Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty...

Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty...

Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty or the objective function is unbounded. HINT [See Example 1.] (Enter EMPTY if the region is empty. Enter UNBOUNDED if the function is unbounded.) Maximize p = 3x + y subject to 5x − 8y ≤ 0 8x − 5y ≥ 0 x + y ≤ 13 x ≥ 0, y ≥ 0. p = ? (x, y) = ?

1. Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is...

1. Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty or the objective function is unbounded. HINT [See Example 1.] (Enter EMPTY if the region is empty. Enter UNBOUNDED if the function is unbounded.) Maximize p = 3x + 2y subject to 1.8x + 0.9y ≤ 9 0.15x + 0.3y ≤ 1.5 8x + 8y ≤ 48 x ≥ 0, y ≥ 0. p = (x,y) = 2. Solve the LP problem. If...

Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty...

Solve the LP problem. If no optimal solution exists, indicate whether the feasible region is empty or the objective function is unbounded. HINT [See Example 1.] (Enter EMPTY if the region is empty. Enter UNBOUNDED if the function is unbounded.) Maximize and minimize p = x + 2y subject to x + y ≥ 2 x + y ≤ 10 x − y ≤ 2 x − y ≥ −2. Minimum: p= (x,y)= Maximum: p= (x,y)=

Consider the following Linear Programming model: Maximize x+2.5y Subject to x+3y<=12 x+2y<=11 x-2y<=9 x-y>=0 x+5y<=15 x>=0...

Consider the following Linear Programming model: Maximize x+2.5y Subject to x+3y<=12 x+2y<=11 x-2y<=9 x-y>=0 x+5y<=15 x>=0 y>=0 (a) Draw the feasible region for the model, but DO NOT draw the objective function. Without graphing the objective function, find the optimal solution(s) and the optimal value. Justify your method and why the solution(s) you obtain is (are) optimal. (4 points) (b) Add the constraint “x+5y>=15” to the Linear Programming model. Is the optimal solution the same as the one in (a)?...

Given the following linear optimization problem Maximize 10x + 20y Subject to x + y ≤...

Given the following linear optimization problem Maximize 10x + 20y Subject to x + y ≤ 50 2x + 3y ≤ 120 x ≥ 10 x, y ≥ 0 (a) Graph the constraints and determine the feasible region. (b) Find the coordinates of each corner point of the feasible region. (c) Determine the optimal solution and optimal objective function value.

1. It is impossible for a linear program with unbounded feasible region to have a unique...

1. It is impossible for a linear program with unbounded feasible region to have a unique optimal solution. True or False? 2. It is impossible for an integer program to have infinitely many optimal solutions. True or False? 3. When we solve an integer program with a minimization objective using Branch and Bound, we can discard a subproblem for which the optimal objective value of the associated LP is larger than the objective value of the incumbent solution. True or...

Solve the linear programming problem by sketching the region and labeling the vertices, deciding whether a...

Solve the linear programming problem by sketching the region and labeling the vertices, deciding whether a solution exists, and then finding it if it does exist. (If an answer does not exist, enter DNE.) Maximize P = 10x + 6y Subject to 2x + y ≤ 90 x + y ≤ 50 x + 2y ≤ 90 x ≥ 0, y ≥ 0

Solve the linear programming problem by sketching the region and labeling the vertices, deciding whether a...

Solve the linear programming problem by sketching the region and labeling the vertices, deciding whether a solution exists, and then finding it if it does exist. (If an answer does not exist, enter DNE.) Minimize C = 10x + 50y Subject to      2x + 5y ≥ 20 x ≥ 0,  y ≥ 0 C =

Solve the LP problem using graphical method. Determine the optimal values of the decision variables and...

Solve the LP problem using graphical method. Determine the optimal values of the decision variables and compute the objective function. Minimize Z = 2x1 + 3x2 Subject to             4x1 + 2x2 ≥ 20             2x1 + 6x2 ≥ 18               x1 + 2x2 ≤ 12 x1, x2  ≥ 0 with solution! thak you so much :D

Solve the linear programming problem by the simplex method. Maximize   P = 5x + 4y subject...

Solve the linear programming problem by the simplex method. Maximize   P = 5x + 4y subject to   3x + 5y ≤ 214 4x + y ≤ 172 x ≥ 0, y ≥ 0    The maximum is P = at (x, y) = .