The analysis and design of complex aerospace structures requires the rapid solution of large systems of linear and nonlinear equations, eigenvalue extraction for buckling, vibration and flutter modes, structural optimization and design sensitivity calculation. Computers with multiple processors and vector capabilities can offer substantial computational advantages over traditional scalar computer for these analyses. These computers fall into two categories: shared memory computers and distributed memory computers. This presentation covers general-purpose, highly efficient algorithms for generation/assembly or element matrices, solution of systems of linear and nonlinear equations, eigenvalue and design sensitivity analysis and optimization. All algorithms are coded in FORTRAN for shared memory computers and many are adapted to distributed memory computers. The capability and numerical performance of these algorithms will be addressed

Storaasli, Olaf O.

English

NASA Technical Reports Server

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N95- 16458
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Rapid Solution of Large-scale Systems Of Equations
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by Olaf O. Storaasli, (O.O.Storaasli@larc.nasa.gov or 804-864-2927)
for Workshop on the Role of Computers in Langley R&D (6-15-94)
The analysis and design of complex aerospace structures requires the rapid
solution of large systems of linear and nonlinear equations, eigenvalue extraction
for buckling, vibration and flutter modes, structural optimization and design
sensitivity calculation. Computers with multiple processors and vector capabilities
can offer substantial computational advantages over traditional scalar computers
for these analyses. These computers fall into two categories: shared-memory
computers (e.g., Cray C-90) and distributed-memory computers (e.g., lntel
Paragon, IBM SP-2).
Shared-memory computers have only a few processors (16on aCray C-90),
which rapidly process vector instructions (simultaneous adds and multiPlies)and
address a large memory. Information is shared among processors by referencing
a common variable in shared-memory.
Distributed-memory computers may have thousands of processors, each with
limited memory. Explicit message passing commands (i.e. send, receive), are
used to communicate information between processors. Such communication is
time consuming, so algorithms need to be designed to run efficiently on
distributed-memory computers.
This presentation will cover general-purpose, highly-efficient algorithms for:
generation/assembly of element matrices, solution of systems of linear and
nonlinear equations, eigenvalue and design sensitivity analysis and optimization.
All algorithms are coded in FORTRAN for shared-memory computers, and many
adapted to distributed-memory computers. The capability and numerical
performance of these algorithms will be addressed.
O. Storaasli, D. Nguyen, M. Baddourah and ]. Qjn (1993), "Computational
Mechanics Analysis Tools for Parallel-Vector Supercomputers", AIAA/ASME/
ASCE/AHS/ASC 34th Structures, Structural Dynamics and Materials Conference
Proceedings, Part 2, pp. 772-778 (Int. J. of Computing Systems in Engineering,
Vol 4, No. 2-4, 1993)
130
https://ntrs.nasa.gov/search.jsp?R=19950010043 2020-06-16T08:51:23+00:00Z
Dr. Olaf Oliver Storaasli is a senior research scientist in computational mechanics
at the NASA Langley Research Center, Hampton, Virginia. He began his career
at Langley after receiving a Ph.D. degree in Engineering Mechanics from North
Carolina State University in 1970.
Long before parallel computers were commercially available, Dr. Storaasli led a
hardware, software and applications team at NASA Lang ey Research Center to
develop one of the first parallel computersl the Finite Element Machine. He has
authored over 80 works in computational structural mechanics including static
and dynamic structural analysis, eigenvalue and optimization methods,
interdisciplinary analysis, data management, and parallel-vector structural
analysis methods on supercomputers. He received the Floyd L." Thompson
Fellowship of NASA Langley Research Center for post-doctoral research at
Norges Tekniske Hogskole in Trondheim, Norway, and Det Norske Veritas, Oslo,
Norway, during 1984-85 and has been invited back twice since He received 5
NASA-wide and 8 Langley Achievement awards for outstanding work in
Computational Structural Mechanics. These awards included significant
contributions to the NASA Viking and Integrated Programs for Aerospace-Vehicle
Design (IPAD) Projects as well as to the development of Relational Information
Management (RIM), since developed into the commercial relational data-base
software: R:BASE. In August, 1989, Cray Research selected the general-purpose
matrix equation solution software, pvsolve, developed by Dr. Storaasli and his
colleagues, to receive the GigaFLOP Performance Award. pvsolve was used to
solve the 54,870 equations (9.2 billion floating point operations) in the Space
Shuttle Solid Rocket Booster structural analysis in six seconds elapsed time. His
recent research has resulted in methods to analyze a 172,400 equation (5,737
bandwidth) refined model of a high speed civil transport and a 265,000 equation
automobile (3,374 bandwidth) application in less than two minutes on the Cray C-
90 and a method to generate and assemble stuctural stiffness matrices on the
Intel Delta at speeds 25 times that of one Cray C-90 processor.
