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Changzhi Li
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2020 – today
- 2024
- [c78]Christopher Williams
, Changzhi Li:
Angular Dependency of Human Speech Recognition using Interferometry Radar. RWS 2024: 112-114 - [c77]Rachel Ma, Aaron B. Carman
Secure Occupancy Sensing with Passive Radar for Spectrally Congested Spaces. WiSNeT 2024: 9-11 - [c76]Aaron B. Carman
A Digital Beamforming Approach for Indoor Passive Sensing. WiSNeT 2024: 12-14 - [c75]Victor Gabriel Rizzi Varela, Changzhi Li:
Wind Turbines Structural Health Monitoring Using a FMCW Radar Mounted on a Drone. WiSNeT 2024: 15-17 - [c74]Davi V. Q. Rodrigues, Changzhi Li:
Tracking Driver's Foot Movements Using mmWave FMCW Radar. WiSNeT 2024: 34-36 - [c73]Luigi Ferro
Robust Doppler Displacement Measurement Resolving the Uncertainty During Target Stationary Moment. WiSNeT 2024: 57-60 - [c72]John T. Crainer, Changzhi Li:
Software Configurable Multi-mode Radar Sensor System for Range Tracking and Life Sensing. WiSNeT 2024: 73-75 - 2023
- [j54]Michael C. Brown
Incorporation of Digital Modulation into Vital Sign Detection and Gesture Recognition Using Multimode Radar Systems. Sensors 23(18): 7675 (2023) - [j53]Victor Gabriel Rizzi Varela
Multitarget Physical Activities Monitoring and Classification Using a V-Band FMCW Radar. IEEE Trans. Instrum. Meas. 72: 1-10 (2023) - [j52]Changzhi Li
Robust website fingerprinting through resource loading sequence. World Wide Web (WWW) 26(5): 2329-2349 (2023) - [c71]Christopher Williams
Prediction and Simulation of FMCW Radar Hand Gesture Detection based on Captured 3D Motion Data. RWS 2023: 55-57 - [c70]Hannah Gao, Christopher Williams
Violin Gesture Recognition Using FMCW Radars. WiSNeT 2023: 13-15 - [c69]Aaron B. Carman
Passive Multistatic Wireless Sensing Based on Discrete LNA/Mixer Co-Optimization and Fast-Startup Baseband Amplifier. WiSNeT 2023: 43-45 - [c68]Max Vasconcelos, Prateek Nallabolu
Range Resolution Improvement in FMCW Radar Through VCO's Nonlinearity Compensation. WiSNeT 2023: 53-56 - 2022
- [j51]Zhengxiong Li, Baicheng Chen, Xingyu Chen, Chenhan Xu, Yuyang Chen
Reliable Digital Forensics in the Air: Exploring an RF-based Drone Identification System. Proc. ACM Interact. Mob. Wearable Ubiquitous Technol. 6(2): 63:1-63:25 (2022) - [j50]Ashish Mishra
Correction: Mishra, A.; Li, C. A Review: Recent Progress in the Design and Development of Nonlinear Radars. Remote Sens. 2021, 13, 4982. Remote. Sens. 14(17): 4265 (2022) - [j49]Chengjun Chen
Assembly Monitoring Using Semantic Segmentation Network Based on Multiscale Feature Maps and Trainable Guided Filter. IEEE Trans. Instrum. Meas. 71: 1-11 (2022) - [c67]Michael C. Brown, Changzhi Li:
A K-Band Broadband Binary Phase Shifter. RWS 2022: 16-18 - [c66]Davi V. Q. Rodrigues, Dongyang Tang, Changzhi Li:
A Novel Microwave Architecture for Passive Sensing Applications. RWS 2022: 57-59 - [c65]Natalia Vallejo Montoya, Daniel Rodriguez, Changzhi Li:
Wireless Power Transfer Sensing Approach for Milk Adulteration Detection Using Supervised Learning. RWS 2022: 131-134 - [c64]Victor Gabriel Rizzi Varela
