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The images and descriptions in this article are updated to cover interfacing between RingMaster CB901 and the AlphaCom XE Audio Server with AMC-IP software version 11.3.3.2 and AlphaPro 11.6.3.3.
 
==SYSTEM BUILD-UP==
 
==SYSTEM BUILD-UP==
 
===General Description===
 
===General Description===
An existing Ring-Master CB901 system can be expanded by adding one
+
An existing Ring-Master CB901 system can be expanded by adding one or more STENTOFON AlphaCom XE exchanges. The two systems are interconnected via data and audio links. Stations and equipment in both systems will interact as part of the same system. The AlphaCom XE IP services can be accessed from the Ring-Master system.
or more STENTOFON AlphaCom E exchanges. The two systems are
+
 
interconnected via data and audio links. Stations and equipment in both
+
[[Image:CB901 General description.jpg|left|thumb|500px]]
systems will interact as part of the same system. The AlphaCom E IP
+
<br style="clear:both;" />
services can be accessed from the Ring-Master system.
+
 
 +
'''<u>Data</u>'''
  
'''Data'''
+
Data are transmitted via one or two serial RS232 links.  
<br>
+
* One link (ETP, External Trunk Protocol) is used for station-to-station calls, Group Call, Call Request and Caller ID.
Data are transmitted via one or two serial RS232 links.
+
* An optional link (SIO, Serial Input Output) is used for other functions like Privacy information and Call Request camp on.
* One link (ETP, External Trunk Protocol) is used for station-tostation
+
 
calls, Group Call, Call Request and Caller ID.
+
'''<u>Audio</u>'''
* An optional link (SIO, Serial Input Output) is used for other
+
 
functions like Privacy information and Call Request camp on.
+
The audio interconnection between CB901 and AlphaCom XE is analogue.
<br>
+
* There are 6 conversation channels in a 12 pair twisted cable between each Interlink B board in CB901 and AGA board(s) in AlphaCom XE.
<br>
+
 
'''Audio'''
+
'''<u>Audio switching control (Duplex)</u>'''
<br>
+
 
The audio interconnection between CB901 and AlphaCom E is
+
There is no transfer of switching control signals between the CB901 and AlphaCom XE. The switching will take place individually in the Ring-Master station and in AlphaCom XE.
analogue.
+
 
* There are 6 conversation channels in a 12 pair twisted cable
+
 
between each Interlink B board in CB901 and AGA board(s) in
+
'''<u>Programming</u>'''
AlphaCom E.
+
 
<br>
+
The CB901-AlphaCom XE interface features are programmed by use of:
<br>
 
'''Audio switching control (Duplex)'''
 
<br>
 
There is no transfer of switching control signals between the CB901 and
 
AlphaCom E. The switching will take place individually in the Ring-Master station and in AlphaCom E.
 
<br>
 
<br>
 
'''Programming'''
 
<br>
 
The CB901-AlphaCom E interface features are programmed by use of:
 
 
* SVT for the CB901 part
 
* SVT for the CB901 part
* AlphaPro and AlphaWeb for the AlphaCom E part and the Ring-Master Daemon
+
* AlphaPro and AlphaWeb for the AlphaCom XE part and the Ring-Master Daemon
  
 
==== Basic System Features====
 
==== Basic System Features====
 
All internal features in both systems will remain as they are.
 
All internal features in both systems will remain as they are.
<br>
 
The following features will be included in the interface between CB901 and AlphaCom E:
 
  
 +
The following features will be included in the interface between CB901 and AlphaCom XE:
 
* ''Station to station calling''.
 
* ''Station to station calling''.
<br>
 
 
* ''Display information''. <br> Call number of calling station or station ID
 
* ''Display information''. <br> Call number of calling station or station ID
<br>
 
 
* ''Simultaneous (global) All-Call and Group-Call''.<br> One global call at the time in the RM /ACE system.
 
* ''Simultaneous (global) All-Call and Group-Call''.<br> One global call at the time in the RM /ACE system.
<br>
+
* ''Call request and queuing from stations in CB901 to master stations(guards) in AlphaCom XE''.<br> Calling stations will be camped on in one program distribution channel in CB901.
* ''Call request and queuing from stations in CB901 to master stations(guards) in AlphaCom E''.<br> Calling stations will be camped on in one program distribution channel in CB901.
+
* ''Pocket paging''. <br> Automatic pocket paging in both systems. One individual serial ESPA 4.4.4. connection between AlphaCom XE and the pager system; and CB901 and the pager system. <br> The info in the pager display will identify the caller who has to be called back manually.
<br>
+
* ''Privacy''.<br> Stations in CB901 will be tested for privacy also when called from AlphaCom XE. The subscriber board must be modified according to section 6.2
* ''Pocket paging''. <br> Automatic pocket paging in both systems. One individual serial ESPA 4.4.4. connection between AlphaCom E and the pager system; and CB901 and the pager system. <br> The info in the pager display will identify the caller who has to be called back manually.
+
* ''Remote door opening''. <br> AlphaCom XE will generate a DTMF signal when a button is pressed in the AlphaCom station during conversation with the CB901 door station. This signal will be decoded by the remote output board DP997 inside the RM door station and used to activate the magnetic lock.
<br>
 
* ''Privacy''.<br> Stations in CB901 will be tested for privacy also when called from AlphaCom E. The subscriber board must be modified according to section 6.2
 
<br>
 
* ''Remote door opening''. <br> AlphaCom E will generate a DTMF signal when a button is pressed in the AlphaCom station during conversation with the CB901 door station. This signal will be decoded by the remote output board DP997 inside the RM door station and used to activate the magnetic lock.
 
 
 
  
 +
See: '''[[Door opening of Ring Master stations from AlphaCom]]'''
  
 
=== Software Description ===
 
=== Software Description ===
 
====Ring-Master CB901 ====
 
====Ring-Master CB901 ====
 
 
The ETP (External Trunk Protocol) communication software is included in revisions from TX5.7. The software in the Ring-Master system must be upgraded if the present software revision is TX5.6 or lower.
 
The ETP (External Trunk Protocol) communication software is included in revisions from TX5.7. The software in the Ring-Master system must be upgraded if the present software revision is TX5.6 or lower.
  
 
The upgrade includes changing of E-PROMs on all processor boards. It is not necessary to change the software in the DNC.
 
The upgrade includes changing of E-PROMs on all processor boards. It is not necessary to change the software in the DNC.
 +
 +
[[Image:CB901 Processor board.jpg|left|thumb|500px|Processor board]]
 +
<br style="clear:both;" />
  
 
If the software revision is lower than TX5.0 (TX4.x or TX3.x) the processor board(s) must be changed.
 
If the software revision is lower than TX5.0 (TX4.x or TX3.x) the processor board(s) must be changed.
Line 75: Line 65:
 
'''Note: The same software must be installed in all nodes in a CB901 multistage system'''.
 
'''Note: The same software must be installed in all nodes in a CB901 multistage system'''.
  
==== AlphaCom E ====
+
==== AlphaCom E (XE) ====
  
The software must be of revision '''10.30''' or higher. <br> This revision includes the following software routines:
+
The software must be of revision '''10.30''' or higher. It is recommended to always have the latest version available.<br> This revision includes the following software routines:
  
 
* The software module (Daemon) which is linking the CB901 ETP format with the AlphaCom E main software.
 
* The software module (Daemon) which is linking the CB901 ETP format with the AlphaCom E main software.
 
* The WEB interface which is used to configure the AlphaCom for communication with CB901 (AlphaWeb)
 
* The WEB interface which is used to configure the AlphaCom for communication with CB901 (AlphaWeb)
<br>
+
 
The AlphaPro software must be of revision '''10.28''' or higher.
+
The AlphaPro software must be of revision '''10.28''' or higher. This revision includes the following commands:
This revision includes the following commands:
 
 
* Identification of CB901 stages as nodes in AlphaCom
 
* Identification of CB901 stages as nodes in AlphaCom
 
* Identify the audio links
 
* Identify the audio links
<br>
+
 
'''''AlphaWeb Configuration Commands'''''<br>The Ring-Master Daemon will use a number of tables to maintain the ETP function. These tables will be configurable through the AlphaWeb window.
+
'''''<u>AlphaWeb Configuration Commands</u>'''''
<br>
+
 
 +
The Ring-Master Daemon will use a number of tables to maintain the ETP function. These tables will be configurable through the AlphaWeb window.
 +
 
 
The following tables are identified:
 
The following tables are identified:
<br>
+
 
 
* Group Call
 
* Group Call
* Call Request (CAS) to stations in AlphaCom E
+
* Call Request (CAS) to stations in AlphaCom XE
 
* Program channel for call request camp-on in CB901.
 
* Program channel for call request camp-on in CB901.
 
* Privacy test of stations in CB901
 
* Privacy test of stations in CB901
 
* RMD system parameters
 
* RMD system parameters
  
'''''AlphaWeb System Monitoring and Logging'''''<br>The AlphaCom E can monitor and log real-time events. This can be
+
'''''<u>AlphaWeb System Monitoring and Logging</u>'''''
viewed in the AlphaWeb.
+
 
 +
The AlphaCom XE can monitor and log real-time events. This can be viewed in the AlphaWeb.
 +
 
 +
'''''<u>Ring-Master Daemon System log</u>'''''
  
'''''Ring-Master Daemon System log''''' <br> The Ring-Master Daemon (RMD) will report the following to the syslog server:
+
The Ring-Master Daemon (RMD) will report the following to the syslog server:
 
* RMD Up/Down
 
* RMD Up/Down
 
* AlphaNet Connected/Disconnected
 
* AlphaNet Connected/Disconnected
 
* Serial Port Up/Down
 
* Serial Port Up/Down
  
'''''Ring-Master Daemon System Monitoring''''' <br> The Ring-Master Daemon will report the following to the syslog server:
+
'''''<u>Ring-Master Daemon System Monitoring</u>'''''
 +
 
 +
The Ring-Master Daemon will report the following to the syslog server:
 
* AGA/ETP trunks Up/Down
 
* AGA/ETP trunks Up/Down
 
* AGA Trunk allocation failed (no more audio links available)
 
* AGA Trunk allocation failed (no more audio links available)
 
* Unknown/Erroneous commands from the Ring-Master system
 
* Unknown/Erroneous commands from the Ring-Master system
 
  
 
=== Programming ===
 
=== Programming ===
 +
Individual programming will be carried out in each system by using a locally connected data terminal (PC or laptop).
  
Individual programming will be carried out in each system by using a locally connected data terminal (PC or laptop).
 
<br>
 
 
One system can not be programmed from the other system.
 
One system can not be programmed from the other system.
<br>
+
 
'''''Number plan'''''
+
'''''<u>Number plan</u>'''''
* The call number in AlphaCom E must have 4 digits in order to call from CB901 to AlphaCom E. This is limited by the ETP format.
+
* The call number in AlphaCom XE must have 4 digits in order to call from CB901 to AlphaCom XE. This is limited by the ETP format.
* The number of call digits in AlphaCom E is 2 - 5. Only 4-digit numbers can be reached from the RM side.
+
* The number of call digits in AlphaCom XE is 1 - 8. Only 4-digit numbers can be reached from the RM side.
 
* The maximum number of call digits in CB901 is 6. All digits from 2 to 6 can be reached from both sides.
 
* The maximum number of call digits in CB901 is 6. All digits from 2 to 6 can be reached from both sides.
 +
 +
[[Image:RM-AC NumberPlan 01.png|left|thumb|500px]]
 +
<br style="clear:both;" />
  
 
==== Programming Ring-Master CB901 ====
 
==== Programming Ring-Master CB901 ====
Use a terminal emulating program such as ProCom plus or Hyperterminal. See section 4.2 for detailed procedure.
+
Use a terminal emulating program such as ProCom plus or HyperTerminal. See section 4.2 for detailed procedure.
  
Purpose of programming
+
'''''<u>Purpose of programming</u>'''''
* Set the data of the serial port used for ETP communication with AlphaCom E
+
* Set the data of the serial port used for ETP communication with AlphaCom XE
* Set the data of the serial port used for remote dialing from AlphaCom E (PC port) and status output to AlphaCom E
+
* Set the data of the serial port used for remote dialing from AlphaCom XE (PC port) and status output to AlphaCom XE
* Program the feature code for the access to the numbers in the AlphaCom E <br> If the feature code is one digit ‘F’, then the call number in AlphaCom E will be ‘F A A A’. ‘AAA’ represent any digit
+
* Program the feature code for the access to the numbers in the AlphaCom XE <br> If the feature code is one digit ‘F’, then the call number in AlphaCom XE will be ‘F A A A’. ‘AAA’ represent any digit
* Identify the 6 hex positions where the NFE1545 audio interface board is connected. This is fixed to F8-FD.
+
* Identify the 6 hex positions where the NFE1545 audio interface board is connected. This is fixed to E0-E5.
 
* Identify the 2 hex positions (call numbers) that will be used for privacy test of the RM stations (ETP and SIO).
 
* Identify the 2 hex positions (call numbers) that will be used for privacy test of the RM stations (ETP and SIO).
<br>
+
 
 
A modification must be carried out on the subscriber board in order to link two and two subscriber positions together. Se section 6.2
 
A modification must be carried out on the subscriber board in order to link two and two subscriber positions together. Se section 6.2
<br>
+
 
 
* Each modified subscriber board will offer 4 privacy links.
 
* Each modified subscriber board will offer 4 privacy links.
 
* Each CB901 stage must have one modified subscriber board for privacy test of the stations within the stage.
 
* Each CB901 stage must have one modified subscriber board for privacy test of the stations within the stage.
  
==== Programming AlphaComE ====
+
==== Programming AlphaCom XE ====
Use the STENTOFON AlphaPro and AlphaWeb PC programs to
+
Use the STENTOFON AlphaPro PC program and AlphaWeb to perform programming. See section 4.3 for detailed programming procedure.
perform programming. See section 4.3 for detailed programming
+
 
procedure.
+
 
<br>
+
'''''<u>Purpose of programming</u>'''''
<br>
 
'''''Purpose of programming'''''
 
 
* Identify the CB901 stage(s) where the NFE1545 audio interface board(s) is(are) installed
 
* Identify the CB901 stage(s) where the NFE1545 audio interface board(s) is(are) installed
 
* Program the 6 positions used by the AGA board(s)
 
* Program the 6 positions used by the AGA board(s)
Line 154: Line 149:
  
 
=== Rack layouts ===
 
=== Rack layouts ===
 +
 
==== Ring-Master CB901 ====
 
==== Ring-Master CB901 ====
  
Most board types have their fixed position in the racks. Some positions
+
Most board types have their fixed position in the racks. Some positions may be left empty or accept different boards depending on performance and configuration. The table below is a typical set-up when integrated
may be left empty or accept different boards depending on performance
+
with AlphaCom XE.
and configuration. The table below is a typical set-up when integrated
 
with AlphaCom E.
 
  
<br>
+
[[Image:CB901 Rock layouts1.jpg|left|thumb|500px]]
The subscriber lines are available on P2 and the subscriber number
+
<br style="clear:both;" />
address is in hexadecimal format.
+
[[Image:CB901 Rock layouts2.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
  
 +
The subscriber lines are available on P2 and the subscriber number address is in hexadecimal format.
  
 
{|border="1"
 
{|border="1"
Line 184: Line 180:
 
|10||NFE 1626 || Audio Interface Board || For C - GC - AC - PD
 
|10||NFE 1626 || Audio Interface Board || For C - GC - AC - PD
 
|-
 
|-
|10||NFE 1625 || Subscriber Board || If GC - AC - PD is not needed
+
|10||NFE 1625 || Subscriber Board || If GC - AC - PD *
 
|-
 
|-
|11 || NFE 1545 || Audio Interface Board || Audio to AlphaCom,<br>address F8-FD
+
|11 || NFE 1545 || Audio Interface Board || Audio to AlphaCom,<br>address E0-E5
 
|-
 
|-
 
|12 || NFE 1545 || Audio Interface Board || If 12 audio links are needed
 
|12 || NFE 1545 || Audio Interface Board || If 12 audio links are needed
Line 219: Line 215:
 
{|
 
{|
 
|width="30"|C
 
|width="30"|C
|width="80"|= Call
+
|width="280"|= Call
 
|-
 
|-
 
| GC || = Group Call
 
| GC || = Group Call
Line 228: Line 224:
 
|-
 
|-
 
| D || = Display
 
| D || = Display
 +
|-
 +
| * || = PD card is only required for Call Request.
 
|}
 
|}
  
 +
==== AlphaCom XE7 ====
 +
Except for the AMC-IP Computer Board in position 7, all board types can be inserted in any board position.
  
 +
[[Image:CB901 AlphaCom E7.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
  
==== AlphaCom E7 ====
+
When interconnected to CB901, at least one AGA Audio Interface Board with 6 lines will be used. It is good practice to insert these boards from position 6 and downwards.
 
 
Except for the AMC-IP Computer Board in position 7, all board types
 
can be inserted in any board position.
 
  
When interconnected to CB901, at least one AGA Audio Interface Board
+
Normally there will be only ASLT Subscriber Boards for analogue stations in the rest of the positions.
with 6 lines will be used. It is good practice to insert these boards from
 
pos 6 and downwards.
 
  
Normally there will be only ASLT Subscriber Boards for analogue
+
The stations and the AGA audio lines are connected to plug-on screw terminals on the backplane. The physical line numbers are equal to the decimal station number.
stations in the rest of the positions.
 
  
The stations and the AGA audio lines are connected to plug-on screw
+
IP stations do not need ASLT boards; they are connected to the IP network.
terminals on the backplane. The physical line numbers are equal to the
 
decimal station number.
 
