On a Unique Solution for the Two-Point Boundary Value Problem

Journal of Mathematical Analysis and Applications 247, 653–657 (2000) doi:10.1006/jmaa.2000.6870, available online at http://www.idealibrary.com on

NOTE On a Unique Solution for the Two-Point Boundary Value Problem Zhang Shu-Qin1 and Zhong Cheng-Kui Department of Mathematics, Lanzhou University, Lanzhou, 730000, Gansu, People’s Republic of China Submitted by George Leitmann Received March 29, 2000

An existence and uniqueness result concerned with the boundary value problem u00 + gt; ut‘‘ = et‘; is presented.

u0 0‘ = u0 π‘ = 0

© 2000 Academic Press

1. INTRODUCTION Consider the boundary value problem u00 + gt; u‘ = et‘;

u0 0‘ = u0 π‘:

(1)

In [1], Huang and Shen consider the existence and uniqueness result of the solution for (1). There they consider the case that gu t; u‘ is non-negative. Here, we consider the case that gu t; u‘ may be negative. In this paper, we also use the following Min–Max Theorem (see [2]) to prove our main result. Min–Max Theorem (Manasevich). Let H be a real Hilbert space and let f x H → R be of class C 2 . Suppose that there exist two closed subspaces X and Y such that H = X ⊕ Y and two continuous nonincreasing functions α x ’0; ∞‘ → 0; ∞‘; 1

β x ’0; ∞‘ → 0; ∞‘

This work was supported by the National Natural Science Foundation of China 653 0022-247X/00 $35.00 Copyright © 2000 by Academic Press All rights of reproduction in any form reserved.

654

note

such that

Z

∞

1

αs‘ds = ∞

Z

∞

1

βs‘ds = ∞



2 D f x + y‘k; k ≥ ᐎŽyŽŽ‘ŽŽkŽŽ2

for all x ∈ X, y ∈ Y , and k ∈ Y , and 

2 D f x + y‘h; h ≤ −␎ŽxŽŽ‘ŽŽhŽŽ2 for all x ∈ X, y ∈ Y , and h ∈ X. Then (a)

there exists a unique v0 ∈ H such that ∇f v0 ‘ = 0;

(b)

f v0 ‘ = max x∈X miny∈Y f x + y‘ = miny∈Y max x∈X f x + y‘:

In the above theorem, ∇f u‘ and D2 f u‘ denote the gradient and the Hessian of f at u ∈ H; respectively. In this case, f x H → H is a C 0 mapping and ∇f ‘0 u‘ = D2 f u‘ is a bounded self-adjoint linear operator on H. Let U = ”uŽut‘R ∈ C 2 ’0; π“; u0 0‘ = u0 π‘ = 0; ut‘ is absolutely continπ uous and satisfies 0 u2 t‘dt < +∞•. Then U is a real Hilbert space with the inner product Zπ u0 v0 + uv‘ dt: Œu; v = 0

The norm induced in U by the inner product Œ· will be denoted by ŽŽ · ŽŽU . We assume that: (A)

g ∈ C 0 ’0; π“ × R; R‘ and e ∈ C’0; π“y

(B)

there exists some positive integer n such that

n2 + bn + c < gu t; u‘ < n + 1‘2

for all u ∈ U; t ∈ ’0; π“;

(2)

where n2 + bn + c < 0 and b; c satisfy c>0 b + c + 1 < 0:

(3)

2. THE MAIN RESULT In this section, we consider the existence of a unique solution for Problem (1). We let gu∗ t; u‘ = gu t; u‘ + 2n + 1‘2 ;

note

655

then 3n2 + 4 + b‘n + 2 + c‘ < gu∗ t; u‘ < 3n + 1‘2 : By (3), we see that 3n2 + 4n + 2 < 3n2 + 4 + b‘n + 2 + c‘: We denote ζs‘ = min max gu∗ t; u‘ − 3n2 + 4n + 2‘‘

(4)

ηs‘ = min max n + 1‘2 − gu t; u‘‘:

(5)

ŽŽuŽŽU ≤st∈’0;π“

ŽŽuŽŽU ≤st∈’0;π“

Clearly, ζx ’0; +∞‘ → 0; +∞‘ and η x ’0; +∞‘ → 0; +∞‘ are two continuous nonincreasing functions. Define subspaces X and Y of U as X = ”xŽxt‘ =

n X a0 + am cos mt; am ∈ R; m = 0; 1; 2; · · · ; n• 2 m=1 ∞ X

Y = ”yŽyt‘ =

m=n+1

am cos mt; am ∈ R; m = n + 1; n + 2; · · ·•;

(6)

(7)

P where n is as in (2) and the series yt‘ = ∞ m=n+1 am cos mt as well as the series obtained by termwise differentiation of (7) converges uniformly on R. Clearly, we have U = X ⊕ Y and the inequalities Zπ Zπ Zπ Zπ Žx0 t‘Ž2 dt ≤ n2 Žxt‘Ž2 dt Žy 0 t‘Ž2 dt ≥ n + 1‘2 Žyt‘Ž2 dt 0

