In the given figure graph of `y = P(x) = ax^(5) + bx^(4) + cx^(3) + dx^(2) + ex + f`, is given.

If P''(x) has real roots `alpha, beta, gamma`, then `[alpha] + [beta] + [gamma]`, is

If the function f(x)=x^(3)-9x^(2)+24x+c has three real and distinct roots alpha, beta and gamma , then the value of [alpha]+[beta]+[gamma] is

In the given figure prove that g = alpha + beta + gamma .

In the given figure prove that g = alpha + beta + gamma .

ax^2 + bx + c = 0(a > 0), has two roots alpha and beta such alpha 2, then

In the fig. Prove that x=alpha+beta+gamma

Suppose alpha, beta are roots of ax^(2)+bx+c=0 and gamma, delta are roots of Ax^(2)+Bx+C=0 . If a,b,c are in GP as well as alpha,beta, gamma, delta , then A,B,C are in:

If a line makes anles alpha, beta, gamma with the coordinate axes, porve that sin^2alpha+sin^2beta+sin^2gamma=2

Let f(x) = x^2 + b_1x + c_1 . g(x) = x^2 + b_2x + c_2 . Real roots of f(x) = 0 be alpha, beta and real roots of g(x) = 0 be alpha+gamma, beta+gamma . Least values of f(x) be - 1/4 Least value of g(x) occurs at x=7/2

The curve x+y-log_(e)(x+y)=2x+5 has a vertical tangent at the point (alpha, beta). then alpha+beta is equal to

Let f(x)=x^(2) +ax + b and the only solution of the equation f(x)= min(f(x)) is x =0 and f(x) =0 "has root " alpha and beta, "then" int _(alpha )^(beta)x^(3) dx is equal to