Title :
Compact Dynamic Modeling for Fast Simulation of Nonlinear Heat Conduction in Ultra-Thin Chip Stacking Technology
Author :
Codecasa, L. ; d´Alessandro, Vincenzo ; Magnani, A. ; Rinaldi, Niccolo
Author_Institution :
Dipt. di Elettron., Inf. e Bioingegneria, Inf. e Bioingegneria, Milan, Italy
Abstract :
A novel nonlinear model order reduction method is proposed for constructing one-port dynamic compact models of nonlinear heat diffusion problems for ultra-thin chip stacking technology. The method leads to models of small state-space dimensions, which allow accurately reconstructing the whole time evolution of the temperature field due to an arbitrary power waveform of practical interest. The approach is also efficient, since the computational time/memory requirements for constructing each dynamic compact model is about one order of magnitude lower than that corresponding to a single 3-D finite element method transient simulation of a nonlinear problem.
Keywords :
finite element analysis; heat conduction; integrated circuit modelling; integrated circuit packaging; reduced order systems; thermal diffusion; thermal management (packaging); three-dimensional integrated circuits; 3D finite element method transient simulation; arbitrary power waveform; compact dynamic modeling; fast simulation; nonlinear heat conduction; nonlinear heat diffusion problems; nonlinear model order reduction method; nonlinear problem; one-port dynamic compact models; state-space dimensions; temperature field; ultra-thin chip stacking technology; whole time evolution; Approximation methods; Equations; Heating; Materials; Mathematical model; Thermal conductivity; Vectors; Dynamic compact thermal model (DCTM); nonlinear model order reduction (MOR); self-heating; thermal impedance; ultra-thin chip stacking (UTCS); ultra-thin chip stacking (UTCS).;
Journal_Title :
Components, Packaging and Manufacturing Technology, IEEE Transactions on
DOI :
10.1109/TCPMT.2014.2352933
