The Second Fundamental Theorem of Calculus - At A Glance

As if one Fundamental Theorem of Calculus wasn't enough, there's a second one. The first FTC says how to evaluate the definite integral

if you know an antiderivative of f. The second FTC says how to build an antiderivative of f if you don't know one already.

Given a continuous function f and a constant a, we can define a new function F(x) by integrating f from a to x:

We can think of this new function F as an accumulation function—it accumulates the weighted area under f from a to x.

Given a continuous function f, we can build a new function F(x) by picking a lower limit of integration a and integrating f from a to x.

The Second Fundamental Theorem of Calculus says that when we build a function this way, we get an antiderivative of f.

Second Fundamental Theorem of Calculus:

Assume f(x) is a continuous function on the interval I and a is a constant in I. Define a new function F(x) by

Then F(x) is an antiderivative of f(x)—that is, F '(x) = f(x) for all x in I.

That business about the interval I is to make sure we only get limits of integration that are are reasonable for your function. Some things that wouldn't be reasonable:

  • Choosing a = -1 for the function
    . Then

    doesn't make sense because if x ≠ -1 we're trying to integrate a function over an interval where the function isn't even entirely defined.
      
  • Choosing a = 1 for the function  but then trying to evaluate

    Again, we're trying to integrate a function over an interval where the function isn't entirely defined.
      
  • Choosing a = 0 for the function . How would you evaluate

    The problem is that a = 0 isn't in an interval on which f is continuous. Actually, we can do stuff with this integral—it just requires some extra work, and we haven't gotten there yet.
      
  • Choosing a = -1 for the function  and trying to evaluate

    If I is any interval that contains both -1 and 1, the function  isn't continuous on that interval. Again, we can do stuff with this integral, but we haven't learned how yet.

We can condense this discussion into a short warning.

Be Careful: Whenever you go to evaluate an integral, make sure the limits of integration are reasonable for the function you're integrating.

If a function is discontinuous at or between the limits of integration we may still be able to evaluate the integral, but it requires a little extra sneakiness that we haven't gotten to yet.

So far, we've used the second FTC to build antiderivatives for things we already have derivatives for. That's not very exciting. Why go to all the trouble of writing

to get an antiderivative for sin x, when we already know that

-cos x

is an antiderivative of sin x?

It turns out there are many functions whose antiderivatives we don't know how to find. Some we'll learn how to find using various techniques of integration. However, there are many functions whose antiderivatives can't be written down with a nice formula. We can't write down a nice formula for the antiderivative of

eex

or

,

for example - not just because we don't know how, but because it can't be done.

The second FTC lets us build an antiderivative of f(x) even in the cases where it's impossible to write a nice formula for an antiderivative.

Example 1

Let f(x) = sin x and a = 0. Define

Find

(a) F(π)

(b) 

(c) 


Example 2

Let . Find each value and represent each value using a graph of the function 2t.

(a) F(2)

(b) F(1)

(c) F(0)

(d) F(-1)

(e) F(-2)


Exercise 1

Let f(x) = sin x and a = 0. Define

Find each value and represent using a graph of sin t.

(a) F(-π)

(b) F(2π)

(c) 

(d) Consider all real values of x. For what values of x is F(x)

(i) positive?

(ii) negative?

(iii) zero?


Exercise 2

Let

Find each value and represent each value using a graph of the function (1 – t).

(a) F(3)

(b) F(1)

(c) F(0)

(d) F(-1)

(e) F(-2)


Exercise 3

Use the second FTC to build two different antiderivatives of the function f(x) = eex.