  
IP stations do not need ASLT boards; they are connected to the IP bus.
+
==== AlphaCom XE20 and XE26 ====
 +
The AMC-IP Computer Board and the APC Program and Clock Board have dedicated positions in slot 25 and 26.
  
 +
[[Image:CB901 AlphaCom E20 and E26.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
  
==== AlphaCom E20 and E26 ====
+
When interconnected to CB901, at least one AGA Audio Interface Board with 6 lines will be used. This board should be inserted in slot position 23.
The AMC-IP Computer Board and the APC Program and Clock Board
 
have dedicated positions in slot 25 and 26.
 
  
When interconnected to CB901, at least one AGA Audio Interface Board
+
If more AGA boards are used, it is good practice to insert these boards from position 23 and downwards even if they will function in any position.
with 6 lines will be used. This board should be inserted in slot pos. 24.
 
  
If more AGA boards are used, it is good practice to insert these boards
+
Normally there will be only ASLT Subscriber Boards for analogue stations and/or ATLB boards for analogue telephones in the rest of the positions.
from pos. 23 and downwards even if they will function in any position.
 
  
Normally there will be only ASLT Subscriber Boards for analogue
 
stations and/or ATLB boards for analogue telephones in the rest of the
 
positions.
 
  
 +
'''Note that board positions 2-7 are missing in AlphaCom XE20 exchanges.'''
  
'''Note that board positions 2-7 are missing in AlphaCom E20 exchanges.'''<br>
+
The stations and the AGA audio lines are available on connection boards on the back of the rack. The physical line numbers are equal to the decimal station number.
The stations and the AGA audio lines are available on connection
 
boards on the back of the rack. The physical line numbers are equal to
 
the decimal station number.
 
  
IP stations do not need ASLT boards; they are connected to the IP bus.
+
IP stations do not need ASLT boards; they are connected to the IP network.
  
 +
* '''Note: Avoid using AGA in position 24, this position is for MultiModule and High Availability use only!'''
  
 
=== System Configuration ===
 
=== System Configuration ===
 
==== CB901 ====
 
==== CB901 ====
  
All CB901 system configurations can be interfaced to AlphaCom E. One
+
All CB901 system configurations can be interfaced to AlphaCom XE. One CB901 stage has one basic board rack with power, system boards and up to 8 subscriber boards for 64 lines. An additional subscriber board
CB901 stage has one basic board rack with power, system boards and
 
up to 8 subscriber boards for 64 lines. An additional subscriber board
 
 
rack will extend the number of lines with up to 176.
 
rack will extend the number of lines with up to 176.
  
'''''Single stage'''''
+
'''''<u>Single stage</u>'''''
*64 subscribers in a basic board rack<br>
+
[[Image:CB901 Single Stage.jpg|left|thumb|500px]]
* Up to 240 subscribers with additional subscriber board rack<br>
+
<br style="clear:both;" />
* 15 internal conversation links<br>
+
* 64 subscribers in a basic board rack
'''''Double stage'''''
+
* Up to 240 subscribers with additional subscriber board rack
<br>
+
* 15 internal conversation links
* Up to 480 subscribers with subscriber board racks<br>
+
----
* 15 internal conversation links in each 240 number node<br>
+
 
* 8 conversation links between the nodes<br>
+
'''''<u>Double stage</u>'''''
 +
[[Image:CB901 Double Stage.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Up to 480 subscribers with subscriber board racks
 +
* 15 internal conversation links in each 240 number node
 +
* 8 conversation links between the nodes
 
* Node interconnection via 1 x 18 pairs twisted cable or 2 x optical multimode fiber cables
 
* Node interconnection via 1 x 18 pairs twisted cable or 2 x optical multimode fiber cables
<br>
+
----
'''''Triple stage'''''
+
 
* Up to 720 subscribers with subscriber board racks<br>
+
'''''<u>Triple stage</u>'''''
* 15 internal conversation links in each 240 number node<br>
+
[[Image:CB901 Triple Stage.jpg|left|thumb|500px]]
* 8 conversation links between each node<br>
+
<br style="clear:both;" />
* Node interconnection via 3 x 18 pairs twisted cable or 3 x 1 pair optical multimode fibers<br>
+
* Up to 720 subscribers with subscriber board racks
 +
* 15 internal conversation links in each 240 number node
 +
* 8 conversation links between each node
 +
* Node interconnection via 3 x 18 pairs twisted cable or 3 x 1 pair optical multimode fibers
 
* Nodes are interconnected in a triangle configuration
 
* Nodes are interconnected in a triangle configuration
<br>
+
----
'''''Multistage'''''
+
 
 +
'''''<u>Multistage</u>'''''
 +
[[Image:CB901 Multistage.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Up to 30 x 240 (7200) subscribers
 
* Up to 30 x 240 (7200) subscribers
 
* 15 internal conversation links in each 240 number node
 
* 15 internal conversation links in each 240 number node
* Nodes are connected to a Digital Network Controller (DNC) in a star configuration via one pair optical multimode fiber cable<br>
+
* Nodes are connected to a Digital Network Controller (DNC) in a star configuration via one pair optical multimode fiber cable
* 8 conversation links between each node and the DNC<br>
+
* 8 conversation links between each node and the DNC
 
* There are no subscribers connected to the DNC
 
* There are no subscribers connected to the DNC
 +
----
  
 +
====AlphaCom XE====
 +
AlphaCom cabinets have a fixed position for the [[AMC-IP]] Computer Board and the [[APC]] Program and Clock Board (XE20 and XE26 only). All other boards including ASLT Line Boards and AGA Audio Interface Boards can be put in any free position.
  
 +
It is strongly recommended to insert the ASLT boards starting from the lowest board position and the AGA boards from the highest.
  
====AlphaCom E====
+
'''''<u>XE7 – single module</u>'''''
AlphaCom cabinets have a fixed position for the AMC-IP Computer
+
[[Image:CB901 E7 - single module.jpg|left|thumb|500px]]
Board and the APC Program and Clock Board (E20 and E26 only). All
+
<br style="clear:both;" />
other boards including ASLT Line Boards and AGA Audio Interface
+
* Up to 36 traditional stations + IP stations as required.
Boards can be put in any free position.
+
* 6 free positions for AGA or other boards.
 
+
* Each AGA board will reduce the number of traditional stations by 6 per board.
It is strongly recommended to insert the ASLT boards starting from the
+
* 1 internal conversation link per ASLT line board.
lowest board position and the AGA boards from the highest.
+
----
  
<br>
+
'''''<u>XE20 – single module</u>'''''
'''''E7 – single module'''''
+
[[Image:CB901 E20 - single module.jpg|left|thumb|500px]]
* Up to 36 traditional stations + IP stations as required
+
<br style="clear:both;" />
* Each AGA board with 6 audio lines will reduce the number of subscribers by 6
+
* Up to 102 traditional stations + IP stations as required.
* 1 internal conversation link per ASLT line board
+
* 17 free positions for AGA or other boards.
<br>
+
* Each AGA board will reduce the number of traditional stations by 6 per board.
'''''E20 single module'''''<br>
+
* 1 internal conversation link per ASLT line board.
* Up to 80 subscribers + IP stations as required in normal mode. Up to 102 subscribers with extra power supply
+
----
* 5 free positions for AGA or other boards in normal mode.
 
* 1 internal conversation link per ASLT line board
 
  
'''''E26 – single module'''''<br>
+
'''''<u>XE26 – single module</u>'''''
* Up to 138 subscribers + IP stations as required
+
[[Image:CB901 E26 - single module.jpg|left|thumb|500px]]
* More than one AGA board will reduce the number of subscribers by
+
<br style="clear:both;" />
6 per board
+
* Up to 138 traditional stations + IP stations as required.
* 1 internal conversation link per ASLT line board
+
* 23 free positions for AGA or other boards.
 +
* Each AGA board will reduce the number of traditional stations by 6 per board.
 +
* 1 internal conversation link per ASLT line board.
 +
----
  
'''''Multi-modules'''''<br>
+
'''''<u>Multi-modules</u>'''''
* Up to 4 modules (1 master + 1-3 slaves) can be interconnected to act as one exchange node with extended number of subscriber lines.
+
[[Image:CB901 Multi-modules.jpg|left|thumb|500px]]
* 4 x E7 can have up to 144 subscribers
+
<br style="clear:both;" />
* 4 x E20 can have up to 320 subscribers or 408 with extra power supplies
+
* Up to 4 modules (1 master + 1-3 slaves) can be interconnected to act as one exchange node with extended number of analogue subscriber lines.
* 4 x E26 can have up to 552 subscribers
+
* 4 x XE7 can have up to 144 subscribers
* The modules are normally interconnected via an IP network but connection using AE1 boards and E1/T1 signaling is also possible
+
* 4 x XE20 can have up to 408 subscribers
* The number of audio channels depends on the purchased AlphaNet
+
* 4 x XE26 can have up to 552 subscribers
VoIP licenses, max. 30 per module
+
* The modules are normally interconnected via an [[AlphaNet|IP network]] but connection using [[AE1]] boards and E1/T1 signaling is also possible
 +
* The number of audio channels depends on the purchased [[Licenses#AlphaNet|AlphaNet VoIP licenses]], max. 30 per module
 +
----
  
'''''AlphaNet'''''<br>
+
'''''<u>AlphaNet</u>'''''
* Up to 254 AlphaCom E exchanges can be interconnected in one network
+
[[Image:CB901 AlphaNet.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Up to 254 AlphaCom XE exchanges can be interconnected in one network
 
* The exchanges are interconnected via an IP network
 
* The exchanges are interconnected via an IP network
 
* The total number of global directory numbers is limited to 8700
 
* The total number of global directory numbers is limited to 8700
 
* The number of audio channels depends on the purchased AlphaNet VoIP licenses, max. 30
 
* The number of audio channels depends on the purchased AlphaNet VoIP licenses, max. 30
 
+
----
  
 
=== Interconnection ===
 
=== Interconnection ===
  
 
==== General ====
 
==== General ====
The AlphaCom E and Ring-Master systems are interconnected via
+
The AlphaCom XE and Ring-Master systems are interconnected via
 
* One or two RS232 serial ports
 
* One or two RS232 serial ports
* One or several 4-wire, 0 dBm audio links.<br>
+
* One or several 4-wire, 0 dBm audio links.
The physical interfacing between the Ring-Master and AlphaCom E
+
 
exchanges depends on the configuration on both sides, but the general
+
The physical interfacing between the Ring-Master and AlphaCom XE exchanges depends on the configuration on both sides, but the general configuration is the same.
configuration is the same.
+
 
<br>
+
The following examples show the most typical situations. The AlphaCom shown is an XE7, but the general connection to XE20 and XE26 is the same.
The following examples show the most typical situations. The AlphaCom
+
 
shown is an E7, but the general connection to E20 and E26 is the same.
+
 
<br>
+
'''''<u>Single stage CB901 with ETP data link</u>'''''
<br>
+
[[Image:CB901 Single Stage CB901 with ETP data link.jpg|left|thumb|500px]]
'''''Single stage CB901 with ETP data link'''''
+
<br style="clear:both;" />
 
* This configuration will give normal call, Group Call and 6 audio links.
 
* This configuration will give normal call, Group Call and 6 audio links.
 
* Privacy indication and Call Request is NOT supported.
 
* Privacy indication and Call Request is NOT supported.
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
* Pocket Paging must be connected to AlphaCom E.
+
* Pocket Paging must be connected to AlphaCom XE.
<br>
+
----
'''''Single stage CB901 with ETP and SIO data links'''''
+
 
 +
'''''<u>Single stage CB901 with ETP and SIO data links</u>'''''
 +
[[Image:CB901 Single Stage CB901 with ETP and SIO data links.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* This configuration will give normal call, Group Call and 6 audio links.
 
* This configuration will give normal call, Group Call and 6 audio links.
 
* Privacy indication and Call Request is supported.
 
* Privacy indication and Call Request is supported.
 
* Option 1: Display in RM stations is NOT supported.
 
* Option 1: Display in RM stations is NOT supported.
 
* Option 2: One current loop port must be modified to RS232 in CB901
 
* Option 2: One current loop port must be modified to RS232 in CB901
<br>
+
----
'''''Dual stage CB901 with ETP data link'''''
+
 
 +
'''''<u>Dual stage CB901 with ETP data link</u>'''''
 +
[[Image:CB901 Dual stage CB901 width ETP data link.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* This configuration will give normal call, Group Call and 12 audio links.
 
* This configuration will give normal call, Group Call and 12 audio links.
 
* Privacy indication and Call Request is NOT supported.
 
* Privacy indication and Call Request is NOT supported.
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
 
* Pocket Paging can be connected to RM stage 2 or be connected to AlphaCom.
 
* Pocket Paging can be connected to RM stage 2 or be connected to AlphaCom.
 +
----
 +
  
'''''Dual stage CB901 with ETP and SIO data links'''''
+
'''''<u>Dual stage CB901 with ETP and SIO data links</u>'''''
 +
[[Image:CB901 Dual stage CB901 width ETP and SIO data links.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* This configuration will give normal call, Group Call and 12 audio links.
 
* This configuration will give normal call, Group Call and 12 audio links.
 
* Privacy indication and Call Request is supported.
 
* Privacy indication and Call Request is supported.
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
 
* Display in RM stations is supported. (Subscriber boards NFE1813 only).
* Pocket Paging must be connected to AlphaCom E.  
+
* Pocket Paging must be connected to AlphaCom XE.  
 +
----
  
'''''Multi stage CB901'''''
+
'''''<u>Triple stage CB901</u>'''''
 
* The ETP and SIO data links are connected to the first two stages like in a two stage configuration.
 
* The ETP and SIO data links are connected to the first two stages like in a two stage configuration.
 
* Each stage can supply 6 audio links by adding an AGA board in the AlphaCom exchange.
 
* Each stage can supply 6 audio links by adding an AGA board in the AlphaCom exchange.
 +
----
 +
 +
==== Processor board NFE1683 location ====
 +
In order to connect the serial data links to the processor board NFE1683, there must be a P2 connector on the motherboard in board position 19.
  
 +
Old systems using processor boards type NFE1515 or NFE1592 does not have this P2 connector. The new processor board NFE1683 can then be installed in position 20 if there are long pins on the back plane for the serial port connections.
 +
 +
If there are no connection pins for board connector 19 or 20 on the back plane, the whole cabinet must be changed to type DP979.
  
==== Processor board MFE1683 location ====
 
In order to connect the serial data links to the processor board
 
NFE1683, there must be a P2 connector on the motherboard in board
 
position 19.
 
<br>
 
Old systems using processor boards type NFE1515 or NFE1592 does
 
not have this P2 connector. The new processor board NFE1683 can
 
then be installed in position 20 if there are long pins on the back plane
 
for the serial port connections.
 
<br>
 
If there are no connection pins for board connector 19 or 20 on the back
 
plane, the whole cabinet must be changed to type DP979.
 
<br>
 
 
:'''Note: If the processor board is plugged into position 20 in an old rack, a piece of the cabinet profile must cut out in order to get room for the battery RAM on the board.'''
 
:'''Note: If the processor board is plugged into position 20 in an old rack, a piece of the cabinet profile must cut out in order to get room for the battery RAM on the board.'''
  
 
==== ETP data link ====
 
==== ETP data link ====
Use RS232 serial port 4 on the processor board NFE1683 in stage no.1
+
Use RS232 serial port 4 on the processor board NFE1683 in stage no.1 for the ETP data-link connection to AlphaCom XE. This link is controlling the RM station connections.
for the ETP data-link connection to AlphaCom E.
 
This link is controlling the RM station connections.
 
  
'''''CB901, non EMC cabinet'''''
+
'''''<u>CB901, non EMC cabinet</u>'''''
* Insert the upper connector from the CPU terminal block on board connector P2-19. Leave the upper 4 pair of pins unconnected.
+
[[Image:CB901 ETP data link.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Insert the upper connectors from the CPU terminal block on board connector P2-19. Leave the upper 4 pair of pins unconnected.
 
* Connect 3 wires to the terminal block pos. 18, 19 and 20.
 
* Connect 3 wires to the terminal block pos. 18, 19 and 20.
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom E according to the table below.
+
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom XE according to the table below.
 
 
  
 
{| border="1" |align=center
 
{| border="1" |align=center
Line 433: Line 444:
 
|}
 
|}
  
Port 0 in AlphaCom E20 and E26 need an RJ45 – 9-pin D-sub Serial
+
Port 0 in AlphaCom XE20 and XE26 need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.
Cable Adapter type A100A 08010.
+
----
<br>
+
 
<br>
+
'''''<u>CB901, EMC approved cabinet</u>'''''
'''''CB901, EMC approved cabinet'''''
+
[[Image:CB901 ETP data link2.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
 
* Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
 
* Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
 
  
 
{| border="1" |align=center
 
{| border="1" |align=center
Line 459: Line 470:
  
 
Complete connection table for BF952 is found in Appendix 7.1
 
Complete connection table for BF952 is found in Appendix 7.1
 +
----
  
 
====SIO data link, non EMC cabinets====
 
====SIO data link, non EMC cabinets====
 +
This port is used for optional functionality data like Privacy info and Call Request.
  
This port is used for optional functionality data like Privacy info and Call
+
'''''<u>Single stage CB901 without display stations</u>'''''
Request.
+
[[Image:CB901 SIO data link, non EMC cabinets1.jpg|left|thumb|500px]]
<br>
+
<br style="clear:both;" />
<br>
 
'''''Single stage CB901 without display stations'''''
 
  
The SIO data link cable can be connected to serial port 3 since this port
+
The SIO data link cable can be connected to serial port 3 since this port is not in use for display stations.
is not in use for display stations.
+
* Insert the lower connector from the CPU terminal block on board connector P2-19. Leave 1 pair of pins unconnected between the two connectors.
* Insert the lower connector from the CPU terminal block on board
 
connector P2-19. Leave 1 pair of pins unconnected between the two
 
connectors.
 
