首页 > 过刊浏览>2022年第38卷第17期 >91-100. DOI:10.11975/j.issn.1002-6819.2022.17.010
PDF HTML阅读 XML下载 导出引用 引用提醒
麦田土壤水分时空变异特性及CA-Markov模型模拟预报
作者:
基金项目:

国家重点研发计划项目(2018YFD0300503-15);河北省重点研发计划项目(22327002D;21327001D);河北省自然基金(E2017204125)


Spatial-temporal variation of soil moisture in wheat field and simulation prediction using CA-Markov model
Author:
  • 摘要
    • | |
  • 访问统计
    • |
  • 参考文献 [38]
    • | | | |
  • 文章评论
    摘要:

    为揭示农田土壤水分时空变异特征,精准预测土壤含水量,该研究以河北省太行山山前平原井灌区典型麦田为例,在监测土壤水分的基础上,采用时间稳定性指数法、空间自相关性评价法研究土壤水分时空分布规律,构建了适用于模拟预报田间水分时空变化的CA-Markov 模型,并将该模型的模拟预报效果与HYDRUS 模型进行比较。结果表明:随着土层深度的增加,土壤水分等值线由密变疏,变异系数逐渐减小。随着小麦生育期的推移,前期监测的土壤水分稳定性高于后期;在土壤较湿润的情况下,土壤水分空间相关性较强,土壤水分全局Moran’s I 指数随小麦生育期的推移呈现先增大后变小的规律。CA-Markov 模型模拟预报的各土壤相对湿度等级面积误差的平均值为1.61%,比HYDRUS 模型模拟预报的面积误差平均值(10.86%)小9.25个百分点; CA-Markov 模型对研究区4月下旬、5月上旬的土壤水分干旱等级预测的空间分布Kappa 系数分别为 89.31%、91.46%。该模型可综合考虑麦田墒情的时空变化及随机特性,模拟预测土壤墒情的精度较高、效果良好,可以作为麦田水分管理的重要工具。

    Abstract:

    Soil moisture can be a very important indicator to monitor agricultural drought. The dynamics of water distribution in the soil can greatly contribute to the decision-making on the soil and water resources. This study aims to reveal the spatial and temporal variation characteristics of soil moisture in the farmland, and then accurately predict the soil moisture. The soil information fixed-point monitoring was carried out in a typical Wheat Grains field of Taihang mountain front and plain region in Hebei province, China. A total of 150 sampling points were designed from April 19th to May 9th 2017. A wheat field with a width of 100 m and a length of 50 m was meshed by 10 m for the soil sampling in each mesh grid. Soil samples were collected from the depth points at 0-20, >20-40, >40-60, and >60-80 cm six times during the sampling. The temporal stability index and spatial autocorrelation evaluation were then used to determine the spatial and temporal distribution of soil moisture. The CA-Markov model was constructed to predict the spatial and temporal variation of soil moisture in the field. A comparison was made on the prediction with the HYDRUS model. A field test of data detection was finally conducted to verify the accuracy of the simulation. The results showed that the isoline map of soil moisture was changed from dense to sparse with the increase in soil depth. There was the largest variation in the surface soil moisture. The variation coefficient of soil moisture also decreased gradually, as the soil depth increased. Specifically, the proportions of temporal stability index for the soil moisture less than 10% accounted for 52%, 58%, 60%, and 74% in the soil layers of 0-20, >20-40, >40-60, and >60-80 cm, respectively. Correspondingly, there was high temporal stability with the increase in soil depth. Furthermore, irrigation was an important factor with a strong spatial correlation under humid conditions, thus influencing the spatial distribution pattern of soil moisture. A spatial analysis was also conducted using the Moran's I statistic. It was found that the global Moran's I index increased firstly and then decreased with the growth period of wheat. Particularly, the global Moran's I index of relative humidity in the last three times was 0.064-0.142 smaller than that in the first three times, indicating the weak autocorrelation caused by the soil structure. Once the degree of drought reached a certain level, there was a decreasing trend in the spatial autocorrelation of soil moisture and relative humidity. A CA-Markov model was constructed to simulate the change of drought grade, according to the characteristics of soil relative moisture. The average area error was 1.61% for each grade of soil relative moisture, which was 9.25% smaller than that (10.86%) by the HYDRUS model. At the same time, the CA-Markov model was used to simulate the drought grade of soil moisture in late April and early May. The Kappa coefficients of predicted spatial distribution were 89.31% and 91.46%, respectively. Both the Kappa coefficients were higher than 75%, indicating an excellent performance of the improved model on the prediction of soil moisture distribution. The findings can provide a strong reference for crop growth and irrigation water management.

