Freescale/FullChip | SuiteSparse Matrix Collection

circuit simulation, Kiran Gullapalli, Freescale Semiconductor, Inc.

Name	FullChip
Group	Freescale
Matrix ID	2380
Num Rows	2,987,012
Num Cols	2,987,012
Nonzeros	26,621,983
Pattern Entries	26,621,990
Kind	Circuit Simulation Problem
Symmetric	No
Date	2011
Author	K. Gullapalli
Editor	T. Davis

Dulmage-Mendelsohn Permutation of Freescale/FullChip

Connected Components of the Bipartite Graph of Freescale/FullChip

Graph Visualization of A+A' for Freescale/FullChip

Force-Directed Graph Visualization of Freescale/FullChip

Structural Rank	2,987,012
Structural Rank Full	true
Num Dmperm Blocks	35
Strongly Connect Components	35
Num Explicit Zeros	7
Pattern Symmetry	100%
Numeric Symmetry	0.6%
Cholesky Candidate	no
Positive Definite	no
Type	real

Download	MATLAB Rutherford Boeing Matrix Market
Notes	Full-chip circuit simulation matrix from Kiran Gullapalli, Freescale Semiconductor, Inc. This is a full-chip (everything that is actually built in silicon is in the netlist), for an automotive part. For simulation, the flash-memory and sram-memory cores are removed. But everything else is in the matrix. The chip takes an external battery (voltage source), but has internal voltage generators. the node of the external battery can be removed from the matrix. but the internal generators create some VERY HIGH degree nodes. So, there are about 6 nodes with degree greater than 1000 (actually, the degree is 2M+ for 2 of these). After ordering, nnz(L+U) = 200,180,468, with about 1.03793E+11 flops (a += b * c is counted as one flop).

Download

MATLAB Rutherford Boeing Matrix Market

Notes

Full-chip circuit simulation matrix from Kiran Gullapalli, Freescale  
Semiconductor, Inc.                                                   
                                                                      
This is a full-chip (everything that is actually built in silicon is  
in the netlist), for an automotive part.  For simulation, the         
flash-memory and sram-memory cores are removed. But everything else is
in the matrix.                                                        
                                                                      
The chip takes an external battery (voltage source), but has internal 
voltage generators. the node of the external battery can be removed   
from the matrix. but the internal generators create some VERY HIGH    
degree nodes. So, there are about 6 nodes with degree greater than    
1000 (actually, the degree is 2M+ for 2 of these).                    
                                                                      
After ordering, nnz(L+U) = 200,180,468, with about 1.03793E+11        
flops (a += b * c is counted as one flop).