Implementation of soil fertility detection and crop recommendation system based on Geographic Information System (GIS) for precision agriculture

Monika Faswia Fahmi; Deni Tri Laksono; Ahmad Sahru Romadhon; Arsy Aryasafa Putra; Devi Novitasari

doi:10.1051/epjconf/202534401035

All issues

Volume 344 (2025)

EPJ Web Conf., 344 (2025) 01035

Abstract

Open Access

Issue		EPJ Web Conf. Volume 344, 2025 AI-Integrated Physics, Technology, and Engineering Conference (AIPTEC 2025)


Article Number		01035
Number of page(s)		8
Section		AI-Integrated Physics, Technology, and Engineering
DOI		https://doi.org/10.1051/epjconf/202534401035
Published online		22 December 2025

EPJ Web of Conferences 344, 01035 (2025)
https://doi.org/10.1051/epjconf/202534401035

Implementation of soil fertility detection and crop recommendation system based on Geographic Information System (GIS) for precision agriculture

Monika Faswia Fahmi¹^*, Deni Tri Laksono¹, Ahmad Sahru Romadhon², Arsy Aryasafa Putra¹ and Devi Novitasari¹

¹ Electrical Engineering, Department of Electrical Engineering, Universitas Trunodjoyo Madura, Bangkalan, Indonesia
² Electrical Engineering, Department of Mechatronic Engineering, Universitas Trunodjoyo Madura, Bangkalan, Indonesia

^* Corresponding author: monika.faswiaf@trunojoyo.ac.id

Published online: 22 December 2025

Abstract

Accurate soil fertility detection and intelligent crop recommendation systems are fundamental to the advancement of precision agriculture, enabling data-driven decision-making for sustainable food production. However, many smallholder farmers still rely on intuition or traditional practices for crop selection, which often leads to mismatches between soil characteristics and crop requirements, resulting in inefficient input use and reduced productivity. To address this issue, this study implements an integrated Soil Fertility Detection and Crop Recommendation System based on Geographic Information System (GIS) technology. The system integrates real-time soil sensors (pH, temperature, and moisture) with a Fuzzy Mamdani inference model to classify fertility levels and generate crop recommendations visualized through a web-based GIS interface. Field testing was conducted in Kamal Village, Bangkalan, Indonesia, using multiple soil sampling points. Experimental validation showed high computational precision, with an average fuzzy system deviation of 0.00397% compared to MATLAB simulations. Sensor calibration yielded MAPE values of 0.0209% (temperature), 0.0481% (pH), and 0.0929% (moisture), while GPS testing using the BN220 module produced an average positional error of 4.1 cm. The recommendation subsystem accurately classified field conditions, identifying peanut for Field 1 and maize for Fields 2 and 3. GIS visualization effectively mapped spatial variations of soil parameters and crop suitability, confirming the system’s reliability and applicability for data-driven precision agriculture.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License 4.0, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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