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On the stability of the discrepancy method for solving operator equations of the first kind with perturbed operators
141
14
KRAWCZYK R., Newton-Algcrithmec zur Bestimmung von Nullstellcn mit Fchlcrschranken, Computing, 4, 187-29?, 1969. HANSEN E. and SENGUPTA S., Bounding solutions of systems of equations using interval analysis, BIT, 21, 2, 203-211, 1981. MOORE R. , A test for existence of sclutions tc non-linear systems, SIAM J. Numer. Anal., 14, 611-615, 1977.
15 16
Translated
:~U.S.S.R.Comput.Harhs.~~th.Fhys.,vo1.29,~-.5,pp.lal-147,19B9 Printed in Great Britain
by
Z.L.
0041-5553/89 $10.00+0.00 01991 Pergamon Press plc
ON THE STABILITY OF THE DISCREPANCY METHOD FOR SOLVING OPERATOR EQUATIONS OF THE FIRST KIND WITH PERTURBED OPERATORS" N.V. KINH operator equations The stability of the discrepancy method for solving of the firs: kind with approximate operators is established assuming weak continuity of the operators in locally convex topological spaces. The eqcivalenc e cf certain. generalized variational problems in these spaces is alsc shcwr, The 8-stabiilty of the discrepaccy method for solving operator equations of the first kind with approximative operators being continuous (or se!?:-continuous) or closed (or preclosed), has been investigated by many authors (see i;-101:. In this paper, we investigate prcblens, ir, which given operators are weaKly co:tinuous (see Section 11, and we shall also investigate the equivalence sf varlaticna: prcklems called 1, 2 (see Section, 2). 1.
1.
in
which
vector fying
Definition of B-stability the operator equatisr. We consider
X is
a separated
lczaily
space correspz-ding to the fc;:owing cor.Ziticn:
car.-ex
the
cf
:>e
vec:cr
metr:c
g being
a fixed
real-valued
function.
g(O) -0.
A acting
The operator For and
c-4,. ~0)
which to
the
is
operator
Y, and moreover
from
X intc
not
defined
Ak acting (A,. y,)
exactiy
defir.ed
but
is
the
number
T is
fixed
fcr
;~:a:::;
dis;lace-ent,
co:Ivex f,rther,
satis-
l!
such
only
that
cz X, of
is
defined
following
weak;y
the
continuous.
solutions
of
approximately
on X,
is
weakly
Eq.
(1)
is
nonempty
ty
(A,. yt). in continuous, ye belongs
condlrions:
P(1/1. YG)Gb
Y-h. 620.
q,(h. 6)-O
as h. 6-O.
and
q,(k, 6) is a nonnegative real-valued of operators defined by
*~Zh.UyChiSi!.Hat.mot.Fiz.
a metriza:le
y‘i.= [O. 11.
Y and defined the
d,(Ahr A,!Gh. r’h+b
ir. [C,
X‘r consisting
from X into satisfies
!’ is
invar;a:le
and g(i.)-g(l-i.)Cl
Y are that
k:r,d:
Yi.=[O.11. Yy=>..
increasing
g(lr=l
we assume
(A<. y,).
sl;ace,
P be:ng
p(i.y. Oi
firs:
fznctioz
,29,10,1458-1465,1989
cf
the
variables
h,
6.
and dM is
a quasimetric
142
dw(A, Ao)- sup n is a stable functional, following cond:tions:
i.e.
it
‘($;:J) ,
is a functional
n(z)>0
e0,
Ycx,
defined
on dom R, satisfying
the
(2)
YzEdom R,
XJdom W0,
(3)
R,-(r=domR:R(t)
(4)
is 8 compact set in X yc>O First let us put M O&b)
=
&,e,=
if E x :P L&r, ye) f M,,(h, s),qdom L2,
p1
(h, 6)),
Nov we introduce Definition
the following definition of B-stability. 1. The discrepancy method is called B-stability for Eq. (1) if the net of h, 6-O (see 191). sets X, (h, 6) B-converges to .&ndomR as 2. The foliowing lemmas are used to establish B-stability. Lemm 1. If the net of sets (kfO.oelr) &converges to the set M then: (see [91). a) each of ltssubnets converges to M; and A’=,!! then the net (m,. a=X) B-converges to N. b) if g+m.<.l!,. 0=x If the net of sets Lemna 2. (see [91j. {M,. oeI). M,cX. being a separated topologiof the net each subnet {If) cal space, satisfies the condition: {I$). zo=.~f,* holds at least one of the properties:
where LT.)’ is the set (W.. 0=X) B-converges Lem
3.
(see
(x’) =dom I!
sequence
of liniting tc [9!J.
pcints
of the
kc1
set
and
M=X‘.
then
the
net
#. 7T.e stable
functicnai
R
is
lcwrr
seri-ccnrin;ous
i.e.
eaci
suck. that lim I,===. n-m
ondl1nlnnf G(1,)=b
and R(r) G w:tk centre at :/ in the mctrizable locally convex space (y. P) definec in Ii), is s ciosed convex set in Y. Proof. We will first s.how that B(y rl is ccnvex. Since the metric p is invariable for displacement, it is sufficient to show that the ciosed sphere Bi@,r) of radius r with centre 0 is a closed convex set. Let arbitrary elements Y,. Y:EBt(7. r). hence then
there
Lenm
pi!< We
@)Cr.
p,y:.
O)cr
have U)Cp(i.y,+(l-i.)yr.
(l-i.)Yl)+ O)C Cg(%)p(y,. O)+g(l-i.)p(y2,O)Cr(g(~-)-
p(i.y,-
tp(
(I-i.)y:.
(l-L)yr.