Separation of Simultaneous Multi-Person Noncontact Physical Activity Signals Using Frequency-Modulated Continuous-Wave Radars. WiSNet 2022: 5-7 - [c63]Davi V. Q. Rodrigues, Changzhi Li:
RF-Tag-Referenced Structural Displacement Measurements With Multiple Moving Interferers. WiSNet 2022: 14-17 - [c62]Daniel Rodriguez, Natalia Vallejo Montoya, Changzhi Li:
SMCW Radar for Low IF Sensing Applications. WiSNet 2022: 22-25 - [c61]Rita Abad Lima, Ashish Mishra
Advantages of Utilizing Higher-order Response for a Harmonic Radar. WiSNet 2022: 29-31 - 2021
- [j48]Prateek Nallabolu
Human Presence Sensing and Gesture Recognition for Smart Home Applications With Moving and Stationary Clutter Suppression Using a 60-GHz Digital Beamforming FMCW Radar. IEEE Access 9: 72857-72866 (2021) - [j47]Changzhi Li, Dhanagopal Ramachandran, Karthikeyan Rajagopal
Predicting Tipping Points in Chaotic Maps with Period-Doubling Bifurcations. Complex. 2021: 9927607:1-9927607:10 (2021) - [j46]Changzhi Li, Karthikeyan Rajagopal, Fahimeh Nazarimehr
A non-autonomous chaotic system with no equilibrium. Integr. 79: 143-156 (2021) - [j45]Ashish Mishra
A Review: Recent Progress in the Design and Development of Nonlinear Radars. Remote. Sens. 13(24): 4982 (2021) - [j44]Davi V. Q. Rodrigues, Changzhi Li
A Review on Low-Cost Microwave Doppler Radar Systems for Structural Health Monitoring. Sensors 21(8): 2612 (2021) - [j43]Jingtao Liu
Accurate Measurement of Human Vital Signs With Linear FMCW Radars Under Proximity Stationary Clutters. IEEE Trans. Biomed. Circuits Syst. 15(6): 1393-1404 (2021) - [j42]Chengjun Chen
Mechanical Assembly Monitoring Method Based on Depth Image Multiview Change Detection. IEEE Trans. Instrum. Meas. 70: 1-13 (2021) - [j41]Davi V. Q. Rodrigues, Delong Zuo, Changzhi Li:
Wind-Induced Displacement Analysis for a Traffic Light Structure Based on a Low-Cost Doppler Radar Array. IEEE Trans. Instrum. Meas. 70: 1-9 (2021) - [c60]Aaron B. Carman
A Novel Wavelength-Division Differential Detection Technique for Microwave Pulse Oximetry. EMBC 2021: 7390-7393 - [c59]Emanuele Cardillo
Radar-Based Monitoring of the Worker Activities by Exploiting Range-Doppler and Micro-Doppler Signatures. MetroInd4.0&IoT 2021: 412-416 - [c58]Changzhi Li
RLTree: Website Fingerprinting Through Resource Loading Tree. NSS 2021: 3-16 - [c57]Daniel Rodriguez, Jing Wang, Changzhi Li:
Spoofing Attacks to Radar Motion Sensors with Portable RF Devices. RWS 2021: 73-75 - [c56]Davi V. Q. Rodrigues, Changzhi Li:
Hand Gesture Recognition Using FMCW Radar in Multi-Person Scenario. WiSNet 2021: 50-52 - [c55]Dongyang Tang, Ashish Mishra
Intermodulation Radar with Dynamic Fundamental Tone Cancellation for Linearity Improvement. WiSNet 2021: 63-65 - 2020
- [j40]Fazhong Shen
Induction Logging Through Casing by Detecting Lateral Waves: A Numerical Analysis. IEEE Trans. Geosci. Remote. Sens. 58(4): 2937-2946 (2020) - [j39]Davi V. Q. Rodrigues
Adaptive Displacement Calibration Strategies for Field Structural Health Monitoring Based on Doppler Radars. IEEE Trans. Instrum. Meas. 69(10): 7813-7824 (2020) - [c54]Emanuele Cardillo
