基于无人机红外测温的室内温度预测准确性分析

Accuracy Analysis of Indoor Temperature Prediction Based on Unmanned Aerial Vehicle Infrared Temperature Measurement

  • 摘要: 通过无人机搭载红外相机结合随机森林回归模型,构建居民楼室内温度预测模型,开展实验结合模拟计算分析测试距离、俯仰角度及房间位置对预测精度的影响。本文选取8户不同位置的房间进行无人机的红外测温实验,并获得有效红外图像及环境参数。无人机测温结果表明,测试距离对预测精度影响不显著;俯仰角度对精度影响显著,0°为最佳角度,确保红外信号准确接收,此外,中层中间户温度分布稳定,预测精度最高,而顶层及边户受与外界空气接触的对流换热影响,温度波动较大,预测难度较高,不供热房间预测效果最差。使用随机森林回归模型整合红外图像特征与环境参数,预测精度高,展现出良好的泛化能力。

     

    Abstract: This study develops an indoor temperature prediction model for residential buildings by combining an infrared camera mounted on an unmanned aerial vehicle (UAV) with a random forest regression model. Experimental and simulated analyses were used to evaluate the effects of the measurement distance, pitch angle, and apartment location on prediction accuracy. Eight households with different locations for UAV-based infrared thermography experiments were selected to obtain valid thermal images and environmental parameters. The UAV measurement results show that the distance does not significantly affect the prediction accuracy. The pitch angle plays a critical role: 0° was the optimal angle for accurate infrared signal reception. The middle-floor central units demonstrated stable temperature distributions and achieved the highest prediction accuracy. In contrast, top floor and corner units, affected by convective heat transfer with outdoor air, exhibited greater temperature fluctuations and proved more challenging to predict, with nonheated units showing the worst prediction performance. The random forest regression model, which integrates thermal image features with environmental parameters, achieved high predictive accuracy and demonstrated excellent generalization capabilities.

     

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