Corner points of the feasible region determined by the system of linear constraints are `(0, 3), (1, 1) and (3, 0)`. Let `z=px+qy`, where `p, q gt 0`. Condition on p and q so that the minimum of z occurs at (3, 0) and (1, 1) is

The corner points of the feasible region determined by the system linear constraints are (0,10), (5,5), (15,15), (0,20). Let Z = px+ qy, where p, q gt 0 , condition on p and q so that the maximum of Z occurs at both the points (15,15) and (0,20) is

The corner points of the feasible region determined by the system of linear constraints are (0,0), (0,40), (20,40), (60, 20), (60, 0). The objective function is Z = 4x + 3y. Compare the quantity in column in A and column B. Column A= Maximum of Z Column B= 325

Corner points of feasible region for an LPP are (0,2),(3,0),(6,0),(6,8) and (0,5). Let F=4 x+6 y be the objective function. The minimum value of F occur at

Let A(-1, 0), B(0, 0) and C(3, 3sqrt(3)) be three points. Then the bisector of angle ABC is :

Let P(-1, 0), Q(0, 0) and R(3, 3sqrt(3)) be three points. Then the equation of the bisector of the angle PQR is :

Show that the points P(- 2 , 3, 5) , Q (1, 2, 3) and R(7, 0, -1) are collinear.

find the direction ratios of the vector, joining the points P(2,3,0) and Q(-1,-2,-3) direction from P to Q.

The locus of the orthocenter of the triangle formed by the lines (1+p)x-py+p(1+p)=0,(1+q)x-qy+q(1+q)=0 and y=0 , where p ne q , is

Let P-=(-1, Q), Q-=(0, 0) and R-=(3, 3sqrt(3)) be three points. The equation of the bisector of the angle PQR is :

f: Z to Z is a linear function defined by f={(1,1),(0,-1),(2,3)} , find f(x)