O)Cp(Ly,, o)+p((l-A)YI,
tg(l-A))Gr hy,+ (1->.)y+R(O. r). Thus the sphere B(O,r) is convex. the sphere B(O,r, is closed. Lemna 6. If x is a separated locally convex vector space then the weak convergence the nat in X is unique. Proof. We assume that there exists a net {f.)=X, that converges to either of z,, +,=X. z,+z:. Since z,-&+o and x is a separated localiy convex space, there exists a linear COntlnuOUS funCtlOna1 defined on x such that I(z,-z~)+@. Therefore we have f@J+f(&): consequently Clearly,
of
143
may converge to at most a point This is not true, because the net (f(r,)) We have proved the lenma. Thus z,=z,. then the set X.,(h, 6) LenaM 6. If AkV h r 0, is weakly continuous Q, XJ~dom Q+S, Since By property (3) cf the functional PrOOf.
exists
zr. z,=Xp*‘dom R. such
an element
that
Q(Z,)
p(A.r,. y,Jip(Az‘. A&)fp(Ad~. (R’(ro)h~b
and Q(r)
w=X,.
is
lover
mh,GQ(.r:) If m,,-R(r,). If m,,
then
2, belongs
then,
there
exists
R(z.)GI!(zr)
nonempty.
for
such
10, we obtain
yb)C
Therefore z&J,, (h.0. bounded, there exists
m,.b = Clearly,
is
to X.
inf Q(z), ~ww= 0
T>
there
belonging
inf P(I). ~E~,QL.b,
to X.,(8, c,. a sequence
(zI)~DllGh,(,
Yn and R(z.)-mrs
such
that: (5)
as n-m.
exists that z.C=Q, Yn. c=G (zp). Since the set R. is compact, there Frorr (5,, it follows En,. a subsequence of i2n) such that converges to and without loss of generality, we may assume that the sequence (2,) itself converges to f. By Lemma 4, the sphere B(y, IJ,(/~, 6)) is closed convex in Y, therefore, it is alsc weakly closed ill]. We obtain A,.-‘[B(yr.~.(h.6!)l-M,;,,,, since
.KT,h,,, A h r 0, is weakly CO%t:T:JC’JS, SLC!. 2 Se: is weakly closed h’ Or. the other hand, we have and therefcre, G-1, I>, f & .b < .vc,,, .bi Fro- (5) and Lemma 3, it follows that JEJom!1 Thus
=D,
in X. r=Al,,
L
l(+_e,.
(61
By !5) we obtain (7)
mAs- lim inl Q(G) - lim R (I,) >R (I), .-. . ..I
it follows that R(r;=m,,,. X=X., 0.. L]. Thus the set X,,,,,, +g. Hence the lemma. Now we establish S-stability. Theorem 1. Under the hypothesis of Lemma 6, the sequence X.,p.o B-converges to when h, 6-O. X,fidom R Proof. By Lemma 6, .X,rl,+b,*~. Arbitrarily choosing z,,EX.,~~,~,, we establish the net {s,, h, 6-O). Similar to proof such that of Lemma 6, there exists an element z@X,ndomQ consequently to=D.,,n,e,t’b, h; +-a., c-R (20). From (61, (71, We have proved
Since Qo is compact, there exists a subnet of the net such {II, I h, e-01 verges to and without loss of generality, it can be assumed that the r@sn,. converges to Z. Now we show that 5 belongs to X$dom R. We have
that net
it
con-
itself
~(A,~,~,~~~~p(A~~.,.~~~,;)tp(~~~.,~~~)+p(y~.y~)c
(8)
~n’(z,,)h+-~.(h,6)+6C~‘h+e,(h,6)+6~2~,(h.6). The right-hand
side
of
(6’
converges
to zero
as
h, 6-0,
hence
AG,,*~o
as
h, 6-0,
con-
144
scqucntly
We obtain
At+,, -w yo.
G,,::i, From Lemma 5 and (91,
It
follows
A&:
yo.
(9)
that AS-y,.
f=dom R ; consequently On the other hand Thus we obtain fExo. By Lemma 2, the net {X.l,h. L,, h, 6-O) B-converges to X,ndom R as proved the theorem. 2. Equivalence of variational problems 1, 2 In this section, we shall establish the equivalence of variational retain the hypothesis of X, Y, (A*, pc), R, as in preceding section. Variational DrOblem 1: r-min Variational
Droblem
:~(AG,
X*,-argmin {Q(t) : p(A&, #JCR’(r)h+6)*0). Variational problems 1, 2 are calied identical
hence
ye& Put
If assume
We
y.=B., the
and A is continuous,
solvable
and the contrary,
sequence which
VA,
they
are
if
its
then
set
these
consisting
6>0
solvable
and these
sets
Yh, 6>0.
The following lemma is obvious. and T.-r as Lenmu 7. If O-Q.+,Cr. Yn, a sphere of radius r with centre at ys in Y, then n
We
if
equlva:ent
X,,-X,r
Lenvna 8.
1, 2.
gJCR’(z)h+d).
(Q(r) : p(A,,.r, ~,)Cr’h+b)}+I
Xhe=arg (r-min
Proof.
problems
have
2:
If X is an &-space and Y is a Banach space Remark 1. variational problems are equivalent (see [2]). First we introduce the following deflnltion. Definition 2. Variational problem 1 (or 2) is called of solutions is nonempty, i.e.
are
We
(Q(z) : p(A.+r, I/~)Gr’h+6).
min {R(I)
(or
rrXJldom Q h, 6-O.
lyni means,
n-a: B,=B,,,
and Vn
&-{yeY: and
P(g,Yo)
weakly converges to Y~Y there exists a no such that
is
then y=B. Vn. yfB,.
