Answer to Question #307113 in Quantitative Methods for Dolce

The given data is summarized in the following table

"\\begin{array}{|c|c|c|c|}\n\\hline\n& D_1 & D_2 & \\text{Profit}\\\\\n\\hline\n\\text{Product 1} & 1 & 3 & 3\\\\\n\\text{Product 2} & 2 & 2 & 5\\\\\n\\hline\n\\text{Available Time} & 860 & 1200 &\\\\\n\\hline\n\\end{array}"

Let "x_1, x_2" be the number of units of Product 1 and Product 2 to be produced respectively to get maximum profit. Then "x_1, x_2 \\ge 0".

The objective function is "z = 3x_1+ 5x_2" and the contraints are

"\\begin{aligned}\nx_1+ 2x_2 &\\le 860\\\\\n3x_1 + 2x_2 & \\le 1200\n\\end{aligned}" .

Hence the linear programming model for the given problem is

"\\text{Maximize } z = 3x_1+ 5x_2\\\\\n\\text{subject to}\\\\\n\\begin{aligned}\nx_1+ 2x_2 &\\le 860\\\\\n3x_1 + 2x_2 & \\le 1200\\\\\nx_1, x_2 &\\geq 0\n\\end{aligned}"

To solve the problem graphically, we consider the constraints as equations and draw straight lines. The graph of the equations is given below.

The feasible region is bounded by the extreme points OABC. Point B is the point of intersection obtained by solving the two equations. The values at these extreme points are tabulated below.

"\\begin{array}{|c|c|}\n\\hline\n\\text{Extreme point} & \\text{Value of }z = 3x_1 + 5x_2\\\\\n\\hline\nO(0,0) & 0\\\\\nA(400,0) & 1200\\\\\nB(170,345) & 2235\\\\\nC(0,430) & 2150\\\\\n\\hline\n\\end{array}"

From the table, the maximum value occurs at B(170, 345), and the maximum value is z = 2235.