 
* Connect 3 wires to the terminal block pos. 22, 23 and 24.
 
* Connect 3 wires to the terminal block pos. 22, 23 and 24.
* Solder a male 9 pin D-sub plug to the other end of the cable for
+
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 1 in AlphaCom XE according to the table below.
connection to port 1 in AlphaCom E according to the table below.
 
 
 
 
 
  
 
{| border="1"  
 
{| border="1"  
Line 492: Line 497:
 
|}
 
|}
  
 +
Port 1 in all AlphaCom XE exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.
 +
----
  
Port 1 in all AlphaCom E exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A 08010.
+
'''''<u>Single stage CB901 with display stations</u>'''''
<br>
+
[[Image:CB901 SIO data link, non EMC cabinets2.jpg|left|thumb|500px]]
<br>
+
<br style="clear:both;" />
'''''Single stage CB901 with display stations'''''
 
 
 
 
If the CB901 exchange has display stations, serial port 3 will be in use.
 
If the CB901 exchange has display stations, serial port 3 will be in use.
  
Use the serial 20mA current loop port no.1. The processor board
+
Use the serial 20mA current loop port no.1. The processor board NFE1683 must be modified and re-programmed to change the port to RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1 for modification procedure.
NFE1683 must be modified and re-programmed to change the port to
+
* Insert the lower connector from the CPU terminal block on board connector P2-19 from pin 1 upwards.
RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1
 
for modification procedure.
 
* Insert the lower connector from the CPU terminal block on board
 
connector P2-19 from pin 1 upwards.
 
 
* Connect 3 wires to the terminal block pos. 39, 40 and 41.
 
* Connect 3 wires to the terminal block pos. 39, 40 and 41.
* Solder a male 9 pin D-sub plug to the other end of the cable for
+
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 1 in AlphaCom ZE according to the table below.
connection to port 1 in AlphaCom E according to the table below.
 
 
 
 
 
  
 
{| border="1"  
 
{| border="1"  
Line 525: Line 523:
 
|}
 
|}
  
Port 1 in all AlphaCom E exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A 08010.
+
Port 1 in all AlphaCom XE exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.
 +
----
  
 
+
'''''<u>Dual and Triple stage CB901</u>'''''
'''''Multi stage CB901'''''
+
[[Image:CB901 SIO data link, non EMC cabinets3.jpg|left|thumb|500px]]
 
+
<br style="clear:both;" />
Use RS232 serial port 4 on the processor board NFE1683 in stage no.2
+
Use RS232 serial port 4 on the processor board NFE1683 in stage no.2 for the SIO data-link connection to AlphaCom XE.
for the SIO data-link connection to AlphaCom E.
 
 
* Insert the upper connector from the CPU terminal block on board connector P2-19 in stage 2. Leave the upper 4 pair of pins unconnected.
 
* Insert the upper connector from the CPU terminal block on board connector P2-19 in stage 2. Leave the upper 4 pair of pins unconnected.
 
* Connect 3 wires to the terminal block pos. 18, 19 and 20.
 
* Connect 3 wires to the terminal block pos. 18, 19 and 20.
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom E according to the table below.
+
* Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom XE according to the table below.
 
 
  
 
{| border="1"  
 
{| border="1"  
Line 550: Line 547:
 
|}
 
|}
  
Port 0 in AlphaCom E20 and E26 need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A 08010.
+
Port 0 in AlphaCom XE20 and XE26 need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.
 
+
----
  
 
====SIO data link, EMC approved cabinet====
 
====SIO data link, EMC approved cabinet====
The SIO data link can be connected to serial port 3 since this port is not
+
'''''<u>Single stage CB901 without display stations</u>'''''
in use for display stations.
+
[[Image:SIO data link, EMC approved cabinet1.jpg|left|thumb|500px]]
If the rear side of the motherboard has green straps for display station
+
<br style="clear:both;" />
modification, remove the two straps at 19A and 20A on card pos. 19.
+
The SIO data link can be connected to serial port 3 since this port is not in use for display stations. If the rear side of the motherboard has green straps for display station modification, remove the two straps at 19A and 20A on card pos. 19.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
Line 576: Line 573:
 
|align=center|-||align=center|NC||width="1" style=background:#EE8844;|&nbsp;|| align=left|ORANGE
 
|align=center|-||align=center|NC||width="1" style=background:#EE8844;|&nbsp;|| align=left|ORANGE
 
|}
 
|}
 
  
 
Complete connection table for BF952 is found in Appendix 7.1
 
Complete connection table for BF952 is found in Appendix 7.1
 +
----
  
 
+
'''''<u>Single stage CB901 with display stations</u>'''''
 
+
[[Image:SIO data link, EMC approved cabinet2.jpg|left|thumb|500px]]
 
+
<br style="clear:both;" />
'''''Single stage CB901 with display stations'''''
 
 
 
 
If the CB901 exchange has display stations, serial port 3 will be in use.
 
If the CB901 exchange has display stations, serial port 3 will be in use.
  
Use the serial 20mA current loop port no.1. The processor board
+
Use the serial 20mA current loop port no.1. The processor board NFE1683 must be modified and re-programmed to change the port to RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1 for modification procedure.
NFE1683 must be modified and re-programmed to change the port to
 
RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1
 
for modification procedure.
 
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
 
* Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
 
* Select the RS232 port no.1 wires at the cable end and solder to a male 9-pin D-sub plug.
 
* Select the RS232 port no.1 wires at the cable end and solder to a male 9-pin D-sub plug.
<br>
+
 
<br>
 
 
{| border="1" |align=center
 
{| border="1" |align=center
 
!width="50"|Signal
 
!width="50"|Signal
Line 610: Line 601:
 
|align=center|-||align=center|NC||width="1" style=background:#22AA22;|&nbsp;|| align=left|GREEN
 
|align=center|-||align=center|NC||width="1" style=background:#22AA22;|&nbsp;|| align=left|GREEN
 
|}
 
|}
<br><br>
+
----
'''''Multi stage CB901'''''
 
  
Use RS232 serial port no.4 on the processor board NFE1683 in stage 2
+
'''''<u>Dual and Triple stage CB901</u>'''''
for the SIO data-link connection to AlphaCom E.
+
[[Image:SIO data link, EMC approved cabinet3.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
Use RS232 serial port no.4 on the processor board NFE1683 in stage 2 for the SIO data-link connection to AlphaCom XE.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Use the 3 m external RS232/Subscriber cable BF952.
 
* Connect the 37 pin D-sub connector to the processor board terminal on the stage 2 cabinet rear (upper right).
 
* Connect the 37 pin D-sub connector to the processor board terminal on the stage 2 cabinet rear (upper right).
 
* Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
 
* Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
<br><br>
+
 
 
{| border="1" |align=center
 
{| border="1" |align=center
 
!width="50"|Signal
 
!width="50"|Signal
Line 633: Line 625:
 
|align=center|-||align=center|NC||width="1" style=background:#884422;|&nbsp;|| align=left|BROWN
 
|align=center|-||align=center|NC||width="1" style=background:#884422;|&nbsp;|| align=left|BROWN
 
|}
 
|}
 
  
  
 
Complete connection table for BF952 is found in Appendix 7.1
 
Complete connection table for BF952 is found in Appendix 7.1
 +
----
  
====Data links, AlphaCom E====
+
====Data links, AlphaCom XE====
 
+
'''''<u>AlphaCom XE7</u>'''''
<br>
+
[[Image:CB901 Data links, AlphaCom E.jpg|left|thumb|500px]]
'''''AlphaCom E7'''''
+
<br style="clear:both;" />
 +
In the AlphaCom XE7 serial port 0 is a 9-pin D-sub connector and port 1 is an RJ45 connector.
  
In the AlphaCom E7 serial port 0 is a 9-pin D-sub connector and port 1
+
In order to connect the 9-pin D-sub plug (SIO signal) to the exchange, an RS232-RJ45 Interface Cable type A100A08010 must be used.
is an RJ45 connector.
+
----
  
In order to connect the 9-pin D-sub plug (SIO signal) to the exchange,
+
'''''<u>AlphaCom XE20 and XE26</u>'''''
an RS232-RJ45 Interface Cable type A100A 08010 must be used.
+
[[Image:CB901 Data links, AlphaCom E 2.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
The AlphaCom XE20 and XE26 have a filter board with two RJ45 serial ports and two Ethernet RJ45 connectors.
  
<br>
+
The upper connector is serial port 0 for ETP signals, and the next is serial port 1 used for SIO signals.
'''''AlphaCom E20 and E26'''''
 
  
The AlphaCom E20 and E26 have a filter board with two RJ45 serial
+
In order to connect the 9-pin D-sub plugs to the exchange, an RS232-RJ45 Interface Cable type A100A08010 must be used.
ports and two Ethernet RJ45 connectors.
+
----
  
The upper connector is serial port 0 for ETP signals, and the next is
+
'''''<u>RS232 – RJ45 Interface Cable</u>'''''
serial port 1 used for SIO signals.
+
[[Image:CB901 Data links, AlphaCom E 3.jpg|left|thumb|500px]]
 
+
<br style="clear:both;" />
In order to connect the 9-pin D-sub plugs to the exchange, an RS232-
+
The internal connection in the A100A08010 interface cable is:
RJ45 Interface Cable type A100A 08010 must be used.
 
 
 
<br>
 
'''''RS232 – RJ45 Interface Cable'''''
 
 
 
The internal connection in the A100A 08010 interface cable is:
 
  
 
{| border="1"  
 
{| border="1"  
Line 677: Line 665:
 
|align=center |6||align=center |3||align=center |RX
 
|align=center |6||align=center |3||align=center |RX
 
|}
 
|}
 
+
----
<br>
 
  
 
====Audio interlinks, CB901 side====
 
====Audio interlinks, CB901 side====
 +
The NFE1545 Audio Interface Board shall be installed in board position no.11 in the CB901 basic board rack of stage 1.
  
The NFE1545 Audio Interface Board shall be installed in board position
+
The AGA Audio Interface Board can be installed in any free subscriber board position in AlphaCom XE. Pos. 20-23 is recommended in E26 to avoid modifications of the backplane.
no.11 in the CB901 basic board rack of stage 1.
 
 
 
The AGA Audio Interface Board can be installed in any free subscriber
 
board position in AlphaCom E. Pos. 20-23 is recommended in E26 to
 
avoid modifications of the backplane.
 
  
Please see section 3.2.2 for available board slots, and the AlphaCom E
+
Please see section 3.2.2 for available board slots, and the AlphaCom XE installation manual for further installation details.
installation manual for further installation details.
 
  
The NFE1545 board has 8 interlinks, but since the corresponding AGA
+
The NFE1545 board has 8 interlinks, but since the corresponding AGA board in AlphaCom XE has 6, only the 6 first interlinks on the NFE1545 board will be used.
board in AlphaCom E has 6, only the 6 first interlinks on the NFE1545
 
board will be used.
 
  
If more interlinks are required in a multi stage system, additional
+
If more interlinks are required in a multi stage system, additional NFE1545 boards can be installed in the other stages. Use slot no.11 in all stages.
NFE1545 boards can be installed in the other stages. Use slot no.11 in
 
all stages.
 
  
The number of AGA boards in the AlphaCom E exchange is only limited
+
The number of AGA boards in the AlphaCom XE exchange is only limited by the number of subscriber board positions.
by the number of subscriber board positions.
 
  
*The address programming jumpers on the NFE1545 board shall be put in positions E2-E3 and E5-E6.  
+
*The address programming jumpers on the NFE1545 board shall be put in positions E2-E3 and E5-E6. The hex addresses for the 6 board positions will then be from E0 to E5.
The hex addresses for the 6 board positions will then be from F8 to FD.
 
  
The lowest LED on the NFE1545 board will be ON. This is just an
+
The lowest LED on the NFE1545 board will be ON. This is just an indication for the free hex address FF.
indication for the free hex address FF.
+
[[Image:CB901 adress programming jumpers.jpg|left|thumb|500px|adress programming jumpers]]
 +
<br style="clear:both;" />
 +
----
  
<br><br>
+
'''''<u>Audio links, non EMC cabinets</u>'''''
'''''Audio links, non EMC cabinets'''''
+
[[Image:CB901 Audio links, non EMC cabinets.jpg|left|thumb|500px]]
* Use a 12 pair twisted cable for the audio link between the CB901 and the AlphaCom E exchange. The connections are made on the
+
<br style="clear:both;" />
Krone terminal block.
+
* Use a 12 pair twisted cable for the audio link between the CB901 and the AlphaCom XE exchange. The connections are made on the Krone terminal block.
 
* The two 20 pin connectors are connected to P1 on the NFE1545 board (the lower connector on the motherboard).
 
* The two 20 pin connectors are connected to P1 on the NFE1545 board (the lower connector on the motherboard).
 
:* Leave two unconnected pair of pins above the upper connector
 
:* Leave two unconnected pair of pins above the upper connector
 
:* Leave four unconnected pair of pins between the two connectors
 
:* Leave four unconnected pair of pins between the two connectors
 
  
 
{|border="1" style="text-align: center;"
 
{|border="1" style="text-align: center;"
Line 724: Line 701:
 
!width="120" colspan="2" |ALPHACOM
 
!width="120" colspan="2" |ALPHACOM
 
|-
 
|-
|No. || Direction || E7 || E20/26
+
|No. || Direction || XE7 || XE20/26
 
|-
 
|-
 
|rowspan="2"| 1 ||RM>ACE || 30 A-B || 2-3 || 31 a-b || 1 a-b
 
|rowspan="2"| 1 ||RM>ACE || 30 A-B || 2-3 || 31 a-b || 1 a-b
Line 750: Line 727:
 
| ACE>RM || 13 A-B || 28-29 || 36 c-d || 6c-d
 
| ACE>RM || 13 A-B || 28-29 || 36 c-d || 6c-d
 
|}
 
|}
 +
----
  
 
+
'''''<u>Audio links, EMC approved cabinets</u>'''''
 
+
[[Image:CB901 Audio links, EMC approved cabinets.jpg|left|thumb|500px]]
'''''Audio links, EMC approved cabinets'''''
+
<br style="clear:both;" />
 
+
* The audio link between the CB901 and the AlphaCom exchanges are made by means of an external 3 meter open-end subscriber cable type BF952. Identify the D-sub connector on the exchange rear coming from the NFE1545 board in pos. no. 11. <br>See section [[#Audio|Audio]] for complete interconnection cable table.
* The audio link between the CB901 and the AlphaCom exchanges are made by means of an external 3 m open-end subscriber cable type BF952. Identify the D-sub connector on the exchange rear coming from the NFE1545 board in pos. no. 11. <br>See section [[#Audio|Audio]] for complete interconnection cable table.
 
 
 
  
 
{|border="1" style="text-align: center;"
 
{|border="1" style="text-align: center;"
Line 763: Line 739:
 
!width="150" colspan="2" |ALPHACOM
 
!width="150" colspan="2" |ALPHACOM
 
|-
 
|-
|No.||Direction||colspan="2" |Color w.1||colspan="2" |Color w.2||Pair no.||E7*||E20/26*
+
|No.||Direction||colspan="2" |Color w.1||colspan="2" |Color w.2||Pair no.||XE7*||XE20/26*
 
|-
 
|-
 
|rowspan="2"|1||AC>RM||&nbsp;||White|| width="10" style=background:#2244EE;|&nbsp; ||Blue||1||31 a-b||1 a-b
 
|rowspan="2"|1||AC>RM||&nbsp;||White|| width="10" style=background:#2244EE;|&nbsp; ||Blue||1||31 a-b||1 a-b
Line 790: Line 766:
 
|}
 
|}
  
See section [[#Audio interlinks, AlphaCom E|Audio interlinks, AlphaCom E]] side for AlphaCom E connection terminals.
+
See section [[#Audio interlinks, AlphaCom XE|Audio interlinks, AlphaCom XE]] side for AlphaCom XE connection terminals.
 
+
----
====Audio interlinks, AlphaCom E====
 
 
 
*Connect the 12-pair twisted cable from the non EMC CB901 cabinet
 
to the AlphaCom E terminals. Make a coding table for connection on
 
both sides.
 
  
 +
====Audio interlinks, AlphaCom XE side====
 +
*Connect the 12-pair twisted cable from the non EMC CB901 cabinet to the AlphaCom XE terminals. Make a coding table for connection on both sides.
 
'''Or'''
 
'''Or'''
* Connect the 20-pair cable from the EMC CB901 approved cabinet to the AlphaCom E terminals. See table in section 3.3.7 for wire pair color coding
+
* Connect the 20-pair cable from the EMC CB901 approved cabinet to the AlphaCom XE terminals. See table in section 3.3.7 for wire pair color coding  
:* The '''a''' and '''b''' wires are audio FROM AlphaCom E
+
:* The '''a''' and '''b''' wires are audio FROM AlphaCom XE
:* The '''c''' and '''d''' wires are audio TO AlphaCom E
+
:* The '''c''' and '''d''' wires are audio TO AlphaCom XE
These lines are balanced; the twisted pairs may be connected either
+
These lines are balanced; the twisted pairs may be connected either way.
way.
+
----
<br><br>
 
'''''Audio links, AlphaCom E7'''''
 
  
Even if the AGA board can be placed in any subscriber board position, it
+
'''''<u>Audio links, AlphaCom XE7</u>'''''
is good practice to choose slot no. 6 (line no. 31-36).
+
[[Image:CB901 Audio links, AlphaCom E7.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
Even if the AGA board can be placed in any subscriber board position, it is good practice to choose slot no. 6 (line no. 31-36).
  
