Hossein Nejati scite author profile

Abstract-We address the vehicle detection and classification problems using Deep Neural Networks (DNNs) approaches. Here we answer to questions that are specific to our application including how to utilize DNN for vehicle detection, what features are useful for vehicle classification, and how to extend a model trained on a limited size dataset, to the cases of extreme lighting condition. Answering these questions we propose our approach that outperforms state-of-the-art methods, and achieves promising results on image with extreme lighting conditions.

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Neural correlates of the food/non-food visual distinction

Tsourides

Shariat

Nejati

et al. 2016

Biological Psychology

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Dimensionality reduction of brain imaging data using graph signal processing

Liu

Nejati

Cheung

2016

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Fine-Grained Wound Tissue Analysis Using Deep Neural Network

Nejati

Ghazijahani

Abdollahzadeh

et al. 2018

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Tissue assessment for chronic wounds is the basis of wound grading and selection of treatment approaches. While several image processing approaches have been proposed for automatic wound tissue analysis, there has been a shortcoming in these approaches for clinical practices. In particular, seemingly, all previous approaches have assumed only 3 tissue types in the chronic wounds, while these wounds commonly exhibit 7 distinct tissue types that presence of each one changes the treatment procedure. In this paper, for the first time, we investigate the classification of 7 wound tissue types. We work with wound professionals to build a new database of 7 types of wound tissue. We propose to use pre-trained deep neural networks for feature extraction and classification at the patch-level. We perform experiments to demonstrate that our approach outperforms other state-of-the-art. We will make our database publicly available to facilitate research in wound assessment.

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Deep neural networks on graph signals for brain imaging analysis

Guo

Nejati

Cheung

2017

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Brain imaging data such as EEG or MEG are high-dimensional spatiotemporal data often degraded by complex, non-Gaussian noise. For reliable analysis of brain imaging data, it is important to extract discriminative, low-dimensional intrinsic representation of the recorded data. This work proposes a new method to learn the lowdimensional representations from the noise-degraded measurements. In particular, our work proposes a new deep neural network design that integrates graph information such as brain connectivity with fully-connected layers. Our work leverages efficient graph filter design using Chebyshev polynomial and recent work on convolutional nets on graph-structured data. Our approach exploits graph structure as the prior side information, localized graph filter for feature extraction and neural networks for high capacity learning. Experiments on real MEG datasets show that our approach can extract more discriminative representations, leading to improved accuracy in a supervised classification task.

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Simultaneous low-rank component and graph estimation for high-dimensional graph signals: Application to brain imaging

Liu

Nejati

Safavi

et al. 2017

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We propose an algorithm to uncover the intrinsic low-rank component of a high-dimensional, graph-smooth and grossly-corrupted dataset, under the situations that the underlying graph is unknown. Based on a model with a low-rank component plus a sparse perturbation, and an initial graph estimation, our proposed algorithm simultaneously learns the low-rank component and refines the graph. The refined graph improves the effectiveness of the graph smoothness constraint and increases the accuracy of the low-rank estimation. We derive the learning steps using ADMM. Our evaluations using synthetic and real brain imaging data in a supervised classification task demonstrate encouraging performance.

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Smartphone and Mobile Image Processing for Assisted Living: Health-monitoring apps powered by advanced mobile imaging algorithms

Nejati

Pomponiu

et al. 2016

IEEE Signal Process. Mag.

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Hossein Nejati

Deepmole: Deep neural networks for skin mole lesion classification

Image-based vehicle analysis using deep neural network: A systematic study

Neural correlates of the food/non-food visual distinction

Dimensionality reduction of brain imaging data using graph signal processing

Fine-Grained Wound Tissue Analysis Using Deep Neural Network

Deep neural networks on graph signals for brain imaging analysis

Simultaneous low-rank component and graph estimation for high-dimensional graph signals: Application to brain imaging

Smartphone and Mobile Image Processing for Assisted Living: Health-monitoring apps powered by advanced mobile imaging algorithms

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