Prove that , `(x - alpha )^(2) + (y - beta)^(2) = a^(2) . ` for all ` alpha " and " beta `
satisfiles the differential equation `(1 + y_(1)^(2))^(3) = (ay_(2))^(2)`.

The differential equation whose solution is (x - alpha)^(2) + (y - beta)^(2) = a^(2) [ for all alpha " and " beta where a is constant ] of is -

Prove that (cos alpha - cos beta)^(2) +(sin alpha - sin beta)^(2) = 4 "sin"^(2) (alpha-beta)/2

The equation (x-alpha)^2+(y-beta)^2=k(l x+m y+n)^2 represents

Prove that (cos2 alpha-cos 2 beta)/(sin2 alpha+sin2 beta)=tan(beta-alpha)

Prove that , tan(alpha+beta)tan(alpha-beta)=(sin^2alpha-sin^2beta)/(cos^2alpha-sin^2beta)

If tan^(2) alpha = 1 + 2 tan^(2) beta, "prove that ," cos 2 beta = 1 + 2 cos 2 alpha

If tan alpha =(1+2^(-x))^(-1) and tan beta =(1+2^(x+1))^(-1) then the value of (alpha + beta) is-

Prove that 2tan^(-1)[tan((alpha)/(2)) tan((pi)/(4)-(beta)/(2))]=tan^(-1)((sin alpha cos beta)/(cos alpha+sin beta))

If tan (alpha - beta) = 1, "sec" (alpha + beta) = 2/(sqrt3) , find positive magnitude of alpha and beta .

The locus of a point P ( alpha , beta ) moving under the condition that the line y= alpha x + beta is a tangent to the hyperbola (x^(2))/(a^(2)) - (y^(2))/(b^(2))=1 is a/an-