TY - JOUR
T1 - Power Device Interface Characterization with Low-Cost Thermal System Identification
AU - Polom, Timothy A.
AU - Lorenz, Robert D.
PY - 2021
Y1 - 2021
N2 - This paper develops a technique, requiring no dedicated temperature sensing calibration step, to rapidly characterize transient heat transfer in packaged, power semiconductor components. It is presented as an alternative to traditional step response characterization methods by exploiting the phase delay metric native to frequency response function (FRF) analysis in the field of system identification. The paper presents principles of power device physics and transient waveform analysis to identify design space in which FRF data extracted from experiments are robust. Introduced are electronic circuitry, providing the needed, periodic heat actuation, and a measurement strategy leveraging direct processing of a temperature sensitive electrical parameter. The developed method is applied to make a key measurement confirming the high-frequency-only thermal FRF sensitivity to component die-attach condition. The measurement is shown to align with an output from a partial differential thermal model embedding a single, corrective scaling factor. Overall, the paper highlights the emergent opportunity to measure a packaged power device’s transient thermal impedance with standard lab equipment and the ongoing opportunity to realize converter degradation self-sensing.
AB - This paper develops a technique, requiring no dedicated temperature sensing calibration step, to rapidly characterize transient heat transfer in packaged, power semiconductor components. It is presented as an alternative to traditional step response characterization methods by exploiting the phase delay metric native to frequency response function (FRF) analysis in the field of system identification. The paper presents principles of power device physics and transient waveform analysis to identify design space in which FRF data extracted from experiments are robust. Introduced are electronic circuitry, providing the needed, periodic heat actuation, and a measurement strategy leveraging direct processing of a temperature sensitive electrical parameter. The developed method is applied to make a key measurement confirming the high-frequency-only thermal FRF sensitivity to component die-attach condition. The measurement is shown to align with an output from a partial differential thermal model embedding a single, corrective scaling factor. Overall, the paper highlights the emergent opportunity to measure a packaged power device’s transient thermal impedance with standard lab equipment and the ongoing opportunity to realize converter degradation self-sensing.
KW - characterization
KW - electrothermal
KW - frequency response
KW - heat transfer
KW - power semiconductor devices
KW - packaging
KW - thermal interface
KW - sensitivity analysis
KW - system identification
UR - https://ieeexplore.ieee.org/document/9467348/
U2 - 10.1109/JESTPE.2021.3093490
DO - 10.1109/JESTPE.2021.3093490
M3 - Article
SN - 2168-6785
VL - PP
SP - 1
EP - 1
JO - IEEE Journal of Emerging and Selected Topics in Power Electronics
JF - IEEE Journal of Emerging and Selected Topics in Power Electronics
IS - 99
M1 - 9467348
ER -