Difference between revisions of "Aufgaben:Exercise 2.6: Complex Fourier Series"

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[[File:P_ID312__Sig_A_2_6.png|right|frame|Various periodic triangular signals]]
 
[[File:P_ID312__Sig_A_2_6.png|right|frame|Various periodic triangular signals]]
  
We consider the signal  $x(t)$, defined by the two parameters  $T_0$  and  $T_1$  where  $T_1 \leq T_0$  should always apply. For the complex Fourier coefficients
+
We consider the signal  $x(t)$,  defined by the two parameters  $T_0$  and  $T_1$  where  $T_1 \leq T_0$  should always apply.  For the complex Fourier coefficients
 
   
 
   
 
:$$D_n=\frac{1}{T_0} \cdot \int_0^{T_0}x(t)\cdot\rm e^{-\rm j\it n\omega_0t}\,{\rm d} \it t$$
 
:$$D_n=\frac{1}{T_0} \cdot \int_0^{T_0}x(t)\cdot\rm e^{-\rm j\it n\omega_0t}\,{\rm d} \it t$$
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of this signal are obtained after mathematical transformations:
 
of this signal are obtained after mathematical transformations:
 
   
 
   
:$$D_n=\frac{T_0/T_1} {(2\pi n)^2} \cdot  \bigg(1-{\rm e}^{-{\rm j} 2\pi nT_1/T_0}\bigg)-\frac{\rm j}{2\pi n}.$$
+
:$$D_n=\frac{T_0/T_1} {(2\pi n)^2} \cdot  \big(1-{\rm e}^{-{\rm j} 2\pi nT_1/T_0}\big)-\frac{\rm j}{2\pi n}.$$
  
 
*The parameter set dealt with in subtasks  '''(1)'''  and  '''(3)'''    $($with $T_1 = T_0/2)$  is represented as the signal  $x(t)$ .  
 
*The parameter set dealt with in subtasks  '''(1)'''  and  '''(3)'''    $($with $T_1 = T_0/2)$  is represented as the signal  $x(t)$ .  
 
*For  $T_1 = T_0$  ⇒   subtask  '''(2)'''  the function  $y(t)$ results.  
 
*For  $T_1 = T_0$  ⇒   subtask  '''(2)'''  the function  $y(t)$ results.  
*In subtask  '''(4)'''  the signal  $z(t)$  is considered. Its Fourier coefficients are:
+
*In subtask  '''(4)'''  the signal  $z(t)$  is considered.  Its Fourier coefficients are:
 
   
 
   
 
:$$A_0=1/4,\hspace{1cm}
 
:$$A_0=1/4,\hspace{1cm}
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''Hints:''  
 
''Hints:''  
*This exercise refers to the page  [[Signal_Representation/Fourier_Series#Complex_Fourier_Series|Complex Fourier Series]].
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*This exercise refers to the page  [[Signal_Representation/Fourier_Series#Complex_Fourier_Series|Complex Fourier series]].
 
   
 
   
  
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<quiz display=simple>
 
<quiz display=simple>
  
{Calculate the coefficient&nbsp; $D_0$&nbsp; and show that it is always real. What value results for&nbsp; $T_1 = T_0/2$, i.e. for the signal&nbsp; $x(t)$?
+
{Calculate the coefficient&nbsp; $D_0$&nbsp; and show that it is always real.&nbsp; What value results for&nbsp; $T_1 = T_0/2$, i.e. for the signal&nbsp; $x(t)$?
 
|type="{}"}
 
|type="{}"}
 
$D_0^{(x)}\ = \ $  { 0.25 3% }
 
$D_0^{(x)}\ = \ $  { 0.25 3% }
  
{Calculate the complex Fourier coefficients&nbsp; $D_n^{(y)}$&nbsp; for&nbsp; $n \neq 0$ for the special case &nbsp; $T_1 = T_0$&nbsp; corresponding to the signal&nbsp; $y(t)$&nbsp;. <br>What are the coefficients&nbsp; $A_n^{(y)}$&nbsp; and&nbsp; $B_n^{(y)}$, especially for&nbsp; $n = 1$?
+
{Calculate the complex Fourier coefficients&nbsp; $D_n^{(y)}$&nbsp; for&nbsp; $n \neq 0$&nbsp; for the special case &nbsp; $T_1 = T_0$&nbsp; corresponding to the signal&nbsp; $y(t)$&nbsp;. <br>What are the coefficients&nbsp; $A_n^{(y)}$&nbsp; and&nbsp; $B_n^{(y)}$,&nbsp; especially for&nbsp; $n = 1$?
 
