- Email: [email protected]
The Sturm-Liouville difference problem for a fourth order equation with discontinuous coefficients
TBE STURM-LIOUVILLEDIFFERENCE PROBLEM FOR A FOURTH ORDER EQUATION WITH DISCONTINUOUSCOEFFICIENTS' KIM0 6800 (Yoscon) (Received
20 October
19621
In this paper we use the methods developed by AN. Tikhonov and A.A. Samarskii (see [ll. [21) to study the Stum-Liouville difference problem for a differential equation with discontinuous coefficients: L(Jw.q.WU =L(k.m)
LW.rMu
=
u -
Sr (2) u = 0,
gb[k(4 $$I-& [p(2) $I+ q(4 I&.
To solve this problem we use the homogeneous differeme
schemes (see
[31) Lf.mz.W
y = LFpeq)y -
l% (2) y,
We shall give the argument below for the boundary conditions u (0) = a’(0) = u (1) = u’(i) = 0. The results obtained for these bouudary .conditions csu be used without essential alteration for the class of boundary value problems with other bouudarJ conditions (see 131). We shall prove that any homogeneous difference scheme of second rauh which satisfies the necessary conditions for second order approximation has second order accuracy in the class of smooth coefflcieuts aud first order accuracy iu the class of discontinuous coefficients. The difference
’
Zh.
vych.
mot.
3,
No. 6,
1014-1031, 1363
1963.
1384
Kh tto Shou
scheme with the coefficients 1 c1=
+ \,:,_I,ds]-1, b =
[S&&s 0
0
‘8
d =
5p(x + sh)&
-1
%
I?=
g(x+Wds,
f
%
s %
r (5 + sh) ds
has second order accuracy in the class of discontinuous coefficients.
1. Statement of the Stnrm-Lionville 1. The Stura-Liaville
problem
for
a differential
We consider the homogeueous differential ~(k.v,q.ar)u
=
p.P.a)
difference
24 -
problem
equation
equation
hr(x)u
= 0,
o
with homogeneous boundary conditions u (0) = u’(0) = 2.5(1) = u’(l) = 0.
(2)
The Stuns-Liouville problem for the differential equation (1) with boundary conditions (2) consists in finding those values of the parameter h (eigenvaluesf to which there correspond non-trivial solutions (eigenfunctions) of the problem (l)a(2) and also in finding the eig~f~ctions of this problem. We shall assume that the coefficients conditions
in equation (1) SatiSfY the
where Cja j = 1, 2, 3, 4, 5, 6 are certain positive
constants.
Whenthe coefficients k(x), p(x) of equation (11 have discontinuities of the first kind at certain points of the interval 0 < x < 1, as we s8w in k3], the solutions of the Sty-Liouville problem must satisfy the coupling conditions
difference
The Sturn-Liouville
ful = 0,
lu’f = 0,
where 5 is a point of discontinuity (1). We shall call (1%.
2.
Equivalence
pu’l = 0
[(ku”)’ -
[ku”] = 0,
1385
problem
of the coefficients
the problem defined by conditions
of the &urn-Liouville
problem
for
2 =
E.
(4)
k, p of equation
(l)-(4)
the problem
and an integral
equation We consider Green’s function G(x, g) of the operator L(k*peq) for the boundary conditions (2). The definition
of Green*s, function for the case
be extended with some alteration When
k,
p,
q EQ’O)
to the case
k,
p,
k,
p,
q E
q E
C(a)
can
Qfm).
Green’s function is defined from the conditions:
1) the functions Gk 5) and GL (2, f), in the square 0
k (z) G& (5, E) are continuous
2) for 0 < x < S and 5 < x < I the function G(x, g) satisfies homogeneous equation
the
t(kz’.q) c -_ 0 and the coupling conditions; 3) for any values of E from the interval satisfies the boundary conditions G (0,E) = G; (0, E) =
G (5, El =
4) on the diagonal of the rectangle in (kG&
For
k,
-
pG;
p,
q E
[O, 11 the function G(x, 0
G’*: ($1&) = 0;
there is a sudden discontinuity
defined by the condition
Q(O)
Green’s function G(r, Q has the following
form
1386
Khao Shou
where Vi, j = 1, 2, 3, 4 are solutions #h+,,j satisfying
the coupling conditions
of the homogeneous equation = 0,
and the conditions
01(O) = 0,
0s (0) = 0,
f)a (1) = 0,
04 (1) = 0,
sr; (0) = 0,
0; (0) = 0,
0; (i) = 0,
0; (1) = 0,
(b;),
= 4,
(G),
= 0,
(G),
(b;),
(k?& = 0,
(k&
= i,
(kz& = 0,
= 1,
= 0,
(kv;); = -
1.
If p(x) = q(x) f 0 then all the solutions Vi, and therefore Green’ s function g(x, cl, can be calculated with the help of quadratures. Then Vj has the folloWing form: xz !! .
It 1s not difficult to see that problm homogeneous integral equation
(1% is equivalent to the
(6)
The Sturn-Liouvi
3.
equivalence of the Sturr-Liouvil variational problem
The
The Sturm-Liouville ational problem: 1) in the class of
1 le difference
functions
0,
problm
q” @‘“‘)
le problem
and a
(I&) is equivalent
of comparison
functions
satisfying
1387
problem
to the following
cp E g(*) (Q‘“’
vari-
is the class
the condition
1
bpl = s r(z)(p’(z)dz=
H
1,
cp(0) = qyo; = cp(1) = (p’(i) = 0, to find
the minimum of the functional D
bpl = Sk [cp”l’dx + j p [tp’l* dx + i qcp¶dx. 0
This
minimum defines
the first
eigenvalue:
Al = min D [VI = 2) the
other
eigenvalues
A,,
(7)
0
0
D [z+];
n > 1 are found as the minimum of
functional (‘0 in the class of comparison ing the supplementary conditions
functions
cp E Q(*)
the
satisfy-
1 H
[ql = i,
Ii lq, 4
=
cp (0) = q’(O) = &)
s
qw,,r dx = 0 for
m
= q’(1) = 0,
where uI is the m-th eigenfunction. This minimum defines
the n-th L=
4. Basic
properties
eigeavalue:
miu D Icpl = D [u,,].
of eigenfwactions
and eigenvalues
Let us give some of the basic properties values of the Sturm-Liouville problem (1% efficients
k E
Q(O), p E
Q(O), q E
Q@), r e
of eigenfunctfons and eigenfor piece-rise continuous coQ(O) (see
[41).
Khao Shou
1. There exists
a countable set of eigenvalues
to which the eigenfunctions
correspond. The eigenvalues have multiplicity not greater than two. For, as is easily seen, there exist not more than two linearly independent solutions of equation (1) for which u(0) = u’ (0) = 0. 2. All the eigenvalues are positive:
n = 1,‘2,3, . . * ,
h,>o*
3. For the eigenvalues h, we have the following 4
Q L < can’,
n=i,2,.
estimate: . . ,
where cr and ca are positive
constants which do not depend on n.
4. All the eigenfunctions with weight r(x):
un form an orthogonal system normalised
5. We have the estimates [ &lb)
b <
wz,
&wjo
for the eigenfnnctions not depend on n.
iph)~
u,, and their derivatives,
5. The Sturm-Liouvil le difference To solve the Sturm-Liouville ence scheme (see E31): (k.P. 9. W y = QPJ+/ r, where Lh(k*pDq)y =
where Ml, & and hfa do
problem
problem (IhI we use the following -
(uy;Ltp
&&
-
h
dy.
differ-
The
Sturn-Liouvi
lfe
difference
1389
problem
By analogy with [31 we shall assume everywhere that
Lj,*J’*e*&)is a
homogeneous conservative scheme of standard type. Its coefficients a(x), b(x), d(x) and e(r) are defined with the help of pattern functionals defined in the class Q(O).
by
Ah Irp (41,
--1BsQi,
Bh [cp (41,
--I<864
@
19 (41,
-+<3<+,
I?
