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Taeseong Kim

Status
Master student
Mail
hakts189@knu.ac.kr
1 more property
Education
MS. | Electronic and Electrical Engineering at Kyungpook National University (Mar. 2024 - current)
BS. | Electronics Engineering at Kyungpook National University (Mar. 2017 - Feb. 2024)
Research Experience
Reseach Intern | ICE at Kyungpook National University (Jun. 2023 - Feb. 2024)
Research Interest
1. AI Accelerator Design
2. Digital Circuit Design w/ DFT
Publication
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International Journal (SCOPUS)
1
Area- and Energy-Efficient Ternary D Flip-Flop Design -Journal of Sensor Science and Technology | Korea Science
In this study, we propose a ternary D flip-flop using tristate ternary inverters for an energy-efficient ternary circuit design of sequential logic. The tristate ternary inverter is designed by adding the functionality of the transmission gate to a standard ternary inverter without an additional transistor. The proposed flip-flop uses 18.18% fewer transistors than conventional flip-flops do. To verify the advancement of the proposed circuit, we conducted an HSPICE simulation with CMOS 28 nm technology and 0.9 V supply voltage. The simulation results demonstrate that the proposed flip-flop is better than the conventional flip-flop in terms of energy efficiency. The power consumption and worst delay are improved by 11.34% and 28.22%, respectively. The power-delay product improved by 36.35%. The above simulation results show that the proposed design can expand the Pareto frontier of a ternary flip-flop in terms of energy consumption. We expect that the proposed ternary flip-flop will contribute to the development of energy-efficient sensor systems, such as ternary successive approximation register analog-to-digital converters.
https://koreascience.kr/article/JAKO202417172006545.page
Area-and Energy-Efficient Ternary D Flip-Flop Design
Journal of Sensor Science and Technology
Journal Club (Jul. 2023 - Current)
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2025 first half
5
2024 second half
4
Analyzing and Improving the Image Quality of StyleGAN
Unsupervised Anomaly Detection of a Home Appliance by Monitoring EMI Data
A New Zero-Overhead Test Method for Low-Power AI Accelerators | IEEE Journals & Magazine | IEEE Xplore
Artificial intelligence (AI) accelerators that support AI services consist of multiple identical cores for parallel computation to accelerate artificial neural networks. Recently, systolic array-based architectures for low-power AI accelerators have been studied to support battery-operated edge devices and reduce power consumption. In this brief, a zero-overhead method is proposed for efficient testing of systolic array-based low-power AI accelerators. By using the structural characteristics of the systolic array and a reset operation, the proposed method can test multiple identical cores based on the systolic array without any additional hardware. The proposed method is divided into MAC and comparator test methods to use the structural characteristics of systolic arrays for low-power AI accelerators. The experimental results demonstrate that the proposed method achieves 100% test coverage without any additional hardware and has reasonable test times compared to previous methods.
https://ieeexplore.ieee.org/document/10366839
A New Zero-Overhead Test Method for Low-Power AI Accelerators
Generating Single- and Double-Pattern Tests for Multiple CMOS Fault Models in One ATPG Run
2024 first half
5
Scan Cell Modification for Intra Cell-Aware Scan Chain Diagnosis
A Bypassable Scan Flip-Flop for Low Power Testing With Data Retention Capabilit
A High-Speed Low-Noise Comparator With Auxiliary-Inverter-Based Common Mode-Self-Regulation for Low-Supply-Voltage SAR ADCs
A Reusable Code-Based SAR ADC Design With CDAC Compiler and Synthesizable Analog Building Blocks | IEEE Journals & Magazine | IEEE Xplore
This brief proposes a code-reusable design methodology for synthesizable successive approximation register (SAR) ADCs based on the digital design flow to significantly reduce design effort. The SAR ADCs are composed of a capacitor-DAC (CDAC) macro cell generated by a CDAC compiler and analog functional blocks implemented utilizing digital standard cells. Two prototypes of SAR ADCs (12-bit 100 kS/s and 11-bit 50 MS/s) are fabricated in different CMOS processes (180 nm and 28 nm). The prototype ADCs prove the effectiveness of the proposed design methodology with comparable performances with full-custom designed SAR ADCs.
https://ieeexplore.ieee.org/document/8331129
A Reusable Code-Based SAR ADC Design With CDAC Compiler and Synthesizable Analog Building Blocks
2023 second half
5