VnTn,. consequently
&‘-B.-y‘
B.‘={L.EY:p(L..O)~r.). The set g,’ is closed, convex Y (Lemma 41, further, it is also a balanced set (see and then - v=B.’ ?.B.‘cB.‘, OChC I. Therefore, [ll]), indeed, clearly, if U-B.’ it is balanced. The set g,’ is absolutely closed convex and Therefore by Hany-y&B. Vn>n,. Banach’s theorem (see IllI), there exists a linear continuous functional defined on X such that: !(y-yO>i
and
VvrB,’
ll(v)l41
consequently !(Y-Y~)~~~~(Y.-Y~)
Vn>n,,
I(Y) rl+l(Yo)
>f(v.)
Vn>n,. It
follows
theorem
that
g.gY.
contrary
to hypothesis.
Thus
y=B. \‘,I.
We have proved
the
I The following Theorem 2.
If
theorem asserts the solvability of variational problem 2. the stable functional R satisfies the condition: each {z.)cdomR,
&-I
145
liminf Q(q)-b<= “.-.
and
Proof. If
Put
imply M*a=(zEX:p(A~,
sp=XJIdOm
Da-M,&
further
such
problem
and
~a)
I/J
~.ED+.~+B.
A&,)+p(Acr,.
2 is
Du-MJdom
solvable.
0.
r,&,,,
it
fc:lows
If
n&-Q(zr)
then
I
If
m6RM
then
there
y,)GR’(r,)h%
Pur inf Q(r). -DII
mrbFrom
variational
then
Q
P(AG, Thus
then
Q(r)=+
that
belongs
G
to
exists
X,,=z such
(I.) =DM
a sequence
O
that: (10)
Yn,
lim Q(G) =nitip. m_ D
ges
to
From
(lC),
Since
R,
it is :t
zEQ,.
can
of generality.
loss
Fror
the
On the
that
&.=R.
there
exists
follows
compa:t, Therefcre
it
a subsequence the
From
(lo)-(12:
We
have
implies
to
XI
Since to
Q, f.
converges
is
compact,
As in ? as
to
and
to
p(y.ya)Gr,.
{znlsuchthatitoonvar-
I as
IER,.
to
without
n-m. that
y,=A,r.-A,.z
the
there
proof
cf
of
that
reM,,
tbe
set
ci
?:ecrei-
2,
tte
X .rZ
net
EC!. c=Oiz
exists
Therefcre
zel!,,‘don,
R=D.,
approximate nef
sclutions
cf
equaticn
(1).
B-converges
{X,6, h, 6-O)
to
F’ii. t,>?. tr.c
(I.8
ii. b-0).
Ctvicusly.
Z:E ,Y .dc,n. !!
j
a scbnet i,
Theorerr
!1 21
theore-.
called
I
T,-R’(I.,)h+d).
fc;lows the
estatllsr.
Therefcre
z,=D,t t’h. 6:Oo.
verges
sequence converges
A,. It fc?lows
c;eratcr
proved
SOL is alsc Remark 2. The set TheoreT 3. Under the typcrhese XJldom R as h, 6-O. Proof. By Thecrea 2, we have I,~ beiong
weakly
Lemmas 5, E, it
and
rEX,,+E.
Let
the
itself
we have
hand,
y.,=B,,=(y=)’
consequently
of
sequence
converges
t f the
ccntir,Gitp
weak other
Yr,. c-nix‘).
that
be assurred
(11)
cf
we can
the
assume
net
{I+,(. h. 6-O)
that
the
net
s:cr. itself,
that
it
con-
{I:.:. i.. C-O)
h, 6-O : --r a.c h b-c!
We shall From
show
that
fPX.‘domS!
Q(r,,)Go(r%).
it
fc;lows
tnat lim inf R (r,J h.L-O
From
(13),
On the
(14),
in
other
'i3,
addition
tc
lower
GR(z,). Of the
semi-continuity
+p(A,r.,.
of
side
9.
it
follows
O)GO'(z
yt!-.O!yt.
,jh-Q.cz,,)h-
(15)
converges
to zerc
as
h,
01
6-O.
Thus
ADZ.f---1/‘ as )r. E-O.
From (131, &E-go
proved
;
(161,
in addition
consequently
By Lemma 2, the theorem.
the
that
(151
I I. A,&!)-
+bc2[R'(r!h-6]~-l[o'~.r:)h-
right-hand
functional
we have
hand,
p(A,r.,. yocpr.4
the
(16,
5~X:‘dom
net
to
weak
(16) of
continuity
the
operator
4~.
it
follows
that
Q
{A’,,. h. 6-O)
B-converges
to
X,Odom R
as
h,
b-0.
We have
146
The following
theorem asserts the Under the hypothesis Variational problem 2 is Proof. (Theorem 31, B-converges to X,:dom R Therefore it is sufficient to show that We have ~+,:‘-R(z) Y~eXha. For variational problem 1, there Theorem
4.
kg is empty. Indeed, we assume the to this set. Therefore we have
equivalence of variational problems 1, 2. of Theorem 2, these problems are equivalent. solvable (Theorem 2), further, the net (X,,,h,640) of course, it also converges to X, (Lemma 1). X~I-X~,YA, 6. are
the
following
cases:
(T-min(R(r):p(&,
p&7%+6))
this
means there
contrary;
On the
other
hand,
ZU’ belonging
we have
This is nc,t true. Thus this T>T*r(, then the set
set
We as.sume tne ccntrary, we alsc cbta:r. a similar
is a:sc, empty, Therefore set. We have
yl)
i.e. there exists an element relation to (17).
