Fief,re. 7 ,,hov, s variatums in number of epochs and
1 Payload.
Apay
(lbs)(All
NEURAL
variables
are normalized
NETWORK
AND
ROCKET Rajkumar
RESPONSE
ENGINE
Vaidyanathan
_:',
Nilav
respective
COMPONENT
tIaftka
baseline
SURFACE
}'apila '_''. Wet
Raphael 'l>Department
bv their
values).
METHODOLOGY
OPTIMIZATION
Shyy :__i: p. Kevin
_'= and Norman
Tucker
Fitz-Cof
Mar,shall
Space
Flight
Center,
ABSTRACT
of
-oal
response
of this ,.,,ork
surface
neural
networks
Huntsville,
1.1
cn,:ine_
components..\
rest
points,
'.hree clement.
from
76
employed
to select
response
hack-pr(_pagation layered ilig(qlIhnls,
is
Various
issues
_ie
addressed,
_p|lmlZall_H1 !+1c
alH{}l-ilhm
choices, n.',lS
the te
nl
considered. linear
RBNN
_,ptimization
lhe
i]etna[
promise strategy
This the
of
possibility
tbr engineering
is
,,pt_mum
design
!he
'.,Hllaccs
_t design
been
,t O_i_, cIli,rt tn
in
,+L1..tdr;.ItlC
Jcpendent
i_cated
,NN
more
using
c,,n>tstcnc; as
problems.
RSM
have
lor rocket
,in?.' _,pec_fic
an
data
is
a concern,
and
RSM
enables
for
of
The associated
of with
reeions
design
data.
are normalized
bv thmr respective
baseline
space.
be
both
effectively
any number
ot
injectors
generality depth
of
the
breadth
_'i.e., details
and
it on
values_. AIAA-2000-4880
of
the
global
filters
noise
the
shape of the actual substantial errors et al. 4 have
of and
allows
levels
in representing
Shyy
to
of the
through
can
space
used tied
dimensionality
Depending
and the introduce
engine
is not
{_btained
and
is effective design
of the design
approach
The
Surface
rocket
et al. -_ have
at varying
the
polynomial employed suttee, the RSM can
Response for
types
This
information
RSM
polynomial
to combine
_i.e.. ,,,cope of design _ariables) the desi,an variables _.
characteristics
The
methods
combinations.
consideration
desion
used.
data
different
the
polynomials
['he
the designer
variables
propellant
and
experimental
which cubic
Tucker
or >_urce.
and
and
before
For example,
type
or RSM
space.
method.
design.
and
objective
linear regression. The ltle surface can then be
used
rejector
data
n()t
numerical
search
been
design.
an
used. Graduate Student Assistant, Student Member AIAA : Graduate Student Assistant, Student Member AIAA • I)_olessor and Dept. Chair., A_,sociate Fclh),,_ .\I.V\ .-\cmspace Engineer. Member AI:XA _][Aerospace Engineer. Member AIAA :# Distinguished Professor. Fellow AIAA _* Associate Professor. Member AIAA 1 INTRODUCTION
a gradient
methodoh)gies
to rocket
injectors The
in
is bx (ff
for
constraints.
pcrf,,rmance
quadratic
_,brained minimum
models
related
the de_qgn
',ariahlcs.
are t)r the
_m_ponent
it reqmrcs used
lhc
,,_ei(ic,ents :ll:.lXlfllunl
i,,sucs
RSM.
with
complex
optimization
gas-gas
rciatr_e
polxnomial-based
is represented
from
these
investigated.
in _epresemqng
•\ Nmce
_t
the
_s {,_ :>>ess
NN techmqucs
design
,Jbs_ _..\11 variables
desien
have
generate
_m specified
turbines
yields
it being
,.he p;climinary
Neural
to
An
_ntermgate
and
and
used
obtained
based
>_upers(mic
. Olglp()ncnts
die
to
nctx_orks
•\mollg
as
used
including
"(_[[_
{RSM)
been
data
conditions,
new
Accordingly,
simulations.
c_mponents,
{">LliAi[',
is eas_cr \_lth
!n this ,,mdv.