    参考文献
    [1]景冰丹,靳根会,闵雷雷,等. 太行山前平原典型灌溉农田深层土壤水分动态[J]. 农业工程学报,2015,31(19):128-134.Jing Bingdan, Jin Genhui, Min Leilei, et al. Deep soil moisture dynamic of typical irrigation farmland in piedmont of Taihang mountain[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2015, 31(19): 128-134. (in Chinese with English abstract)
    [2]Cui Y Q, Zhang B, Huang H, et al. Spatiotemporal characteristics of drought in the North China Plain over the past 58 years[J]. Atmosphere, 2021, 12(7): 844-860.
    [3]Yang X L, Chen Y Q, Steenhuis T S, et al. Mitigating groundwater depletion in North China Plain with cropping system that alternate deep and shallow rooted crops[J]. Frontiers in Plant Science, 2017, 8: 980
    [4]孙爽,杨晓光,张镇涛,等. 华北平原不同等级干旱对冬小麦产量的影响[J]. 农业工程学报,2021,37(14):69-78.Sun Shuang, Yang Xiaoguang, Zhang Zhentao, et al. Impacts of different grades of drought on winter wheat yield in North China Plain[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(14): 69-78. (in Chinese with English abstract)
    [5]刘昭,周艳莲,居为民,等. 基于BEPS生态模型模拟农田土壤水分动态[J]. 农业工程学报,2011,27(3):67-72.Liu Zhao, Zhou Yanlian, Ju Weimin, et al. Simulation of soil water content in farm lands with the BEPS ecological model[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2011, 27(3): 67-72. (in Chinese with English abstract)
    [6]雷志栋,杨诗秀. 非饱和土壤水一维流动的数值计算[J].土壤学报,1982,19(2):141-153.Lei Zhidong, Yang Shixiu. Numerical method of one-dimensional flow through unsaturated soils[J]. Acta Pedologica Sinica. 1982(2): 141-153. (in Chinese with English abstract)
    [7]哈建强,祝明,朱艳飞. 沧州市土壤墒情变化规律研究[J].水文,2017,37(6):74-79.Ha Jianqiang, Zhu Ming, Zhu Yanfei. Studying on soil moisture content change in Cangzhou[J]. Hydrology, 2017, 37(6): 74-79. (in Chinese with English abstract)
    [8]雷志栋,杨诗秀,许志荣,等. 土壤特性空间变异性初步研究[J]. 水利学报,1985(9):10-21.Lei Zhidong,Yang Shixiu. Xu Zhirong, et al. Preliminary investigation of the spatial variability of soil properties[J]. Journal of Hydraulic Engineering, 1985(9): 10-21. (in Chinese with English abstract)
    [9]尚松浩,毛晓敏,雷志栋,等. 冬小麦田间墒情预报的BP神经网络模型[J]. 水利学报,2002(4):60-63,68.Shang Songhao, Mao Xiaomin, Lei Zhidong, et al. Measurement and calculation of air concentration distribution of self-aerated flow in spillway tunnel[J]. Journal of Hydraulic Engineering, 2002(4): 60-63, 68. (in Chinese with English abstract)
    [10]赵文举,李晓萍,范严伟,等. 西北旱区压砂地土壤水分的时空分布特征[J]. 农业工程学报,2015,31(17):144-151.Zhao Wenju, Li Xiaoping, Fan Yanwei, et al. Spatial-temporal stability distribution characteristics of soil moisture in gravel-sand mulched field in northwestern arid area[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2015, 31(17): 144-151. (in Chinese with English abstract)
    [11]郭欣欣,付强,卢贺,等. 东北黑土区农林混合利用坡面土壤水分空间异质性及主控因素[J]. 农业工程学报,2018,34(19):123-130.Guo Xinxin, Fu Qiang, Lu He, et al. Spatial variability and its controlling factors of soil moisture on cropland-forestland mixed hillslope in black soil area of Northeast China[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2018, 34(19): 123-130. (in Chinese with English abstract)
    [12]Kumar H, Srivastava P, Ortiz B. Field-Scale spatial and temporal soil water variability in irrigated croplands[J]. Transactions of the Aasbe, 2021, 64(4):1277-1294.
    [13]刘继龙,任高奇,付强,等. 秸秆还田下土壤水分时间稳定性与玉米穗质量的相关性[J]. 农业机械学报,2019,50(5):320-326.Liu Jilong, Ren Gaoqi, Fu Qiang, et al. Relationship between temporal stability of soil water and corn ear weight under straw returning[J]. Transactions of the Chinese Society for Agricultural Machinery, 2019, 50(5): 320-326. (in Chinese with English abstract)
