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2020 – today
- 2024
[j12]Yumito Aoyagi
, Koji Nii, Makoto Yabuuchi, Tomotaka Tanaka, Yuichiro Ishii, Yoshiaki Osada, Takaaki Nakazato, Isabel Wang, Yu-Hao Hsu, Hong-Chen Cheng, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
A 3-nm FinFET 27.6-Mbit/mm2 Single-Port 6T SRAM Enabling 0.48-1.2 V Wide Operating Range With Far-End Pre-Charge and Weak-Bit Tracking. IEEE J. Solid State Circuits 59(4): 1225-1234 (2024)- [c29]Hidehiro Fujiwara, Haruki Mori, Wei-Chang Zhao, Kinshuk Khare, Cheng-En Lee, Xiaochen Peng, Vineet Joshi, Chao-Kai Chuang, Shu-Huan Hsu, Takeshi Hashizume, Toshiaki Naganuma, Chen-Hung Tien, Yao-Yi Liu, Yen-Chien Lai, Chia-Fu Lee, Tan-Li Chou, Kerem Akarvardar, Saman Adham, Yih Wang, Yu-Der Chih, Yen-Huei Chen, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
34.4 A 3nm, 32.5TOPS/W, 55.0TOPS/mm2 and 3.78Mb/mm2 Fully-Digital Compute-in-Memory Macro Supporting INT12 × INT12 with a Parallel-MAC Architecture and Foundry 6T-SRAM Bit Cell. ISSCC 2024: 572-574 - [c28]Ming-Chieh Huang, Wei Wing Mar, Shankar Kanade, Boris Bai, Aditya Gayatri, Krishna Khairnar, Amy Lai, Yu-Hao Hsu, Hung-Jen Liao, Yih Wang, Tsung-Yung Jonathan Chang:
A 3.3GHz 1024X640 Multi-Bank Single-Port SRAM with Frequency Enhancing Techniques and 0.55V-1.35V Wide Voltage Range Operation in 3nm FinFET for HPC Applications. VLSI Technology and Circuits 2024: 1-2 - [c27]Tomotaka Tanaka, Yuichiro Ishii, Makoto Yabuuchi, Yumito Aoyagi, Masaya Hamada, Kazuto Mizutani, Koji Nii, Hidehiro Fujiwara, Isabel Wang, Hong-Chen Cheng, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
A 3nm Fin-FET 19.87-Mbit/mm2 2RW Pseudo Dual-Port 6T SRAM with High-R Wire Tracking and Sequential Access Aware Dynamic Power Reduction. VLSI Technology and Circuits 2024: 1-2 - 2023
- [c26]Haruki Mori, Wei-Chang Zhao, Cheng-En Lee, Chia-Fu Lee, Yu-Hao Hsu, Chao-Kai Chuang, Takeshi Hashizume, Hao-Chun Tung, Yao-Yi Liu, Shin-Rung Wu, Kerem Akarvardar, Tan-Li Chou, Hidehiro Fujiwara, Yih Wang, Yu-Der Chih, Yen-Huei Chen, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
A 4nm 6163-TOPS/W/b $\mathbf{4790-TOPS/mm^{2}/b}$ SRAM Based Digital-Computing-in-Memory Macro Supporting Bit-Width Flexibility and Simultaneous MAC and Weight Update. ISSCC 2023: 132-133 - [c25]Yumito Aoyagi, Makoto Yabuuchi, Tomotaka Tanaka, Yuichiro Ishii, Yoshiaki Osada, Takaaki Nakazato, Koji Nii, Isabel Wang, Yu-Hao Hsu, Hong-Chen Cheng, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