|type="{}"}
 
|type="{}"}
 
$A_1^{(y)}\ = \ $ { 0. }
 
$A_1^{(y)}\ = \ $ { 0. }
 
$B_1^{(y)}\ = \ $ { 0.318 3% }
 
$B_1^{(y)}\ = \ $ { 0.318 3% }
  
{Now calculate the coefficients&nbsp; $A_n^{(x)}$&nbsp; and&nbsp; $B_n^{(x)}$&nbsp; for the signal&nbsp; $x(t)$&nbsp; with&nbsp; $T_1 = T_0/2$&nbsp; for&nbsp; $n \neq 0$. What are the values for&nbsp; $A_1^{(x)}$&nbsp; and&nbsp; $B_1^{(x)}$?
+
{Now calculate the coefficients&nbsp; $A_n^{(x)}$&nbsp; and&nbsp; $B_n^{(x)}$&nbsp; for the signal&nbsp; $x(t)$&nbsp; with&nbsp; $T_1 = T_0/2$&nbsp; for&nbsp; $n \neq 0$.&nbsp; What are the values for&nbsp; $A_1^{(x)}$&nbsp; and&nbsp; $B_1^{(x)}$?
 
|type="{}"}
 
|type="{}"}
 
$A_1^{(x)}\ = \ $ { 0.203 3% }
 
$A_1^{(x)}\ = \ $ { 0.203 3% }

Revision as of 10:41, 16 April 2021

Various periodic triangular signals

We consider the signal  $x(t)$,  defined by the two parameters  $T_0$  and  $T_1$  where  $T_1 \leq T_0$  should always apply.  For the complex Fourier coefficients

$$D_n=\frac{1}{T_0} \cdot \int_0^{T_0}x(t)\cdot\rm e^{-\rm j\it n\omega_0t}\,{\rm d} \it t$$

of this signal are obtained after mathematical transformations:

$$D_n=\frac{T_0/T_1} {(2\pi n)^2} \cdot \big(1-{\rm e}^{-{\rm j} 2\pi nT_1/T_0}\big)-\frac{\rm j}{2\pi n}.$$
  • The parameter set dealt with in subtasks  (1)  and  (3)    $($with $T_1 = T_0/2)$  is represented as the signal  $x(t)$ .
  • For  $T_1 = T_0$  ⇒   subtask  (2)  the function  $y(t)$ results.
  • In subtask  (4)  the signal  $z(t)$  is considered.  Its Fourier coefficients are:
$$A_0=1/4,\hspace{1cm} A_n=\left\{ \begin{array}{cl} {\frac{\displaystyle-2}{\displaystyle(\pi n)^2}} & {\rm for\; even\; \it n \rm ,} \\ 0 & {\rm for\; odd\; \it n,} \end{array}\right. $$
$$B_n=0\; \;\; \rm{ f\ddot{u}r\; alle\; \it n.}$$




Hints:




Questions

1

Calculate the coefficient  $D_0$  and show that it is always real.  What value results for  $T_1 = T_0/2$, i.e. for the signal  $x(t)$?

$D_0^{(x)}\ = \ $

2

Calculate the complex Fourier coefficients  $D_n^{(y)}$  for  $n \neq 0$  for the special case   $T_1 = T_0$  corresponding to the signal  $y(t)$ .
What are the coefficients  $A_n^{(y)}$  and  $B_n^{(y)}$,  especially for  $n = 1$?

$A_1^{(y)}\ = \ $

$B_1^{(y)}\ = \ $

3

Now calculate the coefficients  $A_n^{(x)}$  and  $B_n^{(x)}$  for the signal  $x(t)$  with  $T_1 = T_0/2$  for  $n \neq 0$.  What are the values for  $A_1^{(x)}$  and  $B_1^{(x)}$?

$A_1^{(x)}\ = \ $

$B_1^{(x)}\ = \ $

4

Which of the following statements are true regarding  $x(t)$,  $y(t)$  and  $z(t)$ ?

It is true that  $x(t) = y(t) + z(t)$.
It is true that  $x(t) = y(t) - z(t)$.
The cosine coefficients  $A_n$  of  $x(t)$  und  $z(t)$  are identical.
The cosine coefficients  $A_n$  of  $x(t)$  und  $z(t)$  are equal in magnitude.
The sine coefficients  $B_n$  of  $y(t)$  und  $z(t)$  are identical.


