If `az^2+bz+1=0`, where `a,b in C`, `|a|=1/2` and have a root `alpha` such that `|alpha|=1` then `|abarb-b|=`

If the roots of the quadratic equation ax^(2)+bx-b=0 , where a , b in R such that a*b gt 0 , are alpha and beta , then the value of log_(|(beta-1)|)|(alpha-1)| is

If alpha " and "beta are the distinct roots of ax^(2)+bx+c=0 , where a,b and c are non-zero real numbers, then (a alpha^(2)+b alpha+6c)/(a beta^(2)+ b beta+9c)+(a beta^(2)+b beta+19c)/(a alpha^(2)+b alpha+ 13c) is equal to

If alpha is a complex constant such that alpha z^2+z+ baralpha=0 has a real root, then (a) alpha+ bar alpha=1 (b) alpha+ bar alpha=0 (c) alpha+ bar alpha=-1 (d)the absolute value of the real root is 1

Repeated roots : If equation f(x) = 0, where f(x) is a polyno- mial function, has roots alpha,alpha,beta,… or alpha root is repreated root, then f(x) = 0 is equivalent to (x-alpha)^(2)(x-beta)…=0, from which we can conclude that f(x)=0 or 2(x-alpha)[(x-beta)...]+(x-alpha)^(2)[(x-beta)...]'=0 or (x-alpha) [2 {(x-beta)...}+(x-alpha){(x-beta)...}']=0 has root alpha . Thus, if alpha root occurs twice in the, equation, then it is common in equations f(x) = 0 and f'(x) = 0. Similarly, if alpha root occurs thrice in equation, then it is common in the equations f(x)=0, f'(x)=0, and f'''(x)=0. If a_(1)x^(3)+b_(1)x^(2)+c_(1)x+d_(1)=0 and a_(2)x^(3)+b_(2)x^(2)+c_(2)x+d_(2)=0 have a pair of repeated roots common, then |{:(3a_(1),2b_(1),c_(1)),(3a_(2),2b_(2),c_(2)),(a_(2)b_(1)-a_(1)b_(2),c_(1)a_(2)-c_(2)a_(1),d_(1)a_(2)-d_(2)a_(1)):}|=

If alpha,beta re the roots of a x^2+c=b x , then the equation (a+c y)^2=b^2y in y has the roots a. alphabeta^(-1),alpha^(-1)beta b. alpha^(-2),beta^(-2) c. alpha^(-1),beta^(-1) d. alpha^2,beta^2

If a,b,c,d in R and all the three roots of az^3 + bz^2 + cZ + d=0 have negative real parts, then

If alphaa n dbeta(alpha

If alpha_1, ,alpha_2, ,alpha_n are the roots of equation x^n+n a x-b=0, show that (alpha_1-alpha_2)(alpha_1-alpha_3).......(alpha_1-alpha_n)=n(alpha_1^(n-1)+a)

If roots of the equation a x^2+b x+c=0 are alphaa n dbeta , find the equation whose roots are 1/alpha,1/beta (ii) -alpha,-beta (iii) (1-alpha)/(1+alpha),(1-beta)/(1+beta)

If roots alpha, beta of the equation (x^(2)-bx)/(ax-c)=(lambda-1)/(lambda+1) are such that alpha+ beta=0 , then the value of lambda is