If `|ax^2 + bx+c|<=1` for all x is `[0, 1]`,then

If ax^2 + bx + c = 0 and bx^2 + cx+a= 0 have a common root and a!=0 then (a^3+b^3+c^3)/(abc) is

If ax^(2)+ bx +c and bx ^(2) + ax + c have a common factor x +1 then show that c=0 and a =b.

In the quadratic equation ax^2 + bx + c = 0 . if delta = b^2-4ac and alpha+beta , alpha^2+beta^2 , alpha^3+beta^3 and alpha,beta are the roots of ax^2 + bx + c =0

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, that

If ax^2-bx + c=0 have two distinct roots lying in the interval (0,1); a, b,in N , then the least value of a , is

If alpha and beta are the roots of the equation ax^2 + bx +c =0 (a != 0; a, b,c being different), then (1+ alpha + alpha^2) (1+ beta+ beta^2) =

f(x)= x^(3) + ax^(2) + bx + c is real valued function in which a, b and c are selected by tossing one baised dice twice. Then ......... is the probability for f(x) becomes an increasing function.

If one root of the equation ax^2 + bx + c = 0 is equal to the n^(th) power of the other, then (ac^n)^(1/(n+1)) + (a^n c)^(1/(n+1)) + b is equal to

If alpha, beta be the roots of the equation ax^2 + bx + c= 0 and gamma, delta those of equation lx^2 + mx + n = 0 ,then find the equation whose roots are alphagamma+betadelta and alphadelta+betagamma

If ax^3 + bx^2 + cx + d is divisible by ax^2 + c , then a, b, c, d are in