winter wheat Triticum aestivum agroecosystem. From a practical perspective, applications of pesticides and fertilizers are carried out at specific phenological stages. In
crop-simulation modeling, the prediction of yield components (kernel number and kernel weight) and wheat-grain yield relies on accurate prediction of phenology. In this study, a nonlinear multiplicative model by Wang & Engel (WE) for predicting
phenological development in differing winter wheat cultivars was evaluated using data from a 3 yr field experiment. In the vegetative phase (emergence to anthesis) the daily development rate (r) was simulated based on the product of a maximum
development rate (Rmax) in the vegetative phase, a temperature response function [ƒ(T)], a photoperiod response function [f(P)], and a vernalization response function [ƒ(V)]. ƒ(T)
was a nonlinear
the 3 cardinal temperatures for phenological development (minimum, Tmin, optimum, Topt, and maximum, Tmax). ƒ(P) was an exponential function of the actual and critical photoperiods and a
sensitivity parameter unique to each cultivar. ƒ(V) was calculated using ƒ(T) based on the cardinal temperatures for vernalization (Tmin,vn, Topt,vn, and Tmax,vn). In the
reproductive phase, r was simulated based on the product of Rmax for the reproductive phase and ƒ(T). Predictions from this nonlinear model were compared to predictions from the phenology submodel of CERES-Wheat V3.0
(CW3).
The nonlinear model performed very well for predicting phenological development in the 3 winter wheat cultivars, the mean root mean square error (RMSE) ranged from 2.9 to 4.1 d from booting to maturity. For the CW3 model, the mean RMSE ranged from 4.8 to
5.9 d for the same phenological stages. The WE model predicted double ridge with a mean RMSE of 7.3 d. Both models predicted terminal spikelet with a mean RMSE ranging from 6.2 to 7.1 d. The WE model was generally a better predictor of phenology between
booting and maturity than the CW3 model.
KEY WORDS: Phenology · Temperature · Photoperiod · Vernalization · Modeling · Triticum aestivum L.
Full text in pdf format
Published in CR Vol.
25, No. 3
(2004) on January 23
Print ISSN: 0936-577X; Online ISSN: 1616-1572.
Copyright © Inter-Research, Oldendorf/Luhe, 2004
|
