A CMOS-MEMS clamped–clamped beam displacement amplifier for resonant switch applications

2018 ◽  
Vol 28 (6) ◽  
pp. 065001 ◽  
Author(s):  
Jia-Ren Liu ◽  
Shih-Chuan Lu ◽  
Chun-Pu Tsai ◽  
Wei-Chang Li
Keyword(s):  
Beam Displacement ◽  
Cmos Mems ◽  
Resonant Switch

Fabrication of Monolithic Integrated Bimaterial Resonant Uncooled IR Sensor

2013 ◽  
Vol 543 ◽  
pp. 176-179 ◽  
Author(s):  
D.Q. Zhao ◽  
Xia Zhang ◽  
P. Liu ◽  
F. Yang ◽  
C. Lin ◽  
...  
Keyword(s):  
Silicon Nitride ◽  
Hole Mobility ◽  
Micro Electro Mechanical System ◽  
Cmos Process ◽  
Standard Cmos Process ◽  
Ir Sensor ◽  
Cantilever Structure ◽  
Cmos Mems ◽  
On Chip ◽  
Micro Cantilever

In this work we studied the fabrication of a monolithic bimaterial micro-cantilever resonant IR sensor with on-chip drive circuits. The effects of high temperature process and stress induced performance degradation were investigated. The post-CMOS MEMS (micro electro mechanical system) fabrication process of this IR sensor is the focus of this paper, starting from theoretical analysis and simulation, and then moving to experimental verification. The capacitive cantilever structure was fabricated by surface micromachining method, and drive circuits were prepared by standard CMOS process. While the stress introduced by MEMS films, such as the tensile silicon nitride which works as a contact etch stopper layer for MOSFETs and releasing stop layer for the MEMS structure, increases the electron mobility of NMOS, PMOS hole mobility decreases. Moreover, the NMOS threshold voltage (Vth) shifts, and transconductance (Gm) degrades. An additional step of selective removing silicon nitride capping layer and polysilicon layer upon IC area were inserted into the standard CMOS process to lower the stress in MOSFET channel regions. Selective removing silicon nitride and polysilicon before annealing can void 77% Vth shift and 86% Gm loss.

A CMOS-MEMS Accelerometer with U-channel Suspended Gate SOI FET

2021 ◽  
pp. 1-1
Author(s):  
Pramod Martha ◽  
Naveen Kadayinti ◽  
V. Seena
Keyword(s):  
Mems Accelerometer ◽  
Cmos Mems

CMOS-MEMS Based Current Mirror MOSFET Embedded Pressure Sensor for Healthcare and Biomedical Applications

2013 ◽  
Vol 647 ◽  
pp. 315-320 ◽  
Author(s):  
Pradeep Kumar Rathore ◽  
Brishbhan Singh Panwar
Keyword(s):  
Pressure Sensor ◽  
Biomedical Applications ◽  
Circuit Simulation ◽  
Applied Pressure ◽  
Pressure Sensors ◽  
Cmos Technology ◽  
Current Mirror ◽  
Sensing Element ◽  
Pressure Sensing ◽  
Cmos Mems

This paper reports on the design and optimization of current mirror MOSFET embedded pressure sensor. A current mirror circuit with an output current of 1 mA integrated with a pressure sensing n-channel MOSFET has been designed using standard 5 µm CMOS technology. The channel region of the pressure sensing MOSFET forms the flexible diaphragm as well as the strain sensing element. The piezoresistive effect in MOSFET has been exploited for the calculation of strain induced carrier mobility variation. The output transistor of the current mirror forms the active pressure sensing MOSFET which produces a change in its drain current as a result of altered channel mobility under externally applied pressure. COMSOL Multiphysics is utilized for the simulation of pressure sensing structure and Tspice is employed to evaluate the characteristics of the current mirror pressure sensing circuit. Simulation results show that the pressure sensor has a sensitivity of 10.01 mV/MPa. The sensing structure has been optimized through simulation for enhancing the sensor sensitivity to 276.65 mV/MPa. These CMOS-MEMS based pressure sensors integrated with signal processing circuitry on the same chip can be used for healthcare and biomedical applications.

scholarly journals A Tunable-Gain Transimpedance Amplifier for CMOS-MEMS Resonators Characterization

Micromachines ◽  
2021 ◽  
Vol 12 (1) ◽  
pp. 82
Author(s):  
Rafel Perelló-Roig ◽  
Jaume Verd ◽  
Sebastià Bota ◽  
Jaume Segura
Keyword(s):  
Cmos Technology ◽  
Open Loop ◽  
Transimpedance Amplifier ◽  
Mems Devices ◽  
Monolithically Integrated ◽  
Mems Resonators ◽  
Electromechanical Performance ◽  
Cmos Mems ◽  
Promising Solution ◽  
On Chip

