If `alpha` is a complex constant such that `alpha z^2+z+bar( alpha)=0` has a real root, then

Let alpha and beta be two distinct complex numbers, such that abs(alpha)=abs(beta) . If real part of alpha is positive and imaginary part of beta is negative, then the complex number (alpha+beta)//(alpha-beta) may be

Statement I The system of linear equations x+(sin alpha )y+(cos alpha )z=0 x+(cos alpha ) y+(sin alpha )z=0 -x+(sin alpha )y-(cos alpha )z=0 has a not trivial solution for only one value of alpha lying between 0 and pi . Statement II |{:(sin x, cos x , cos x),( cos x , sin x , cos x) , (cos x , cos x , sin x ):}|=0 has no solution in the interval -pi//4 lt x lt pi//4 .

If alpha is a root of the equation 4x^2+2x-1=0, then prove that 4alpha^3-3alpha is the other root.

Let alpha and beta be real numbers and z be a complex number. If z^(2)+alphaz+beta=0 has two distinct non-real roots with Re(z)=1, then it is necessary that

If 4nalpha =pi then cot alpha cot 2 alpha cot 3alpha ...cot (2n-1)alpha n in Z is equal to

If alpha is a root of 25 cos^2 theta+ 5 cos theta- 12 = 0,pi/2 < alpha< pi , then sin 2 alpha is equal to :

Let alpha be a real number such that 0 <= alpha <= pi. If f(x)=cosx+cos(x+alpha)+cos(x+2alpha) takes some constant number c for any x in R, then the value of [c + alpha] is equal to (Note : [y] denotes greatest integer less than or equal to y.)

If alpha is the nth root of unity then prove that 1+2 alpha+ 3 alpha^2+…. upto n terms

Let alpha and beta be non-zero real numbers such that 2 ( cos beta - cos alpha) + cos alpha cos beta =1 . Then which of the following is/are true ?

f: D->R, f(x) = (x^2 +bx+c)/(x^2+b_1 x+c_1) where alpha,beta are the roots of the equation x^2+bx+c=0 and alpha_1,beta_1 are the roots of x^2+b_1 x+ c_1= 0 . Now answer the following questions for f(x). A combination of graphical and analytical approach may be helpful in solving these problems. (If alpha_1 and beta_1 are real, then f(x) has vertical asymptote at x = (alpha_1,beta_1) If alpha_1 lt alpha lt beta_1 lt beta , then