Paper Info
Title
A logarithmic full-chip thermal analysis algorithm based on multi-layer Green's function
Abstract
This paper derives the multi-layer heat conduction Green's function, by integrating the eigen-expansion technique and the classic transmission line theories, and presents a logarithmic full-chip thermal analysis algorithm, which is verified by comparisons with a computational fluid dynamics tool (FLUENT). The paper considers Dirichlet's and general heat convection boundary conditions at chip surfaces. Experimental results show that the algorithm offers superior computing speed, compared to FLUENT and traditional Green's function based methods. The paper also studies the limitations of the traditional single-layer thermal model.
Year
DOI
Venue
2006
10.1109/DATE.2006.243966
design, automation, and test in europe
Keywords
Field
DocType
classic transmission line theory,general heat convection boundary,traditional single-layer thermal model,chip surface,multi-layer Green,computational fluid dynamics tool,traditional Green,eigen-expansion technique,multi-layer heat conduction,experimental result,logarithmic full-chip thermal analysis
Boundary value problem,Green's function,Computer science,Algorithm,Dirichlet boundary condition,Chip,Logarithm,Thermal conduction,Computational fluid dynamics,Fluent
Conference
ISSN
ISBN
Citations 
1530-1591
3-9810801-0-6
2
PageRank 
References 
Authors
0.36
14
2
Name
Order
Citations
PageRank
Baohua Wang19813.54
Pinaki Mazumder246672.03