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Your search keyword '"Kuk-Jin Yoon"' showing total 63 results
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63 results on '"Kuk-Jin Yoon"'

1. Deep-learning-based gas identification by time-variant illumination of a single micro-LED-embedded gas sensor

Author

Incheol Cho, Kichul Lee, Young Chul Sim, Jae-Seok Jeong, Minkyu Cho, Heechan Jung, Mingu Kang, Yong-Hoon Cho, Seung Chul Ha, Kuk-Jin Yoon, and Inkyu Park

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Abstract Electronic nose (e-nose) technology for selectively identifying a target gas through chemoresistive sensors has gained much attention for various applications, such as smart factory and personal health monitoring. To overcome the cross-reactivity problem of chemoresistive sensors to various gas species, herein, we propose a novel sensing strategy based on a single micro-LED (μLED)-embedded photoactivated (μLP) gas sensor, utilizing the time-variant illumination for identifying the species and concentrations of various target gases. A fast-changing pseudorandom voltage input is applied to the μLED to generate forced transient sensor responses. A deep neural network is employed to analyze the obtained complex transient signals for gas detection and concentration estimation. The proposed sensor system achieves high classification (~96.99%) and quantification (mean absolute percentage error ~ 31.99%) accuracies for various toxic gases (methanol, ethanol, acetone, and nitrogen dioxide) with a single gas sensor consuming 0.53 mW. The proposed method may significantly improve the efficiency of e-nose technology in terms of cost, space, and power consumption.

Published
2023
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2. Artificial Olfactory Neuron for an In‐Sensor Neuromorphic Nose

Author

Joon‐Kyu Han, Mingu Kang, Jaeseok Jeong, Incheol Cho, Ji‐Man Yu, Kuk‐Jin Yoon, Inkyu Park, and Yang‐Kyu Choi

Subjects
electronic nose (E‐nose), electronic sommelier, neuromorphic system, olfactory neuron, spiking neural network (SNN), Science
Abstract

Abstract A neuromorphic module of an electronic nose (E‐nose) is demonstrated by hybridizing a chemoresistive gas sensor made of a semiconductor metal oxide (SMO) and a single transistor neuron (1T‐neuron) made of a metal‐oxide‐semiconductor field‐effect transistor (MOSFET). By mimicking a biological olfactory neuron, it simultaneously detects a gas and encoded spike signals for in‐sensor neuromorphic functioning. It identifies an odor source by analyzing the complicated mixed signals using a spiking neural network (SNN). The proposed E‐nose does not require conversion circuits, which are essential for processing the sensory signals between the sensor array and processors in the conventional bulky E‐nose. In addition, they do not have to include a central processing unit (CPU) and memory, which are required for von Neumann computing. The spike transmission of the biological olfactory system, which is known to be the main factor for reducing power consumption, is realized with the SNN for power savings compared to the conventional E‐nose with a deep neural network (DNN). Therefore, the proposed neuromorphic E‐nose is promising for application to Internet of Things (IoT), which demands a highly scalable and energy‐efficient system. As a practical example, it is employed as an electronic sommelier by classifying different types of wines.

Published
2022
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46. Ultra-Low-Power E-Nose System Based on Multi-Micro-LED-Integrated, Nanostructured Gas Sensors and Deep Learning

Author

Kichul Lee, Incheol Cho, Mingu Kang, Jaeseok Jeong, Minho Choi, Kie Young Woo, Kuk-Jin Yoon, Yong-Hoon Cho, and Inkyu Park

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

As interests in air quality monitoring related to environmental pollution and industrial safety increase, demands for gas sensors are rapidly increasing. Among various gas sensor types, the semiconductor metal oxide (SMO)-type sensor has advantages of high sensitivity, low cost, mass production, and small size but suffers from poor selectivity. To solve this problem, electronic nose (e-nose) systems using a gas sensor array and pattern recognition are widely used. However, as the number of sensors in the e-nose system increases, total power consumption also increases. In this study, an ultra-low-power e-nose system was developed using ultraviolet (UV) micro-LED (μLED) gas sensors and a convolutional neural network (CNN). A monolithic photoactivated gas sensor was developed by depositing a nanocolumnar In

Published
2022

47. Deep Learning for HDR Imaging: State-of-the-Art and Future Trends

Author

Lin Wang and Kuk-Jin Yoon

Subjects
Diagnostic Imaging, FOS: Computer and information sciences, Computer Science - Machine Learning, Computer science, Computer Vision and Pattern Recognition (cs.CV), Computer Science - Computer Vision and Pattern Recognition, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Image processing, Field (computer science), Machine Learning (cs.LG), Computer graphics, Deep Learning, Artificial Intelligence, Human–computer interaction, Image Processing, Computer-Assisted, Computer Graphics, FOS: Electrical engineering, electronic engineering, information engineering, High dynamic range, Point (typography), business.industry, Applied Mathematics, Deep learning, Image and Video Processing (eess.IV), Electrical Engineering and Systems Science - Image and Video Processing, Computational Theory and Mathematics, Computer Vision and Pattern Recognition, Artificial intelligence, State (computer science), business, Algorithms, Software
Abstract

