[2] Helmut L P D. Phenology and seasonality modeling[J]. Ecological Studies, 120, 461(1975).

[3] Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, 1132(2014).

[4] Liu Y J, Chen Q M, Ge Q S et al. Modelling the impacts of climate change and crop management on phenological trends of spring and winter wheat in China[J]. Agricultural and Forest Meteorology, 248, 518-526(2018).

[5] Liu Y J, Chen Q M, Ge Q S et al. Effects of climate change and agronomic practice on changes in wheat phenology[J]. Climatic Change, 150, 1-15(2018).

[6] Siebert S, Ewert F. Spatio-temporal patterns of phenological development in Germany in relation to temperature and day length[J]. Agricultural and Forest Meteorology, 152, 44-57(2012).

[7] Larson C. Losing arable land, China faces stark choice: Adapt or go hungry[J]. Science, 339, 644-645(2013).

[8] Li Z G, Yang P, Tang H J et al. Response of maize phenology to climate warming in Northeast China between 1990 and 2012[J]. Regional Environmental Change, 14, 39-48(2014).

[9] Sacks W J, Kucharik C J. Crop management and phenology trends in the U.S. Corn Belt: Impacts on yields, evapotranspiration and energy balance[J]. Agricultural and Forest Meteorology, 151, 882-894(2011).

[15] Porter J R, Semenov M A. Crop responses to climatic variation[J]. Philosophical Transactions of the Royal Society of London, 360, 2021(2005).

[17] Liu Y J, Chen Q M, Ge Q S et al. Spatiotemporal differentiation of changes in wheat phenology in China under climate change from 1981 to 2010[J]. Science China: Earth Sciences, 61, 1088-1097(2018).

[18] Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change(2013).

[19] Zhang T Y, Huang Y, Yang X. Climate warming over the past three decades has shortened rice growth duration in China and cultivar shifts have further accelerated the process for late rice[J]. Global Change Biology, 19, 563-570(2013).

[20] Tao F L, Zhang Z, Xiao D P et al. Responses of wheat growth and yield to climate change in different climate zones of China, 1981-2009[J]. Agricultural and Forest Meteorology, 189/190, 91-104(2014).

[22] Estrella N, Sparks T H, Menzel A. Trends and temperature response in the phenology of crops in Germany[J]. Global Change Biology, 13, 1737-1747(2007).

[23] Sadras V O, Monzon J P. Modelled wheat phenology captures rising temperature trends: Shortened time to flowering and maturity in Australia and Argentina[J]. Field Crops Research, 99, 136-146(2006).

[24] Fujisawa M, Kobayashi K. Apple (Malus pumila var. domestica) phenology is advancing due to rising air temperature in northern Japan[J]. Global Change Biology, 16, 2651-2660(2010).

[26] Mo F, Sun M, Liu X Y et al. Phenological responses of spring wheat and maize to changes in crop management and rising temperatures from 1992 to 2013 across the Loess Plateau[J]. Field Crop Research, 196, 337-347(2016).

[29] Xiao D P, Tao F L, Liu Y J et al. Observed changes in winter wheat phenology in the North China Plain for 1981-2009[J]. International Journal of Biometeorology, 57, 275-285(2013).

[30] He L, Asseng S, Zhao G et al. Impacts of recent climate warming, cultivar changes, and crop management on winter wheat phenology across the Loess Plateau of China[J]. Agricultural and Forest Meteorology, 200, 135-143(2015).

[31] Hu Q, Weiss A, Song F et al. Earlier winter wheat heading dates and warmer spring in the U.S. Great Plains[J]. Agricultural and Forest Meteorology, 135, 284-290(2005).

[32] Rezaei E E, Siebert S, Ewert F. Intensity of heat stress in winter wheat-phenology compensates for the adverse effect of global warming[J]. Environmental Research Letters, 10, 024012(2015).

[33] Ahmad S, Abbas Q, Abbas G et al. Quantification of climate warming and crop management impacts on cotton phenology[J]. Plants, 6, 7-22(2017).

