In the given figure graph of `y=p(x)=x^(4)+ax^(3)+bx^(2)+cx+d` is given

The product of all imaginery roots of `p(x)=(0)` is

In the given figure graph of : y =p (x) = x ^(n)+a_(1) x ^(n-1) +a_(2) x ^(n-2)+ ….. + a _(n) is given. The product of all imaginary roots of p(x) =0 is:

In the given figure graph of y = P(x) = ax^(5) + bx^(4) + cx^(3) + dx^(2) + ex + f , is given. The minimum number of real roots of equation (P''(x))^(2) + P'(x).P'''(x) = 0 , is

In the given figure graph of : y =p (x) = x ^(n)+a_(1) x ^(n-1) +a_(2) x ^(n-2)+ …..+ a _(n) is given. The minimum number of real roots of equation (p' (x))^(2) +p(x)p''(x) =0 are:

If P(x)=x^(4)+ax^(3)+bx^(2)+cx+d,P(1)=P2=P(3)=0 then find P(4)

It is given that the graph of y=x^(4)+ax^(3)+bx^(2)+cx+d (where a,b,c,d are real) has at least 3 points of intersection with the x-axis.Prove that either there are exactly 4 distinct points of intersection or one of there 3 point of intersection is a local minimum or meximum.

Let alpha,beta,gamma are the roots of f(x)-=ax^(3)+bx^(2)+cx+d=0 .Then The condition for the product of two of the roots is-1 is

Let alpha , beta , gamma are the roots of (x)-=ax^(3)+bx^(2)+cx+d=0 Then The condition for roots of f(x)=0 are in G.Pis

Let alpha, beta, gamma are the roots of f(x)-=ax^(3)+bx^(2)+cx+d=0 . Then the condition for roots of f(x)=0 are in G.P is (A) ac^(3)=b^(3)d (B) a^(3)c=bd^(3) (C) ac=bd (D) a^(2)c=b^(2)d

If roots of the equation x^(4)-8x^(3)+bx^(2)+cx+16=0 are positive, then