NDVI is the best parameter for yield prediction at the peak vegetative stage of potato (Solanum tuberosum L.)

Climate Smart Agriculture Pub Date : 2025-04-15 DOI:10.1016/j.csag.2025.100053

Poonam Biswal , Ahmad Faisal , Dillip Kumar Swain , Gourav Dhar Bhowmick , Geetha Mohan

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Abstract

Accurate yield prediction and optimization are critical for sustainable potato production, particularly in resource-limited regions affected by climatic variability. This study evaluates the normalized difference vegetation index (NDVI) values obtained during the peak vegetative stage to optimize tuber yield prediction in potato (Solanum tuberosum L.) under subtropical conditions. Field experiments were conducted over two years in Kharagpur, India, using a strip-plot design. Soil management treatments included mulched and non-mulched plots, while water management treatments comprised conventional furrow irrigation (C), drip irrigation at field capacity (D-FC), 90 % field capacity (D-90 %FC), and 80 % field capacity (D-80 %FC). Key parameters, including NDVI, biomass, soil moisture, and tuber yield, were measured and analyzed using correlation, principal component analysis (PCA), and quadratic regression models. NDVI emerged as a critical predictor of tuber yield, showing strong positive correlations with biomass and yield traits. Drip irrigation (D-FC) significantly improved tuber yield compared to conventional furrow irrigation, with the highest yield recorded at 26.22 t ha⁻¹, followed by D-90 %FC at 21.69 t ha⁻¹, while conventional irrigation yielded 22.37 t ha⁻¹. Additionally, mulching (+M) enhanced yields across all drip irrigation treatments. Treatments like D-90 %FC and D-90 %FC-M showed the highest associations with NDVI, biomass, and yield. A quadratic regression model (R² = 0.95) accurately captured the relationship between NDVI and tuber yield, with model validation (R² = 0.97) confirming its reliability across seasons. This study highlights the potential of NDVI-based monitoring for real-time yield prediction and precision irrigation in potato production. The findings suggest that integrating NDVI-based monitoring with advanced irrigation practices can enhance resource efficiency and promote sustainable agriculture.

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NDVI是马铃薯（Solanum tuberosum L.）营养高峰期产量预测的最佳参数。

准确的产量预测和优化对于马铃薯的可持续生产至关重要，尤其是在受气候多变性影响的资源有限地区。本研究评估了在亚热带条件下马铃薯（Solanum tuberosum L.）植被高峰期获得的归一化差异植被指数（NDVI）值，以优化块茎产量预测。在印度哈拉普尔进行了为期两年的田间试验，采用条状小块设计。土壤管理处理包括地膜覆盖地块和非地膜覆盖地块，水管理处理包括常规沟灌（C）、田间滴灌（D-FC）、90 % 田间灌溉（D-90 %FC）和 80 % 田间灌溉（D-80 %FC）。利用相关性、主成分分析（PCA）和二次回归模型测量并分析了包括净植被指数（NDVI）、生物量、土壤水分和块茎产量在内的关键参数。归一化差异植被指数是预测块茎产量的关键指标，与生物量和产量性状呈强正相关。与传统沟灌相比，滴灌（D-FC）显著提高了块茎产量，最高产量为 26.22 吨/公顷，其次是 D-90 %FC，为 21.69 吨/公顷，而传统灌溉产量为 22.37 吨/公顷。此外，地膜覆盖（+M）提高了所有滴灌处理的产量。D-90 %FC 和 D-90 %FC-M 等处理与 NDVI、生物量和产量的关联度最高。二次回归模型（R2 = 0.95）准确地反映了 NDVI 与块茎产量之间的关系，模型验证（R2 = 0.97）证实了其跨季节的可靠性。这项研究强调了基于 NDVI 的监测在马铃薯生产中用于实时产量预测和精确灌溉的潜力。研究结果表明，将基于 NDVI 的监测与先进的灌溉方法相结合，可以提高资源利用效率，促进农业可持续发展。

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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Climate Smart Agriculture

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