We find the zeros of a rational function.

Introduction

Suppose Julia is taking her family on a boat trip miles down the river and back. The river flows at a speed of miles per hour and she wants to drive the boat at a constant speed, miles per hour downstream and back upstream. Due to the current of the river, the actual speed of travel is miles per hour going downstream, and miles per hour going upstream. If Julia plans to spend hours for the whole trip, how fast should she drive the boat?

The time it takes Julia to drive the boat downstream is hours and upstream is hours. The function to model the whole trip’s time is where stands for time in hours. The trip will take hours, so we want to equal , and we have:

To solve this equation algebraically, we would start by subtracting from both sides to obtain:

This has taken our equation involving rational functions, and converted it into the problem of determining the zeros of a single rational function. Namely, we are really just finding the zeros of . (Notice that the function was changed by subtracting the , so we had to use a new name for it.)

In the same way, whenever we are asked to find the solution of a rational equation, it is equivalent to finding the zeros of a rational function instead.

Zeros of Rational Functions

Let’s look at this last example a bit more. We combined the three terms of into a single fraction, but that fraction was not in its reduced form.

Why was not a zero of the function? Because it was also a zero of the denominator. (Notice the common factor of in both the numerator and denominator.) Rewriting the fraction in lowest terms, we see that the numerator is never zero, since it’s a constant .

From this example, it may seem that reducing the rational function to lowest terms will always help you bypass the extraneous solutions. That is not the case.