Difference between revisions of "Aufgaben:Exercise 1.3Z: ISDN Bus System and Interfaces"

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[[File:P_ID1580__Bei_Z_1_3.png|right|frame|Model of ISDN basic rate interface]]
 
[[File:P_ID1580__Bei_Z_1_3.png|right|frame|Model of ISDN basic rate interface]]
The graphic shows an ISDN transmission system. One recognizes:
+
The graphic shows an ISDN transmission system.  One recognizes:
*the network termination (NTBA) at the subscriber,
+
# The network termination  $\rm (NTBA)$  at the subscriber,
*the  $\rm U_{\rm K0}$ interface as the connection between the NTBA and the local exchange (LE),
+
# the  $\rm U_{\rm K0}$ interface as the connection between the NTBA and the local exchange  $\rm (LE)$,
*the  $\rm S_{0}$ bus, to which several terminal equipment  (TE)  of the subscriber can be connected.
+
#the  $\rm S_{0}$ bus,  to which several terminal equipment  $\rm (TE)$  of the subscribers can be connected.
  
  
In the subscriber connection area (between the local exchange and NTBA,  $\rm U_{\rm K0}$) two-wire transmission is used for economic reasons.
+
On the  $\rm U_{\rm K0}$  bus,  two-wire transmission is used for economic reasons.
  
To decouple the receiver from its own transmitter, directional separation methods are required:
+
To decouple the receiver from its own transmitter,  directional separation methods are required:
*The ''fork circuit''  is a bridge circuit, where an attempt is made to approximate the input impedance  $Z_{\rm L}(f)$  of the copper two-wire line coupled via transformers as closely as possible by means of an artificial line replica  $Z_{\rm N}(f)$. 
+
*The  "fork circuit"  is a bridge circuit,  where an attempt is made to approximate the input impedance  $Z_{\rm L}(f)$  of the copper two-wire line coupled via transformers as closely as possible by means of an artificial line replica  $Z_{\rm N}(f)$. 
*For narrowband signals, the resistance replica of  $Z_{\rm L}(f)$  by  $Z_{\rm N}(f)$  succeeds relatively well, so that the decoupling of transmitter and receiver is ensured by the fork circuit alone.
 
*For broadband signals, the ''echo cancellation method''  must also be used. Here, the transmitter emits test signals at regular intervals, measures the received signal and determines the echo impulse response from it.
 
*In normal operation, the echo canceller calculates the expected echo of its own transmitter depending on the message and subtracts this from the received signal in a transversal filter whose coefficients are set and readjusted by a powerful processor.
 
  
 +
*For narrowband signals,  the resistance replica of  $Z_{\rm L}(f)$  by  $Z_{\rm N}(f)$  succeeds relatively well,  so that the decoupling of transmitter and receiver is ensured by the fork circuit alone.
  
 +
*For broadband signals,  the  "echo cancellation method"  must also be used.  Here,  the transmitter emits test signals at regular intervals,  measures the received signal and determines the echo impulse response from it.
  
 +
*In normal operation,  the echo canceller calculates the expected echo of its own transmitter depending on the message and subtracts this from the received signal in a transversal filter whose coefficients are set and re-adjusted by a powerful processor.
  
  
  
  
''Note:''
+
 
 +
Note:  
  
 
*The exercise belongs to the chapter  [[Examples_of_Communication_Systems/ISDN_Basic_Access|"ISDN Basic Access"]].
 
*The exercise belongs to the chapter  [[Examples_of_Communication_Systems/ISDN_Basic_Access|"ISDN Basic Access"]].
*In particular, reference is made to the section  [[Examples_of_Communication_Systems/ISDN_Basic_Access#Directional_separation_method|"Directional separation method"]].
+
 
 +
*In particular,  reference is made to the section  [[Examples_of_Communication_Systems/ISDN_Basic_Access#Directional_separation_method|"Directional separation method"]].
  
  
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{Is the ISDN system shown a
 
{Is the ISDN system shown a
 
|type="()"}
 
|type="()"}
+ Basic Rate Interface  (BRI),
+
+ Basic Rate Interface  $\rm (BRI)$,
- Primary Rate Interface  (PRI)?
+
- Primary Rate Interface  $\rm (PRI)$?
  
 
{What are the characteristics of the  $\rm U_{\rm K0}$ interface?
 
{What are the characteristics of the  $\rm U_{\rm K0}$ interface?
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+ It is realized by one copper twin pair.
 
+ It is realized by one copper twin pair.
 
- It is realized by two copper twisted pairs.
 
- It is realized by two copper twisted pairs.
- It is a fiber optic connection.
+
- It is a fiber-optic connection.
  
 
{What are the properties of the  $\rm S_{0}$ interface?
 
{What are the properties of the  $\rm S_{0}$ interface?
Line 50: Line 52:
 
- It is realized by one copper twin pair
 
- It is realized by one copper twin pair
 
+ It is realized by two copper twisted pairs.
 
