Family of lines `x sec^(2) theta + y tan^(2)theta -2=0` for different real `theta`, is

Solve 3(sec^(2) theta+tan^(2) theta)=5 .

Prove that sec^(2)theta-1-tan^(2)theta=0

Prove that (sec^(2)theta-1)/(tan^(2)theta)=1

If "sec"^(2) theta = sqrt(2) (1-"tan"^(2) theta), "then" theta=

The family of lines (2 cos theta + 3 sin theta) x + (3 cos theta - 5 sin theta) y-(5 cos theta - 2 sin theta) = 0 is concurrent at (x_1, y_1) and the family of lines (a+2b) x+(a-3b) y+b-a=0 for different values of a and b is concurrent at (x_2, y_2) then : (A) x_2 + y_2 = x_1 (B) x_2 + y_2 = y_1 (C) 6x_2 + y_2 = 2x_1 + y_1 (D) none of these

Statement-1: f(theta) = sin^(2)theta+ cos^(2)theta then f(theta)=1 for every real values of theta . Statement:2: g(theta) = sec^(2)theta - tan^(2)theta . then g(theta) =1 for every real value of theta . Statement-3: f(theta) = g(theta) for every real value of theta .

Solve sqrt(2) sec theta+tan theta=1 .

If 1+ tan^(2) theta = sec^(2) theta then find (sec theta + tan theta)

If the length of the latusrectum of the ellipse x^(2) tan^(2) theta + y^(2) sec^(2) theta = 1 is 1/2, then theta =

If a chord joining P(a sec theta, a tan theta), Q(a sec alpha, a tan alpha) on the hyperbola x^(2)-y^(2) =a^(2) is the normal at P, then tan alpha is (a) tan theta (4 sec^(2) theta+1) (b) tan theta (4 sec^(2) theta -1) (c) tan theta (2 sec^(2) theta -1) (d) tan theta (1-2 sec^(2) theta)