2. 3.1 Derivative of a Function

3. Quick Review In Exercises 1 – 4, evaluate the indicated limit algebraically.

4. Quick Review

5. In Exercises 7 – 10, let

6. What you’ll learn about Definition of a Derivative Notation Relationship between the Graphs of f and f ' Graphing the Derivative from Data One-sided Derivatives Essential Question What is the definition of the derivative and how does it help us on a graph of a curve at a point?

7. Definition of Derivative Differentiable Function

8. Example Definition of Derivative

9. Derivative at a Point (alternate)

10. Notation

11. Relationships between the Graphs of f and f’ Because we can think of the derivative at a point in graphical terms as slope, we can get a good idea of what the graph of the function f’ looks like by estimating the slopes at various points along the graph of f. We estimate the slope of the graph of f in y-units per x-unit at frequent intervals. We then plot the estimates in a coordinate plane with the horizontal axis in x-units and the vertical axis in slope units.

12. Graphing the Derivative from Data Discrete points plotted from sets of data do not yield a continuous curve, but we have seen that the shape and pattern of the graphed points (called a scatter plot) can be meaningful nonetheless. It is often possible to fit a curve to the points using regression techniques. If the fit is good, we could use the curve to get a graph of the derivative visually. However, it is also possible to get a scatter plot of the derivative numerically, directly from the data, by computing the slopes between successive points.

13. Graphing f ʹ from f 3.Use the graph of f (x) to graph the derivative f ʹ (x).

14. Graphing f ʹ from f 3.The following table gives the approximate distance traveled by a downhill skier after t seconds 0 < t < 10. Make a scatter plot of the data and use that to sketch a graph of the derivative, and then answer the following. Skiing Distances Time t (sec) Distance traveled (feet) 00 13.3 213.3 329.9 453.2 583.2 6119.8 7163.0 8212.9 9269.5 10332.7 a.What does the derivative represent? Speed - rate of change b.In what units would the derivative be measured? c.Can you guess an equation of the derivative by considering the graph?

15. One-sided Derivatives Right-hand and left-hand derivatives may be defined at any point of a function’s domain. The usual relationship between one-sided and two-sided limits holds for derivatives. Theorem 3, Section 2.1, allows us to conclude that a function has a (two-sided) derivative at a point if and only if the function’s right-hand and left-hand derivatives are defined and equal at that point.

16. Example One-sided Derivatives 5.Show that the following has left-hand and right-hand derivatives at x = 0, but no derivative there. The derivatives are not equal at x = 0.

17. Example One-sided Derivatives 6.Show that the following has left-hand and right-hand derivatives at x = 10, but no derivative there. The derivatives are not equal at x = 1.

18. Pg. 92, 2.4 #2-40 even