If `0 lt c lt b lt a` and the roots `alpha, beta` the equation `cx^(2)+bx+a=0` are imaginary, then

If 0ltaltbltc and the roots alpha,beta of equation a"" x^2+b""x+c="0 are imaginary, then |alpha|="|beta| (b) |alpha|>1 |beta|<1 (d) None of these

If 0 lt a lt b lt c and the roots alpha,beta of the equation ax^2 + bx + c = 0 are non-real complex numbers, then

If c lt a lt b lt d , then roots of the equation bx^(2)+(1-b(c+d)x+bcd-a=0

If 0 gt a gt b gt c and the roots alpha, beta are imaginary roots of ax^(2) + bx + c = 0 then

If a lt c lt b then the roots of the equation (a−b)x^2 +2(a+b−2c)x+1=0 are

If alpha and beta (alpha lt beta) are the roots of the equation x^(2) + bx + c = 0 , where c lt 0 lt b , then

Let a gt 0, b gt 0 and c lt0. Then, both the roots of the equation ax^(2) +bx+c=0

If alpha, beta (alpha lt beta) are the roots of the equation 6x^(2) + 11x + 3 = 0 , then which of the following are real ?

If a , b , c are in geometric progresion and the roots of the equations ax^(2)+2bx+c=0 are alpha and beta and those of cx^(2)+2bx+a=0 are gamma and delta then

If alpha and beta are the roots of the equation x^(2)+alpha x+beta=0 such that alpha ne beta , then the number of integral values of x satisfying ||x-beta|-alpha|lt1 is