0

0

0

for all x ∈ X; y ∈ Y . Next, we shall consider the problem u00 + g∗ t; u‘ = 2n + 1‘2 u + et‘;

u0 0‘ = u0 π‘ = 0:

(8)

We note that Problem (8) is equivalent to Problem (1) by the construction of g∗ t; u‘. Define a function I x U → R by  Z π 1 0 2 2 2 Žu t‘Ž − Gt; ut‘‘ + et‘ut‘ + n + 1‘ u dt; (9) Iu‘ = 2 0 Ru where Gt; u‘ = 0 g∗ t; s‘ds; u ∈ U. Clearly, I is of class C 2 by ssumptions, A‘ and B‘:

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note

It is well known that u ∈2 ’o; π“ is a solution of problem (8) if and only if u is a critical point of I. The following is our main result. Theorem. Suppose that (A) and (B) hold, and Z∞ Z∞ ζs‘ds = +∞; ηs‘ds = +∞; 1

(10)

1

where ζ and η are as in (4) and (5). Then (a) there exists a unique solution u∗ of (8); (b) Iu∗ ‘ = max x∈X miny∈Y Ix + y‘ = miny∈Y max x∈Y Ix + y‘, where Iu‘ is defined in (9) and X and Y are defined in (6) and (7). Proof. First of all, it is easy to prove that a mapping ∇I x U → U is defined by Zπ u0 v0 − g∗ t; u‘v + et‘v + 2n + 1‘2 uv‘ dt: ∇Iu‘; v‘ = 0

And for all u ∈ U; ∀v ∈ U; w ∈ U, we have  Zπ 0 0

2 v w − gu∗ t; u‘vw + 2n + 1‘2 wv‘ dt: D Iu‘w; v = 0

For u = x + y ∈ U; x ∈ X; y ∈ Y , and h ∈ X; k ∈ Y , we have  Z π 02

2 h − gu∗ t; u‘h2 + 2n + 1‘2 h2 ‘ dt D Ix + y‘h; h = 0 Zπ n2 − gu∗ t; u‘ + 2n + 1‘2 ‘h2 ‘ dt ≤ 0 Zπ = − gu∗ t; u‘ − 3n2 + 4n + 2‘h2 ‘ dt 0

min

max gu∗ t; u‘ − 3n2 + 4n + 2‘‘

Z

π

h2 dt   1 max gu∗ t; u‘ − 3n2 + 4n + 2‘ min =− 2 n + 1 ŽŽuŽŽU ≤ŽŽxŽŽU t∈’0;π“   Zπ Zπ h2 dt + h2 dt n2 0 0   1 min max gu∗ t; u‘ − 3n2 + 4n + 2‘ ≤− 2 n + 1 ŽŽuŽŽU ≤ŽŽxŽŽU t∈’0;π“  Z π Zπ 2 h0 dt + h2 dt ≤−

ŽŽuŽŽU ≤ŽŽxŽŽU t∈’0;π“

0

=−

ζ ŽŽxŽŽU ‘ ŽŽhŽŽ2U n2 + 1

0

0

note

657

 Z π 02 k − gu∗ t; u‘k2 + 2n + 1‘2 k2 ‘ dt D2 Ix + y‘k; k = = = ≥

Z

0 π



Z

0 π

 2 k0 − gu t; u‘k2 − 2n + 1‘2 k2 + 2n + 1‘2 k2 dt



 2 k0 − gu t; u‘k2 dt

0

Z

π 0

2

k0 k0 − gu t; u‘ n + 1‘2 2

! dt

1 min max ’n + 1‘2 − gu t; u‘“ n + 1‘2 + 1 ŽŽuŽŽU ≤ŽŽyŽŽU t∈’0;π“ Z π  1 2 k0 dt 1+ n + 1‘2 0  1 min max n + 1‘2 − gu t; u‘‘ ≥ n + 1‘2 + 1 ŽŽuŽŽU ≤ŽŽyŽŽU t∈’0;π“  Zπ 2 0 2 k + k ‘ dt ≥

0

=

琎ŽyŽŽU ‘ ŽŽkŽŽ2U n + 1‘2 + 1

From (10) and the fact that ζs‘ and ηs‘ are nonincreasing, it can be proved that Z∞ Z ∞ ζs‘ ηs‘ ds = +∞ ds = +∞ 2 2 1 n +1 1 n + 1‘ + 1 and ζs‘/n2 + 1, ηs‘/n + 1‘2 + 1 are also nonincreasing. Now, we complete the proof by the Min–Max Theorem. So Problem (1) has one unique solution by the equivalence of Problem (1) and Problem (8). REFERENCES 1. H.-W. Huang and Z.-H. Shen, On the two-point boundary value problem of Duffing equation with Neumann conditions, J. NanJing Univ. Math. Biquart. 16 No. 1 (1999), 8–11. 2. R. F. Manasevich, A min–max theorem, J. Math. Anal. Appl. 90 (1982), 64–71.