Engineering Optimization: Theory and Practice, Fourth Edition

9.5 Example Illustrating the Calculus Method of Solution 559

Lets 4 be the displacement available for allocation to the first three members. Let
δ 3 be the displacement contribution due to the third member andf 3 ∗(s 4 ) he minimumt
weight of the first three members. Then

f 3 ∗(s 4 ) =min

x 3 ≥ 0

[x 3 +f 2 ∗(s 3 )] (E 11 )

wheres 3 is the resource available after allocation to stage 3 and is given by

s 3 =s 4 −δ 3 =s 4 −

1. 5625

x 3

From Eq. (E 10 ) we have

f 2 ∗(s 3 )=

4. 6169

s 4 − 1. 5625 /x 3

(E 12 )

and Eq. (E 11 ) can be written as

f 3 ∗(s 4 ) =min

x 3 ≥ 0

[

x 3 +

4. 6169 x 3

s 4 x 3 − 1. 5625

]

(E 13 )

As before, by letting

F (s 4 , x 3 )=x 3 +

4. 6169 x 3

s 4 x 3 − 1. 5625

(E 14 )

the minimum ofF, for any specified value ofs 4 , can be obtained as

∂F

∂x 3

= 1. 0 −

( 4. 6169 )( 1. 5625 )

(s 4 x 3 − 1. 5625 )^2

= 0 or x 3 ∗=

4. 2445

s 4

(E 15 )

f 3 ∗(s 4 )=x 3 ∗+

4. 6169 x∗ 3

s 4 x 3 ∗− 1. 5625

=

4. 2445

s 4

+

7. 3151

s 4

=

11. 5596

s 4

(E 16 )

Finally, lets 5 denote the displacement available for allocation to the first four
members. Ifδ 4 denotes the displacement contribution due to the fourth member, and
f 4 ∗(s 5 ) he minimum weight of the first four members, thent

f 4 ∗(s 5 ) =min

x 4 ≥ 0

[0. 6 x 4 +f 3 ∗(s 4 )] (E 17 )

where the resource available after allocation to the fourth member (s 4 ) is given by

s 4 =s 5 −δ 4 =s 5 −

1. 3500

x 4

(E 18 )

From Eqs. (E 16 ), (E 17 ), and (E 18 ), we obtain

f 4 ∗(s 5 ) =min

x 4 ≥ 0

[

0. 6 x 4 +

11. 5596

s 5 − 1. 3500 /x 4

]

(E 19 )

By setting

F (s 5 , x 4 )= 0. 6 x 4 +

11. 5596

s 5 − 1. 3500 /x 4