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Research Article

A Robust and Explainable Approach to Crop Recommendation Using a Balanced Multi-Crop Agronomic Dataset

Authors

  • Md Ishtiaque Alam Orfalea College of Business, California Polytechnic State University, San Luis Obispo, CA, USA
  • Tawfiqur Rahman Sikder School of Business, International American University, Los Angeles, CA, USA
  • Mohammad Abdus Sami Department of Business Administration, California Polytechnic State University Pomona, CA, USA
  • Md Lutfor Rahman College of Computer Science, Pacific States University, Los Angeles, CA, USA
  • Md Abu Kawsar Prodhan Hemal College of Computer Science, Pacific States University, Los Angeles, CA, USA
  • Ahmed Ali Linkon Department of Computer Science, Westcliff University, Irvine, CA, USA
  • Mohammad Muzahidur Rahman Bhuiyan College of Business, Westcliff University, Irvine, CA, USA
  • Md Munna Aziz College of Business, Westcliff University, Irvine, CA, USA
  • Md Rashedul Islam College of Business, Westcliff University, Irvine, CA, USA
  • Md Mizanur Rahaman College of Business, Westcliff University, Irvine, CA, USA

Abstract

Crop recommendation systems play a critical role in supporting sustainable agricultural decision making under increasing climate variability. Modern machine learning approaches offer high predictive accuracy, yet their adoption in real-world agri-tech systems depends equally on robustness to environmental change and transparency of decision logic. Using a balanced multi-crop agronomic dataset, this study evaluates classical machine learning models, ensemble methods, and inherently interpretable rule-based learners under two evaluation settings: standard k-fold cross-validation and a rainfall-quartile protocol that simulates shifts in precipitation regimes. The results show that high accuracy under random data splits can substantially overestimate real-world performance when rainfall patterns change. To address this gap, we analyse the accuracy–explainability trade-off by comparing black-box ensembles with interpretable rule-based models. Feature attribution analysis based on SHAP further confirms that rainfall, humidity, and soil potassium are the most influential drivers of crop suitability. The findings provide a data-driven and explainable framework for developing climate-resilient crop recommendation systems that support environmental sustainability, resource-efficient farming, and informed decision making in precision agriculture.

Article information

Journal

Journal of Environmental and Agricultural Studies

Volume (Issue)

7 (3)

Pages

01-15

Published

2026-04-21

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64

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26

Keywords:

Crop recommendation, digital agriculture, explainable artificial intelligence, environmental sustainability, robustness, SHAP, data-driven decision making