This paper describes the development and implementation of an analytical thermal model for fast and accurate thermal simulations of power device modules. A Fourier-based solution is used to solve the heat equation in two dimensions. The solution can describe the variation of temperature through the structure versus time. The thermal model is extremely fast to simulate compared to finite-element (FEM) approaches. The new model has been implemented in MATLAB/Simulink. The model has been validated against FEM simulations and the difference between the two models has been illustrated. The required aspects of heat diffusion are captured successfully by the Fourier-based model
An efficient thermal management in electronic components is essential to minimize the influence of t...
Abstract—Whereas numerical modeling using finite-element methods (FEM) can provide transient tempera...
This paper reports on the development of a hybrid approach to electro-thermal modeling of power devi...
This paper describes the development and implementation of an analytical thermal model for fast and ...
This paper describes the development and implementation of an analytical 3-D thermal model for fast ...
A new thermal model based on Fourier series expansion method has been presented for dynamic thermal ...
The power module is an important building block of a power electronic converter used in high power a...
International audienceThermal simulation is a frequently needed task in the design of integrated pow...
Thermal analysis is essential in 3D-IC technology due to the reduced footprint and higher power dens...
The thermal analysis and management is an important issue for power semiconductor devices especially...
The use of FEA (Finite Element Analysis) in power devices thermal study has become a well-establishe...
The steady-state thermal modelling of a rectangular N-layer structure with an arbitrary number of re...
In this paper, a new thermal model based on the Fourier series solution of heat conduction equation ...
The thermal behavior of power electronics devices has being a crucial design consideration because i...
© 2016 IEEE. A new thermal modeling concept for accurate and fast thermal analysis of GaN based powe...
An efficient thermal management in electronic components is essential to minimize the influence of t...
Abstract—Whereas numerical modeling using finite-element methods (FEM) can provide transient tempera...
This paper reports on the development of a hybrid approach to electro-thermal modeling of power devi...
This paper describes the development and implementation of an analytical thermal model for fast and ...
This paper describes the development and implementation of an analytical 3-D thermal model for fast ...
A new thermal model based on Fourier series expansion method has been presented for dynamic thermal ...
The power module is an important building block of a power electronic converter used in high power a...
International audienceThermal simulation is a frequently needed task in the design of integrated pow...
Thermal analysis is essential in 3D-IC technology due to the reduced footprint and higher power dens...
The thermal analysis and management is an important issue for power semiconductor devices especially...
The use of FEA (Finite Element Analysis) in power devices thermal study has become a well-establishe...
The steady-state thermal modelling of a rectangular N-layer structure with an arbitrary number of re...
In this paper, a new thermal model based on the Fourier series solution of heat conduction equation ...
The thermal behavior of power electronics devices has being a crucial design consideration because i...
© 2016 IEEE. A new thermal modeling concept for accurate and fast thermal analysis of GaN based powe...
An efficient thermal management in electronic components is essential to minimize the influence of t...
Abstract—Whereas numerical modeling using finite-element methods (FEM) can provide transient tempera...
This paper reports on the development of a hybrid approach to electro-thermal modeling of power devi...