I9 601,
-f
the formulae
ft follows
a = A’kPh’ = Ah [it (s)],
L’ (s) = k (5 + Sk),
b = B’“*h, = Bh [p (s) 1)
P (4 = p (z + sh),
a’= D’O*h’= r>h [(l ($)I,
as>
e=
T (4 = r (5 + sh).
IP)
= If [r (s)],
from the fact that k, p,
06 b6
= Q (5: -I- W,
q and r are bounded that
0 6 d6 c,,
Ctc
As the initial class of difference schemes of zero rank.
0 < ci 6 e < c8.
schemes L~k~p~q~Xy) we shall take
Now let us go on to formulate the Sturm-Liouville
difference
problem:
to find those values of the parameter Ah (difference eigenvalues) for which there exist non-trivial solutions (difference eigenfunctlons) of the holaogeneous difference equation h
with homogeneous difference
boundary conditions
0,
yl=
Yx.0
h -2
Yxx.0
(8)
r=
0,
and also to find the difference We shall call the difference Liouville problem (11 $.
Y&ml=
0,
Y;,N+~Y~,N=OR
(9) (W
eigenf~~tio~s,
problem defined by (8)-(10)
Here we use (9) and (101 Instead of the natural difference
the Sturmanalogues
1390
Khao Shou
of the boundary operators (see E31)
6. Equivalence on intcgrat
of the &urn-Liouvilk equation
difference
problem
and
Using Green’s difference formula (see [3’I) we can easily see that the Stun-Liouville difference problem (II?9 is epuivalent to the solution of the difference snalogue of the integral equation Y = I h CC@? ey)),
which, with the help of the substitution cp (4 = m;Y
(r)*
reduces to the difference
p
integral
(29 E) = Ve (4 e (E) @ (r, E) equation
9 = khCC with symmetric “kernel”
Kh(z, E), where c” (5, g)
ence function of the operator
7.
Equivalence
variational
911
ak* ” *’
of the Sturdiouville problem
is the Green differ-
with conditions
problem
(9) snd (IO).
und a difference
Using Green’8 difference formula by analogy with Section 2 it is not difficult to see that the Sturm-Liouville dffference problem (IfA) is equivalent to the following difference variational problem: 1) in the class of net comnarison functions q satisfying tions HN
iv]
‘PI = Q,*.a-2
h
=
((ee, q”))
0,
9 ax.0 = 0,
=
1, 0,
(P&I=
e)jiJv+
-+(pTd;,N = ‘*
to find the minimumof the fuuctional
this minims defines the first
difference
eigenvalue
the condi-
difference
The Stun-Liouvillc
1391
probler
2) the other difference eigenvalues h:~ n > 1 are found as the minimumof the functional 11) in the class of net functions q~satisfying the supplementary conditions
HN bpl = 1,
BN $=
P r,o-2 where
ya
is
the
n-th difference
h
= 0,
cpa.0
m-th difference eigenvalue c=
8. Properties
[qb y,,,] = ((e%y,,# = 0, TN-1 = 0,
eigenfunction;
eigenvalues
and difference
n=1,2
,...,
3. All the difference eigenfunctlons normalised with weight e(x) 1 HNIy,.Y~l={O
Iar,Oo
eigcnfunctions
eigenvalues with corre-
eigenvalues are positive:
C>o,
4. If k, p, q, r E
this minimumdefines the
min &I [VI = &V [y,,].
of difference
All the difference
%
~,N+‘+~&,N=O’
1. For each N there exist N - 4 difference sponding eigenfunctlons
2.
o for m <
yn
N-4.
form an orthogonal system
for m-n, form#n.
Q(O) then we have the estimates II b&II
o<
M* OF*
II b/n)&
< M,
(&“a,
W
for the difference eigenfunctions yn and their difference derivatives, where Ml, MS, and Ma are certain positive constants which do not depend on the step h or the number n. For let x and x’ be any two points of the net Oh. We have
1392
Khao
Y2(4 - Yaw
[a(4 y;;x(412 -
= ad+h i
b(~‘)YT&wla =
Shou
h [Y (4 + i
Y;
(4,
h [~(S)y~~(S)+~(s-h)y~(S-h)lX
[a(4 y&)1;.
From the normalisation condition fore
(s - hII
d+h
x there exists
Y
HN [y, yl = 1 it follows that
at least one point x’ at which e (s’) y2 (cc’) <
1
and there-
yB (5’) < l/c,.
Further, it follows from the boundary conditions
Y&J =
YX,6 +
that
fihhY&(S) =-&(h) + 5hhy&(s).
s=h
r=h
Then using the Cauchy-Bunyakovskii inequality
we obtain
and therefore
IIY,
no < M, (W’*,
0(YJ;IIo < M, (W.
We can put the solution of the problem (IIA) in the form Y (4
=
y (3h) +
y,- (3h) +
+dlxgh
i
_
h
m=ah
m-h
=(m+h)
+d2=sh
i h _,, _+,
1
=(m+Wr
where dl and d2 are determined from the boundary conditions yN_1 = 0, It
is
not difficult
y;, N + +y;;.N
to see that d/ = 0 (Ah),
It follows
=o.
i = 1.2.
from equation (8) that
[a (4 YG WI,-
= b (4 Y,-(4 + i
h I-
d (4 y (4 + hhe (4 y (4
1 + d,
The Sture-Liouville
difference
problcr
1393
and therefore
Since
we obtain
and therefore
2. Convergence of the nolution of the Sturu-Liourillc difference problem In the
work 111 it
tion
that
(II)
converge’to
Liouville
for
(1)
theorem using
epuaproblem
of the initial
of discontinuous
convergence
differential
of the difference
and eigenf~ctions
in the class
8n analogous
a second order
8nd eigenf~ctions
the eigenvalues
problem
we prove
~8s proved
the eigenvalues
coefficients.
the method given
StuwHere in
El].
We omit the proof. We first
consider
Let y = ytx, fWiCtiOn81
DN
the case of the first
hf be the net function
with
the nowslisstion functions
values
which realises
(n = 1). the minimum of
the
[q] x” =
net
eigenvalue
{y(z,
condition
h))
DN
[j/l
HJV [y] =
i.
Consider
and the corresponding
the sequence of
sequence of
first
{Ah? on some sequence of nets.
Lemma 2, For each
positive
E there
??<&$-a where h is the first
eigenvalue
exists
an ho such that
for h
(1%.
eigen-
1394
Proof.
Khoo Shou
Let u’(z)
be some function of G(2) for which J#== i*
and let
From Leppraa 1 we have
for A
a* (A) < a + s Therefore,
from the principle
of the minimumof a functional
kh
h
+ s,
Lemma3. The sequences of functions equicontinuous and bounded.
we have
{y (z, A)} and (y; (2, A))
are
For if x4 and x **are any two points of the net Oh then 9
Using the estimates (12) we find from Lemma2 that {y(x, continuous: I y W,
where M is some positive
h) -
y (s’, W I < M 1 2” -
A)) is equi-
5’ 1,
constant which does not depend on h.