The audio connection to CB901 is made by six 4-way plug-on screw
+
The audio connection to CB901 is made by six 4-way plug-on screw terminals, one link per terminal.
terminals, one link per terminal.
+
----
<br><br>
 
'''''AlphaCom E20 and E26'''''
 
  
Use the same filter board with cable and connection board as the ASLT
+
'''''<u>AlphaCom XE20 and XE26</u>'''''
Subscriber Board.
+
[[Image:CB901 AlphaCom E20 and E26 .jpg|left|thumb|500px]]
 
+
<br style="clear:both;" />
The connection board has six 4-way push-on terminals marked 1-6
+
Use the same filter board with cable and connection board as the ASLT Subscriber Board.
corresponding to the link numbers.
 
  
 +
The connection board has six 4-way push-on terminals marked 1-6 corresponding to the link numbers.
 +
----
  
 
== PROGRAMMING ==
 
== PROGRAMMING ==
The programming procedures in this chapter will only concentrate on the
+
The programming procedures in this chapter will only concentrate on the procedures concerning the interface between Ring-Master CB901 and AlphaCom XE. Further instructions are found in the system programming
procedures concerning the interface between Ring-Master CB901 and
 
AlphaCom E. Further instructions are found in the system programming
 
 
manuals.
 
manuals.
  
 
====Purpose of programming====
 
====Purpose of programming====
  
Individual programming will be carried out in each system via a locally
+
Individual programming will be carried out in each system via a locally connected data terminal (laptop).
connected data terminal (laptop).
 
  
 
:'''Note: One system cannot be programmed from the other.'''
 
:'''Note: One system cannot be programmed from the other.'''
Line 845: Line 814:
 
* Receive event for call button press (8 digit for identification of pager call)
 
* Receive event for call button press (8 digit for identification of pager call)
 
* Set the data of the serial port used for AlphaCom
 
* Set the data of the serial port used for AlphaCom
* Program the feature code for access to the numbers in AlphaCom E. If the feature code is one digit (F), then a call to a number (AAA) in<br>AlphaCom E will be F A A A
+
* Program the feature code for access to the numbers in AlphaCom XE. If the feature code is one digit (F), then a call to a number (AAA) in<br>AlphaCom E will be F A A A
 
* Select the four numbers used for privacy test
 
* Select the four numbers used for privacy test
 
  
 
===Programming CB901===
 
===Programming CB901===
  
 
* Connect a PC to the D-sub in front of the RM CPU board NFE1683 via a crossed 3-wire D-sub cable.
 
* Connect a PC to the D-sub in front of the RM CPU board NFE1683 via a crossed 3-wire D-sub cable.
 +
[[Image:CB901 Programming.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Define the PC as a hyperterminal, Baud rate = 9600/8/n/1
 
* Define the PC as a hyperterminal, Baud rate = 9600/8/n/1
* Log in to the CB901 central by using the super-user command
+
* Log in to the CB901 central by using the super-user command '''hPsaB'''
hPsaB
 
 
The super-user status is needed to adjust the two test timers later on in the process.
 
The super-user status is needed to adjust the two test timers later on in the process.
  
Line 861: Line 830:
 
The CB901 system must be configured before the ETP feature can be executed. The configuration process is carried out through a number of SVT commands. See the SVT manual for details.
 
The CB901 system must be configured before the ETP feature can be executed. The configuration process is carried out through a number of SVT commands. See the SVT manual for details.
 
* Start by un-define the line equipment positions where the ETP trunks will be connected. This is done with the SLEU command:
 
* Start by un-define the line equipment positions where the ETP trunks will be connected. This is done with the SLEU command:
  SLEU F8-FD
+
  SLEU E0-E5
  
 
* Continue to define which line equipment positions to be allocated as ETP trunk positions. This is done with the SETP command:
 
* Continue to define which line equipment positions to be allocated as ETP trunk positions. This is done with the SETP command:
 +
SETP 1 E0 <stage no>
 +
SETP 2 E1 <stage no>
 +
SETP 3 E2 <stage no>
 +
SETP 4 E3 <stage no>
 +
SETP 5 E4 <stage no>
 +
SETP 6 E5 <stage no>
  
SETP 1 F8 <stage no>
+
*Define which first digit(s) to be used as ETP call number(s). This is done via the two commands, SCDU and SFC.<br>In this example 7 is used as first digit in the call numbers in AlphaCom XE (ETP).
SETP 2 F9 <stage no>
 
SETP 3 FA <stage no>
 
SETP 4 FB <stage no>
 
SETP 5 FC <stage no>
 
SETP 6 FD <stage no>
 
 
 
*Define which first digit(s) to be used as ETP call number(s). This is done via the two commands, SCDU and SFC.<br>In this example 7 is used as first digit in the call numbers in AlphaCom E (ETP).
 
 
* Un-define 7 as first call digit for normal calls:
 
* Un-define 7 as first call digit for normal calls:
 
  SCDU 7
 
  SCDU 7
Line 881: Line 849:
 
(87 is selected just to make it easier to remember the call number 7).
 
(87 is selected just to make it easier to remember the call number 7).
  
The call number series starting with 7 as first digit has been
+
The call number series starting with 7 as first digit has been programmed to be associated with the ETP trunks.
programmed to be associated with the ETP trunks.
 
  
All numbers starting with 7 will now be in the AlphaCom E. The call
+
All numbers starting with 7 will now be in the AlphaCom XE. The call numbers must have a total of 4 digits (7xxx).
numbers must have a total of 4 digits (7xxx).
 
  
* Define which of the Ring-Master call numbers shall be able to make ETP calls (calls into the AlphaCom E system). Use the SFA command to give access to dial feature code 7 (feature ID 87):
+
* Define which of the Ring-Master call numbers shall be able to make ETP calls (calls into the AlphaCom XE system). Use the SFA command to give access to dial feature code 7 (feature ID 87):
 
  SFA 1000-1999 87 +
 
  SFA 1000-1999 87 +
All station in the range of 1000-1999 can call in the example above.
+
All stations in the range of 1000-1999 can call in the example above.
  
 
Refer to the SVT programming manual for general configuration of the Ring-Master CB901 system.
 
Refer to the SVT programming manual for general configuration of the Ring-Master CB901 system.
  
 
====Privacy test call numbers SIO====
 
====Privacy test call numbers SIO====
 +
[[Image:CB901 Privacy test.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
This position (call number) will be used by AlphaCom XE to call the stations in CB901. This must be programmed with privilege no.20, ‘Remote dial receive’.
  
This position (call number) will be used by AlphaCom E to call the stations in CB901. This must be programmed with privilege no.20, ‘Remote dial receive’.
+
The remote dialing in CB901 via the SIO port is automatically controlled by the RM Daemon in AlphaCom XE.
 
 
The remote dialing in CB901 via the SIO port is automatically controlled by the RM Daemon in AlphaCom E.
 
  
 
The disconnect event must programmed for both the '''SIO''' number '''C''' (A side, event 12) and the called number '''D''' (B side, event 64). Please see Privacy Test explanation in section [[#RMD Privacy links|RMD Privacy links]] and Subscriber board modification in [[#Subscriber boards|Subscriber boards]].
 
The disconnect event must programmed for both the '''SIO''' number '''C''' (A side, event 12) and the called number '''D''' (B side, event 64). Please see Privacy Test explanation in section [[#RMD Privacy links|RMD Privacy links]] and Subscriber board modification in [[#Subscriber boards|Subscriber boards]].
Line 908: Line 875:
 
  SSO <event no.12> <stage no.> <output to PC port><stage where the PC port is used><stop>
 
  SSO <event no.12> <stage no.> <output to PC port><stage where the PC port is used><stop>
  
<br>
+
 
<br>
 
 
Example
 
Example
 
  Stage 1:
 
  Stage 1:
Line 922: Line 888:
 
  SSO 12 N C 2 U        Disconnect C (SIO)
 
  SSO 12 N C 2 U        Disconnect C (SIO)
 
  SSO 64 N C 2 U        Disconnect D
 
  SSO 64 N C 2 U        Disconnect D
These events are used to ensure complete cancellation of the audio link
+
These events are used to ensure complete cancellation of the audio link when a called Ring-Master station (D) presses the X button, or automatic reset at timeout.
when a called Ring-Master station (D) presses the X button, or
 
automatic reset at timeout.
 
  
 
* Program Group Call using the following commands:
 
* Program Group Call using the following commands:
  SGCN:         Program the call number for each group.  
+
  SGCN:           Program the call number for each group.  
These numbers shall also be programmed into the RMD WEB interface in AlphaCom E in order to set the relation between the internal groups in CB901 and the global group numbers in AlphaCom E.
+
These numbers shall also be programmed into the RMD WEB interface in AlphaCom XE in order to set the relation between the internal groups in CB901 and the global group numbers in AlphaCom XE.
<br>
+
 
<br>
 
<br>
 
 
  SGCM:          Program the receivers in each group in CB901.
 
  SGCM:          Program the receivers in each group in CB901.
  
 
  SPT:            Privilege to manage Group Call and All Call
 
  SPT:            Privilege to manage Group Call and All Call
 
  
 
==== Adjust test timers no. 1 and 2 ====
 
==== Adjust test timers no. 1 and 2 ====
Line 988: Line 949:
 
::'''Note: The data for port 4 cannot be changed when the driver is specified for ETP. In order to modify the data you must re-define port 4 as Pager port via the command SD.'''
 
::'''Note: The data for port 4 cannot be changed when the driver is specified for ETP. In order to modify the data you must re-define port 4 as Pager port via the command SD.'''
  
 
+
===Programming in AlphaCom XE===
===Programming in AlphaCom E===
 
  
 
====Configuration programs====
 
====Configuration programs====
  
The AlphaCom E configuration is partly made from AlphaPro and partly from the embedded Web browser AlphaWeb.
+
The AlphaCom XE configuration is partly made from AlphaPro and partly from the embedded Web browser AlphaWeb.
  
 
The configuration includes the following steps:
 
The configuration includes the following steps:
  
 
+
'''''<u>AlphaPro:</u>'''''
'''''AlphaPro:'''''
+
* Create virtual Ring-Master node(s) which defines a data link between the AlphaCom XE node and the virtual Ring-Master node (RMD)
* Create virtual Ring-Master node(s) which defines a data link between the AlphaCom E node and the virtual Ring-Master nod (RMD)
+
* Create AlphaCom XE <-> Ring-Master audio links
* Create AlphaCom E <-> Ring-Master audio links
 
 
* Create RM call numbers as Global numbers
 
* Create RM call numbers as Global numbers
 
* Call Request
 
* Call Request
Line 1,006: Line 965:
 
* Update the exchange
 
* Update the exchange
  
'''''AlphaWeb:'''''
+
'''''<u>AlphaWeb:</u>'''''
 
* Insert license for the Ring-Master interface
 
* Insert license for the Ring-Master interface
 
* Configure the virtual Ring-Master node
 
* Configure the virtual Ring-Master node
 
  
 
===AlphaPro configuration===
 
===AlphaPro configuration===
AlphaPro 10 is an off-line tool used to configure AlphaCom E. All
+
AlphaPro is an off-line tool used to configure AlphaCom XE. All parameters can be entered without being connected to the exchange. Once all parameter are entered, AlphaPro can be connected to the exchange and the parameters can be sent. AlphaPro can also upload configuration information from an exchange.
parameters can be entered without being connected to the exchange.
 
Once all parameter are entered, AlphaPro 10 can be connected to the
 
exchange and the parameters can be sent. AlphaPro 10 can also
 
upload configuration information from an exchange.
 
  
See the AlphaCom E technical manual “System Management and
+
See the AlphaCom XE technical manual “Alphacom XE Installation, Configuration & Operation” A100K10805 for further programming procedure.
Operation” A100K 10318 for further programming procedure.
 
  
'''Bold text'''====Connect a PC to the exchange====
+
====Connect a PC to the exchange====
  
'''''Insert the HW dongle'''''
+
'''''<u>Insert the HW dongle</u>'''''
* Insert the hardware dongle in the PC’s parallel or USB port depending on the dongle type.
+
* Insert the hardware dongle in the PC’s USB port.
 
* Leave the dongle in the PC during programming and transferring of data to the exchange.
 
* Leave the dongle in the PC during programming and transferring of data to the exchange.
  
'''''Ethernet connection'''''
+
'''''<u>Ethernet connection</u>'''''
 
+
[[Image:AlphaProConnection 1.png|left|thumb|500px]]
AlphaCom E exchanges communicate with the AlphaPro PC over the IP
+
<br style="clear:both;" />
network. Eth0 is the default management port unless the configuration
 
has been changed.
 
 
 
When the AlphaPro communication icon is pressed, AlphaPro will
 
prompt you for user name and password before login to the AlphaCom.
 
See technical manual A100K 10338 for further AlphaPro description.
 
  
====AlphaPro Main Menu====
+
AlphaCom XE exchanges communicate with the AlphaPro PC over the IP network. Eth0 is the default management port unless the configuration has been changed.
Besides creating and selecting networks and exchanges, the menu has a choice of sub-menus. Five of these will be used in this programming.
 
  
'''Exchange & System'''
+
When the AlphaPro communication icon is pressed, AlphaPro will prompt you for user name and password before login to the AlphaCom.
'''Directory & Features'''
 
'''Stations & Users'''
 
'''Groups'''
 
'''Class of Service'''
 
'''Start Communication Program'''
 
  
 
====Create RM-ACE network====
 
====Create RM-ACE network====
From the AlphaPro Main Menu:
+
From the [[AlphaPro - Main Menu|AlphaPro Main Menu]]:
 
* Press the ‘+’ button next to ‘Select Network’
 
* Press the ‘+’ button next to ‘Select Network’
 +
[[Image:Select Network 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Give the network a name, i.e. “AC-RM”
 
* Give the network a name, i.e. “AC-RM”
 
* Give the first exchange a name, i.e. “AlphaCom”
 
* Give the first exchange a name, i.e. “AlphaCom”
 
* The ‘Node Number’ shall be “1”
 
* The ‘Node Number’ shall be “1”
 
* Be sure the ‘AlphaNet Adm. Here’ check box is ticked
 
* Be sure the ‘AlphaNet Adm. Here’ check box is ticked
* The default IP address 169.254.1.5 is used when the AlphaWeb PC is connected directly to the AlphaCom E node on the Eth0 port. If a remote PC is connected via a network for AlphaWeb programming, this address must be changed. Contact the IT administrator to get this address.
+
* The default IP address 169.254.1.5 is used when the AlphaWeb PC is connected directly to the AlphaCom XE node on the Eth0 port. If a remote PC is connected via a network for AlphaWeb programming, this address must be changed. Contact the IT administrator to get this address.
<br>
+
[[Image:Create RM AC Node 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
::'''Note: Make a note of this IP address as it must be entered manually in AlphaWeb!'''
 
::'''Note: Make a note of this IP address as it must be entered manually in AlphaWeb!'''
 
* Click ['''OK'''] to confirm<br>The new network name will appear in the ‘Select Network’ pull-down list and the given exchange name is automatically put in the ‘Select Exchange’ pull-down list.
 
* Click ['''OK'''] to confirm<br>The new network name will appear in the ‘Select Network’ pull-down list and the given exchange name is automatically put in the ‘Select Exchange’ pull-down list.
Line 1,062: Line 1,006:
 
From the AlphaPro Main Menu:
 
From the AlphaPro Main Menu:
 
* Press the ‘'''+'''’ button next to ‘Select Exchange’
 
* Press the ‘'''+'''’ button next to ‘Select Exchange’
 +
[[Image:Select Network 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Type the name of the new RM node i.e. “'''RM Node 101'''”
 
* Type the name of the new RM node i.e. “'''RM Node 101'''”
 
* Type in the node no. i.e. “'''101'''”
 
* Type in the node no. i.e. “'''101'''”
 
* Select ['''Ringmaster Node'''] from the ‘Type’ list
 
* Select ['''Ringmaster Node'''] from the ‘Type’ list
 
* Leave the ['''Adm. Here'''] flag unchecked
 
* Leave the ['''Adm. Here'''] flag unchecked
<br>
+
[[Image:Create Virtual RM Node 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
::'''Note: The Ring-Master node must be assigned a higher node number than the AlphaCom node. Suggested node number is 101.'''
 
::'''Note: The Ring-Master node must be assigned a higher node number than the AlphaCom node. Suggested node number is 101.'''
  
