Clark T.-C. Nguyen (Advisor)

Research Advised by Professor Clark T.-C. Nguyen

Nguyen Group:  List of Projects | List of Researchers

Precision Resonant Beam Strain Sensor Employing Gap-Dependent Frequency Shift

Alper Ozgurluk
Clark T.-C. Nguyen
2020

A micromechanical structure for on-chip strain sensing maps strain-induced gap changes to resonance frequency shifts while employing differential strategies to null out bias uncertainty, all towards repeatable measurement of sub-nm displacement changes that equate to sub- strain increments. The key enabler here is the use of gap-dependent electrical stiffness to shift resonance frequencies as structural elements stretch or shrink to relieve stress. An output based on the difference frequency between two close proximity structures with unequal stress arm lengths (cf. Fig. 1) removes...

Low-Power MEMS-Based Pierce Oscillator Using a 61-MHz Capacitive-Gap Disk Resonator

Thura Lin Naing
Tristan O. Rocheleau
Elad Alon
Clark T.-C. Nguyen
2020

A 61-MHz Pierce oscillator constructed in 0.35-µm CMOS technology and referenced to a polysilicon surface-micromachined capacitive-gap-transduced wineglass disk resonator has achieved phase noise marks of −119 dBc/Hz at 1-kHz offset and −139 dBc/Hz at far-fromcarrier offsets. When divided down to 13 MHz, this corresponds to −132 dBc/Hz at 1-kHz offset from the carrier and −152 dBc/Hz far-from-carrier, sufficient for mobile phone reference oscillator applications, using a single MEMS resonator, i.e., without the need to array multiple resonators. Key to achieving these marks is a Pierce-...

Single-Digit-Nanometer Capacitive-Gap Transduced Micromechanical Disk Resonators

Alper Ozgurluk
Kieran Peleaux
Clark T.-C. Nguyen
2020

Single-digit-nanometer electrode-to-resonator gaps have enabled 200-MHz radial-contour mode polysilicon disk resonators with motional resistance Rx as low as 144 while still posting Q’s exceeding 10,000, all with only 2.5V dc-bias. The demonstrated gap spacings down to 7.98nm are the smallest to date for upper-VHF micromechanical resonators and fully capitalize on the fourth power dependence of motional resistance on gap spacing. High device yield and ease of measurement debunk popular prognosticated pitfalls often associated with tiny gaps, e.g., tunneling, Casimir forces, low yield,...

Qianyi Xie

Alumni
Applied Science and Technology
Professor Clark T.-C. Nguyen (Advisor)
Ph.D. 2022

Qianyi Xie is a Ph.D. candidate in Prof. Clark Nguyen's group. He received his B.E. degree in Microelectronics from Tsinghua University in 2016.

Suppression of Oscillator Bias Voltage Phase Noise via MEMS Resonator Arraying

Jeffrey Ni
Clark T.-C. Nguyen
2022

Microelectromechanical system (MEMS)-based oscillators are in the heart of many of our electronic devices today, forming the timing basis for our increasingly higher frequency circuits. High-performance, low-noise oscillators are critical to meeting the standards of today's communication protocols. Effects of noise from all inputs of a circuit to the final output spectrum should be understood to make better oscillators, and this report specifically considers the effects of noise on the bias voltage supply needed for strong electromechanical coupling to sustain resonance. We investigate how...

Jeffrey Ni

Alumni
Electrical Engineering and Computer Sciences
Professor Clark T.-C. Nguyen (Advisor)
M.S. 2022

Untethered Insect-Scale Flying Robots

Fanping Sui
2022
Fall 2022 BSAC Research Review Presentation View Slides View Presentation at 31:22

Bit Rate-Adapting Resoswitch

Qiutong Jin
2022
Fall 2022 BSAC Research Review Presentation View Slides View Presentation at 45:41

Sherwin A. Afshar

Undergraduate Student Researcher
Electrical Engineering and Computer Sciences
Professor Clark T.-C. Nguyen (Advisor)
B.S. 2022

BPN939: Analysis and Benchmarking of MEMS-Based Super-Regenerative Receivers

Kevin H. Zheng
2022

The recent MEMS-based super-regenerative receiver our group demonstrated used a tunable 65-nm-capacitive-gap transduced wine-glass disk resonator to receive and demodulate OOK signals with only 490uW of power consumption. This work aims to analyze the sensitivity and maximum bit rate for this class of receiver in the presence of adjacent-channel blockers and measure these characteristics for receivers implemented using resonators with sub-40-nm gaps.

Project suspended for Fall 2022