From the normalisation condition at one point x = x’ the inequality
HN [yl = 1 it follows that at least
y (z’, h) G---L v C6 holds. It follows bounded:
from (13) that the sequence {y(x,
1 Y (G h) I <
Similarly
I Y (~3 h) -
Y (2’9 h) I +
/I)) is uniformly
I y W, h) I < M.
we can Prove that {y,-(s, A)} is equicontinuous and bounded.
It follows from the Arzela theorem that there exists some sub-sequence (Y (5, hk)) which converges uniformly to some function G(r) continuous on the segment [O, 11:
0Yt5, hk)
-
G (2) no =
P @kh
where p(hk) +O We shall
as hk-
assume that
{hhk = h (hk)}
difference
Sturn-Liouvillc
The
0.
the
converges
1395
problem
sequence {hk? is such that the sequence
to sooie limit
[ll)
“h (see
lim 1 (hk) = x, hk+Q
the sequence
and
converges uniformly to some function w(x).
(y,-(z,hk)}
Lemna 4. If for some sequence {hk)
1Y,-(2, k) -
‘;; (5) tb = P (hk),
1 Y (G hd -
W (z) g= P (hk),
then ;fi (z) = tD(z). We omit the proof. Lemma 5. If for some sequence {hk)
lim 1 (hk) = x, hk-“’
then
We omit the proof (see [ll). Lemma6. Let gh (z, E) be the Green difference ator
ak’ y = (a&);,
for the boundary conditions
gtx,
function of the oper-
(2).
If
kE
(9) and (lo), operator
Q(O) and the difference
= (ku’)
scheme
has zero rank ilghtt, E) -
g (z, E)ib = P (h),
@(z,
E) -+g
(2, E)C = P (h).
To prove this it is sufficient to note that the functions and v(j)(x) in the expressions of the Green functions g(x, cl and
Proof.
vi(x)
and let
L”‘u
gh(x,
form:
cz
Vl(4
=
k+ ss
ddz,
11
cl
(4 =
zz va (;st-
Adz, o 1so k (0
&jdtdz, ss
XL
00
11
v4 (4 =
ss xz
$$
dtdz;
1396
Khao Shou
We nor consider the equation Y =
W’,, - dy +
Jh)).
(14)
Using the Green formula we cau reduce equation (14) to the equation Y = -
((b,$?I<,+ w9
ve- 4 Yh
where gh(x, Q is the Green difference function of the operator LAk) with conditions (9) and (101. Passing to the limit we obtain 1
L(2) = -
1p (8 g; (2. 8 2 (6)dE+ 5g(5, El iiir(E)0
where g(x,
q (EJI ii tE) d&v (15)
0
Q is the Green function of the operator
(ku”)”
tion (2). It follows that the solution ii(x) of the integral (15) satisfies the differential equation L”.
P. u) ;
-Xr
for condiequation
(z)iY=O
and the boundary conditions E (0) = s (0) = L(1) = 2 (1) = 0. Since A = hl is the least eigenvalue of the problem (IA) and “h < A we have i = A. Because of the multiplicity following lenma.
of difference
eigenvalues we have the
The Sturn-Liouvillt
difference
probltr
139’7
Lemma 6. The difference eigenvalue Ah has multiplicity than the multiplicity of the corresponding eigenvalue A.
for
not greater
Proof. We shall prove the lemma by assuming the contrary. Suppose, example, that h is a simple eigenvalue and that hh is a double eigen-
value of the “kernel” G”(5, t). Let i (5, h) and y (2, h) be orthogonal and normalised eigenfunctions belonging to the eigenvalue Ah. As we have shown there
exists
{hk)
a sequence
sponding sequence {g (x, hk)} converges ul(x) belonging to the eigenvalue A: II i (xv hd -
uniformly
such that
the corre-
to the elgenfunction
~1 (4 jio = P (hk)
and
lim X (hk)
=
x
=
&.
hk*
We shall
assume that
the sequence 19 (G hk) -
{hh)
is
such
that
the equation
% (2) gb = P (hk)
holds.
tion
If not we could pick cut a sub-sequence and restrict our considerato only those suffixes k which corresponded to this sequence. We will
then have
and therefore
11 l-3h@ (X) p
(2, hk);
-*. but this
contradicts
(X&k)-‘2 hfl (‘) “f b) II,=
P thkh
-k
the limit
equation
In exactly the s&a8 nay It can be proved that when h is a double eigenvalue the difference eigenvalue hh has multiplicity not greater two.
than
1398
Khao Shou
Lemma7. The difference eigenvalue Ah has multiplicity the multiplicity of the corresponding eigenvalue A. To prove this it is sufficient form an orthogonal system
to note-that
H [unt 4
The following Theorem
of
u(x)
eigenvalue Al.
to the other eigenvalues A,h, n > 1.
theorem is a consequence of the above argument. If the difference
Convergence.
rank, the solution of nets as h -
the eigenfunctions
n+m.
= 0,
The reasoning above applied to the first It is also applicable
not less than
scileme
L~kvP~q*Ar) has zero
(c, y,,j of problem (IIA) converges on auy sequence
0 to the corresponding solution 11I:--&,=p(h),
for any coefficients
u, IJo= P (4
IIl/n -
k, p, q, r E
(A,,, u,,) of problem (1%:
Q(O).
3. On the accuracy of the solntions of the Sturr4.ionville difference problem I.
The equation
for
the error
Let (Ah, y) be a solution (A, IL) be the corresponding problem (I’). The error z = w.r. t. the solution u(x) of
of an eigenfunction
of the difference problem (11% and let solution of the initial Sturm-Liouville y - u of the solution y(x) of problem (IIh) problem (1% satisfies the conditions W.P>~.W~ = y
Lh q
=
f
VI,
VT&-l =
(W
(47)
p1
(W where Y = $ + (A” I# ---
h) eu,
[(Id)” - (au;;), 1 - [(pu’)’ - (~~;),I + (q - 4 u + h (e - 4 u9 (1% p1 = - u (1 - h), VI = - u (h), h 3
=
-
ux.0 -
2
uu,o
,
IL2=-
UG,N
+$uz,,}.
The Stura-Liouvi
We call
Zle
di,fference
the problem defined by (W-(18)
2. Formula for
the error
1399
problem
problem (111%.
AA = hh - A.
since the parameter hh is an eigenvalue of problem (II’) the difference problem (IIIh) is soluble only when the following equation holds:
From (19) and (20) we obtain a formula for the error Ah = hh - A: W, $4) -t V -f+{-+
i
-
-$-
A) ((eu+ YH + -$ h ~~~~~~+UN-~~N-~~~ alp,
i
&%-&N-2
(Za, -b
+
2al
@aN-%
+
i-
PbJ
2aN+
+
Y% -
function
jj = Cy
w&B
hbN-2)
As in the work iJ.1 we choose a multiplier
-I-
)
%
f
YN-% -
pl
=
0.
C in such a nay that the
is orthogonal to the difference
2 = y--
u:
((6, +,, = 0. We then obtain a formula for estimating the error Ah = hh - h:
aud a formula for estimating c2 -
f C- -
1 = (@b z’>>+
1 1: (HN iuf
-
H !ul),
where cz41
as h-0.
