Validation of the ALMANAC model with different spatial scale

Abstract

Abstract: The ALMANACmodel was validated in a drought stressed year and in a period from 1989 to 1998 at different sites of Texas to evaluate its ability in simulating maize and sorghum yields at different spatial scales and to extend its application range. There were 11 sites for maize and 8 sites for sorghum in plot size simulations, and 9 counties for maize and sorghum in county level simulations. The model showed similar accuracy in simulating both plot size and county level mean grain yields. It could also simulate single year yields under water limited climatic conditions for several sites and mean county yields of maize and sorghum, and had small CVvalues of mean yields for a long term prediction. The mean error was 8.9% for sorghum and 9.4% for maize in field scale simulations, and was only 2.6% for maize and 0.6% for sorghum in county level mean yield simulations.Crop models often require extensive input data sets to realistically simulate crop growth. The development of such input data sets is difficult for some model users. The soil, weather, and crop parameter data sets developed in this study could be used as the guidelines for model applications in similar climatic regions and on similar soils.

CLC Number:

Q141

XIE Yun, James Kiniry, LIU Baoyuan. Validation of the ALMANAC model with different spatial scale[J]. Chinese Journal of Applied Ecology, 2003, (8): 1291-1295.

References

[1] Connolly RD. 1998. Modeling effects of soil structure on the water balance of soil-crop systems: A review. Soil Tillage Res, 48:1～19
[2] Costa JO, Ferreira LGR, DeSouza F. 1988. Produnao do milho submetido a diferents niveis de estresse hidrico. Pesq Agropec Bras Brasilia, 23: 1255～1261
[3] Flenet F, Kiniry JR, Board JE, et al. 1996. Row spacing effects on light extinction coefficients of corn, sorghum, soybean, and sunflower. Agron J, 88(1): 185～190
[4] Hudson N. 1995. Soil Conservation (3rd). Iowa, USA: Iowa State University Press. 126～130
[5] Kiniry JR, Bockholt AJ. 1998. Maize and sorghum simulation in diverse Texas environments. Agron J, 90 (5): 682～687
[6] Kiniry JR, Williams JR, Gassman PW, et al. 1992b. A general, process-oriented model for two competing plant species. Trans ASAE, 35: 80 1～810
[7] Kiniry JR, Williams JR, Vanderlip RL, et al. 1997. Evaluation of two maize models for nine U.S. locations. Agron J,89(3) :421～426
[8] Kiniry JR, Xie Y, Gerik TJ. 2002. Linearity in maize seed number responses for diverse maize hybrids. Crop Sci, 22:265～272
[9] Montieth JL. 1996. The quest for balance in modeling. Agron J, 88 (5) :695～697
[10] Prihar SS, Stewart BA. 1990. Using upper-bound slope through the origin to estimate genetic harvest index. Agron J, 82:1160～1165
[11] Rogers S. 1999.Garst 1998 Yield Results. Garst SeedCo. SIater, IA
[12] Sobriano A, Ginzo HD. 1975. Yield responses of two maize cultivars following short periods of water stress at tasseling. Agroc Meteorol, 15:273～284
[13] Stockle CO, Kiniry JR. 1990. Variability in crop radiation use efficiency associated with vapor pressure deficit. Field Crops Res, 21:171～181
[14] Williama JR. 1990. The erosion-productivity impact calculator (EPIC) model: A case history. Phil Trans R Sec Lond B, 329: 421～428
[15] Williams JR, Jones CA, Kiniry JR, et al. 1989. The EPIC crop growth model. Trans ASAE, 32: 497～511
[16] Yang J-P(杨京平),Wang Z-Q(王兆骞).1999.Crop growth simulation model andits application.Chin J Appl Ecol(应用生态学报),10(4):501～505(in Chinese)