131
J Rapid Solution of . |
Dr. Olaf Storaasli
Computational Structures Branch
Mail Stop 240
NASA Langley Research Center
Hampton, VA 23681
Email: O.O.Storaasli@larc.nasa.gov
Phone: 804-864-2927
[_ FAX: 804-864-8912 [PM_presented at
Workshop on
The Role of Computers in Langley R&D
(_ June 15, 1994, Reid Conference Center• NASA Langley Research Center Langley
Research
Center
ol-1
• Faster, cheaper, better analysis/design
of large-scale structures
- Develop algorithms to exploit high-
performance computers
- Evaluate computational performance
.@ Langley
Research
Center
o=. 2
132
lOutlinel
@
• Supercomputers & Structural Models
• Structural Analysis
- Nodal Generation and Assembly
- Linear Equation Solvers
[__ Shared=memory computers
Distributed-memory computers
- Nonlinear Equation Solvers
* Structural Optimization
• Design Sensitivity
Langley
Research
Center
o=.3
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201
Speedup
Y-MP8
16x20=320
Sequ_ential
Code
10
Paraller Speedup
15
Vector
Speedup
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Research
Center
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Generate mesh
(nodes and elements)
Assemble stiffness [K],
mass [M]i and load {p}
Solve: [K] {u} = {p} fordisplacement,u
[K] {¢} = _. [M] {¢} for modes, q)
| Earth Observation
Platform
Repeat: multiple analyses for nonlinear & design
Plot: u, stresses and vibration modes, (p
Performance Assessment Applications
Langley
Research
Cen_;
1,647 Elements
108 Bandwidth _ -_a
_ed Civil Transport|
770 Bandwidth
@
...h_.0Highs=._
___I__B _ __
I 2,556 Bandwidth
Langley
Research
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135
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Matrix Storage Methods
2910 :Equation Stiffened Panel
i:
VariableAiAA.1SAXPy.ROw.990BandI
Skyline
-Column-
Dot Product
AIAA-1989
Li,._loy
Research
Center
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Algorithms[ Parallel-Vector Structures,
Static
Ku=f
Substructuring
NL Algorithms
Eigenvalue
KCp= _.Mcp
Subspace
Lanczos
Dynamics-Control
Mu + Cu + Ku = f(t)
Time Integration
Reduced.Order
Simulate Multibody
Flutter
K¢= ZM@
Unsymmetr|c
Choleski and
Lanczos
Optimization
bk+l= bk+ S kdk
Search methods
Sensitivity
Matrix Assemblers
- Finite Element based
- Degree-of-Freedom based
Equation Solvers
- Direct - Sparse
- Iterative - SVD
Langley
Research,,
Center
ol._o
136
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[] Generate [] Constraints:m: Output K,M[
I[] Factor [] deflection
Langley• Research
Cent2,r,
i
Parallel Matrix Generation and Assembly
I I I I I
I By element: Traditional thinking |
Generate [k(e)] on different processors | _b,=3
Assemble global [K] = ,T_,[k (e)] _ _l_
°ar,',,,r,,e, J o\
]BY n°de: New meth°d i .,-2 _1_-] 1
Nodal Connectivity
Node Proc. Elements
2 2
3 3
Langley• Research
Centoe.r
137
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Parallel Structural Matrix Generator/|
Assembler Demonstrated on HSCT |
II
• Nearly ideal parallel speedup
• (no interprocessor communication)
Time 3o, _'_=_
20' 770 Bandwidth V
0
1 8 16 32 64 128 256 512
Cray C-90 |ntel Delta Langley
Number of Processors Resaarch
Center
ot.l_
Equation Solution Issues
(Time, memory, disk space, I/0) ! _
[
• lterative or direct ?
• Banded or sparse ?
• "In-core" or "out-of-core"?
Communication
• Broadcast or ring?
• OSF or SUNMOS?