    [14]马美娟,余卫东,胡燕辉. 气温和降水预报准确率对土壤水分模拟精度的影响[J]. 生态学杂志,2022,41(8):1509-1516.Ma Meijuan, Yu Weidong, Hu Yanhui. Effects of temperature and precipitation forecast accuracy on the precision of soil moisture simulation[J]. Chinese Journal of Ecology, 2022, 41(8): 1509-1516. (in Chinese with English abstract)
    [15]徐俊增,刘玮璇,卫琦,等. 基于 HYDRUS-2D 的负压微润灌土壤水分运动模拟[J]. 农业机械学报,2021,52(8):287-296.Xu Junzeng, Liu Weixuan, Wei Qi, et al. Simulation of soil moisture movement under negative pressure micro-irrigation based on HYDRUS 2D[J]. Transactions of the Chinese Society for Agricultural Machinery, 2021, 52(8): 287-296. (in Chinese with English abstract)
    [16]Farooq H, Bashir M, Batool M, et al. Evaluating the performance of HYDRUS-1D by calibrating and validating the model results for vertical movement of water and salts using saline irrigation water under green house conditions[J]. Fresenius Environmental Bulletin, 2022,30(15):12938-12950.
    [17]Scheidegger J M, Jackson C R, Muddu S, et al. Integration of 2D lateral groundwater flow into the variable infiltration capacity (VIC) model and effects on simulated fluxes for different grid resolutions and aquifer diffusivities[J]. Water, 2021, 13(5): 663.
    [18]任庆福,严登华,穆文彬,等. 太行山前平原井灌农田点尺度土壤水分动态随机模拟[J]. 农业机械学报,2015,46(3):131-141,157.Ren Qingfu, Yan Denghua, Mu Wenbin, et al. Stochastic model of irrigated farmland soil moisture dynamics at a point in piedmont of mount Taihang[J]. Transactions of the Chinese Society for Agricultural Machinery, 2015, 46(3): 131-141, 157. (in Chinese with English abstract)
    [19]Chang Y F, Bi H X, Ren Q F, et al. Soil moisture stochastic model in pinus tabuliformis forestland on the loess plateau, China[J]. Water, 2017, 9(5): 354.
    [20]季翔,黄炎和,林金石,等. 基于CA-Markov 模型与 ANUDEM 内插法的崩岗侵蚀量预估[J]. 农业工程学报,2018,34(21):128-136.Ji Xiang, Huang Yanhe, Lin Jinshi, et al. Estimation of erosion amount in collapsed gully based on CA-Markov model and ANUDEM interpolation[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2018, 34(21): 128-136. (in Chinese with English abstract)
    [21]Lin T, Xue X, Shi L, et al. Urban spatial expansion and its impacts on island ecosystem services and landscape pattern: A case study of the island city of Xiamen, Southeast China[J]. O-cean & Coastal Management, 2013, 81(9): 90-96.
    [22]刘毅,杨晟,陈吉宁,等. 基于元胞自动机模型的城市土地利用变化模拟[J]. 清华大学学报,2013,53(1):72-77.Liu Yi, Yang Sheng, Chen Jining, et al. Urban land use changes predictions using a cellular automata model[J]. Journal of Tsinghua University, 2013, 53(1): 72-77. (in Chinese with English abstract)
    [23]Mokarram M, Pourghasemi H R, Hu M, et al. Determining and forecasting drought susceptibility in southwestern Iran using multi-criteria decision-making (MCDM) coupled with CA-Markov model[J]. Science of the Total Environment, 2021, 781: 146703.
    [24]尚莹,霍治国,张蕾,等. 土壤相对湿度对冬小麦干热风灾害发生的影响[J]. 应用气象学报,2019,30(5):598-607.Shang Ying, Huo Zhiguo, Zhang Lei, et al. The influence of soil relative moisture on dry-hot wind disaster of winter wheat[J]. Journal of Applied Meteorological Science. 2019, 30(5): 598-607. (in Chinese with English abstract)
    [25]Matkan A A, Shahri M, MirzaieI M. Bivariate Moran's I and LISA to explore the crash risky locations in urban areas[C]// Proceedings of the Conference of Network-Association of European Researchers on Urbanisation in the South, Enschede:The Netherlands, 2013: 12-14.
    [26]徐占军,张媛,张绍良,等. 基于GIS与分区Kriging的采煤沉陷区土壤有机碳含量空间预测[J]. 农业工程学报,2018,34(10):253-259.Xu Zhanjun, Zhang Yuan, Zhang Shaoliang, et al. Spatial prediction of soil organic carbon content in coal mining subsidence area based on GIS and partition Kriging[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2018, 34(10): 253-259. (in Chinese with English abstract)
    [27]国家气象中心. GB/T 32136-2015农业干旱等级[S]. 北京:中国标准出版社,2015.
