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Mihai Sanduleanu
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- affiliation: Khalifa University of Science and Technology, System on Chip Center (SoCC), Abu Dhabi, United Arab Emirates
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2020 – today
- 2024
- [j12]Mohammed Nabeel
, Homer Gamil
Silicon-Proven ASIC Design for the Polynomial Operations of Fully Homomorphic Encryption. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 43(6): 1924-1928 (2024) - 2023
- [j11]Saeedeh Makhsuci
A review of Doherty power amplifier and load modulated balanced amplifier for 5G technology. Int. J. Circuit Theory Appl. 51(5): 2422-2445 (2023) - [c27]Mohammed Nabeel, Deepraj Soni, Mohammed Ashraf, Mizan Abraha Gebremichael, Homer Gamil, Eduardo Chielle, Ramesh Karri
CoFHEE: A Co-processor for Fully Homomorphic Encryption Execution. DATE 2023: 1-2 - [c26]Mihai Sanduleanu, Ahmed Mahdy:
A SDR Transmitter Baseband-to-IF IC with Digital Out-phasing Exponential Modulation in a 65nm CMOS LPE. ICM 2023: 70-73 - [c25]Ademola Akeem Mustapha
A 120GHz Receiver with $1/f$ Noise Mitigation Technique for Near-Field IoT. ISCAS 2023: 1-4 - [c24]Solomon Michael Serunjogi, Mihai Sanduleanu:
3.125GS/s, 4.9 ENOB, 109 fJ/Conversion Time-Domain ADC for Backplane Interconnect. VLSI-SoC 2023: 1-4 - 2022
- [b1]Nourhan Elsayed, Hani H. Saleh, Baker Mohammad, Mohammed Ismail, Mihai Sanduleanu:
High Efficiency Power Amplifier Design for 28 GHz 5G Transmitters. Springer 2022, ISBN 978-3-030-92745-5, pp. 1-91 - [i1]Mohammed Nabeel, Deepraj Soni, Mohammed Ashraf, Mizan Abraha Gebremichael, Homer Gamil, Eduardo Chielle, Ramesh Karri
CoFHEE: A Co-processor for Fully Homomorphic Encryption Execution. CoRR abs/2204.08742 (2022) - 2021
- [c23]Dan Cracan, Mihai Sanduleanu, Mizan Abraha Gebremicheal:
A 0.7-1.5GHz Tunable Papoulis All-Pole Low-Pass Filter in 22nm CMOS FDSOI. ISCAS 2021: 1-5 - [c22]Nourhan Elsayed, Hani H. Saleh, Ademola Mustapha
A 1: 4 Active Power Divider for 5G Phased-Array Transmitters in 22nm CMOS FDSOI. ISCAS 2021: 1-5 - [c21]Solomon Michael Serunjogi, Mahmoud Rasras
64Gb/s NRZ/PAM4 Burst-Mode Optical Receiver Frontend with Gain Control, Offset Correction and Gain Decoupled from Bandwidth. ISCAS 2021: 1-4 - 2020
- [j10]Nourhan Elsayed
A 28-GHz Cascode Inverse Class-D Power Amplifier Utilizing Pulse Injection in 22-nm FDSOI. IEEE Access 8: 97353-97360 (2020) - [j9]Bodhisatwa Sadhu
A 250-mW 60-GHz CMOS Transceiver SoC Integrated With a Four-Element AiP Providing Broad Angular Link Coverage. IEEE J. Solid State Circuits 55(6): 1516-1529 (2020) - [j8]Mamady Kebe, Rida Gadhafi
Human Vital Signs Detection Methods and Potential Using Radars: A Review. Sensors 20(5): 1454 (2020) - [c20]Nourhan Elsayed, Hani H. Saleh, Baker Mohammad, Mihai Sanduleanu:
A 28GHz, Asymmetrical, Modified Doherty Power Amplifier, in 22nm FDSOI CMOS. ISCAS 2020: 1-4 - [c19]Dima Kilani, Baker Mohammad, Mihai Sanduleanu:
Ratioed Logic Comparator Based Digital LDO Regulator in 22nm FDSOI. ISCAS 2020: 1-5
2010 – 2019
- 2019
- [j7]Dima Kilani
Cascaded power management unit characterization for TEG-based IoT devices in 65 nm CMOS. Microelectron. J. 90: 285-296 (2019) - [c18]Leen Qasem, Dima Kilani
Time-based Digital LDO Regulator. ICM 2019: 23-26 - [c17]Solomon Michael Serunjogi, Mustapha Ademola
2.5GS/s, 8-9 ENOB, 8-12.7 fJ/Conversion Differential T/H Amplifier for Gigabit Radio. ISCAS 2019: 1-5 - 2018
- [j6]Ademola Mustapha
A V-Band Transceiver With Integrated Resonator and Receiver/Transmitter Antenna for Near-Field IoT. IEEE Trans. Circuits Syst. II Express Briefs 65-II(10): 1300-1304 (2018) - 2017