Line 1,075: Line 1,022:
 
====Define the data- and audio link====
 
====Define the data- and audio link====
 
* Select ['''Exchange & System'''] in the Main Menu
 
* Select ['''Exchange & System'''] in the Main Menu
 +
[[File:Menu 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select ['''AlphaCom'''] in the ‘Exchange Information’ window
 
* Select ['''AlphaCom'''] in the ‘Exchange Information’ window
 
* Select ['''Net Routing''']
 
* Select ['''Net Routing''']
 +
[[Image:Exchange Information 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select ['''Insert''']
 
* Select ['''Insert''']
 +
[[File:NetRouting 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select the new ‘RM node’ and click the ['''Select'''] button
 
* Select the new ‘RM node’ and click the ['''Select'''] button
 +
[[File:NetRouting 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select ['''RMD link'''] from the ‘Primary route’ Data ACDP link
 
* Select ['''RMD link'''] from the ‘Primary route’ Data ACDP link
 +
[[Image:NetRouting 3.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* The audio should be on node number ‘101’
 
* The audio should be on node number ‘101’
 
* Click ['''OK'''] to save the record
 
* Click ['''OK'''] to save the record
 
* Click the ['''Close'''] button to get back to the Main Menu
 
* Click the ['''Close'''] button to get back to the Main Menu
 
  
 
====Create AlphaCom / Ring-Master audio links====
 
====Create AlphaCom / Ring-Master audio links====
* Select [Exchange & System] in the Main Menu
+
* Select ['''Exchange & System'''] in the Main Menu
* Select [AlphaCom] in the ‘Exchange Information’ window
+
* Select ['''AlphaCom'''] in the ‘Exchange Information’ window
* Select [Net Audio]
+
* Select ['''Net Audio''']
* Select [Insert]
+
[[File:NetAudio 1.PNG|left|thumb|500px]]
* Check that Ring-Master is the destination node and click on [Select]
+
<br style="clear:both;" />
 +
* Select ['''Insert''']
 +
[[File:NetAudio 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Check that Ring-Master is the destination node and click on ['''Select''']
 +
[[File:NetAudio 3.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Enter the AGA board physical link number and a channel number starting from ‘1’ on the first link, ‘2’ on the second link and so on
 
* Enter the AGA board physical link number and a channel number starting from ‘1’ on the first link, ‘2’ on the second link and so on
* Repeat this operation until all audio links are defined<br>''Example: An E7 has two AGA boards in pos. 5 and 6. The first physical link number is (4x6)+1=25 and the last link number is 36.''
+
[[Image:NetAudio 4.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Repeat this operation until all audio links are defined<br>''Example: An XE7 has two AGA boards in pos. 5 and 6. The first physical link number is (4x6)+1=25 and the last link number is 36.''
 
* Click ['''OK'''] to save the record
 
* Click ['''OK'''] to save the record
 
* Click the ['''Close'''] button to get back to the Main Menu
 
* Click the ['''Close'''] button to get back to the Main Menu
  
 
==== Tone test ====
 
==== Tone test ====
The AGA audio links are by default supervised by a test tone
+
The AGA audio links are by default supervised by a test tone transmitted on the line at regular intervals.
transmitted on the line at regular intervals.
 
  
As this test is not supported when interfacing to the Ring-Master
+
As this test is not supported when interfacing to the Ring-Master system, the test must be disabled to prevent the links from being taken out of service.
system, the test must be disabled to prevent the links from being taken
 
out of service.
 
  
 
* Select ['''Exchange & System''']
 
* Select ['''Exchange & System''']
 
* Click on ['''System''']
 
* Click on ['''System''']
 +
[[File:System 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select ['''Logs and Errors''']
 
* Select ['''Logs and Errors''']
 
* Check that ['''Enable Tone Test'''] is NOT checked
 
* Check that ['''Enable Tone Test'''] is NOT checked
 
* Set ['''Audio Test Period'''] to 65 535 (= Test OFF)
 
* Set ['''Audio Test Period'''] to 65 535 (= Test OFF)
 
+
[[Image:Logs and Errors 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
The audio links require further configuration from the RMD configuration page in AlphaWeb.
 
The audio links require further configuration from the RMD configuration page in AlphaWeb.
 
  
 
==== Create Ring-Master station numbers ====
 
==== Create Ring-Master station numbers ====
All station numbers in the Ring-Master system which should be
+
All station numbers in the Ring-Master system which should be accessed from the AlphaCom XE must be programmed in the AlphaCom directory table (Directory & Features) with feature 083 (Global numbers) and ‘Node’ = Ring-Master node number (e.g. 101).
accessed from the AlphaCom E must be programmed in the AlphaCom
 
directory table (Directory & Features) with feature 083 (Global numbers)
 
and ‘Node’ = Ring-Master node number (e.g. 101).
 
 
 
In the example below, the station number 1258 is defined as Global
 
Number for AlphaNet, feature 083. The display text will be shown in the
 
AlphaCom station when calling the RM station. This text should be
 
coordinated with the RM systems caller ID text for that RM station.
 
  
Further configuration of the call numbers is required from the RMD
+
In the example below, the station number 1258 is defined as Global Number for AlphaNet, feature 083. The display text will be shown in the AlphaCom station when calling the RM station. This text should be coordinated with the RM systems caller ID text for that RM station.
configuration page in AlphaWeb.
 
  
* Click on ['''Directory & Features''']
+
* Click on ['''Directory & Features'''] in the main menu
 +
[[File:Menu 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Select feature 83 ‘Global Number for AlphaNet’ in the ['''Feature'''] pulldown list
 
* Select feature 83 ‘Global Number for AlphaNet’ in the ['''Feature'''] pulldown list
 
* Type the RM node number (‘101’) in the ['''Node'''] field
 
* Type the RM node number (‘101’) in the ['''Node'''] field
 
* Type the RM call number in the ['''Directory Number'''] field
 
* Type the RM call number in the ['''Directory Number'''] field
 +
[[Image:DirNo 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* A warning may appear if the selected number already exists, or if the number is masked by existing numbers. In this case directory number 125 must be deleted.
 +
[[File:DirNo Masking.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Type in the text which will be visible in the display of the calling AC station in the ['''Display Text'''] field
 
* Type in the text which will be visible in the display of the calling AC station in the ['''Display Text'''] field
 
* Click ['''OK''']. The new global number will be updated in the table on the left
 
* Click ['''OK''']. The new global number will be updated in the table on the left
 
Repeat this procedure for each RM number to be defined in AlphaCom
 
Repeat this procedure for each RM number to be defined in AlphaCom
 +
 +
Further configuration of the call numbers is required from the RMD configuration page in AlphaWeb.
  
 
====AlphaCom station numbers====
 
====AlphaCom station numbers====
All station numbers in the AlphaCom E which should be accessed from
+
All station numbers in the AlphaCom XE which should be accessed from the Ring-Master system must be assigned a 4-digit directory number in AlphaCom (Users & Stations). First digit must be the feature code 7 as
the Ring-Master system must be assigned a 4-digit directory number in
 
AlphaCom (Users & Stations). First digit must be the feature code 7 as
 
 
programmed in RM.
 
programmed in RM.
 +
 +
Note that there are a number of standard feature codes in the AlphaCom starting with digit 7, e.g. 70 (Station reset) and 71 (Call forwarding). These codes will mask any station numbers starting with the same digits. For example 70 will mask for all stations in the range 70xx, 71 will mask all stations in the range 71xx, and so on. When a station number is masked by a feature code it will not be possible to call the station. In this case the feature codes must be changed. It is recommended to put a one-digit in front of the standard number, i.e. change 70 to 070, 71 to 071 and so on.
  
 
====Call Request group numbers====
 
====Call Request group numbers====
When the “CAS” function is wanted in the Ring-Master system, it must be converted to generate a Call Request to a group in AlphaCom E. This “group” should include one or several guard station(s) to receive call request calls from RM as well as AC stations.
+
When the “CAS” function is wanted in the Ring-Master system, it must be converted to generate a Call Request to a group in AlphaCom XE. This “group” should include one or several guard station(s) to receive call request calls from RM as well as AC stations.
  
 
The directory no. of the group used for Call Request must be 4 digits and the first digit must be feature code 7 as programmed in RM.
 
The directory no. of the group used for Call Request must be 4 digits and the first digit must be feature code 7 as programmed in RM.
  
Since Ring-Master has 64 group-call groups numbered from 1 - 64, groups from 65 - 100 should be used in AlphaCom E for Call Request.
+
Since Ring-Master has 64 group-call groups numbered from 1 - 64, groups from 65 - 100 should be used in AlphaCom XE for Call Request.
  
In the example below, the group 65 is used for call request and the
+
In the example below, the group 65 is used for call request and the directory number for this group is 7211.
directory number for this group is 7211.
 
 
* Select ['''Groups'''], then ['''Local Groups''']
 
* Select ['''Groups'''], then ['''Local Groups''']
* Scroll down to group 65 and select ['''65''']
+
[[File:Menu 3.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Scroll down and select ['''Station Group 65''']
 +
[[Image:GroupCall 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click on ['''Change''']
 
* Click on ['''Change''']
 
* Type the Call Request call number in the ['''Directory Number'''] field
 
* Type the Call Request call number in the ['''Directory Number'''] field
 
* Type in the display text in the ['''Display Text'''] field
 
* Type in the display text in the ['''Display Text'''] field
 +
[[Image:GroupCall 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click on the ['''Members'''] field. This will be the guard stations (RM CAS operators)
 
* Click on the ['''Members'''] field. This will be the guard stations (RM CAS operators)
 +
[[Image:GroupCall 3.PNG|thumb|left|500px]]
 +
<br style="clear:both;" />
 
* Select the guard stations to be included in the group from the ‘Not Member’ list, and transfer to the ‘Members’ list
 
* Select the guard stations to be included in the group from the ‘Not Member’ list, and transfer to the ‘Members’ list
 
* Click ['''OK''']
 
* Click ['''OK''']
Line 1,162: Line 1,132:
 
In order to make Group Call in both RM and ACE simultaneously, the Global Group numbers must be specified. Follow the same routine as described for Call Request group numbers.
 
In order to make Group Call in both RM and ACE simultaneously, the Global Group numbers must be specified. Follow the same routine as described for Call Request group numbers.
  
====DTMF from AlphaCom E to CB901, pulse operation====
+
====DTMF from AlphaCom XE to CB901, pulse operation====
 +
This is used for e.g. Door Opening Control.
  
This is used for e.g. Door Opening Control
+
'''''<u>Set the Door Open button</u>'''''
'''''Set the Door Open button'''''
 
 
* Click on ['''Directory Numbers & Features'''] on the main menu.
 
* Click on ['''Directory Numbers & Features'''] on the main menu.
 +
* Click on ['''Insert''']
 
* Select feature 107 ‘DTMF during connection’ from the ['''Feature'''] pulldown list.
 
* Select feature 107 ‘DTMF during connection’ from the ['''Feature'''] pulldown list.
* Click on ['''Insert''']
 
 
* Type “'''5'''” in the ID field.<br>This is the DTMF ID to be used. (Any digit from 0-9 may be used)
 
* Type “'''5'''” in the ID field.<br>This is the DTMF ID to be used. (Any digit from 0-9 may be used)
 
* Type “'''6'''” in the ['''Directory Number'''] field.<br>This is the button to be pressed during conversation
 
* Type “'''6'''” in the ['''Directory Number'''] field.<br>This is the button to be pressed during conversation
<br>
 
 
'''Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.'''
 
'''Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.'''
 
+
[[Image:DirNo Replace 1.PNG|left|thumb|500px|Duplicate directory number]]
 +
<br style="clear:both;" />
 
* Type “'''Open Door'''” in the display text field
 
* Type “'''Open Door'''” in the display text field
 +
[[Image:DirNo DTMF 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click ['''OK'''] and ['''Close''']  
 
* Click ['''OK'''] and ['''Close''']  
<br>
+
----
'''''Create a new Class of Service'''''
 
 
 
* Click on ['''''Class of Service'''''] on the main menu.
 
* Click on, for example ['''Class of Serv 2''']
 
* Click on ['''Change''']
 
* Click on ['''Copy From'''…] and choose ‘Default’
 
* Transfer all features which are included as default from the left to the right window
 
* Transfer, in addition, feature no. ‘107 DTMF During Connection’
 
* Click ['''OK'''] and ['''Close'''].
 
  
<br>
+
'''''<u>Adjust the DTMF pulse time</u>'''''
'''''Set the Door Open station'''''
 
* Click on ['''Users & Stations'''] on the main menu.
 
* Click on the call number which shall be permitted to transmit DTMF for door opening in the stations list
 
* Select ['''Class of Service'''] for the selected call number to be ‘Class of Serv 2’
 
* Click ['''OK''']
 
* Repeat for all stations permitted to open doors
 
  
'''''Adjust the DTMF pulse time'''''
 
 
* Select ['''Exchange & System'''] from the main menu
 
* Select ['''Exchange & System'''] from the main menu
 
* Click on ['''System''']
 
* Click on ['''System''']
 
* Select ['''Timers''']
 
* Select ['''Timers''']
 
* Check that ['''RCO Pulse (Door Open) Time'''] is set to default 35 (3.5 sec.)
 
* Check that ['''RCO Pulse (Door Open) Time'''] is set to default 35 (3.5 sec.)
 +
[[Image:Timers 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click ['''OK'''] and ['''Close''']
 
* Click ['''OK'''] and ['''Close''']
 +
----
  
====DTMF from AlphaCom E to CB901, continuous====
+
====DTMF from AlphaCom XE to CB901, continuous====
 
This will transmit a DTMF signal as long as a station button is pressed.
 
This will transmit a DTMF signal as long as a station button is pressed.
 
* Click on ['''Directory & Features'''] on the main menu
 
* Click on ['''Directory & Features'''] on the main menu
Line 1,209: Line 1,168:
 
* Type “255” in the ID field<br>This indicates that the digit specified below will enable the Continuous DTMF feature
 
* Type “255” in the ID field<br>This indicates that the digit specified below will enable the Continuous DTMF feature
 
* Type “6” in the ['''Directory Number'''] field<br>This is the button to press during conversation to enable continuous DTMF transmission
 
* Type “6” in the ['''Directory Number'''] field<br>This is the button to press during conversation to enable continuous DTMF transmission
 
 
::'''Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.'''
 
::'''Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.'''
 
+
[[Image:DirNo Replace 1.PNG|left|thumb|500px|Duplicate directory number]]
 +
<br style="clear:both;" />
 
* Type “Open Door” or actual initiated function in the display text field
 
* Type “Open Door” or actual initiated function in the display text field
 +
[[Image:DTMF 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click ['''OK'''] and ['''Close''']
 
* Click ['''OK'''] and ['''Close''']
  
 
Any number key pressed after 6 will result in a continuous DTMF signal as long as the key is pressed. The DTMF signal will correspond to the depressed number key.
 
Any number key pressed after 6 will result in a continuous DTMF signal as long as the key is pressed. The DTMF signal will correspond to the depressed number key.
  
* Proceed with procedures as explained for ['''Class of Service'''] and ['''Users'''] above
+
====Update the exchange====
 +
* Connect the PC to the AlphaCom XE exchange according to section [[#Connect a PC to the exchange|Connect a PC to the exchange]]
 +
 
 +
* Log on to the exchange and update the configuration by pressing the ['''SendAll'''] button. When the transfer is finished, the AlphaCom XE must be reset by activating the ['''Reset'''] button in the communication window.
 +
 
 +
====AlphaNet====
 +
When there are several AlphaCom exchanges connected in a network (AlphaNet), the Ring-Master node will be related to one of these AlphaCom nodes. The other AlphaCom exchanges need to have routing information to the Ring-Master node.
 +
 
 +
When defining the data- and audio routing from a remote AlphaCom to a Ring-Master node, the AlphaCom node related to the Ring-Master node must be defined as a transit node.
 +
 
 +
'''Example:'''
  
 +
The Ring-Master node is 101 and related to AlphaCom node 1.
  
====Update the exchange====
+
A remote AlphaCom node 2 is connected in AlphaNet with AlphaCom node 1.
* Connect the PC to the AlphaCom E exchange according to section [[#Connect a PC to the exchange|Connect a PC to the exchange]]
 
  
* Log on to the exchange and update the configuration by pressing the ['''SendAll'''] button.
+
The routing from node 2 to the Ring-Master node 101 must go transit via node 1.
When the transfer is finished, the AlphaCom E must be reset by activating the ['''Reset'''] button in the communication window.
+
[[File:AlphaNet 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
  
 
===Configuration from AlphaWeb===
 
===Configuration from AlphaWeb===
 +
 
====Connect to AlphaWeb====
 
====Connect to AlphaWeb====
 
* Connect the PC Ethernet port to the LAN port (Eth0) on the AMC-IP filter board.
 
* Connect the PC Ethernet port to the LAN port (Eth0) on the AMC-IP filter board.
 +
[[Image:CB901 Alpha Web.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Use your web-browser to connect to the AlphaWeb. Enter http://169.254.1.5 (default address) in the address field1 Connection with the AMC is verified by the text: [Login] AlphaWeb
 
* Use your web-browser to connect to the AlphaWeb. Enter http://169.254.1.5 (default address) in the address field1 Connection with the AMC is verified by the text: [Login] AlphaWeb
 
::'''Note: This IP address must be entered manually in AlphaWeb.'''
 
::'''Note: This IP address must be entered manually in AlphaWeb.'''
 
 
*Click on ['''Login''']
 
*Click on ['''Login''']
 
User is prompted for user name and password
 
User is prompted for user name and password
<br>
+
[[Image:Login 1.PNG|left|thumb|500px]]
<br>
+
<br style="clear:both;" />
 
{|
 
{|
 
|width="150"|Default user name:  
 
|width="150"|Default user name:  
Line 1,246: Line 1,220:
  
 
To be able to change the configuration, the user must log in as an administrator. The default login will then be:
 
To be able to change the configuration, the user must log in as an administrator. The default login will then be:
<br>
+
 
<br>
 
 
{|
 
{|
 
|width="120"|User name:  
 
|width="120"|User name:  
Line 1,255: Line 1,228:
 
|}
 
|}
  
See further details on AlphaWeb in the AlphaCom E technical manual
+
See further details on AlphaWeb in the AlphaCom XE technical manual
A100K 10338.
+
A100K10805.
 +
----
  
'''''Insert license for Ring-Master'''''
+
'''''<u>Insert license for Ring-Master</u>'''''
  
 
Log on to AlphaWeb and install the license to enable the Ring-Master interface.
 
