tom.h.wilson Dept. Geology and Geography West Virginia University
Estimating the rate of change of functions with variable slope
The book works through the differentiation of y = x 2, so let’s try y =x 4. multiplying that out -- you get...
Remember the idea of the dy and dx is that they represent differential changes that are infinitesimal - very small. So if dx is (that’s 1x10 -4 ) then (dx) 2 = (or 1x10 -8 ) (dx) 3 = 1x and (dx) 4 = 1x So even though dx is very small, (dx) 2 is orders of magnitude smaller
so that we can just ignore all those terms with (dx) n where n is greater than 1. Our equation gets simple fast Also, since y =x 4, we have and then -
Divide both sides of this equation by dx to get This is just another illustration of what you already know as the power rule,
is Just as a footnote, remember that the constant factors in an expression carry through the differentiation. This is obvious when we consider the derivative - which - in general for
Examining the effects of differential increments in y and x we get the following
Don’t let negative exponents fool you. If n is -1, for example, we still have or just
Given the function - what is? We just differentiate f and g individually and take their sum, so that
Take the simple example - what is? We can rewrite Then just think of the derivative operator as being a distributive operator that acts on each term in the sum.
Where then - On the first term apply the power rule What happens to and ?
Successive differentiations yield Thus -
Differences are treated just like sums so that is just
Differentiating functions of functions - Given a functionwe consider writecompute Then computeand take the product of the two, yielding
We can also think of the application of the chain rule especially when powers are involved as working form the outside to inside of a function
Where Derivative of the quantity squared viewed from the outside. Again use power rule to differentiate the inside term(s)
Using a trig function such as let then Which reduces toor just (the angle is another function 2ax)
In general if then
How do you handle derivatives of functions like ? or The products and quotients of other functions
Removing explicit reference to the independent variable x, we have Going back to first principles, we have Evaluating this yields Since dfdg is very small we let it equal zero; and since y=fg, the above becomes -
Which is a general statement of the rule used to evaluate the derivative of a product of functions. The quotient rule is just a variant of the product rule, which is used to differentiate functions like
The quotient rule states that The proof of this relationship can be tedious, but I think you can get it much easier using the power rule Rewrite the quotient as a product and apply the product rule to y as shown below
We could let h=g -1 and then rewrite y as Its derivative using the product rule is just dh = -g -2 dg and substitution yields
Multiply the first term in the sum by g/g (i.e. 1) to get > Which reduces to the quotient rule
Functions of the type Recall our earlier discussions of the porosity depth relationship
Refer to comments on the computer lab exercise. Derivative concepts
Between 1 and 2 kilometers the gradient is km -1
As we converge toward 1km, / z decreases to km -1 between 1 and 1.1 km depths.
What is the gradient at 1km? What is ?
This is an application of the rule for differentiating exponents and the chain rule
Next time we’ll continue with exponentials and logs, but also have a look at question 8.8 in Waltham (see page 148). Find the derivatives of
tom.h.wilson Dept. Geology and Geography West Virginia University
Differentiating exponential and log functions
Returning to those exponential and natural log cases – recall we implement the chain rule when differentiating h in this case would be ax and, from the chain rule, becomesor and finally since and
For functions like we follow the same procedure. Letand then From the chain rule we have hence
Thus for that porosity depth relationship we were working with -
The derivative of logarithmic functions Given > We’ll talk more about these special cases after we talk about the chain rule.
For logarithmic functions like We combine two rules, the special rule for natural logs and the chain rule. Let Chain rule Log rule then and so
The derivative of an exponential function Given > In general for If express a as e n so that then Note
Sinceand in general a can be thought of as a general base. It could be 10 or 2, etc.