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ORCIDMostafa Gamal Ahmed
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2020 – today
- 2023
[j11]Yongxin Li
, Nilanjan Pal, Tianyu Wang, Mostafa Gamal Ahmed, Ahmed E. AbdelRahman, Mohamed Badr Younis, Kyu-Sang Park, Ruhao Xia, Pavan Kumar Hanumolu:
A 20-μs Turn-On Time, 24-kHz Resolution, 1.5-100-MHz Digitally Programmable Temperature-Compensated Clock Generator. IEEE J. Solid State Circuits 58(3): 785-795 (2023)- [c13]Saion K. Roy, Han-Mo Ou, Mostafa Gamal Ahmed, Peter Deaville, Bonan Zhang, Naveen Verma, Pavan Kumar Hanumolu, Naresh R. Shanbhag:
Compute SNR-boosted 22 nm MRAM-based In-memory Computing Macro using Statistical Error Compensation. ESSCIRC 2023: 25-28 - [c12]Ahmed E. AbdelRahman, Mostafa Gamal Ahmed, Mahmoud A. Khalil, Mohamed Badr Younis, Kyu-Sang Park, Pavan Kumar Hanumolu:
A Carrier-Phase-Recovery Loop for a 3.2pJ/b 24Gb/s QPSK Coherent Optical Receiver. ISSCC 2023: 208-209 - [c11]Mohamed Badr Younis, Mostafa Gamal Ahmed, Tianyu Wang, Ahmed E. AbdelRahman, Mahmoud A. Khalil, Anup P. Jose, Pavan Kumar Hanumolu:
A 5.2 Gb/s 3 mm Air-Gap 4.7 pJ/bit Capacitively-Coupled Transceiver for Giant Video Walls Enabled by a Dual-Edge Tracking Clock and Data Recovery Loop. VLSI Technology and Circuits 2023: 1-2 - 2022
- [j10]Amr Khashaba, Junheng Zhu, Nilanjan Pal, Mostafa Gamal Ahmed, Pavan Kumar Hanumolu:
A 32-MHz, 34-μW Temperature-Compensated RC Oscillator Using Pulse Density Modulated Resistors. IEEE J. Solid State Circuits 57(5): 1470-1479 (2022) - [c10]Yongxin Li, Nilanjan Pal, Tianyu Wang, Mostafa Gamal Ahmed, Ahmed E. AbdelRahman, Mohamed Badr Younis, Ruhao Xia, Kyu-Sang Park, Pavan Kumar Hanumolu:
A 20µs turn-on time, 24kHz resolution, 1.5-100MHz digitally programmable temperature-compensated clock generator with 7.5ppm/°C inaccuracy. CICC 2022: 1-2 - 2021
- [b1]Mostafa Gamal Ahmed:
Receivers for energy efficient optical interconnects. University of Illinois Urbana-Champaign, USA, 2021 - [j9]Mostafa Gamal Ahmed, Dongwook Kim, Romesh Kumar Nandwana, Ahmed Elkholy, Kadaba R. Lakshmikumar, Pavan Kumar Hanumolu:
A 16-Gb/s -11.6-dBm OMA Sensitivity 0.7-pJ/bit Optical Receiver in 65-nm CMOS Enabled by Duobinary Sampling. IEEE J. Solid State Circuits 56(9): 2795-2803 (2021) - 2020
- [j8]Amr Khashaba, Ahmed Elkholy, Karim M. Megawer, Mostafa Gamal Ahmed, Pavan Kumar Hanumolu:
A Low-Noise Frequency Synthesizer Using Multiphase Generation and Combining Techniques. IEEE J. Solid State Circuits 55(3): 592-601 (2020) - [j7]Dongwook Kim, Mostafa Gamal Ahmed, Woo-Seok Choi, Ahmed Elkholy, Pavan Kumar Hanumolu:
A 12-Gb/s 10-ns Turn-On Time Rapid ON/OFF Baud-Rate DFE Receiver in 65-nm CMOS. IEEE J. Solid State Circuits 55(8): 2196-2205 (2020) - [c9]Amr Khashaba, Junheng Zhu, Ahmed Elmallah, Mostafa Gamal Ahmed, Pavan Kumar Hanumolu:
3.2 A 0.0088mm2 Resistor-Based Temperature Sensor Achieving 92fJ·K2 FoM in 65nm CMOS. ISSCC 2020: 60-62 - [c8]Amr Khashaba, Junheng Zhu, Mostafa Gamal Ahmed, Nilanjan Pal, Pavan Kumar Hanumolu:
3.5 A 34µW 32MHz RC Oscillator with ±530ppm Inaccuracy from -40°C to 85°C and 80ppm/V Supply Sensitivity Enabled by Pulse-Density Modulated Resistors. ISSCC 2020: 66-68
2010 – 2019
- 2019
- [j6]Karim M. Megawer, Ahmed Elkholy, Mostafa Gamal Ahmed, Ahmed Elmallah, Pavan Kumar Hanumolu:
Design of Crystal-Oscillator Frequency Quadrupler for Low-Jitter Clock Multipliers. IEEE J. Solid State Circuits 54(1): 65-74 (2019) - [j5]Mostafa Gamal Ahmed, Tam N. Huynh, Christopher Williams, Yong Wang, Pavan Kumar Hanumolu, Alexander V. Rylyakov:
34-GBd Linear Transimpedance Amplifier for 200-Gb/s DP-16-QAM Optical Coherent Receivers. IEEE J. Solid State Circuits 54(3): 834-844 (2019) - [j4]Karim M. Megawer, Nilanjan Pal, Ahmed Elkholy, Mostafa Gamal Ahmed, Amr Khashaba, Danielle Griffith, Pavan Kumar Hanumolu:
A Fast Startup CMOS Crystal Oscillator Using Two-Step Injection. IEEE J. Solid State Circuits 54(12): 3257-3268 (2019) - [j3]Tianyu Wang, Danielle Griffith, Mostafa Gamal Ahmed, Junheng Zhu, Da Wei, Ahmed Elkholy, Ahmed Elmallah, Pavan Kumar Hanumolu:
A 6 $\mu$ W ±50 ppm/°C ±1500 ppm/V 1.5 MHz $RC$ Oscillator Using Self-Regulation. IEEE Trans. Circuits Syst. II Express Briefs 66-II(8): 1297-1301 (2019) - [c7]Amr Khashaba, Ahmed Elkholy, Karim M. Megawer, Mostafa Gamal Ahmed, Pavan Kumar Hanumolu:
A 5GHz 245fsrms 8mW Ring Oscillator-based Digital Frequency Synthesizer. CICC 2019: 1-4 - [c6]Karim M. Megawer, Nilanjan Pal, Ahmed Elkholy, Mostafa Gamal Ahmed, Amr Khashaba, Danielle Griffith, Pavan Kumar Hanumolu:
A 54MHz Crystal Oscillator With 30× 18.5 Start-Up Time Reduction Using 2-Step Injection in 65nm CMOS. ISSCC 2019: 302-304 - [c5]Yangjin Ma, Christopher Williams, Mostafa Gamal Ahmed, Abdellatif Elmoznine, Daihyun Lim, Yang Liu, Ruizhi Shi, Tam N. Huynh, Jose Roman, Abdelrahman H. Ahmed, Leonardo Vera, Yaojia Chen, Alexandre Horth, Hang Guan, Kishore Padmaraju, Matthew Streshinsky, Ari Novack, Rafid A. Sukkar, Rick Younce, Alexander V. Rylyakov, Dominick Scordo, Michael Hochberg:
An All-Silicon Transmitter with Co-Designed Modulator and DC-Coupled Driver. OFC 2019: 1-3 - 2018
- [j2]Mostafa Gamal Ahmed, Mrunmay Talegaonkar, Ahmed Elkholy, Guanghua Shu, Ahmed Elmallah, Alexander V. Rylyakov, Pavan Kumar Hanumolu:
A 12-Gb/s -16.8-dBm OMA Sensitivity 23-mW Optical Receiver in 65-nm CMOS. IEEE J. Solid State Circuits 53(2): 445-457 (2018) - [j1]Ahmed Elkholy, Ahmed Elmallah, Mostafa Gamal Ahmed, Pavan Kumar Hanumolu:
A 6.75-8.25-GHz -250-dB FoM Rapid ON/OFF Fractional-N Injection-Locked Clock Multiplier. IEEE J. Solid State Circuits 53(6): 1818-1829 (2018) - [c4]Ahmed Elmallah, Mostafa Gamal Ahmed, Ahmed Elkholy, Woo-Seok Choi, Pavan Kumar Hanumolu:
A 1.6ps peak-INL 5.3ns range two-step digital-to-time converter in 65nm CMOS. CICC 2018: 1-4 - [c3]Karim M. Megawer, Ahmed Elkholy, Daniel Coombs, Mostafa Gamal Ahmed, Ahmed Elmallah, Pavan Kumar Hanumolu:
A 5GHz 370fsrms 6.5mW clock multiplier using a crystal-oscillator frequency quadrupler in 65nm CMOS. ISSCC 2018: 392-394 - [c2]Mostafa Gamal Ahmed, Tam N. Huynh, Christopher Williams, Yong Wang, Rahul Shringarpure, Reza Yousefi, Jose Roman, Noam Ophir, Alexander V. Rylyakov:
A 34Gbaud Linear Transimpedance Amplifier with Automatic Gain Control for 200Gb/s DP-16QAM Optical Coherent Receivers. OFC 2018: 1-3 - [c1]Ari Novack, Matthew Streshinsky, Tam N. Huynh, Tal Galfsky, Hang Guan, Yang Liu, Yangjin Ma, Ruizhi Shi, Alexandre Horth, Yaojia Chen, Amir Hanjani, Jose Roman, Yury Dziashko, Ran Ding, Saeed Fathololoumi, Andy Eu-Jin Lim, Kishore Padmaraju, Rafid A. Sukkar, Rick Younce, Harald Rohde, Robert Palmer, Guido Saathoff, Torsten Wuth, Marc Bohn, Abdelrahman H. Ahmed, Mostafa Gamal Ahmed, Christopher Williams, Daihyun Lim, Abdellatif Elmoznine, Alexander V. Rylyakov, Tom Baehr Jones, Peter Magill, Dominick Scordo, Michael Hochberg:
A Silicon Photonic Transceiver and Hybrid Tunable Laser for 64 Gbaud Coherent Communication. OFC 2018: 1-3
Coauthor Index
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