ϵ-Pareto Optimality for Nondifferentiable Multiobjective Programming via Penalty Function

JOURNAL OF MATHEMATICAL ANALYSIS AND APPLICATIONS ARTICLE NO.

198, 248]261 Ž1996.

0080

e-Pareto Optimality for Nondifferentiable Multiobjective Programming via Penalty Function J. C. Liu Section of Mathematics, National Uni¨ ersity Preparatory School, National O¨ erseas Chinese Student Uni¨ ersity, Linkou, Taipei, Hsien, Taiwan, 24402, Republic of China Submitted by Koichi Mizukami Received January 9, 1995

Necessary and sufficient conditions without a constraint qualification for e-Pareto optimality of multiobjective programming are derived. The necessary Kuhn]Tucker condition suggests the establishment of a Wolf-type duality theorem for nondifferentiable, convex, multiobjective minimization problems. The generalized e-saddle point for Pareto optimality of the vector Lagrangian is studied. Q 1996 Academic Press, Inc.

1. INTRODUCTION Several authors have been interested recently in e-optimal solutions in nonlinear programming. For details, the readers are advised to consult w1]5x. Loridan w4x derived some properties of e-efficient points solution for vector minimization problems and used the Ekeland’s variational principle w6x to establish the e-Pareto optimality and e-quasi Pareto optimality. In w7x, Liu also adapted the same approach to obtain the e-duality theorem of nondifferentiable nonconvex multiobjective programming. Recently, several authors w8]12x have used an exact penalty function to transform the nonlinear scalar programming problem into an unconstrained problem and derived the e-optimality. In w14x, Yokoyama was concerned with the e-approximate solutions and extended some results of w13x to the vector minimization problems. Similar to w13x, Yokoyama transformed the vector problems into the unconstrained problems by using the exact penalty functions and showed the e-optimality criteria by estimating the penalty parameter in terms of e-approximate solutions for the associated dual problems. 248 0022-247Xr96 $18.00 Copyright Q 1996 by Academic Press, Inc. All rights of reproduction in any form reserved.

e-PARETO

249

OPTIMALITY

In this paper, we are inspired to use the exact penalty function to transform the inequality multiobjective programming problem into a scalar unconstrained problem and to derive the Kuhn]Tucker conditions in which Lagrange multiplers of objective functions are one. Some definitions and notations are given in Section 2. In Section 3, we use scalar penalty functions to establish the necessary and sufficient conditions of e-Pareto solution. Using this result, we formulate a dual problem of the Wolfe-type for multiobjective programming. In Section 4, we give some relationships between the primal problem and the dual problem. The generalized e-Pareto saddle point of the vector Lagrangian is discussed in Section 5.

2. PRELIMINARIES We consider the following convex multiobjective programming problem:

Ž P.

minimize f Ž x . subject to g j Ž x . F 0,

j s 1, . . . , m,

where f s Ž f 1 , f 2 , . . . , f p . and each component function is a convex continuous real-valued function defined on R n and where g j are convex continuous real-valued functions defined on R n, 1 F j F m. We denote the feasible set  x g R n < g j Ž x . F 0, 1 F j F m4 by F and assume the feasible set F is nonempty. Let e be an element of Rqp . We introduce the e feasible set Fe , p

½

Ý ei , 1 F j F m

Fe s x g R n g j Ž x . F

is1

5

.

p For convenience, let g s Ý is1 ei. To transform the problem ŽP. into a scalar unconstrained problem, we use the exact penalty function introduced by Zangwill w8x:

p

u Ž x, r . s

Ý

m

fi Ž x . q r

is1

Ý max Ž 0, g j Ž x . . , js1

where

r ) 0. The associated unconstrained problem in which

Ž ur .

minimize u Ž x, r .