Log on to AlphaWeb and install the license to enable the Ring-Master interface.
* Select ['''System Configuration'''] then ['''License Key''']
+
* Select ['''System Configuration'''] then ['''Licensing''']
 
* Input the RM license key string under ['''New License Key''']
 
* Input the RM license key string under ['''New License Key''']
* Press the ['''Insert new license key'''] button
+
[[Image:License 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Press the ['''Insert new License Key'''] button
 
* Verify that the license has become active in the '''License Configuration''' field
 
* Verify that the license has become active in the '''License Configuration''' field
 +
[[Image:License 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
----
  
 
====Configuration of the virtual Ring-Master node====
 
====Configuration of the virtual Ring-Master node====
Line 1,275: Line 1,254:
 
:* Call Request groups
 
:* Call Request groups
 
* Click on ['''External Systems'''] and then select ['''RingMaster''']
 
* Click on ['''External Systems'''] and then select ['''RingMaster''']
 
+
[[Image:RMd 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
  
 
====RMD General Parameters====
 
====RMD General Parameters====
 
* Select ['''General Parameters''']
 
* Select ['''General Parameters''']
 +
[[Image:RMd 2.PNG|left|thumb|500px|RMD General Parameters]]
 +
<br style="clear:both;" />
 
* Specify the '''AMC Node''' no.
 
* Specify the '''AMC Node''' no.
 
* Specify the '''RMD Node''' no.
 
* Specify the '''RMD Node''' no.
 
* Specify the '''RM Master Node''' where the ETP link is connected (Example: “101”)
 
* Specify the '''RM Master Node''' where the ETP link is connected (Example: “101”)
* Specify the program distribution channel were the call request stations are camped on. Leave the default feature code “96” This is a global PD channel for all stages within node 101
+
* Specify the program distribution channel were the call request stations are camped on. This is a global PD channel for all stages within node 101.
 
* Specify the '''AC Group-Call mode'''<br>1 = No ‘gong’ in AC. 2 = ‘Gong’ in AC stations
 
* Specify the '''AC Group-Call mode'''<br>1 = No ‘gong’ in AC. 2 = ‘Gong’ in AC stations
 
* Specify the Group Call length plus 5 - 10 seconds (more than the time set in CB901).
 
* Specify the Group Call length plus 5 - 10 seconds (more than the time set in CB901).
Line 1,289: Line 1,271:
 
====RMD Trunks====
 
====RMD Trunks====
 
* Select ['''Trunks''']
 
* Select ['''Trunks''']
 +
[[Image:RMd 3.PNG|left|thumb|500px|RMD Trunk]]
 +
<br style="clear:both;" />
 
* Specify the numbers for the RM Trunks (NFE1545) and AGA trunks.
 
* Specify the numbers for the RM Trunks (NFE1545) and AGA trunks.
In this example there are 2 x AGA boards in AlphaCom E.
+
* Press ['''Save'''] to save the changes
 +
In this example there is 1 x AGA board in the AlphaCom XE.
  
 
AGA no.1 is connected with 6 trunks to the one NFE1545 in CB901 and these 6 trunks are identified as trunk 1 - 6 in RM node 101.
 
AGA no.1 is connected with 6 trunks to the one NFE1545 in CB901 and these 6 trunks are identified as trunk 1 - 6 in RM node 101.
 
The two first positions on the second AGA board is connected to the two first positions on the other NFE1545 board and are identified as RM trunks 7-8 in RM node 102.
 
 
* Press ['''Save'''] to save the changes
 
 
  
 
====RMD Call Number Configuration====
 
====RMD Call Number Configuration====
 
* Select ['''Call Numbers''']
 
* Select ['''Call Numbers''']
 
* Select the RMD node to be configured
 
* Select the RMD node to be configured
RM call numbers for the selected node are already programmed in the
+
RM call numbers for the selected node are already programmed in the AC via AlphaPro and listed in the left column.
AC via AlphaPro and listed in the left column.
+
[[Image:RMd 4.PNG|left|thumb|500px|RMD Call Number Configuration]]
The features for each station are specified in the following columns.
+
<br style="clear:both;" />
 
+
The features for each station are specified in the following columns:
 
*'''Normal'''.
 
*'''Normal'''.
 
Station to station direct call with transfer of display information only
 
Station to station direct call with transfer of display information only
Line 1,313: Line 1,293:
 
:* Specify the time-out in minutes for queuing (Auto cancel if not accepted)
 
:* Specify the time-out in minutes for queuing (Auto cancel if not accepted)
 
:* Specify if the calling station shall be removed from the call request queue after time-out.
 
:* Specify if the calling station shall be removed from the call request queue after time-out.
If the ['''Cancel'''] field is not marked, the calling stations ID will be
+
If the ['''Cancel'''] field is not marked, the calling stations ID will be present in the guard stations display as an indication on who has called.
present in the guard stations display as an indication on who has
+
* '''Privacy.'''<br>The station shall be tested for privacy. This requires that there are at least two subscriber positions linked together for indirect privacy testing via remote dialing.
called.
 
* '''Privacy.'''<br>The station shall be tested for privacy. This requires that there are at east two subscriber positions linked together for indirect privacy testing via remote dialing.
 
 
*Press ['''Save'''] to save the changes
 
*Press ['''Save'''] to save the changes
  
Line 1,325: Line 1,303:
  
 
All Group Call numbers programmed in AlpaCom via AlphaPro are listed in the left column.
 
All Group Call numbers programmed in AlpaCom via AlphaPro are listed in the left column.
 +
[[Image:RMd 5.PNG|left|thumb|500px|RMD Global Groups]]
 +
<br style="clear:both;" />
 
* Specify the corresponding RM Group Call number which is already programmed in CB901 via SVT
 
* Specify the corresponding RM Group Call number which is already programmed in CB901 via SVT
 
* Press [Save] to save the changes
 
* Press [Save] to save the changes
  
 
====RMD Privacy links====
 
====RMD Privacy links====
 +
[[Image:RMd 6.PNG|left|thumb|500px|RMD Privacy Links]]
 +
<br style="clear:both;" />
 
* Specify the loop connection between two subscriber positions in CB901 which will be used for the privacy test. All stations programmed to be tested for privacy will use the above specified link.
 
* Specify the loop connection between two subscriber positions in CB901 which will be used for the privacy test. All stations programmed to be tested for privacy will use the above specified link.
  
 
The number of specified links depends on the expected traffic. The calling AC station will receive a reject signal when no more “privacy test links” are available.
 
The number of specified links depends on the expected traffic. The calling AC station will receive a reject signal when no more “privacy test links” are available.
  
Privacy test link #1 is specified to be between B and C.
+
[[Image:CB901 RMD Privacy links2.jpg|left|thumb|500px]]
 
+
* Privacy test link #1 is specified to be between B and C.
An AC station is calling the RM Station at D, which is specified to be privacy tested.
+
* An AC station is calling the RM Station at D, which is specified to be privacy tested.
 
+
* The RMD (Ring-Master Daemon) will make a connection between A and B via the ETP link, and one connection between C and D via remote dialing in the SIO port.
The RMD (Ring-Master Daemon) will make a connection between A and B via the ETP link, and one connection between C and D via remote dialing in the SIO port.
+
*Position C has been programmed for “Remote Dialing Receive” via SVT.
 
+
*If the RM station is in privacy, then the privacy tone will be transmitted to the calling AC station via the B-C link. The RMD in AC will select the first free link if more links are specified.
Position C has been programmed for “Remote Dialing Receive” via SVT.
+
<br style="clear:both;" />
 
 
If the RM station is in privacy, then the privacy tone will be transmitted to the calling AC station via the B-C link. The RMD in AC will select the first free link if more links are specified.
 
  
 
In a multi stage CB901 system there must be one privacy test subscriber board in each stage. The stations in each stage, which shall be tested for privacy, will use the privacy test positions in the local central.
 
In a multi stage CB901 system there must be one privacy test subscriber board in each stage. The stations in each stage, which shall be tested for privacy, will use the privacy test positions in the local central.
  
See section [[#Privacy test call numbers SIO|Privacy test call numbers SIO]] on how to set Privacy test numbers and section 6.2
+
See section [[#Privacy test call numbers SIO|Privacy test call numbers SIO]] on how to set Privacy test numbers and section 6.2 for Subscriber board modifications.
for Subscriber board modifications.
 
 
 
  
 
====RMD Call Request Groups (CAS)====
 
====RMD Call Request Groups (CAS)====
 
* Specify the ETP call number to the group in AC where the guard stations are connected. The guard stations are programmed as members in these groups via AlphaPro.
 
* Specify the ETP call number to the group in AC where the guard stations are connected. The guard stations are programmed as members in these groups via AlphaPro.
 +
[[Image:RMd 7.PNG|left|thumb|500px|RMD Call Request Groups]]
 +
<br style="clear:both;" />
 
* Press ['''Save'''] to save the changes
 
* Press ['''Save'''] to save the changes
<br>
+
 
::'''Note: The AlphaCom exchange must be reset after any change in the RMD configuration pages.'''
+
{{Note|A save should be performed in every RMD menu, even if there is no programming done in that RMD menu.}}
 +
 
 +
{{Note|The AlphaCom exchange must be reset after any change in the RMD configuration pages.}}
  
 
==AUDIO LEVEL ADJUSTMENT==
 
==AUDIO LEVEL ADJUSTMENT==
Line 1,361: Line 1,343:
  
 
===Adjustment procedure===
 
===Adjustment procedure===
The audio transmit level in AlphaCom E is fixed and cannot be adjusted.
+
The audio transmit level in AlphaCom XE is fixed and cannot be adjusted. The receive level is adjusted by potentiometers on the AGA board.
The receive level is adjusted by potentiometers on the AGA board.
 
  
The following procedure describes how to adjust the audio level between the audio interface board NFE1545 in the CB901 exchange and the AGA board in the AlphaCom E exchange.
+
The following procedure describes how to adjust the audio level between the audio interface board NFE1545 in the CB901 exchange and the AGA board in the AlphaCom XE exchange.
  
 
The NFE1545 board has 8 audio channels, but only the first 6 are used when communicating with the AGA board.
 
The NFE1545 board has 8 audio channels, but only the first 6 are used when communicating with the AGA board.
  
A DTMF signal generated in AlphaCom E will be used as reference.
+
A DTMF signal generated in AlphaCom XE will be used as reference.
  
 
The adjustment has to be carried out on all new installations as a part of the commissioning procedure.
 
The adjustment has to be carried out on all new installations as a part of the commissioning procedure.
  
The AlphaCom E exchange should be installed in the same room as the CB901 node where the audio interface board NFE1545 is located in order to simplify the adjustment.
+
The AlphaCom XE exchange should be installed in the same room as the CB901 node where the audio interface board NFE1545 is located in order to simplify the adjustment.
  
====AlphaCom E level adjustment====
+
====AlphaCom XE level adjustment====
 
Re-define the function of 6 audio ports in the AGA board using AlphaPro in order to perform a loop test. This test uses a tone generated internally in the AGA board. The input sensitivity of each AGA audio channel can now be adjusted by means of potentiometers on the AGA board.
 
Re-define the function of 6 audio ports in the AGA board using AlphaPro in order to perform a loop test. This test uses a tone generated internally in the AGA board. The input sensitivity of each AGA audio channel can now be adjusted by means of potentiometers on the AGA board.
  
 
The output level is fixed and cannot be adjusted.
 
The output level is fixed and cannot be adjusted.
  
Information in the display of the AlphaCom “super user” station (the first line point in AlphaCom E) will be used as a reference for correct adjustment of the input level potentiometers.
+
Information in the display of the AlphaCom “super user” station (the first line point in AlphaCom XE) will be used as a reference for correct adjustment of the input level potentiometers.
  
 
When all channels are adjusted, the AlphaPro program must be used in order to set the audio channels back to “default”.
 
When all channels are adjusted, the AlphaPro program must be used in order to set the audio channels back to “default”.
  
<br>
 
 
::'''Note: This adjustment must be carried out on all new installations.'''
 
::'''Note: This adjustment must be carried out on all new installations.'''
  
 
::'''Note: The cable between the AGA board and the NFE1545 board must be disconnected during the adjustment.'''
 
::'''Note: The cable between the AGA board and the NFE1545 board must be disconnected during the adjustment.'''
 
 
*In AlphaPro select ['''Exchange & System'''].
 
*In AlphaPro select ['''Exchange & System'''].
 
* Select ['''Board''']
 
* Select ['''Board''']
 +
[[File:Board 1.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Click on the board number for the AGA board you want to adjust.
 
* Click on the board number for the AGA board you want to adjust.
 
:* The AGA board no. is given by the board location in the cabinet.
 
:* The AGA board no. is given by the board location in the cabinet.
Line 1,396: Line 1,377:
 
:* Start by selecting ['''port 2'''] for the installed AGA board to adjust the input from link 1 until 6.
 
:* Start by selecting ['''port 2'''] for the installed AGA board to adjust the input from link 1 until 6.
 
* Select ['''Change''']
 
* Select ['''Change''']
 +
[[File:Board 2.PNG|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* In the field ['''Port use'''], select ['''5 Gain adjust (Group call)'''] and press ['''OK''']
 
* In the field ['''Port use'''], select ['''5 Gain adjust (Group call)'''] and press ['''OK''']
 
* Repeat the procedure until all 6 AGA channels are changed (port 3, port 4, etc.)
 
* Repeat the procedure until all 6 AGA channels are changed (port 3, port 4, etc.)
 +
[[Image:Board 3.PNG|left|thumb|500px|gain ajust]]
 +
<br style="clear:both;" />
  
 
+
'''Adjusting the audio potentiometers 3, 5, 7, 9, 11 and 13.'''
Adjusting the audio potentiometers 3, 5, 7, 9, 11 and 13.
+
[[Image:CB901 AGA board.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Dial '''7872''' from the Super User station and monitor the information in the stations display.
 
* Dial '''7872''' from the Super User station and monitor the information in the stations display.
 
:* Station key 7: Scroll DOWN
 
:* Station key 7: Scroll DOWN
Line 1,406: Line 1,392:
  
 
* Adjust the potentiometer indicated in the display until “'''Full volume level'''” and “'''Attenuated volume level'''” is the same value.
 
* Adjust the potentiometer indicated in the display until “'''Full volume level'''” and “'''Attenuated volume level'''” is the same value.
 +
[[Image:CB901 Adjusting the audio.jpg|left|thumb|500px|Adjusting the Audio]]
 +
<br style="clear:both;" />
 
* After the adjustment is finished the ['''Port use'''] must be set to ['''Default'''] again via AlphaPro.
 
* After the adjustment is finished the ['''Port use'''] must be set to ['''Default'''] again via AlphaPro.
  
<br>
+
 
 
::'''Note: During this test the output links are programmed as inputs and pot. meters 4, 6, 8, 10 and 12 will adjust the input level for thesereversed links.'''<br>'''This function is not used when interfaced to CB901, and you can disregard the adjustment of these pot.meters. This function is used when the AGA board is operating as an audio program (music) interface with only inputs.'''
 
::'''Note: During this test the output links are programmed as inputs and pot. meters 4, 6, 8, 10 and 12 will adjust the input level for thesereversed links.'''<br>'''This function is not used when interfaced to CB901, and you can disregard the adjustment of these pot.meters. This function is used when the AGA board is operating as an audio program (music) interface with only inputs.'''
  
 
====Ring-Master level adjustment====
 
====Ring-Master level adjustment====
 +
 
The amplification in each channel on the audio interface board NFE1545 must be adjusted with the potentiometers R118-R618. VR1 is a common potentiometer for output adjustment of all 6 channels.
 
The amplification in each channel on the audio interface board NFE1545 must be adjusted with the potentiometers R118-R618. VR1 is a common potentiometer for output adjustment of all 6 channels.
 
+
[[Image:CB901 Ring-Master level adjustment.jpg|left|thumb|500px]]
The DTMF audio reference signal is generated in AlphaCom E. See section 4.4.12 for instruction on how to program AlphaCom to transmit DTMF.
+
<br style="clear:both;" />
 +
The DTMF audio reference signal is generated in AlphaCom XE. See section 4.4.12 for instruction on how to program AlphaCom to transmit DTMF.
  
 
Select one Ring-Master and one AlphaCom master station situated close to the test site to perform the adjustment.
 
Select one Ring-Master and one AlphaCom master station situated close to the test site to perform the adjustment.
  
 
Use oscilloscope or electronic multi-meter to read the values.
 
Use oscilloscope or electronic multi-meter to read the values.
<br>
+
 
<br>
+
'''''<u>Adjustment procedure, audio from AlphaCom XE to Ring-Master</u>'''''
'''''Adjustment procedure, audio from AlphaCom E to Ring-Master'''''
+
 
 
* Connect the instrument to the RM station audio line, screw terminals 4 and 5 in the RJ45 wall socket.
 
* Connect the instrument to the RM station audio line, screw terminals 4 and 5 in the RJ45 wall socket.
 
* Make a call from the RM station to the AC station.
 
* Make a call from the RM station to the AC station.
Line 1,433: Line 1,423:
 
* Adjust the actual channel potentiometer (R118-618) until you read the same line level (Ref.level 2) as noted for Ref.level 1.
 
* Adjust the actual channel potentiometer (R118-618) until you read the same line level (Ref.level 2) as noted for Ref.level 1.
 
:* It may be needed to repeat the reading by pressing digit 6 again. The channel will not change as long as the station is not reset.
 
:* It may be needed to repeat the reading by pressing digit 6 again. The channel will not change as long as the station is not reset.
 +
[[Image:CB901 RM station audio line.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 
* Make a new call from the AC station to the RM station.<br>The next channel will automatically be selected.
 
* Make a new call from the AC station to the RM station.<br>The next channel will automatically be selected.
 
:* Repeat the adjustment (Ref.level 2 = Ref.level 1) for all 6 channels.
 
:* Repeat the adjustment (Ref.level 2 = Ref.level 1) for all 6 channels.
<br>
+
 
<br>
+
 
'''''Adjustment procedure, audio from Ring-Master to AlphaCom E'''''
+
'''''<u>Adjustment procedure, audio from Ring-Master to AlphaCom XE</u>'''''
* Connect the instrument to the a-b wire on the Channel 1 line between the AGA and NFE1545 boards on the AlphaCom E side.
+
[[Image:CB901 audio from Ring-Master to AlphaCom E.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
* Connect the instrument to the a-b wire on the Channel 1 line between the AGA and NFE1545 boards on the AlphaCom XE side.
 
* Make calls from AC to RM until Ch. 1 is selected.
 
* Make calls from AC to RM until Ch. 1 is selected.
 
* Press the digit 6 key in the AC station and measure the DTMF #5 pulse level (Line level 1).
 
* Press the digit 6 key in the AC station and measure the DTMF #5 pulse level (Line level 1).
Line 1,445: Line 1,439:
 
* Press the M (mute) and digit 5 key on the RM station, thereby transmitting DTMF #5 to the AC station.
 
* Press the M (mute) and digit 5 key on the RM station, thereby transmitting DTMF #5 to the AC station.
 
* Adjust VR1 on the NFE1545 board until Line level 2 is the same as Line level 1.<br>This is a common adjustment of the audio level from RM to AC for all six audio channels.
 
* Adjust VR1 on the NFE1545 board until Line level 2 is the same as Line level 1.<br>This is a common adjustment of the audio level from RM to AC for all six audio channels.
 +
[[Image:CB901 audio from Ring-Master to AlphaCom E2.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
 +
==MODIFICATIONS IN THE CB901 EXCHANGE==
 +
A hardware modification must be carried out on one subscriber board and on the processor board, depending on system configuration and feature programming.
 +
 +
===Processor board===
 +
The board may need a modification in order to convert one current loop port to RS232 as two serial ports are needed for interconnection to AlphaCom XE.
 +
:* The '''ETP''' port is used for normal dialing and display information
 +
:* The '''SIO''' port is used for remote dialing
 +
 +
'''''<u>Modification IS NOT necessary in:</u>'''''
 +
* Single stage exchange with no display stations. The central is delivered before 1995 and has not been modified to use display stations. See section 3.3.4
 +
* Multi stage exchange with or without display stations. If the system is using display stations, the serial port 4 in stage 1 and 2 will be used for interface.
 +
 +
 +
'''''<u>Modification IS necessary in:</u>'''''
 +
* Single stage with display stations.
 +
 +
 +
====Modification procedure, NFE1683====
 +
Modify data port no.1 from current loop to RS232.
 +
 +
'''''<u>Remove</u>'''''
 +
:* IC U39
 +
:* IC U40
 +
[[Image:CB901 Modifications in the CB901 exchange 1.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
 +
'''''<u>Cut one track on the PCB component side</u>'''''
 +
:* Cut connection between pin 1B and 3B on plug P2
 +
''Indicated by a circled X in the above image''
 +
 +
'''''<u>Cut 4 tracks on the PCB solder side</u>'''''
 +
 +
''Marked with circled X's in the below image''
 +
:* Connection to U34 pin 2
 +
:* Connection to U34 pin 3
 +
:* Connection to U32 pin 4
 +
:* Connection to U32 pin 6
 +
[[Image:CB901 Modifications in the CB901 exchange 2.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
 +
'''''<u>Mount 6 straps on the PCB solder side</u>'''''
 +
 +
''As indicated with yellow wires in the above image''
 +
:* Between U34 pin 3 and connector P2 pinA1
 +
:* Between U34 pin 2 and U29 pin 30
 +
:* Between U32 pin 4 and connector P2 pin A2
 +
:* Between U32 pin 6 and U29 pin 31
 +
:* Between P2 pin B2 and U16 pin 7 (-5 VDC)
 +
:* Between P2 pin B1 and D1 cat. (+5 VDC)
 +
 +
===Subscriber boards===
 +
Two and two subscriber positions must be looped in order to create 4 privacy test links for the RM-ACE interface. This must be done on one subscriber board in each CB901 node in a RM system. If 4 privacy links are not sufficient, a second subscriber board must be modified in each central.
 +
 +
Positions 1-2, 3-4, 5-6 and 7-8 will be strapped.
 +
 +
The board can be plugged into any valid subscriber board position in the central, and the corresponding HEX address for each position must be programmed with individual call numbers.
 +
:* ETP numbers are programmed for positions 1, 3, 5 and 7
 +
:* SIO numbers are programmed for positions 2, 4, 6 and 8
 +
Each ETP number is linked to one corresponding SIO number.
 +
 +
Stations can not be connected to these modified subscriber boards.
 +
 +
 +
====Modification procedure, NFE1813====
 +
'''''<u>Cut one track on the PCB solder side</u>'''''
 +
:* Cut connection between pin 2 and 3 on U4
 +
 +
'''''<u>Mount 9 straps on the PCB solder side</u>'''''
 +
:* U4 pin 2 and U4 pin 7
 +
:* U102 pin 7 and common point for R222/R223/C223
 +
:* U202 pin 7 and common point for R122/R123/C123
 +
:* U302 pin 7 and common point for R422/R423/C423
 +
:* U402 pin 7 and common point for R322/R323/C323
 +
:* U502 pin 7 and common point for R622/R623/C623
 +
:* U602 pin 7 and common point for R522/R523/C523
 +
:* U702 pin 7 and common point for R822/R823/C823
 +
:* U802 pin 7 and common point for R722/R723/C723
 +
[[Image:CB901 Modifications in the CB901 exchange 3.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
 +
====Modification procedure, NFE1625====
 +
'''''PCB solder side'''''
 +
:* Cut the track between pin 2 and 3 on U4
 +
:* Mount one strap between U4 pin 2 and U4 pin 7
 +
[[Image:CB901 Modifications in the CB901 exchange 4.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
 +
'''''PCB component side'''''
 +
 +
There are 8 identical circuits that need a modification.
 +
:* Remove 8 capacitors: C110, 210, 310, 410, 510, 610, 710 and 810.
 +
:* Unsolder the lower leg on 8 capacitors: C109, 209, 309, 409, 509, 609, 709 and 809.
 +
:* Solder a strap between the free leg on the Cx09 capacitors and pin 9 on the Ux02 ICs in the following way:
 +
[[Image:CB901 Modifications in the CB901 exchange 5.jpg|left|thumb|500px]]
 +
* - C109 to U202
 +
* - C209 to U102
 +
* - C309 to U402
 +
* - C409 to U302
 +
* - C509 to U602
 +
* - C609 to U502
 +
* - C709 to U802
 +
* - C809 to U70
 +
<br style="clear:both;" />
 +
 +
==APPENDIX==
 +
===Equipment List===
 +
The following equipment is required for the interconnection between CB901 and AlphaCom XE.
 +
 +
====Ring-Master CB901====
 +
'''''<u>Basic board rack DP979 (Not EMC)</u>'''''
 +
 +
{|
 +
|width="150"|1 x NFE1545
 +
|Interlink B board including 8 audio lines. 6 lines will be used for audio communication with the AGA board in AlphaCom XE
 +
|-
 +
|2 x BF927 || Interconnection cables for audio and serial data.
 +
|}
 +
'''OR'''
 +
 +
 +
'''''<u>Basic board rack DP991 (EMC approved)</u>'''''
 +
{|
 +
|width="150"|1 x NFE1545
 +
| Interlink B board including 8 audio lines. 6 lines will be used for audio communication with the AGA board in AlphaCom XE
 +
|-
 +
|1 x BF950 || Internal cable for audio from NFE1545
 +
|-
 +
|1 x BF957 || Internal RS232 cable
 +
|-
 +
|2 x BF951 || EMC filter
 +
|-
 +
|2 x BF952 || 3 m external cable for audio and serial data
 +
|}
 +
 +
====STENTOFON AlphaCom XE====
 +
 +
'''''<u>AlphaCom XE7</u>'''''
 +
{|
 +
|width="150"|1 x 1009608100
 +
|XE7 package including 1 x ASLT line boards
 +
|-
 +
|1 x 2030010270 ||Mains transformer
 +
|-
 +
|1 x 1009501100 ||Connection kit ASLT/AGA
 +
|-
 +
|1 x 1009303001 ||AGA board for 6 audio channels
 +
|-
 +
|1 x A100A08010 ||RJ45 – 9-pin D-sub Serial Cable Adapter
 +
|}
 +
 +
'''OR'''
 +
 +
 +
'''''<u>AlphaCom XE20</u>'''''
 +
{|
 +
|width="150"|1 x 1009621000
 +
|XE20 exchange including 2 x ASLT line boards
 +
|-
 +
|1 x 1009303001|| AGA board for 6 audio channels
 +
|-
 +
|1 x 1009501021|| Filter board with 5 m connection cable
 +
|}
 +
 +
'''OR'''
 +
 +
 +
'''''<u>AlphaCom XE26</u>'''''
 +
{|
 +
|width="150"|1 x 1009627000
 +
|XE26 exchange including 2 x ASLT line boards
 +
|-
 +
| 1 x 1009303001|| AGA board for 6 audio channels
 +
|-
 +
|1 x 1009501021|| Filter board with 5 m connection cable
 +
|-
 +
|}
 +
 +
'''AND'''
 +
 +
 +
'''''<u>License</u>'''''
 +
 +
{|
 +
|width="150"|1 x 1009649001
 +
| License key; will enable the communication between CB901 and AlphaCom XE
 +
|}
 +
 +
===Interconnection cable, EMC cabinet===
 +
The cable is a 20-pair twisted telephone cable with a 37-pin D-sub connector in one end and loose wires in the other.
 +
[[Image:CB901 Interconnection cable.jpg|left|thumb|500px]]
 +
<br style="clear:both;" />
 +
Two types are available:
 +
{|
 +
|width="150"|BF952
 +
|External RS232/Subscriber cable, 3 m
 +
|-
 +
|BF952A || External RS232/Subscriber cable, 10 m
 +
|-
 +
|}
 +
 +
====Data====
 +
This cable is used to transfer data between CB901 EMC board racks and AlphaCom XE exchanges. See actual interconnection in section [[#ETP data link|ETP data link]] and [[#SIO data link, EMC approved cabinet|SIO data link, EMC approved cabinet]]
 +
 +
Port #1 is converted to RS232 for SIO data if display stations are used, see section [[#Processor board|Processor board]]
 +
 +
The IEC color coding standard is used for wire pair identification.
 +
 +
{|border="1" style="text-align: center;"
 +
!width="100" colspan="1" |PAIR<br>no
 +
!width="120" colspan="2" |COLOR<br>A-wire
 +
!width="80" colspan="1" |D-sub<br>PIN no.
 +
!width="80" colspan="1" |DATA<br>signal
 +
!width="120" colspan="2" |COLOR<br>B-wire
 +
!width="80" colspan="1" |D-sub<br>PIN no.
 +
!width="80" colspan="1" |DATA<br>signal
 +
!width="200" colspan="1" |FUNCTION<br>&nbsp;
 +
|-
 +
|1||&nbsp;|| WHITE || 1 || RTS || style=background:#2244AA;|&nbsp; || BLUE || 20 || CTS || rowspan="3"|'''PORT #5'''<br>Service terminal RS232<br>(SVT) Fixed
 +
|-
 +
|2||&nbsp;|| WHITE || 2 || RX || style=background:#EE8822;|&nbsp;||ORANGE|| 21 || GND
 +
|-
 +
|3||&nbsp;|| WHITE || 3 || TX || style=background:#228822;|&nbsp; || GREEN|| 22 || DTR
 +
|-
 +
|4||&nbsp;|| WHITE || 4 || RTS|| style=background:#884422;|&nbsp;|| BROWN|| 23 || CTS|| rowspan="3"| '''PORT #6'''<br>Printer RS232<br>Fixed
 +
|-
 +
|5||&nbsp;|| WHITE || 5 || RX || style=background:#888888;|&nbsp;|| GREY || 24 || GND
 +
|-
 +
|6|| style=background:#CC2222;|&nbsp; || RED || 6 || TX || style=background:#2244AA;|&nbsp; || BLUE || 25 || DTR
 +
|-
 +
|7|| style=background:#CC2222;|&nbsp; || RED || 7 || RTS|| style=background:#EE8822;|&nbsp; ||ORANGE|| 26 || CTS || rowspan="3"|'''PORT #4'''<br>Radio paging RS232
 +
|-
 +
|8|| style=background:#CC2222;|&nbsp; || RED || 8 || RX || style=background:#228822;|&nbsp; ||GREEN || 27 || GND
 +
|-
 +
|9|| style=background:#CC2222;|&nbsp; || RED || 9 || TX || style=background:#884422;|&nbsp; ||BROWN || 28 || DTR
 +
|-
 +
|10||style=background:#CC2222;|&nbsp; || RED || 10|| RTS|| style=background:#888888;|&nbsp; || GREY || 29 || CTS || rowspan="3"|'''PORT #3'''<br>Display driver
 +
|-
 +
|11|| style=background:#111111;|&nbsp; ||BLACK|| 11|| RX || style=background:#2244AA;|&nbsp; || BLUE || 30 || GND
 +
|-
 +
|12||style=background:#111111;|&nbsp; ||BLACK|| 12|| TX || style=background:#EE8822;|&nbsp; ||ORANGE|| 31 || DTR
 +
|-
 +
|13||style=background:#111111;|&nbsp; ||BLACK|| 13|| RX+|| style=background:#228822;|&nbsp; ||GREEN || 32 || RX- || Serial input 20 mA current loop
 +
|-
 +
|14||style=background:#111111;|&nbsp; ||BLACK|| 14|| TX+|| style=background:#884422;|&nbsp; ||BROWN || 33 || TX- ||Serial output 20 mA current loop
 +
|-
 +
|15||style=background:#111111;|&nbsp; ||BLACK|| 15|| RX+|| style=background:#888888;|&nbsp; || GREY || 34 || RX- ||rowspan="2"|'''PORT #2''' <br> 20 mA current loop
 +
|-
 +
|16||style=background:#EEEE22;|&nbsp;||YELLOW|| 16|| TX+|| style=background:#2244AA;|&nbsp; || BLUE || 35 || TX
 +
|-
 +
|17||style=background:#EEEE22;|&nbsp;||YELLOW|| 17|| RX+|| style=background:#EE8822;|&nbsp; ||ORANGE|| 36 || RX- ||rowspan="2"|'''PORT #1'''<br>20 mA current loop
 +
|-
 +
|18||style=background:#EEEE22;|&nbsp; ||YELLOW|| 18|| TX+|| style=background:#228822;|&nbsp; ||GREEN || 37 || TX
 +
|-
 +
|19|| style=background:#EEEE22;|&nbsp; || YELLOW || 19 ||&nbsp; ||style=background:#884422;|&nbsp; || BROWN || NC || &nbsp; || &nbsp;
 +
|-
 +
|20 || style=background:#EEEE22;|&nbsp;|| YELLOW || NC ||&nbsp; ||style=background:#888888;|&nbsp; || GREY || NC || &nbsp; || &nbsp;
 +
|}
 +
 +
 +
 +
 +
====Audio====
 +
 +
 +
This cable is used to transfer 6 audio channels between CB901EMC board racks and AlphaCom XE exchanges. See actual interconnection in section [[#Audio interlinks, CB901 side|Audio interlinks, CB901 side]]
 +
 +
The IEC color coding standard is used for wire pair identification.
 +
 +
{|border="1" style="text-align: center;"
 +
!width="100" colspan="1" |PAIR<br>no
 +
!width="120" colspan="2" |COLOR<br>A-wire
 +
!width="80" colspan="1" |D-sub<br>PIN no.
 +
!width="120" colspan="2" |COLOR<br>B-wire
 +
!width="80" colspan="1" |D-sub<br>PIN no.
 +
!width="200" colspan="2" |CABLE<br>FUNCTION
 +
|-
 +
|1||&nbsp;|| WHITE || 1 ||  style=background:#2244AA;|&nbsp; || BLUE || 20 || Out|| rowspan="2"|LINK #1
 +
|-
 +
|2||&nbsp;|| WHITE || 2 ||  style=background:#EE8822;|&nbsp;||ORANGE|| 21 || In
 +
|-
 +
|3||&nbsp;|| WHITE || 3 ||  style=background:#228822;|&nbsp; || GREEN|| 22 || Out || rowspan="2"|LINK #2
 +
|-
 +
|4||&nbsp;|| WHITE || 4 ||  style=background:#884422;|&nbsp;|| BROWN|| 23 || In
 +
|-
 +
|5||&nbsp;|| WHITE || 5 ||  style=background:#888888;|&nbsp;|| GREY || 24 || Out||rowspan="2"|LINK #3
 +
|-
 +
|6|| style=background:#CC2222;|&nbsp; || RED || 6 ||  style=background:#2244AA;|&nbsp; || BLUE || 25 || In
 +
|-
 +
|7|| style=background:#CC2222;|&nbsp; || RED || 7 ||  style=background:#EE8822;|&nbsp; ||ORANGE|| 26 || Out|| rowspan="2"|LINK #4
 +
|-
 +
|8|| style=background:#CC2222;|&nbsp; || RED || 8 ||  style=background:#228822;|&nbsp; ||GREEN || 27 || In
 +
|-
 +
|9|| style=background:#CC2222;|&nbsp; || RED || 9 ||  style=background:#884422;|&nbsp; ||BROWN || 28 || NC||&nbsp;
 +
|-
 +
|10||style=background:#CC2222;|&nbsp; || RED || 10||  style=background:#888888;|&nbsp; || GREY || 29 || NC||&nbsp;
 +
|-
 +
|11|| style=background:#111111;|&nbsp; ||BLACK|| 11|| style=background:#2244AA;|&nbsp; || BLUE || 30 || Out||rowspan="2"|LINK #5
 +
|-
 +
|12||style=background:#111111;|&nbsp; ||BLACK|| 12||  style=background:#EE8822;|&nbsp; ||ORANGE|| 31 || In
 +
|-
 +
|13||style=background:#111111;|&nbsp; ||BLACK|| 13||  style=background:#228822;|&nbsp; ||GREEN || 32 || Out ||rowspan="2"|LINK #6
 +
|-
 +
|14||style=background:#111111;|&nbsp; ||BLACK|| 14||  style=background:#884422;|&nbsp; ||BROWN || 33 || In
 +
|-
 +
|15||style=background:#111111;|&nbsp; ||BLACK|| 15||  style=background:#888888;|&nbsp; || GREY || 34 || NC ||&nbsp;
 +
|-
 +
|16||style=background:#EEEE22;|&nbsp;||YELLOW|| 16||  style=background:#2244AA;|&nbsp; || BLUE || 35 || NC||&nbsp;
 +
|-
 +
|17||style=background:#EEEE22;|&nbsp;||YELLOW|| 17|| style=background:#EE8822;|&nbsp; ||ORANGE|| 36 || NC||&nbsp;
 +
|-
 +
|18||style=background:#EEEE22;|&nbsp; ||YELLOW|| 18||  style=background:#228822;|&nbsp; ||GREEN || 37 || NC||&nbsp;
 +
|-
 +
|19|| style=background:#EEEE22;|&nbsp; || YELLOW || 19 ||style=background:#884422;|&nbsp; || BROWN || NC|| NC || &nbsp;
 +
|-
 +
|20 || style=background:#EEEE22;|&nbsp;|| YELLOW || NC ||style=background:#888888;|&nbsp; || GREY || NC|| NC || &nbsp;
 +
|}
 +
 +
===Interconnection, non EMC cabinet===
 +
 +
====Data from the CPU board====
 +
 +
Port #1 is converted to RS232 for SIO data if display stations are used, see section [[#Processor board|Processor board]]
 +
 +
{|border="1" style="text-align: center;"
 +
!width="50" |CPU<br>pin no.
 +
!width="70" |BLOCK<br>no display
 +
!width="50" |BLOCK<br>display
 +
!width="50" |Data<br>signal
 +
!width="50" |CPU<br>pin no.
 +
!width="80" |BLOCK<br>no display
 +
!width="80" |BLOCK<br>display
 +
!width="80" |DATA<br>signal
 +
!width="120" |FUNCTION<br>&nbsp;
 +
|-
 +
|27A||4||4||RTS|| 27B ||5 ||5|| CTS ||rowspan="3" align="left"| '''PORT #5'''<br>Service terminal RS232<br>(SVT) Fixed
 +
|-
 +
|26A||6||6|| RX||26B||7||7|| GND
 +
|-
 +
|25A||8||8||TX|| 25B ||9 ||9|| DTR
 +
|-
 +
|24A||10||10||RTS ||24B||11||11|| CTS ||rowspan="3" align="left"| '''PORT #6'''<br>Printer RS232<br>Fixed
 +
|-
 +
|23A||12||12||RX|| 23B ||13 ||13|| GND
 +
|-
 +
|22A||14||14||TX|| 22B ||15||15|| DTR
 +
|-
 +
|21A||16||16||RTS||21B||17 ||17 || CTS ||rowspan="3" align="left"| '''PORT #4'''<br>Radio paging RS232<br>(ETP)
 +
|-
 +
|20A||18||18||RX|| 20B ||19||19|| GND
 +
|-
 +
|19A||20||20||TX||19B||21 ||21 || DTR
 +
|-
 +
|18A||NC||NC||RTS|| 18B||NC||NC|| CTS ||rowspan="3" align="left"| '''PORT #3'''<br>Display driver<br>(SIO)
 +
|-
 +
|17A||22||NC||RX||17B|| 23||NC || GND
 +
|-
 +
|16A||24||NC||TX|| 16B ||23||NC|| DTR
 +
|-
 +
|'''7A-15A'''||&nbsp;||&nbsp;||'''-'''||''' 7B-15B''' ||&nbsp; ||&nbsp;||'''-'''||align="left"|'''NC'''
 +
|-
 +
|6A||NC||30||RX+ ||6B||NC||31|| RX- || align="left" |Serial input 20 mA current loop
 +
|-
 +
|5A||NC||32||TX+|| 5B ||NC ||33|| TX- || align="left" |Serial output 20 mA current loop
 +
|-
 +
|4A||NC||34|| RX+ ||4B ||NC||35|| RX- || rowspan="2" align="left"| '''PORT #2'''<br>20 mA current loop
 +
|-
 +
|3A||NC||36||TX+|| 3B ||NC ||37|| TX-
 +
|-
 +
|2A||NC||38||RX+|| 2B ||NC||39|| RX- || rowspan="2" align="left"| '''PORT #1'''<br>20 mA current loop (RS232/SIO)
 +
|-
 +
|1A||NC||40||TX+|| 1B || NC || 41 || TX-
 +
|}
 +
 +
====Audio from the Audio Interface board====
 +
See also section [[#Audio interlinks, CB901 side|Audio interlinks, CB901 side]]
 +
 +
 +
{|border="1" | style=center
 +
!rowspan="2" | BOARD11<br>P1
 +
!rowspan="2" | TERMINAL<br>BLOCK
 +
!rowspan="2" | BOARD11<br>P1
 +
!rowspan="2" | TERMINAL<br>BLOCK
 +
!colspan="2" | CABLE
 +
|-
 +
!DIRECTION || LINK
 +
|-
 +
|31A-32A || NC || 31B-32B || NC || &nbsp; || &nbsp;
 +
|-
 +
|30A || 2 || 30B || 3 || Out || rowspan="2" | LINK #1
 +
|-
 +
|29A || 4 || 29B || 5 || In
 +
|-
 +
|28A || 6 || 28B || 7 || Out || rowspan="2" | LINK #2
 +
|-
 +
|27A || 8 || 27B || 9 || In
 +
|-
 +
|26A || 10 || 26B || 11 || Out || rowspan="2"| LINK #3
 +
|-
 +
|25A || 12 || 25B || 13 || In
 +
|-
 +
|24A || 14 || 24B || 15 || Out || rowspan="2"| LINK #4
 +
|-
 +
|23A || 16 || 23B || 17 || In
 +
|-
 +
|21A-22A || 18-20 || 21B-22B || 19-21 || - || NC
 +
|-
 +
|17A-20A || NC || 17B-22B || NC || - || -
 +
|-
 +
|16A || 22 || 16B || 23 || Out || rowspan="2"| LINK #5
 +
|-
 +
|15A || 24 || 15B || 25 || In
 +
|-
 +
|14A || 26 || 14B || 27 || Out || rowspan="2"| LINK #6
 +
|-
 +
|13A || 28 || 13B || 29 || In
 +
|-
 +
|7A-12A || 30-40 || 7B-12B || 31-41 || - || NC
 +
|-
 +
|1A-6A || NC || 1B-6B || NC || - || -
 +
|}
 +
 +
[[Category:3rd party integration]]

