Application of a simulation based optimization model for winter wheat irrigation scheduling in North China

Irrigation needs to be scheduled properly for winter wheat, the main food crop in North China where the water resources are limited. We optimized the irrigation timing of crops under limited water supply by integrating a soil water balance model, dated water production function with cumulative function of water sensitivity index, and a nonlinear search method. The optimization produced the optimal irrigation date series with the predetermined irrigation quota for each application, which aims to obtain higher crop yield with limited irrigation water and be convenient for irrigation management. This simulation–optimization model was used to investigate the irrigation scheduling of winter wheat in Xiaohe irrigation Area in North China. Results show that optimal irrigation date series, corresponding relative yield and relative evapotranspiration are all closely related to the irrigation quota and initial soil water conditions. For rich and medium initial soil water conditions in medium precipitation year, it takes four times of irrigation (60 mm each time) after greening in order to obtain higher crop yield. But it increases to five times for poor initial condition. With limited irrigation water, irrigation should generally be applied in the preferential sequence of early May or late April (in the jointing stage), then mid and late May (in the heading stage), and finally March (in the greening stage). Irrigation should be applied earlier with lower initial soil water storage. Higher irrigation quota increases the crop yield but tends to decrease the marginal value, especially when irrigation quota exceeds 180 mm. The study also indicates that the optimized relative yield is generally higher than that obtained in field experiment. Based on the optimization, we proposed to use the quadratic polynomial function to describe the frontier water production function, which shows the mathematical relationship between optimized relative yield and relative evapotranspiration.     

泾惠渠灌区作物需水量特征及影响因素分析

通过CROPWAT模型分析泾惠渠灌区冬小麦和玉米蒸发蒸腾量及灌溉需水量的变化,同时运用SPSS软件,计算灌区作物需水量与气象因子的相关系数,分析结果表明:冬小麦整个生育期蒸发蒸腾量平均值为634.04 mm,蒸发蒸腾量最高峰出现在4月中旬—5月中旬,灌区各分区蒸发蒸腾量趋势基本一致;玉米蒸发蒸腾量平均值为525.22 mm,蒸发蒸腾量高峰期出现在7月中旬—8月下旬,其中三原最大为535.97 mm,富平最小为514.68 mm;灌区冬小麦在播种—越冬期灌溉需水量最低,返青—拔节期需水量增加;灌区玉米在拔节—抽雄期需水量增加,灌溉平均需水量为133.04 mm;7月—8月为籽粒形成乳熟期,需水量为359.15 mm,至9月下旬,玉米灌溉需水量下降;灌区作物需水量与气温呈正相关,与降水呈负相关,与风速和相对湿度相关性较小,气温、日照时数和相对湿度是影响作物需水量的主要因素.     

气候变化对区域农业灌溉用水影响分析

从气候变化对区域灌溉用水影响机理入手,利用区域经济发展、灌溉用水、种植结构等因素之间动态反馈关系,采用系统动力学建模方法,构建了气候变化背景下灌溉用水响应模型,分析了未来不同气候情景下宝鸡峡灌区灌溉用水的变化过程。结果表明,随着未来气温升高趋势的增加,灌溉用水亦呈明显升高趋势,不同情景稍有差异,但差别不大,而不同作物间差异较大。以B1情景为例,温度升高1℃,灌区内灌溉净需水量约增加12050×104m3,毛需水量约增加20080×104m3,灌区内小麦单位面积约增加需水量28m3/亩;玉米约增加8m3/亩,这可能与冬小麦和夏玉米生育期的变化有关,应进一步加强研究。     

