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Ramesh Harjani
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- affiliation: University of Minnesota, USA
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2020 – today
- 2024
- [j44]Kyoung-Ub Cho, Joonho Gil, Chulhyun Park, Kyu-Jin Cho, Jaewoo Shin, Eun Seong Kim, Yun Seong Eo, Ramesh Harjani, Nam-Young Kim, Taehyoun Oh:
A 3.5 to 4.7-GHz Fractional-N ADPLL With a Low-Power Time-Interleaved GRO-TDC of 6.2-ps Resolution in 65-nm CMOS Process. IEEE Access 12: 142677-142694 (2024) - [j43]Arvind K. Sharma, Meghna Madhusudan, Steven M. Burns, Soner Yaldiz, Parijat Mukherjee, Ramesh Harjani, Sachin S. Sapatnekar:
Constructive Place-and-Route for FinFET-Based Transistor Arrays in Analog Circuits Under Nonlinear Gradients. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 43(12): 4373-4385 (2024) - [j42]Yishuang Lin, Yaguang Li, Meghna Madhusudan, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
MMM: Machine Learning-Based Macro-Modeling for Linear Analog ICs and ADC/DACs. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 43(12): 4740-4752 (2024) - [c118]Kishor Kunal, Jitesh Poojary, S. Ramprasath, Ramesh Harjani, Sachin S. Sapatnekar:
Automated synthesis of mixed-signal ML inference hardware under accuracy constraints. ASPDAC 2024: 478-483 - [c117]Kishor Kunal, Meghna Madhusudan, Jitesh Poojary, S. Ramprasath, Arvind K. Sharma, Ramesh Harjani, Sachin S. Sapatnekar:
Reinforcing the Connection between Analog Design and EDA (Invited Paper). ASPDAC 2024: 665-670 - 2023
- [j41]Nibedita Karmokar, Arvind K. Sharma, Jitesh Poojary, Meghna Madhusudan, Ramesh Harjani, Sachin S. Sapatnekar:
Constructive Placement and Routing for Common-Centroid Capacitor Arrays in Binary-Weighted and Split DACs. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 42(9): 2782-2795 (2023) - [j40]Kishor Kunal, Tonmoy Dhar, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Jiang Hu, Ramesh Harjani, Sachin S. Sapatnekar:
GNN-Based Hierarchical Annotation for Analog Circuits. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 42(9): 2801-2814 (2023) - [j39]Yaguang Li, Yishuang Lin, Meghna Madhusudan, Arvind K. Sharma, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
Performance-driven Wire Sizing for Analog Integrated Circuits. ACM Trans. Design Autom. Electr. Syst. 28(2): 19:1-19:23 (2023) - [j38]Ramprasath Srinivasa Gopalakrishnan, Meghna Madhusudan, Arvind K. Sharma, Jitesh Poojary, Soner Yaldiz, Ramesh Harjani, Steven M. Burns, Sachin S. Sapatnekar:
A Generalized Methodology for Well Island Generation and Well-tap Insertion in Analog/Mixed-signal Layouts. ACM Trans. Design Autom. Electr. Syst. 28(5): 69:1-69:25 (2023) - [c116]Sumanth Kamineni, Arvind K. Sharma, Ramesh Harjani, Sachin S. Sapatnekar, Benton H. Calhoun:
AuxcellGen: A Framework for Autonomous Generation of Analog and Memory Unit Cells. DATE 2023: 1-6 - [c115]Nibedita Karmokar, Ramesh Harjani, Sachin S. Sapatnekar:
Minimum Unit Capacitance Calculation for Binary-Weighted Capacitor Arrays. DATE 2023: 1-2 - [c114]Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Ramprasath S, Kishor Kunal, Sachin S. Sapatnekar, Ramesh Harjani:
Understanding Distance-Dependent Variations for Analog Circuits in a FinFET Technology. ESSDERC 2023: 69-72 - [c113]Yishuang Lin, Yaguang Li, Meghna Madhusudan, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
MMM: Machine Learning-Based Macro-Modeling for Linear Analog ICs and ADC/DACs. MLCAD 2023: 1-6 - 2022
- [j37]Taehyoun Oh, Joonho Gil, Ramesh Harjani:
Linear Characteristic Analysis of High-Resolution Counter-Based Frequency Detector in Type-I Digital PLL. IEEE Trans. Circuits Syst. II Express Briefs 69(2): 264-268 (2022) - [j36]Sanggeun Lee, Ramesh Harjani, Taehyoun Oh:
Pseudo-Reference Counter-Based FLL for 6 Gb/s Reference-Less CDR in 65-nm CMOS. IEEE Trans. Circuits Syst. II Express Briefs 69(4): 2096-2100 (2022) - [c112]Nibedita Karmokar, Meghna Madhusudan, Arvind K. Sharma, Ramesh Harjani, Mark Po-Hung Lin, Sachin S. Sapatnekar:
Common-Centroid Layout for Active and Passive Devices: A Review and the Road Ahead. ASP-DAC 2022: 114-121 - [c111]Tonmoy Dhar, Ramprasath S, Jitesh Poojary, Soner Yaldiz, Steven M. Burns, Ramesh Harjani, Sachin S. Sapatnekar:
A Charge Flow Formulation for Guiding Analog/Mixed-Signal Placement. DATE 2022: 148-153 - [c110]Yishuang Lin, Yaguang Li, Donghao Fang, Meghna Madhusudan, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
Are Analytical Techniques Worthwhile for Analog IC Placement? DATE 2022: 154-159 - [c109]Nibedita Karmokar, Arvind K. Sharma, Jitesh Poojary, Meghna Madhusudan, Ramesh Harjani, Sachin S. Sapatnekar:
Constructive Common-Centroid Placement and Routing for Binary-Weighted Capacitor Arrays. DATE 2022: 166-171 - [c108]Ramprasath S, Meghna Madhusudan, Arvind K. Sharma, Jitesh Poojary, Soner Yaldiz, Ramesh Harjani, Steven M. Burns, Sachin S. Sapatnekar:
Analog/Mixed-Signal Layout Optimization using Optimal Well Taps. ISPD 2022: 159-166 - 2021
- [j35]Tonmoy Dhar, Kishor Kunal, Yaguang Li, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Ramesh Harjani, Jiang Hu, Desmond A. Kirkpatrick, Parijat Mukherjee, Soner Yaldiz, Sachin S. Sapatnekar:
ALIGN: A System for Automating Analog Layout. IEEE Des. Test 38(2): 8-18 (2021) - [c107]Tonmoy Dhar, Jitesh Poojary, Yaguang Li, Kishor Kunal, Meghna Madhusudan, Arvind K. Sharma, Susmita Dey Manasi, Jiang Hu, Ramesh Harjani, Sachin S. Sapatnekar:
Fast and Efficient Constraint Evaluation of Analog Layout Using Machine Learning Models. ASP-DAC 2021: 158-163 - [c106]Arvind K. Sharma, Meghna Madhusudan, Steven M. Burns, Parijat Mukherjee, Soner Yaldiz, Ramesh Harjani, Sachin S. Sapatnekar:
Common-Centroid Layouts for Analog Circuits: Advantages and Limitations. DATE 2021: 1224-1229 - [c105]Juzheng Liu, Shiyu Su, Meghna Madhusudan, Mohsen Hassanpourghadi, Samuel Saunders, Qiaochu Zhang, Rezwan A. Rasul, Yaguang Li, Jiang Hu, Arvind Kumar Sharma, Sachin S. Sapatnekar, Ramesh Harjani, Anthony Levi, Sandeep Gupta, Mike Shuo-Wei Chen:
From Specification to Silicon: Towards Analog/Mixed-Signal Design Automation using Surrogate NN Models with Transfer Learning. ICCAD 2021: 1-9 - [c104]Arvind K. Sharma, Meghna Madhusudan, Steven M. Burns, Soner Yaldiz, Parijat Mukherjee, Ramesh Harjani, Sachin S. Sapatnekar:
Performance-Aware Common-Centroid Placement and Routing of Transistor Arrays in Analog Circuits. ICCAD 2021: 1-9 - [c103]Tonmoy Dhar, Jitesh Poojary, Ramesh Harjani, Sachin S. Sapatnekar:
Aging of Current DACs and its Impact in Equalizer Circuits. IRPS 2021: 1-6 - [c102]Tonmoy Dhar, Kishor Kunal, Yaguang Li, Yishuang Lin, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Steven M. Burns, Ramesh Harjani, Jiang Hu, Parijat Mukherjee, Soner Yaldiz, Sachin S. Sapatnekar:
Machine Learning Techniques in Analog Layout Automation. ISPD 2021: 71-72 - [c101]Jitesh Poojary, Ramesh Harjani:
6.4 A 1-to-3GHz Co-Channel Blocker Resistant, Spatially and Spectrally Passive MIMO Receiver in 65nm CMOS with +6dBm In-Band/In-Notch B1dB. ISSCC 2021: 96-98 - [c100]Ramesh Harjani, Mike Chen, Marco Berkhout, Johan H. C. van den Heuvel, Thomas H. Lee, Robert Bogdan Staszewski, Kathleen Philips, Howard C. Luong, Vadim Ivanov:
SE3: Favorite Circuit Design and Testing Mistakes of Starting Engineers. ISSCC 2021: 541-542 - [c99]Yaguang Li, Yishuang Lin, Meghna Madhusudan, Arvind K. Sharma, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
A Circuit Attention Network-Based Actor-Critic Learning Approach to Robust Analog Transistor Sizing. MLCAD 2021: 1-6 - 2020
- [b1]Mustafijur Rahman, Ramesh Harjani:
