Search

Your search keyword '"Jang, Hyunsung"' showing total 8 results
Start Over Author "Jang, Hyunsung" Publisher ieee
8 results on '"Jang, Hyunsung"'

1. Learning Deeply Aggregated Alternating Minimization for General Inverse Problems.

Author

Jung, Hyungjoo, Kim, Youngjung, Min, Dongbo, Jang, Hyunsung, Ha, Namkoo, and Sohn, Kwanghoon

Subjects
CONVOLUTIONAL neural networks, INVERSE problems, COMPUTER vision, IMAGE processing
Abstract

Regularization-based image restoration is one of the most powerful tools in image processing and computer vision thanks to its flexibility for handling various inverse problems. However, designing an optimal regularization function still remains unsolved since natural images and related scene types have a complex structure. In this paper, we present a general and principled framework, called deeply aggregated alternating minimization (DeepAM). We design a convolutional neural network (CNN) to implicitly parameterize the regularizer of the alternating minimization (AM) algorithm. Contrary to the conventional AM algorithm based on a point-wise proximal mapping, the DeepAM projects intermediate estimate into a set of natural images via deep aggregation. Since the CNN is fully integrated into the AM procedure, all parameters can be jointly optimized through end-to-end training. These properties enable the DeepAM to converge with a small number of iterations, while maintaining an algorithmic simplicity. We show that the DeepAM outperforms state-of-the-art methods, including nonlocal-based methods, Plug-and-Play regularization, and recent data-driven approaches. The effectiveness of our framework is demonstrated in a variety of image restoration tasks: Guassian denoising, deraining, deblurring, super-resolution, color-guided depth upsampling, and RGB/NIR restoration. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

2. Unsupervised Deep Image Fusion With Structure Tensor Representations.

Author

Jung, Hyungjoo, Kim, Youngjung, Jang, Hyunsung, Ha, Namkoo, and Sohn, Kwanghoon

Subjects
IMAGE fusion, DEEP learning, COMPUTER vision, IMAGE reconstruction, FEATURE extraction, CONVOLUTIONAL neural networks, SUPERVISED learning
Abstract

Convolutional neural networks (CNNs) have facilitated substantial progress on various problems in computer vision and image processing. However, applying them to image fusion has remained challenging due to the lack of the labelled data for supervised learning. This paper introduces a deep image fusion network (DIF-Net), an unsupervised deep learning framework for image fusion. The DIF-Net parameterizes the entire processes of image fusion, comprising of feature extraction, feature fusion, and image reconstruction, using a CNN. The purpose of DIF-Net is to generate an output image which has an identical contrast to high-dimensional input images. To realize this, we propose an unsupervised loss function using the structure tensor representation of the multi-channel image contrasts. Different from traditional fusion methods that involve time-consuming optimization or iterative procedures to obtain the results, our loss function is minimized by a stochastic deep learning solver with large-scale examples. Consequently, the proposed method can produce fused images that preserve source image details through a single forward network trained without reference ground-truth labels. The proposed method has broad applicability to various image fusion problems, including multi-spectral, multi-focus, and multi-exposure image fusions. Quantitative and qualitative evaluations show that the proposed technique outperforms existing state-of-the-art approaches for various applications. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

8. Practical localization system for consumer devices using zigbee networks.

Author

Cho, Hyuntae, Jang, Hyunsung, and Baek, Yunju

Abstract

As the era of ubiquitous computing dawns, there is a growing need for a reliable, efficient positioning and tracking system. A localization system involves ongoing tracking of the location of assets and personnel. This paper presents a practical localization system for consumer devices on Zigbee networks. The proposed system is based on timedifference-of-arrival (TDOA). Localization based on TDOA involves estimating the location of the device by calculating the time-difference-of-arrival of the signal received from a device. In order to calculate the time difference of the signal, TDOA-based methods require precision time measurements of the signal, and reader time synchronization accurate to within a few nanoseconds. We also propose a precise time stamping unit, which enables the system to determine the arrival time of the radio signal, and a precision time synchronization protocol, which enables readers to have a reference clock. In addition, this paper includes an experimental performance evaluation of the localization system. The performance shows that the localization system has a DRMS of approximately two meters in a harsh environment. [ABSTRACT FROM PUBLISHER]

Published
2010
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results