If the plane `2 x-3 y+6z-11=0` makes an angle `sin ^-1(lambda)` with `x` -axis, then `lambda` is equal to

Let L be the line of intersection of the planes 2x+3y+z=1a n dx+3y+2z=2. If L makes an angle alpha with the positive x-axis, then cosalpha equals a. 1/2 b. 1 c. 1/(sqrt(2)) d. 1/(sqrt(3))

If the line (x-2)/(3)=(y+1)/(2)=(z-1)/(-1) intersects the plane 2x+3y-z+13=0 at a point P and the plane 3x+y+4z=16 at a point Q, then PQ is equal to

If the equation |x^2-5x + 6|-lambda x+7 lambda=0 has exactly 3 distinct solutions then lambda is equal to

If a circle passes through the point of intersection of the lines lambdax- y +1=0 and x-2y+3=0 with the coordinate axis, then value of lambda is

If the equations 2x-lambday+5z=7 and lambda x-8y-10z+14=0 represent the same plane then lambda is :

If the lines 3x + 4y+ 1 = 0, 5x +lambda y + 3 = 0 and 2x + y-1 = 0 are concurrent, then lambda=

Consider point A(6, 30), point B(24, 6) and line AB: 4x+3y = 114. Point P(0, lambda) is a point on y-axis such that 0 lt lambda lt 38 " and point " Q(0, lambda) is a point on y-axis such that lambda gt 38 . For all positions of pont P, angle APB is maximum when point P is

Consider point A(6, 30), point B(24, 6) and line AB: 4x+3y = 114. Point P(0, lambda) is a point on y-axis such that 0 lt lambda lt 38 " and point " Q(0, lambda) is a point on y-axis such that lambda gt 38 . The maximum value of angle APB is

Find the equation of the plane through the intersection of the planes x + 3y + 6 = 0 and 3x - y - 4z = 0 whose perpendicular distance from the orgin is equal to 1.