What are Polynomials and Rational Expressions Used For?
In economics we learn that profit is the difference between revenue (money coming in), and costs (money going out). Positive profit means that there is a net inflow of money, while negative profit means that money is being lost.
Suppose that you own a company that manufactures and sells furniture. A particular chair sells for $40. If your company builds and sells 500 of these chairs in one month, then your monthly revenue would be $20,000. In general, if you manufacture and sell [latex]x[/latex] chairs, then the revenue [latex]R[/latex], in dollars, would be given by this formula:
[latex]R=40x[/latex]
Now let’s talk about costs. Let’s say it costs $10,000 each month just to keep the factory open, regardless of how many chairs are produced. This amount might include the electric and gas bills as well as the monthly paychecks for each of your employees. These costs, which do not depend on the number of items produced, are called the overhead costs. Furthermore, suppose the materials cost $25 per chair. That means that if we produced [latex]x[/latex] chairs, then the total cost for materials would be [latex]$25x[/latex]. Together with the overhead, we can derive a total estimated cost formula.
[latex]C=\left(overhead\right)+\left(materials\right)=10,000+25x[/latex]
Both formulas for revenue and cost are examples of polynomials. In fact both polynomials are what we call degree 1, or linear polynomials, because the variable [latex]x[/latex] only occurs with exponent 1. What is the profit formula? Simply subtract the two expressions (Profit = Revenue – Costs), to find:
[latex]P=R-C[/latex]
[latex]P=\left(40x\right)-\left(10,000+25x\right)[/latex]
[latex]P=40x-10,000-25x[/latex]
[latex]P=15x-10,000[/latex]
Will your company make money if it manufactures and sells 500 chairs? What about 800 chairs?
Now imagine that your small company has gotten more and more business over that past few months. You’re producing so many chairs that you had to hire new employees, purchase new trucks and even plan for a larger factory. Those costs are adding up!
After carefully analyzing monthly expenses, you estimate the additional costs (above and beyond the overhead and materials costs) to be modeled by a degree 2 (or quadratic) term, [latex]0.001x^2[/latex]. Here are your new cost and profit formulas:
[latex]C=10,000+15x+0.001x^2[/latex]
[latex]P=40x-\left(10,000+25x+0.001x^2\right)=-0.001x^2+15x-10,000[/latex]
These new formulas are also polynomials, but they behave differently than the previous formulas for large values of [latex]x[/latex].
Finally, let’s suppose you want to find out whether it is still cost-effective to produce your $40 chairs in mass quantities. Perhaps the best way to find out is to determine the average profit when [latex]x[/latex] chairs are manufactured and sold. As always, an average is equal to the total amount ([latex]P[/latex], for profit in this case) divided by the number of items ([latex]x[/latex]).
[latex]\Large\frac{P}{x}=\frac{-0.001x^2+15x-10,000}{x}[/latex]
This time, the formula for average profit is no longer a polynomial, but a rational function, which is the ratio of two polynomials.
In this module, you’ll learn how to classify and perform algebraic operations on polynomials and rational functions. We will check back in on our company’s profits at the end of the module.
Learning Objectives
Polynomial Basics
- Identify the degree, leading coefficient, and leading term of a polynomial expression
- Perform algebraic operations on polynomial expressions
Factoring Polynomials
- Identify the greatest common factor of a polynomial expression
- Factor a wide variety of polynomials including those with fractional or negative exponents
Rational Expressions
- Simplify and perform algebraic operations on rational expressions