Design of Low Power Integrated Radios for Emerging Standards. Springer 2020, ISBN 978-3-030-21332-9, pp. 1-67 - [j34]Shiva Jamali-Zavareh, Ramesh Harjani:
Jitter Suppression Techniques for High-Speed Sample-and-Hold Circuits. IEEE Trans. Circuits Syst. I Regul. Pap. 67-I(1): 1-11 (2020) - [c98]Kishor Kunal, Tonmoy Dhar, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Jiang Hu, Ramesh Harjani, Sachin S. Sapatnekar:
GANA: Graph Convolutional Network Based Automated Netlist Annotation for Analog Circuits. DATE 2020: 55-60 - [c97]Tonmoy Dhar, Kishor Kunal, Yaguang Li, Yishuang Lin, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Steven M. Burns, Ramesh Harjani, Jiang Hu, Parijat Mukherjee, Soner Yaldiz, Sachin S. Sapatnekar:
The ALIGN Open-Source Analog Layout Generator: v1.0 and Beyond (Invited talk). ICCAD 2020: 54:1-54:2 - [c96]Kishor Kunal, Jitesh Poojary, Tonmoy Dhar, Meghna Madhusudan, Ramesh Harjani, Sachin S. Sapatnekar:
A general approach for identifying hierarchical symmetry constraints for analog circuit layout. ICCAD 2020: 120:1-120:8 - [c95]Yaguang Li, Yishuang Lin, Meghna Madhusudan, Arvind K. Sharma, Wenbin Xu, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
A Customized Graph Neural Network Model for Guiding Analog IC Placement. ICCAD 2020: 135:1-135:9 - [c94]Kishor Kunal, Tonmoy Dhar, Yaguang Li, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Ramesh Harjani, Jiang Hu, Parijat Mukherjee, Sachin S. Sapatnekar:
Learning from Experience: Applying ML to Analog Circuit Design. ISPD 2020: 55 - [c93]Yaguang Li, Yishuang Lin, Meghna Madhusudan, Arvind K. Sharma, Wenbin Xu, Sachin S. Sapatnekar, Ramesh Harjani, Jiang Hu:
Exploring a Machine Learning Approach to Performance Driven Analog IC Placement. ISVLSI 2020: 24-29 - [i2]Tonmoy Dhar, Kishor Kunal, Yaguang Li, Meghna Madhusudan, Jitesh Poojary, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Ramesh Harjani, Jiang Hu, Desmond A. Kirkpatrick, Parijat Mukherjee, Sachin S. Sapatnekar, Soner Yaldiz:
ALIGN: A System for Automating Analog Layout. CoRR abs/2008.10682 (2020) - [i1]Kishor Kunal, Jitesh Poojary, Tonmoy Dhar, Meghna Madhusudan, Ramesh Harjani, Sachin S. Sapatnekar:
A general approach for identifying hierarchical symmetry constraints for analog circuit layout. CoRR abs/2010.00051 (2020)
2010 – 2019
- 2019
- [j33]Naser Mousavi, Zhiheng Wang, Danijela Cabric, Ramesh Harjani:
A 0.4-1.0 GHz, 47 MHop/s Frequency-Hopped TXR Front End With 20 dB In-Band Blocker Rejection. IEEE J. Solid State Circuits 54(7): 1917-1928 (2019) - [c92]Saurabh Chaubey, Ramesh Harjani:
A Multi-Mode DC-DC Converter for Direct Battery-to-Silicon High Tension Power Delivery in 65nm CMOS. CICC 2019: 1-4 - [c91]Kishor Kunal, Meghna Madhusudan, Arvind K. Sharma, Wenbin Xu, Steven M. Burns, Ramesh Harjani, Jiang Hu, Desmond A. Kirkpatrick, Sachin S. Sapatnekar:
ALIGN: Open-Source Analog Layout Automation from the Ground Up. DAC 2019: 77 - [c90]Saurabh Chaubey, Meghna Madhusudan, Ramesh Harjani:
Design Techniques for Zero Steady-State Output Ripple in Digital Low Dropout Regulators. MWSCAS 2019: 1041-1044 - 2018
- [j32]Mustafijur Rahman, Ramesh Harjani:
A 2.4-GHz, Sub-1-V, 2.8-dB NF, 475-µW Dual-Path Noise and Nonlinearity Cancelling LNA for Ultra-Low-Power Radios. IEEE J. Solid State Circuits 53(5): 1423-1430 (2018) - [c89]Xingyi Hua, Ramesh Harjani:
A 5μW-5mW input power range, 0-3.5V output voltage range RF energy harvester with power-estimator-enhanced MPPT controller. CICC 2018: 1-4 - [c88]Naser Mousavi, Zhiheng Wang, Ramesh Harjani:
A 0.4-1.0GHz, 47MHop/S Frequency Hopped TXR Front-End with 20dB in-Band Blocker Rejection. ESSCIRC 2018: 66-69 - [c87]Qingrui Meng, Ramesh Harjani:
A 4GHz Instantaneous Bandwidth Low Squint Phased Array Using Sub-Harmonic ILO Based Channelization. ESSCIRC 2018: 110-113 - [c86]Mustafijur Rahman, Ramesh Harjani:
