Fot the curve y = f (x), prove that
`(("length of normal")^(2))/(("length of tangent"))=("sub-normal")/("sub-tangent").`

For the curve y=f(x) prove that (lenght of normal)^2/(lenght of tangent)^2 =length of sub-normal/length of sub-tangent

For a curve (length of normal)^2/(length of tangent)^2 is equal to

Consider curve y=f(x), then if PT = Length of tangent PN= Length of normal TM=Length of subtangent MN=Length of sub normal, then (a) T MdotM N=f^(prime)(x) (b) (P T)/(P N)=1/(f^(prime)(x)) (c) C TdotP N=con s t a n t (d) P TdotT M=con s t a n t

For the curve y=a1n(x^2-a^2) , show that the sum of length of tangent and sub-tangent at any point is proportional to product of coordinates of point of tangency.

For the curve y=a1n(x^2-a^2) , show that the sum of length of tangent and sub-tangent at any point is proportional to product of coordinates of point of tangency.

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 .

At any point on the curve 2x^2y^2-x^4=c , the mean proportional between the abscissa and the difference between the abscissa and the sub-normal drawn to the curve at the same point is equal to (a)Ordinate (b) radius vector (c)x-intercept of tangent (d) sub-tangent

Find all the curves y=f(x) such that the length of tangent intercepted between the point of contact and the x-axis is unity.

Let P be any point on the curve x^(2//3)+y^(2//3)=a^(2//3). Then the length of the segment of the tangent between the coordinate axes in of length

Let P be any point on the curve x^(2//3)+y^(2//3)=a^(2//3). Then the length of the segment of the tangent between the coordinate axes in of length