Tangents to ` x^(2) //a^(2) -y^(2)//b^(2) =1 ` make angles ` theta_1 ,theta _2` with transverse axis . The equation of the locus of their intersection when ` cot theta _1 +cot theta _2 = k ` is

Tangents to the hyperbola x^(2)//a^(2) -y^(2)//b^(2)= 1 make angle theta_1 , theta _2 with the transverse axis. The equations o the locus of their intersection when tan (theta_1+theta_2 )=k is

Tangents to the ellipse x^(2)//a^(2)+y^(2)//b^(2)=1 make angles theta_(1), theta_(2) with the major axis. The equation of the locus of their point of intersection when tan(theta_(1)+theta_(2))=k is

Tangents to the hyperbola x^(2) //a^(2) -y^(2)//b^(2) =1 make angle theta_1 , theta _2 with the transverse axis .if theta_1 , theta _2 are complementary then the locus of the point of intcrsection of the tangents is

Tangents to the hyperbola x^(2)/a^(2)-y^(2)/b^(2)=1 makes angles theta_(1), theta_(2) with the transverse axis. If theta_(1), theta_(2) are complementary then the locus of the point of intersection of tangents is

Tangents to the hyperbola (x^(2))/(a^(2))-(y^(2))/(b^(2))=1 make angle theta_(1), theta_(2) with transvrse axis of a hyperbola. Show that the points of intersection of these tangents lies on the curve 2xy=k(x^(2)-a^(2)) when tan theta_(1)+ tan theta_(2)=k

Tangents drawn from (alpha , beta ) to the hyperbola x^(2) //a^(2) -y^(2)//b^(2) =1 make angles theta _1 and theta _2 with the axis .If tan theta _1 tan theta _2=1 then alpha ^(2) -beta ^(2) =

If cosec theta + cot theta = 1//3 then cosec theta - cot theta =

sqrt (sec^2 theta - tan^2 theta + cot^2 theta) =………

If tan theta + cot theta = 2, find the value of tan^2 theta + cot^2 theta .