A 2.4GHz IEEE 802.15.6 Compliant 1.52nJ/bit TX & 1.32nJ/bit RX Multiband Transceiver for Low Power Standards. ICECS 2018: 821-824 - [c85]Anindya Saha, Saurabh Chaubey, Ramesh Harjani:
A 100MS/s 9-bit Companding SAR ADC with On-Chip Input Driver in 65nm CMOS for Multi-Carrier Communications. MWSCAS 2018: 174-177 - 2017
- [j31]Hundo Shin, Ramesh Harjani:
Low-Power Wideband Analog Channelization Filter Bank Using Passive Polyphase-FFT Techniques. IEEE J. Solid State Circuits 52(7): 1753-1767 (2017) - [j30]M. Hassan Najafi, Shiva Jamali-Zavareh, David J. Lilja, Marc D. Riedel, Kia Bazargan, Ramesh Harjani:
An Overview of Time-Based Computing with Stochastic Constructs. IEEE Micro 37(6): 62-71 (2017) - [j29]M. Hassan Najafi, Shiva Jamali-Zavareh, David J. Lilja, Marc D. Riedel, Kia Bazargan, Ramesh Harjani:
Time-Encoded Values for Highly Efficient Stochastic Circuits. IEEE Trans. Very Large Scale Integr. Syst. 25(5): 1644-1657 (2017) - [c84]Saurabh Chaubey, Ramesh Harjani:
A smart-offset analog LDO with 0.3V minimum input voltage and 99.1% current efficiency. A-SSCC 2017: 269-272 - [c83]Saurabh Chaubey, Ramesh Harjani:
Fully tunable software defined DC-DC converter with 3000X output current & 4X output voltage ranges. CICC 2017: 1-4 - [c82]Ramesh Harjani:
Integrated DC-DC converter design. CICC 2017: 1-92 - 2016
- [c81]Hundo Shin, Ramesh Harjani:
A 1GHz signal bandwidth 4-channel-I/Q polyphase-FFT filter bank. ESSCIRC 2016: 355-358 - [c80]Qingrui Meng, Ramesh Harjani:
An easily extendable FFT based four-channel, four-beam receiver with progressive partial spatial filtering in 65nm. ESSCIRC 2016: 359-362 - [c79]Shiva Jamali-Zavareh, Ramesh Harjani:
A jitter-resilient sampling technique for high-resolution ADCs in wideband RF receivers. ICECS 2016: 229-232 - [c78]Mustafijur Rahman, Ramesh Harjani:
CMOS energy efficient integrated radios for emerging low power standards. ISOCC 2016: 151-152 - 2015
- [j28]Ramesh Harjani, Danijela Cabric, Dejan Markovic, Brian M. Sadler, Rakesh Kumar Palani, Anindya Saha, Hundo Shin, Eric Rebeiz, Sina Basir-Kazeruni, Fang-Li Yuan:
Wideband blind signal classification on a battery budget. IEEE Commun. Mag. 53(10): 173-181 (2015) - [j27]Mustafijur Rahman, Mohammad Elbadry, Ramesh Harjani:
An IEEE 802.15.6 Standard Compliant 2.5 nJ/Bit Multiband WBAN Transmitter Using Phase Multiplexing and Injection Locking. IEEE J. Solid State Circuits 50(5): 1126-1136 (2015) - [j26]Rakesh Kumar Palani, Ramesh Harjani:
A 220-MS/s 9-Bit 2X Time-Interleaved SAR ADC With a 133-fF Input Capacitance and a FOM of 37 fJ/conv in 65-nm CMOS. IEEE Trans. Circuits Syst. II Express Briefs 62-II(11): 1053-1057 (2015) - [c77]Ramesh Harjani, Rakesh Kumar Palani:
Design of PVT tolerant inverter based circuits for low supply voltages. CICC 2015: 1-8 - [c76]Xingyi Hua, Ramesh Harjani:
3.5-0.5V input, 1.0V output multi-mode power transformer for a supercapacitor power source with a peak efficiency of 70.4%. CICC 2015: 1-4 - [c75]Rakesh Kumar Palani, Ramesh Harjani:
A 4.6mW, 22dBm IIP3 all MOSCAP based 34-314MHz tunable continuous time filter in 65nm. CICC 2015: 1-4 - [c74]Hundo Shin, Rakesh Kumar Palani, Anindya Saha, Fang-Li Yuan, Dejan Markovic, Ramesh Harjani:
An eight channel analog-FFT based 450MS/s hybrid filter bank ADC with improved SNDR for multi-band signals in 40nm CMOS. CICC 2015: 1-4 - [c73]Rakesh Kumar Palani, Aravindhan Rangarajan, Ramesh Harjani:
Chopper stabilized sub 1V reference voltage in 65nm CMOS. MWSCAS 2015: 1-4 - [c72]Fang-Li Yuan, Rakesh Kumar Palani, Sina Basir-Kazeruni, Hundo Shin, Anindya Saha, Ramesh Harjani, Dejan Markovic:
A throughput-agnostic 11.9-13.6GOPS/mW multi-signal classification SoC for cognitive radios in 40nm CMOS. VLSIC 2015: 150- - 2014
- [j25]Bodhisatwa Sadhu, Martin Sturm, Brian M. Sadler, Ramesh Harjani:
Building an on-chip spectrum sensor for cognitive radios. IEEE Commun. Mag. 52(4): 92-100 (2014) - [c71]Mohammad Elbadry, Sachin Kalia, Ramesh Harjani:
A 52% tuning range QVCO with a reduced noise coupling scheme and a minimum FOMT of 196dBc/Hz. CICC 2014: 1-4 - [c70]Ramesh Harjani, Saurabh Chaubey:
A unified framework for capacitive series-parallel DC-DC converter design. CICC 2014: 1-8 - [c69]Sudhir S. Kudva, Saurabh Chaubey, Ramesh Harjani:
High power-density, hybrid inductive/capacitive converter with area reuse for multi-domain DVS. CICC 2014: 1-4 - [c68]Rakesh Kumar Palani, Ramesh Harjani:
High linearity PVT tolerant 100MS/s rail-to-rail ADC driver with built-in sampler in 65nm CMOS. CICC 2014: 1-4 - 2013
- [j24]Bodhisatwa Sadhu, Mark A. Ferriss, Arun Natarajan, Soner Yaldiz, Jean-Olivier Plouchart, Alexander V. Rylyakov, Alberto Valdes-Garcia, Benjamin D. Parker, Aydin Babakhani, Scott K. Reynolds, Xin Li, Lawrence T. Pileggi, Ramesh Harjani, José A. Tierno, Daniel J. Friedman:
A linearized, low-phase-noise VCO-based 25-GHz PLL with autonomic biasing. IEEE J. Solid State Circuits 48(5): 1138-1150 (2013) - [j23]Bodhisatwa Sadhu, Martin Sturm, Brian M. Sadler, Ramesh Harjani:
Analysis and Design of a 5 GS/s Analog Charge-Domain FFT for an SDR Front-End in 65 nm CMOS. IEEE J. Solid State Circuits 48(5): 1199-1211 (2013) - [j22]Taehyoun Oh, Ramesh Harjani:
A 12-Gb/s Multichannel I/O Using MIMO Crosstalk Cancellation and Signal Reutilization in 65-nm CMOS. IEEE J. Solid State Circuits 48(6): 1383-1397 (2013) - [j21]Bodhisatwa Sadhu, Mark A. Ferriss, Arun S. Natarajan, Soner Yaldiz, Jean-Olivier Plouchart, Alexander V. Rylyakov, Alberto Valdes-Garcia, Benjamin D. Parker, Aydin Babakhani, Scott K. Reynolds, Xin Li, Lawrence T. Pillage, Ramesh Harjani, José A. Tierno, Daniel J. Friedman:
Correction to "A Linearized, Low Phase Noise VCO Based 25 GHz PLL With Autonomic Biasing". IEEE J. Solid State Circuits 48(6): 1539 (2013) - [j20]Sudhir S. Kudva, Ramesh Harjani:
Fully Integrated Capacitive DC-DC Converter With All-Digital Ripple Mitigation Technique. IEEE J. Solid State Circuits 48(8): 1910-1920 (2013) - [j19]Jean-Olivier Plouchart, Mark A. Ferriss, Arun Natarajan, Alberto Valdes-Garcia, Bodhisatwa Sadhu, Alexander V. Rylyakov, Benjamin D. Parker, Michael P. Beakes, Aydin Babakhani, Soner Yaldiz, Larry T. Pileggi, Ramesh Harjani, Scott K. Reynolds, José A. Tierno, Daniel J. Friedman:
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) - [j18]Sachin Kalia, Satwik A. Patnaik, Bodhisatwa Sadhu, Martin Sturm, Mohammad Elbadry, Ramesh Harjani:
Multi-Beam Spatio-Spectral Beamforming Receiver for Wideband Phased Arrays. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(8): 2018-2029 (2013) - 2012
- [c67]Jaehyup Kim, Bruce Hammer, Ramesh Harjani:
A 5-300MHz CMOS transceiver for multi-nuclear NMR spectroscopy. CICC 2012: 1-4 - [c66]Sudhir S. Kudva, Ramesh Harjani:
Fully integrated capacitive converter with all digital ripple mitigation. CICC 2012: 1-4 - [c65]Satwik A. Patnaik, Sachin Kalia, Bodhisatwa Sadhu, Martin Sturm, Mohammad Elbadry, Ramesh Harjani:
An 8GHz multi-beam spatio-spectral beamforming receiver using an all-passive discrete time analog baseband in 65nm CMOS. CICC 2012: 1-4 - [c64]Jean-Olivier Plouchart, Mark A. Ferriss, Arun Natarajan, Alberto Valdes-Garcia, Bodhisatwa Sadhu, Alexander V. Rylyakov, Benjamin D. Parker, Michael P. Beakes, Aydin Babakhani, Soner Yaldiz, Lawrence T. Pileggi, Ramesh Harjani, Scott K. Reynolds, José A. Tierno, Daniel J. Friedman:
A 23.5GHz PLL with an adaptively biased VCO in 32nm SOI-CMOS. CICC 2012: 1-4 - [c63]Alberto Valdes-Garcia, Ramesh Harjani:
Radio receiver techniques. CICC 2012: 1 - [c62]Taehyoun Oh, Ramesh Harjani:
4×12 Gb/s 0.96 pJ/b/lane analog-IIR crosstalk cancellation and signal reutilization receiver for single-ended I/Os in 65 nm CMOS. VLSIC 2012: 140-141 - 2011