Empowering Blind People Mobility: A Millimeter-Wave Radar Cane. MetroInd4.0&IoT 2020: 213-217 - [c53]Hao Wang
Wireless Orientation in the Presence of Mutual Couplings. RWS 2020: 97-99 - [c52]William McDonnell, Ashish Mishra
Comprehensive Vital Sign Detection using a Wrist Wearable Nonlinear Target and a 5.8-GHz ISM Band Intermodulation Radar. RWS 2020: 123-126 - [c51]Shuqin Dong
Cardiogram Detection with a Millimeter-wave Radar Sensor. RWS 2020: 127-129 - [c50]Zhenyu Chen, Changzhi Li
Algorithms and Wideband Architecture for PIM localizations. RWS 2020: 173-175 - [c49]Tian Peng, Dexin Ye, Fazhong Shen, Chun Wang, Changzhi Li
Implementation of a Miniaturized Cylindrical Anechoic Chamber Based on an Angle-dependent PML Surface. RWS 2020: 180-182 - [c48]Davi V. Q. Rodrigues, Ziyan Tang, Jing Wang, Delong Zuo, Changzhi Li
Structural Health Monitoring of a Traffic Signal Support Structure Based on 5.8-GHz Doppler Radar with Median Filter and Revised Circle Fitting. RWS 2020: 187-190 - [c47]Junjun Xiong, Hongqiang Zhang, Hong Hong, Heng Zhao, Xiaohua Zhu, Changzhi Li
Multi-target Vital Signs Detection Using SIMO Continuous-wave Radar with DBF Technique. RWS 2020: 194-196 - [c46]Daniel Rodriguez
A Low-Power and Low-Cost Monostatic Radar Based on a Novel 2-Port Transceiver Chain. WiSNet 2020: 9-12 - [c45]Prateek Nallabolu
A Novel Radar Imaging Method Based on Random Illuminations Using FMCW Radar. WiSNet 2020: 27-29 - [c44]Jing Wang, Daniel Nolte
Trade-off on Detection Range and Channel Usage for Moving Target Tracking using FSK Radar. WiSNet 2020: 38-41
2010 – 2019
- 2019
- [j38]Ashish Mishra
Intermodulation-Based Nonlinear Smart Health Sensing of Human Vital Signs and Location. IEEE Access 7: 158284-158295 (2019) - [j37]Huan Li
Wide-Angle Beam Steering Based on an Active Conformal Metasurface Lens. IEEE Access 7: 185264-185272 (2019) - [j36]Zhengyu Peng
Portable Microwave Radar Systems for Short-Range Localization and Life Tracking: A Review. Sensors 19(5): 1136 (2019) - [j35]Zhitao Gu
Remote Blind Motion Separation Using a Single-Tone SIMO Doppler Radar Sensor. IEEE Trans. Geosci. Remote. Sens. 57(1): 462-472 (2019) - [j34]Chuanwei Ding
Continuous Human Motion Recognition With a Dynamic Range-Doppler Trajectory Method Based on FMCW Radar. IEEE Trans. Geosci. Remote. Sens. 57(9): 6821-6831 (2019) - [j33]Dongyang Tang
A DC-Coupled High Dynamic Range Biomedical Radar Sensor With Fast-Settling Analog DC Offset Cancelation. IEEE Trans. Instrum. Meas. 68(5): 1441-1450 (2019) - [j32]Zhitao Gu, Jun Wang, Fazhong Shen, Kuiwen Xu, Dexin Ye, Jiangtao Huangfu, Changzhi Li
Blind Separation of Doppler Human Gesture Signals Based on Continuous-Wave Radar Sensors. IEEE Trans. Instrum. Meas. 68(7): 2659-2661 (2019) - [j31]Heng Zhao
A Noncontact Breathing Disorder Recognition System Using 2.4-GHz Digital-IF Doppler Radar. IEEE J. Biomed. Health Informatics 23(1): 208-217 (2019) - [c43]Baicheng Chen, Zhengxiong Li, Zhuolin Yang, Changzhi Li
E-Eye: mmWave nonlinear response for hidden electronic device recognition: demo abstract. SenSys 2019: 392-393 - [c42]Rachel Chae