250

J. C. LIU

is called a penalized problem with respect to the penalty parameter r . For convenience, let p Ž t . s max Ž 0, r t . . p Clearly, we have u Ž x, r . s Ý is1 f i Ž x . q Ý mjs1 pŽ g j Ž x ...

DEFINITION 2.1. A point x g R n is called an e-Pareto solution of ŽP. if x g F and there is no x g F such that f Ž x . F f Ž x . y e and f Ž x . / f Ž x . y e ,

in R p .

DEFINITION 2.2. A point x g R n is called an almost e-Pareto solution of ŽP. if x g Fe and there is no x g F such that f Ž x . F f Ž x . y e and f Ž x . / f Ž x . y e ,

in R p .

DEFINITION 2.3. Let a ) 0. A point x g R n is called an a-solution of the scalar problem Ž ur . if

u Ž x, r . F u Ž x, r . q a ,

for all x g R n .

DEFINITION 2.4. Let h: R n ª R j  q`4 be a convex function, finite at x. The e-subdifferential of h at x is the set ­e hŽ x . defined by

­e h Ž x . s  x* g R n < h Ž y . G h Ž x . y e q ² x*, y y x : for any y g R n 4 .

3. NECESSARY AND SUFFICIENT CONDITIONS In this section, we present some Kuhn]Tucker conditions for e-Pareto optimality. THEOREM 3.1. If there exists r 0 such that x is a g-solution for Ž ur . for any r G r 0 , then x is an e-Pareto solution for ŽP. and there exist scalars e i G 0 Ž1 F i F p ., e jG 0 Ž1 F j F m., l jG 0 Ž1 F j F m. such that: p

Ži. 0 g

Ý ­ e Žl j g j .Ž x .,

is1

js1

p

Žii.

m

Ý ­ e i fi Ž x . q

j

m

Ý ei q

Ý

is1

js1

Ž1.

m

ej y g F

Ý l j g j Ž x . F 0. js1

Ž2.

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251

OPTIMALITY

Proof. If x is a g-solution of Problem Ž ur .,

u Ž x, r . F u Ž x, r . q g ,

for all x g R n .

Ž 3.

Clearly, p

u Ž x, r . s

for all x g F.

Ý fi Ž x . , is1

Thus, we have p

p

Ý f i Ž x . F u Ž x, r . F Ý f i Ž x . q g , is1

for all x g F.

Ž 4.

is1

If x f F, Ý mjs1 pŽ g j Ž x .. ) 0. Choose any feasible point ˆ x which is also in F and let

r ) max

½ž

p

p

m

Ý f i Ž ˆx . y Ý f i Ž x . is1

is1

Ý pŽ gj Ž x . . , r0

/

js1

5

.

We then have the conclusion p

Ý

p

fi Ž ˆ x. s u Ž ˆ x, r . G u Ž x, r . y g )

is1

Ý f i Ž ˆx . y g . is1

This conclusion gives a contradiction and hence x g F. If x is not an e-Pareto solution of ŽP., then there exists x 1 g F such that fi Ž x1 . F fi Ž x . y ei , 1 F i F p, with at least one strict inequality. Therefore, we have p

p

Ý

fi Ž x1 . -

is1

Ý fi Ž x . y g , is1

which contradicts Ž4.. Thus x is an e-Pareto solution of ŽP.. With Ž3. and the result of w15x, we have p

0 g ­g

žÝ

m

fi Ž ?. q r

/

Ý p Ž g j Ž ?. . Ž x . .

is1

js1

Then, there exist scalars e iG 0 Ž1 F i F p ., e jG 0 Ž1 F j F m., a j G 0 Ž1 F j F m., and hj G 0 Ž1 F j F m. such that p

m

Ý ei q

Ý ej s g ,

is1

js1

p

0g

Ž 5.

m

Ý ­ e i fi Ž x . q

Ý ­h Ž a j r g j . Ž x . ,

is1

js1

i

Ž 6.