A 3-nm 27.6-Mbit/mm2 Self-timed SRAM Enabling 0.48 - 1.2 V Wide Operating Range with Far-end Pre-charge and Weak-Bit Tracking. VLSI Technology and Circuits 2023: 1-2 - [c24]Jonathan Chang, Yen-Huei Chen, Gary Chan, Kuo-Cheng Lin, Po-Sheng Wang, Yangsyu Lin, Sevic Chen, Peijiun Lin, Ching-Wei Wu, Chih-Yu Lin, Yi-Hsin Nien, Hidehiro Fujiwara, Atul Katoch, Robin Lee, Hung-Jen Liao, Jhon-Jhy Liaw, Shien-Yang Michael Wu, Quincy Li:
A 3nm 256Mb SRAM in FinFET Technology with New Array Banking Architecture and Write-Assist Circuitry Scheme for High-Density and Low-VMIN Applications. VLSI Technology and Circuits 2023: 1-2 - [c23]Yoshiaki Osada, Takaaki Nakazato, Koji Nii, Jhon-Jhy Liaw, Shien-Yang Michael Wu, Quincy Li, Hidehiro Fujiwara, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
3.7-GHz Multi-Bank High-Current Single-Port Cache SRAM with 0.5V-1.4V Wide Voltage Range Operation in 3nm FinFET for HPC Applications. VLSI Technology and Circuits 2023: 1-2 - [c22]Nick Zhang, Young Suk Kim, Peter Hsu, Samsoo Kim, Derek Tao, Hung-Jen Liao, Ping-Wei Wang, Geoffrey Yeap, Quincy Li, Tsung-Yung Jonathan Chang:
A 4.24GHz 128X256 SRAM Operating Double Pump Read Write Same Cycle in 5nm Technology. VLSI Technology and Circuits 2023: 1-2 - 2022
- [c21]Hidehiro Fujiwara, Haruki Mori, Wei-Chang Zhao, Mei-Chen Chuang, Rawan Naous, Chao-Kai Chuang, Takeshi Hashizume, Dar Sun, Chia-Fu Lee, Kerem Akarvardar, Saman Adham, Tan-Li Chou, Mahmut Ersin Sinangil, Yih Wang, Yu-Der Chih, Yen-Huei Chen, Hung-Jen Liao, Tsung-Yung Jonathan Chang:
A 5-nm 254-TOPS/W 221-TOPS/mm2 Fully-Digital Computing-in-Memory Macro Supporting Wide-Range Dynamic-Voltage-Frequency Scaling and Simultaneous MAC and Write Operations. ISSCC 2022: 1-3 - [c20]Nail Etkin Can Akkaya, Gary Chan, Hung-Jen Liao, Yih Wang, Jonathan Chang:
A 135.6Tbps/W 2R2W SRAM with 12T Logic Bit-cell with Vmin Down to 335mV Targeted for Machine-Learning Applications in 6nm FinFET CMOS Technology. VLSI Technology and Circuits 2022: 110-111 - 2021
- [j11]Tsung-Yung Jonathan Chang, Yen-Huei Chen, Wei-Min Chan, Hank Cheng, Po-Sheng Wang, Yangsyu Lin, Hidehiro Fujiwara, Robin Lee, Hung-Jen Liao, Ping-Wei Wang, Geoffrey Yeap, Quincy Li:
A 5-nm 135-Mb SRAM in EUV and High-Mobility Channel FinFET Technology With Metal Coupling and Charge-Sharing Write-Assist Circuitry Schemes for High-Density and Low-VMIN Applications. IEEE J. Solid State Circuits 56(1): 179-187 (2021) - [j10]Mahmut E. Sinangil, Burak Erbagci, Rawan Naous, Kerem Akarvardar, Dar Sun, Win-San Khwa, Hung-Jen Liao, Yih Wang, Jonathan Chang:
A 7-nm Compute-in-Memory SRAM Macro Supporting Multi-Bit Input, Weight and Output and Achieving 351 TOPS/W and 372.4 GOPS. IEEE J. Solid State Circuits 56(1): 188-198 (2021) - [c19]Yu-Der Chih, Po-Hao Lee, Hidehiro Fujiwara, Yi-Chun Shih, Chia-Fu Lee, Rawan Naous, Yu-Lin Chen, Chieh-Pu Lo, Cheng-Han Lu, Haruki Mori, Wei-Cheng Zhao, Dar Sun, Mahmut E. Sinangil, Yen-Huei Chen, Tan-Li Chou, Kerem Akarvardar, Hung-Jen Liao, Yih Wang, Meng-Fan Chang, Tsung-Yung Jonathan Chang:
An 89TOPS/W and 16.3TOPS/mm2 All-Digital SRAM-Based Full-Precision Compute-In Memory Macro in 22nm for Machine-Learning Edge Applications. ISSCC 2021: 252-254 - [c18]Hidehiro Fujiwara, Yi-Hsin Nien, Chih-Yu Lin, Hsien-Yu Pan, Hao-Wen Hsu, Shin-Rung Wu, Yao-Yi Liu, Yen-Huei Chen, Hung-Jen Liao, Jonathan Chang:
A 5nm 5.7GHz@1.0V and 1.3GHz@0.5V 4kb Standard-Cell- Based Two-Port Register File with a 16T Bitcell with No Half-Selection Issue. ISSCC 2021: 340-342 - [c17]Hung-Jen Liao, Chin-Ping Yu:
3D-printed mold-assisted U-shaped optical fiber sensor for displacement sensing. WOCC 2021: 115-117 - 2020
- [c16]Jonathan Chang, Yen-Huei Chen, Gary Chan, Hank Cheng, Po-Sheng Wang, Yangsyu Lin, Hidehiro Fujiwara, Robin Lee, Hung-Jen Liao, Ping-Wei Wang, Geoffrey Yeap, Quincy Li:
15.1 A 5nm 135Mb SRAM in EUV and High-Mobility-Channel FinFET Technology with Metal Coupling and Charge-Sharing Write-Assist Circuitry Schemes for High-Density and Low-VMIN Applications. ISSCC 2020: 238-240 - [c15]Qing Dong, Mahmut E. Sinangil, Burak Erbagci, Dar Sun, Win-San Khwa, Hung-Jen Liao, Yih Wang, Jonathan Chang:
15.3 A 351TOPS/W and 372.4GOPS Compute-in-Memory SRAM Macro in 7nm FinFET CMOS for Machine-Learning Applications. ISSCC 2020: 242-244
2010 – 2019
- 2019
- [j9]Mahmut E. Sinangil, Yen-Ting Lin, Hung-Jen Liao, Jonathan Chang:
A 290-mV, 7-nm Ultra-Low-Voltage One-Port SRAM Compiler Design Using a 12T Write Contention and Read Upset Free Bit-Cell. IEEE J. Solid State Circuits 54(4): 1152-1160 (2019) - [c14]Hidehiro Fujiwara, Chih-Yu Lin, Hsien-Yu Pan, Cheng-Han Lin, Po-Yi Huang, Kao-Cheng Lin, Jhon-Jhy Liaw, Yen-Huei Chen, Hung-Jen Liao, Jonathan Chang:
A 7nm 2.1GHz Dual-Port SRAM with WL-RC Optimization and Dummy-Read-Recovery Circuitry to Mitigate Read- Disturb-Write Issue. ISSCC 2019: 390-392 - 2018
- [c13]Mahmut E. Sinangil, Yen-Ting Lin, Hung-Jen Liao, Jonathan Chang:
A 290MV Ultra-Low Voltage One-Port SRAM Compiler Design Using a 12T Write Contention and Read Upset Free Bit-Cell in 7NM FinFET Technology. VLSI Circuits 2018: 13-14 - 2017
- [c12]Jonathan Chang, Yen-Huei Chen, Wei-Min Chan, Sahil Preet Singh, Hank Cheng, Hidehiro Fujiwara, Jih-Yu Lin, Kao-Cheng Lin, John Hung, Robin Lee, Hung-Jen Liao, Jhon-Jhy Liaw, Quincy Li, Chih-Yung Lin, Mu-Chi Chiang, Shien-Yang Wu:
12.1 A 7nm 256Mb SRAM in high-k metal-gate FinFET technology with write-assist circuitry for low-VMIN applications. ISSCC 2017: 206-207 - [c11]Michael Clinton, Hank Cheng, Hung-Jen Liao, Robin Lee, Ching-Wei Wu, Johnny Yang, Hau-Tai Hsieh, Frank Wu, Jung-Ping Yang, Atul Katoch, Arun Achyuthan, Donald Mikan, Bryan Sheffield, Jonathan Chang:
12.3 A low-power and high-performance 10nm SRAM architecture for mobile applications. ISSCC 2017: 210-211 - 2016
- [j8]Chun-Hung Richard Lin, Hung-Jen Liao, Ying-Chih Lin, Jain-Shing Liu, Yu-Hsiu Huang:
An efficient tabu search for cell planning problem in mobile communication. Wirel. Commun. Mob. Comput. 16(4): 486-496 (2016) - [c10]Hidehiro Fujiwara, Yen-Huei Chen, Chih-Yu Lin, Wei-Cheng Wu, Dar Sun, Shin-Rung Wu, Hung-Jen Liao, Jonathan Chang:
A 64-Kb 0.37V 28nm 10T-SRAM with mixed-Vth read-port and boosted WL scheme for IoT applications. A-SSCC 2016: 185-188 - [c9]Yen-Huei Chen, Kao-Cheng Lin, Ching-Wei Wu, Wei-Min Chan, Jhon-Jhy Liaw, Hung-Jen Liao, Jonathan Chang:
A 16nm dual-port SRAM with partial suppressed word-line, dummy read recovery and negative bit-line circuitries for low VMIN applications. VLSI Circuits 2016: 1-2 - 2015
- [j7]Yen-Huei Chen, Wei-Min Chan, Wei-Cheng Wu, Hung-Jen Liao, Kuo-Hua Pan, Jhon-Jhy Liaw, Tang-Hsuan Chung, Quincy Li, Chih-Yung Lin, Mu-Chi Chiang, Shien-Yang Wu, Jonathan Chang:
A 16 nm 128 Mb SRAM in High-κ Metal-Gate FinFET Technology With Write-Assist Circuitry for Low-VMIN Applications. IEEE J. Solid State Circuits 50(1): 170-177 (2015) - [c8]Hidehiro Fujiwara, Li-Wen Wang, Yen-Huei Chen, Kao-Cheng Lin, Dar Sun, Shin-Rung Wu, Jhon-Jhy Liaw, Chih-Yung Lin, Mu-Chi Chiang, Hung-Jen Liao, Shien-Yang Wu, Jonathan Chang:
17.2 A 64kb 16nm asynchronous disturb current free 2-port SRAM with PMOS pass-gates for FinFET technologies. ISSCC 2015: 1-3 - 2014
- [c7]Ching-Wei Wu, Ming-Hung Chang, Chia-Cheng Chen, Robin Lee, Hung-Jen Liao, Jonathan Chang:
A configurable 2-in-1 SRAM compiler with constant-negative-level write driver for low Vmin in 16nm Fin-FET CMOS. A-SSCC 2014: 145-148 - [c6]Yen-Huei Chen, Wei-Min Chan, Wei-Cheng Wu, Hung-Jen Liao, Kuo-Hua Pan, Jhon-Jhy Liaw, Tang-Hsuan Chung, Quincy Li, George H. Chang, Chih-Yung Lin, Mu-Chi Chiang, Shien-Yang Wu, Sreedhar Natarajan, Jonathan Chang:
13.5 A 16nm 128Mb SRAM in high-κ metal-gate FinFET technology with write-assist circuitry for low-VMIN applications. ISSCC 2014: 238-239 - [c5]Saman Adham, Jonathan Chang, Hung-Jen Liao, John Hung, Ting-Hua Hsieh:
The importance of DFX, a foundry perspective. ITC 2014: 1-6 - 2013
- [j6]Hung-Jen Liao, Chun-Hung Richard Lin, Ying-Chih Lin, Kuang-Yuan Tung:
Intrusion detection system: A comprehensive review. J. Netw. Comput. Appl. 36(1): 16-24 (2013) - [j5]Meng-Fan Chang, Shin-Jang Shen, Chia-Chi Liu, Che-Wei Wu, Yu-Fan Lin, Ya-Chin King, Chorng-Jung Lin, Hung-Jen Liao, Yu-Der Chih, Hiroyuki Yamauchi:
An Offset-Tolerant Fast-Random-Read Current-Sampling-Based Sense Amplifier for Small-Cell-Current Nonvolatile Memory. IEEE J. Solid State Circuits 48(3): 864-877 (2013) - [c4]Jonathan Chang, Yen-Huei Chen, Hank Cheng, Wei-Min Chan, Hung-Jen Liao, Quincy Li, Stanley Chang, Sreedhar Natarajan, Robin Lee, Ping-Wei Wang, Shyue-Shyh Lin, Chung-Cheng Wu, Kuan-Lun Cheng, Min Cao, George H. Chang:
A 20nm 112Mb SRAM in High-к metal-gate with assist circuitry for low-leakage and low-VMIN applications. ISSCC 2013: 316-317 - 2012
- [j4]Yen-Huei Chen, Shao-Yu Chou, Quincy Li, Wei-Min Chan, Dar Sun, Hung-Jen Liao, Ping Wang, Meng-Fan Chang, Hiroyuki Yamauchi:
Compact Measurement Schemes for Bit-Line Swing, Sense Amplifier Offset Voltage, and Word-Line Pulse Width to Characterize Sensing Tolerance Margin in a 40 nm Fully Functional Embedded SRAM. IEEE J. Solid State Circuits 47(4): 969-980 (2012) - 2011
- [j3]Jui-Jen Wu, Yen-Hui Chen, Meng-Fan Chang, Po-Wei Chou, Chien-Yuan Chen, Hung-Jen Liao, Ming-Bin Chen, Yuan-Hua Chu, Wen-Chin Wu, Hiroyuki Yamauchi:
A Large Sigma V TH /VDD Tolerant Zigzag 8T SRAM With Area-Efficient Decoupled Differential Sensing and Fast Write-Back Scheme. IEEE J. Solid State Circuits 46(4): 815-827 (2011) - [c3]Meng-Fan Chang, Shin-Jang Shen, Chia-Chi Liu, Che-Wei Wu, Yu-Fan Lin, Shang-Chi Wu, Chia-En Huang, Han-Chao Lai, Ya-Chin King, Chorng-Jung Lin, Hung-Jen Liao, Yu-Der Chih, Hiroyuki Yamauchi:
An offset-tolerant current-sampling-based sense amplifier for Sub-100nA-cell-current nonvolatile memory. ISSCC 2011: 206-208 - 2010
- [j2]Meng-Fan Chang, Jui-Jen Wu, Kuang-Ting Chen, Yung-Chi Chen, Yen-Hui Chen, Robin Lee, Hung-Jen Liao, Hiroyuki Yamauchi:
A Differential Data-Aware Power-Supplied (D 2 AP) 8T SRAM Cell With Expanded Write/Read Stabilities for Lower VDDmin Applications. IEEE J. Solid State Circuits 45(6): 1234-1245 (2010)
2000 – 2009
- 2009
- [j1]Yen-Huei Chen, Gary Chan, Shao-Yu Chou, Hsien-Yu Pan, Jui-Jen Wu, Robin Lee, Hung-Jen Liao, Hiroyuki Yamauchi:
A 0.6 V Dual-Rail Compiler SRAM Design on 45 nm CMOS Technology With Adaptive SRAM Power for Lower VDD_min VLSIs. IEEE J. Solid State Circuits 44(4): 1209-1215 (2009) - 2007
- [c2]D. P. Wang, Hung-Jen Liao, Hiroyuki Yamauchi, Y. H. Chen, Y. L. Lin, S. H. Lin, D. C. Liu, Huan-Cheng Chang, W. Hwang:
A 45nm dual-port SRAM with write and read capability enhancement at low voltage. SoCC 2007: 211-214 - 2000
- [c1]Ding-Ming Kwai, Hung-Wen Chang, Hung-Jen Liao, Ching-Hua Chiao, Yung-Fa Chou:
etection of SRAM cell stability by lowering array supply voltage. Asian Test Symposium 2000: 268-273
Coauthor Index
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