1. Preliminary Knowledge
Definition 1 [1] -[3] Let 
be an integrable function on
. Then the coefficients 
and 
are calculated by
and are called the Fourier coefficients of
.
Definition 2 [1] -[5] Let 
with the period 
be an integrable function on
, trigonometric series with the Fourier coefficient are called Fourier series of
, denoted by
Lemma 1 [6] Let 
be an integrable function on 
with period of
, the Fourier coefficients are calculated according to period of
. The calculation indicates there are same results between Fourier
series with period of ![]()
and![]()
.
2. Calculating Fourier Series According to the Nature of the Function
Theorem 1 Let ![]()
be an integrable function on ![]()
and satisfy the condition![]()
, then we have
![]()
where![]()
, ![]()
,![]()
.
Proof It was clear that the period of ![]()
is ![]()
and we have
![]()
Let![]()
, then![]()
. Therefore
![]()
.
So we get
![]()
.
![]()
.
Let![]()
, then![]()
. Therefore
![]()
Therefore, we obtain
![]()
In the same way, we have
![]()
In a word, while ![]()
is an even number, ![]()
, and
![]()
Thus in this case, the expansion reduces to
![]()
Theorem 2 Let ![]()
be an integrable function on ![]()
and satisfy the conditions![]()
, then we have
![]()
where![]()
,![]()
.
Proof The period of ![]()
is![]()
, so we can calculate Fouries series of ![]()
with period of ![]()
by Lemma 1. We have
![]()
Let![]()
, then![]()
. Therefore
![]()
So we get
![]()
Let![]()
, then![]()
. Therefore
![]()
We obtain
![]()
In the same way, we have
![]()
Thus in this case, the expansion reduces to
![]()
where![]()
,![]()
.
Theorem 3 Let ![]()
be an integrable function on![]()
. When![]()
, it satisfies the condition![]()
. Then we have
(1) While ![]()
is an even function in![]()
, then we get
![]()
where![]()
.
(2) While ![]()
is an odd function in![]()
,then we get
![]()
where![]()
.
Proof (1) We use the method of periodic extension to ![]()
with period of![]()
.
Because ![]()
is an even function, we have![]()
,![]()
.
![]()
Let![]()
, ![]()
, then we have
![]()
Let![]()
, therefore
![]()
We obtain
![]()
Thus in this case, the expansion reduces to
![]()
where![]()
.
(2) In the same way, we can prove Theorem 3 (2).
Similarly, we can prove the following Theorem 4.
Theorem 4 Let ![]()
be an integrable function on![]()
. When![]()
, it satisfies the condition![]()
. Then we have
(1) While ![]()
is an even function in![]()
, then we get
![]()
where![]()
.
(2) While ![]()
is an odd function in![]()
, then we get
![]()
where![]()
.
3. Conclusion
Suppose the function is defined on![]()
, if we use symmetry extension about the point ![]()
and then
use odd and periodic extension, we can get two forms of Fourier series as Theorem 3. If we use symmetry ex-
tension about the line ![]()
and then use odd and periodic extension, we can get two forms of Fourier series as Theorem 4. Suppose the function is defined on![]()
, we have a similar conclusion.
Acknowledgements
I would like to thank the referees and the editor for their valuable suggestions.