- [j17]Taehyoun Oh, Ramesh Harjani:
A 6-Gb/s MIMO Crosstalk Cancellation Scheme for High-Speed I/Os. IEEE J. Solid State Circuits 46(8): 1843-1856 (2011) - [j16]Sudhir S. Kudva, Ramesh Harjani:
Fully-Integrated On-Chip DC-DC Converter With a 450X Output Range. IEEE J. Solid State Circuits 46(8): 1940-1951 (2011) - [j15]Narasimha Lanka, Satwik A. Patnaik, Ramesh Harjani:
Frequency-Hopped Quadrature Frequency Synthesizer in 0.13-mum Technology. IEEE J. Solid State Circuits 46(9): 2021-2032 (2011) - 2010
- [j14]Mahmoud Reza Ahmadi, Amir Amirkhany, Ramesh Harjani:
A 5 Gbps 0.13 μ m CMOS Pilot-Based Clock and Data Recovery Scheme for High-Speed Links. IEEE J. Solid State Circuits 45(8): 1533-1541 (2010) - [c61]Sudhir S. Kudva, Ramesh Harjani:
Fully integrated on-chip DC-DC converter with a 450x output range. CICC 2010: 1-4 - [c60]Taehyoun Oh, Ramesh Harjani:
A 5Gb/s 2×2 MIMO crosstalk cancellation scheme for high-speed I/Os. CICC 2010: 1-4 - [c59]Bodhisatwa Sadhu, Ramesh Harjani:
Capacitor bank design for wide tuning range LC VCOs: 850MHz-7.1GHz (157%). ISCAS 2010: 1975-1978
2000 – 2009
- 2009
- [j13]Jie Gu, Ramesh Harjani, Chris H. Kim:
Design and Implementation of Active Decoupling Capacitor Circuits for Power Supply Regulation in Digital ICs. IEEE Trans. Very Large Scale Integr. Syst. 17(2): 292-301 (2009) - [c58]Mahmoud Reza Ahmadi, Amir Amirkhany, Ramesh Harjani:
A 5Gbps 0.13μm CMOS pilot-based clock and data recovery scheme for high-speed links. CICC 2009: 125-128 - [c57]Ramesh Harjani, Alireza Shirvani Marvell:
Millimeter-wave ICs. CICC 2009 - [c56]Narasimha Lanka, Satwik A. Patnaik, Ramesh Harjani:
A sub-2.5ns frequency-hopped quadrature frequency synthesizer in 0.13-μm technology. CICC 2009: 57-60 - [c55]Bodhisatwa Sadhu, Jaehyup Kim, Ramesh Harjani:
A CMOS 3.3-8.4 GHz wide tuning range, low phase noise LC VCO. CICC 2009: 559-562 - [c54]Satwik A. Patnaik, Narasimha Lanka, Ramesh Harjani:
A dual-mode architecture for a phased-array receiver based on injection locking in 0.13µm CMOS. ISSCC 2009: 490-491 - 2008
- [j12]Josh Wibben, Ramesh Harjani:
A High-Efficiency DC-DC Converter Using 2 nH Integrated Inductors. IEEE J. Solid State Circuits 43(4): 844-854 (2008) - [j11]Kin-Joe Sham, Shubha Bommalingaiahnapallya, Mahmoud Reza Ahmadi, Ramesh Harjani:
A 3, times, 5-Gb/s Multilane Low-Power 0.18-muhbox m CMOS Pseudorandom Bit Sequence Generator. IEEE Trans. Circuits Syst. II Express Briefs 55-II(5): 432-436 (2008) - [j10]Mahmoud Reza Ahmadi, Jaekyun Moon, Ramesh Harjani:
Constrained Partial Response Receivers for High-Speed Links. IEEE Trans. Circuits Syst. II Express Briefs 55-II(10): 1006-1010 (2008) - [c53]Liuchun Cai, Ramesh Harjani:
Modeling, measurement and mitigation of crosstalk noise coupling in 3D-ICs. CICC 2008: 683-686 - [c52]Ramesh Harjani, Andrea Mazzanti:
Session 19 - Low power and non-traditional RF tranceivers. CICC 2008 - [c51]Bodhisatwa Sadhu, Umaikhe E. Omole, Ramesh Harjani:
Modeling and synthesis of wide-band switched-resonators for VCOs. CICC 2008: 225-228 - 2007
- [c50]Narasimha Lanka, Satwik A. Patnaik, Ramesh Harjani:
Understanding the Transient Behavior of Injection Locked LC Oscillators. CICC 2007: 667-670 - [c49]Shubha Bommalingaiahnapallya, Kin-Joe Sham, Mahmoud Reza Ahmadi, Ramesh Harjani:
High-Speed Circuits for a Multi-Lane 12 Gbps CMOS PRBS Generator. ISCAS 2007: 3896-3899 - 2006
- [j9]Frank R. Dropps, Ramesh Harjani:
Gain Calibration Technique for Increased Resolution in FRC Data Converters. IEEE Trans. Circuits Syst. II Express Briefs 53-II(11): 1200-1204 (2006) - [c48]Kin-Joe Sham, Mahmoud Reza Ahmadi, S. B. Gerry Talbot, Ramesh Harjani:
FEXT Crosstalk Cancellation for High-Speed Serial Link Design. CICC 2006: 405-408 - 2005
- [j8]Mi-Kyung Oh, Byunghoo Jung, Ramesh Harjani, Dong-Jo Park:
A new noncoherent UWB impulse radio receiver. IEEE Commun. Lett. 9(2): 151-153 (2005) - [j7]Yongwang Ding, Ramesh Harjani:
A high-efficiency CMOS +22-dBm linear power amplifier. IEEE J. Solid State Circuits 40(9): 1895-1900 (2005) - [c47]Jafar Savoj, Ramesh Harjani:
Clocking circuits for wireline communications. CICC 2005: 526-527 - [c46]Byunghoo Jung, Yi-Hung Tseng, Jackson Harvey, Ramesh Harjani:
Pulse generator design for UWB IR communication systems. ISCAS (5) 2005: 4381-4384 - [c45]Byunghoo Jung, Shubha Bommalingaiahnapallya, Ramesh Harjani:
Power optimized LC VCO and mixer co-design. ISCAS (5) 2005: 4393-4396 - [c44]Shubha Bommalingaiahnapallya, Ramesh Harjani:
Process tolerant design of N-tone Sigma-Delta converters. ISCAS (5) 2005: 4630-4633 - [c43]Sachin S. Sapatnekar, Jaijeet S. Roychowdhury, Ramesh Harjani:
High-Speed Interconnect Technology: On-Chip and Off-Chip. VLSI Design 2005: 7 - 2004
- [j6]Byunghoo Jung, Ramesh Harjani:
ΣHigh-frequency LC VCO design using capacitive degeneration. IEEE J. Solid State Circuits 39(12): 2359-2370 (2004) - [c42]Wooyoung Choi, Bapiraju Vinnakota, Ramesh Harjani:
A digital DFT technique for verifying the static performance of A/D converters. CICC 2004: 207-210 - [c41]Yong Zhan, Ramesh Harjani, Sachin S. Sapatnekar:
On the selection of on-chip inductors for the optimal VCO design. CICC 2004: 277-280 - [c40]Jim Koeppe, Ramesh Harjani:
Enhanced analytic noise model for RF CMOS design. CICC 2004: 383-386 - [c39]Yongwang Ding, Ramesh Harjani:
A CMOS high efficiency +22 dBm linear power amplifier. CICC 2004: 557-560 - [c38]Byunghoo Jung, Ramesh Harjani:
A wide tuning range VCO using capacitive source degeneration. ISCAS (4) 2004: 145-148 - [c37]Shubha Bommalingaiahnapallya, Ramesh Harjani:
Low power implementation of an n-tone Sigma Delta converter. ISCAS (1) 2004: 461-464 - [c36]Ramesh Harjani, Jackson Harvey, Robert Sainati:
Analog/RF Physical Layer Issues For UWB Systems. VLSI Design 2004: 941- - 2003
- [c35]Byunghoo Jung, Anand Gopinath, Ramesh Harjani:
A novel noise optimization design technique for radio frequency low noise amplifiers. ISCAS (1) 2003: 209-212 - [c34]Deepa S. Parthasarathy, Ramesh Harjani:
Novel integratable notch filter implementation for 100 dB image rejection. ISCAS (1) 2003: 473-476 - 2001
- [j5]Ramesh Harjani:
A 455-Mb/s MR preamplifier design in a 0.8-μm CMOS process. IEEE J. Solid State Circuits 36(6): 862-872 (2001) - [c33]Ron Balczewski, Ramesh Harjani:
Capacitive voltage multipliers: a high efficiency method to generate multiple on-chip supply voltages. ISCAS (1) 2001: 508-511 - [c32]Wooyoung Choi, Ramesh Harjani, Bapiraju Vinnakota:
Non-ideal amplifier effects on the accuracy of analog-to-digital capacitor ratio converter. ISCAS (1) 2001: 552-555 - [c31]Jonghae Kim, Ramesh Harjani:
An ISM band CMOS integrated transceiver design for wireless telemetry system. ISCAS (4) 2001: 694-697 - [c30]Ming-Ta Hsieh, Jackson Harvey, Ramesh Harjani:
Power optimization of CMOS LC VCOs. ISCAS (4) 2001: 718-721 - [c29]Jackson Harvey, Ramesh Harjani:
Analysis and gain design of an integrated quadrature mixer with improved noise and image rejection. ISCAS (4) 2001: 786-789 - [c28]Ramesh Harjani, Jackson Harvey:
Tutorial: CMOS Analog Circuits for Wireless Communications. VLSI Design 2001: 18 - [c27]Jackson Harvey, Ramesh Harjani:
An Integrated Quadrature Mixer with Improved Image Rejection at Low Voltage. VLSI Design 2001: 269-273 - 2000
- [j4]Liang Dai, Ramesh Harjani:
CMOS switched-op-amp-based sample-and-hold circuit. IEEE J. Solid State Circuits 35(1): 109-113 (2000) - [j3]Bapiraju Vinnakota, Ramesh Harjani:
DFT for digital detection of analog parametric faults in SC filters. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 19(7): 789-798 (2000) - [c26]Wooyoung Choi, Ramesh Harjani, Bapiraju Vinnakota:
Optimal test-set generation for parametric fault detection in switched capacitor filters. Asian Test Symposium 2000: 72-77 - [c25]Ramesh Harjani, Oyvind Birkenes, Jonghae Kim:
An IF stage design for an ASK-based wireless telemetry system. ISCAS 2000: 52-55 - [c24]Liang Dai, Ramesh Harjani:
Comparison and analysis of phase noise in ring oscillators. ISCAS 2000: 77-80 - [c23]Yongwang Ding, Ramesh Harjani:
A universal analytic charge injection model. ISCAS 2000: 144-147 - [c22]Doug Dean, Ramesh Harjani:
A high speed differential to single-ended amplifier for instrumentation applications. ISCAS 2000: 459-462 - [c21]Liang Dai, Ramesh Harjani:
Analysis and design of low-phase-noise ring oscillators. ISLPED 2000: 289-294 - [c20]Ramesh Harjani:
Analog Circuits for Wireless Communications. VLSI Design 2000: 7
1990 – 1999
- 1999
- [c19]Bapiraju Vinnakota, Ramesh Harjani:
Digital detection of parametric faults in data converters. CICC 1999: 151-154 - [c18]Ramesh Harjani, Bapiraju Vinnakota:
Digital Aetection of Analog Parametric Faults in SC Filters. DAC 1999: 772-777 - [c17]Kavita Nair, Ramesh Harjani:
A telemetry and interface circuit for piezoelectric sensors. ISCAS (5) 1999: 152-155 - [c16]Kavita Nair, Ramesh Harjani:
Compact, Ultra Low Power, Programmable Continuous-Time Filter Banks for Feedback Cancellation in Hearing Aid. VLSI Design 1999: 55-60 - 1997
- [c15]Kaushik Roy, Rabindra K. Roy, Ramesh Harjani, K. S. Murthy:
T5: Low-Power Design. VLSI Design 1997: 4 - [c14]Bapiraju Vinnakota, Ramesh Harjani, Wooyoung Choi:
Pseudoduplication - An ACOB Technique for Single-Ended Circuits. VLSI Design 1997: 398-402 - 1996
- [j2]Nicholas J. Stessman, Bapiraju Vinnakota, Ramesh Harjani:
System-level design for test of fully differential analog circuits. IEEE J. Solid State Circuits 31(10): 1526-1534 (1996) - [c13]Bapiraju Vinnakota, Ramesh Harjani:
Mixed-Signal Design for Test. VLSI Design 1996: 2 - 1995
- [c12]Bapiraju Vinnakota, Ramesh Harjani, Nicholas J. Stessman:
System-Level Design for Test of Fully Differential Analog Circuits. DAC 1995: 450-454 - [c11]Feng Wang, Ramesh Harjani:
Dynamic Amplifiers: Settling, Slewing and Power Issues. ISCAS 1995: 319-322 - 1994
- [c10]Jianfeng Shao, Ramesh Harjani:
Macromodeling of analog circuits for hierarchical circuit design. ICCAD 1994: 656-663 - [c9]Andrew Cable, Ramesh Harjani:
A 6-Bit 50MHz Current-Subtracting Two Step Flash Converter. ISCAS 1994: 465-468 - [c8]Bapiraju Vinnakota, Ramesh Harjani:
The Design of Analog Self-Checking Circuits. VLSI Design 1994: 67-70 - [c7]Ramesh Harjani, Bapiraju Vinnakota:
Analog circuit observer blocks. VTS 1994: 258-263 - 1993
- [c6]Rongtai Wang, Ramesh Harjani:
Acoustic feedback cancellation in hearing aids. ICASSP (1) 1993: 137-140 - [c5]Rongtai Wang, Ramesh Harjani:
Suppression of acoustic oscillations in hearing aids using minimum phase techniques. ISCAS 1993: 818-821 - [c4]Brian A. Blow, Ramesh Harjani, Dennis L. Polla, Takashi Tamagawa:
A Dual Frequency Range Integrated Circuit Accelerometer Using Capacitive and Piezoelectric Sensing Techniques. ISCAS 1993: 1120-1123
1980 – 1989
- 1989
- [j1]Ramesh Harjani, Rob A. Rutenbar, L. Richard Carley:
OASYS: a framework for analog circuit synthesis. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 8(12): 1247-1266 (1989) - 1988
- [c3]Ramesh Harjani, Rob A. Rutenbar, L. Richard Carley:
Analog circuit synthesis for performance in OASYS. ICCAD 1988: 492-495 - [c2]Ramesh Harjani, Rob A. Rutenbar, L. Richard Carley:
Analog circuit synthesis and exploration in OASYS. ICCD 1988: 44-47 - 1987
- [c1]Ramesh Harjani, Rob A. Rutenbar, L. Richard Carley:
A Prototype Framework for Knowledge-Based Analog Circuit Synthesis. DAC 1987: 42-49
Coauthor Index
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