Langley
Research
Center
138
• Iterative and Direct (function of application)
• Linpack (MP Linpack), LApack
(needs full matrix for best performance)
• Banded Indefinite, nonsymmetric
(requires pivoting)
• Banded Definite Symmetric
(seldom occurs in practical structures)
• Skyline*, Variable-band*
(DOT- product, SAXPY operations minimize time)
• Sparse*, Wavefront* (<5% nonzeros)
(_ * node or equation Langleyreordering minimizes solution time
• Research
Center
ol._$
i Direct Equation Solvers |
_ar-Valued Dec_
_nonsingular_ ,_
_ LanRgJ:Yarch
Center
o=-111
139
• '•i i _¸,
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t iterative Vs Direct Solvers I
• lterative slow, convergence not. guaranteed
• Direct complex coding (banded, sparse)
1600
1200,
Time
(sec) 800.
400.
0
m _2.4 HSCT
_-_---Iterative (PCG)
4 8 16 32
Number of Intel Gamma Processors
,_ Langley
• Research
Center
eat7
_V-MP l;i ]17 • I! Out-of-core Direct.Solver|
- using Cray Solid State Disk
l r ' "
C-90
I .... I H ]1
• as fast as "in-core" solver
15.6
15FE:::! • memory used'l.lxbandwidth 2
Time t_ (or 24 x bandwidth + 6 x neq)
(sec) I_ "_ ___l_ , Mach 2,4 HSCT I
16,152 Equations I
7.8. 3.5 billion operations I
__ e"=_ .s _
i_ 3 _ out-of-core"
1 2 4 8 16• Number of Cray Processo rs (Y-MP, C-90) LangleyResearch
Center
o=-18
140
/i '
I Automotive Application |
i of Sparse Solver .....|
48,894 Elements
44,188 Nodes
263,574 Equations
• Langley solution took 40 CPU sec (1 Cray C-90 processor)
- fastest solution known to date -
• Challenge: achieve even faster solution on SP-2 and Paragon/
Langloy• Resoarch
Center
Convex
,oo0oo   
10000- B
I O0 3
SS
(sec)
heratlve Pvsolve Vect S )arse Pvsolve-ooc Sparse-Cray Veer-Sparse
.... Convex ........ ,Cray C-90. .... co, t%
,:./i ¸¸
141
/y :
i _i_i"_:
Solvers for [A]{x}={b} and[A]{x}=h[M]{x}
I I I I
APPlication _ parallelfshared)
. . .
equatlo_ts X Bandwidth Ye= (Crey C-90, et¢)
Solver Parallel(Distributed)
PVSOLVE Symmetric + Def" Yes (Intel Paragon, IBM SP-1]
PVSOLVE-OOC 1.1 x Bandwfdth z Yes (Cray C-90, etc) Not yet
PVSOLVE-OOC+ 24 x Bandwidth No (Cmy C.90, etc) Not yet
VSS (Vector Sparse) function of tpartlty NO (Cray C-nO, etc) Not yet
PCG(Itemtlve) : " - matrix nonzero= Yes (Cray C-90, etc) Yes (]ntel Paragon, IBM SP.I|
LANZ(Elgen$olver) equations X bandwidth Yes (Cray C-90, etc) Yes (Intel Paragon)
NOTE: These solvers have been evaluated on real applications with up to 263.574 eouations
and larger matrices with several million eauations. PCG is slowest, VSS Is fastest
(for large, sparse problems) and PVSOLVE-OOC is the best all-around parallel-
vector solver. PVSOLVE-OOC exploits Cray solid-state disk.
(_ * ,pedal versions of PVSOLVE for unzymmetrlc and negative coefficient maVlce= Langley• so_ve panel flutter, CFD, nonlinear and optimization problems Research
Center,
' ara''e'vec'°rEqua'i¸°°l,,.sloL.E,s°'verl 
[ Shared Memory I Cray GigaFLOP'award I
• "in-core skyline and variable-band versions
• "out-of-core" versions: memory ~ t.2 bandwidth=
and 24 x bandwidth
• tuned for Crays (orsharedmemorycomputer/workstation)
I Distributed Memory I
• "in-core" skyline - Intel i/860or Paragon
• "in-core" row version - Intel 860 or Paragon, IBM SP-1
_ Conversion underway to TMC CM-5, Convex SSP-1 and Cray T-3D
. COMET, Ford, U. Virginia, IBM, Princeton, LLNL, NSF sites Langley" onvex COMCO, NASA Lewis + sev ral dozen sites R_s arch
Cent,v,
: ::. 142
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i ¸ •! :•f •
30-
I
Time 25.
