The area between a curve f(x)>0 and the x-axis is given by

Approximate area beneath a curve from x=a to x=b by summing the area of n trapezoids of equivalent width.

Each trapezoid's area is the common width (nb−a​) times the average of the function's value on the left and rigth side of the trapezoid:

Integration, or anti-differentiation, is essentially the opposite of differentiation. We use the integral symbol∫ and write:

By convention we denote this function F:

We can also write

Notice the dx under the integral. This tells us which variable we are integrating with respect to - in this case we are reversing dxd​.

Since the derivative of a constant is always zero, then if if F′(x)=f(x), then (F(x)+C)′=f(x).

This means that when we integrate, we can add any constant to our result, since differentiating makes this constant irrelevant:

In the same way that constant multiples can pass through the derivative, they can pass through the integral:

And in the same way that the derivative of a sum is the sum of the derivatives:

If we know the value of y or f(x) for a given x, we can determine C by plugging in x and y.

A definite integral is evaluated between a lower and upper bound.

We can solve a definite integral with

where F(x)=∫f(x)dx.

Graphing calculators can be used to evaluate definite integrals.

For example, on a TI-84, math > 9:fnInt(, which prompts you with ∫□□​(□)d□. Make sure the variable of your function matches the variable that you take the integral with respect to.

Integrals of the same function with adjacent domains can be merged:

Similarly, the domain of an integral can be split:

for any a<m<b.