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Aydin Babakhani
Person information
- affiliation: University of California, Los Angeles, USA
- affiliation (former): Rice University, Houston, TX, USA
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2020 – today
- 2024
- [j21]Sidharth Thomas
, Sam Razavian
A 400-GHz Efficient Radiator and OOK Transceiver for Multi-Gb/s Wireless Communication in Silicon. IEEE J. Solid State Circuits 59(5): 1381-1397 (2024) - [c33]Sidharth Thomas, Benyamin Fallahi Motlagh, Aydin Babakhani:
A 132-204 GHz Carrier Storage Frequency Divider with sub-50 Micro-Watt DC Power. BCICTS 2024: 221-224 - 2023
- [j20]Sidharth Thomas
A 0.4-4 THz p-i-n Diode Frequency Multiplier in 90-nm SiGe BiCMOS. IEEE J. Solid State Circuits 58(9): 2407-2420 (2023) - [j19]Arkaprova Ray
A Fully Wireless and Batteryless Localization System With 50 Micrometre Motion Detection Capability and Adaptive Transmitter Power Control for Point-of-Care Biomedical Applications. IEEE Trans. Biomed. Circuits Syst. 17(4): 674-687 (2023) - [c32]Aydin Babakhani, Sidharth Thomas, Sam Razavian:
High-Power, Efficient THz Generation in Silicon for Broadband Sensing and Wireless Communication. CICC 2023: 1-8 - 2022
- [c31]Sam Razavian, Sidharth Thomas, Mostafa Hosseini, Aydin Babakhani:
A 0.4 THz Efficient OOK/FSK Wireless Transmitter Enabling 3 Gbps at 20 meters. BCICTS 2022: 178-181 - [c30]Sidharth Thomas, Sam Razavian, Wei Sun, Anthony D. Kim, Yu Wu, Benjamin S. Williams, Aydin Babakhani:
Broadband 0.4-4 THz Generation in 90nm SiGe BiCMOS. BCICTS 2022: 199-202 - [c29]Arkaprova Ray
Fully Wireless and Batteryless Localization and Physiological Motion Detection System for Point-of-care Biomedical Applications. BioCAS 2022: 26-30 - [c28]Roshan P. Mathews
Towards a Miniaturized, Low Power, Batteryless, and Wireless Bio-Potential Sensing Node. BioCAS 2022: 404-408 - [c27]Sam Razavian
A Highly Power Efficient 2×3 PIN-Diode-Based Intercoupled THz Radiating Array at 425GHz with 18.1dBm EIRP in 90nm SiGe BiCMOS. ISSCC 2022: 1-3 - 2021
- [j18]Ian F. Akyildiz
Guest Editorial Special Issue on "THz Communications and Networking". IEEE J. Sel. Areas Commun. 39(6): 1499-1505 (2021) - [j17]Hamed Rahmani
A Wirelessly Powered Reconfigurable FDD Radio With On-Chip Antennas for Multi-Site Neural Interfaces. IEEE J. Solid State Circuits 56(10): 3177-3190 (2021) - [j16]Hongming Lyu
A 13.56-MHz -25-dBm-Sensitivity Inductive Power Receiver System-on-a-Chip With a Self-Adaptive Successive Approximation Resonance Compensation Front-End for Ultra-Low-Power Medical Implants. IEEE Trans. Biomed. Circuits Syst. 15(1): 80-90 (2021) - [c26]Jaeeun Jang, Iman Habibagahi, Hamed Rahmani
Wirelessly Powered, Batteryless Closed-loop Biopotential Recording IC for Implantable Leadless Cardiac Monitoring Applications. BioCAS 2021: 1-4 - [c25]Vuong Van Pham, Amirmasoud Kalantari Dahaghi
Intelligent Approach in Smart Microchip Proppants Data Processing for Complex Hydraulic Fractures Diagnostic. INISTA 2021: 1-5 - [c24]Vuong Van Pham, Amirmasoud Kalantari Dahaghi
Machine Learning Enabled Fracture Network Imaging Using The Wirelessly powered Smart Microchip Proppants Technology. IST 2021: 1-5 - 2020
- [c23]Mostafa Hosseini, Aydin Babakhani:
A Fully Integrated 20-500-GHz Coherent Detector with 2-Hz Frequency Resolution. BCICTS 2020: 1-4 - [c22]Hamed Rahmani
