Aufgaben:Exercise 1.2Z: Puls Code Modulation: Difference between revisions

Revision as of 12:02, 26 March 2021

All modern communication systems are digital. The principle of digital transmission of speech signals goes back to Alec Reeves , who invented the so-called Puls-code modulation (PCM) as early as 1938.

On the right you see the (simplified) block diagram of the PCM transmitter with three functional units:

The band-limited speech signal ${q(t)}$ is sampled, where the Sampling Theorem is observed, and yields the sampled signal $q_{\rm A}(t)$.
Each sample $q_{\rm A}(t)$ is mapped to one of $M = 2^N$ results in the quantized signal $q_{\rm Q}(t)$.
Each individual quantized value is represented by a code sequence of $N$ binary symbols and results in the coded signal $q_{\rm C}(t)$.

In this task only the different signals of the PCM transmitter are to be classified. Later tasks will deal with other properties of pulse-code modulation.

Notes: This task belongs to the chapter Signal classification.

Questions

Solution

(1) Correct are the solutions 1, 2 and 4:

The source signal ${q(t)}$ is analog, i.e. continuous in time and value.
In general, it makes no sense to transmit a deterministic signal.
For the mathematical description, a deterministic source signal – such as a periodic signal – is better suited than a random signal.
Deterministic signals are also used for testing in order to be able to reconstruct detected errors.

(2) Correct are the solution suggestions 2 and 3:

After sampling, the signal $q_{\rm A}(t)$ is still value-continuous, but now also time-discrete.
The sampling frequency $f_{\rm A}$ is given by the so-called sampling theorem .
The greater the maximum frequency $f_{\rm N,\,max}$ of the message signal, the greater must $f_{\rm A} ≥ 2 \cdot f_{\rm N,\,max}$ be selected.

(3) Correct are the solution suggestions 1 and 3:

The quantized signal $q_{\rm Q}(t)$ is time and value discrete, where the number of steps are $M = 2^8 = 256$ .
A binary signal, on the other hand, is a discrete value signal with the number of steps $M = 2$.

(4) Correct here are the solutions 1, 3 and 5:

The coded signal $q_{\rm C}(t)$ is binary $($level number $M = 2)$ with bit duration $T_{\rm B} = T_{\rm A}/8$.

@@ Line 2: / Line 2: @@
-[[File:EN_Sig_Z_1_2.png|right|frame|Components of pulse code modulation]]
+[[File:EN_Sig_Z_1_2.png|right|frame|Components of pulse-code modulation]]
 All modern communication systems are digital. The principle of digital transmission of speech signals goes back to&nbsp; [https://de.wikipedia.org/wiki/Alec_Reeves Alec Reeves]&nbsp;, who invented the so-called&nbsp; ''Puls-code modulation''&nbsp; ('''PCM''')&nbsp; as early as 1938.
 On the right you see the (simplified) block diagram of the PCM transmitter with three functional units:
-*The band-limited speech signal&nbsp; ${q(t)}$&nbsp; is sampled, where the&nbsp; [[Signal_Representation/Time_Discrete_Signal_Representation#Das_Abtasttheorem|Abtasttheorem]]&nbsp; is observed, and yields the sampled signal&nbsp; $q_{\rm A}(t)$.
+*The band-limited speech signal&nbsp; ${q(t)}$&nbsp; is sampled, where the&nbsp; [[Signal_Representation/Time_Discrete_Signal_Representation#The_Sampling_Theorem|Sampling Theorem]]&nbsp; is observed, and yields the sampled signal&nbsp; $q_{\rm A}(t)$.
 * Each sample &nbsp;$q_{\rm A}(t)$&nbsp; is mapped to one of&nbsp; $M = 2^N$&nbsp; results in the quantized signal&nbsp; $q_{\rm Q}(t)$.
 * Each individual quantized value is represented by a code sequence of&nbsp; $N$&nbsp; binary symbols and results in the coded signal&nbsp; $q_{\rm C}(t)$.
-In this task only the different signals of the PCM transmitter are to be classified. Later tasks will deal with other properties of pulse code modulation.
+In this task only the different signals of the PCM transmitter are to be classified. Later tasks will deal with other properties of pulse-code modulation.

	In normal operation ${q(t)}$ is a stochastic signal.
	A deterministic source signal is only useful in test operation or for theoretical investigations.
	${q(t)}$ is a time-discrete signal.
	${q(t)}$ is a continuous-valued signal.

	$q_{\rm Q}(t)$ is a time-discrete signal.
	$q_{\rm Q}(t)$ is a discrete-valued with signal $M = 8$ possible values.
	$q_{\rm Q}(t)$ is a discrete-valued with signal $M = 256$ possible values.
	$q_{\rm Q}(t)$ is a binary signal.

	$q_{\rm C}(t)$ is a time-discrete signal.
	$q_{\rm C}(t)$ is a discrete-valued signal with $M = 8$ possible values.
	$q_{\rm C}(t)$ is a binary signal.
	When sampling at distance $T_{\rm A}$ the bit duration is $T_{\rm B} = T_{\rm A}$.
	When sampling at distance $T_{\rm A}$ the bit duration is $T_{\rm B} = T_{\rm A}/8$.

	$q_{\rm A}(t)$ is a discrete-valued signal.
	$q_{\rm A}(t)$ is a time-discrete signal.
	The higher the maximum frequency of the message signal, the higher the sampling rate must be selected.