Find the equation of the curve in which the subnormal varies as the square of the ordinate.

For the equation of the curve whose subnormal is constant then,

The equation of the curve whose subnormal is constant is

Prove that for the curve y=be^(x//a) , the subtangent is of constant length and the sub-normal varies as the square of the ordinate .

The equation of the curve whose subnormal is twice the abscissa, is

In the curve y=c e^(x/a) , the sub-tangent is constant sub-normal varies as the square of the ordinate tangent at (x_1,y_1) on the curve intersects the x-axis at a distance of (x_1-a) from the origin equation of the normal at the point where the curve cuts y-a xi s is c y+a x=c^2

Find the equation of the curve which is such that the area of the rectangle constructed on the abscissa of and the initial ordinate of the tangent at this point is a constanta =a^2 .

If the length of the portion of the normal intercepted between a curve and the x-axis varies as the square of the ordinate, find the equation of the curve.

Find the equation of the circle which lies in the first quadrant and touching each-co ordinate-axis at a distance of 2 units from the origin.

The co-ordinates of the vertex A of a square ABCD are (1, 2) and the equation of the diagonal BD is x+2y= 10 . Find the equation of the other diagonal and the co-ordinates of the centre of the square.

Find the equation of a line which makes a triangle of area 96sqrt(3) square from co-ordinate axes and the perpendicular drawn from origin to this line makes an angle 60^(@) from X -axis.