Difference between revisions of "Aufgaben:Exercise 1.1Z: ISDN Connection"

Revision as of 13:47, 25 December 2020

a telephone connection scenario

We consider the scenario shown in the picture:

A woman from Munich dials a number in Hamburg with her ISDN phone. However, she cannot reach the person she wants to talk to, so she leaves him a message on tape.

The distortion-free connection is fully described by

an attenuation coefficient $\alpha$,
a term $\tau$, and
the current signal-to-noise ratio (SNR)

Notes: The task shall establish a relation between this real scenario and the functional units of a general message transmission system mentioned in the theory section .

Questions

Solution

(1) The first two statements are correct:

The speech signal ${q(t)}$ must first be converted into an electrical signal and then prepared for transmission.
For ISDN the transmitted signal ${s(t)}$ is digital.

(2) Correct are the solutions 3 and 4:

The received signal ${r(t)}$ is always analog due to the unavoidable thermal noise.
The message sink is the answering machine.
In an ideal transmission system $v(t) = {q(t)}$ should apply.
However, due to the additive noise term ${n(t)}$, the attenuation $\alpha$ and the running time $\tau$ the following applies here:

$$v(t) = \alpha \cdot q ( t - \tau) + n(t).$$

By our definitions, this is a distortion-free system.

@@ Line 50: / Line 50: @@
 '''(1)'''&nbsp;  The <u>first two statements</u> are correct:
 *The speech signal&nbsp; ${q(t)}$&nbsp; must first be converted into an electrical signal and then prepared for transmission.
-*For ISDN the transmitted signal is&nbsp; ${s(t)}$&nbsp; digital.
+*For ISDN the transmitted signal&nbsp; ${s(t)}$&nbsp; is digital.
@@ Line 56: / Line 56: @@
 '''(2)'''&nbsp; Correct are the <u>solutions 3 and 4</u>:
 *The received signal&nbsp; ${r(t)}$&nbsp; is always analog due to the unavoidable thermal noise.
-*The message sink is the answering machine
+*The message sink is the answering machine.
 *In an ideal transmission system&nbsp; $v(t) = {q(t)}$&nbsp; should apply.
-* Due to the additive noise term&nbsp; ${n(t)}$, the damping&nbsp; $\alpha$&nbsp; and the running time&nbsp; $\tau$&nbsp; but applies here:
+*However, due to the additive noise term&nbsp; ${n(t)}$, the attenuation&nbsp; $\alpha$&nbsp; and the running time&nbsp; $\tau$&nbsp; the following applies here:
 :$$v(t) = \alpha \cdot q ( t - \tau) + n(t).$$
 *By our definitions, this is a distortion-free system.

	The received signal $r(t)$ is digital.
	The news sink is the telephone set in Hamburg.
	The news sink is the answering machine.
	The following applies $v(t) = \alpha \cdot q(t - \tau ) + {n(t)}$.
	There is an ideal transmission system.

	The news source is the caller. The source signal ${q(t)}$ is the acoustic wave of her voice signal.
	The unit labelled "transmitter" contains, among other things, a signal converter and a modulator.
	The transmitted signal $s(t)$ is analog.