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J. C. LIU

where

a j F 1, hj q p Ž g j Ž x . . y a j r g j Ž x . s e j

for j s 1, . . . , m.

Ž 7.

By Ž5. and Ž7., we have p

m

m

Ý e i q Ý hj y g F Ý a j r g j Ž x . F 0. is1

js1

js1

Finally, we obtain the results Ž1. and Ž2. by setting

lj s aj r , e j s hj ,

1 F j F m, 1 F j F m.

REMARK 3.1. If p s 1, then the necessary condition of Theorem 3.1 reduces to Theorem 4.1 of w13x. THEOREM 3.2. If x is a feasible solution of ŽP. and there exist e iG 0 Ž1 F i F p ., e jG 0 Ž1 F j F m., l jG 0 Ž1 F j F m. such that: p

Ži. 0 g

m

Ý ­ e f i Ž x . q Ý ­ e Žl j g j .Ž x ., i

is1 p

Žii.

Ž8.

j

js1 m

m

Ý e i q Ý e j y g F Ý l j g j Ž x . F 0. is1

js1

Ž9.

js1

Then, x is an e-Pareto solution of ŽP.. Proof. If x is a feasible solution of ŽP. and there exist e iG 0 Ž1 F i F p ., e jG 0 Ž1 F j F m., l jG 0 Ž1 F j F m. which satisfy relations Ž8. and Ž9., then there exist xUi g ­ e i f i Ž x ., 1 F i F p, yUj g ­ e j Ž l j g j .Ž x ., 1 F j F m, such that p

m

Ý xUi q Ý yUj s 0. is1

js1

By using the characterization of the e-subgradient, we obtain f i Ž x . G f i Ž x . q ² xUi , x y x : y e i ,

lj g j Ž x . G lj g j Ž x . q ²

yUj ,

x y x: y ej,

1 F i F p, 1 F j F m.

e-PARETO

253

OPTIMALITY

Thus, we have p

p

m

m

Ý fi Ž x . q Ý l j g j Ž x . y Ý ei y Ý e j is1

js1

is1

p

F

js1 p

m

Ý fi Ž x . q Ý l j g j Ž x . F Ý fi Ž x . , is1

js1

for all x g F.

is1

With Ž9., we have p

Ý

p

fi Ž x . F

is1

Ý fi Ž x . q g ,

for all x g F.

Ž 10 .

is1

If x is not an e-Pareto solution of ŽP., there exists x 1 g F such that fi Ž x1 . F fi Ž x . y ei ,

1 F i F p,

with at least one strict inequality. Therefore, we have p

p

Ý

fi Ž x1 . -

is1

Ý fi Ž x . y g , is1

which contradicts Ž10.. Thus x is an e-Pareto solution of ŽP.. THEOREM 3.3. If for sufficiently large r , x is a g-solution for Ž ur ., then x is an almost e-Pareto solution for ŽP. and there exist scalars e iG 0 Ž1 F i F p ., e jG 0 Ž1 F j F m., l jG 0 Ž1 F j F m. such that: p

Ž i. 0 g

m

Ý ­ e fi Ž x . q Ý ­ e Ž l j g j . Ž x . , i

is1

p

Ž ii .

j

js1

m

m

Ý e i q Ý e j y g F Ý l j g j Ž x . F 0. is1

js1

js1

Proof. If x is a g-solution of Problem Ž ur ., p

p

Ý f i Ž x . F u Ž x, r . F Ý f i Ž x . q g , is1

is1

for all x g F.

254

J. C. LIU

Since p

inf

p

Ý fi Ž x . F Ý fi Ž x . ,

xgR n is1

is1

we have p

m

r

p

inf Ý f i Ž x . y Ý p Ž g j Ž x . . F xgF

js1

is1

inf n

xgR

Ý fi Ž x . q g . is1

Let p

r0 Ž e . s g

inf

Ý

xgF is1

p

f i Ž x . y inf n xgR

Ý fi Ž x . q g is1

Then, there exists r F r 0 Ž e . such that pŽ gj Ž x. . F g ,

1 F j F m.

Hence, we have x g Fe . This concludes the proof of the theorem. 4. e-DUALITY THEOREM OF THE WOLFE TYPE The result of Theorem 3.1 is used to formulate such a dual problem of the Wolfe type for multiobjective programming as follows: maximize  L Ž x, l . < Ž x, l . g FD 4 ;

Ž D. here

p

½

m < FD s Ž x, l . g R n = Rq 0g

m

Ý ­ e fi Ž x . q Ý ­ e Ž l j g j . Ž x . , i

j

is1 p

m

js1

m

Ý e i q Ý e j y g F Ý l j g j Ž x . F 0, is1

js1

js1

5

e i G 0, 1 F i F p, e j G 0, 1 F j F m ,

e-PARETO

255

OPTIMALITY

and the vector Lagrangian function LŽ x, l. is defined by L Ž x, l . s f Ž x . q ²² l , g Ž x . :: s

¦

m

f 1 Ž x . q Ž 1rp .

m

;

Ý l j g j Ž x . , . . . , f p Ž x . q Ž 1rp . Ý l j g j Ž x . js1

js1

,

for all x g R n, l j g R, 1 F j F m. m DEFINITION 4.1. A point Ž x, l. g R n = Rq is called an e-Pareto solution of ŽD. if Ž x, l. g FD and there is no Ž x, l. g FD , such that

m

f i Ž x . q Ž 1rp .

Ý

m

l j g j Ž x . G f i Ž x . q Ž 1rp .

js1

Ý l j g j Ž x . q ei ,

1 F i F p,

js1

with at least one strict inequality. THEOREM 4.1 ŽDuality.. If there exists r 0 such that x is a g-solution for Ž ur . for any r G r 0 , then x is an e-Pareto solution for ŽP. and there exist m scalars l g Rq such that Ž x, l. is an e-Pareto solution of ŽD., for all l j G l j, 1 F j F m. Proof. With Theorem 3.1, we conclude that Ž x, l. is a feasible solution m of ŽD.. Let Ž x, l. g R n = Rq be any feasible solution of ŽD.. Then, there U exist x i g ­ e i f i Ž x ., 1 F i F p, yUj g ­ e j Ž l j g j .Ž x ., 1 F j F m, such that p

m

Ý xUi q Ý yUj s 0, is1 p

js1

m

m

Ý e i q Ý e j y g F Ý l j g j Ž x . F 0. is1

js1

js1

By using the characterization of the e-subgradient, we obtain f i Ž x . G f i Ž x . q ² xUi , x y x : y e i ,

lj g j Ž x . G lj g j Ž x . q ²

yUj ,

x y x: y ej,

1 F i F p, 1 F j F m.

Thus, we have p

p

m

m

p

m

Ý fi Ž x . q Ý l j g j Ž x . G Ý fi Ž x . q Ý l j g j Ž x . y Ý ei y Ý e j is1

js1

is1

js1

is1

p

G

Ý fi Ž x . y g is1 p

G

Ý is1

m

fi Ž x . q

Ý lj g j Ž x . y g . js1

js1

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J. C. LIU

Since l j G l j and g j Ž x . F 0, for all 1 F j F m, m

m

lj g j Ž x . G

Ý

Ý lj g j Ž x . .

js1

js1

We then deduce that p

m

fi Ž x . q

Ý is1

Ý lj g j Ž x . q g js1

p

G

Ý

m

fi Ž x . q

is1

Ý lj gj Ž x . ,

for all Ž x, l . g FD .

Ž 11 .

js1

If Ž x, l. is not an e-Pareto solution of the dual problem ŽD., there exists Ž x*, l*. g FD such that m

f i Ž x* . q Ž 1rp .

Ý lUj g j Ž x*. js1 m

G f i Ž x . q Ž 1rp .

Ý l j g j Ž x . q ei ,

1 F i F p,

js1

with at least one strict inequality. Thus, we have p

Ý is1

m

f i Ž x* . q

Ý js1

p

lUj g j Ž x* . )

Ý is1

m

fi Ž x . q

Ý lj g j Ž x . q g js1

which contradicts Ž11.. THEOREM 4.2 ŽConverse Duality.. Let x be a feasible solution of ŽP.. If Ž x, l. is a feasible solution of ŽD., x is an e-Pareto solution of ŽP.. Proof. It follows from Theorem 3.2. 5. VECTOR LAGRANGIAN AND ITS e-PARETO SADDLE POINT In this section, we consider the e-Pareto saddle point of the vector Lagrangian function.

e-PARETO

257

OPTIMALITY

m DEFINITION 5.1. A point Ž x, l. g R n = Rq is called an e-Pareto saddle point of the vector Lagrangian LŽ x, l. if the following conditions hold:

Ž i.

L Ž x, l . sŽ p. L Ž x, l . q e ,

m for all l g Rq ;

Ž ii .

L Ž x, l . sŽ p. L Ž x, l . q e ,

for all x g R n .

m That is to say, there exist neither l g Rq nor x g R n such that:

m

Ž i.

Ý lj g j Ž x .

f i Ž x . q Ž 1rp .

js1 m

G f i Ž x . q Ž 1rp .

Ý l j g j Ž x . q ei ,

1 F i F p,

js1

with at least one strict inequality, m

Ž ii .

Ý l j g j Ž x . q ei

f i Ž x . q Ž 1rp .

js1 m

F f i Ž x . q Ž 1rp .

Ý lj g j Ž x . ,

1 F i F p,

js1

with at least one strict inequality. THEOREM 5.1. If there exists r 0 such that x is a g-solution for Ž ur . for any m r G r 0 , then x is an e-Pareto solution for ŽP. and there exist scalars l g Rq such that Ž x, l. is an e-Pareto-saddle point of the ¨ ector Lagrangian. m Proof. With Theorem 3.1, there exist l g Rq such that

p

0g

m

Ý ­ e fi Ž x . q Ý ­ e Ž l j g j . Ž x . , i

j

is1 p

m

m

Ý e i q Ý e j y g F Ý l j g j Ž x . F 0. is1

Ž 12 .

js1

js1

Ž 13 .

js1

Then, there exist xUi g ­ e i f i Ž x ., 1 F i F p, yUj g ­ e j Žl j g j .Ž x ., 1 F j F m, such that p

Ý is1

xUi q

m

Ý yUj s 0. js1

258

J. C. LIU

By using the characterization of the e-subgradient, we obtain f i Ž x . G f i Ž x . q ² xUi , x y x : y e i ,

lj g j Ž x . G lj g j Ž x . q ²

yUj ,

1 F i F p,

x y x: y ej,

1 F j F m.

Thus, we have p

p

m

p

m

m

Ý fi Ž x . q Ý l j g j Ž x . G Ý fi Ž x . q Ý l j g j Ž x . y Ý ei y Ý e j is1

js1

is1

js1

is1

js1

p

G

Ý fi Ž x . y g is1 p

G

m

Ý fi Ž x . q Ý l j g j Ž x . y g , is1

for all x g R n .

js1

Ž 14 . Assume that there is an x* g R n such that m

f i Ž x* . q Ž 1rp .

Ý l j g j Ž x*. q e i js1 m

F f i Ž x . q Ž 1rp .