CMOS-MEMS resonators have become a promising solution thanks to their miniaturization and on-chip integration capabilities. However, using a CMOS technology to fabricate microelectromechanical system (MEMS) devices limits the electromechanical performance otherwise achieved by specific technologies, requiring a challenging readout circuitry. This paper presents a transimpedance amplifier (TIA) fabricated using a commercial 0.35-µm CMOS technology specifically oriented to drive and sense monolithically integrated CMOS-MEMS resonators up to 50 MHz with a tunable transimpedance gain ranging from 112 dB to 121 dB. The output voltage noise is as low as 225 nV/Hz1/2—input-referred current noise of 192 fA/Hz1/2—at 10 MHz, and the power consumption is kept below 1-mW. In addition, the TIA amplifier exhibits an open-loop gain independent of the parasitic input capacitance—mostly associated with the MEMS layout—representing an advantage in MEMS testing compared to other alternatives such as Pierce oscillator schemes. The work presented includes the characterization of three types of MEMS resonators that have been fabricated and experimentally characterized both in open-loop and self-sustained configurations using the integrated TIA amplifier. The experimental characterization includes an accurate extraction of the electromechanical parameters for the three fabricated structures that enables an accurate MEMS-CMOS circuitry co-design.

scholarly journals Manufacturing issues of BEOL CMOS-MEMS devices

IEEE Access ◽  
2021 ◽  
pp. 1-1
Author(s):  
Juan Valle ◽  
Daniel Fernandez ◽  
Olivier Gibrat ◽  
Jordi Madrenas
Keyword(s):  
Mems Devices ◽  
Cmos Mems

A compact CMOS MEMS microphone with 66dB SNR

2009 ◽  
Author(s):  
J. Citakovic ◽  
P.F. Hovesten ◽  
G. Rocca ◽  
A. van Halteren ◽  
P. Rombach ◽  
...  
Keyword(s):  
Mems Microphone ◽  
Cmos Mems

scholarly journals A Thermopile Device with Sub-Wavelength Hole Arrays by CMOS-MEMS Technology

Sensors ◽  
2020 ◽  
Vol 21 (1) ◽  
pp. 180
Author(s):  
Chi-Feng Chen ◽  
Chih-Hsiung Shen ◽  
Yun-Ying Yeh
Keyword(s):  
Fdtd Method ◽  
Elliptical Hole ◽  
Oxide Semiconductor ◽  
Active Area ◽  
Hole Array ◽  
Cmos Mems ◽  
Simulation Results ◽  
Hole Arrays ◽  
Hole Structure ◽  
Sub Wavelength

A thermopile device with sub-wavelength hole array (SHA) is numerically and experimentally investigated. The infrared absorbance (IRA) effect of SHAs in active area of the thermopile device is clearly analyzed by the finite-difference time-domain (FDTD) method. The prototypes are manufactured by the 0.35 μm 2P4M complementary metal-oxide-semiconductor micro-electro-mechanical-systems (CMOS-MEMS) process in Taiwan semiconductor manufacturing company (TSMC). The measurement results of those prototypes are similar to their simulation results. Based on the simulation technology, more sub-wavelength hole structural effects for IRA of such thermopile device are discussed. It is found from simulation results that the results of SHAs arranged in a hexagonal shape are significantly better than the results of SHAs arranged in a square and the infrared absorption efficiencies (IAEs) of specific asymmetric rectangle and elliptical hole structure arrays are higher than the relatively symmetric square and circular hole structure arrays. The overall best results are respectively up to 3.532 and 3.573 times higher than that without sub-wavelength structure at the target temperature of 60 °C when the minimum structure line width limit of the process is ignored. Obviously, the IRA can be enhanced when the SHAs are considered in active area of the thermopile device and the structural optimization of the SHAs is absolutely necessary.

An optimal design of thermal-actuated and piezoresistive-sensed CMOS-MEMS resonant sensor

2013 ◽  
Vol 23 (11) ◽  
pp. 115015 ◽  
Author(s):  
Chun-Chieh Wang ◽  
Chun-Yin Tsai ◽  
Tsung-Lin Chen ◽  
Sin-Hao Liao
Keyword(s):  
Optimal Design ◽  
Resonant Sensor ◽  
Cmos Mems
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