Introducing the function q(xt with the help of the conditions tt;,=g**
ql=rit.l=o
and then using Green’ s formula we find that for k, p, q, r E c’( 2 * I)
(211
1400
Khoo
Shou
where
I#@)= ku” q,’ = (q -
IIS’ II*=
q(b) = bu, -
ataG,
4 u + A (e - r) u + q (2) =
II71b + h I rl(1 - 4
$,
0 (W,
5 h i hqqz”), i=lh z&ah
pu’ ,= (pu’) l p;, This gives
the following
lemas
Lemma8. If y(x) has the form
then
IAll=
iA”- 1 I < M (9 Illlva) ll, + lwb) III + IIlb*lls+ I Vl +
I3
I+
IIL1
I+
I + I PaII,
and hma
9. If y(x) has the form
at all points &+s, then
of the net q, Wart from the points
AX 1 < M @I #i’,‘“’ II; f
+h*
n+S 7A Iel+q
8-n-l
IWb)II;+ US’a;+ l#$_, I + I$$,+,l + z
w-3--s)*,I+hl
l-n-1
grp./+ r-n-1
+
where
x = xn+, G, til,
I Yl
I + I VI I +
IIL1 I
+ I CL%’ IL
The
3.
A
priori
Sturw-Liouville
difference
1401
problcn
estimates
By analogy with [I] we estimate the error z = y - u. We first the problem (IIIA) to the analogue of the integral equation z = h” ((Ch, ei)) +
reduce
((Gh, !I!)) + [p,(t~(-l)G-,-)~a(-lfG~p,l~ -
(22) - [vl(d+')Gk)r - a(+'~Gh,v,l,-, - bi+IpIG;,N_I + b,~,Gh*,~,
where G%x, @ is the difference function of the operator the boundary conditions (9) and (10). The eigenfunction tion
T of problem (IIA) satisfies
Lik*p* 9) for
the “integral’
epua-
i = Ah((Gh, &)), which, with the help of the substitution Kh (5, E) = I/e (4 e (F;) G” (JG EL reduces to the difference
“integral”
with symmetric “kernel” Khfx, @;
elation
and with the help of the substitution
Kh(5, E) = v’e(4 e (%)Gh(2, %I,
--
v (4 = Ve h-42 (4
equation fZZt reduces to the equation E,= hh ((P,
v)) + f,
(231
where
Equation (23) is soluble and so we shall have au o~hogonality tion for the solution rg(x) and the right-hand side f: W
condi-
f)) = 0.
Now let us go on to construct the resolvant
R of the “kernel” Kh(x,Q
ilhao Shou
through
which the solution WV(X)of equation (23) can be expressed
by
formula Q= f + W
01.
It follows from the conditions that
t(G* 3, = 0,
ml m = 0
The resolvant R is found from the equation
and can be written in the
form (see El])
R = K, + R,, where
and the sm is taken over all qpkwith the exception of those to which the eigenvalue %,hcorresponds. Be have the following
estimate (see
[II ):
From this we obtain
Themera 1. Let yn(r) be the n-th normalised eigenfunction of the difference problem (IIA) and let u,(z) be the n-th normalised eigenfunction of the problem CIA. If y(x) has the form
the
The
Sturm-Liouuillc
difference
problem
i4nn
then
where M(A) is some positive Proof.
constant which does not depend on
h.
We consider
f = ((fYh, Fj) -!- (A” -
A)) ((Kh, fi
+ J& { (pL1(a(-l)G&
-
u)) +
a(-l)G~q,I~ -
Iv1 (a(+l)G$), -
a(+W&v210} -
- 1/- eh-rCrlG$,,,
-
b~G~,dy
where I=
--L-Y. I/c
Introducing the function q(x) with the help of the conditions q& = \p’*
rll =
rlr.1 = 0
we have
II4 G df (V W”’ IL + IIWb)III + IIS’ Ila+ I Vl I + I v2
I+
IPl I +
I P2 I>*
Using (21) and !Z=
y---u=- ;
++z,
we obtain (24). Theorem 2. Let y,(x) be the n-th normalised eigenfunction of the difference problem (11% and let u,(x) be the n-th normalised eigenfunction of the problem (IA). If Y(X) has the form ‘Ip = 9::
-f- Sib’ -!- 9’
at all points of the net
1404
Khao Shou
of
4. The order
accuracy
of
in the class
smooth coefficients
from Theorems 1 and 2 that the order of accuracy ot the solution of the Sturm-Liouville difference problem WA) depends on the approximation error of the difference scheme y and also on the approximation error of the normalising functional HN, i.e. on the quantity It
is clear
X = HN [ul -
H [u].
In order to study the question of the accuracy of tile solution problem (IIh)
it is sufficient
to estimate
We shall prove the following
of
/I$@)l/r, llp(b)j/l, 11 $*]I, and x.
theorem.
Theorem 3. If the difference scheme ~~~‘p~q,~r’ of second rank satisfies the necessary conditions for second order approximation, then the solution r E
(G, &,)
C( 2 * ‘)
of the difference
problem (IIA) in the class k, p, q,
has second order accuracy,
I 1Lt:-
5
I<
M &J
h2,
where M&J is some positive
i. e.
II yn (4 -
un (4 lb <
&if (W h2,
constant which does not depend on h.
Proof. Carrying out the seme reasoning as in the proof of Theorem 3 in 131 we obtain
gcar = ku” -
au- = xx
0
(h2),
+a) = bn, -
AS we have shown the difference order approximation:
v1 = 0 (h%), It is not difficult k, P, Q,
F E
c’2n”
y1 = 0 (P),
operators
ptr’ = 0 (h2),
$,’ = 0 (h”).
(9) and (10) have second
l.~ = 0 (ha),
pS = 0 (h2).
to see that the normalising function N,,, for h&M
S econd
order approximation w.r. t. h (see
~11~:
7he
.5. The order
Starm-liouo~lle
of accuracy
in the class
difference
problem
of discontinuous
14(25
coefficients
In this section we discuss tne auestion of the accuracy of the solution of the Sturm-Liouvifle difference prObleM UIh) in the class of disconti~uo~~scoefficients Qini). To avoid complicating the explanation we assume that the coefficients of equation (1) have the same point of discontinuity: E = xn -!-oh, 0 < 8 < 1. We note that for a second rank scheme satisfying the necessary conditions for second order approximation in the class k, p, q, r E fy2,” n-a
h2 2
n+2 (n -i-3 -
sf $1 = 0 (h),
ain-1
k
2
** = 0 (k);
m-1
for the scheme Lik*p’Q*“” with coefficients
(25)
cm (271
w3)
in the class k, p, q, r E
n+z
Q(‘*‘)
n+e
n+a
This gives the following theorem. Theorem 4.
Any difference scheme
L~kip*q*x” of second rank satisfying
1408
Khao
Shou
the necessary conditions for second order approximation has in the class first order accuracy: k, p, (I, r E P*l)
and the difference scheme with coefficients accuracy in the class k, p, q, r E Q’ ’ * I’:
where U(h,) is some positive
(25)-(28)
gives second order
constant which does not depend on h.
In conclusion, I express my sincere gratitude to A.A. Ssmarskii for his valuable advice and help in the completion of this work, and also to A.N. Tikhonov for his interest in it.
REF'ERENCES 1.
TI~ONOV, A.N. and SAMARSKII, 805, 1981,
2.
SAMARSKII, A.A.. 2%. wych. Rat., 1. No. 6. 972-1000, 1961.
3.
KHAO SHOU, Zh.
4.
COURANT. R. and HILEERT, D., Metody
vych.
mat.,
of Mathematical Physics), dat. 1951.
A.A.
t
Zh.
uycft.
aat.,
I.