华北冬小麦-夏玉米农田水分动态模拟研究

冬小麦-夏玉米连作是华北地区主要的粮食作物种植模式。根据华北季节性冻土区的特点,将全年划分为作物生长期与越冬期,分别建立了作物生长条件下农田水分运移模型、冻融条件下土壤水热运移模型。前一模型主要包括参照腾发量计算、腾发量分配、作物根系吸水、土壤表面蒸发、土壤水分特征参数和土壤水分运动等子模型;后一模型主要包括冻土水热耦舍迁移、地气水热交换等子模型。应用以上模型对冬小麦-夏玉米连作条件下的土壤水分过程进行模拟,根据北京永乐店试验资料对模型进行检验。模拟了不同降水水平年、不同灌溉处理下的农田灌溉制度及土壤水分过程,分析了降水、灌溉对农田蒸散、土壤水利用、深层渗漏等的影响。     

Model validation and crop coefficients for irrigation scheduling in the North China plain

ISAREG is a model for simulation and evaluation of irrigation scheduling. The model performs the soil water balance and evaluates impacts of water stress on yields for different crops. It is now being used to support a water saving irrigation scheduling program in a pilot area in the North China plain. This paper reports on the calibration and validation of the model using independent data sets relative to winter wheat and summer maize. Data are originated from the Wangdu experimental station and concern a set of drainage lysimeters where diverse irrigation treatments were applied representing different strategies of deficit irrigation. The calibration of the model was performed by deriving the crop coefficients adapted to the local climatic conditions, and considering the soil freezing during winter. The validation of the model was performed using different data sets. Results show that the relative errors to estimate the soil water content averaged 5.3% for summer maize and 7.3% for the winter wheat. These results support the use of the model in the practice.     

The soil water balance of rainfed and irrigated oats,Italian rye grass and rye using the CropSyst model

Crop growth models have been used in simulating the soil water balance for purposes of irrigation management and yield predictions. The application of CropSyst, a cropping systems simulation model, was evaluated for Cedara, South Africa. Simulations included soil water balance of fallow land and rainfed and irrigated winter crops [oats (Avena sativa), Italian ryegrass (Lolium multiflorum) and rye (Secale cereale)]; and irrigation scheduling of the winter crops. Soil, plant, weather and management inputs were used for the soil water balance simulations. Model crop parameters were used from past experiments or obtained from model documentation, with a slight modification to account for varietal differences. The fallow land soil water simulations were more accurate for dry than for wet soil. For all three winter crops, the model consistently over-estimated the soil water content in the upper layers, with a good agreement for the deeper layers until a large precipitation event occurred to which the model responded more slowly than that observed. Simulations using model-scheduled irrigation based on 0.4 and 0.6 maximum allowable depletion criteria indicated that the observed applied irrigation in the field was more than that required. Soil water depletion and accumulated transpiration simulations were similar in both the observed and model-scheduled irrigations, but total soil evaporation and percolation were greater in the case of the observed than the model-scheduled irrigations. Irrigation scheduling using crop growth models may assist in avoiding over- or under-application of irrigation applications by ensuring efficient utilization of rain and irrigation.     

冬小麦、春玉米间作条件下作物需水规律

通过田间试验研究了冬小麦、春玉米间作条件下各生育期的作物需水规律.结果表明:与单作相比,第1个试验期内冬小麦全生育期内间作麦田土壤蒸发量增加34.63 mm,作物蒸腾量减小65.81 mm, 蒸发蒸腾量减小31.18 mm.第2个试验期内冬小麦生育期内间作麦田土壤蒸发量增加26.00 mm,作物蒸腾量减小64.81 mm, 蒸发蒸腾量减小40.81 mm.与单作春玉米相比,间作春玉米的土壤蒸发减少了40.94 mm,作物蒸腾增加了147.73 mm,ET值增加了106.79 mm.可为间作种植的水分管理提供参考.     