[34] Wang Z, Chen J, Li Y et al. Effect of climate change and cultivar on summer maize phenology[J]. International Journal of Plant Production, 10, 509-525(2016).

[35] Zhang L, Zhu L, Yu M et al. Warming decreases photosynthates and yield of soybean [Glycine max (L.) Merrill] in the North China Plain[J]. The Crop Journal, 4, 139-146(2016).

[36] Therond O, Hengsdijk H, Casellas E et al. Using a cropping system model at regional scale: Low-data approaches for crop management information and model calibration[J]. Agriculture Ecosystems and Environment, 142, 85-94(2011).

[37] Zheng H F, Chen L D, Han X Z et al. Classification and regression tree (CART) for analysis of soybean yield variability among fields in Northeast China: the importance of phosphorus application rates under drought conditions[J]. Agriculture Ecosystems and Environment, 132, 98-105(2009).

[38] Anandhi A, Hutchinson S, Harrington J et al. Changes in spatial and temporal trends in wet, dry, warm and cold spell length or duration indices in Kansas, USA[J]. International Journal of Climatology, 36, 4085-4101(2016).

[39] Lobell D B, Sibley A, Ortiz-Monasterio J I. Extreme heat effects on wheat senescence in India[J]. Nature Climate Change, 2, 186-189(2012).

[40] Wang H L, Gan Y T, Wang R Y et al. Phenological trends in winter wheat and spring cotton in response to climate changes in northwest China[J]. Agricultural and Forest Meteorology, 148, 1242-1251(2008).

[42] Liu Y J, Qin Y, Ge Q S et al. Reponses and sensitivities of maize phenology to climate change from 1981 to 2009 in Henan Province, China[J]. Journal of Geographical Sciences, 27, 1072-1084(2017).

[43] Craufurd P Q, Wheeler T R. Climate change and the flowering time of annual crops[J]. Journal of Experimental Botany, 60, 2529-2539(2009).

[44] Carberry P S, Ranganathan R, Reddy L et al. Predicting growth and development of pigeonpea: Flowering response to photoperiod[J]. Field Crops Research, 69, 151-162(2001).

[45] Tao F L, Zhang S, Zhang Z. Spatiotemporal changes of wheat phenology in China under the effects of temperature, day length and cultivar thermal characteristics[J]. European Journal of Agronomy, 43, 201-212(2012).

[46] Guo L, Hu B, Dai J et al. Response of chestnut flowering in Beijing to photosynthetically active radiation variation and change in recent fifty years[J]. Plant Diversity and Resources, 523-532(2014).

[47] Setiyono T D, Weiss A, Specht J et al. Understanding and modeling the effect of temperature and day length on soybean phenology under high-yield conditions[J]. Field Crops Research, 100, 257-271(2007).

[48] Allen R G, Pereira L S, Raes D et al. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements[J]. FAO Irrigation and Drainage Paper 56. FAO, 56(1998).

[51] Challinor A J, Simelton E S, Fraser E D G et al. Increased crop failure due to climate change: Assessing adaptation options using models and socio-economic data for wheat in China[J]. Environmental Research Letters, 5, 034012(2010).

[52] Tester M, Langridge P. Breeding technologies to increase crop production in a changing world[J]. Science, 327, 818-822(2010).

[53] Wang J, Wang E, Yang X et al. Increased yield potential of wheat-maize cropping system in the North China Plain by climate change adaptation[J]. Climatic Change, 113, 825-840(2012).

[54] Liu B H. Spatiotemporal change in China's climatic growing season: 1955-2000[J]. Climatic Change, 99, 93-118(2010).

[55] Chen C, Baethgen W E, Wang E et al. Characterizing spatial and temporal variability of crop yield caused by climate and irrigation in the North China Plain[J]. Theoretical and Applied Climatology, 106, 365-381(2011).

