Derivative Functions: Connection of Algebra and Calculus
editDerivative functions can be difficult to learn and understand. If you learn it yourself instead of being lectured, its a lot easier. Socratic method.
Process
editThe first step is to graph a third degree polynomial function. I chose .
Secant Line
edit- Construct a secant line by the following
- Constructing first one point, a, anywhere on the function plot f, and measuring it's abscissa and ordinate (XA & YA).
- Construct parameter h.
- Calculate XA+h and f(XA+h)
- Select XA+h and f(XA+h) in order, to plot point B by using Plot as (x,y) from the "graph menu".
- Construct the line joining A and B
- Select secant line AB and find its slope.
- Plot point P by selecting XA and the slope measurement AB in order, then Plot As (x,y).
- Select point A and point P in order, and make a locus from the construct menu.
Derivative
edit- Select and produce its derivative.
- Plot the derivative.
What's going on
editIn this beautiful work of art, the only thing we made that does not rely on something else, is the original function:
A is a point on the function, and B is a point on the function that is a given distance away from point A at all times, which changes depending on how large or small parameter h is. The secant line is an approximation of the tangent line, and moves depending on where A and B are on the original function.
Between steps one and two under Derivative, we see the what I call the minus-droppy rule applied. The derivative's function's, 's, form is because the original was in form . Each exponent of is dropped as a coefficient, and 1 is subtracted from it's place in the superscript as well as being dropped, hence "minus-droppy!" The best part about self-teaching is that you get to make up your own names for things! Okay, I don't know what its name is, but I am sure it is some kind of important rule.
The larger parameter h is, the farther away A and B are from each other on the function, and also, the more error there is in the locus, an approximation of the derivative. When h is 0, the secant line becomes a tangent line because A and B are overlapping (therefore the tangent line is the limit of the secant line, see right). When h is 0, all points on the locus match with all points on the derivative.
When h=0, the secant line is undefined, but as h —> 0, the secant line approaches to the tangent. Because h cannot equal 0, the definition must be . AB [coordinates (XA,f(x)) and (XA+h,f(XA+h)) respectively] approach the derivative
Point A and Point P at all y values, have equal x values, while A is attached to and P to , because they share XA. P's y coordinates come from the slope of line AB. In the ideal condition that h is zero and AB is a tangent line, slope of AB is actually the slope of each point in the original function, and the locus is the derivative.