电子邮箱:yuh3@sustc.edu.cn
副教授
简历 研究领域 文献发表

教育经历:

2007年获得获得美国加州大学洛杉矶分校电子工程系博士学位

XXX年获得美国加州大学洛杉矶分校硕士学位

1999年获得上海复旦大学学士学位

 

工作经历:

2017年6月至今,南方科技大学,副教授

XXXX年至XXXX年,新加坡南洋理工大学,助理教授

XXXX年至XXXX年,美国伯克利自动化设计,研究员

 

 

研究领域:

人工智能芯片

太赫兹通讯芯片

DNA传感器芯片

 

研究简介:

余浩教授在高性能集成电路(人工智能芯片,太赫兹通讯芯片,DNA传感器芯片)领域有取得多项原创性成果,是该领域的国际著名专家。他是国家2017年千人计划(青年项目)入选者。余浩教授有6部英文专著(其中一部3D 集成电路设计是Amazon 电路设计畅销书前100 名),共210 篇出版物(会议论文145 篇,学术期刊65篇)。其中15篇JCR Q1区期刊,30篇JCR Q2区期刊,如Nature Scientific Reports, IEEE Journal of Solid State Circuits, IEEE Trans. on Microwave Theory and Tech.等,并有1篇有关3D-IC互连的热电耦合论文获得国际计算机协会(ACM Trans. on Design Automation of Electronic Systems)最佳论文奖。余浩教授的高速太赫兹互连工作获美国半导体工业联合会(SRC)创新发明奖创新发明奖,并有授权专利20项。其研究成果多次被美国在线技术杂志报道。已毕业5名博士生,其博士生工作多次获国际论文奖励,并在多个国际著名高新企业及高校任职。

余浩教授的学术工作在国际上具有影响力,他是IEEE 电路系统(CAS)方向的杰出宣讲人。众多国际著名期刊,Nature Scientific Reports (JCR Q1期刊)编委, IEEE Trans. Biomedical Circuit and System (JCR Q2期刊)副主编, Elsevier Microelectronics Journal总副主编, ACM Trans. on Embedded Computing System副主编, Elsevier Integration, the VLSI Journal副主编。余浩教授还是20个国际顶级会议的技术委员会委员和分会主席(IEEE-ASSCC,IEEE-APMC,IEEE-ISLPED,ACM/IEEE-DAC等)。他在国际大会主题报告2次,受邀报告25次(IEEE-IMS,IEEE-ISCAS,Columbia University等)。余浩教授曾任新加坡南洋理工大学VIRTUS集成电路研究协助创始人及中心部门主任。期间作为第一负责人近五年累计获得5千万的政府资助(新加坡NRF-CRP 3000万一项,MOE-TIER-2 500万二项等)及企业项目(英特尔,华为,华大基因等)。

 

代表文章:* 通信作者

[1] Xu Liu^, Xiwei Huang, Yu Jiang, Hang Xu, Jing Guo, Han Wei Hou, Mei Yan, and Hao Yu, “A Microfluidic Cytometer for Complete Blood Count with a 3.2-Megapixel, 1.1-µm-pitch Super-Resolution Image Sensor in 65-nm BSI CMOS”, IEEE Transaction on Biomedical Circuits and Systems, 2017. (10.1109/TBCAS.2017.2697451) (Impact Factor 3.15) 

[2] Leibin Ni*, Zichuan Liu, Rajiv V. Joshi and Hao Yu, "An Energy-efficient Digital ReRAM-crossbar based CNN with Bitwise Parallelism," IEEE Journal of Exploratory Solid-State Computational Devices and Circuits, 2017. (10.1109/JXCDC.2017.2697910)

[3] Dongsuk Jeon, Qing Dong, Yejoong Kim, Xiaolong Wang, Shuai Chen, Hao Yu, David Blaauw, Dennis Sylvester, “A 23mW Face Recognition Processor with Mostly-Read 5T Memory in 40nm CMOS”. IEEE Journal of Solid-State Circuits (JSSC), January 2017 (doi:10.1109/JSSC.2017.2661838) (Impact Factor 3.29)

[4] Yuan Liang^, Hao Yu, Jincai Wen, Anak Agung Alit Apriyana, Nan Li, Yu Luo, and Lingling Sun, “On-chip sub-terahertz surface plasmon polariton transmission lines with mode converter in CMOS”, Nature Scientific Reports, article# 30063, July 2016. (Impact Factor 5.58)

[5] Yuhao Wang*, Leibin Ni, Chip-Hong Chang and Hao Yu, “DW-AES: A Domain-wall Nanowire based AES for High Throughput and Energy-efficient Data Encryption in Non-volatile Memory”, IEEE Transactions on Information Forensics & Security, 2016. (doi: 10.1109/TIFS.2016.2576903) (Impact Factor 2.40)

[6] Yang Shang*, Hao Yu, Yuan Liang, Xiaojun Bi, and Muthukumaraswamy Annamalai, “Millimeter-wave Sources at 60 GHz and 140 GHz by Magnetic Plasmon Waveguide based In-phase Coupled Oscillator Network in 65-nm CMOS”, IEEE Transactions on Microwave Theory and Techniques,  vol.64, no.5, pp1560-1571, May 2016. (Impact Factor 2.24)

[7] Sai Manoj P.D.*, Hao Yu, Hantao Huang and Dongjun Xu, “A Q-Learning based Self-adaptive I/O Communication for 2.5D Integrated Many-core Microprocessor and Memory”, IEEE Transactions on Computers, vol.65, no.4, pp1185-1196, April 2016.  (Impact Factor 1.47)

[8] Yuan Liang^, Hao Yu, Haochi Zhang, Chang Yang, and Tiejun Cui, “On-chip sub-terahertz surface plasmon polariton transmission lines in CMOS”, Nature Scientific Reports, article# 14853, October 2015.  (Impact Factor 5.58)

[9] Xiwei Huang*, Hao Yu, Xu Liu, Yu Jiang, Mei Yan, and Dongping Wu, “A Dual-mode Large-arrayed CMOS ISFET Sensor for Accurate and High-throughput pH Sensing in Biomedical Diagnosis”, IEEE Transactions on Biomedical Engineering (TBME), vol.62, no.9, pp2224–2233, September 2015. (Featured Article in September 2015) (Impact Factor 2.23)

[10] Yang Shang*, Hao Yu, Sanming Hu, Yuan Liang, Xiaojun Bi, and Muthukumaraswamy Annamalai, “High-sensitivity CMOS Super-regenerative Receiver with Quench-controlled High-Q Metamaterial Resonator for Millimeter-wave Imaging at 96 and 135 GHz”, IEEE Transactions on Microwave Theory and Techniques, vol.62, no.12, pp3095-3106, December 2014  (Impact Factor 2.94)