icDlesclltcd
cnEil]C
representing experimental
space
of these
by, development
_
have
propuisum
optimum
;Inc
Methodoh)gy
not
design
Iechniques.
techniques
then
the
evaluation
be facilitated
lunct|orL
eradicnt-bascd
.s(,lrerb
both
coupled
aleorithm
111ode[s
t_r
ROllccd.
using P, BNN
l'_ _-
_ ,rl(;I
than
been
for
and
nctv,_qks,
better
have
models
numerical
consideration
in combinations
increasing
,:tnd efficient
Surface
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neural
standard,
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tr;.tincd
designed
training
regression.
performance
a
Response
and
!'._,{_-[a\cI-cd
and
being
decreasing
are forcing
ranees
can
are
performance,
concurrently
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cubic
diJfcrcnt
.X search
designs
and
[ICtlltHl",. t)l
using
performance Fhe
_[
and complex
systems
increased
goals
thereby
Objecti:e
(RBNN)
'_.
{_t the
employed,
(NN)
;raining
new
oxer
c,_mpiexiLv.
Netv,'ork-
ditterent
for while
These
variables
then
) are c'_m_parcd,
propulsion
goals
safety
cost.
implementation
NN are are
Quadratic
space•
performs exceptions
but
•
tm :,ix ,)Dl_lil]ed
uans[cr
training
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RS and
_¢H'vcll'?
accHracv
{_,,er
and
polynomial
p_)l.,,nomml
,.'O
out
poi}ll,,Hlli;_ds
JLIDLc
tile
design
carried
atld
on
inlcdtl_r
Science,
rocket
meet and
and
based
test data
t\'.,'{)
x_eight
,>1 desi_,n
,._J,.lta
netv, ork
IBPNN
fItHllbcI
and
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lan-Sigmold
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is
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robustness,
-'0
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l'he
t)[
(:_1,
Background
to
,.lnd
ci_axial
Sc\'eral
neural
_t)/l('l/_('
('e)II,','IHIIIY,
design
RS
basis net_)rk
related
15
data.
types
W. Griffin
AL "4_381._.
General
pr V,,,,,, > 0.0484
individual
are
l is the
The
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2. 197 > c.l,'V): > 0.343
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functions
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the values
111 and i21
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(3)
x_nhin
t,, tc_,lcd.
and
two
is of the
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normalized
W i,,
t_n IANF"
i_l_dc[:,
their
/
din_enslonai
>tructural
di_,tnbuted
xanablcs
desirability
l
a cmnpositc Using
composite
example,
turbine,
_cioht
to
Hd,
are
¢._,Vi: qA...... ,
e, a tl0si.gn
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constraints
mean
!he i[lclementai
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I_l). Therefore.
minimized
measure.
D=
76 for
the
of the
W, a lumped
xariables.
face
points,
properties
weight.
dependent
a
only
L.
_tructural
Overall
lot
not converge are
and
For
to combine
in this
using
variables
annulus Co,
this
available
of 77 design could
Q. The
are six
flJr six ;ariables,
code
design
influencing
perlormance
design
ERE
objectives, torm
function. mean
a
In
There
b_
Instead
runs
involved
selected
design.
The
and
points
is
composite
a geometric
using
flowpath.
variables design
the meanline
designs.
diameter,
76
by a/co
l]owpath this
is
design analysis
considered.
output
points (fcc)
since
the
a on
has been
and
be provided
were
preliminary
generates
There
examined
aerodynamic
turbine
composite
componem
the
calculation
stage
design
payh)ad
where
meanline
training.
system
one-dimensional
12.
preliminary study,
propulsion
the
et al 3 used
the
is normally
Ior C S ERE
where
(" is the
target
_alue.
VCesetd
o=
A,
C,
E
B,
priorities values
and
value
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and
are
Candd
chosen
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or, as in the present to reflect
de_on
in the
the
study
respectively.
Values
respectively.'.
