# Ch06 - 1 MP CHAPTER 6 SOLUTIONS SECTION 6.1 1 Typical...

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MP CHAPTER 6 SOLUTIONS SECTION 6.1 1. Typical isoprofit line is 3x 1 +c 2 x 2 =z. This has slope -3/c 2 . If slope of isoprofit line is <-2, then Point C is optimal. Thus if -3/c 2 <-2 or c 2 <1.5 the current basis is no longer optimal. Also if the slope of the isoprofit line is >-1 Point A will be optimal. Thus if -3/c 2 >-1 or c 2 >3 the current basis is no longer optimal. Thus for 1.5 c 2 3 the current basis remains optimal. For c 2 = 2.5 x 1 = 20, x 2 = 60, but z = 3(20) + 2.5(60) = \$210. 2. Currently Number of Available Carpentry Hours = b 2 = 80. If we reduce the number of available carpentry hours we see that when the carpentry constraint moves past the point (40,20) the carpentry and finishing hours constraints will be binding at a point where x 1 >40. In this situation b 2 <40 + 20 = 60. Thus for b 2 <60 the current basis is no longer optimal. If we increase the number of available carpentry hours we see that when the carpentry constraint moves past (0,100) the carpentry and finishing hours constraints will both be binding at a point where x 1 <0. In this situation b 2 >100.Thus if b 2 >100 the current basis is no longer optimal. Thus the current basis remains optimal for 60 b 2 100. If 60 b 2 100, the number of soldiers and trains produced will change. 3. If b 3 , the demand for soldiers, is increased then the current basis remains feasible and therefore optimal. If, however, b 3 <20 then the point where the finishing and carpentry constraints are binding is no longer feasible (it has s 3 <0). Thus for b 3 >20 the current basis remains optimal. For b 3 >20 the point where the carpentry and finishing constraints are still binding remains at (20, 60) so producing 20 soldiers and 60 trains remains optimal. 4. and 5. See answers to Section 5.1 SECTION 6.2 1. BV = {x 1 , x 2 } B = - - 1 1 1 2 B -1 = 2 1 1 1 c BV = [3 1] 1

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c BV B -1 = [4 5] Coefficient of s 1 in row 0 = 4 Coefficient of s 2 in row 0 = 5 Right hand Side of row 0 = c BV B -1 b = [4 5] 4 2 = 28 s 1 column = B -1 0 1 = 1 1 s 2 column = B -1 1 0 = 2 1 x 1 column = 0 1 x 2 column = 1 0 Right hand Side of Constraints = B -1 b = 2 1 1 1 4 2 = 10 6 Thus the optimal tableau is Z + 4s 1 + 5s 2 = 28 x 1 + s 1 + s 2 = 6 x 2 + s 1 + 2s 2 = 10 2. BV = {x 2 ,s 1 } B = 0 1 1 1 B -1 = - 1 1 1 0 c BV = [1 0] c BV B -1 = [1 0] - 1 1 1 0 = [0 1] Coefficient of x 1 in row 0 = c BV B -1 a 1 -c 1 = [0 1] 1 2 +1=2 2
Coefficient of s 2 in row 0 = c BV B -1 1 0 = 1 RHS of row 0 = c BV B -1 b = [0 1] 2 4 = 2 Column for x 1 = B -1 a 1 = - 1 1 1 0 1

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Ch06 - 1 MP CHAPTER 6 SOLUTIONS SECTION 6.1 1 Typical...

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