Going Deeper With Contextual CNN for Hyperspectral Image Classification

Lee, Hyungtae; Kwon, Heesung

doi:10.1109/tip.2017.2725580

Cited by 836 publications

(441 citation statements)

References 43 publications

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“…When using the multi-scale filters for feature extraction, we choose a method that differs from the one-time convolution used in many current studies [17], which focuses on using the multi-scale filters to convolve the original input data, then integrating the feature maps generated by the process and inputting them into the following network with convolution based on one fixed-scale filter. We utilize multi-scale filters to extract hierarchical features several times.…”

Section: Architecture Of the Proposed Networkmentioning

confidence: 99%

“…To test the effectiveness and practicability of the proposed method, we introduced five kinds of networks similar to the proposed method: DNN [47], URDNN [48], contextual deep CNN [17], two-stream neural network [26] and SAE + SVM [49]. DNN uses deconvolution to realize an end-to-end, pixel-to-pixel classification.…”

Section: Contrast Experiments With Other Networkmentioning

confidence: 99%

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DenseNet-Based Depth-Width Double Reinforced Deep Learning Neural Network for High-Resolution Remote Sensing Image Per-Pixel Classification

Tao

et al. 2018

Remote Sensing

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Abstract:Deep neural networks (DNNs) face many problems in the very high resolution remote sensing (VHRRS) per-pixel classification field. Among the problems is the fact that as the depth of the network increases, gradient disappearance influences classification accuracy and the corresponding increasing number of parameters to be learned increases the possibility of overfitting, especially when only a small amount of VHRRS labeled samples are acquired for training. Further, the hidden layers in DNNs are not transparent enough, which results in extracted features not being sufficiently discriminative and significant amounts of redundancy. This paper proposes a novel depth-width-reinforced DNN that solves these problems to produce better per-pixel classification results in VHRRS. In the proposed method, densely connected neural networks and internal classifiers are combined to build a deeper network and balance the network depth and performance. This strengthens the gradients, decreases negative effects from gradient disappearance as the network depth increases and enhances the transparency of hidden layers, making extracted features more discriminative and reducing the risk of overfitting. In addition, the proposed method uses multi-scale filters to create a wider neural network. The depth of the filters from each scale is controlled to decrease redundancy and the multi-scale filters enable utilization of joint spatio-spectral information and diverse local spatial structure simultaneously. Furthermore, the concept of network in network is applied to better fuse the deeper and wider designs, making the network operate more smoothly. The results of experiments conducted on BJ02, GF02, geoeye and quickbird satellite images verify the efficacy of the proposed method. The proposed method not only achieves competitive classification results but also proves that the network can continue to be robust and perform well even while the amount of labeled training samples is decreasing, which fits the small training samples situation faced by VHRRS per-pixel classification.

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Section: Architecture Of the Proposed Networkmentioning

confidence: 99%

Section: Contrast Experiments With Other Networkmentioning

confidence: 99%

DenseNet-Based Depth-Width Double Reinforced Deep Learning Neural Network for High-Resolution Remote Sensing Image Per-Pixel Classification

Tao

et al. 2018

Remote Sensing

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“…A deep neural network (DNN) is a kind of machine learning method; the basic idea is to build a neural network model containing multiple hidden layers, which needs a large amount of training data to train the network model. There are already many supervised DNN methods [12,[14][15][16][17][22][23][24][25][26]. In [22], deep convolutional neural networks (DCNNs) are employed to classify HSIs directly in the spectral domain.…”

Section: Related Workmentioning

confidence: 99%

When Low Rank Representation Based Hyperspectral Imagery Classification Meets Segmented Stacked Denoising Auto-Encoder Based Spatial-Spectral Feature

2018

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When confronted with limited labelled samples, most studies adopt an unsupervised feature learning scheme and incorporate the extracted features into a traditional classifier (e.g., support vector machine, SVM) to deal with hyperspectral imagery classification. However, these methods have limitations in generalizing well in challenging cases due to the limited representative capacity of the shallow feature learning model, as well as the insufficient robustness of the classifier which only depends on the supervision of labelled samples. To address these two problems simultaneously, we present an effective low-rank representation-based classification framework for hyperspectral imagery. In particular, a novel unsupervised segmented stacked denoising auto-encoder-based feature learning model is proposed to depict the spatial-spectral characteristics of each pixel in the imagery with deep hierarchical structure. With the extracted features, a low-rank representation based robust classifier is then developed which takes advantage of both the supervision provided by labelled samples and unsupervised correlation (e.g., intra-class similarity and inter-class dissimilarity, etc.) among those unlabelled samples. Both the deep unsupervised feature learning and the robust classifier benefit, improving the classification accuracy with limited labelled samples. Extensive experiments on hyperspectral imagery classification demonstrate the effectiveness of the proposed framework.

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“…Alexnet is a deep CNN created by Alex Krizhevsky, Ilya Sutskever, and Geoffrey E. Hinton which is trained with over a million images from 1000 different classes [20]. Alexnet consists of five convolutional layers and three fully connected layers [21]. Figure 1 shows all the steps of the experiment.…”

Section: E Alexnetmentioning

confidence: 99%

An analysis of Feature extraction and Classification Algorithms for Dangerous Object Detection

Kibria

Hasan

2017

2017 2nd International Conference on Electrical &Amp; Electronic Engineering (ICEEE)

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Abstract-One of the important practical applications of object detection and image classification can be for security enhancement. If dangerous objects e.g. knives can be identified automatically, then a lot of violence can be prevented. For this purpose, various different algorithms and methods are out there that can be used. In this paper, four of them have been investigated to find out which can identify knives from a dataset of images more accurately. Among Bag of Words, HOG-SVM, CNN and pre-trained Alexnet CNN, the deep learning CNN methods are found to give best results, though they consume significantly more resources.

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Going Deeper With Contextual CNN for Hyperspectral Image Classification

Cited by 836 publications

References 43 publications

DenseNet-Based Depth-Width Double Reinforced Deep Learning Neural Network for High-Resolution Remote Sensing Image Per-Pixel Classification

DenseNet-Based Depth-Width Double Reinforced Deep Learning Neural Network for High-Resolution Remote Sensing Image Per-Pixel Classification

When Low Rank Representation Based Hyperspectral Imagery Classification Meets Segmented Stacked Denoising Auto-Encoder Based Spatial-Spectral Feature

An analysis of Feature extraction and Classification Algorithms for Dangerous Object Detection

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