Both
E i.,, the highest
/ foranyQ
and
process
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network
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accurate
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ol
NN
process
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network
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values
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nodes
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Networks
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and biases
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points.
been
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ts. The
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weights
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until
network
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new
an can
set of
variables in the design .,,pace. The neural network _ available in ._,latlab is used ti0r the current
analysis. 2.4.1
Radial
Basis
Neural
Radial-basis
number
and
2.4
then
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order.
equation
fl_c number
design
oxidizer
points
the three
both
the
potenlial
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ARF.
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In this bx
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distinct
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is depicted
to
15
_',,q' . and
9 distinct
V/V,
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lem, ths oli;er in
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in`._fl`.ed. dcxehq-_ed
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ratio.
lit in L,,,,,,,.
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Since
velocity
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model
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for this problem
the "_ distinct _rder
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performance,
for the
lhc
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Lr.,,m_. Therefore,
on
space
ot design
velocttv
available
only
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the
pr, fiqcm,
depends
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('alhoon
on
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evaluated
networks
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function
and
requires
large
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set.
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the_weights
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is due
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to the
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uses
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when
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depending
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in a small
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of
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be efficient
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RBNN
the size
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of data
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(Figure
be designed
fact
are
radial-basis
layer
of neurons, can
(RBNN)
networks
output
number but
Networks
neural
neurons to train
for training.
AIAA-2000-4880
The transfer radbas,
which
function
is shown
and minimum
outputs
the function
of
is given
for
in Figure 1 and
radial
2b.
basis
Radbas
neuron
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In case
3 and 4 give
injector
and Q and
In case
also
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w
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it, troOp
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for stable
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learning
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(13)
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2.5
Design
!he design in the hidden
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the
tbr
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network.
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of random
Process
optimization
process
can
be
divided
parts:
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error
xaiues
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and
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the
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phase
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In BPNN
l l:ieure
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in
the
This
results
takes
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initial
weights
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of the
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to solve or
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with
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similar
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architecture kind
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the
The
in Matlab.
an
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based
For a given of
so its to start
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on
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set.
,,ptimiz,2r
uses until
tile
italia]
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of
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The
the
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ub
used
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is
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upper
x.
be Ib is
boundary
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functitm. be
goal
Additional
incorporated
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programming
from
process
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then li.v; can be written
process
constraints.
at
vector
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and
funcmm
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the
to lb _"t1 \aries
in the
response
,";22.00 follows:
and
lL_r the
between
surface
(.I.68.
Ihe quadralic values
c_nce
_mportant
_o note
li_e
bv in
betx_een
t l and
"apparent"
accuracy
levels
a
in Figures
the
teaction.
some
bx K,
the
RPM,
RSM (8)
in r/and
the
maximize
error
Apay.
bias
in turn
in
it is
tot
worst.
causes
more
accurate.
rmalizcd
76
number
37
except that BPNN is clearly based on the two cases, it seems
most
design
D - 300.440,(_
RPM
is
i_ptimal
response
c_cilicicnts
+5.__SD, _,_''
- 0.00362k
in.jector, Overall.
have hidden
and 60 neurons
supersonic
lbr the to RBNN.
constraints. \vith
has
but pertbrms
8 for the 4
in the
D_-114.407C
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with
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1.2. I'hc
t-statistics
with
me reduced
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ol oare
respectively
significantly
that _oh'crh evaluated.
S
cklbic polynomial
with
W.
uses
_.._iohcrbe
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t[t_e
designed
t? and
The accuracy of the various available in Table 6A and
data
ba_,ed L_n the _btaincd
,elected
0 _,uggcsts
terms.
(19)
be due to overfitting,
trend
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45
polynommb,
eqtmtion
l'be
presence
W was
of
cubic
that are products ol three because ,_1 the number of
the
Dk, RPM
DA ,,,,,k , -- O.O162 DC,kr
networks
those
was
_._,ith the
I'hen.
+ 921.053
-- 0.692
for
BPNN
fable generated.
of levels
also
order
and
initially
the number
ThereR_re.
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RPM
respectively, in a single hidden chosen are listed in "Fable 7.
V.,_:,_,.
