Hyo-Young Hyun scite author profile

Hyo-Young Hyun

5Publications

11Citation Statements Received

25Citation Statements Given

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Kyungpook National University

Publications

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Retina-Motivated CMOS Vision Chip Based on Column Parallel Architecture and Switch-Selective Resistive Network

Kong¹,

Hyun²,

Seo³

et al. 2008

ETRI Journal

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A bio‐inspired vision chip for edge detection was fabricated using 0.35 μm double‐poly four‐metal complementary metal‐oxide‐semiconductor technology. It mimics the edge detection mechanism of a biological retina. This type of vision chip offer several advantages including compact size, high speed, and dense system integration. Low resolution and relatively high power consumption are common limitations of these chips because of their complex circuit structure. We have tried to overcome these problems by rearranging and simplifying their circuits. A vision chip of 160×120 pixels has been fabricated in 5×5 mm2 silicon die. It shows less than 10 mW of power consumption.

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Fundamental research of the target tracking system using a CMOS vision chip for edge detection

Hyun¹,

Kong²,

Shin³

2009

Journal of Sensor Science and Technology

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A 160×120 Edge Detection Vision Chip for Neuromorphic Systems Using Logarithmic Active Pixel Sensor with Low Power Dissipation

Kong

Sung

Hyun

et al.

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The effect of body bias of the metal-oxide-semiconductor field-effect transistor in the resistive network on spatial current distribution in a bio-inspired complementary metal-oxide-semiconductor vision chip

Kong

Hyun

Seo

et al. 2008

OPT REV

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Analysis of the resistive network in a bio-inspired CMOS vision chip

Kong

Sung

Hyun

et al. 2007

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CMOS vision chips for edge detection based on a resistive circuit have recently been developed. These chips help develop neuromorphic systems with a compact size, high speed of operation, and low power dissipation. The output of the vision chip depends dominantly upon the electrical characteristics of the resistive network which consists of a resistive circuit. In this paper, the body effect of the MOSFET for current distribution in a resistive circuit is discussed with a simple model. In order to evaluate the model, two 160×120 CMOS vision chips have been fabricated by using a standard CMOS technology. The experimental results have been nicely matched with our prediction.

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Hyo-Young Hyun

Retina-Motivated CMOS Vision Chip Based on Column Parallel Architecture and Switch-Selective Resistive Network

Fundamental research of the target tracking system using a CMOS vision chip for edge detection

A 160×120 Edge Detection Vision Chip for Neuromorphic Systems Using Logarithmic Active Pixel Sensor with Low Power Dissipation

The effect of body bias of the metal-oxide-semiconductor field-effect transistor in the resistive network on spatial current distribution in a bio-inspired complementary metal-oxide-semiconductor vision chip

Analysis of the resistive network in a bio-inspired CMOS vision chip

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