Liu Wei, Song Yingbo. A daily meteorological impact index of maize yield based on weather elements. J Appl Meteor Sci, 2022, 33(3): 364-374. DOI:  10.11898/1001-7313.20220310.
Citation: Liu Wei, Song Yingbo. A daily meteorological impact index of maize yield based on weather elements. J Appl Meteor Sci, 2022, 33(3): 364-374. DOI:  10.11898/1001-7313.20220310.

A Daily Meteorological Impact Index of Maize Yield Based on Weather Elements

DOI: 10.11898/1001-7313.20220310
  • Received Date: 2022-02-22
  • Rev Recd Date: 2022-04-02
  • Publish Date: 2022-05-31
  • Ten-day and monthly climate suitability has been widely used in agrometeorological research and operation, but it will underestimate the impact of short-term meteorological disasters on crops. In order to dynamically reflect the effect of meteorological conditions on crop yields, the daily precipitation suitability is optimized by calculating a weighed 10-day mean of daily precipitation including previous 9 days. Daily climate suitability is constructed consideringthe suitability of temperature, sunshine and precipitation. The correlation coefficient and Euclidean distance of daily climate suitability before the forecast period is used to identify three similar years and the comprehensive similar year. The whole growth climate suitability sequence of crop is established based on daily climate suitability before the forecast period and daily climate suitability in the similar years after the forecast period. And the climate suitability index is integrated from daily climate suitability sequence. The yield forecast model is established by using crop meteorological yields and the daily climate suitability. Daily crop meteorological yield impact index is designed to indicate the effect of meteorological conditions on crop yields. A daily yield forecast model is constructed to analyze the accuracy of daily yield forecast in the main maize-producing provinces in Northeast China and to indicate the accuracy of the meteorological impact index on crop yield. The results show that the use of comprehensive similar years can improve the accuracy of forecasts. The interannual fluctuation of daily forecast accuracy in Heilongjiang smaller than that in the other three provinces. The forecast accuracy is the lowest in Liaoning. Under the comprehensive similar years in monthly time scale, the advancement of the maize fertility process and the access of real-time meteorological data will improve the accuracy of monthly average forecasts. The accuracy on 31 August is generally higher that on 31 July. The daily forecast can provide a reference for yield forecast. The daily scale forecast in Liaoning varies greatly.Daily forecast yield and the announced yield are gradually approaching with the advancement of the maize fertility process and the accuracy of daily forecast yield is also improved. The impact index based on daily meteorological data can quantitatively assess the effect of meteorological conditions on crop yields at different time scales. To a certain extent, the daily meteorological impact index on crop yield can improve the quantitative evaluation level of agrometeorology operation.
  • Fig. 1  Weight coefficients of precipitation in previous 10 days

    Fig. 2  Comparison on the accuracy of yield in Northeast China from 2011 to 2020

    Fig. 3  Yield in Northeast China from 2011 to 2020

    Fig. 4  Comparison on the accuracy of yield in different month under the comprehensive similar year in Northeast China from 2011 to 2020

    Fig. 5  Daily forecast yield, announced yield and forecast accuracy of Liaoning in 2014(a) and 2018(b)

    Fig. 6  The daily crop meteorological yield impact index(a) and same period index(b)of Liaoning in 2014 and 2018

    Table  1  Average accuracy of 10 years under the different similar yearsin Northeast China from 2011 to 2020 (unit:%)

    年型 辽宁 内蒙古东部 黑龙江 吉林
    第1相似年 90.3 93.9 91.8 91.9
    第2相似年 90.9 93.7 91.4 91.7
    第3相似年 90.3 93.6 92.4 91.8
    综合相似年 91.2 94.1 93.4 92.4
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    Table  2  Monthly average forecast accuracy in Northeast China from 2011 to 2020 (unit:%)

    月份 辽宁 内蒙古东部 黑龙江 吉林
    5 89.9 94.1 91.6 92.2
    6 89.9 94.4 92.5 92.5
    7 89.7 94.4 93.5 92.0
    8 92.5 94.1 95.1 92.5
    9 93.8 93.5 94.4 92.6
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    Table  3  Forecast accuracy in Northeast China on 31 Jul and 31 Aug from 2011 to 2020 (unit:%)

    年份 辽宁 内蒙古东部 黑龙江 吉林
    07-31 08-31 07-31 08-31 07-31 08-31 07-31 08-31
    2011 94.2 94.5 83.3* 89.3* 95.1 98.4 95.9 95.2
    2012 95.9 98.7 91.7 94.2 95.0 98.9 92.0 91.1
    2013 87.7* 89.9* 99.1 96.7 94.8 90.3 94.5 93.2
    2014 73.8* 83.2* 86.3* 86.3* 91.3 93.3 91.9 98.3
    2015 96.2 96.2 93.3 89.8* 89.0* 87.8* 93.6 95.5
    2016 91.2 93.9 95.9 96.7 92.8 97.5 93.4 90.9
    2017 91.2 92.4 99.6 96.7 92.2 93.7 90.5 96.1
    2018 99.5 99.7 99.9 99.2 97.6 98.4 80.7* 85.7*
    2019 84.8* 90.6 98.5 95.5 94.1 94.2 92.9 89.8*
    2020 93.4 95.0 97.6 95.8 100.0 90.6 93.6 90.0
    注:*表示逐日预报准确率低于90%。
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    • Received : 2022-02-22
    • Accepted : 2022-04-02
    • Published : 2022-05-31

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