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Abstract
Even though computer vision has been developing, edge detection is still one of the challenges in that field. It comes from the limitations of the complementary metal oxide semiconductor (CMOS) Image sensor used to collect the image data, and then image signal processor (ISP) is additionally required to understand the information received from each pixel and performs certain processing operations for edge detection. Even with/without ISP, as an output of hardware (camera, ISP), the original image is too raw to proceed edge detection image, because it can include extreme brightness and contrast, which is the key factor of image for edge detection. To reduce the onerousness, we propose a pre-processing method to obtain optimized brightness and contrast for improved edge detection. In the pre-processing, we extract meaningful features from image information and perform machine learning such as k-nearest neighbor (KNN), multilayer perceptron (MLP) and support vector machine (SVM) to obtain enhanced model by adjusting brightness and contrast. The comparison results of F1 score on edgy detection image of non-treated, pre-processed and pre-processed with machine learned are shown. The pre-processed with machine learned F1 result shows an average of 0.822, which is 2.7 times better results than the non-treated one. Eventually, the proposed pre-processing and machine learning method is proved as the essential method of pre-processing image from ISP in order to gain better edge detection image. In addition, if we go through the pre-processing method that we proposed, it is possible to more clearly and easily determine the object required when performing auto white balance (AWB) or auto exposure (AE) in the ISP. It helps to perform faster and more efficiently through the proactive ISP.
Highlights
Published: 11 January 2021After the invention of camera, the quality of image from machinery has been continuously improved and it is easy to access the image data
The complementary metal oxide semiconductor (CMOS) image sensor can be mass-produced through the application of a logic large scale integration (LSI) manufacturing processor; it has the advantage of low manufacturing cost and low power consumption due to its small device size compared to a charge coupled device (CCD) image sensor having a high voltage analog circuit
The most of testing set is categorized in type F, H, E, B we compare F1 score of these types to test the performance of our method comparing original image without pre-processing with pre-processing in BIPED dataset
Summary
After the invention of camera, the quality of image from machinery has been continuously improved and it is easy to access the image data. It is recognized as the main data itself and is used to extract additional information through complex data processing using artificial intelligence (AI) [1]. The CMOS Image Sensor is one of the microelectromechanical systems (MEMS) related image data expected to combine with different devices such as visible light communication (VLC), light detection and ranging (LiDAR), Optical ID tags, etc. Edge detection is fundamentally important because they can quickly determine the boundaries of objects in an image [3]. Edge detection is performed to simplify the image in order to minimize the amount of data to be processed
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