    [28]Fitzjohn C, Ternan J L, Williams A G. Soil moisture variability in a semi-arid gully catchment: implications for runoff and erosion control[J]. Caterna, 1998, 32(1): 55-70.
    [29]Hao X M, Qiu Y, Fan Y Q, et al. Applicability of temporal stability analysis in predicting field mean of soil moisture in multiple soil depths and different seasons in an irrigated vineyard[J]. Journal of Hydrology, 2020, 588(12): 50-59.
    [30]Li X Z, Shao M G, Jia X X, et al. Landscape-scale temporal stability of soil water storage within profiles on the semiarid Loess Plateau of China[J]. Journal of Soils and Sediments, 2015, 15(4): 946-961.
    [31]朱绪超,邵明安,朱军涛,等. 高寒草甸生态系统表层土壤水分时间稳定性研究[J]. 农业机械学报,2017,48(8):212-218.Zhu Xuchao, Shao Ming'an, Zhu Juntao, et al. Temporal stability of surface soil moisture in alpine meadow ecosystem on northern Tibetan plateau[J]. Transactions of the Chinese Society for Agricultural Machinery, 2017, 48(8): 212-218. (in Chinese with English abstract)
    [32]Zhang P P, Shao M A. Temporal stability of surface soil moisture in a desert area of northwestern China[J]. Journal of Hydrology, 2013, 505: 91-101.
    [33]Brocca L, Morbidelli R, Melone F, et al. Soil moisture spatial variability in experimental areas of central Italy[J]. Journal of Hydrology, 2007, 333(2/3/4): 356-373.
    [34]薛昌颖,刘荣花,马志红. 黄淮海地区夏玉米干旱等级划分[J]. 农业工程学报,2014,30(16):147-156.Xue Changying, Liu Ronghua, Ma Zhihong. Drought grade classification of summer maize in Huang-Huai-Hai area[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2014, 30(16): 147-156. (in Chinese with English abstract)
    [35]包青岭,丁建丽,王敬哲,等. 基于 VIC 模型模拟的干旱区土壤水分及其时空变化特征[J]. 生态学报,2020,40(9):3048-3059.Bao Qingling, Ding Jianli, Wang Jingzhe, et al. Spatio-temporal variation of soil moisture in arid area based on VIC land surface model[J]. Acta Ecologica Sinica, 2020, 40(9): 3048-3059. (in Chinese with English abstract)
    [36]王慧,孙亚勇,黄诗峰,等. LAI和FVC植被参数对VIC模型土壤含水量模拟的影响研究[J]. 中国水利水电科学研究院学报,2018,16(2):141-148,155.Wang Hui, Sun Yayong, Huang Shifeng, et al. Study on the effects of vegetation parameters LAI and FVC on soil water content simulation using VIC model[J]. Journal of China Institute of Water Resources and Hydropower Research, 2018, 16(2): 141-148, 155. (in Chinese with English abstract)
    [37]杨荣赞,王龙,余航,等. 小麦生育期内田间土壤水分动态变化过程及其模型模拟[J]. 云南农业大学学报(自然科学),2020,35(4):717-725.Yang Rongzan, Wang Long, Yu Hang, et al. The dynamic process and model simulation of soil moisture in wheat growth period[J]. Journal of Yunnan Agricultural University (Natural Science), 2020, 35(4): 717-725. (in Chinese with English abstract)
    [38]王斌,郭帅帅,冯杰,等. 基于 SWAT 的积雪消融对高寒区农田土壤水分影响模拟[J]. 农业机械学报,2022,53(1):271-278.Wang Bin, Guo Shuaishuai, Feng Jie, et al. Simulation on effect of snowmelt on cropland soil moisture with in basin in high latitude cold region using SWAT. [J]. Transactions of the Chinese Society for Agricultural Machinery, 2022, 53(1): 271-278. (in Chinese with English abstract)
    相似文献
    引证文献
    网友评论
    网友评论
    分享到微博
    发 布
引用本文

靳亚红,王晶,郄志红,吴鑫淼,李秀梅,甄文超.麦田土壤水分时空变异特性及CA-Markov模型模拟预报[J].农业工程学报,2022,38(17):91-100. DOI:10.11975/j. issn.1002-6819.2022.17.010

Jin Yahong, Wang Jing, Qie Zhihong, Wu Xinmiao, Li Xiumei, Zhen Wenchao. Spatial-temporal variation of soil moisture in wheat field and simulation prediction using CA-Markov model[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE),2022,38(17):91-100. DOI:10.11975/j. issn.1002-6819.2022.17.010

复制
分享
文章指标
  • 点击次数:178
  • 下载次数: 422
  • HTML阅读次数: 0
  • 引用次数: 0
历史
  • 收稿日期:2022-07-09
  • 最后修改日期:2022-08-30
  • 在线发布日期: 2022-10-26
文章二维码
您是第39815076位访问者
ICP:京ICP备06025802号-3
农业工程学报 ® 2025 版权所有
技术支持:北京勤云科技发展有限公司
请使用 Firefox、Chrome、IE10、IE11、360极速模式、搜狗极速模式、QQ极速模式等浏览器,其他浏览器不建议使用!