Difference between revisions of "Aufgaben:Exercise 1.1: Music Signals"

Revision as of 13:44, 25 December 2020

Music signals, original,
noisy and/or distorted?

On the right you see a ca. $\text{30 ms}$ long section of a music signal $q(t)$. It is the piece „For Elise” by Ludwig van Beethoven.

Underneath are drawn two sink signals $v_1(t)$ and $v_2(t)$, which were recorded after the transmission of the music signal $q(t)$ over two different channels.

The following controls allow you to listen to the first fourteen seconds of each of the three audio signals $q(t)$, $v_1(t)$ and $v_2(t)$.

Original signal $q(t)$

Sink signal $v_1(t)$

Sink signal $v_2(t)$

Notes:

	The signal frequency is approximately $f = 250\,\text{Hz}$.
	The signal frequency is approximately $f = 500\,\text{Hz}$.
	The signal frequency is about $f = 1\,\text{kHz}$.

	The signal $v_1(t)$ is undistorted compared to $q(t)$.
	The signal $v_1(t)$ shows distortions compared to $q(t)$ .
	The signal $v_1(t)$ is noisy compared to $q(t)$ .

	The signal $v_2(t)$ is undistorted compared to $q(t)$ .
	The signal $v_2(t)$ shows distortions compared to $q(t)$ .
	The signal $v_2(t)$ is noisy compared to $q(t)$ .

$ \alpha \ = \ $

$ \tau \ = \ $

$\ \text{ms}$

(1) Correct is the solution 2:

In the marked range of $20$ milliseconds approx. $10$ oscillations can be detected.
From this the result follows approximately for the signal frequency; $f = {10}/(20 \,\text{ms}) = 500 \,\text{Hz}$.

(2) Correct is the solution 1:

The signal $v_1(t)$ is undistorted compared to the original signal $q(t)$. The following applies: $v_1(t)=\alpha \cdot q(t-\tau) .$

An attenuation $\alpha$ and a delay $\tau$ do not cause distortion, but the signal is then only quieter and delayed in time, compared to the original.

(3) Correct are the solutions 1 and 3:

One can recognize both in the displayed signal $v_2(t)$ and in the audio signal additive noise ⇒ solution 3.
The signal-to-noise ratio is approx. $\text{30 dB}$; but this cannot be seen from this representation.
Correct is also the solution 1: Without this noise component $v_2(t)$ identical with $q(t)$.

(4) The signal $v_1(t)$ is identical in form to the original signal $q(t)$ and differs from it only

by the attenuation factor $\alpha = \underline{\text{0.3}}$ (dies entspricht etwa $\text{–10 dB)}$
and the delay $\tau = \underline{10\,\text{ms}}$.

Revision as of 12:26, 22 December 2020 (view source) Noah (talk \| contribs) ← Older edit		Revision as of 13:44, 25 December 2020 (view source) Noah (talk \| contribs) Newer edit →
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	*The signal  <math>v_1(t)</math>  is undistorted compared to the original signal <math>q(t)</math>. The following applies:   $v_1(t)=\alpha \cdot q(t-\tau) .$		*The signal  <math>v_1(t)</math>  is undistorted compared to the original signal <math>q(t)</math>. The following applies:   $v_1(t)=\alpha \cdot q(t-\tau) .$

−	*An attenuation  <math>\alpha</math>  and a delay  <math>\tau</math>  do not cause distortion, but the signal is then only quieter and ~~comes later than~~ the original.	+	*An attenuation  <math>\alpha</math>  and a delay  <math>\tau</math>  do not cause distortion, but the signal is then only quieter and delayed in time, compared to the original.

	The signal frequency is approximately \(f = 250\,\text{Hz}\).
	The signal frequency is approximately \(f = 500\,\text{Hz}\).
	The signal frequency is about \(f = 1\,\text{kHz}\).

	The signal \(v_1(t)\) is undistorted compared to \(q(t)\).
	The signal \(v_1(t)\) shows distortions compared to \(q(t)\) .
	The signal \(v_1(t)\) is noisy compared to \(q(t)\) .

	The signal \(v_2(t)\) is undistorted compared to \(q(t)\) .
	The signal \(v_2(t)\) shows distortions compared to \(q(t)\) .
	The signal \(v_2(t)\) is noisy compared to \(q(t)\) .