C is the centre of the ellipse `(x^(2))/(a^(2))+(y^(2))/(b^(2)) = 1` and L is an end of a latusrectum. If the normal at L meets the major axis at G then CG =

If the ecentricity of the ellipse (x^(2))/( a^(2) +1) +(y^(2))/(a^(2)+2) =1 be (1)/(sqrt6) then length of the latusrectum of the ellipse is

The eccentric angles of the ends of L.R. of the ellipse (x^(2)/(a^(2))) + (y^(2)/(b^(2))) = 1 is

Assertion (A) If the tangent and normal to the ellipse 9x^(2)+16y^(2)=144 at the point P(pi/3) on it meet the major axis in Q and R respectively, then QR=(57)/(8) . Reason (R) If the tangent and normal to the ellipse (x^(2))/(a^(2))+(y^(2))/(b^(2))= at the point P(theta) on it meet the major axis in Q and R respectively, then QR=|(a^(2)sin^(2)theta-b^(2)cos^(2)theta)/(a cos theta)| The correct answer is

P is a point on the ellipse (x^(2))/(a^(2)) +(y^(2))/( b^(2)) =1 with foci at S, S^(-1). Normal at P cuts the x-axis at G and (SP)/( S^(1)P) =(2)/(3) then (SG)/( S^(1)G)

The equation of the tangent to the ellipse 9x^(2)+16y^(2)=144 at the positive end of the latusrectum is

If the normal at one end of latusrectum of an ellipse (x^(2))/(a^(2))+(y^(2))/(b^(2))=1 passes through one end of minor axis then

The tangent at 'p' on the ellipse (x^(2))/(a^(2))+(y^(2))/(b^(2))=1 cuts the major axis in T and PN is the perpendicular to the x-axis, C being centre then CN.CT =