Related papers: A CNN with Noise Inclined Module and Denoise Framework for Hyperspectral Image Classification

A CNN with Noise Inclined Module and Denoise Framework for Hyperspectral Image Classification

URL: http://arxiv.org/abs/2205.12459v1
Date: Wed, 25 May 2022 03:12:26 GMT
Title: A CNN with Noise Inclined Module and Denoise Framework for Hyperspectral Image Classification
Authors: Zhiqiang Gong and Ping Zhong and Jiahao Qi and Panhe Hu
Abstract summary: This work develops a novel deep learning framework with the noise inclined module and denoise framework for hyperspectral image classification. A noise inclined module is developed to capture the physical noise within each object and a denoise framework is then followed to remove such noise from the object. The CNN with noise inclined module and the denoise framework is developed to obtain discriminative features and provides good classification performance of hyperspectral image.
Score: 7.217678679646926
License: http://creativecommons.org/publicdomain/zero/1.0/
Abstract: Deep Neural Networks have been successfully applied in hyperspectral image classification. However, most of prior works adopt general deep architectures while ignore the intrinsic structure of the hyperspectral image, such as the physical noise generation. This would make these deep models unable to generate discriminative features and provide impressive classification performance. To leverage such intrinsic information, this work develops a novel deep learning framework with the noise inclined module and denoise framework for hyperspectral image classification. First, we model the spectral signature of hyperspectral image with the physical noise model to describe the high intraclass variance of each class and great overlapping between different classes in the image. Then, a noise inclined module is developed to capture the physical noise within each object and a denoise framework is then followed to remove such noise from the object. Finally, the CNN with noise inclined module and the denoise framework is developed to obtain discriminative features and provides good classification performance of hyperspectral image. Experiments are conducted over two commonly used real-world datasets and the experimental results show the effectiveness of the proposed method. The implementation of the proposed method and other compared methods could be accessed at https://github.com/shendu-sw/noise-physical-framework.

Related papers

Deep Learning CT Image Restoration using System Blur and Noise Models [2.2530496464901106]
We present a method that leverages both degraded image inputs and a characterization of the system blur and noise to combine modeling and deep learning approaches. Results demonstrate the efficacy of providing a deep learning model with auxiliary inputs, representing system blur and noise characteristics.
arXiv Detail & Related papers (2024-07-20T21:17:35Z)
Data Augmentation in Training CNNs: Injecting Noise to Images [0.0]
This study analyzes the effects of adding or applying different noise models of varying magnitudes to CNN architectures. Basic results are conforming to the most of the common notions in machine learning. New approaches will provide better understanding on optimal learning procedures for image classification.
arXiv Detail & Related papers (2023-07-12T17:29:42Z)
Learning to Generate Realistic Noisy Images via Pixel-level Noise-aware Adversarial Training [50.018580462619425]
We propose a novel framework, namely Pixel-level Noise-aware Generative Adrial Network (PNGAN) PNGAN employs a pre-trained real denoiser to map the fake and real noisy images into a nearly noise-free solution space. For better noise fitting, we present an efficient architecture Simple Multi-versa-scale Network (SMNet) as the generator.
arXiv Detail & Related papers (2022-04-06T14:09:02Z)
Treatment Learning Causal Transformer for Noisy Image Classification [62.639851972495094]
In this work, we incorporate this binary information of "existence of noise" as treatment into image classification tasks to improve prediction accuracy. Motivated from causal variational inference, we propose a transformer-based architecture, that uses a latent generative model to estimate robust feature representations for noise image classification. We also create new noisy image datasets incorporating a wide range of noise factors for performance benchmarking.
arXiv Detail & Related papers (2022-03-29T13:07:53Z)
Practical Blind Image Denoising via Swin-Conv-UNet and Data Synthesis [148.16279746287452]
We propose a swin-conv block to incorporate the local modeling ability of residual convolutional layer and non-local modeling ability of swin transformer block. For the training data synthesis, we design a practical noise degradation model which takes into consideration different kinds of noise. Experiments on AGWN removal and real image denoising demonstrate that the new network architecture design achieves state-of-the-art performance.
arXiv Detail & Related papers (2022-03-24T18:11:31Z)
Neighbor2Neighbor: Self-Supervised Denoising from Single Noisy Images [98.82804259905478]
We present Neighbor2Neighbor to train an effective image denoising model with only noisy images. In detail, input and target used to train a network are images sub-sampled from the same noisy image. A denoising network is trained on sub-sampled training pairs generated in the first stage, with a proposed regularizer as additional loss for better performance.
arXiv Detail & Related papers (2021-01-08T02:03:25Z)
Reconstructing the Noise Manifold for Image Denoising [56.562855317536396]
We introduce the idea of a cGAN which explicitly leverages structure in the image noise space. By learning directly a low dimensional manifold of the image noise, the generator promotes the removal from the noisy image only that information which spans this manifold. Based on our experiments, our model substantially outperforms existing state-of-the-art architectures.
arXiv Detail & Related papers (2020-02-11T00:31:31Z)
Variational Denoising Network: Toward Blind Noise Modeling and Removal [59.36166491196973]
Blind image denoising is an important yet very challenging problem in computer vision. We propose a new variational inference method, which integrates both noise estimation and image denoising.
arXiv Detail & Related papers (2019-08-29T15:54:06Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.