Effect of field of view of canopy temperature observations on crop water stress index for irrigation scheduling

Water Supply Pub Date : 2023-11-28 DOI:10.2166/ws.2023.313

Aditi Yadav, H. Upreti, G. Singhal

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Abstract

The monitoring of canopy temperature (Tc) helps to establish appropriate watering methods. This study calculates the crop water stress index (CWSI) for four irrigation regimes in semi-arid region, India. Plots 1, 2, 3, and 4 had soil moisture depletion of 50% (drip system), 25% (drip system), unregulated (farmer replicated flood system), and 50% (flood system) with irrigation. In this work, we examined the value of employing a portable infrared thermometer (IRT) to measure wheat canopy temperature (Tc) at two geographical locations. The IRT field of view is 51.28–5,128 cm2, or 10–100 cm from the canopy crown. The field of view change from 10 to 100 cm affects Tc and CWSI in the four irrigation treatments, ranging from 0.65 to 2.71% and 9.2 to 36.4%, respectively. The research found that increasing the IRT from 10 to 100 cm reduced slope by 5.7% and intercept values by 20.6% in lower baselines. The R2 for CWSI and soil moisture was 0.78 (10 cm) and 0.77 (100 cm). Drip-irrigated plots are more sensitive to IRT spatial resolution than flood-irrigated plots. The findings suggest that CWSI studies may benefit from specific sample methods for Tc evaluation.

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冠层温度观测视场对灌溉调度中作物水分胁迫指数的影响

监测冠层温度（Tc）有助于确定适当的浇水方法。本研究计算了印度半干旱地区四种灌溉制度下的作物水分胁迫指数（CWSI）。1 号、2 号、3 号和 4 号地的土壤水分消耗量分别为 50%（滴灌系统）、25%（滴灌系统）、无调节（农民重复灌溉系统）和 50%（灌溉系统）。在这项工作中，我们研究了在两个地理位置使用便携式红外测温仪（IRT）测量小麦冠层温度（Tc）的价值。IRT 的视场为 51.28-5128 平方厘米，即距离冠层冠部 10-100 厘米。视场从 10 厘米到 100 厘米的变化对四种灌溉处理的 Tc 和 CWSI 均有影响，影响范围分别为 0.65% 到 2.71% 和 9.2% 到 36.4%。研究发现，将 IRT 从 10 厘米增加到 100 厘米可使较低基线的斜率降低 5.7%，截距值降低 20.6%。CWSI 和土壤湿度的 R2 分别为 0.78（10 厘米）和 0.77（100 厘米）。滴灌地块比漫灌地块对 IRT 空间分辨率更敏感。研究结果表明，CWSI 研究可能会受益于特定的 Tc 评估取样方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Water Supply

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