No,
5. 784-
3, No. 5, 841-860, 1963.
Vol.
aatcnatichaskoi
fiziki
(Methods
1. Moscow and Leningrad, Gostekhiz-
20 October
19621
In this paper we use the methods developed by AN. Tikhonov and A.A. Samarskii (see [ll. [21) to study the Stum-Liouville difference problem for a differential equation with discontinuous coefficients: L(Jw.q.WU =L(k.m)
LW.rMu
=
u -
Sr (2) u = 0,
gb[k(4 $$I-& [p(2) $I+ q(4 I&.
To solve this problem we use the homogeneous differeme
schemes (see
[31) Lf.mz.W
y = LFpeq)y -
l% (2) y,
We shall give the argument below for the boundary conditions u (0) = a’(0) = u (1) = u’(i) = 0. The results obtained for these bouudary .conditions csu be used without essential alteration for the class of boundary value problems with other bouudarJ conditions (see 131). We shall prove that any homogeneous difference scheme of second rauh which satisfies the necessary conditions for second order approximation has second order accuracy in the class of smooth coefflcieuts aud first order accuracy iu the class of discontinuous coefficients. The difference
’
Zh.
vych.
mot.
3,
No. 6,
1014-1031, 1363
1963.
1384
Kh tto Shou
scheme with the coefficients 1 c1=
+ \,:,_I,ds]-1, b =
[S&&s 0
0
‘8
d =
5p(x + sh)&
-1
%
I?=
g(x+Wds,
f
%
s %
r (5 + sh) ds
has second order accuracy in the class of discontinuous coefficients.
1. Statement of the Stnrm-Lionville 1. The Stura-Liaville
problem
for
a differential
We consider the homogeueous differential ~(k.v,q.ar)u
=
p.P.a)
difference
24 -
problem
equation
equation
hr(x)u
= 0,
o
with homogeneous boundary conditions u (0) = u’(0) = 2.5(1) = u’(l) = 0.
(2)
The Stuns-Liouville problem for the differential equation (1) with boundary conditions (2) consists in finding those values of the parameter h (eigenvaluesf to which there correspond non-trivial solutions (eigenfunctions) of the problem (l)a(2) and also in finding the eig~f~ctions of this problem. We shall assume that the coefficients conditions
in equation (1) SatiSfY the
where Cja j = 1, 2, 3, 4, 5, 6 are certain positive
constants.
Whenthe coefficients k(x), p(x) of equation (11 have discontinuities of the first kind at certain points of the interval 0 < x < 1, as we s8w in k3], the solutions of the Sty-Liouville problem must satisfy the coupling conditions
difference
The Sturn-Liouville
ful = 0,
lu’f = 0,
where 5 is a point of discontinuity (1). We shall call (1%.
2.
Equivalence
pu’l = 0
[(ku”)’ -
[ku”] = 0,
1385
problem
of the coefficients
the problem defined by conditions
of the &urn-Liouville
problem
for
2 =
E.
(4)
k, p of equation
(l)-(4)
the problem
and an integral
equation We consider Green’s function G(x, g) of the operator L(k*peq) for the boundary conditions (2). The definition
of Green*s, function for the case
be extended with some alteration When
k,
p,
q EQ’O)
to the case
k,
p,
k,
p,
q E
q E
C(a)
can
Qfm).
Green’s function is defined from the conditions:
1) the functions Gk 5) and GL (2, f), in the square 0
k (z) G& (5, E) are continuous
2) for 0 < x < S and 5 < x < I the function G(x, g) satisfies homogeneous equation
the
t(kz’.q) c -_ 0 and the coupling conditions; 3) for any values of E from the interval satisfies the boundary conditions G (0,E) = G; (0, E) =
G (5, El =
4) on the diagonal of the rectangle in (kG&
For
k,
-
pG;
p,
q E
[O, 11 the function G(x, 0
G’*: ($1&) = 0;
there is a sudden discontinuity
defined by the condition
Q(O)
Green’s function G(r, Q has the following
form
1386
Khao Shou
where Vi, j = 1, 2, 3, 4 are solutions #h+,,j satisfying
the coupling conditions
of the homogeneous equation = 0,
and the conditions
01(O) = 0,
0s (0) = 0,
f)a (1) = 0,
04 (1) = 0,
sr; (0) = 0,
0; (0) = 0,
0; (i) = 0,
0; (1) = 0,
(b;),
= 4,
(G),
= 0,
(G),
(b;),
(k?& = 0,
(k&
= i,
(kz& = 0,
= 1,
= 0,
(kv;); = -
1.
If p(x) = q(x) f 0 then all the solutions Vi, and therefore Green’ s function g(x, cl, can be calculated with the help of quadratures. Then Vj has the folloWing form: xz !! .
It 1s not difficult to see that problm homogeneous integral equation
(1% is equivalent to the
(6)
The Sturn-Liouvi
3.
equivalence of the Sturr-Liouvil variational problem
The
The Sturm-Liouville ational problem: 1) in the class of
1 le difference
functions
0,
problm
q” @‘“‘)
le problem
and a
(I&) is equivalent
of comparison
functions
satisfying
1387
problem
to the following
cp E g(*) (Q‘“’
vari-
is the class
the condition
1
bpl = s r(z)(p’(z)dz=
H
1,
cp(0) = qyo; = cp(1) = (p’(i) = 0, to find
the minimum of the functional D
bpl = Sk [cp”l’dx + j p [tp’l* dx + i qcp¶dx. 0
This
minimum defines
the first
eigenvalue:
Al = min D [VI = 2) the
other
eigenvalues
A,,
(7)
0
0
D [z+];
n > 1 are found as the minimum of
functional (‘0 in the class of comparison ing the supplementary conditions
functions
cp E Q(*)
the
satisfy-
1 H
[ql = i,
Ii lq, 4
=
cp (0) = q’(O) = &)
s
qw,,r dx = 0 for
m
= q’(1) = 0,
where uI is the m-th eigenfunction. This minimum defines
the n-th L=
4. Basic
properties
eigeavalue:
miu D Icpl = D [u,,].
of eigenfwactions
and eigenvalues
Let us give some of the basic properties values of the Sturm-Liouville problem (1% efficients
k E
Q(O), p E
Q(O), q E
Q@), r e
of eigenfunctfons and eigenfor piece-rise continuous coQ(O) (see
[41).
Khao Shou
1. There exists
a countable set of eigenvalues
to which the eigenfunctions
correspond. The eigenvalues have multiplicity not greater than two. For, as is easily seen, there exist not more than two linearly independent solutions of equation (1) for which u(0) = u’ (0) = 0. 2. All the eigenvalues are positive:
n = 1,‘2,3, . . * ,
h,>o*
3. For the eigenvalues h, we have the following 4
Q L < can’,
n=i,2,.
estimate: . . ,
where cr and ca are positive
constants which do not depend on n.
4. All the eigenfunctions with weight r(x):
un form an orthogonal system normalised
5. We have the estimates [ &lb)
b <
wz,
&wjo
for the eigenfnnctions not depend on n.
iph)~
u,, and their derivatives,
5. The Sturm-Liouvil le difference To solve the Sturm-Liouville ence scheme (see E31): (k.P. 9. W y = QPJ+/ r, where Lh(k*pDq)y =
where Ml, & and hfa do
problem
problem (IhI we use the following -
(uy;Ltp
&&
-
h
dy.
differ-
The
Sturn-Liouvi
lfe
difference
1389
problem
By analogy with [31 we shall assume everywhere that
Lj,*J’*e*&)is a
homogeneous conservative scheme of standard type. Its coefficients a(x), b(x), d(x) and e(r) are defined with the help of pattern functionals defined in the class Q(O).
by
Ah Irp (41,
--1BsQi,
Bh [cp (41,
--I<864
@
19 (41,
-+<3<+,
I?
