师资
呼唤,博士毕业于美国华盛顿州立大学,曾就职于美国Skyworks Solutions及德国医疗设备公司Biotronik/MSEI,于2022年加入南方科技大学深港微电子学院。他主要从事超低功耗模拟/混合信号集成电路及可穿戴/植入集成电路与系统设计等相关领域的研究,其中主要包括应用于生物医疗及物联网的超低功耗模拟前端及数据转换器、高能效收发技术、及面向智能物联网的存内计算电路等。他已有10余篇论文发表在IEEE国际集成电路顶级期刊和会议(包括TMTT,TCAS-I&II,RFIC,BioCAS等),同时担任多个国际顶级期刊及会议的论文审稿人(包括JSSC,TBioCAS,TCAS-I&II等)。
招聘信息
呼唤博士课题组常年招聘博士后、科研助理,招收博士生、硕士生、本科实习生,有意应聘者请将简历(格式PDF)发送至呼唤博士邮箱,以“招聘岗位_应聘者姓名”为题。课题组网站:https://faculty.sustech.edu.cn/huh3/。
联系方式
电邮:huh3@sustech.edu.cn
教育经历
2021年,美国华盛顿州立大学,博士学位
2015年,美国俄勒冈州立大学,硕士学位
2013年,电子科技大学,学士学位
工作经历
2022年1月至今,南方科技大学,助理教授
2021年3月至10月,美国Skyworks Solutions,主管工程师
2018年6月至12月,德国Biotronik/美国MSEI,集成电路研发实习生
研究简介
超低功耗低压传感器接口电路
面向医用/物联网的高能效收发机电路与架构
应用于存内计算的模拟及混合信号集成电路
所获荣誉
深圳市“鹏城孔雀”特聘C类人才,2022
RFIC Best Student Paper Award Nomination, 2020
Alaska Airline Travel Award, 2018
WSU Grand Challenges Fellowship Award, 2016-2017
OSU Laurels Scholarship Award, 2014-2015
代表文章
1. H. Hu and S. Gupta, “A 0.22μW single-bit VCO-based time-domain sensor-to-digital front-end with reduced supply sensitivity,” IEEE TCAS-I, vol. 69, no. 1, pp. 148-159, Jan. 2022,
2. H. Hu, C.C. Lin, and S. Gupta, “A 197.1μW wireless sensor SoC with an energy-efficient analog front-end and a harmonic injection-locked OOK TX,” IEEE TCAS-I, vol. 68, no. 6, pp. 2444-2456, June 2021.
3. H. Hu, T. Islam, A. Kostyukova, S. Ha, and S. Gupta, “From battery enabled to natural harvesting: enzymatic biofuel cell assisted integrated analog front-end in 130 nm CMOS for Long-Term Monitoring,” IEEE TCAS-I, vol. 66, no. 2, pp. 534-545, Feb. 2019.
4. H. Hu, T. Islam, C.C. Lin, A. Kostyukova, S. Ha, and S. Gupta, “A 3.51μW 0.31μVrms biofuel cell enabled integrated analog CMOS front-end in 130nm CMOS,” Proc. IEEE BioCAS, Oct. 2018, pp. 1-4.
5. H. Hu, M. Schiavenato, and S. Gupta, “An 143nW relaxation oscillator for ultra-low power biomedical systems,” Proc. IEEE Sensors Conf., Nov. 2016, pp. 1-3.
6. H. Hu, A. Delane, M. Schiavenato, and S. Gupta, “3D UWB localization-based infant pain assessment system in incubators using dynamic averaging algorithm and ranging,” 2016 BMES/FDA Frontiers in Medical Devices Conf., May 2016.
7. Q. Xu, C.C. Lin, H. Hu, S. Gupta, “Common-Mode Drift Resilient Ring-Oscillator-Based Time-Domain Filter for Next-Generation Wireless”, IEEE MWSCAS, Aug. 2023.
8. C.C. Lin, Q. Xu, H. Hu, S. Gupta, “Design Considerations of Time-interleaved Discrete-time Beamformers Toward Wideband Communications”, IEEE TCAS-II, Early Access.
9. C. Nie, C. Tang, J. Lin, H. Hu, C. Lv, T. Cao, W. Zhang, L. Jiang, X. Liang, W. Qian, Y. Sun, and Z. He, “VSPIM: SRAM Processing-in-Memory DNN Acceleration via Vector-Scalar Operations”, IEEE TC, Early Access.
10. C. Nie, J. Lin, H. Hu, J. Li, X. Liang, and Z. He, “Energy-Efficient Hybrid-RAM with Hybrid Bit-Serial based VMM Support,” ACM GLSVLSI, June 2021.
11. C.C. Lin, H. Hu, and S. Gupta, “Improved Performance Trade-Offs in Harmonic Injection-Locked ULP TX for Sub-GHz Radios,” IEEE TMTT, vol. 69, no. 6, pp. 2885-2898, June. 2021.
12. C.C. Lin*, H. Hu*, and S. Gupta, “Spur minimization techniques for ultra-low-power injection-locked transmitters,” IEEE TCAS-I, vol. 67, no. 11, pp. 3643-3655, Nov. 2020. (* - Equally contributed author)
13. C.C. Lin*, H. Hu*, and S. Gupta, “A 66.97pJ/bit 0.0413mm2 self-aligned PLL-calibrated harmonic-injection-locked TX with >62dBc spur suppression for IoT applications,” Proc. IEEE RFIC, Aug. 2020, pp. 1-4. (* - Equally contributed author)
14. S.K. Govindan, H. Hu, and S. Gupta, “A 25.6 µW 8.97 ps period jitter phase-locked relaxation oscillator with sub-1µs start-up for low power IoT,” Proc. IEEE ISCAS, May 2019, pp. 1-5.
15. A. Rahimi, H. Hu, K. Sivakumar, and S. Gupta, “Energy-efficient serialized Walsh-Hadamard transform based feature-extraction for information-aware compressive sensing,” Proc. IEEE ISCAS, May 2018, pp. 1-5.
16. A. Rahimi, H. Hu, and S. Gupta, “A compressive sensing information aware analog front end for IoT sensors using adaptive clocking techniques,” Proc. IEEE MWSCAS, Aug. 2017, pp. 325-328.
K. Shashank, S. A. Ay, A. Fulzele, R. C. Ram, H. Hu, S. Gupta, “Precise Placement of Precordial Electrodes with +/−0.5 cm Accuracy for Recording ECG in Self-operable Diagnostic Devices”, Proc. AHFE, June 2017, pp. 529-539.