{T:P@G. y,)~R’(z,~‘)h+6)=(r:p(Ah~. Clearly equal to
inf R(z). _%
is empty.
.4gr(7-min(R(r):p(A,t,
z&e’ belonging
to this
yajG(71r0)%+6).
(18)
on the set defined on the left-hand side of the minimum values of R(t) side of (18) contains the R(rht’) and the set define d on the right-hand
118)
z&X,+.
7=O:r.:‘)
Thus we have 7==7h:0. Let us artitrariiy
take
This &!EX.‘,.
is not Clearly,
true,
Conversely, R(r,+‘) =7nr‘ an:
let
us arbitrarily
choose
consequently
such z,,( alsc
fi,,‘-.irg{7=min(n(l):p(A,I,
this
beiongs
set
is empty,
to the
following
I&?’ belonging
to the
(201,
in addition
if set: (19)
ye)G~‘h+6)). set
(19);
hence,
we have
(20)
P(A.Z”,‘.Y,)G (Thrcj’h-6 from
set
(17)
7-Z!(11~‘)~7~d~-inf{R(t):p(Aht,yd)<~’(~)~+~)-
elements
an element
exists
the
rnc’=Dha.
conseque-tly
are
then
y~)
pu"Ihr'.
If
o<7c7u”.
if
tc 7*cp= min R(rj, *=D1C
it
follows that I.~‘EX,~. Thus XI~‘-X~~. From the above cases, it follows that X,a-X,t Vh. 6. Thus these problems are equivalent. Therefore, the net (X~lb.h. 6-O) We have proved the theorem. ges to X&dom 9. I would like to thank N.M. Chuong for suggesting this problem.
also
conver-
REFERENCES 1. 2. 3. 4.
Tha stability of the discrepancy method when solving ill-posed problems, TANANAV.P., Izv. VUZ. Matematika, 9, 75-60, 1974. TANANAV.P., A projection-iterative algorithm for solving ill-posed problems with an approximately specified operator, Zh. vychisl. Mat. mat. Fiz., 17, 1, 15-23, 1977. A projection-iterative algorithm for operator equations of the first TANANAV.P., Dokl. Akad. Nauk SSSR, 224, 5, 1028-1029, 1975. kind with a perturbed operator, LISKOVETS O.A., The solutlon of equations of the first kind with a closed operator, Dlf.. Urav. 19, 13, 1666-la?:, 1974.
147
9.
The solution of ill-posed problems with a closed operator, Dokl. LISKOVETS O.A., Akad. Nati SSSA, 219, 5, 1069-1071, 1974. The convergence of an approximate method of solving operator equations MOROZOV V.A., of the first kind, Zh. vychisl. Mat. mat. Fiz., 13, 1, 3-17, 1973. An approximate discrepancy method in non-reflexive spaces, Zh. VINCKUPOV V.A., vychisl. Mat. mat. Fiz., 12, 1, 207-212, 1972. A regularizing algorithm for ill-posed LEONOV A.S. and YAGOLA A.G., GONCHARSKII A.V., problems with an approximately specified operator, Zh. vychlsl. Mat. mat. Fiz., 12, 6, 1592-1594, 1972. Variational Methods of Solving Unstable Problems, Nauka 1 Tekhnika, LISKOVETS O.A.,
10.
Minsk, 1981. IVANOV V.K.,
5. 6. 7. 8.
and
its
VASIN V.V. and TANANA V.P.,
Appiications,
ROBERTSONA.P.
11.
Press,
Nauka,
Moscow,
The
Topological
and ROBERTS% W.,
Theory
of
vector
spaces.
Non-Linear
Problems
Cambridge
Univ.,
1964.
LI.S.S.R.Comput.Ma?hs.Math.Phys.,Vcl.2C,rJc.5,pp.147-157,1989 Printed
Ill-Posed
1976.
in
Great
0041-5553189 $10.00+0.00 C 1991 Pergamon Press plc
Eritain
MEAh SQUARE APPROXIMATION OF A RECTANGULAR MATRIX BY MATRICES OF LOWER RANK!' V.A. DAL’SAVETan2 F .V. YAKCVLEV The probiem defined in the title basis of its connection with the
of this paper is examined, on the decompcsitior, problem of Singular In particular, it is proved that the wellof the matrix in question. known group relaxation methcd is convergent given any initial aPpr:xirr,ation, and its rate of convergence is shown tc depend on the relation the correspcnding sir.galar numbers of the matrix. between
Introduction
1.
Let FiM, N] be an artitrarg The probiem of mean sq,uare
1141 / most
r
(the
set
of
all
rectang_;ar approximation
matrices
such
ilM,
matrix and r L 1 a fixed integer. cf F;ti,flj by matrices Z:K; R: ty F,) is as ?cllc*s. ?I':is dencted
r
c,(z~:-~~F-z112-
where product
Z is (RI = r. of twc
a member
of
Our problem matrices of
F,
if
and
or,ly
may therefore lower rank:
if
I.r,
it
be
I m:r.! I#:, ranr: at
(F[i,j]-Z[i.I])‘-min.
).YJ.W A matrix
r ci
be
expressed
reinterpreted
can
as
C,(X. Y) :-IIF-XY’II’
as
Z[M. .v]-X:&f.
follows:
R]x)“[R,
apprcximate
.v].
F by a
+ min.
11.2;
y, Here is
H, the
is
the
sum of
we have yet matrices of
set at
of most
another rank 1:
pairs
of
r matrices
matrices of
interpreta?ion
(X, rank
of
the
YI each
wit?.
r
columns.