I9 601,
-f
the formulae
ft follows
a = A’kPh’ = Ah [it (s)],
L’ (s) = k (5 + Sk),
b = B’“*h, = Bh [p (s) 1)
P (4 = p (z + sh),
a’= D’O*h’= r>h [(l ($)I,
as>
e=
T (4 = r (5 + sh).
IP)
= If [r (s)],
from the fact that k, p,
06 b6
= Q (5: -I- W,
q and r are bounded that
0 6 d6 c,,
Ctc
As the initial class of difference schemes of zero rank.
0 < ci 6 e < c8.
schemes L~k~p~q~Xy) we shall take
Now let us go on to formulate the Sturm-Liouville
difference
problem:
to find those values of the parameter Ah (difference eigenvalues) for which there exist non-trivial solutions (difference eigenfunctlons) of the holaogeneous difference equation h
with homogeneous difference
boundary conditions
0,
yl=
Yx.0
h -2
Yxx.0
(8)
r=
0,
and also to find the difference We shall call the difference Liouville problem (11 $.
Y&ml=
0,
Y;,N+~Y~,N=OR
(9) (W
eigenf~~tio~s,
problem defined by (8)-(10)
Here we use (9) and (101 Instead of the natural difference
the Sturmanalogues
1390
Khao Shou
of the boundary operators (see E31)
6. Equivalence on intcgrat
of the &urn-Liouvilk equation
difference
problem
and
Using Green’s difference formula (see [3’I) we can easily see that the Stun-Liouville difference problem (II?9 is epuivalent to the solution of the difference snalogue of the integral equation Y = I h CC@? ey)),
which, with the help of the substitution cp (4 = m;Y
(r)*
reduces to the difference
p
integral
(29 E) = Ve (4 e (E) @ (r, E) equation
9 = khCC with symmetric “kernel”
Kh(z, E), where c” (5, g)
ence function of the operator
7.
Equivalence
variational
911
ak* ” *’
of the Sturdiouville problem
is the Green differ-
with conditions
problem
(9) snd (IO).
und a difference
Using Green’8 difference formula by analogy with Section 2 it is not difficult to see that the Sturm-Liouville dffference problem (IfA) is equivalent to the following difference variational problem: 1) in the class of net comnarison functions q satisfying tions HN
iv]
‘PI = Q,*.a-2
h
=
((ee, q”))
0,
9 ax.0 = 0,
=
1, 0,
(P&I=
e)jiJv+
-+(pTd;,N = ‘*
to find the minimumof the fuuctional
this minims defines the first
difference
eigenvalue
the condi-
difference
The Stun-Liouvillc
1391
probler
2) the other difference eigenvalues h:~ n > 1 are found as the minimumof the functional 11) in the class of net functions q~satisfying the supplementary conditions
HN bpl = 1,
BN $=
P r,o-2 where
ya
is
the
n-th difference
h
= 0,
cpa.0
m-th difference eigenvalue c=
8. Properties
[qb y,,,] = ((e%y,,# = 0, TN-1 = 0,
eigenfunction;
eigenvalues
and difference
n=1,2
,...,
3. All the difference eigenfunctlons normalised with weight e(x) 1 HNIy,.Y~l={O
Iar,Oo
eigcnfunctions
eigenvalues with corre-
eigenvalues are positive:
C>o,
4. If k, p, q, r E
this minimumdefines the
min &I [VI = &V [y,,].
of difference
All the difference
%
~,N+‘+~&,N=O’
1. For each N there exist N - 4 difference sponding eigenfunctlons
2.
o for m <
yn
N-4.
form an orthogonal system
for m-n, form#n.
Q(O) then we have the estimates II b&II
o<
M* OF*
II b/n)&
< M,
(&“a,
W
for the difference eigenfunctions yn and their difference derivatives, where Ml, MS, and Ma are certain positive constants which do not depend on the step h or the number n. For let x and x’ be any two points of the net Oh. We have
1392
Khao
Y2(4 - Yaw
[a(4 y;;x(412 -
= ad+h i
b(~‘)YT&wla =
Shou
h [Y (4 + i
Y;
(4,
h [~(S)y~~(S)+~(s-h)y~(S-h)lX
[a(4 y&)1;.
From the normalisation condition fore
(s - hII
d+h
x there exists
Y
HN [y, yl = 1 it follows that
at least one point x’ at which e (s’) y2 (cc’) <
1
and there-
yB (5’) < l/c,.
Further, it follows from the boundary conditions
Y&J =
YX,6 +
that
fihhY&(S) =-&(h) + 5hhy&(s).
s=h
r=h
Then using the Cauchy-Bunyakovskii inequality
we obtain
and therefore
IIY,
no < M, (W’*,
0(YJ;IIo < M, (W.
We can put the solution of the problem (IIA) in the form Y (4
=
y (3h) +
y,- (3h) +
+dlxgh
i
_
h
m=ah
m-h
=(m+h)
+d2=sh
i h _,, _+,
1
=(m+Wr
where dl and d2 are determined from the boundary conditions yN_1 = 0, It
is
not difficult
y;, N + +y;;.N
to see that d/ = 0 (Ah),
It follows
=o.
i = 1.2.
from equation (8) that
[a (4 YG WI,-
= b (4 Y,-(4 + i
h I-
d (4 y (4 + hhe (4 y (4
1 + d,
The Sture-Liouville
difference
problcr
1393
and therefore
Since
we obtain
and therefore
2. Convergence of the nolution of the Sturu-Liourillc difference problem In the
work 111 it
tion
that
(II)
converge’to
Liouville
for
(1)
theorem using
epuaproblem
of the initial
of discontinuous
convergence
differential
of the difference
and eigenf~ctions
in the class
8n analogous
a second order
8nd eigenf~ctions
the eigenvalues
problem
we prove
~8s proved
the eigenvalues
coefficients.
the method given
StuwHere in
El].
We omit the proof. We first
consider
Let y = ytx, fWiCtiOn81
DN
the case of the first
hf be the net function
with
the nowslisstion functions
values
which realises
(n = 1). the minimum of
the
[q] x” =
net
eigenvalue
{y(z,
condition
h))
DN
[j/l
HJV [y] =
i.
Consider
and the corresponding
the sequence of
sequence of
first
{Ah? on some sequence of nets.
Lemma 2, For each
positive
E there
??<&$-a where h is the first
eigenvalue
exists
an ho such that
for h
(1%.
eigen-
1394
Proof.
Khoo Shou
Let u’(z)
be some function of G(2) for which J#== i*
and let
From Leppraa 1 we have
for A
a* (A) < a + s Therefore,
from the principle
of the minimumof a functional
kh
h
+ s,
Lemma3. The sequences of functions equicontinuous and bounded.
we have
{y (z, A)} and (y; (2, A))
are
For if x4 and x **are any two points of the net Oh then 9
Using the estimates (12) we find from Lemma2 that {y(x, continuous: I y W,
where M is some positive
h) -
y (s’, W I < M 1 2” -
A)) is equi-
5’ 1,
constant which does not depend on h.