泾惠渠灌区冬小麦夏玉米连作需水量及灌水模式研究

为了寻求冬小麦-夏玉米连作下的节水高效灌溉制度,采用大田小区试验,在连作种植模式下,统筹分析了冬小麦和夏玉米的需水量及生育期内降雨量,并与当地传统灌溉制度进行了产量对比。结果表明,连作种植模式下,泾惠渠灌区冬小麦、夏玉米全生育期需水量分别为410 mm和400 mm。在年降雨量为490 mm时,连作种植1 a内的经济灌溉定额为305 mm,相比于传统灌溉能节水8.9%。连作条件下作物总产量为12 010 kg/hm~2,产量相对于传统单作种植增加了6.2%,达到了增产目的。在冬小麦抽穗期和夏玉米播种期减少灌水,可在保证产量的基础上有效提高水分利用效率,是更为优化的连作灌水模式。     

冬小麦节水高效优化灌溉制度模型应用研究

根据霍泉灌区田间试验资料,考虑水分亏缺的后效性,以冠层叶面积指数修正后的作物-水模型作为目标函数,建立二雏动态规划模型,计算冬小麦节水高效优化灌溉制度。结果显示,该模型充分反映了灌水时间、灌水定额和灌溉水量产生的冬小麦的产量效应,所建模型和参数确定较合理,在实践中更有实用性。     

河西绿洲灌区主要作物需水量及作物系数试验研究

利用Penman-Monteith公式计算了甘肃张掖绿洲主要作物各生育期参考作物蒸散量,利用农田水量平衡方程及土壤水分胁迫系数计算了作物实际蒸发蒸腾量,并计算比较了充分灌溉和非充分灌溉条件下不同生育期作物需水特征,确定了非充分灌溉条件下主要作物的作物系数。结果表明,非充分灌溉条件下,主要作物各生育期需水规律和充分灌溉具有一致变化趋势。非充分灌溉条件下,小麦、玉米、马铃薯全生育期作物系数平均值分别为0.81、0.7和0.73。在全生育期当中,随生育期的延续,主要作物叶面蒸腾比例逐渐增大,棵间蒸发逐渐减少。     

黄河下游灌区农田排水再利用效应模拟评价

在田间试验观测基础上,采用SWAP模型分析黄河下游簸箕李引黄灌区农田排水再利用下的土壤盐分季节性变化以及地下水位对土壤盐分剖面分布的影响,模拟农田排水补灌对作物产量的效应。研究结果表明,咸排水补灌引起的土壤盐分积聚主要在冬小麦生长期,夏玉米生长期内并不明显,有效地控制地下水位有助于减少土壤盐分累积量,维系作物根区的盐分平衡。利用含盐量为4mg/cm3以下的农田排水在冬小麦生长后期水分亏缺阶段进行补灌,可在基本不影响随后夏玉米产量的基础上,不同程度地改善冬小麦产量。对缺水严重的黄河下游引黄灌区,农田排水再利用是缓解水资源供需矛盾、改善作物产量的一种有效水管理措施。     

限量灌溉和施磷对冬小麦光合性能及水分利用效率的影响

在大田条件下研究了不同灌水和施磷组合对冬小麦整个生育阶段光和性能的影响。结果表明,灌水、施磷影响了冬小麦的生理指标。施磷主要是提高了作物的光合作用能力,从而使作物的瞬时水分利用效率提高;灌水主要促进了冬小麦的蒸腾速率,使光合速率/蒸腾速率的比值降低。冬小麦叶片的蒸腾和光合速率呈非线性关系,光合速率随蒸腾速率增加而缓慢增加,增加到一定程度后,光合速率不再增加。冬小麦叶片的蒸腾速率和瞬时水分利用效率呈直线负相关关系,瞬时水分利用效率随着蒸腾速率的增大而减小。试验条件下,灌水量为180 mm与施磷量120 kg/hm2是冬小麦节水效果较佳的组合。     