Since
the
product
XYT
1,
originai
problem:
approximate
F by a sum of
7 &(T,...., T,):=UF-&Ii’,-I All Incidentally,
these
interpretations (1.2) is a discrete
of
min . (7, 1ImLti <‘I
the problem are useful version o f the problem
be utilized in the sequel. approximating a function of twc
and will of
(1.3)
14
KRAWCZYK R., Newton-Algcrithmec zur Bestimmung von Nullstellcn mit Fchlcrschranken, Computing, 4, 187-29?, 1969. HANSEN E. and SENGUPTA S., Bounding solutions of systems of equations using interval analysis, BIT, 21, 2, 203-211, 1981. MOORE R. , A test for existence of sclutions tc non-linear systems, SIAM J. Numer. Anal., 14, 611-615, 1977.
15 16
Translated
:~U.S.S.R.Comput.Harhs.~~th.Fhys.,vo1.29,~-.5,pp.lal-147,19B9 Printed in Great Britain
by
Z.L.
0041-5553/89 $10.00+0.00 01991 Pergamon Press plc
ON THE STABILITY OF THE DISCREPANCY METHOD FOR SOLVING OPERATOR EQUATIONS OF THE FIRST KIND WITH PERTURBED OPERATORS" N.V. KINH operator equations The stability of the discrepancy method for solving of the firs: kind with approximate operators is established assuming weak continuity of the operators in locally convex topological spaces. The eqcivalenc e cf certain. generalized variational problems in these spaces is alsc shcwr, The 8-stabiilty of the discrepaccy method for solving operator equations of the first kind with approximative operators being continuous (or se!?:-continuous) or closed (or preclosed), has been investigated by many authors (see i;-101:. In this paper, we investigate prcblens, ir, which given operators are weaKly co:tinuous (see Section 11, and we shall also investigate the equivalence sf varlaticna: prcklems called 1, 2 (see Section, 2). 1.
1.
in
which
vector fying
Definition of B-stability the operator equatisr. We consider
X is
a separated
lczaily
space correspz-ding to the fc;:owing cor.Ziticn:
car.-ex
the
cf
:>e
vec:cr
metr:c
g being
a fixed
real-valued
function.
g(O) -0.
A acting
The operator For and
c-4,. ~0)
which to
the
is
operator
Y, and moreover
from
X intc
not
defined
Ak acting (A,. y,)
exactiy
defir.ed
but
is
the
number
T is
fixed
fcr
;~:a:::;
dis;lace-ent,
co:Ivex f,rther,
satis-
l!
such
only
that
cz X, of
is
defined
following
weak;y
the
continuous.
solutions
of
approximately
on X,
is
weakly
Eq.
(1)
is
nonempty
ty
(A,. yt). in continuous, ye belongs
condlrions:
P(1/1. YG)Gb
Y-h. 620.
q,(h. 6)-O
as h. 6-O.
and
q,(k, 6) is a nonnegative real-valued of operators defined by
*~Zh.UyChiSi!.Hat.mot.Fiz.
a metriza:le
y‘i.= [O. 11.
Y and defined the
d,(Ahr A,!Gh. r’h+b
ir. [C,
X‘r consisting
from X into satisfies
!’ is
invar;a:le
and g(i.)-g(l-i.)Cl
Y are that
k:r,d:
Yi.=[O.11. Yy=>..
increasing
g(lr=l
we assume
(A<. y,).
sl;ace,
P be:ng
p(i.y. Oi
firs:
fznctioz
,29,10,1458-1465,1989
cf
the
variables
h,
6.
and dM is
a quasimetric
142
dw(A, Ao)- sup n is a stable functional, following cond:tions:
i.e.
it
‘($;:J) ,
is a functional
n(z)>0
e0,
Ycx,
defined
on dom R, satisfying
the
(2)
YzEdom R,
XJdom W0,
(3)
R,-(r=domR:R(t)
(4)
is 8 compact set in X yc>O First let us put M O&b)
=
&,e,=
if E x :P L&r, ye) f M,,(h, s),qdom L2,
p1
(h, 6)),
Nov we introduce Definition
the following definition of B-stability. 1. The discrepancy method is called B-stability for Eq. (1) if the net of h, 6-O (see 191). sets X, (h, 6) B-converges to .&ndomR as 2. The foliowing lemmas are used to establish B-stability. Lemm 1. If the net of sets (kfO.oelr) &converges to the set M then: (see [91). a) each of ltssubnets converges to M; and A’=,!! then the net (m,. a=X) B-converges to N. b) if g+m.<.l!,. 0=x If the net of sets Lemna 2. (see [91j. {M,. oeI). M,cX. being a separated topologiof the net each subnet {If) cal space, satisfies the condition: {I$). zo=.~f,* holds at least one of the properties:
where LT.)’ is the set (W.. 0=X) B-converges Lem
3.
(see
(x’) =dom I!
sequence
of liniting tc [9!J.
pcints
of the
kc1
set
and
M=X‘.
then
the
net
#. 7T.e stable
functicnai
R
is
lcwrr
seri-ccnrin;ous
i.e.
eaci
suck. that lim I,===. n-m
ondl1nlnnf G(1,)=b
and R(r)
there
Lenm
pi!< We
@)Cr.
p,y:.
O)cr
have U)Cp(i.y,+(l-i.)yr.
(l-i.)Yl)+ O)C Cg(%)p(y,. O)+g(l-i.)p(y2,O)Cr(g(~-)-
p(i.y,-
tp(
(I-i.)y:.
(l-L)yr.
