Computer Vision and Machine Learning-Based Predictive Analysis for Urban Agricultural Systems

Future Internet Pub Date : 2024-01-28 DOI:10.3390/fi16020044
Arturs Kempelis, I. Poļaka, A. Romānovs, Antons Patlins
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Abstract

Urban agriculture presents unique challenges, particularly in the context of microclimate monitoring, which is increasingly important in food production. This paper explores the application of convolutional neural networks (CNNs) to forecast key sensor measurements from thermal images within this context. This research focuses on using thermal images to forecast sensor measurements of relative air humidity, soil moisture, and light intensity, which are integral to plant health and productivity in urban farming environments. The results indicate a higher accuracy in forecasting relative air humidity and soil moisture levels, with Mean Absolute Percentage Errors (MAPEs) within the range of 10–12%. These findings correlate with the strong dependency of these parameters on thermal patterns, which are effectively extracted by the CNNs. In contrast, the forecasting of light intensity proved to be more challenging, yielding lower accuracy. The reduced performance is likely due to the more complex and variable factors that affect light in urban environments. The insights gained from the higher predictive accuracy for relative air humidity and soil moisture may inform targeted interventions for urban farming practices, while the lower accuracy in light intensity forecasting highlights the need for further research into the integration of additional data sources or hybrid modeling approaches. The conclusion suggests that the integration of these technologies can significantly enhance the predictive maintenance of plant health, leading to more sustainable and efficient urban farming practices. However, the study also acknowledges the challenges in implementing these technologies in urban agricultural models.
基于计算机视觉和机器学习的城市农业系统预测分析
城市农业面临着独特的挑战,尤其是在小气候监测方面,而小气候监测在粮食生产中的重要性与日俱增。本文探讨了卷积神经网络 (CNN) 在此背景下预测热图像中关键传感器测量值的应用。研究重点是利用热图像预测相对空气湿度、土壤湿度和光照强度等传感器测量值,这些测量值与城市农业环境中的植物健康和生产率密不可分。结果表明,预报相对空气湿度和土壤湿度水平的准确度较高,平均绝对百分比误差 (MAPE) 在 10-12% 之间。这些发现与这些参数对热模式的强烈依赖性有关,而 CNN 可以有效地提取热模式。相比之下,光照强度的预测更具挑战性,准确率较低。性能下降的原因可能是城市环境中影响光照的因素更加复杂多变。相对空气湿度和土壤湿度的预测准确率较高,从中获得的启示可以为城市农业实践的针对性干预措施提供参考,而光照强度预测的准确率较低,则凸显了进一步研究整合其他数据源或混合建模方法的必要性。结论表明,这些技术的集成可以显著提高植物健康的预测维护能力,从而实现更可持续、更高效的城市耕作实践。不过,该研究也承认在城市农业模型中实施这些技术所面临的挑战。
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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