Solution

(1)  With Euler's theorem, the complex Fourier coefficient  $D_n$ can be represented as follows:

$${\rm Re} [D_n] =\frac{T_0/T_1}{(2\pi n)^2}\cdot(1-\cos(2\pi nT_1/T_0)),$$
$${\rm Im}[D_n] =\frac{T_0/T_1}{(2\pi n)^2} \cdot \sin(2\pi nT_1/T_0)-\frac{1}{2\pi n}.$$
  • With the approximation  $\text{sin}(\alpha ) \approx \alpha$  valid for small  $\alpha$-values one obtains for the imaginary part:
$${\rm Im}[D_n] =\frac{T_0/T_1}{(2\pi n)^2}\cdot(2\pi nT_1/T_0)-\frac{1}{2\pi n}=0.$$
  • For the real part one obtains with  $\text{cos}(\alpha) \approx 1 – \alpha^{2}/2$:
$${\rm Re}[D_n] =\frac{T_0/T_1}{(2\pi n)^2}\frac{(2\pi nT_1/T_0)^2}{2}=\frac{T_1/T_0}{2}.$$
  • For  $T_1 = T_0/2$  it follows that the DC signal coefficient  $D_0^{(x)} \hspace{0.1cm}\underline{= 0.25}$.
  • With  $T_1 = T_0$  it results in  $D_0^{(y)} = 0.5$.
  • A comparison with the signals   $x(t)$  and  $y(t)$ on the data page show the correctness of these results.


(2)  It is now assumed  $n \neq 0$ . With  $T_1 = T_0$  one obtains for the real part because of  $\text{cos}(2\pi n) = 1$:

$${\rm Re}[D_n^{(y)}] =\frac{1}{(2\pi n)^2}\cdot(1-\cos(2\pi n))=0.$$
  • The imagnary part is:
$${\rm Im}[D_n^{(y)}] =\frac{1}{(2\pi n)^2}\cdot(\sin(2\pi n))-\frac{1}{2\pi n}.$$
  • Because  $\text{sin}(2\pi n) = 0$  it follows that   ${\rm Im}[D_n] =-{1}/({2\pi n}).$ Thus
$$D_n^{(y)}=\frac{-\rm j}{2\pi n}={1}/{2} \cdot (A_n- {\rm j} \cdot B_n).$$
  • The coefficient comparison yields  $A_n^{(y)} = 0$  and  $B_n^{(y)} = 1/(\pi n)$. In particular  $A_1^{(y)} \hspace{0.1cm}\underline{= 0}$  und  $B_1^{(y)}\hspace{0.1cm}\underline{ \approx 0.318}$.
  • As expected, $B_{-n}^{(y)} = -B_n^{(y)}$ always holds.


(3)  From the general equation calculated in subtask  (1)  it follows with  $T_1/T_0 = 1/2$:

$$D_n^{(x)}=\frac{2}{(2\pi n)^2}(1-\cos(\pi n))+{\rm j}\cdot \left[\frac{2\sin(\pi n)}{(2\pi n)^2}-\frac{1}{(2\pi n)}\right].$$
  • From this one obtains the cosine coefficients
$$A_n^{(x)}={2}\cdot{\rm Re}[D_n] =\left\{ \begin{array}{cl} {\frac{\displaystyle 2}{\displaystyle(\pi n)^2}} & {\rm for\; odd\; \it n ,} \\ 0 & {\rm for\; even\;\it n.} \end{array}\right. $$
  • The sine coefficients are:
$$B_n^{(x)}=-2\cdot{\rm Im}[D_n] =\frac{1}{\pi n}.$$
  • Here it is taken into account that for all integer values of  $n$  the function  $\text{sin}(n\pi ) = 0$ . The first real coefficients are as follows
$$A_1^{(x)} = 2/\pi^{2} \hspace{0.1cm}\underline{\approx 0.203},$$
$$B_1 = 1/\pi \hspace{0.1cm}\underline{\approx 0.318}.$$


(4)  The correct solutions are 2, 4 and 5:

  • The signal  $x(t)$  is equal to the difference between  $y(t)$  and  $z(t)$. Since  $z(t)$  is an even and  $y(t)$  an odd function, the cosine coefficients  $A_n$  are determined by the coefficients of the signal  $z(t)$  alone, but with negative signs.
  • The sine coefficients $B_n$ completely agree with those of  $y(t)$  überein.
  • The DC component of  $x(t)$  results from the difference of the two DC components of  $y(t)$  und  $z(t)$:  
$$A_0 = 0.5 - 0.25 = 0.25.$$