- [c16]Solomon Michael Serunjogi, Kai-Wei Lin, Mahmoud Rasras
Low-jitter, plain vanilla CMOS CDR with half-rate linear PD and half rate frequency detector. VLSI-SoC 2017: 1-6 - 2016
- [c15]Mihai Sanduleanu
Invited - Ultra low power integrated transceivers for near-field IoT. DAC 2016: 143:1-143:6 - [c14]Badreyya Al Shehhi, Mihai Sanduleanu
An 800µW Peak Power Consumption, 24GHz (K-Band), Super-Regenerative Receiver with 200p J/bit Energy Efficiency, for IoT. VLSID 2016: 219-223 - 2014
- [j5]Jean-Olivier Plouchart, Fa Wang, Xin Li, Benjamin D. Parker, Mihai A. T. Sanduleanu
Adaptive Circuit Design Methodology and Test Applied to Millimeter-Wave Circuits. IEEE Des. Test 31(6): 8-18 (2014) - [j4]Shupeng Sun, Fa Wang, Soner Yaldiz, Xin Li, Lawrence T. Pileggi, Arun Natarajan, Mark A. Ferriss, Jean-Olivier Plouchart, Bodhisatwa Sadhu
Indirect Performance Sensing for On-Chip Self-Healing of Analog and RF Circuits. IEEE Trans. Circuits Syst. I Regul. Pap. 61-I(8): 2243-2252 (2014) - 2013
- [c13]Mihai A. T. Sanduleanu
A 60GHz, linear, direct down-conversion mixer with mm-Wave tunability in 32nm CMOS SOI. CICC 2013: 1-4 - [c12]Shupeng Sun, Fa Wang, Soner Yaldiz, Xin Li, Lawrence T. Pileggi, Arun Natarajan, Mark A. Ferriss, Jean-Olivier Plouchart, Bodhisatwa Sadhu
Indirect performance sensing for on-chip analog self-healing via Bayesian model fusion. CICC 2013: 1-4 - 2012
- [c11]Jean-Olivier Plouchart, Mihai A. T. Sanduleanu
A 3.2GS/s 4.55b ENOB two-step subranging ADC in 45nm SOI CMOS. CICC 2012: 1-4 - 2011
- [c10]Mihai A. T. Sanduleanu
A 4GS/s, 8.45 ENOB and 5.7fJ/conversion, digital assisted, sampling system in 45nm CMOS SOI. CICC 2011: 1-4
2000 – 2009
- 2008
- [j3]Yanyu Jin, Mihai A. T. Sanduleanu
A Wideband Millimeter-Wave Power Amplifier With 20 dB Linear Power Gain and +8 dBm Maximum Saturated Output Power. IEEE J. Solid State Circuits 43(7): 1553-1562 (2008) - [j2]Wanghua Wu, Mihai A. T. Sanduleanu
17 GHz RF Front-Ends for Low-Power Wireless Sensor Networks. IEEE J. Solid State Circuits 43(9): 1909-1919 (2008) - [j1]Mihai A. T. Sanduleanu
Receiver Front-End Circuits for Future Generations of Wireless Communications. IEEE Trans. Circuits Syst. II Express Briefs 55-II(4): 299-303 (2008) - [c9]John R. Long, Wanghua Wu, Yunzhi Dong, Yi Zhao, Mihai A. T. Sanduleanu
Energy-efficient wireless front-end concepts for ultra lower power radio. CICC 2008: 587-590 - [c8]Maja Vidojkovic, Mihai A. T. Sanduleanu
A 1.2V receiver front-end for multi-standard wireless applications in 65 nm CMOS LP. ESSCIRC 2008: 414-417 - 2007
- [c7]Maja Vidojkovic, Mihai Sanduleanu
A broadband, inductorless LNA for multi-standard aplications. ECCTD 2007: 260-263 - [c6]Yanyu Jin, Mihai A. T. Sanduleanu
A millimeter-wave power amplifier with 25dB power gain and +8dBm saturated output power. ESSCIRC 2007: 276-279 - [c5]Mihai A. T. Sanduleanu, Maja Vidojkovic, Vojkan Vidojkovic, Arthur H. M. van Roermund, Aleksandar Tasic:
Receiver Front-End Circuits for Future Generations of Wireless Communications. ISCAS 2007: 745-748 - 2005
- [c4]Mihai A. T. Sanduleanu
A 34GHz/1V prescaler in 90nm CMOS SOI. ESSCIRC 2005: 109-112 - [c3]Mihai A. T. Sanduleanu
A 10Gb/s, 3.3V, laser/modulator driver with high power efficiency. ESSCIRC 2005: 427-430 - 2003
- [c2]Mihai A. T. Sanduleanu
Inductor-less, 10Gb/s limiter with 10mV sensitivity and offset/temperature compensation in baseline CMOS18. ESSCIRC 2003: 153-156
1990 – 1999
- 1998
- [c1]Mihai A. T. Sanduleanu
A low noise, low residual offset, chopped amplifier for mixed level applications. ICECS 1998: 333-336
Coauthor Index
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