O)Cp(Ly,, o)+p((l-A)YI,
tg(l-A))Gr hy,+ (1->.)y+R(O. r). Thus the sphere B(O,r) is convex. the sphere B(O,r, is closed. Lemna 6. If x is a separated locally convex vector space then the weak convergence the nat in X is unique. Proof. We assume that there exists a net {f.)=X, that converges to either of z,, +,=X. z,+z:. Since z,-&+o and x is a separated localiy convex space, there exists a linear COntlnuOUS funCtlOna1 defined on x such that I(z,-z~)+@. Therefore we have f@J+f(&): consequently Clearly,
of
143
may converge to at most a point This is not true, because the net (f(r,)) We have proved the lenma. Thus z,=z,. then the set X.,(h, 6) LenaM 6. If AkV h r 0, is weakly continuous Q, XJ~dom Q+S, Since By property (3) cf the functional PrOOf.
exists
zr. z,=Xp*‘dom R. such
an element
that
Q(Z,)
p(A.r,. y,Jip(Az‘. A&)fp(Ad~. (R’(ro)h~b
and Q(r)
w=X,.
is
lover
mh,GQ(.r:) If m,,-R(r,). If m,,
then
2, belongs
then,
there
exists
R(z.)GI!(zr)
nonempty.
for
such
10, we obtain
yb)C
Therefore z&J,, (h.0. bounded, there exists
m,.b = Clearly,
is
to X.
inf Q(z), ~ww= 0
T>
there
belonging
inf P(I). ~E~,QL.b,
to X.,(8, c,. a sequence
(zI)~DllGh,(,
Yn and R(z.)-mrs
such
that: (5)
as n-m.
exists that z.C=Q, Yn. c=G (zp). Since the set R. is compact, there Frorr (5,, it follows En,. a subsequence of i2n) such that converges to and without loss of generality, we may assume that the sequence (2,) itself converges to f. By Lemma 4, the sphere B(y, IJ,(/~, 6)) is closed convex in Y, therefore, it is alsc weakly closed ill]. We obtain A,.-‘[B(yr.~.(h.6!)l-M,;,,,, since
.KT,h,,, A h r 0, is weakly CO%t:T:JC’JS, SLC!. 2 Se: is weakly closed h’ Or. the other hand, we have and therefcre, G-1, I>, f & .b < .vc,,, .bi Fro- (5) and Lemma 3, it follows that JEJom!1 Thus
=D,
in X. r=Al,,
L
l(+_e,.
(61
By !5) we obtain (7)
mAs- lim inl Q(G) - lim R (I,) >R (I), .-. . ..I
it follows that R(r;=m,,,. X=X., 0.. L]. Thus the set X,,,,,, +g. Hence the lemma. Now we establish S-stability. Theorem 1. Under the hypothesis of Lemma 6, the sequence X.,p.o B-converges to when h, 6-O. X,fidom R Proof. By Lemma 6, .X,rl,+b,*~. Arbitrarily choosing z,,EX.,~~,~,, we establish the net {s,, h, 6-O). Similar to proof such that of Lemma 6, there exists an element z@X,ndomQ consequently to=D.,,n,e,t’b, h; +-a., c-R (20). From (61, (71, We have proved
Since Qo is compact, there exists a subnet of the net such {II, I h, e-01 verges to and without loss of generality, it can be assumed that the r@sn,. converges to Z. Now we show that 5 belongs to X$dom R. We have
that net
it
con-
itself
~(A,~,~,~~~~p(A~~.,.~~~,;)tp(~~~.,~~~)+p(y~.y~)c
(8)
~n’(z,,)h+-~.(h,6)+6C~‘h+e,(h,6)+6~2~,(h.6). The right-hand
side
of
(6’
converges
to zero
as
h, 6-0,
hence
AG,,*~o
as
h, 6-0,
con-
144
scqucntly
We obtain
At+,, -w yo.
G,,::i, From Lemma 5 and (91,
It
follows
A&:
yo.
(9)
that AS-y,.
f=dom R ; consequently On the other hand Thus we obtain fExo. By Lemma 2, the net {X.l,h. L,, h, 6-O) B-converges to X,ndom R as proved the theorem. 2. Equivalence of variational problems 1, 2 In this section, we shall establish the equivalence of variational retain the hypothesis of X, Y, (A*, pc), R, as in preceding section. Variational DrOblem 1: r-min Variational
Droblem
:~(AG,
X*,-argmin {Q(t) : p(A&, #JCR’(r)h+6)*0). Variational problems 1, 2 are calied identical
hence
ye& Put
If assume
We
y.=B., the
and A is continuous,
solvable
and the contrary,
sequence which
VA,
they
are
if
its
then
set
these
consisting
6>0
solvable
and these
sets
Yh, 6>0.
The following lemma is obvious. and T.-r as Lenmu 7. If O-Q.+,Cr. Yn, a sphere of radius r with centre at ys in Y, then n
We
if
equlva:ent
X,,-X,r
Lenvna 8.
1, 2.
gJCR’(z)h+d).
(Q(r) : p(A,,.r, ~,)Cr’h+b)}+I
Xhe=arg (r-min
Proof.
problems
have
2:
If X is an &-space and Y is a Banach space Remark 1. variational problems are equivalent (see [2]). First we introduce the following deflnltion. Definition 2. Variational problem 1 (or 2) is called of solutions is nonempty, i.e.
are
We
(Q(z) : p(A.+r, I/~)Gr’h+6).
min {R(I)
(or
rrXJldom Q h, 6-O.
lyni means,
n-a: B,=B,,,
and Vn
&-{yeY: and
P(g,Yo)
weakly converges to Y~Y there exists a no such that
is
then y=B. Vn. yfB,.