From the normalisation condition at one point x = x’ the inequality
HN [yl = 1 it follows that at least
y (z’, h) G---L v C6 holds. It follows bounded:
from (13) that the sequence {y(x,
1 Y (G h) I <
Similarly
I Y (~3 h) -
Y (2’9 h) I +
/I)) is uniformly
I y W, h) I < M.
we can Prove that {y,-(s, A)} is equicontinuous and bounded.
It follows from the Arzela theorem that there exists some sub-sequence (Y (5, hk)) which converges uniformly to some function G(r) continuous on the segment [O, 11:
0Yt5, hk)
-
G (2) no =
P @kh
where p(hk) +O We shall
as hk-
assume that
{hhk = h (hk)}
difference
Sturn-Liouvillc
The
0.
the
converges
1395
problem
sequence {hk? is such that the sequence
to sooie limit
[ll)
“h (see
lim 1 (hk) = x, hk+Q
the sequence
and
converges uniformly to some function w(x).
(y,-(z,hk)}
Lemna 4. If for some sequence {hk)
1Y,-(2, k) -
‘;; (5) tb = P (hk),
1 Y (G hd -
W (z) g= P (hk),
then ;fi (z) = tD(z). We omit the proof. Lemma 5. If for some sequence {hk)
lim 1 (hk) = x, hk-“’
then
We omit the proof (see [ll). Lemma6. Let gh (z, E) be the Green difference ator
ak’ y = (a&);,
for the boundary conditions
gtx,
function of the oper-
(2).
If
kE
(9) and (lo), operator
Q(O) and the difference
= (ku’)
scheme
has zero rank ilghtt, E) -
g (z, E)ib = P (h),
@(z,
E) -+g
(2, E)C = P (h).
To prove this it is sufficient to note that the functions and v(j)(x) in the expressions of the Green functions g(x, cl and
Proof.
vi(x)
and let
L”‘u
gh(x,
form:
cz
Vl(4
=
k+ ss
ddz,
11
cl
(4 =
zz va (;st-
Adz, o 1so k (0
&jdtdz, ss
XL
00
11
v4 (4 =
ss xz
$$
dtdz;
1396
Khao Shou
We nor consider the equation Y =
W’,
Jh)).
(14)
Using the Green formula we cau reduce equation (14) to the equation Y = -
((b,$?I<,+ w9
ve- 4 Yh
where gh(x, Q is the Green difference function of the operator LAk) with conditions (9) and (101. Passing to the limit we obtain 1
L(2) = -
1p (8 g; (2. 8 2 (6)dE+ 5g(5, El iiir(E)0
where g(x,
q (EJI ii tE) d&v (15)
0
Q is the Green function of the operator
(ku”)”
tion (2). It follows that the solution ii(x) of the integral (15) satisfies the differential equation L”.
P. u) ;
-Xr
for condiequation
(z)iY=O
and the boundary conditions E (0) = s (0) = L(1) = 2 (1) = 0. Since A = hl is the least eigenvalue of the problem (IA) and “h < A we have i = A. Because of the multiplicity following lenma.
of difference
eigenvalues we have the
The Sturn-Liouvillt
difference
probltr
139’7
Lemma 6. The difference eigenvalue Ah has multiplicity than the multiplicity of the corresponding eigenvalue A.
for
not greater
Proof. We shall prove the lemma by assuming the contrary. Suppose, example, that h is a simple eigenvalue and that hh is a double eigen-
value of the “kernel” G”(5, t). Let i (5, h) and y (2, h) be orthogonal and normalised eigenfunctions belonging to the eigenvalue Ah. As we have shown there
exists
{hk)
a sequence
sponding sequence {g (x, hk)} converges ul(x) belonging to the eigenvalue A: II i (xv hd -
uniformly
such that
the corre-
to the elgenfunction
~1 (4 jio = P (hk)
and
lim X (hk)
=
x
=
&.
hk*
We shall
assume that
the sequence 19 (G hk) -
{hh)
is
such
that
the equation
% (2) gb = P (hk)
holds.
tion
If not we could pick cut a sub-sequence and restrict our considerato only those suffixes k which corresponded to this sequence. We will
then have
and therefore
11 l-3h@ (X) p
(2, hk);
-*. but this
contradicts
(X&k)-‘2 hfl (‘) “f b) II,=
P thkh
-k
the limit
equation
In exactly the s&a8 nay It can be proved that when h is a double eigenvalue the difference eigenvalue hh has multiplicity not greater two.
than
1398
Khao Shou
Lemma7. The difference eigenvalue Ah has multiplicity the multiplicity of the corresponding eigenvalue A. To prove this it is sufficient form an orthogonal system
to note-that
H [unt 4
The following Theorem
of
u(x)
eigenvalue Al.
to the other eigenvalues A,h, n > 1.
theorem is a consequence of the above argument. If the difference
Convergence.
rank, the solution of nets as h -
the eigenfunctions
n+m.
= 0,
The reasoning above applied to the first It is also applicable
not less than
scileme
L~kvP~q*Ar) has zero
(c, y,,j of problem (IIA) converges on auy sequence
0 to the corresponding solution 11I:--&,=p(h),
for any coefficients
u, IJo= P (4
IIl/n -
k, p, q, r E
(A,,, u,,) of problem (1%:
Q(O).
3. On the accuracy of the solntions of the Sturr4.ionville difference problem I.
The equation
for
the error
Let (Ah, y) be a solution (A, IL) be the corresponding problem (I’). The error z = w.r. t. the solution u(x) of
of an eigenfunction
of the difference problem (11% and let solution of the initial Sturm-Liouville y - u of the solution y(x) of problem (IIh) problem (1% satisfies the conditions W.P>~.W~ = y
Lh q
=
f
VI,
VT&-l =
(W
(47)
p1
(W where Y = $ + (A” I# ---
h) eu,
[(Id)” - (au;;), 1 - [(pu’)’ - (~~;),I + (q - 4 u + h (e - 4 u9 (1% p1 = - u (1 - h), VI = - u (h), h 3
=
-
ux.0 -
2
uu,o
,
IL2=-
UG,N
+$uz,,}.
The Stura-Liouvi
We call
Zle
di,fference
the problem defined by (W-(18)
2. Formula for
the error
1399
problem
problem (111%.
AA = hh - A.
since the parameter hh is an eigenvalue of problem (II’) the difference problem (IIIh) is soluble only when the following equation holds:
From (19) and (20) we obtain a formula for the error Ah = hh - A: W, $4) -t V -f+{-+
i
-
-$-
A) ((eu+ YH + -$ h ~~~~~~+UN-~~N-~~~ alp,
i
&%-&N-2
(Za, -b
+
2al
@aN-%
+
i-
PbJ
2aN+
+
Y% -
function
jj = Cy
w&B
hbN-2)
As in the work iJ.1 we choose a multiplier
-I-
)
%
f
YN-% -
pl
=
0.
C in such a nay that the
is orthogonal to the difference
2 = y--
u:
((6, +,, = 0. We then obtain a formula for estimating the error Ah = hh - h:
aud a formula for estimating c2 -
f C- -
1 = (@b z’>>+
1 1: (HN iuf
-
H !ul),
where cz41
as h-0.
