Chapter 3: Polynomial Functions

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3.1: Power Functions and Polynomial Functions
In this section, we will examine functions that we can use to estimate and predict values and changes in many real-life situations through the use of polynomials.
3.2: Operations on Functions
Many times, we must combine functions to achieve the desired results. We can combine functions using arithmetic and algebraic operations as well as function composition.
3.3: Graph Polynomials with Transformations
Often when given a problem, we try to model the scenario using mathematics in the form of words, tables, graphs, and equations. One method we can employ is to adapt the basic graphs of the toolkit functions to build new models for a given scenario. There are systematic ways to alter functions to construct appropriate models for the problems we are trying to solve.
3.4: Introduction to Polynomial Functions
The revenue in millions of dollars for a fictional company can be modeled by the polynomial function. From the model, one may be interested in which intervals the revenue for the company increases or decreases? These questions, along with many others, can be answered by examining the graph of the polynomial function. We have already explored the local behavior of quadratics, a special case of polynomials. In this section we will explore the local behavior of polynomials in general.
3.5: Dividing Polynomials
We are familiar with the long division algorithm for ordinary arithmetic. We begin by dividing into the digits of the dividend that have the greatest place value. We divide, multiply, subtract, include the digit in the next place value position,. Division of polynomials that contain more than one term has similarities to long division of whole numbers. We can write a polynomial dividend as the product of the divisor and the quotient added to the remainder.
3.6: Zeros of Polynomial Functions
In the last section, we learned how to divide polynomials. We can now use polynomial division to evaluate polynomials using the Remainder Theorem. If the polynomial is divided by \(x–k\), the remainder may be found quickly by evaluating the polynomial function at \(k\), that is, \(f(k)\).
3.7: Polynomial Inequalities
We now consider inequalities. Solving inequalities is quite similar to solving equalities. There is one extra consideration, that multiplying or dividing by a negative number on both sides of an inequality changes the direction of the inequality sign.
3.8: Rational Functions
In the last few sections, we have worked with polynomial functions, which are functions with non-negative integers for exponents. In this section, we explore rational functions, which have variables in the denominator.
3.9: Rational Inequalities
In the last few sections, we have worked with polynomial functions, which are functions with non-negative integers for exponents. In this section, we explore rational functions, which have variables in the denominator.
3.10: Applications of Polynomial and Rational Functions
In this section, we will solve application problems for the different functions we have used in this chapter.

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