VnTn,. consequently
&‘-B.-y‘
B.‘={L.EY:p(L..O)~r.). The set g,’ is closed, convex Y (Lemma 41, further, it is also a balanced set (see and then - v=B.’ ?.B.‘cB.‘, OChC I. Therefore, [ll]), indeed, clearly, if U-B.’ it is balanced. The set g,’ is absolutely closed convex and Therefore by Hany-y&B. Vn>n,. Banach’s theorem (see IllI), there exists a linear continuous functional defined on X such that: !(y-yO>i
and
VvrB,’
ll(v)l41
consequently !(Y-Y~)~~~~(Y.-Y~)
Vn>n,,
I(Y) rl+l(Yo)
>f(v.)
Vn>n,. It
follows
theorem
that
g.gY.
contrary
to hypothesis.
Thus
y=B. \‘,I.
We have proved
the
I The following Theorem 2.
If
theorem asserts the solvability of variational problem 2. the stable functional R satisfies the condition: each {z.)cdomR,
&-I
145
liminf Q(q)-b<= “.-.
and
Proof. If
Put
imply M*a=(zEX:p(A~,
sp=XJIdOm
Da-M,&
further
such
problem
and
~a)
I/J
~.ED+.~+B.
A&,)+p(Acr,.
2 is
Du-MJdom
solvable.
0.
r,&,,,
it
fc:lows
If
n&-Q(zr)
then
I
If
m6RM
then
there
y,)GR’(r,)h%
Pur inf Q(r). -DII
mrbFrom
variational
then
Q
P(AG, Thus
then
Q(r)=+
that
belongs
G
to
exists
X,,=z such
(I.) =DM
a sequence
O
that: (10)
Yn,
lim Q(G) =nitip. m_ D
ges
to
From
(lC),
Since
R,
it is :t
zEQ,.
can
of generality.
loss
Fror
the
On the
that
&.=R.
there
exists
follows
compa:t, Therefcre
it
a subsequence the
From
(lo)-(12:
We
have
implies
to
XI
Since to
Q, f.
converges
is
compact,
As in ? as
to
and
to
p(y.ya)Gr,.
{znlsuchthatitoonvar-
I as
IER,.
to
without
n-m. that
y,=A,r.-A,.z
the
there
proof
cf
of
that
reM,,
tbe
set
ci
?:ecrei-
2,
tte
X .rZ
net
EC!. c=Oiz
exists
Therefcre
zel!,,‘don,
R=D.,
approximate nef
sclutions
cf
equaticn
(1).
B-converges
{X,6, h, 6-O)
to
F’ii. t,>?. tr.c
(I.8
ii. b-0).
Ctvicusly.
Z:E ,Y .dc,n. !!
j
a scbnet i,
Theorerr
!1 21
theore-.
called
I
T,-R’(I.,)h+d).
fc;lows the
estatllsr.
Therefcre
z,=D,t t’h. 6:Oo.
verges
sequence converges
A,. It fc?lows
c;eratcr
proved
SOL is alsc Remark 2. The set TheoreT 3. Under the typcrhese XJldom R as h, 6-O. Proof. By Thecrea 2, we have I,~ beiong
weakly
Lemmas 5, E, it
and
rEX,,+E.
Let
the
itself
we have
hand,
y.,=B,,=(y=)’
consequently
of
sequence
converges
t f the
ccntir,Gitp
weak other
Yr,. c-nix‘).
that
be assurred
(11)
cf
we can
the
assume
net
{I+,(. h. 6-O)
that
the
net
s:cr. itself,
that
it
con-
{I:.:. i.. C-O)
h, 6-O : --r a.c h b-c!
We shall From
show
that
fPX.‘domS!
Q(r,,)Go(r%).
it
fc;lows
tnat lim inf R (r,J h.L-O
From
(13),
On the
(14),
in
other
'i3,
addition
tc
lower
GR(z,). Of the
semi-continuity
+p(A,r.,.
of
side
9.
it
follows
O)GO'(z
yt!-.O!yt.
,jh-Q.cz,,)h-
(15)
converges
to zerc
as
h,
01
6-O.
Thus
ADZ.f---1/‘ as )r. E-O.
From (131, &E-go
proved
;
(161,
in addition
consequently
By Lemma 2, the theorem.
the
that
(151
I I. A,&!)-
+bc2[R'(r!h-6]~-l[o'~.r:)h-
right-hand
functional
we have
hand,
p(A,r.,. yocpr.4
the
(16,
5~X:‘dom
net
to
weak
(16) of
continuity
the
operator
4~.
it
follows
that
Q
{A’,,. h. 6-O)
B-converges
to
X,Odom R
as
h,
b-0.
We have
146
The following
theorem asserts the Under the hypothesis Variational problem 2 is Proof. (Theorem 31, B-converges to X,:dom R Therefore it is sufficient to show that We have ~+,:‘-R(z) Y~eXha. For variational problem 1, there Theorem
4.
kg is empty. Indeed, we assume the to this set. Therefore we have
equivalence of variational problems 1, 2. of Theorem 2, these problems are equivalent. solvable (Theorem 2), further, the net (X,,,h,640) of course, it also converges to X, (Lemma 1). X~I-X~,YA, 6. are
the
following
cases:
(T-min(R(r):p(&,
p&7%+6))
this
means there
contrary;
On the
other
hand,
ZU’ belonging
we have
This is nc,t true. Thus this T>T*r(, then the set
set
We as.sume tne ccntrary, we alsc cbta:r. a similar
is a:sc, empty, Therefore set. We have
yl)
i.e. there exists an element relation to (17).
{T:P@G. y,)~R’(z,~‘)h+6)=(r:p(Ah~. Clearly equal to
inf R(z). _%
is empty.
.4gr(7-min(R(r):p(A,t,
z&e’ belonging
to this
yajG(71r0)%+6).
