Jin Jin

Orcid: 0000-0002-4102-6077

Affiliations:
  • Nanjing University of Science and Technology (NJUST), Ministry of Education Key Laboratory of Near-Range RF Sensing ICs and Microsystems, China
  • National ASIC System Engineering Research Center, Southeast University, Nanjing, China (PhD 2022)
  • University of Pavia, MicroLab, Italy (2019-2021)


According to our database1, Jin Jin authored at least 10 papers between 2020 and 2026.

Collaborative distances:
  • Dijkstra number2 of five.
  • Erdős number3 of five.

Timeline

Legend:

Book  In proceedings  Article  PhD thesis  Dataset  Other 

Links

Online presence:

On csauthors.net:

Bibliography

2026
A +43.3-dBm IIP<sub>3</sub>, Low-Power Transimpedance Amplifier Employing a Switched-Capacitor Amplifier-Based Transition-Band Pole-Zero Doublets Compensation Technique.
IEEE J. Solid State Circuits, June, 2026

An Ultra-Low-Power Capacitive Stacking Receiver Front-End with a PVT-Robust Switched-Capacitor-Based Feed-Forward IM3 Cancellation Technique.
Proceedings of the IEEE Custom Integrated Circuits Conference, 2026

A 14.0-to-17.3GHz Inter-Core 1<sup>st</sup>&2<sup>nd</sup> Harmonics Co-Circulation Quad-Core Inverse Class-F Oscillator Achieving 199.1dBc/Hz Peak FoM in 65nm CMOS.
Proceedings of the IEEE Custom Integrated Circuits Conference, 2026

2025
A Trifilar Transformer-Based Class-F<sub>23</sub> VCO With Noise-Circulating Technology.
IEEE Trans. Very Large Scale Integr. Syst., August, 2025

34.5 An 18.5-to-23.6GHz Quad-Core Class-F23 Oscillator Without 2nd/3rd Harmonic Tuning Achieving 193dBc/Hz Peak FoM and 140-to-250kHz 1/f<sup>3</sup>PN Corner in 65nm CMOS.
Proceedings of the IEEE International Solid-State Circuits Conference, 2025

2023
A 5.2GHz Trifilar Transformer-Based Class-F23 Noise Circulating VCO with FoM of 192.6 dBc/Hz.
Proceedings of the IEEE Asian Solid-State Circuits Conference, 2023

2022
A 400-μW IoT Low-IF Voltage-Mode Receiver Front-End With Charge-Sharing Complex Filter.
IEEE J. Solid State Circuits, 2022

An FDD Auxiliary Receiver with a Highly Linear Low Noise Amplifier.
Proceedings of the 48th IEEE European Solid State Circuits Conference, 2022

2021
A 400-µW Low-IF IoT Receiver Front-End with Tunable Charge-Sharing Complex Filter.
Proceedings of the 47th ESSCIRC 2021, 2021

2020
A Low Phase Noise Open Loop Fractional-N Frequency Synthesizer With Injection Locking Digital Phase Modulator.
IEEE Trans. Circuits Syst. II Express Briefs, 2020


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