Water use and wheat yields in northern India under different irrigation regimes

Field studies were conducted during a 3-year period to determine wheat (Triticum aestivum L.) yield in response to irrigation scheduling and variable fertilization.Irrigation scheduling was done on the basis of cumulative pan evaporation. Irrigations were given at 25, 50 and 75% available water in the top 60 cm soil profile. The amount of irrigation water applied at each irrigation was equivalent to 75% of the cumulative open pan evaporation. The crop was fertilized at the rate of 0, 60, and 120 kg/ha nitrogen.The yield of wheat was significantly affected by irrigation water and nitrogen treatments. Maximum yield was obtained with irrigation at 50% available soil water and 120 kg/ha nitrogen addition (5092 kg/ha). Consumptive use of water was maximum when irrigation was applied at 75% available soil water. The irrigation at 50% available soil water, however, resulted in greatest yield per cm water use by the crop.     

不同作物种植条件下微咸水灌溉的土壤环境效应试验研究

在田间试验条件下,采用正常灌溉定额和淋洗灌溉定额2种灌溉水平,对小麦、葵花、玉米3种作物进行了不同灌溉水浓度处理的灌溉试验,对3种作物种植条件下土壤水盐运移规律进行了研究。研究发现灌溉水浓度达到某一临界值时,盐分将在土壤剖面一定深度的土层内聚集明显增大。且不同作物的临界灌水浓度值不同。     

不同沟灌方式下夏玉米棵间蒸发试验

采用常规沟灌和交替隔沟灌技术,研究了不同水分处理(水分控制下限为田间持水率的80%、70%、60%)夏玉米的棵间蒸发。结果表明:常规沟灌的灌后蒸发和全生育期棵间蒸发量均大于交替隔沟灌,灌水后短期内由于表层土壤含水率较高,土壤蒸发较大;在满足作物蒸腾耗水的基础上,交替隔沟灌减小了灌溉湿润面积而减小无效蒸发耗水;不同沟灌方式下土壤蒸发与表层土壤含水率呈明显的脉冲波动变化,而深层土壤含水率波动较弱;表层土壤含水率和叶面积指数对棵间蒸发影响明显,二者与相对土面蒸发强度均有良好的指数函数关系。水分下限控制合适,交替隔沟灌棵间蒸发与蒸腾耗水明显降低,是夏玉米适宜的灌水方式。     

Effect of precipitation change on water balance and WUE of the winter wheat-summer maize rotation in the North China Plain

Limited precipitation restricts crop yield in the North China Plain, where high level of production depends largely on irrigation. Establishing the optimal irrigation scheduling according to the crop water requirement (CWR) and precipitation is the key factor to achieve rational water use. Precipitation data collected for about 40 years were employed to analyze the long-term trend, and weather data from 1984 to 2005 were used to estimate the CWR and irrigation water requirements (IWR). Field experiments were performed at the Luancheng Station from 1997 to 2005 to calculate the soil water consumption and water use efficiency (WUE). The results showed the CWR for winter wheat and summer maize were similar and about 430 mm, while the IWR ranged from 247 to 370 mm and 0 to 336 mm at the 25% and 75% precipitation exceedance probabilities for winter wheat and summer maize, respectively. The irrigation applied varied in the different rainfall years and the optimal irrigation amount was about 186, 161 and 99 mm for winter wheat and 134, 88 and 0 mm for summer maize in the dry, normal and wet seasons, respectively. However, as precipitation reduces over time especially during the maize growing periods, development of water-saving management practices for sustainable agriculture into the future is imperative.     

基于SIMDual_Kc模型估算非充分灌水条件下冬小麦蒸散量

为研究关中冬小麦植株蒸腾和土壤蒸发规律,利用2 a冬小麦小区控水试验实测数据,率定和验证了双作物系数SIMDual_Kc模型在关中地区的适用性.用大型称重式蒸渗仪的实测蒸散量值(或水量平衡法计算值)与模型模拟值进行对比.结果表明:SIMDualKc模型可较准确地模拟关中不同水分条件下冬小麦蒸散量,且模拟精度较高.模型估算的平均绝对误差为0.643 3 mm/d.模型估算的冬小麦初期、中期和后期的基础作物系数分别为0.35,1.30,0.20.另外,模型还可以较准确地估算不同水分供应条件下的土壤水分胁迫系数、土壤蒸发量和植株蒸散量.冬小麦整个生育期,土壤蒸发主要发生在作物生育前期,中期较低,后期略微增大;植株蒸腾主要发生在作物快速生长期和生长中期,整个生育期中呈先增大后减小的趋势.     