(18)
on the set defined on the left-hand side of the minimum values of R(t) side of (18) contains the R(rht’) and the set define d on the right-hand
118)
z&X,+.
7=O:r.:‘)
Thus we have 7==7h:0. Let us artitrariiy
take
This &!EX.‘,.
is not Clearly,
true,
Conversely, R(r,+‘) =7nr‘ an:
let
us arbitrarily
choose
consequently
such z,,( alsc
fi,,‘-.irg{7=min(n(l):p(A,I,
this
beiongs
set
is empty,
to the
following
I&?’ belonging
to the
(201,
in addition
if set: (19)
ye)G~‘h+6)). set
(19);
hence,
we have
(20)
P(A.Z”,‘.Y,)G (Thrcj’h-6 from
set
(17)
7-Z!(11~‘)~7~d~-inf{R(t):p(Aht,yd)<~’(~)~+~)-
elements
an element
exists
the
rnc’=Dha.
conseque-tly
are
then
y~)
pu"Ihr'.
If
o<7c7u”.
if
tc 7*cp= min R(rj, *=D1C
it
follows that I.~‘EX,~. Thus XI~‘-X~~. From the above cases, it follows that X,a-X,t Vh. 6. Thus these problems are equivalent. Therefore, the net (X~lb.h. 6-O) We have proved the theorem. ges to X&dom 9. I would like to thank N.M. Chuong for suggesting this problem.
also
conver-
REFERENCES 1. 2. 3. 4.
Tha stability of the discrepancy method when solving ill-posed problems, TANANAV.P., Izv. VUZ. Matematika, 9, 75-60, 1974. TANANAV.P., A projection-iterative algorithm for solving ill-posed problems with an approximately specified operator, Zh. vychisl. Mat. mat. Fiz., 17, 1, 15-23, 1977. A projection-iterative algorithm for operator equations of the first TANANAV.P., Dokl. Akad. Nauk SSSR, 224, 5, 1028-1029, 1975. kind with a perturbed operator, LISKOVETS O.A., The solutlon of equations of the first kind with a closed operator, Dlf.. Urav. 19, 13, 1666-la?:, 1974.
147
9.
The solution of ill-posed problems with a closed operator, Dokl. LISKOVETS O.A., Akad. Nati SSSA, 219, 5, 1069-1071, 1974. The convergence of an approximate method of solving operator equations MOROZOV V.A., of the first kind, Zh. vychisl. Mat. mat. Fiz., 13, 1, 3-17, 1973. An approximate discrepancy method in non-reflexive spaces, Zh. VINCKUPOV V.A., vychisl. Mat. mat. Fiz., 12, 1, 207-212, 1972. A regularizing algorithm for ill-posed LEONOV A.S. and YAGOLA A.G., GONCHARSKII A.V., problems with an approximately specified operator, Zh. vychlsl. Mat. mat. Fiz., 12, 6, 1592-1594, 1972. Variational Methods of Solving Unstable Problems, Nauka 1 Tekhnika, LISKOVETS O.A.,
10.
Minsk, 1981. IVANOV V.K.,
5. 6. 7. 8.
and
its
VASIN V.V. and TANANA V.P.,
Appiications,
ROBERTSONA.P.
11.
Press,
Nauka,
Moscow,
The
Topological
and ROBERTS% W.,
Theory
of
vector
spaces.
Non-Linear
Problems
Cambridge
Univ.,
1964.
LI.S.S.R.Comput.Ma?hs.Math.Phys.,Vcl.2C,rJc.5,pp.147-157,1989 Printed
Ill-Posed
1976.
in
Great
0041-5553189 $10.00+0.00 C 1991 Pergamon Press plc
Eritain
MEAh SQUARE APPROXIMATION OF A RECTANGULAR MATRIX BY MATRICES OF LOWER RANK!' V.A. DAL’SAVETan2 F .V. YAKCVLEV The probiem defined in the title basis of its connection with the
of this paper is examined, on the decompcsitior, problem of Singular In particular, it is proved that the wellof the matrix in question. known group relaxation methcd is convergent given any initial aPpr:xirr,ation, and its rate of convergence is shown tc depend on the relation the correspcnding sir.galar numbers of the matrix. between
Introduction
1.
Let FiM, N] be an artitrarg The probiem of mean sq,uare
1141 / most
r
(the
set
of
all
rectang_;ar approximation
matrices
such
ilM,
matrix and r L 1 a fixed integer. cf F;ti,flj by matrices Z:K; R: ty F,) is as ?cllc*s. ?I':is dencted
r
c,(z~:-~~F-z112-
where product
Z is (RI = r. of twc
a member
of
Our problem matrices of
F,
if
and
or,ly
may therefore lower rank:
if
I.r,
it
be
I m:r.! I#:, ranr: at
(F[i,j]-Z[i.I])‘-min.
).YJ.W A matrix
r ci
be
expressed
reinterpreted
can
as
C,(X. Y) :-IIF-XY’II’
as
Z[M. .v]-X:&f.
follows:
R]x)“[R,
apprcximate
.v].
F by a
+ min.
11.2;
y, Here is
H, the
is
the
sum of
we have yet matrices of
set at
of most
another rank 1:
pairs
of
r matrices
matrices of
interpreta?ion
(X, rank
of
the
YI each
wit?.
r
columns.
Since
the
product
XYT
1,
originai
problem:
approximate
F by a sum of
7 &(T,...., T,):=UF-&Ii’,-I All Incidentally,
these
interpretations (1.2) is a discrete
of
min . (7, 1ImLti <‘I
the problem are useful version o f the problem
be utilized in the sequel. approximating a function of twc
and will of
(1.3)