Improving temperature estimation in low-cost infrared cameras using deep neural networks
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Low-cost thermal cameras are inaccurate (usually ± 3^∘ C) and have space-variant nonuniformity across their detector. Both inaccuracy and nonuniformity are dependent on the ambient temperature of the camera. The main goal of this work was to improve the temperature accuracy of low-cost cameras and rectify the nonuniformity. A nonuniformity simulator that accounts for the ambient temperature was developed. An end-to-end neural network that incorporates the ambient temperature at image acquisition was introduced. The neural network was trained with the simulated nonuniformity data to estimate the object's temperature and correct the nonuniformity, using only a single image and the ambient temperature measured by the camera itself. Results show that the proposed method lowered the mean temperature error by approximately 1^∘ C compared to previous works. In addition, applying a physical constraint on the network lowered the error by an additional 4%. The mean temperature error over an extensive validation dataset was 0.37^∘ C. The method was verified on real data in the field and produced equivalent results.
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