(sec)
20
15
10
5
0
• Newton-Raphson fastest on parallel'vector computers
Ri!iiN_':;:=°__::..w,ooo._.oo
. p (3O_M)
m_iilfNi|
1 2 4 8 LanQley
Number of Cray Y-MP Processors Resea,_h
Cente=_
Find aircraft minimum weight subject to
displacement and stress constraints
Nonlinear constrained optimization finds:
• Direction: BFGS, Simplex-Linear
Programming
° Step size: Golden Block
Ibk_'=bk+Skdk___
Langley- Research
Center
143
Time
(sec)
Parallel Simplex Method ILinear Programming
I
• Scalable time reduction
124
3,000 design variables
500 constraints
32
a'a 9.7
1 2 4 8 16
Number of Cray C-90 Processors Langley
• Research
Cente_
125-
100
75
50
25
Minimize F(xl, x 2..... x.) is equivalent to
For 11,000 nonlinear equations:
3
Time 2.6
(sec)
1.37
//
1 2
F l(x_, x2..... x.) = 0 _lt
F2(x I, x=..... x.) = 0
Fn(xl, x z..... Xn) = 0
or
Min (F12 + F22 + ... FnZ)
0.762
g 0.45 0.29
4 8 16
Number of Cray C-90 Processors Langley
Research
Center
144
iZ/i ii' ¸ii_i
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Time 14
(sec) 12
10
8
6
4
2
°
I; ....... F_ r SensitiVity Analysis|_
jtomatic::Differentiation (ADIFOR) |:
I III I '1
2'D Truss (80 bays x t90 :stories)
60,990 truss elements
16.27 30,780 equations .........
_i_i_i_ii_i_iiiiiiiiiiii_!ii 5!2 _ii[ion matrix terms
iil;iiiii;iiii_i;i;iii!iii!i;iiiii!iiii;iil;I 168 semi-bandwidth
96 Design Variabies (X-Sect areas)iii iii ii iiiii ii"i"i"iiii!i!i"iiiiiiiiiii_"_""iiii!ii!!ii"ii'i'ili!ii"
Displacement Sensitivity (Gradients)
=/Generate RHS
_=r / Factor .....
__ Generate/ASsemble
iliill_;ii_li_iiii_iiiii_, _ , !:!:!:!'!:!i:i:!:!_!!:!:ii:i:'!i!:!:!_!:i:_'i:i:i:_:!:itLangley
1 8 16 Research
Number of Cray C-90 Processors Center
_i Ill I
Design Sensitivity Analysis Methods
for Mach 2.4_HSCT
7,868 Triangular Elements
! Design Variable (skin thiCkness)
l r_Hand coded [] ADIFOR _ Finite Oifference_
Time
(sec.)
140
120
100
80
6O
I20
0
16 64 64 128
Number of Intel Delta Processors
145
Langley
Research
Center
i i __
i i _ • : .
i, _
New algorithms for high-performance computers
Perform well on large-scale applications:
- Nodal Matrix Generation and Assembly
- E .q.uation Solvers: [K]{u} = {p} ,,
(l,near, nonlinear, "out-of core ,sparse)
• Structural Optimization
- Design Sensitivity
• Operate on Cray, Paragon, IBM SP-1 and SP.2!
@ LangleyResearch
Center
• Storaasli, O., Nguyen, D., Baddourah, M. and Qin, J.;
Computational Mechanics Analysis Tools for Parallel-
Vector Supercomputers",AIAA/ASME/ASCE/AHS/ASC
34th Structures, Structural Dynamics and Materials
Conference Proceedings, Part 2, pp. 772-778, April 1993.
• also International Journal of Computing Systems in
Engineering, Vol. 4, No. 2-4, 1993 pp. 349-354
• on MOSAIC-WWW (Langley Technical Report Server)
• Questions: O.O.Storaasli@larc.nasa.gov
• Free Videotape from: shuguez@nas.nasa.gov
(Santa Huguez at 415-604-4632)
@ LangleyResearch
Center
o=._o
146


Rapid solution of large-scale systems of equations

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