High dynamic range (HDR) imaging is a technique that allows an extensive dynamic range of exposures, which is important in image processing, computer graphics, and computer vision. In recent years, there has been a significant advancement in HDR imaging using deep learning (DL). This study conducts a comprehensive and insightful survey and analysis of recent developments in deep HDR imaging methodologies. We hierarchically and structurally group existing deep HDR imaging methods into five categories based on (1) number/domain of input exposures, (2) number of learning tasks, (3) novel sensor data, (4) novel learning strategies, and (5) applications. Importantly, we provide a constructive discussion on each category regarding its potential and challenges. Moreover, we review some crucial aspects of deep HDR imaging, such as datasets and evaluation metrics. Finally, we highlight some open problems and point out future research directions., Comment: IEEE Transactions on Pattern Analysis and Machine Intelligence (TPAMI), main and suppl. material

Published
2022

48. Joint Framework for Single Image Reconstruction and Super-Resolution With an Event Camera

Author

Kuk-Jin Yoon, Lin Wang, and Tae-Kyun Kim

Subjects
Ground truth, Network architecture, Event (computing), business.industry, Computer science, Applied Mathematics, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Cognitive neuroscience of visual object recognition, Iterative reconstruction, Image (mathematics), Computational Theory and Mathematics, Artificial Intelligence, Computer vision, Segmentation, Computer Vision and Pattern Recognition, Artificial intelligence, business, Image resolution, Software
Abstract

Event cameras sense brightness changes in each pixel and yield asynchronous event streams instead of producing intensity images. They have distinct advantages over conventional cameras, such as a high dynamic range (HDR) and no motion blur. To take advantage of event cameras with existing image-based algorithms, a few methods have been proposed to reconstruct images from event streams. However, the output images have a low resolution (LR) and are unrealistic. Low-quality outputs stem from broader applications of event cameras, where high-quality and high-resolution (HR) images are needed. In this work, we consider the problem of reconstructing and super-resolving images from LR events when no ground truth (GT) HR images and degradation models are available. We propose a novel end-to-end joint framework for single image reconstruction and super-resolution from LR event data. Our method is primarily unsupervised to handle the absence of real inputs from GT and deploys adversarial learning. To train our framework, we constructed an open dataset, including simulated events and real-world images. The use of the dataset boosts the network performance, and the network architectures and various loss functions in each phase help improve the quality of the resulting image. Various experiments showed that our method surpasses the state-of-the-art LR image reconstruction methods for real-world and synthetic datasets. The experiments for super-resolution (SR) image reconstruction also substantiate the effectiveness of the proposed method. We further extended our method to more challenging problems of HDR, sharp image reconstruction, and color events. In addition, we demonstrate that the reconstruction and super-resolution results serve as intermediate representations of events for high-level tasks, such as semantic segmentation, object recognition, and detection. We further examined how events affect the outputs of the three phases and analyze our method's efficacy through an ablation study.

Published
2022

49. SpherePHD: Applying CNNs on 360 Images With Non-Euclidean Spherical PolyHeDron Representation

Author

Jaeseok Jeong, Jongseob Yun, Yeonkun Lee, Wonjune Cho, and Kuk-Jin Yoon

Subjects
Pixel, Orientation (computer vision), business.industry, Computer science, Applied Mathematics, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 02 engineering and technology, Ellipse, Convolutional neural network, Object detection, Convolution, Computational Theory and Mathematics, Kernel (image processing), Artificial Intelligence, Non-Euclidean geometry, Computer Science::Computer Vision and Pattern Recognition, Distortion, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Computer vision, Computer Vision and Pattern Recognition, Artificial intelligence, Representation (mathematics), business, Software
Abstract

Omni-directional images are becoming more prevalent for understanding the scene of all directions around a camera, as they provide a much wider field-of-view (FoV) compared to conventional images. In this work, we present a novel approach to represent omni-directional images and suggest how to apply CNNs on the proposed image representation. The proposed image representation method utilizes a spherical polyhedron to reduce distortion introduced inevitably when sampling pixels on a non-Euclidean spherical surface around the camera center. To apply convolution operation on our representation of images, we stack the neighboring pixels on top of each pixel and multiply with trainable parameters. This approach enables us to apply the same CNN architectures used in conventional Euclidean 2D images on our proposed method in a straightforward manner. Compared to the previous work, we additionally compare different designs of kernels that can be applied to our proposed method. We also show that our method outperforms in monocular depth estimation task compared to other state-of-the-art representation methods of omni-directional images. In addition, we propose a novel method to fit bounding ellipses of arbitrary orientation using object detection networks and apply it to an omni-directional real-world human detection dataset.

Published
2022

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