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IC. RPM/%
while
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nf the weights
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-- 162.604
a
process.
with
values
neuron
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training
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of one
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evaluated
D + 10.744Q,
e -- 0.0104C,,
--0.00183k,
but
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A,,,," -- 0.00856Q
be due
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The
tbr to the it
is
stage
we are dealing
AIAA-2000-4880
onlywiththesinglestageof theturbine,ftencethereis no splitonthestage reaction. 4
5
The
SUMMARYANDCONCLUSIONS In
the
constructed employed and
adding combined
helps in
NN
are
first
test
data
are
then
of
polynomial
the
BPNN
and
Ihe
is
or,, and
accuracy
and
various
improvement
between
evaluate
neurons
model
best
evaluation
RS
data.
performance
into
The
Marshall
the
training
the
insight
terms.
stud.,,,,
the
to assess
to offer
data
present
using
selected
on
NN,
netv_orks
a
for
optimum
gradient-based surfaces networks.
Based
c,n the
polynomutls
and
obtained.
as
the
both
present all
',kith
perform
the','
have
stud>',
both
NN
data
sizes.
the
NN
than
seems
more
to be
cases.
networks,
even
s(s[ver/L
[cndt()
,wer
fact
a large
l;curt>lls
respond
space.
Thus,
bas_s neurons that
to
larger
can
in
b:t"
neurons
can
>pace,
while
ICl_.ltl\C{\
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MIILI[J
Based
i/axe
output.,,
tadia[
the
for
network
ellen
i_l
more
takes
network
shown
technique
_s not
method
t)f making
designing
,'.
less
ume the
K,.
Rocket
Eneine
ASEE ] 3-15.
Joint 199g
Shy.v,
W.,
10.
procedure
fast
such
out cases.
of efficient.
of the be
aimed modest
and should
data
size
sizes to
the
are criucat
be add'ressed
to
pertbrm a The
number for pracucat
of
12.
better work is
Response Product John
Wiley
R. G., httroduction
to
Lecture
Publishing W.
Tucker,
and
Notes
Company,
Sloan,
J.
G,,
"An
Methodology
34 th AIAA
P.
Snr#lce Engine
and
K.
June
and
Nettr¢ll
InJector / ASEE
/ ASME
For / SAE
Vaidyanathan,
Network
_'0-24.
for
35 th AIAA
Propulsion 1999,
R.,
techniques
Opttmtzatton.'" Joint
/
July
Conference
/ and
AIAA-99-2455,
Los
CA. N.,
Shy5,,
V¢.. Fitz-Cm
tcnt
and turbine
basis
this is the
that
t)_e
Mxver t_rder
flexibilitx.
configurati_m>.
comparable back-propagation si,_,moid neurons in the hidden
--
better
neural
reached
Myers,
Integrated
response
trained
ha_c
more
l\_r modest
in teeter
P, adial
!_.
3.
a standard. the
,a¢
statistical measure needs the best terms to include.
,_fl,,'erb
the
using _wer
4.
polynomials
,\mong
5.
out
algorithm
results
polynomials
In
4.
the
t li,.z,her order
ct_mparably 3.
is carried
conclusions.
appropriate determine 2.
by
represented
following 1.
design
optimizanon
has
Center.
REFERENCE:
the
RBNN.
Thus the test data are adopted to help select appropriate RSM and NN models. Once an RSM or NN model is constructed, a search
study
Flight
Optimization Using & Sons, 1995. 2.
xarying
m
present
Space
Surface
the test
with
constants
1. and
based
[:_r the
spread
6
polynomials
by removing
or.
of
varying
ACKNOWLEDGMENT
Propulsion (2000),
liquid NAS3F.
and
For
A 36 a'
Conference Huntsville,
AIAA-2000-4880 Neural
13. Haftka, R. T., Gurdal, Z. and Kamat, M, P., Elements of Structural Optimization, 3 'd edition, Kluwer Academic Publishers, 1990. 14. SAS Institute Inc. (1995). JMP version 3. Cary, NC. 15. Dernuth, It. and Beale M., Matlab Neural Network Toolbox, The Math Works Inc, 1992. 16. Stepniewski, S. W., Greenman, R. M., Jorgensen. C. C. and Roth, K. R., "Designm.? Compact Feedlbrward O/F 4.6.8 4.6,8
[
4,6,8 1: Range of design
Table
Model # [
Coefficient
= 0
V/Vo _
Training
!i
.
