WiMi Hologram Cloud a leading global Hologram Augmented Reality (“AR”) Technology provider announced that its R&D team is working on machine learning-based multi-focus image fusion technology, which utilizes deep learning algorithms to process and analyze input images for more accurate and realistic fusion results.

The machine learning-based multi-focus image fusion researched by WiMi requires multiple steps of processing and analysis to get the final image fusion result. These steps need to consider various factors such as application scenarios, data quality, model design, etc. to get better results and performance.

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Data pre-processing: The input multiple images are subjected to pre-processing operations such as denoising, alignment, depth estimation, etc. to improve the accuracy and effectiveness of subsequent processing.

Feature extraction: Pre-processed multiple images are input into the deep learning model, and the input images are feature extracted and abstracted using models such as CNN to obtain a feature vector representation of each pixel. These feature vectors contain more semantic information and advanced features, thus improving the accuracy and effectiveness of subsequent processing.

Selection and training of models: Appropriate machine learning models are selected based on the application scenarios and requirements, and trained and tuned using training data to get the best fusion results. These models can be based on different types of models such as classification, regression, generative adversarial network (GAN), etc. The specific selection needs to be based on the application scenario and requirements.

Fusion Output: The trained model is applied to the image data to classify or regress each pixel to get the final fusion results. These results can be of different types such as weighted average, probability statistics, least squares, etc.

The steps of machine learning-based multi-focus image fusion technology are not linear, and the steps may affect each other or cross over. For example, when applying CNN for feature extraction, operations such as data enhancement and batch normalization may be required; during model training, operations such as hyper-parameter adjustment and regularization may be required. In addition, due to the limitation of computational resources and time, the specific implementation of each step may also vary depending on the application scenario.

The machine learning-based multi-focus image fusion technology researched by WiMi has been greatly improved and upgraded over traditional methods in several aspects. It can not only improve the speed and accuracy of image processing, but also deal with more complex and diverse image data, providing better image processing solutions for various fields, and it has the advantages of strong adaptability, strong generalization ability, fast processing speed and high processing accuracy. The traditional multi-focus image fusion technology usually adopts the pixel-level fusion method, which lacks the understanding and analysis of the image content, and the machine learning-based multi-focus image fusion technology can adaptively adjust and optimize according to the content and characteristics of the input image, to obtain more accurate and realistic fusion results. At the same time, it can not only deal with image data under different scenes and different lighting conditions, but also deal with image data under different equipment and different shooting parameters, which has strong generalization ability and can deal with more complex and diversified image data. In addition, the machine learning-based multi-focus image fusion technology uses deep learning models such as CNN, which have the ability of efficient parallel computing, can complete the processing and analysis of a large amount of image data in a short period, and can further improve the image processing accuracy through model training and tuning.

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With the continuous development and improvement of deep learning algorithms, there are more and more demands for image analysis and processing. Multi-focus image fusion technology based on machine learning will receive wider attention and application under this trend. On the one hand, with the continuous optimization and improvement of deep learning algorithms, this technology can further improve the speed and accuracy of image processing, so as to better meet the needs for image analysis and processing in various fields. On the other hand, with the continuous increase in computing resources and the continuous improvement of computing power, the multi-focus image fusion technology based on machine learning can process large-scale image data more efficiently and be applied to more new scenes and fields, which can be applied to many fields such as medicine, machine vision, intelligent security, etc., and has a wide range of prospects for application and commercial value.

The future development direction of machine learning-based multi-focus image fusion technology includes multi-modal fusion, model optimization, algorithm expansion and application expansion, etc. WiMi will also continue to improve the multi-modal fusion and model performance of its technology and broaden the scope of application, so as to promote the application of machine learning-based multi-focus image fusion technology in the actual scene.

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