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A Desmoking Algorithm for Endoscopic Images Based on Improved U-Net |
Lin Jinzhao, Jiang Meiqiu, Pang Yu*, Wang Huiqian |
(College of Optoelectronic Engineering, Chongqing University of Posts and Telecommunications, Chongqing 400065, China) |
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Abstract In minimally invasive surgery, the smoke generated by operations such as electrocautery and laser ablation seriously fade image quality, not only obstructs the doctor’s field of view and increases the risk of surgery, but also reduces the performance of computer-assisted surgery algorithms (such as segmentation, 3D reconstruction, tracking, etc.). Therefore, the smoke needs to be removed real time to maintain a clear vision. This paper proposed a desmoking algorithm based on the improved U-Net network. To retain more image details, we add images which undergone Laplace pyramid transformation to the encoder part; and to improve network's performance, we add attention mechanism module (CBAM) to decoder part. The laparoscopic image was provided by the Hamlyn Center and used as the original dataset (15000 training images, 1000 synthetic smoke test images, and 129 real smoke test images), and the Blender software was used to simulate various situations of smoke which was added to the laparoscopic image, and the composite image was obtained and sent to the improved U-Net model for training, and performed 5-fold cross-validation. We obtained a PSNR value of 31.05 and SSIM index of 0.98 on the composed dataset. These two indicators showed that the smoke-purified image was very similar to the original image, which helped restore the real vision of the human body during surgery. The average running time is 90.91 fps, which is applicable in a real-time medical system. The obtained results are better than the other six methods based on physical or based on GAN, therefore the proposed approach provided a high-quality solution for the endoscopic smoke removal algorithm, which helps doctors get a clear surgical field of vision.
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Received: 02 September 2020
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