FMCW Radar Driver Head Motion Monitoring Based on Doppler Spectrogram and Range-Doppler Evolution. WiSNet 2019: 1-4 - [c41]José M. Muñoz-Ferreras
Coherent Deramping-Based Multi-FMCW Radar Architecture. WiSNet 2019: 1-4 - [c40]Daniel Rodriguez
Self-Powered 24-GHz Doppler Radar for Building Entrance Monitoring Using Cross Correlation and Envelope Detection. WiSNet 2019: 1-4 - 2018
- [j30]Changzhi Li
Guest Editorial Wireless Sensing Circuits and Systems for Healthcare and Biomedical Applications. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(2): 161-164 (2018) - [j29]Changzhi Li
Overview of Recent Development on Wireless Sensing Circuits and Systems for Healthcare and Biomedical Applications. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(2): 165-177 (2018) - [j28]Zhiming Xiao, Weibo Hu, Chenhui Liu, Hang Yu, Changzhi Li
Noncontact Human-Machine Interface With Planar Probing Coils in a Differential Sensing Architecture. IEEE Trans. Instrum. Meas. 67(4): 956-964 (2018) - [j27]Xiaokang Qi, Lei Chen, Kang An, Jun Wang, Chao Ma, Bin Zhang, Kuiwen Xu, Huan Li, Dexin Ye, Jiangtao Huangfu, Changzhi Li
Wireless Indoor Positioning With Vertically Uniform Alternating Magnetic Fields. IEEE Trans. Instrum. Meas. 67(11): 2733-2735 (2018) - [j26]Xiaokang Qi, Lei Chen, Kang An
Bioinspired In-Grid Navigation and Positioning Based on an Artificially Established Magnetic Gradient. IEEE Trans. Veh. Technol. 67(11): 10583-10589 (2018) - [c39]Jing Wang, Changzhi Li
A Human Tracking and Physiological Monitoring FSK Technology for Single Senior at Home Care. EMBC 2018: 4432-4435 - [c38]Zhengyu Peng, Ashish Mishra
Long-time non-contact water level measurement with a 5.8-GHz DC-coupled interferometry radar. I2MTC 2018: 1-5 - [c37]Dongyang Tang, Jing Wang, Zhengyu Peng, Yi-Chyun Chiang, Changzhi Li
A DC-coupled biomedical radar sensor with analog DC offset calibration circuit. I2MTC 2018: 1-6 - [c36]Ashish Mishra
5.8-GHz ISM band intermodulation radar for high-sensitivity motion-sensing applications. RWS 2018: 4-6 - [c35]Anjie Zhu, Tenglong Fan, Zhitao Gu, Qinyi Lv
Indoor localization based on a single-tone SIMO-structured Doppler radar system. RWS 2018: 7-9 - [c34]Tianyi Zhou, Anjie Zhu, Yuzhou Shen, Huan Li, Changzhi Li
Single frequency microwave imaging based on compressed sensing. RWS 2018: 133-135 - [c33]Jing Wang, Yao Tang, José Maria Muñoz-Ferreras
An improved indoor localization solution using a hybrid UWB-Doppler system with Kalman filter. RWS 2018: 181-183 - [c32]Ashish Mishra
Investigation of unique broadband nonlinear RF response of electronic devices. RWS 2018: 281-283 - [c31]Zhengxiong Li, Zhuolin Yang, Chen Song, Changzhi Li
E-Eye: Hidden Electronics Recognition through mmWave Nonlinear Effects. SenSys 2018: 68-81 - 2017
- [j25]Feng Lin
SleepSense: A Noncontact and Cost-Effective Sleep Monitoring System. IEEE Trans. Biomed. Circuits Syst. 11(1): 189-202 (2017) - [j24]Heng Zhao, Hong Hong, Li Sun, Yusheng Li, Changzhi Li
Noncontact Physiological Dynamics Detection Using Low-power Digital-IF Doppler Radar. IEEE Trans. Instrum. Meas. 66(7): 1780-1788 (2017) - [c30]Feng Lin