A 1.6mm3 Wirelessly Powered Reconfigurable FDD Radio with On-Chip Antennas Achieving 4.7 pJ/b TX and 1 pJ/b RX Energy Efficiencies for Medical Implants. CICC 2020: 1-4 - [c21]Babak Jamali, Deeban Ramalingam, Aydin Babakhani:
Intelligent Material Classification and Identification Using a Broadband Millimeter-Wave Frequency Comb Receiver. IEEE SENSORS 2020: 1 - [c20]Mostafa Hosseini, M. Mahdi Assefzadeh, Sam Razavian
Terahertz Channel Characterization using a Silicon-based Picosecond Pulse Source. RWS 2020: 76-79
2010 – 2019
- 2019
- [j15]Hongming Lyu, Xiangyu Liu, Aydin Babakhani:
A 100-M/s 2.6-pJ/pulse compact UWB impulse transmitter based on antenna-and-pulse-generator codesign. IEICE Electron. Express 16(24): 20190672 (2019) - [j14]Hongming Lyu
A 430-MHz Wirelessly Powered Implantable Pulse Generator With Intensity/Rate Control and Sub-1 μA Quiescent Current Consumption. IEEE Trans. Biomed. Circuits Syst. 13(1): 180-190 (2019) - [c19]Sam Razavian
A THz Pulse Radiator Based on PIN Diode Reverse Recovery. BCICTS 2019: 1-4 - 2018
- [j13]Hongming Lyu
An Energy-Efficient Wirelessly Powered Millimeter-Scale Neurostimulator Implant Based on Systematic Codesign of an Inductive Loop Antenna and a Custom Rectifier. IEEE Trans. Biomed. Circuits Syst. 12(5): 1131-1143 (2018) - [c18]Hongming Lyu, Mathews John, David Burkland, Brian Greet, Yutao Xi, Luiz Sampaio, Doris Taylor, Mehdi Razavi, Aydin Babakhani:
A Multi-site Heart Pacing Study Using Wirelessly Powered Leadless Pacemakers. EMBC 2018: 3434-3437 - 2017
- [j12]M. Mahdi Assefzadeh
Broadband Oscillator-Free THz Pulse Generation and Radiation Based on Direct Digital-to-Impulse Architecture. IEEE J. Solid State Circuits 52(11): 2905-2919 (2017) - [c17]Dai Li, Aydin Babakhani:
A 4.3 to 5.7 GHz frequency-agile receiver for rapidly-changing channels. MWSCAS 2017: 1458-1460 - 2016
- [j11]Xuebei Yang, Aydin Babakhani:
A Full-Duplex Single-Chip Transceiver With Self-Interference Cancellation in 0.13 µm SiGe BiCMOS for Electron Paramagnetic Resonance Spectroscopy. IEEE J. Solid State Circuits 51(10): 2408-2419 (2016) - [c16]Hamed Rahmani
A fully integrated electromagnetic energy harvesting circuit with an on-chip antenna for biomedical implants in 180 nm SOI CMOS. IEEE SENSORS 2016: 1-3 - [c15]Himanshu Aggrawal, Aydin Babakhani:
An ultra-wideband impulse receiver for sub-100fsec time-transfer and sub-30μm localization. RWS 2016: 42-44 - [c14]Babak Jamali
A 0.2-2.6GHz instantaneous frequency-to-voltage converter in 90nm CMOS. RWS 2016: 45-47 - 2015
- [c13]Charles Chen, Aydin Babakhani:
Wireless synchronization of mm-wave arrays in 65nm CMOS. CICC 2015: 1-4 - [c12]Peiyu Chen
A 30GHz impulse radiator with on-chip antennas for high-resolution 3D imaging. RWS 2015: 32-34 - 2013
- [j10]Mark A. Ferriss, Jean-Olivier Plouchart, Arun Natarajan, Alexander V. Rylyakov, Benjamin D. Parker, José A. Tierno, Aydin Babakhani, Soner Yaldiz, Alberto Valdes-Garcia, Bodhisatwa Sadhu
An Integral Path Self-Calibration Scheme for a Dual-Loop PLL. IEEE J. Solid State Circuits 48(4): 996-1008 (2013) - [j9]Bodhisatwa Sadhu
A linearized, low-phase-noise VCO-based 25-GHz PLL with autonomic biasing. IEEE J. Solid State Circuits 48(5): 1138-1150 (2013) - [j8]Bodhisatwa Sadhu
Correction to "A Linearized, Low Phase Noise VCO Based 25 GHz PLL With Autonomic Biasing". IEEE J. Solid State Circuits 48(6): 1539 (2013) - [j7]Jean-Olivier Plouchart, Mark A. Ferriss, Arun Natarajan, Alberto Valdes-Garcia, Bodhisatwa Sadhu