Ý lj g j Ž x . ,

1 F i F p,

js1

with at least one strict inequality, we obtain p

Ý

p

m

f i Ž x* . q

is1

Ý

l j g j Ž x* . q g -

js1

m

Ý fi Ž x . q Ý l j g j Ž x . , is1

js1

which contradicts Ž14.. This gives the first condition of the definition for e-Pareto saddle point. With Ž13., we deduce that p

m

m

Ý l j g j Ž x . q g G Ý e i q Ý e j G 0. js1

is1

js1

m Since x g F, Ý mjs1 l j g j Ž x . F 0, for all l g Rq . Thus, we have

m

Ý js1

m

lj g j Ž x . q g G

Ý lj g j Ž x . js1

m for all l g Rq .

e-PARETO

259

OPTIMALITY

Therefore, we obtain p

m

Ý fi Ž x . q Ý l j g j Ž x . q g is1

js1 p

G

m

Ý fi Ž x . q Ý l j g j Ž x . , is1

m for all l g Rq .

Ž 15 .

js1

m If there is a l* g Rq such that

m

f i Ž x . q Ž 1rp .

Ý lUj g j Ž x . js1 m

G f i Ž x . q Ž 1rp .

Ý l j g j Ž x . q ei ,

1 F i F p,

js1

with at least one strict inequality, we obtain p

m

p

js1

is1

m

Ý f i Ž x . q Ý lUj g j Ž x . ) Ý f i Ž x . q Ý l j g j Ž x . q g is1

js1

which contradicts Ž15.. This completes the proof. THEOREM 5.2. If Ž x, l. is an e-Pareto saddle point of the ¨ ector Lagrangian L and g j Ž x . F g j Ž x ., 1 F j F m, for all x g F, then x is an almost e-Pareto solution of ŽP.. Proof. If Ž x, l. is an e-Pareto saddle point of the vector Lagrangian L, m there is no l g Rq such that m

f i Ž x . q 1rp

m

Ý l j g j Ž x . G f i Ž x . q 1rp Ý l j g j Ž x . q e i , js1

1 F i F p,

js1

Ž 16 . with at least one strict inequality. If x f Fe , g k Ž x . ) g ) ei for some k and all i. Thus, we have g k Ž x . q lk g k Ž x . ) lk g k Ž x . q ei for all i.

260

J. C. LIU

Choose l k s 1 q l k and l j s l j for all j / k for LŽ x, l.; we obtain m

f i Ž x . q 1rp

m

Ý l j g j Ž x . s f i Ž x . q 1rp Ž 1 q lk . g k Ž x . q 1rp Ý l j g j Ž x . js1

j/k m

) f i Ž x . q 1rp

Ý l j g j Ž x . q ei js1 m

s f i Ž x . q 1rpl k g k Ž x . q 1rp

Ý l j g j Ž x . q ei j/k

for all i which contradicts Ž16.. We conclude that x g Fe . Now, we use the other inequality for an e-Pareto saddle point. Then, there is no x g R n such that m

f i Ž x . q Ž 1rp .

m

Ý l j g j Ž x . G f i Ž x . q Ž 1rp . Ý l j g j Ž x . q e i , js1

1 F i F p,

js1

with at least one strict inequality. From gj Ž x. F gj Ž x. ,

1 F j F m,

for all x g F ,

we conclude that there is no x g F such that fi Ž x . F fi Ž x . y ei ,

1 F i F p,

with at least one strict inequality. This concludes the proof of the theorem.

ACKNOWLEDGMENTS The author is thankful to Dr. Koichi Mizukami of Hirosaki University for his comments and suggestions on an earlier version of the paper, especially on the proof of Theorem 5.2.

REFERENCES 1. S. S. Kutateladze, Convex e-programming, So¨ iet. Math. Dokl 20 Ž1979., 391]393. 2. P. Loridan, Necessary conditions for e-optimality, Math. Programming Study 19 Ž1982., 140]152. 3. P. Loridan and J. Morgan, Penalty functions in e-programming and e-minimax problems, Math. Programming 26 Ž1983., 213]231. 4. P. Loridan, e-Solution in vector minimization problems, J. Optim. Theory Appl. 43 Ž1984., 265]267.

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