Polynomials

Polynomials - Formulas & Theorems

IB Mathematics Analysis & Approaches (SL & HL)

📐 Polynomial Definition

General Form:

A polynomial of degree \(n\) has the form:

\[P(x) = a_nx^n + a_{n-1}x^{n-1} + \cdots + a_2x^2 + a_1x + a_0\]

where \(a_n \neq 0\), \(a_i\) are real constants, and \(n\) is a non-negative integer

Key Terms:

Degree: The highest power of \(x\) (which is \(n\))

Leading Term: The term with the highest power (\(a_nx^n\))

Leading Coefficient: The coefficient of the leading term (\(a_n\))

Common Polynomial Types:

• Degree 1: Linear → \(ax + b\)

• Degree 2: Quadratic → \(ax^2 + bx + c\)

• Degree 3: Cubic → \(ax^3 + bx^2 + cx + d\)

• Degree 4: Quartic → \(ax^4 + bx^3 + cx^2 + dx + e\)

🔑 Factor Theorem

Statement:

For a polynomial \(P(x)\) and a constant \(k\):

\[P(k) = 0 \iff (x - k) \text{ is a factor of } P(x)\]

Usage:

• If \(P(k) = 0\), then \((x - k)\) is a factor
• If \((x - k)\) is a factor, then \(P(k) = 0\)
• Used to find factors and roots of polynomials

📊 Remainder Theorem

Statement:

When a polynomial \(P(x)\) is divided by \((x - k)\), the remainder is \(P(k)\).

\[\text{Remainder} = P(k)\]

General Form:

\[P(x) = (x - k)Q(x) + R\]

where \(Q(x)\) is the quotient and \(R\) is the remainder

Extended Form (for linear divisors):

When dividing by \((ax - b)\):

\[\text{Remainder} = P\left(\frac{b}{a}\right)\]

➗ Polynomial Division

Division Algorithm:

\[P(x) = D(x) \cdot Q(x) + R(x)\]

where \(D(x)\) = divisor, \(Q(x)\) = quotient, \(R(x)\) = remainder
The degree of \(R(x)\) is less than the degree of \(D(x)\)

Methods:

Long Division: Traditional algorithm for dividing polynomials
Synthetic Division: Shortcut method for dividing by linear factors
Factor Theorem: For finding remainders quickly

🎯 Roots, Zeros, and Factors

Definitions:

Zero/Root: A value \(x = r\) where \(P(r) = 0\)

Factor: If \(r\) is a root, then \((x - r)\) is a factor

Multiplicity: The number of times a root is repeated

Number of Roots:

A polynomial of degree \(n\) has exactly \(n\) roots (counting multiplicities)

These roots may be real or complex, and may be repeated

➕ Sum and Product of Roots (HL)

For polynomial: \(a_nx^n + a_{n-1}x^{n-1} + \cdots + a_1x + a_0 = 0\)

With roots \(\alpha_1, \alpha_2, \ldots, \alpha_n\):

Sum of Roots:

\[\sum_{i=1}^{n} \alpha_i = -\frac{a_{n-1}}{a_n}\]

Given in formula booklet as: \(\alpha_1 + \alpha_2 + \cdots + \alpha_n = -\frac{a_{n-1}}{a_n}\)

Product of Roots:

\[\prod_{i=1}^{n} \alpha_i = (-1)^n \frac{a_0}{a_n}\]

Given in formula booklet as: \(\alpha_1 \cdot \alpha_2 \cdot \ldots \cdot \alpha_n = (-1)^n \frac{a_0}{a_n}\)

Quadratic Example (degree 2):

For \(ax^2 + bx + c = 0\) with roots \(\alpha\) and \(\beta\):

\[\alpha + \beta = -\frac{b}{a}\]

\[\alpha \cdot \beta = \frac{c}{a}\]

🔢 Complex Roots Theorem (HL)

Conjugate Root Theorem:

If a polynomial has real coefficients and \(a + bi\) is a complex root (where \(b \neq 0\)), then its complex conjugate \(a - bi\) is also a root.

\[\text{If } (a + bi) \text{ is a root, then } (a - bi) \text{ is also a root}\]

Corresponding Quadratic Factor:

If \(a + bi\) and \(a - bi\) are roots, the corresponding factor is:

\[(x - (a + bi))(x - (a - bi)) = (x - a)^2 + b^2\]

🌟 Fundamental Theorem of Algebra

Statement:

• Every polynomial of degree \(n \geq 1\) has exactly \(n\) complex roots (counting multiplicities)
• Every polynomial can be factored into \(n\) linear factors over the complex numbers
• Every real polynomial can be factored into real linear and/or real irreducible quadratic factors

Factored Form:

\[P(x) = a_n(x - \alpha_1)(x - \alpha_2)\cdots(x - \alpha_n)\]

where \(\alpha_1, \alpha_2, \ldots, \alpha_n\) are the roots (may be complex or repeated)

📈 Graph Properties

End Behavior:

Determined by the leading term \(a_nx^n\):
Even degree, \(a_n > 0\): Both ends go up
Even degree, \(a_n < 0\): Both ends go down
Odd degree, \(a_n > 0\): Left down, right up
Odd degree, \(a_n < 0\): Left up, right down

Turning Points:

A polynomial of degree \(n\) has at most \(n - 1\) turning points

Multiplicity and Graph Behavior:

Multiplicity 1: Graph crosses the x-axis
Multiplicity 2: Graph touches (turning point) the x-axis
Odd multiplicity ≥ 3: Graph crosses with a point of inflection
Even multiplicity ≥ 4: Graph touches with a turning point

🔨 Forming Polynomial Equations

From Known Roots:

If roots are \(\alpha_1, \alpha_2, \ldots, \alpha_n\), the polynomial is:

\[P(x) = a(x - \alpha_1)(x - \alpha_2)\cdots(x - \alpha_n)\]

where \(a\) is any non-zero constant (usually chosen so leading coefficient is 1 or a specific value)

For Quadratic with Roots \(\alpha\) and \(\beta\):

\[x^2 - (\alpha + \beta)x + \alpha\beta = 0\]

or: \(x^2 - (\text{sum of roots})x + (\text{product of roots}) = 0\)

💡 Exam Tip: The sum and product of roots formulas are given in the IB formula booklet. Factor and Remainder theorems are essential for solving polynomial questions efficiently. Remember that complex roots always come in conjugate pairs for polynomials with real coefficients. Use your GDC for polynomial division and finding roots when allowed.