Simply transporting design codes from sequential-scalar computers to parallel-vector computers does not fully utilize the computational benefits offered by high performance computers. By performing integrated controls and structures design on an experimental truss platform with both sequential-scalar and parallel-vector design codes, conclusive results are presented to substantiate this claim. The efficiency of a Cholesky factorization scheme in conjunction with a variable-band row data structure is presented. In addition, the Lanczos eigensolution algorithm has been incorporated in the design code for both parallel and vector computations. Comparisons of computational efficiency between the initial design code and the parallel-vector design code are presented. It is shown that the Lanczos algorithm with the Cholesky factorization scheme is far superior to the sub-space iteration method of eigensolution when substantial numbers of eigenvectors are required for control design and/or performance optimization. Integrated design results show the need for continued efficiency studies in the area of element computations and matrix assembly.
[1]
W. Keith Belvin,et al.
Langley's CSI evolutionary model: Phase 2
,
1991
.
[2]
H. Saunders,et al.
Finite element procedures in engineering analysis
,
1982
.
[3]
J. Pasciak,et al.
Computer solution of large sparse positive definite systems
,
1982
.
[4]
K. C. Park,et al.
Structural tailoring and feedback control synthesis - An interdisciplinary approach
,
1990
.
[5]
Suresh M. Joshi,et al.
Integrated design of the CSI evolutionary structure: A verification of the design methodology
,
1993
.
[6]
Duc T. Nguyen,et al.
A Parallel-Vector Algorithm for Rapid Structural Analysis on High-Performance Computers
,
1990
.