Most of the results presented for -periodic functions extend easily to functions 2*L*-periodic functions. So we only discuss the case of -periodic functions.

**Definition.** The function *f*(*x*) defined on [*a*,*b*], is said to be **piecewise continuous** if and only if, there exits a partition
of [*a*,*b*] such that

- (1)
*f*(*x*) is continuous on [*a*,*b*] except may be for the points*x*_{i},- (2)
- the right-limit and left-limit of
*f*(*x*) at the points*x*_{i}exist.

Recall that
is a partition of [*a*,*b*] if

All the known results on the sum, product, and the quotient are valid for piecewise smooth functions. Except for the fundamental theorem of Calculus which needs to be modified. Indeed, we have let

the fundamental theorem of Calculus translates into

Before we state the fundamental result on convergence of Fourier series, we need some intermediary results.

**Remark.** Recall that our initial problem is to approximate a function globally (on an interval versus Taylor approximations which are local). In this context, the approximation of *f*(*x*) will be done via the Fourier polynomials

These Fourier polynomials will be called the

The fundamental result on convergence of Fourier series, due to Dirichlet, states:

**Theorem.** Let *f*(*x*) be a function, which is twice differentiable, such that *f*(*x*), *f*'(*x*), and *f*''(*x*) are piecewise continuous on the interval
.
Then, for any
,
the sequence of Fourier partial sums
converges to
,
as *n* tends to .

Recall that the notation *f*(*x*+) (resp. *f*(*x*-)) represent the right-limit and left-limit respectively of *f* at the point *x*. Let us associate to *f* the new function *S*(*f*) defined by

The conclusion of the Theorem above translates into

**Example.** Show that

This function satisfies the assumptions of the main Theorem. Before, we use the Thoerem's conclusion, let us find its Fourier series. We have

Easy calculations give

The Theorem's conclusion gives the desired identity.

In the next page, you may find more on convergence of Fourier series.

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**Author**: M.A. Khamsi

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