Difference between revisions of "Aufgaben:Exercise 3.7Z: Rectangular Signal with Echo"

Revision as of 14:39, 23 March 2021

Transmit signal

$s(t)$ & signal

$r(t)$ with echo

We consider a periodic square wave signal $s(t)$ with the possible amplitude values $0\text{ V}$ and $2\text{ V}$ and the period duration $T_0 = T = 1 \text{ ms}$ . At the jump points, for example at $t = T/4$ , the signal value is $1\text{ V}$ . The DC component $($ also i.e. the Fourier coefficient $A_0)$ of the signal is also $1\text{ V}$ .

Further applies:

Due to symmetry (even function), all sine coefficients $B_n = 0$ .

The coefficients $A_n$ with even $n$ are also zero.

For odd values of $n$ on the other hand, the following applies:

$A_n = ( { - 1} )^{\left( {n - 1} \right)/2} \cdot \frac{{4\;{\rm{V}}}}{{n \cdot {\rm{\pi }}}}.$

The signal $s(t)$ reaches the receiver via two paths (see sketch below):

Once on the direct path and secondly via a secondary path.
The latter is characterised by the attenuation factor $\alpha$ and the transit time $\tau$ .
Therefore, the following applies to the received signal:

$r(t) = s(t) + \alpha \cdot s( {t - \tau } ).$ The frequency response of the channel is $H(f) = R(f)/S(f)$ , the impulse response is denoted by $h(t)$ .

Hints:

This exercise belongs to the chapter The Convolution Theorem and Operation.
Important information can be found in particular on the page Convolution of a Function With a Dirac Function.

Questions

Solution

(1) The second suggested solution is correct:

The impulse response is equal to the received signal $r(t)$ , if a single Dirac impulse is present at the input at time $t = 0$ :

$h(t) = \delta (t) + \alpha \cdot \delta( {t - \tau } ).$

Convolution of square wave signal

$s(t)$ and impulse response

$h(t)$

(2) It holds that $r(t) = s(t) ∗ h(t)$ . This convolution operation is most easily performed graphically:

The values of the received signal are generally:

$0.00 < t/T < 0.25\text{:}\hspace{0.4cm} r(t) = +1\hspace{0.02cm}\text{ V}$ ,
$0.25 < t/T < 0.50\text{:}\hspace{0.4cm} r(t) = -1 \hspace{0.02cm}\text{ V}$ ,
$0.50 < t/T < 0.75\text{:}\hspace{0.4cm} r(t) = 0 \hspace{0.02cm}\text{ V}$ ,
$0.75 < t/T < 1.00\text{:}\hspace{0.4cm} r(t) = +2 \hspace{0.02cm}\text{ V}$ .

The values we are looking for are thus

$r(t = 0.2 \cdot T) \hspace{0.15cm}\underline{= +1 \hspace{0.02cm}\text{ V}},$

$r(t = 0.3 · T) \hspace{0.15cm}\underline{= -1 \hspace{0.02cm}\text{ V}}.$

(3) Using a similar procedure as in (2) , a DC signal of $2\hspace{0.02cm}\text{ V}$ is obtained for $r(t)$ :

The gaps in the signal $s(t)$ are completely filled by the echo $s(t - T/2)$ .
This result can also be derived in the frequency domain.
The channel frequency response is with $\alpha = 1$ and $\tau = T/2$ :

$H( f ) = 1 + 1 \cdot {\rm{e}}^{ - {\rm{j\pi }}fT} = 1 + \cos ( {{\rm{\pi }}fT} ) - {\rm{j}} \cdot {\rm{sin}}( {{\rm{\pi }}fT} ).$

Apart from the DC component, the input signal ${s(t)}$ only has components at $f = f_0 = 1/T$ , $f = 3 \cdot f_0$ , $f = 5 \cdot f_0$ etc..
At these frequencies, however, both the real– and the imaginary part of ${H(f)}$ are equal to zero.
Thus, for the output spectrum with $A_0 = 1 \text{ V}$ and $H(f = 0) = 2$ we obtain:

$R(f) = A_0 \cdot H(f = 0) \cdot \delta (f) = 2\;{\rm{V}} \cdot \delta (f).$

The inverse Fourier transformation thus also yields $r(t) \underline{= 2 \text{ V= const}}$ .

Revision as of 23:17, 28 January 2021 (view source) Noah (talk \| contribs) ← Older edit		Revision as of 14:39, 23 March 2021 (view source) Javier (talk \| contribs) m (Text replacement - "Category:Exercises for Signal Representation" to "Category:Signal Representation: Exercises") Newer edit →
Line 96:		Line 96:

	__NOEDITSECTION__		__NOEDITSECTION__
−	[[Category:~~Exercises for~~ Signal Representation\|^3.4 The Convolution Theorem^]]	+	[[Category:Signal Representation: Exercises\|^3.4 The Convolution Theorem^]]

	For $0 ≤ t < \tau$ $h(t) = 1$ is true, for $t > \tau$ $h(t) = 1 + \alpha$ .
	It holds that $h(t) = \delta (t) + \alpha \cdot \delta(t - \tau)$ .
	$h(t)$ has a gaussian shape.