A 23.5 GHz PLL With an Adaptively Biased VCO in 32 nm SOI-CMOS. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(8): 2009-2017 (2013) - [c11]Xuebei Yang, Aydin Babakhani:
Optical waveguides and photodiodes in 0.18µm CMOS SOI with no post-processing. OFC/NFOEC 2013: 1-3 - 2012
- [c10]Jean-Olivier Plouchart, Mark A. Ferriss, Arun Natarajan, Alberto Valdes-Garcia, Bodhisatwa Sadhu
A 23.5GHz PLL with an adaptively biased VCO in 32nm SOI-CMOS. CICC 2012: 1-4 - [c9]Mark A. Ferriss, Jean-Olivier Plouchart, Arun Natarajan, Alexander V. Rylyakov, Benjamin D. Parker, Aydin Babakhani, Soner Yaldiz, Bodhisatwa Sadhu
An integral path self-calibration scheme for a 20.1-26.7GHz dual-loop PLL in 32nm SOI CMOS. VLSIC 2012: 176-177 - 2011
- [j6]Javad Lavaei, Aydin Babakhani, Ali Hajimiri
Solving Large-Scale Hybrid Circuit-Antenna Problems. IEEE Trans. Circuits Syst. I Regul. Pap. 58-I(2): 374-387 (2011) - 2010
- [c8]Javad Lavaei, Aydin Babakhani, Ali Hajimiri
A study of near-field direct antenna modulation systems using convex optimization. ACC 2010: 1065-1072 - [c7]Javad Lavaei, Aydin Babakhani, Ali Hajimiri
Passively Controllable Smart Antennas. GLOBECOM 2010: 1-6
2000 – 2009
- 2009
- [j5]Arjang Hassibi, Aydin Babakhani, Ali Hajimiri:
A Spectral-Scanning Nuclear Magnetic Resonance Imaging (MRI) Transceiver. IEEE J. Solid State Circuits 44(6): 1805-1813 (2009) - [c6]Javad Lavaei, Aydin Babakhani, Ali Hajimiri
Solving large-scale linear circuit problems via convex optimization. CDC 2009: 4977-4984 - 2008
- [j4]Sanggeun Jeon, Yu-Jiu Wang, Hua Wang, Florian Bohn, Arun Natarajan, Aydin Babakhani, Ali Hajimiri
A Scalable 6-to-18 GHz Concurrent Dual-Band Quad-Beam Phased-Array Receiver in CMOS. IEEE J. Solid State Circuits 43(12): 2660-2673 (2008) - [j3]Aydin Babakhani, David B. Rutledge, Ali Hajimiri
Transmitter Architectures Based on Near-Field Direct Antenna Modulation. IEEE J. Solid State Circuits 43(12): 2674-2692 (2008) - [c5]Sanggeun Jeon, Yu-Jiu Wang, Hua Wang, Florian Bohn, Arun Natarajan, Aydin Babakhani, Ali Hajimiri
A Scalable 6-to-18GHz Concurrent Dual-Band Quad-Beam Phased-Array Receiver in CMOS. ISSCC 2008: 186-187 - [c4]Aydin Babakhani, David B. Rutledge, Ali Hajimiri
A Near-Field Modulation Technique Using Antenna Reflector Switching. ISSCC 2008: 188-189 - 2007
- [c3]Arjang Hassibi, Aydin Babakhani, Ali Hajimiri
A Spectral-Scanning Magnetic Resonance Imaging (MRI) Integrated System. CICC 2007: 123-126 - 2006
- [j2]Aydin Babakhani, Xiang Guan, Abbas Komijani, Arun Natarajan, Ali Hajimiri
A 77-GHz Phased-Array Transceiver With On-Chip Antennas in Silicon: Receiver and Antennas. IEEE J. Solid State Circuits 41(12): 2795-2806 (2006) - [j1]Arun Natarajan, Abbas Komijani, Xiang Guan, Aydin Babakhani, Ali Hajimiri
A 77-GHz Phased-Array Transceiver With On-Chip Antennas in Silicon: Transmitter and Local LO-Path Phase Shifting. IEEE J. Solid State Circuits 41(12): 2807-2819 (2006) - [c2]Aydin Babakhani, Xiang Guan, Abbas Komijani, Arun Natarajan, Ali Hajimiri
A 77GHz 4-Element Phased Array Receiver with On-Chip Dipole Antennas in Silicon. ISSCC 2006: 629-638 - [c1]Arun Natarajan, Abbas Komijani, Xiang Guan, Aydin Babakhani, Y. Wang, Ali Hajimiri
A 77GHz Phased-Array Transmitter with Local LO-Path Phase-Shifting in Silicon. ISSCC 2006: 639-648
Coauthor Index
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last updated on 2024-11-30 00:16 CET by the dblp team
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