Cardiac Scan: A Non-contact and Continuous Heart-based User Authentication System. MobiCom 2017: 315-328 - [c29]Jialong Chen, Dexin Ye, Jiangtao Huangfu, Changzhi Li
Orientation and cancellation of directional interfering signals based on a radio frequency beamforming array. RWS 2017: 32-34 - [c28]Tenglong Fan, Dexin Ye, Jiangtao Huangfu, Yongzhi Sun, Changzhi Li
Hand gesture recognition based on Wi-Fi chipsets. RWS 2017: 98-100 - [c27]José Maria Muñoz-Ferreras
Doppler-radar-based short-range acquisitions of time-frequency signatures from an industrial-type wind turbine. WiSNet 2017: 5-7 - [c26]José Maria Muñoz-Ferreras
A frequency-multiplexed Doppler-plus-FMCW hybrid radar architecture: Theory and simulations. WiSNet 2017: 8-10 - 2016
- [j23]Qingyang Meng
Microwave Imaging under Oblique Illumination. Sensors 16(7): 1046 (2016) - [j22]Hong Hong, Heng Zhao
Time-Varying Vocal Folds Vibration Detection Using a 24 GHz Portable Auditory Radar. Sensors 16(8): 1181 (2016) - [j21]Ming-Chun Huang
A Self-Calibrating Radar Sensor System for Measuring Vital Signs. IEEE Trans. Biomed. Circuits Syst. 10(2): 352-363 (2016) - [j20]José Maria Muñoz-Ferreras
Short-Range Doppler-Radar Signatures from Industrial Wind Turbines: Theory, Simulations, and Measurements. IEEE Trans. Instrum. Meas. 65(9): 2108-2119 (2016) - [j19]Tooraj Nikoubin, Mahdieh Grailoo
Energy and Area Efficient Three-Input XOR/XNORs With Systematic Cell Design Methodology. IEEE Trans. Very Large Scale Integr. Syst. 24(1): 398-402 (2016) - [c25]José M. Muñoz-Ferreras
A step forward towards radar sensor networks for structural health monitoring of wind turbines. RWS 2016: 23-25 - [c24]Yan Zhuang, Chen Song, Feng Lin
On the feasibility of Non-contact Cardiac Motion Sensing for emerging heart-based biometrics. RWS 2016: 204-206 - 2015
- [j18]Yang Zhang, Teng Jiao, Hao Lv, Sheng Li, Changzhi Li
An Interference Suppression Technique for Life Detection Using 5.75- and 35-GHz Dual-Frequency Continuous-Wave Radar. IEEE Geosci. Remote. Sens. Lett. 12(3): 482-486 (2015) - [j17]Changzhan Gu, Changzhi Li
Assessment of Human Respiration Patterns via Noncontact Sensing Using Doppler Multi-Radar System. Sensors 15(3): 6383-6398 (2015) - [j16]Li Sun, Hong Hong, Yusheng Li, Chen Gu, Feng Xi
Noncontact Vital Sign Detection based on Stepwise Atomic Norm Minimization. IEEE Signal Process. Lett. 22(12): 2479-2483 (2015) - [j15]Li Lu, Bozorgmehr Vosooghi, Liang Dai, Changzhi Li
A 0.7 V Relative Temperature Sensor With a Non-Calibrated $\pm 1~^{\circ}{\rm C}$ 3$\sigma$ Relative Inaccuracy. IEEE Trans. Circuits Syst. I Regul. Pap. 62-I(10): 2434-2444 (2015) - [c23]Yan Zhuang, Chen Song, Aosen Wang, Feng Lin
SleepSense: Non-invasive sleep event recognition using an electromagnetic probe. BSN 2015: 1-6 - [c22]Zhengyu Peng
A 24-GHz low-cost continuous beam steering phased array for indoor smart radar. MWSCAS 2015: 1-4 - [c21]Jinjin Xu, Jiang Long, Yongzhi Sun, Dexin Ye, Jiangtao Huangfu, Changzhi Li
Remote phase synchronization for satellite network systems. RWS 2015: 17-19 - [c20]Chenhui Liu, Changzhan Gu, Changzhi Li
Non-contact hand interaction with smart phones using the wireless power transfer features. RWS 2015: 20-22 - [c19]Jiaqi Zhao, Zhongbo Zhu, Bin Zhang, Dexin Ye, Changzhi Li
Power synthesis at low frequencies in the sub-THz gap. RWS 2015: 26-28 - [c18]Tooraj Nikoubin, José Maria Muñoz-Ferreras
Structural health monitoring of wind turbines using a low-cost portable k-band radar: An ab-initio field investigation. WiSNet 2015: 69-71 - 2014
- [j14]Somayeh Kazemi
Cyclostationary approach to Doppler radar heart and respiration rates monitoring with body motion cancelation using Radar Doppler System. Biomed. Signal Process. Control. 13: 79-88 (2014) - [j13]Bozorgmehr Vosooghi, Li Lu, Changzhi Li
Leakage, Area, and Headroom Tradeoffs for Scattered Relative Temperature Sensor Front-End Architectures. IEEE Trans. Circuits Syst. II Express Briefs 61-II(2): 80-84 (2014) - [j12]Zhongwei Zhao, Tiancun Hu, Wanzhao Cui, Jiangtao Huangfu, Changzhi Li
Long-Distance Geomagnetic Navigation: Imitations of Animal Migration Based on a New Assumption. IEEE Trans. Geosci. Remote. Sens. 52(10): 6715-6723 (2014) - [j11]Jingyu Wang, Xiang Wang, Lei Chen, Jiangtao Huangfu, Changzhi Li
Noncontact Distance and Amplitude-Independent Vibration Measurement Based on an Extended DACM Algorithm. IEEE Trans. Instrum. Meas. 63(1): 145-153 (2014) - [j10]Yihong Yang, Changzhan Gu, Yiran Li, Richard Gale, Changzhi Li
Doppler Radar Motion Sensor With CMOS Digital DC-Tuning VGA and Inverter-Based Sigma-Delta Modulator. IEEE Trans. Instrum. Meas. 63(11): 2666-2674 (2014) - [j9]Shanyue Guan, Jennifer A. Rice, Changzhi Li
Automated DC Offset Calibration Strategy for Structural Health Monitoring Based on Portable CW Radar Sensor. IEEE Trans. Instrum. Meas. 63(12): 3111-3118 (2014) - [j8]Chun Zhang, Dian Ma, Changzhi Li
Runtime Self-Calibrated Temperature-Stress Cosensor for 3-D Integrated Circuits. IEEE Trans. Very Large Scale Integr. Syst. 22(11): 2411-2417 (2014) - [c17]Yiran Li, Ranadip Pal
Non-contact multi-radar smart probing of body orientation based on micro-Doppler signatures. EMBC 2014: 598-601 - [c16]Qian Wan, Yiran Li, Changzhi Li
Gesture recognition for smart home applications using portable radar sensors. EMBC 2014: 6414-6417 - [c15]Yiran Li, Changzhan Gu, Tooraj Nikoubin, Changzhi Li
Wireless radar devices for smart human-computer interaction. MWSCAS 2014: 65-68 - [c14]Guochao Wang
Software-configured smart radar sensor for civil and biomedical applications. MWSCAS 2014: 551-554 - [c13]Guochao Wang
Linear-frequency-modulated continuous-wave radar for vital-sign monitoring. WiSNet 2014: 37-39 - 2013
- [j7]Li Lu, Bozorgmehr Vosooghi, Jinghong Chen, Changzhi Li
A Subthreshold-MOSFETs-Based Scattered Relative Temperature Sensor Front-End With a Non-Calibrated ±2.5°C 3σ Relative Inaccuracy From -40°C to 100°C. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(5): 1104-1112 (2013) - [j6]Jingyu Wang, Zhongbo Zhu, Changzhi Li
PLL-Based Self-Adaptive Resonance Tuning for a Wireless-Powered Potentiometer. IEEE Trans. Circuits Syst. II Express Briefs 60-II(7): 392-396 (2013) - [j5]Li Lu, Scott T. Block, David E. Duarte, Changzhi Li
A 0.45-V MOSFETs-Based Temperature Sensor Front-End in 90 nm CMOS With a Noncalibrated ± 3.5°C 3σ Relative Inaccuracy From -55°C to 105°C. IEEE Trans. Circuits Syst. II Express Briefs 60-II(11): 771-775 (2013) - [c12]Han Ren, Jin Shao, Rongguo Zhou, Bayaner Arigong, Hyoung Soo Kim, Changzhi Li
A compact phased array antenna system based on dual-band Butler matrices. RWS 2013: 214-216 - [c11]Guochao Wang
Highly accurate noncontact water level monitoring using continuous-wave Doppler radar. WiSNet 2013: 19-21 - [c10]Ravindranath D. Shrivastava, Devashish Deshpande, Changzhi Li
An Energy Harvesting System using 3-stage voltage multiplier and MPVD Charge Pump for wireless sensor networks. WiSNet 2013: 40-42 - 2012
- [j4]Changzhan Gu, Ruijiang Li
Accurate Respiration Measurement Using DC-Coupled Continuous-Wave Radar Sensor for Motion-Adaptive Cancer Radiotherapy. IEEE Trans. Biomed. Eng. 59(11-2): 3117-3123 (2012) - [j3]Dong Li, Meigen Shen, Jiangtao Huangfu, Jiang Long, Yong Tao, Jingyu Wang, Changzhi Li
Wireless Sensing System-on-Chip for Near-Field Monitoring of Analog and Switch Quantities. IEEE Trans. Ind. Electron. 59(2): 1288-1299 (2012) - [c9]Rui Wang, Xiaoke Wen, Kamran Azadet, Changzhi Li
A power-optimized reconfigurable CT ΔΣ modulator in 65nm CMOS. ISCAS 2012: 305-308 - [c8]Yi Yang, David M. Binkley, Changzhi Li
Using moderate inversion to optimize voltage gain, thermal noise, and settling time in two-stage CMOS amplifiers. ISCAS 2012: 432-435 - [c7]Li Lu, Changzhi Li
An all-CMOS low supply voltage temperature sensor front-end with error correction techniques. ISCAS 2012: 2973-2976 - [c6]Lei Chen, Xiaoke Wen, Yang You, Deping Huang, Changzhi Li
A radiation-tolerant ring oscillator phase-locked loop in 0.13µm CMOS. MWSCAS 2012: 13-16 - [c5]Changzhan Gu, Jennifer A. Rice, Changzhi Li
A wireless smart sensor network based on multi-function interferometric radar sensors for structural health monitoring. WiSNet 2012: 33-36 - 2011
- [c4]Changzhan Gu, Ruijiang Li, Steve B. Jiang, Changzhi Li
A multi-radar wireless system for respiratory gating and accurate tumor tracking in lung cancer radiotherapy. EMBC 2011: 417-420 - [c3]Li Lu, Changzhi Li
A regulated 3.1-10.6 GHz linear dual-tuning differential ring oscillator for UWB applications. ISCAS 2011: 225-228 - [c2]Yi Yang, David M. Binkley, Lu Li, Changzhan Gu, Changzhi Li
All-CMOS subbandgap reference circuit operating at low supply voltage. ISCAS 2011: 893-896 - 2010
- [j2]Changzhi Li
Accurate Doppler Radar Noncontact Vital Sign Detection Using the RELAX Algorithm. IEEE Trans. Instrum. Meas. 59(3): 687-695 (2010) - [j1]Changzhan Gu, Changzhi Li
Instrument-Based Noncontact Doppler Radar Vital Sign Detection System Using Heterodyne Digital Quadrature Demodulation Architecture. IEEE Trans. Instrum. Meas. 59(6): 1580-1588 (2010)
2000 – 2009
- 2006
- [c1]Changzhi Li
Robust Overnight Monitoring of Human Vital Signs by a Non-contact Respiration and Heartbeat Detector. EMBC 2006: 2235-2238
Coauthor Index
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