1. Polynomials - Chapter Importance

1. Polynomials of degrees \(1\), \(2\) and \(3\) are called linear, quadratic and cubic polynomials respectively. A quadratic polynomial in \(x\) with real coefficients is of the form \(ax^2 + bx + c\), where \(a\), \(b\), \(c\) are real numbers with a \(0\). A quadratic polynomial can have at most \(2\) zeroes and a cubic polynomial can have at most \(3\) zeroes.

 

2. The zeroes of a polynomial \(p(x)\) are precisely the \(x\)-coordinates of the points, where the graph of \(y = p(x)\) intersects the \(x\) -axis.

 

3. If \(\alpha \) is the zero of the linear polynomial \(p(x)=ax+b\) then

\(\alpha = \frac{-b}{a}\) \(= \frac{-\text{constant term}}{\text{coefficient of }x} \)

 

 

4. If \(\alpha, \beta\) is the zero of the linear polynomial \(p(x)=ax^2+bx+c\) then

\(\alpha+\beta = \frac{-b}{a} = \frac{-\text{coefficient of }x}{\text{coefficient of }x^2}\)

\(\alpha\beta = \frac{c}{a} = \frac{\text{constant term}}{\text{coefficient of }x^2}\)

The general form of the quadratic polynomial based on its zeros is given by

\(p(x)=x^2-(\text{sum of zeroes})x+\text{product of zeroes}\)

\(p(x)=x^2-(\alpha+\beta)x+\alpha\beta\).

 

 

5. If \(\alpha,\beta,\gamma\) is the zero of the linear polynomial \(p(x)=ax^3+bx^2+cx+d\) then

\(\alpha+\beta+\gamma = \frac{-b}{a} = \frac{-\text{coefficient of }x^2}{\text{coefficient of }x^3}\)

\(\alpha\beta+\beta\gamma+\gamma\alpha = \frac{c}{a} = \frac{\text{coefficient of }x}{\text{coefficient of }x^2}\)

\(\alpha\beta\gamma = \frac{-d}{a} = \frac{-\text{constant term}}{\text{coefficent of }x^3}\)

The general form of the cubic polynomial based on its zeros is given by

\(p(x)=x^3-(\text{sum of zeroes})x^2+(\text{taking two roots at a time})x-\text{product of zeroes}\)

 

\(p(x)=x^3-(\alpha+\beta+\gamma)x^2+(\alpha\beta+\beta\gamma+\gamma\alpha)x- \alpha\beta\gamma\).