TY - JOUR
T1 - A Novel Transient PDE Model for Development of Highly Sensitive Microthermal Expansion-Based Angular Motion Sensor
AU - Luo, Huahuang
AU - Cabot, Jose
AU - Wang, Xiaoyi
AU - Duan, Mingzheng
AU - Xu, Wei
AU - Ke, Qingqing
AU - Lee, Yi Kuen
N1 - Publisher Copyright:
© 2001-2012 IEEE.
PY - 2024/3/15
Y1 - 2024/3/15
N2 - We propose a novel transient partial differential equation (PDE) model for the development of highly sensitive microthermal expansion-based angular motion (μ TEAM) sensors based on the study of time-dependent response. With the efficient prediction of thermal time constant (τ∗) based on the PDE model, which is >2200 times faster than 3-D CFD simulation (32.67 s versus >20 h) and was validated by the experimental results, the parametric analysis has been conducted for design optimization. The μ TEAM sensors with three pairs of temperature detectors (TDs) were adopted for the systematic study of the PWM frequency (fPWM) effect on the sensor performance to identify the optimal fPWM (fo), which can optimize the sensitivity by >11%. Based on the time-dependent analysis of our PDE model, fo was verified to be dominated by the thermal response of the sensor. A generalized 'Phase Diagram' regarding the normalized sensitivity (S∗) was presented, for the first time, as a function of fPWM and the normalized heater-to-detector distance (Dx/Lx). Accordingly, an optimal region, where S∗≥0.95, was identified to successfully develop an SF 6-based μ TEAM sensor with a high sensitivity of 1.5631 mV/°/s, which was >3.5 times as large as that of the N2-based sensor (0.4203 mV/°/s). In particular, the SF6-based sensor reveals an excellent normalized sensitivity of 0.0487 mV/°/s/mW compared to the reported thermal angular motion sensors (AMSs); thus, the comprehensive study based on the PDE model enables the significant improvement of sensor sensitivity and would be useful for system-level integration in the future.
AB - We propose a novel transient partial differential equation (PDE) model for the development of highly sensitive microthermal expansion-based angular motion (μ TEAM) sensors based on the study of time-dependent response. With the efficient prediction of thermal time constant (τ∗) based on the PDE model, which is >2200 times faster than 3-D CFD simulation (32.67 s versus >20 h) and was validated by the experimental results, the parametric analysis has been conducted for design optimization. The μ TEAM sensors with three pairs of temperature detectors (TDs) were adopted for the systematic study of the PWM frequency (fPWM) effect on the sensor performance to identify the optimal fPWM (fo), which can optimize the sensitivity by >11%. Based on the time-dependent analysis of our PDE model, fo was verified to be dominated by the thermal response of the sensor. A generalized 'Phase Diagram' regarding the normalized sensitivity (S∗) was presented, for the first time, as a function of fPWM and the normalized heater-to-detector distance (Dx/Lx). Accordingly, an optimal region, where S∗≥0.95, was identified to successfully develop an SF 6-based μ TEAM sensor with a high sensitivity of 1.5631 mV/°/s, which was >3.5 times as large as that of the N2-based sensor (0.4203 mV/°/s). In particular, the SF6-based sensor reveals an excellent normalized sensitivity of 0.0487 mV/°/s/mW compared to the reported thermal angular motion sensors (AMSs); thus, the comprehensive study based on the PDE model enables the significant improvement of sensor sensitivity and would be useful for system-level integration in the future.
KW - Partial differential equation (PDE) model
KW - pulsewidth modulation (PWM) frequency effect
KW - thermal time constant
KW - time-dependent analysis
UR - http://www.scopus.com/inward/record.url?scp=85184017401&partnerID=8YFLogxK
U2 - 10.1109/JSEN.2024.3356182
DO - 10.1109/JSEN.2024.3356182
M3 - Article
AN - SCOPUS:85184017401
SN - 1530-437X
VL - 24
SP - 8045
EP - 8053
JO - IEEE Sensors Journal
JF - IEEE Sensors Journal
IS - 6
ER -