The derivative of a function at is a number that tells us how much the graph of the function is increasing (or decreasing) when the -coordinate is .
The derivative at is written as .
The relationships between the derivative, the instantaneous rate of change, and the slope of the tangent to the graph is described below.
Theory
Before you read the explanation below, you need to know what and means ( is read as “delta ”).
means “change in the value of ”, so it represents the distance between two -values.
means a distance from .
Look closely at the figures below while you read the text.
You have the function (the blue graph), and you have drawn a secant (the pink line) between the points and . As you’ve now learned, the slope of the pink line is the average rate of change of the function between these points. In addition you’ve learned that if these points lie close together, then the average rate of change approaches the instantaneous rate of change.
By reducing , the rightmost point of intersection approaches the leftmost point of intersection . When this happens, the distance between and , as well as the distance between and , becomes smaller. The slope of the secant is gradually approaching the slope of the tangent of the function at .
As the distance between the two points of intersection approaches zero, the pink line will touch at . The slope of the tangent is equal to the instantaneous rate of change at that point.
The value of was arbitrary. This means that if you formulate your approach mathematically, you get a new function for the slope of for all values of . This is precisely what the derivative of a function is.
By using what you’ve learned regarding instantaneous rate of change and limits, you get the following definition of the derivative:
Theory
Example 1
Given , you can differentiate by using the definition:
It’s pretty rare to differentiate a function by using the definition of the derivative. Most of the time, you use the rules for derivation.