微咸水灌溉下土壤水盐动态及对作物产量的影响

华北平原农业灌溉用水非常紧缺,水资源日益缺乏与粮食需求日益增多之间的矛盾尖锐。充分利用微咸水资源是缓解这一矛盾的重要途径之一。该文以中国农业大学曲周试验站1997－2005年冬小麦和夏玉米微咸水灌溉田间长期定位试验为基础,研究了充分淡水、充分淡咸水、关键期淡水、关键期淡咸水和不灌溉等5个处理下土壤饱和电导率和含盐量的动态变化,探讨了微咸水灌溉对冬小麦和夏玉米产量的影响。结果表明：土壤水盐动态呈受灌溉和降雨影响的短期波动和受季节更替影响的长期波动;在正常降雨年份,使用微咸水进行灌溉是可行的,不会导致土壤的次生盐渍化;微咸水灌溉虽然导致冬小麦和夏玉米产量降低10%～15%,但节约淡水资源60%～75%。如果降雨量达到多年平均水平以及微咸水灌溉制度制订合理,微咸水用于冬小麦/玉米田间灌溉前景广阔。     

基于RS数据和GIS方法的冬小麦水分生产函数估算

以冬小麦遥感监测耗水与产量为数据支持,开展了多种水分生产函数模型的对比研究,探求与研究区相适宜的水分生产函数模型及其参数,其中全生育期水分生产函数模型分别选择直线模型、抛物线模型、D-K模型及指数模型;而分生育阶段水分生产函数模型分别选择Jensen、Minhas、Blank、Stewart及Singh模型。研究结果表明,冬小麦全生育水分生产函数模型推荐采用抛物线模型;而分生育阶段水分生产函数模型推荐采用Stewart模型;冬小麦对水分最敏感的阶段是抽穗期,其次为扬花-成熟期,而出苗-拔节期最小。为此,在北京市大兴区的冬小麦灌溉应优先满足抽穗灌浆期的需水,而在出苗-拔节期适度减少灌溉量,可达到节水增效目的。     

基于Meta分析的中国灌溉冬小麦产量及水分利用效率影响因素研究

【目的】目前针对灌溉冬小麦产量与水分利用效率影响因素的研究大多集中于某一特定区域,研究结果零散,针对上述问题,揭示宏观尺度下灌溉冬小麦产量和水分利用效率的影响因素。【方法】综合已发表的田间试验数据,采用Meta分析方法得出灌溉在不同地区的增产效应和水分效应,在异质性检验的基础上,通过Meta亚组分析探究灌溉定额、降雨量和平均气温等对冬小麦产量和水分利用效率的影响机制。【结果】与生育期不灌溉相比,灌溉使冬小麦总体增产39.34%,水分利用效率提高3.39%;增产率随灌溉定额的增加而增大,增幅最终趋于稳定,水分利用效率随灌溉定额的增加呈先增加后减少的趋势,当灌溉定额>240 mm时,冬小麦相对水分利用效率变化率显著降低11.29%;随着生育期平均温度上升,灌溉冬小麦增产效应显著提高,生育期均温>9℃时,冬小麦增产率高达45.81%;生育期降雨量对灌溉冬小麦产量影响显著,生育期降雨量处于干旱年份时灌溉增产效应最明显,增产率为72.48%。【结论】灌溉定额为60~120 mm更有利于提高冬小麦产量和水分利用效率。