Difference between revisions of "Aufgaben:Exercise 3.3: From the Signal to the Spectrum"
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Revision as of 09:59, 23 April 2021
A rectangular pulse $x(t)$ with a duration of $T = 50\,\text{µs}$ and the height of $A = 2\,\text{V}$ is considered. At the jump points at $t = 0$ and $t = T$ the signal value is $A/2$, in each case, but this has no influence on the solution of the task.
In the graphic below, the corresponding spectral function is sketched qualitatively according to magnitude and phase. It is valid:
- $$X( f ) = \left| {X( f )} \right| \cdot {\rm e}^{ - {\rm j}\hspace{0.05cm}\cdot \hspace{0.05cm} \varphi ( f )} .$$
The analytical function progression of $X(f)$ is to be determined.
Hints:
- This exercise belongs to the chapter Special Cases of Impulse Signals.
- The following trigonometric transformations are also given:
- $$\sin ^2( \alpha ) = {1}/{2} \cdot \big( {1 - \cos ( {2\alpha } )} \big),\hspace{0.5cm} \tan( {\alpha /2} ) = \frac{ {1 - \cos ( \alpha )}}{ {\sin ( \alpha )}}.$$
Questions
Solution
(1) With the abbreviation $\omega = 2\pi f$ the spectral function is according to the first Fourier integral:
- $$X( f ) = \int_0^T {A \cdot {\rm{e}}^{-{\rm{j}}\omega t} \hspace{0.05cm}{\rm d}t = } \int_0^T {A \cdot \cos \left( {\omega t} \right)\hspace{0.05cm}{\rm d}t }\hspace{0.1cm}-\hspace{0.1cm} {\rm{j}} \cdot \int_{\rm{0}}^T {A \cdot \sin ( {\omega t} )} \hspace{0.05cm}{\rm d}t.$$
- After integration and insertion of the limits, it follows:
- $${\mathop{\rm Re}\nolimits} [ {X( f )} ] = \frac{A}{\omega } \cdot \sin( {\omega T} ),$$
- $${\mathop{\rm Im}\nolimits} [ {X( f)} ] = \frac{A}{\omega } \cdot \left( {\cos ( {\omega T}) - 1} \right) = - \frac{A}{\omega } \cdot\left( {1 - \cos ( {\omega T} )} \right).$$
- For the frequency $f = 1/(2T) = 10\, \text{kHz}$ ⇒ $\omega \cdot T = \pi$ we get::
- $${\mathop{\rm Re}\nolimits}[{X( {f = 10 \;{\rm{kHz}}} )}] = \frac{A}{ {2{\rm{\pi }}f}} \cdot \sin ( {\rm{\pi }} ) \hspace{0.15 cm}\underline{= 0},$$
- $${\mathop{\rm Im}\nolimits} [ {X( {f = 10 \;{\rm{kHz}}})} ] = \frac{ { - A}}{ {2{\rm{\pi }}f}} \cdot \big( {1 - \cos ( {\rm{\pi }} )} \big) = - \frac{ { A}}{{ {\rm{\pi }}f}}\hspace{0.15 cm}\underline{= - 0.0637 \;{\rm{mV/Hz}}}{\rm{.}}$$
(2) The magnitude square is the sum of the real and imaginary parts, squared in each case:
- $$\left| {X( f )} \right|^2 = \frac{ {A^2 }}{ {\omega ^2 }}\big[ {\sin ^2 ( {\omega T} ) + 1 - 2 \cdot \cos ( {\omega T}) + \cos ^2 ( {\omega T} )} \big].$$
- Because of $\sin^2(\alpha) + \cos^2(\alpha) = 1$ , this can also be written:
- $$\left| {X( f )} \right|^2 = \frac{ {2A^2 }}{ {\omega ^2 }} \cdot \big( {1 - \cos ( {\omega T} )} \big) = \frac{ {4A^2 }}{ {\omega ^2 }} \cdot \sin ^2( {\omega T/2} ).$$
- Setting $\omega = 2\pi f$ and taking the root, we obtain, under the condition $A > 0$:
- $$\left| {X( f )} \right| = \left| \frac{A}{ {\rm\pi }f} \cdot \sin ( {\rm \pi }fT ) \right| = A \cdot T \cdot \left| \frac{\sin ( {\rm\pi }fT )}{ {\rm \pi}fT} \right|.$$
- With the shortcut $\text{si}(x) = \sin(x)/x$ the result is:
- $$\left| {X( f)} \right| = A \cdot T \cdot\left|{\rm si} ( { {\rm{\pi }}fT} ) \right|.$$
- The spectral value at the frequency $f = 1/T = \text{20 kHz}$ is given by
- $$\left| {X( {f = 20\;{\rm{kHz}}} )} \right| = \frac{ {A \cdot T}}{ {\rm{\pi }}} \cdot \sin ( {\rm{\pi }} ) \hspace{0.15 cm}\underline{= 0}.$$
- When calculating the value for $f = 0$ the quotient $\text{0 divided by 0}$. By applying L'Hospitals rule the limiting value can be calculated:
- $$\mathop {\lim }\limits_{x \to 0 } \frac{ {\sin \left( x \right)}}{x} = 1.$$
- From this follows:
- $$\left| {X( {f = 0} )} \right| = A \cdot T \hspace{0.15 cm}\underline{= 0.1 \;{\rm{mV/Hz}}}{\rm{.}}$$
- This result is obvious because, according to the first Fourier integral, the spectral value at $f = 0$ corresponds exactly to the area under the time function.
(3) Proposed solutions 1 and 3 are correct::
- According to the result of subtask (2) the zeros occur at the distance $f_0 = 1/T$ .
- With $f_0 = 1/(2T) = f = 10 \;{\rm{kHz}}$ the real part is $0$, but not the imaginary part.
- With the arguments $f \cdot T = 0.5, 1.5, 2.5,\hspace{0.05cm}\text{ ... }$ the sine function is in each case equal in magnitude to $1$, and it holds:
- $$\left| {X( f )} \right| = \frac{A}{ {{\rm{\pi }}\left| f \right|}} = X_{\rm S} ( f ).$$
- At other frequencies, $X_{\rm S}(f)$ als obere Schranke, serves as an upper bound, i.e. $|Xf)| \leq X_{\rm S}(f)$ always applies.
- In the sketch, this bound is drawn as a violet curve in addition to $|X(f)|$ .
(4) According to the definition on the information page, one can calculate the phase function as follows:
- $$\varphi ( f ) = - \arctan \frac{ { {\mathop{\rm Im}\nolimits} ( f )}}{ { {\mathop{\rm Re}\nolimits} ( f )}}.$$
- With the results from subtask (1) the following thus applies:
- $$\varphi ( f ) = \arctan \left( {\frac{ {1 - \cos ( {\omega T} )}}{ {\sin ( {\omega T} )}}} \right).$$
- The argument of this function is equal to $\tan(\omega T/2) = \tan(\pi fT)$ according to the specification. From this follows a linearly increasing course with the frequency:
- $$\varphi ( f ) = \arctan \left( {\tan ( { {\rm{\pi }}fT} )} \right) = {\rm{\pi }}fT.$$
- With $f = 10\,\text{kHz}$ and $T = 50\,\text{µs}$ one obtains from this the phase angle $\pi /2$ corresponding to $\underline{90^{\circ}}$ .