[56] Sacks W J, Deryng D, Foley J A et al. Crop planting dates: An analysis of global patterns[J]. Global Ecology and Biogeography, 19, 607-620(2010).

[57] Bolson J, Martinez C, Breuer N et al. Climate information use among Southeast US water managers: Beyond barriers and toward opportunities[J]. Regional Environmental Change, 13, 141-151(2013).

[58] Rost S, Gerten D, Hoff H et al. Global potential to increase crop production through water management in rainfed agriculture[J]. Environmental Research Letters, 4, 044002(2009).

[60] Moradi R, Koocheki A, Mahallati M N et al. Adaptation strategies for maize cultivation under climate change in Iran: Irrigation and planting date management[J]. Mitigation and Adaptation Strategies for Global Change, 18, 265-284(2013).

[61] Xiao D P, Tao F L. Contributions of cultivars, management and climate change to winter wheat yield in the North China Plain in the past three decades[J]. European Journal of Agronomy, 52, 112-122(2014).

[62] Li Z T, Yang P, Tang H J et al. Response of maize phenology to climate warming in Northeast China between 1990 and 2012[J]. Regional Environmental Change, 14, 39-48(2014).

[63] Ceccarelli S, Grando S, Maatougui M et al. Plant breeding and climate changes[J]. Journal of Agricultural Science, 148, 627-637(2010).

[64] Zhao J, Yang X G, Dai S W et al. Increased utilization of lengthening growing season and warming temperatures by adjusting sowing dates and cultivar selection for spring maize in Northeast China[J]. European Journal of Agronomy, 67, 12-19(2015).

[65] Sun Z, Jia S F, Lv A F et al. Impacts of climate change on growth period and planting boundaries of spring wheat in China under RCP4.5 Scenario[J]. Journal of Resources and Ecology, 7, 1-11(2016).

[66] Karlsen S R, Høgda K A, Wielgolaski F E et al. Growing-season trends in Fennoscandia 1982-2006, determined from satellite and phenology data[J]. Climate Research, 39, 275-286(2009).

[70] Shimono H. Earlier rice phenology as a result of climate change can increase the risk of cold damage during reproductive growth in northern Japan[J]. Agriculture Ecosystems and Environment, 144, 201-207(2011).

[74] Guo L, An N, Wang K. Reconciling the discrepancy in ground- and satellite-observed trends in the spring phenology of winter wheat in China from 1993 to 2008[J]. Journal of Geophysical Research: Atmospheres, 121, 1027-1042(2016).

[79] Supit I, Hooijer A A, van Diepen C A. System Description of the WOFOST 6.0 Crop simulation model implemented in CGMS, Vol. 1: Theory and algorithms[J]. Luxembourg: Joint Research Centre of the Commission of the European Communities(1994).

[80] Jones J W, Hoogenboom G, Porter C H et al. The DSSAT cropping system model[J]. European Journal of Agronomy, 18, 235-265(2003).

[81] McCown R L, Hammer G L, Hargreaves J N G et al. APSIM: A novel software system for model development, model testing and simulation in agricultural systems research[J]. Agricultural Systems, 50, 255-271(1996).

[83] Liu Yujie, Tao Fulu. Probabilistic change of wheat productivity and water use in china for global mean temperature changes of 1, 2, and 3 ℃[J]. Journal of Applied Meteorology and Climatology, 52, 114-129(2013).

[84] Zhang T, Zhu J, Yang X. Non-stationary thermal time accumulation reduces the predictability of climate change effects on agriculture[J]. Agricultural and Forest Meteorology, 148, 1412-1418(2008).

[85] Andrej C, Zalika Č, Lučka K B et al. The simulation of phenological development in dynamic crop model: The Bayesian comparison of different methods[J]. Agricultural and Forest Meteorology, 151, 101-115(2011).

[86] Lobell D B, Burke M B. On the use of statistical models to predict crop yield responses to climate change[J]. Agricultural and Forest Meteorology, 150, 1443-1452(2010).