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Gabriel Chong

Orcid: 0000-0001-9985-2067

According to our database¹, Gabriel Chong authored at least 13 papers between 2019 and 2023.

Collaborative distances:

Dijkstra number² of five.
Erdős number³ of four.

Timeline

Legend:

Book

In proceedings

Article

PhD thesis

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Links

On csauthors.net:

Bibliography

2023

A Fully Integrated CMOS Tri-Band Ambient RF Energy Harvesting System for IoT Devices.

[BibT_eX]

[DOI]

,

,

Harikrishnan Ramiah

,

Kishore Kumar Pakkirisami Churchill

,

,

,

,

,

Rui Paulo Martins

IEEE Trans. Circuits Syst. I Regul. Pap., December, 2023

A Reconfigurable CMOS Stack Rectifier With 22.8-dB Dynamic Range Achieving 47.91% Peak PCE for IoT/WSN Application.

[BibT_eX]

[DOI]

Kishore Kumar Pakkirisami Churchill

,

Harikrishnan Ramiah

,

Alexander Choo Chia Chun

,

,

,

,

Rui Paulo Martins

IEEE Trans. Very Large Scale Integr. Syst., October, 2023

A Subthreshold Operation Series-Parallel Charge Pump Incorporating Dynamic Source-Fed Oscillator for Wide-Input-Voltage Energy Harvesting Application.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

Kishore Kumar Pakkirisami Churchill

,

,

,

,

,

,

Rui Paulo Martins

IEEE Access, 2023

A Fully-Integrated CMOS Dual-Band RF Energy Harvesting Front-End Employing Adaptive Frequency Selection.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

,

Kishore Kumar Pakkirisami Churchill

,

,

,

,

,

Rui Paulo Martins

IEEE Access, 2023

2022

A -20-dBm Sensitivity RF Energy-Harvesting Rectifier Front End Using a Transformer IMN.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

,

Kishore Kumar Pakkirisami Churchill

,

,

,

,

Rui Paulo Martins

IEEE Trans. Very Large Scale Integr. Syst., 2022

A 0.1-V V<sub>IN</sub> Subthreshold 3-Stage Dual-Branch Charge Pump With 43.4% Peak Power Conversion Efficiency Using Advanced Dynamic Gate-Bias.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

Kishore Kumar Pakkirisami Churchill

,

,

,

,

,

Rui Paulo Martins

IEEE Trans. Circuits Syst. II Express Briefs, 2022

A Fully-Integrated Ambient RF Energy Harvesting System with 423-μW Output Power.

[BibT_eX]

[DOI]

Kishore Kumar Pakkirisami Churchill

,

Harikrishnan Ramiah

,

,

,

,

Rui Paulo Martins

Sensors, 2022

2021

A Wide-PCE-Dynamic-Range CMOS Cross-Coupled Differential-Drive Rectifier for Ambient RF Energy Harvesting.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

,

Jagadheswaran Rajendran

,

,

Rui Paulo Martins

IEEE Trans. Circuits Syst. II Express Briefs, 2021

A 0.1V Input Energy Harvesting Charge Pump with Dynamic Gate Biasing and Capacitance Scaling.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

P. C. Kishore Kumar

,

Proceedings of the IEEE Asia Pacific Conference on Circuit and Systems, 2021

A Differential RF Front-end CMOS Transformer Matching for Ambient RF Energy Harvesting Systems.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

,

P. C. Kishore Kumar

Proceedings of the IEEE Asia Pacific Conference on Circuit and Systems, 2021

2020

Low-Voltage Capacitive-Based Step-Up DC-DC Converters for RF Energy Harvesting System: A Review.

[BibT_eX]

[DOI]

Kishore Kumar Pakkirisami Churchill

,

,

Harikrishnan Ramiah

,

Mohd Yazed Ahmad

,

Jagadheswaran Rajendran

IEEE Access, 2020

2019

CMOS Cross-Coupled Differential-Drive Rectifier in Subthreshold Operation for Ambient RF Energy Harvesting - Model and Analysis.

[BibT_eX]

[DOI]

,

Harikrishnan Ramiah

,

,

Jagadheswaran Rajendran

,

,

,

Rui Paulo Martins

IEEE Trans. Circuits Syst. II Express Briefs, 2019

Analysis of a Single-Frequency Multi-Channel Ambient RF Energy Harvesting in CMOS Technology.

[BibT_eX]

[DOI]

P. C. Kishore Kumar

,

Harikrishnan Ramiah

,

Mohd Yazed Ahmad

,

,

Jagadheswaran Rajendran

Proceedings of the 2019 IEEE Asia Pacific Conference on Circuits and Systems, 2019

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