default search action
Gaurab Banerjee
Person information
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2024
- [c19]Easha, Gaurab Banerjee:
Advancing In-Home Gait Monitoring: A Feasibility Study of Upper Limb Swing Analysis Using FMCW Radar. ISCAS 2024: 1-5 - [c18]Soham Lakhote, Easha, Gaurab Banerjee:
A Dual-Slope BlueFMCW Radar for Simultaneous Mitigation Against Close-in DRFM and Frequency Domain Spoofing Attacks. ISCAS 2024: 1-5 - [c17]Sumit Kumar, Gaurab Banerjee:
An Improved Charge-Pump Design to Increase Tuning Range and Reduce Spurs in FMCW Radar Synthesizers. VLSID 2024: 96-100 - 2022
- [c16]Alex Tamkin, Gaurab Banerjee, Mohamed Owda, Vincent Liu, Shashank Rammoorthy, Noah D. Goodman:
DABS 2.0: Improved Datasets and Algorithms for Universal Self-Supervision. NeurIPS 2022 - [i2]Anand Kumar, Easha, Debdeep Sarkar, Gaurab Banerjee:
A Compact Quasi-Yagi Antenna for FMCW Radar-on-Chip based Through-Wall Imaging. CoRR abs/2208.11034 (2022) - 2020
- [j15]Immanuel Raja
, Gaurab Banerjee
A 0.75-2.5-GHz All-Digital RF Transmitter With Integrated Class-E Power Amplifier for Spectrum Sharing Applications in 5G Radios. IEEE Trans. Very Large Scale Integr. Syst. 28(10): 2109-2121 (2020) - [c15]Jackie (Junrui) Yang
Soundr: Head Position and Orientation Prediction Using a Microphone Array. CHI 2020: 1-12 - [i1]Gaurab Banerjee, Samuel Spinner, Yasmine Mitchell:
"You eat with your eyes first": Optimizing Yelp Image Advertising. CoRR abs/2011.01434 (2020)
2010 – 2019
- 2019
- [j14]Manas Kumar Lenka
A Wideband Blocker-Tolerant Receiver With Frequency-Translational Resistive Feedback. IEEE Trans. Very Large Scale Integr. Syst. 27(5): 993-1006 (2019) - [j13]Manas Kumar Lenka
Corrections Corrections to "A Wideband Blocker-Tolerant Receiver With Frequency-Translational Resistive Feedback". IEEE Trans. Very Large Scale Integr. Syst. 27(5): 1238 (2019) - [c14]Vipul Jain, Saurabh Kumar Gupta, Vishal Khatri, Gaurab Banerjee:
A 19.3-24.8 GHz Dual-Slope VCO in 65-nm CMOS for Automotive Radar Applications. VLSID 2019: 118-123 - [c13]Kundan Kumar
A 75-µW 2.4 GHz Wake-up Receiver in 65-nm CMOS for Neonatal Healthcare Application. VLSID 2019: 287-292 - 2017
- [j12]Immanuel Raja
A 0.1-2-GHz Quadrature Correction Loop for Digital Multiphase Clock Generation Circuits in 130-nm CMOS. IEEE Trans. Very Large Scale Integr. Syst. 25(3): 1044-1053 (2017) - [c12]Javed S. Gaggatur, Gaurab Banerjee:
A 13.5 bit 1.6 mW 3rd order CT ΣΔ ADC for integrated capacitance sensor interface. SoCC 2017: 40-44 - [c11]Javed S. Gaggatur, Immanuel Raja
On-Chip Non-intrusive Temperature Detection and Compensation of a Fully Integrated CMOS RF Power Amplifier. VLSID 2017: 21-26 - [c10]Javed S. Gaggatur, Gaurab Banerjee:
High Gain Capacitance Sensor Interface for the Monitoring of Cell Volume Growth. VLSID 2017: 201-206 - 2016
- [j11]Immanuel Raja
A 0.1-3.5-GHz Duty-Cycle Measurement and Correction Technique in 130-nm CMOS. IEEE Trans. Very Large Scale Integr. Syst. 24(5): 1975-1983 (2016) - [j10]Vishal Khatri, Gaurab Banerjee:
A 0.25-3.25-GHz Wideband CMOS-RF Spectrum Sensor for Narrowband Energy Detection. IEEE Trans. Very Large Scale Integr. Syst. 24(9): 2887-2898 (2016) - [c9]Zaira Zahir, Gaurab Banerjee:
A multi-tap inductor based 2.0-4.1 GHz wideband LC-oscillator. APCCAS 2016: 330-333 - [c8]Immanuel Raja
An inductor-less transmission line based 60 GHz PA in 65-nm CMOS with analog power control. ICECS 2016: 149-152 - [c7]Javed S. Gaggatur, Pradeep K. Dixena, Gaurab Banerjee:
A 3.2 mW 0.13 μm high sensitivity frequency-domain CMOS capacitance interface. ISCAS 2016: 1070-1073 - [c6]Javed S. Gaggatur, Gaurab Banerjee:
Noise analysis in ring oscillator-based capacitance sensor interface. MWSCAS 2016: 1-4 - [c5]Manas Kumar Lenka, Akash Agrawal, Vishal Khatri, Gaurab Banerjee:
A Wide-Band Receiver Front-End with Programmable Frequency Selective Input Matching. VLSID 2016: 168-173 - 2015
- [j9]Vishal Khatri, Gaurab Banerjee:
A Mitigation Technique for Harmonic Downconversion in Wideband Spectrum Sensors. IEEE Trans. Instrum. Meas. 64(12): 3226-3238 (2015) - 2013
- [j8]Mohamad A. Zeidan
Asynchronous Measurement of Transient Phase-Shift Resulting From RF Receiver State-Change. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(10): 2740-2751 (2013) - 2012
- [j7]Mohamad A. Zeidan
Phase-Aware Multitone Digital Signal Based Test for RF Receivers. IEEE Trans. Circuits Syst. I Regul. Pap. 59-I(9): 2097-2110 (2012) - [j6]Pramod Murali, Ranjit K., Navakanta Bhat, Gaurab Banerjee, Bharadwaj Amrutur, K. N. Bhat, Praveen C. Ramamurthy
A CMOS Gas Sensor Array Platform With Fourier Transform Based Impedance Spectroscopy. IEEE Trans. Circuits Syst. I Regul. Pap. 59-I(11): 2507-2517 (2012) - [c4]Pramod Murali, Navakanta Bhat, Gaurab Banerjee, Bharadwaj Amrutur, K. N. Bhat, Praveen C. Ramamurthy
CMOS Gas Sensor Array Platform with Fourier Transform Based Impedance Spectroscopy. VLSI Design 2012: 173-178 - 2011
- [j5]Gaurab Banerjee, Manas Behera, Mohamad A. Zeidan
Analog/RF Built-in-Self-Test Subsystem for a Mobile Broadcast Video Receiver in 65-nm CMOS. IEEE J. Solid State Circuits 46(9): 1998-2008 (2011)
2000 – 2009
- 2008
- [j4]Ganesh Balamurugan, Joseph T. Kennedy, Gaurab Banerjee, James E. Jaussi, Mozhgan Mansuri, Frank O'Mahony, Bryan Casper, Randy Mooney:
A Scalable 5-15 Gbps, 14-75 mW Low-Power I/O Transceiver in 65 nm CMOS. IEEE J. Solid State Circuits 43(4): 1010-1019 (2008) - [j3]Gaurab Banerjee, Krishnamurthy Soumyanath, David J. Allstot:
Desensitized CMOS Low-Noise Amplifiers. IEEE Trans. Circuits Syst. I Regul. Pap. 55-I(3): 752-765 (2008) - 2006
- [j2]Yorgos Palaskas, Ashoke Ravi, Stefano Pellerano, Brent R. Carlton, Mostafa A. Elmala, Ralph E. Bishop, Gaurab Banerjee, Rich B. Nicholls, Stanley K. Ling, Nati Dinur, Stewart S. Taylor, Krishnamurthy Soumyanath:
A 5-GHz 108-Mb/s 2 $\times$2 MIMO Transceiver RFIC With Fully Integrated 20.5-dBm ${\rm P}_{\rm 1dB}$ Power Amplifiers in 90-nm CMOS. IEEE J. Solid State Circuits 41(12): 2746-2756 (2006) - [c3]Yorgos Palaskas, Ashoke Ravi, Stefano Pellerano, Brent R. Carlton, Mostafa A. Elmala, Ralph E. Bishop, Gaurab Banerjee, Rich B. Nicholls, Stanley K. Ling, Stewart S. Taylor, Krishnamurthy Soumyanath:
A 5GHz 108Mb/s 2x2 MIMO Transceiver with Fully Integrated +16dBm PAs in 90nm CMOS. ISSCC 2006: 1420-1429 - 2004
- [c2]Gaurab Banerjee, David T. Becher, Celia Hung, David J. Allstot, Krishnamurthy Soumyanath:
Measurement and modeling of noise parameters for desensitized low noise amplifiers. CICC 2004: 387-390 - [c1]Gaurab Banerjee, David T. Becher, Celia Hung, Krishnamurthy Soumyanath, David J. Allstot:
Desensitized design of MOS low noise amplifiers by Rn minimization. ICECS 2004: 619-622
1990 – 1999
- 1997
- [j1]Gaurab Banerjee, Amiya Kumar Mallick:
A semi empirical model for low latitude HF ionospheric propagation prediction. IEEE Trans. Broadcast. 43(1): 89-95 (1997)
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from ,
, and
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and
to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from .
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-08-06 21:07 CEST by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by: