Let `F1,F_2` be two focii of the ellipse and `PT and PN` be the tangent and the normal respectively to the ellipse at ponit P.then

Find the equation of tangent and normal to the ellipse x^2+8y^2=33 at (-1,2).

P is the point on the ellipse is x^2/16+y^2/9=1 and Q is the corresponding point on the auxiliary circle of the ellipse. If the line joining the center C to Q meets the normal at P with respect to the given ellipse at K, then find the value of CK.

Let F_1(x_1,0)" and "F_2(x_2,0) , for x_1 lt 0 " and" x_2 gt 0 , be the foci of the ellipse (x^2)/(9)+(y^2)/(8)=1 . Suppose a parabola having vertex at the origin and focus at F_2 intersects the ellipse at point M in the first quadrant and at point N in the fourth quadrant. If the tangents to the ellipse at M and N meet at R and the normal to the parabola at M meets the x-axis at Q, then the ratio of the area of the triangle MQR to area of the quadrilateral MF_1NF_2 is :

Let C : x^(2) + y^(2) = 9, E : (x^(2))/(9) + (y^(2))/(4) =1 and L : y = 2x be three curves P be a point on C and PL be the perpendicular to the major axis of ellipse E. PL cuts the ellipse at point M. If equation of normal to C at point P be L : y = 2x then the equation of the tangent at M to the ellipse E is

A tangent to the ellipse x^2+4y^2=4 meets the ellipse x^2+2y^2=6 at P&Q.

The product of the perpendiculars drawn from the two foci of an ellipse to the tangent at any point of the ellipse is

Let the line y=mx and the ellipse 2x^(2)+y^(2)=1 intersect at a point P in the first quadrant. If the normal to this ellipse at P meets the co - ordinate axes at (-(1)/(3sqrt2),0) and (0, beta) , then beta is equal to

Let the line y=mx and the ellipse 2x^(2)+y^(2)=1 intersect at a point P in the first quadrant. If the normal to this ellipse at P meets the co - ordinate axes at (-(1)/(3sqrt2),0) and (0, beta) , then beta is equal to

Let P be a point on the ellipse x^2/100 + y^2/25 =1 and the length of perpendicular from centre of the ellipse to the tangent to ellipse at P be 5sqrt(2) and F_1 and F_2 be the foci of the ellipse, then PF_1.PF_2 .

Let d be the perpendicular distance from the centre of the ellipse x^2/a^2+y^2/b^2=1 to the tangent drawn at a point P on the ellipse. If F_1 & F_2 are the two foci of the ellipse, then show the (PF_1-PF_2)^2=4a^2[1-b^2/d^2] .