Introducing the function q(xt with the help of the conditions tt;,=g**
ql=rit.l=o
and then using Green’ s formula we find that for k, p, q, r E c’( 2 * I)
(211
1400
Khoo
Shou
where
I#@)= ku” q,’ = (q -
IIS’ II*=
q(b) = bu, -
ataG,
4 u + A (e - r) u + q (2) =
II71b + h I rl(1 - 4
$,
0 (W,
5 h i hqqz”), i=lh z&ah
pu’ ,= (pu’) l p;, This gives
the following
lemas
Lemma8. If y(x) has the form
then
IAll=
iA”- 1 I < M (9 Illlva) ll, + lwb) III + IIlb*lls+ I Vl +
I3
I+
IIL1
I+
I + I PaII,
and hma
9. If y(x) has the form
at all points &+s, then
of the net q, Wart from the points
AX 1 < M @I #i’,‘“’ II; f
+h*
n+S 7A Iel+q
8-n-l
IWb)II;+ US’a;+ l#$_, I + I$$,+,l + z
w-3--s)*,I+hl
l-n-1
grp./+ r-n-1
+
where
x = xn+, G, til,
I Yl
I + I VI I +
IIL1 I
+ I CL%’ IL
The
3.
A
priori
Sturw-Liouville
difference
1401
problcn
estimates
By analogy with [I] we estimate the error z = y - u. We first the problem (IIIA) to the analogue of the integral equation z = h” ((Ch, ei)) +
reduce
((Gh, !I!)) + [p,(t~(-l)G-,-)~a(-lfG~p,l~ -
(22) - [vl(d+')Gk)r - a(+'~Gh,v,l,-, - bi+IpIG;,N_I + b,~,Gh*,~,
where G%x, @ is the difference function of the operator the boundary conditions (9) and (10). The eigenfunction tion
T of problem (IIA) satisfies
Lik*p* 9) for
the “integral’
epua-
i = Ah((Gh, &)), which, with the help of the substitution Kh (5, E) = I/e (4 e (F;) G” (JG EL reduces to the difference
“integral”
with symmetric “kernel” Khfx, @;
elation
and with the help of the substitution
Kh(5, E) = v’e(4 e (%)Gh(2, %I,
--
v (4 = Ve h-42 (4
equation fZZt reduces to the equation E,= hh ((P,
v)) + f,
(231
where
Equation (23) is soluble and so we shall have au o~hogonality tion for the solution rg(x) and the right-hand side f: W
condi-
f)) = 0.
Now let us go on to construct the resolvant
R of the “kernel” Kh(x,Q
ilhao Shou
through
which the solution WV(X)of equation (23) can be expressed
by
formula Q= f + W
01.
It follows from the conditions that
t(G* 3, = 0,
ml m = 0
The resolvant R is found from the equation
and can be written in the
form (see El])
R = K, + R,, where
and the sm is taken over all qpkwith the exception of those to which the eigenvalue %,hcorresponds. Be have the following
estimate (see
[II ):
From this we obtain
Themera 1. Let yn(r) be the n-th normalised eigenfunction of the difference problem (IIA) and let u,(z) be the n-th normalised eigenfunction of the problem CIA. If y(x) has the form
the
The
Sturm-Liouuillc
difference
problem
i4nn
then
where M(A) is some positive Proof.
constant which does not depend on
h.
We consider
f = ((fYh, Fj) -!- (A” -
A)) ((Kh, fi
+ J& { (pL1(a(-l)G&
-
u)) +
a(-l)G~q,I~ -
Iv1 (a(+l)G$), -
a(+W&v210} -
- 1/- eh-rCrlG$,,,
-
b~G~,dy
where I=
--L-Y. I/c
Introducing the function q(x) with the help of the conditions q& = \p’*
rll =
rlr.1 = 0
we have
II4 G df (V W”’ IL + IIWb)III + IIS’ Ila+ I Vl I + I v2
I+
IPl I +
I P2 I>*
Using (21) and !Z=
y---u=- ;
++z,
we obtain (24). Theorem 2. Let y,(x) be the n-th normalised eigenfunction of the difference problem (11% and let u,(x) be the n-th normalised eigenfunction of the problem (IA). If Y(X) has the form ‘Ip = 9::
-f- Sib’ -!- 9’
at all points of the net
1404
Khao Shou
of
4. The order
accuracy
of
in the class
smooth coefficients
from Theorems 1 and 2 that the order of accuracy ot the solution of the Sturm-Liouville difference problem WA) depends on the approximation error of the difference scheme y and also on the approximation error of the normalising functional HN, i.e. on the quantity It
is clear
X = HN [ul -
H [u].
In order to study the question of the accuracy of tile solution problem (IIh)
it is sufficient
to estimate
We shall prove the following
of
/I$@)l/r, llp(b)j/l, 11 $*]I, and x.
theorem.
Theorem 3. If the difference scheme ~~~‘p~q,~r’ of second rank satisfies the necessary conditions for second order approximation, then the solution r E
(G, &,)
C( 2 * ‘)
of the difference
problem (IIA) in the class k, p, q,
has second order accuracy,
I 1Lt:-
5
I<
M &J
h2,
where M&J is some positive
i. e.
II yn (4 -
un (4 lb <
&if (W h2,
constant which does not depend on h.
Proof. Carrying out the seme reasoning as in the proof of Theorem 3 in 131 we obtain
gcar = ku” -
au- = xx
0
(h2),
+a) = bn, -
AS we have shown the difference order approximation:
v1 = 0 (h%), It is not difficult k, P, Q,
F E
c’2n”
y1 = 0 (P),
operators
ptr’ = 0 (h2),
$,’ = 0 (h”).
(9) and (10) have second
l.~ = 0 (ha),
pS = 0 (h2).
to see that the normalising function N,,, for h&M
S econd
order approximation w.r. t. h (see
~11~:
7he
.5. The order
Starm-liouo~lle
of accuracy
in the class
difference
problem
of discontinuous
14(25
coefficients
In this section we discuss tne auestion of the accuracy of the solution of the Sturm-Liouvifle difference prObleM UIh) in the class of disconti~uo~~scoefficients Qini). To avoid complicating the explanation we assume that the coefficients of equation (1) have the same point of discontinuity: E = xn -!-oh, 0 < 8 < 1. We note that for a second rank scheme satisfying the necessary conditions for second order approximation in the class k, p, q, r E fy2,” n-a
h2 2
n+2 (n -i-3 -
sf $1 = 0 (h),
ain-1
k
2
** = 0 (k);
m-1
for the scheme Lik*p’Q*“” with coefficients
(25)
cm (271
w3)
in the class k, p, q, r E
n+z
Q(‘*‘)
n+e
n+a
This gives the following theorem. Theorem 4.
Any difference scheme
L~kip*q*x” of second rank satisfying
1408
Khao
Shou
the necessary conditions for second order approximation has in the class first order accuracy: k, p, (I, r E P*l)
and the difference scheme with coefficients accuracy in the class k, p, q, r E Q’ ’ * I’:
where U(h,) is some positive
(25)-(28)
gives second order
constant which does not depend on h.
In conclusion, I express my sincere gratitude to A.A. Ssmarskii for his valuable advice and help in the completion of this work, and also to A.N. Tikhonov for his interest in it.
REF'ERENCES 1.
TI~ONOV, A.N. and SAMARSKII, 805, 1981,
2.
SAMARSKII, A.A.. 2%. wych. Rat., 1. No. 6. 972-1000, 1961.
3.
KHAO SHOU, Zh.
4.
COURANT. R. and HILEERT, D., Metody
vych.
mat.,
of Mathematical Physics), dat. 1951.
A.A.
t
Zh.
uycft.
aat.,
I.
No,
5. 784-
3, No. 5, 841-860, 1963.
Vol.
aatcnatichaskoi
fiziki
(Methods
1. Moscow and Leningrad, Gostekhiz-