Sets,"
4.5.6.7.8
Terms Removed
l
Terms
Included
: V,/Vo]
I
Quadratic
and less
!
.......... r l 'd'_)" ! J_":q',:_l ......... , _'./_'::) _',A"o) _ I
_,, (%)
0"(%)
0.218 0.0857 0.0799
0.280 0.212 0.214 0.214 0.213 0.212 0.212
0.0799 0.0859 J 0.0936
t_'/_:°f2l
, l..,,,,,/ L,,,,,..,)"_,(V/V,,):(L,,,,,,:,):
7
[ :VYVoj:L,,,,,,,. _'/Vo_ _ :l.,,,,,u) _, :I, ,A,,) _L,,,,,,U . Vcq/o(L,.,,,,,f,)' 0.0988 'Fable 21a): Different cubic pob'nomiats for ERE. (Dependent variables: _i/_:,, and L,,,,,,,, t5 training points, 10 test pointsl (Errors are given in percentages of the mean value of the responses). ('oefficient
Model
: I)
I
ferms !,?.cmoxcd
Terms
Included
_, l";)
[
_l 1
_
# of lxp,'ers
Scheme RBNN (Soh'crbe) RBNN (Soh'erb)
, ,
') ] _ 4 i used to design
"
, :_'A'o)-fO/t:)-
5.445 5.584 5.584 5.584 5.584
i
3.490 2.234 2.094 2.094 2.234
3.909 5,584
_ i
2.094 2,094
lot Q. i Dependent variables: O/F and V/_.:,, 9 training (,f lhe mean value of the responses).
# of neurons in I # of neurons !' the hidden lax er ! the_
_ RBNN {Soh'e,be) ," i 1_ RBNN(Soh'erb_ 2 14 BPNN 2 8 "Fable 3: Neural Network architectures spread constant }
! !
( t"/_o_. I OIF)' ( I'A,'ol'. : O/F) J, r _iA:o _: _ _,'/_,'-). _C)/t":'. t _'/Vo)-
Table 2(b): Dit'fl:rent cubic polynomials points) (Errors are g,ven in percentages Scheme
and less
, t,, _.o: :_,'/_'or, !O/F)' '
6 7
0"(%)
1-
()uadratic
/V/V:n'.: 0/f:)' __)/l,b'
] i
O/FI2 3 4 5
38 th
clement.
i
5
Data
L,.,,_,, in. 4,5.6,7,8 4.5.6.7,8
8 for the shear coaxial injector
r _'./_"_)/:L.........
4
4
Snzall
i
i
V'./Y_/
3
with
V/V, 4 6
I considered
variables
Models
AIAA Aerospace Sciences Meeting and Exhibit, January l0-13, 2000. 17. Coleman, T., Branch. M. A. and Grace, A., Optimization Toolbox for Use with Matlab, Version 2, The Math Works Inc, 1999.
in
: .'7 I _ 1 i' I 1 / I the model for
cr tiw ERE I';:f ) 0.207 0.133
points.
Error qoal aimed for during
4 test
training
e i O.O {so= 3.25) I).0 {sc = 1.20} ,: 0.001 {so= 1.05} 0.001 {sc= 1.05} I 0.01 I 0.01 shear coaxial injector element. {sc =
cr tbr Q (%) 1.396 1.536
BPNN
0.i80
0.832
Partial Cubic RS
0.213
2.234
Quadratic RS 0,280 Table 4: RMS err_}r i_, predicting the values ot the objecIive function bv various schemes coaxial in ector element (Errors are L,iven in percentages of the mean value of the responses).
3.490 for the shear
AIAA-2000-4880 V/V,,
Scheme
4
O/F
L,.,,,,_, in.
