Engineering Optimization: Theory and Practice, Fourth Edition

Problems 489

Determine whether the solution

X=







√^0

√^2

2







is optimum by finding the values of the Lagrange multipliers.

7.43 Determine whether the solution

X=







√^0

√^2

2







is optimum for the problem considered in Example 7.8 using a perturbation method with

    xi= 0 .001,i= 1 , 2 ,3.

7.44 The following results are obtained during the minimization of

f (X)= 9 − 8 x 1 − 6 x 2 − 4 x 3 + 2 x 12 + 2 x 22 +x^23 + 2 x 1 x 2 + 2 x 1 x 3

subject to

x 1 +x 2 + 2 x 3 ≤ 3

xi≥ 0 , i= 1 , 2 , 3

using the interior penalty function method:

Starting point for
minimization of Unconstrained minimum
Value ofri φ (X, ri) ofφ (X, ri)=X∗i f (X∗i)=fi∗

1







0. 1

0. 1

0. 1













0. 8884

0. 7188

0. 7260







0.7072

0.01







0. 8884

0. 7188

0. 7260













1. 3313

0. 7539

0. 3710





 0.1564

0.0001







1. 3313

0. 7539

0. 3710













1. 3478

0. 7720

0. 4293







0.1158

Use an extrapolation technique to predict the optimum solution of the-problem using the

following relations:

(a) X(r) =A 0 +rA 1 ;f (r)=a 0 +ra 1

(b) X(r) =A 0 +r^1 /^2 A 1 ;f (r)=a 0 +r^1 /^2 a 1

Compare your results with the exact solution

X∗=











12

9

7

9

4

9











, fmin=^19