+ It is realized by two copper twisted pairs.
- It is a fiber optic connection.
+
- It is a fiber-optic connection.
  
 
{Which statements are valid regarding directional separation methods?
 
{Which statements are valid regarding directional separation methods?
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+ They are part of the  $\rm U_{\rm K0}$ interface.
 
+ They are part of the  $\rm U_{\rm K0}$ interface.
 
- They are part of the  $\rm S_{0}$ interface.
 
- They are part of the  $\rm S_{0}$ interface.
+ A fork circuit can be found in every NTBA.
+
+ A fork circuit can be found in every  $\rm NTBA$.
  
 
{Which statements are valid regarding the connection options to the  $\rm S_{0}$ bus?
 
{Which statements are valid regarding the connection options to the  $\rm S_{0}$ bus?

Revision as of 16:21, 18 October 2022

Model of ISDN basic rate interface

The graphic shows an ISDN transmission system.  One recognizes:

  1. The network termination  $\rm (NTBA)$  at the subscriber,
  2. the  $\rm U_{\rm K0}$ interface as the connection between the NTBA and the local exchange  $\rm (LE)$,
  3. the  $\rm S_{0}$ bus,  to which several terminal equipment  $\rm (TE)$  of the subscribers can be connected.


On the  $\rm U_{\rm K0}$  bus,  two-wire transmission is used for economic reasons.

To decouple the receiver from its own transmitter,  directional separation methods are required:

  • The  "fork circuit"  is a bridge circuit,  where an attempt is made to approximate the input impedance  $Z_{\rm L}(f)$  of the copper two-wire line coupled via transformers as closely as possible by means of an artificial line replica  $Z_{\rm N}(f)$. 
  • For narrowband signals,  the resistance replica of  $Z_{\rm L}(f)$  by  $Z_{\rm N}(f)$  succeeds relatively well,  so that the decoupling of transmitter and receiver is ensured by the fork circuit alone.
  • For broadband signals,  the  "echo cancellation method"  must also be used.  Here,  the transmitter emits test signals at regular intervals,  measures the received signal and determines the echo impulse response from it.
  • In normal operation,  the echo canceller calculates the expected echo of its own transmitter depending on the message and subtracts this from the received signal in a transversal filter whose coefficients are set and re-adjusted by a powerful processor.



Note:


Questions

1

Is the ISDN system shown a

Basic Rate Interface  $\rm (BRI)$,
Primary Rate Interface  $\rm (PRI)$?

2

What are the characteristics of the  $\rm U_{\rm K0}$ interface?

It is realized by one copper twin pair.
It is realized by two copper twisted pairs.
It is a fiber-optic connection.

3

What are the properties of the  $\rm S_{0}$ interface?

It is realized by one copper twin pair
It is realized by two copper twisted pairs.
It is a fiber-optic connection.

4

Which statements are valid regarding directional separation methods?

They are part of the  $\rm U_{\rm K0}$ interface.
They are part of the  $\rm S_{0}$ interface.
A fork circuit can be found in every  $\rm NTBA$.

5

Which statements are valid regarding the connection options to the  $\rm S_{0}$ bus?

The  $\rm S_{0}$ bus is terminated with  $100 \ \rm Ω$. 
The length of the  $\rm S_{0}$ bus is unlimited.
Up to  $150 \ \rm m$  in length, you can connect up to eight devices.
ISDN terminal equipment can be connected directly to the  $\rm S_{0}$ bus.
Analog devices can be connected directly to the  $\rm S_{0}$ bus.


Solution

(1)  The identifier "$0$" already indicates a basic rate interface. In the case of the primary rate multiplex connection, the interfaces are designated $\rm S_{\rm 2M}$ and $\rm U_{\rm K2}$, while the network termination equipment is designated NTPM (Network Termination for Primary Rate Multiplex Access).


(2)  Answer 1 is correct:

  • Each NTBA is connected to the local exchange by a pair of wires. The identifier "K" in $\rm U_{\rm K0}$ indicates a copper line.
  • Only in the case of a "primary rate interface" with 30 B channels, one D channel and one synchronization channel is a connection via optical fiber possible.
  • But even for this, copper lines are usually used.


(3)  Solution 2 is correct:

  • In the house connection area, ISDN uses four-wire transmission, with one copper twisted pair for each transmission direction.


(4)  Solutions 1 and 3 are correct:

  • A directional separation method is only required for two-wire transmission,
  • whereby the simpler method is realized by means of a fork circuit in each NTBA.


(5)  Solutions 1, 3 and 4 are correct:

  • If the length is limited to 150 meters, up to eight terminals can be connected at any point. This is referred to as a short bus.
  • An extended bus exists if the line length is 500 meters or less.
  • Here, up to four terminal equipment can be connected; these must be concentrated on the last 50 meters before the terminating resistor $(100 \ \rm \Omega)$.
  • In the case of a single connection, the line length can be increased to one kilometer (long bus).
  • Analog terminal equipment cannot be connected directly to the $\rm S_{0}$ bus, but only via a terminal adapter (TA).