RBNN
(Soh'erbe)
i
8.0
7.0
98.60
(0.00)
0.588
(0.00)
RBNN
(So/verb)
8.0
7.0
98.60
(0.00)
0.588
(0.00)
8.0
6.9
98.64
(0.14)
0.578
(1.70)
8.0
7.0
98.61
(0.01)
0.594
(1.02)
8.0
7.0
98.67
(0.07)
0.591
(0.51)
Model
8.0
7,0
Model
8.0
6.9
8.0
7.0
99.20
BPNN Partial
Cubic
Quadratic
6
RBNN
RS RS
(Soh'erbe)
RBNN
(Soh'erbl
BPNN Partial Cubic
[ ]
Quadratic Model RBNN RBNN
_
Cubic
Quadratic J Fable
5
Solution,,,
and RSM
schemes
are given
in parenthesis
lot
for the _hear
0.588
(0.00)
0.512
(0.00)
99.20
(0.00)
0.512
(0.00)
7.0 7.0
99.18 99.15
(0.02) (0.05)
0.513 0.500
(0.20) (2.34)
l _
8.0 8.0
7.0 7.0
99.17 (0.03) 99.20
0.531 (3.71) 0.512
j t
80
7.0
99.40
(0.00)
0.493
(0.00)
8.0
7.0
99.40
(0.00)
0.493
(0.00)
7.0 7.0 70
99.41 99.42 09.67
(0.01) (0.02 } (0.27)
0.500
(1.42)
, ti\cd
'.atuc',
coaxi;.t[
8.0 8.0 S.O
i 1
,',.0
!
I
,ff _,,,"_ and
mlector
for cizch prediclion
TypeofRS
98.50
7.0
Model
Optimal
0.588
8.0
RS RS
98.60
8.0 8.0
BPNN Partial
Q, Btu/inZ-sec
!
i
(Soh'erbe (SolverS)
%
I RS RS
ERE,
7.0 given
elemem.
T
0.499 ( 1.22) 0.47 ! (4.46)
99.40
_('onstraints:
t
0.493
and l ....... ,, obtained
ran,_,e _t 0/1: 4 _< O/F
_< 8.4
\_ith
NN
tlktltll_
_'II I }ptlllltH1?
i.:1'".I
,:2 :h_c
..----O--,
RS
i +::_ J4
%,
I 24 --
+
-El
--
RI/NN ",,4 .cibca
-7
--
'_I
--
RBNN naK¢lb¢)
t:
ca -
-
-X o -
"
.!,:FINN
"
-)
1.20
ISolver_l
-
\
130
-
-
-K-
-
-A-
--
_1: No
+
'_
t Solve
BPNN
t'ase
#
constraints:
0
2
I 1: No
2: ('oll',,ll_llllls
on
AN `) and
Case
# 2 2; (_onstraints
and
\rllldl_
I constraints: \N2
tit ('OIl_ffalllt_
[!IfCCt
_
......
on
(d)
or1 ( )l_tilllum
[$1allc
I!_tCCl
\ _LLI k It, ,hl
-
Ol! ()ptill/tlm
OI ( OIP, ltalllt>,
_'Jtag¢
]4CaCIIOI1
50
_
........ -------'4_t
ublc
RS
'
•
7
&-----t_
t tl)
? _i_
7-
rb
BPNN
"¢Iltd_
(el
±
"RBNN
erb)
I OO I
fl
:25
RS
I 60
..............
I 41)
Vane
I
os 07
:
of Constraints
150erbe
'RBNN
_
t 71)
7
I,LBNN I SoN
o -
,N
- -X-
-
5
-
'-X-
- -RBNN , Sohcrb+
E
] (16_
'
--
-_"
--
BI'NN --
-d_" --
F;F'NN
H _tl
I'c
NOCO_IMIdHIthl ,n \N2
(,,nMr,tzn[_
_ .rod
\ [l',_lu
_','.!
at/d
\ [ll;]_J
_o_
I_
I:igLIlC 14: t!li'o-'t due to prc:,cn,.'c l)iameter, D (in.L (b) Optimum C'_ tin.),
n_wtnallzcd
by
{e) Optimum their
Blade
respective
,.\',:h.t[ (ihurd.
t_a,_clillC
\ ;lilACS
(
_ln.) and
,pCC[I',
C
{";t>Clllle
iack
t,t 11
+lbs). (ci
\ttJllegJ.
Ct)Ib,
ll;.lil]t_,