Latest revision as of 09:58, 4 July 2018

AlphaCom icon 300px.png
RM AC.PNG

The images and descriptions in this article are updated to cover interfacing between RingMaster CB901 and the AlphaCom XE Audio Server with AMC-IP software version 11.3.3.2 and AlphaPro 11.6.3.3.

Contents

SYSTEM BUILD-UP

General Description

An existing Ring-Master CB901 system can be expanded by adding one or more STENTOFON AlphaCom XE exchanges. The two systems are interconnected via data and audio links. Stations and equipment in both systems will interact as part of the same system. The AlphaCom XE IP services can be accessed from the Ring-Master system.

CB901 General description.jpg


Data

Data are transmitted via one or two serial RS232 links.

  • One link (ETP, External Trunk Protocol) is used for station-to-station calls, Group Call, Call Request and Caller ID.
  • An optional link (SIO, Serial Input Output) is used for other functions like Privacy information and Call Request camp on.

Audio

The audio interconnection between CB901 and AlphaCom XE is analogue.

  • There are 6 conversation channels in a 12 pair twisted cable between each Interlink B board in CB901 and AGA board(s) in AlphaCom XE.

Audio switching control (Duplex)

There is no transfer of switching control signals between the CB901 and AlphaCom XE. The switching will take place individually in the Ring-Master station and in AlphaCom XE.


Programming

The CB901-AlphaCom XE interface features are programmed by use of:

  • SVT for the CB901 part
  • AlphaPro and AlphaWeb for the AlphaCom XE part and the Ring-Master Daemon

Basic System Features

All internal features in both systems will remain as they are.

The following features will be included in the interface between CB901 and AlphaCom XE:

  • Station to station calling.
  • Display information.
    Call number of calling station or station ID
  • Simultaneous (global) All-Call and Group-Call.
    One global call at the time in the RM /ACE system.
  • Call request and queuing from stations in CB901 to master stations(guards) in AlphaCom XE.
    Calling stations will be camped on in one program distribution channel in CB901.
  • Pocket paging.
    Automatic pocket paging in both systems. One individual serial ESPA 4.4.4. connection between AlphaCom XE and the pager system; and CB901 and the pager system.
    The info in the pager display will identify the caller who has to be called back manually.
  • Privacy.
    Stations in CB901 will be tested for privacy also when called from AlphaCom XE. The subscriber board must be modified according to section 6.2
  • Remote door opening.
    AlphaCom XE will generate a DTMF signal when a button is pressed in the AlphaCom station during conversation with the CB901 door station. This signal will be decoded by the remote output board DP997 inside the RM door station and used to activate the magnetic lock.

See: Door opening of Ring Master stations from AlphaCom

Software Description

Ring-Master CB901

The ETP (External Trunk Protocol) communication software is included in revisions from TX5.7. The software in the Ring-Master system must be upgraded if the present software revision is TX5.6 or lower.

The upgrade includes changing of E-PROMs on all processor boards. It is not necessary to change the software in the DNC.

Processor board


If the software revision is lower than TX5.0 (TX4.x or TX3.x) the processor board(s) must be changed.

Connector P2 must be present on the motherboard in board position 19 in order to get power to the serial links of the processor board NFE1683.

Old systems using the first processor boards NFE1515 and NFE1592 does not have connector P2 on the motherboard in position 19. The new processor board NFE1683 can then be installed in position 20 if there are long pins on the back for the PC port connections. If there are no connection pins at the back, the whole cabinet must be changed to type DP979.
Note: If the processor board is plugged into position 20 in an old rack, you must cut out a piece of the cabinet profile in order to get room for the battery RAM on the board.
Note: The same software must be installed in all nodes in a CB901 multistage system.

AlphaCom E (XE)

The software must be of revision 10.30 or higher. It is recommended to always have the latest version available.
This revision includes the following software routines:

  • The software module (Daemon) which is linking the CB901 ETP format with the AlphaCom E main software.
  • The WEB interface which is used to configure the AlphaCom for communication with CB901 (AlphaWeb)

The AlphaPro software must be of revision 10.28 or higher. This revision includes the following commands:

  • Identification of CB901 stages as nodes in AlphaCom
  • Identify the audio links

AlphaWeb Configuration Commands

The Ring-Master Daemon will use a number of tables to maintain the ETP function. These tables will be configurable through the AlphaWeb window.

The following tables are identified:

  • Group Call
  • Call Request (CAS) to stations in AlphaCom XE
  • Program channel for call request camp-on in CB901.
  • Privacy test of stations in CB901
  • RMD system parameters

AlphaWeb System Monitoring and Logging

The AlphaCom XE can monitor and log real-time events. This can be viewed in the AlphaWeb.

Ring-Master Daemon System log

The Ring-Master Daemon (RMD) will report the following to the syslog server:

  • RMD Up/Down
  • AlphaNet Connected/Disconnected
  • Serial Port Up/Down

Ring-Master Daemon System Monitoring

The Ring-Master Daemon will report the following to the syslog server:

  • AGA/ETP trunks Up/Down
  • AGA Trunk allocation failed (no more audio links available)
  • Unknown/Erroneous commands from the Ring-Master system

Programming

Individual programming will be carried out in each system by using a locally connected data terminal (PC or laptop).

One system can not be programmed from the other system.

Number plan

  • The call number in AlphaCom XE must have 4 digits in order to call from CB901 to AlphaCom XE. This is limited by the ETP format.
  • The number of call digits in AlphaCom XE is 1 - 8. Only 4-digit numbers can be reached from the RM side.
  • The maximum number of call digits in CB901 is 6. All digits from 2 to 6 can be reached from both sides.
RM-AC NumberPlan 01.png


Programming Ring-Master CB901

Use a terminal emulating program such as ProCom plus or HyperTerminal. See section 4.2 for detailed procedure.

Purpose of programming

  • Set the data of the serial port used for ETP communication with AlphaCom XE
  • Set the data of the serial port used for remote dialing from AlphaCom XE (PC port) and status output to AlphaCom XE
  • Program the feature code for the access to the numbers in the AlphaCom XE
    If the feature code is one digit ‘F’, then the call number in AlphaCom XE will be ‘F A A A’. ‘AAA’ represent any digit
  • Identify the 6 hex positions where the NFE1545 audio interface board is connected. This is fixed to E0-E5.
  • Identify the 2 hex positions (call numbers) that will be used for privacy test of the RM stations (ETP and SIO).

A modification must be carried out on the subscriber board in order to link two and two subscriber positions together. Se section 6.2

  • Each modified subscriber board will offer 4 privacy links.
  • Each CB901 stage must have one modified subscriber board for privacy test of the stations within the stage.

Programming AlphaCom XE

Use the STENTOFON AlphaPro PC program and AlphaWeb to perform programming. See section 4.3 for detailed programming procedure.


Purpose of programming

  • Identify the CB901 stage(s) where the NFE1545 audio interface board(s) is(are) installed
  • Program the 6 positions used by the AGA board(s)
  • Specify optional station and system functions related to CB901
  • Normal station
  • Privacy test
  • Call request and corresponding parameters

SYSTEM DESCRIPTION

Rack layouts

Ring-Master CB901

Most board types have their fixed position in the racks. Some positions may be left empty or accept different boards depending on performance and configuration. The table below is a typical set-up when integrated with AlphaCom XE.

CB901 Rock layouts1.jpg


CB901 Rock layouts2.jpg


The subscriber lines are available on P2 and the subscriber number address is in hexadecimal format.

Pos Type Name Note
    Basic board rack  
1 NFE 1528 Power Board  
2-9 NFE 1813 Subscriber Board Supports:
C - GC - AC - PD - D
2-9 NFE 1625 Subscriber Board Supports:
C - GC - AC - PD
2-9 NFE 1525 Subscriber Board Supports:
C - GC - AC
10 NFE 1626 Audio Interface Board For C - GC - AC - PD
10 NFE 1625 Subscriber Board If GC - AC - PD *
11 NFE 1545 Audio Interface Board Audio to AlphaCom,
address E0-E5
12 NFE 1545 Audio Interface Board If 12 audio links are needed
12 NFE 1692 2 Mbit Link Board Used in 3-stage systems
13 NFE 1692 2 Mbit Link Board Used in 2-, 3- and multistage systems
14-15 NFE 1521 Link Control Board  
16 NFE 1607 Audio Control Board  
17 NFE 1519 Switch Control Board  
18 NFE 1606 Timing Control Board  
19 NFE 1683 Processor Board  
20 - - Not used
    Subscriber board rack  
21-39 NFE 1813 Subscriber Board Supports:
C - GC - AC - PD - D
21-39 NFE 1625 Subscriber Board Supports:
C - GC - AC - PD
21-39 NFE 1525 Subscriber Board Supports:
C - GC - AC
40 - - Not used
C = Call
GC = Group Call
AC = All Call
PD = Program Distribution
D = Display
* = PD card is only required for Call Request.

AlphaCom XE7

Except for the AMC-IP Computer Board in position 7, all board types can be inserted in any board position.

CB901 AlphaCom E7.jpg


When interconnected to CB901, at least one AGA Audio Interface Board with 6 lines will be used. It is good practice to insert these boards from position 6 and downwards.

Normally there will be only ASLT Subscriber Boards for analogue stations in the rest of the positions.

The stations and the AGA audio lines are connected to plug-on screw terminals on the backplane. The physical line numbers are equal to the decimal station number.

IP stations do not need ASLT boards; they are connected to the IP network.

AlphaCom XE20 and XE26

The AMC-IP Computer Board and the APC Program and Clock Board have dedicated positions in slot 25 and 26.

CB901 AlphaCom E20 and E26.jpg


When interconnected to CB901, at least one AGA Audio Interface Board with 6 lines will be used. This board should be inserted in slot position 23.

If more AGA boards are used, it is good practice to insert these boards from position 23 and downwards even if they will function in any position.

Normally there will be only ASLT Subscriber Boards for analogue stations and/or ATLB boards for analogue telephones in the rest of the positions.


Note that board positions 2-7 are missing in AlphaCom XE20 exchanges.

The stations and the AGA audio lines are available on connection boards on the back of the rack. The physical line numbers are equal to the decimal station number.

IP stations do not need ASLT boards; they are connected to the IP network.

  • Note: Avoid using AGA in position 24, this position is for MultiModule and High Availability use only!

System Configuration

CB901

All CB901 system configurations can be interfaced to AlphaCom XE. One CB901 stage has one basic board rack with power, system boards and up to 8 subscriber boards for 64 lines. An additional subscriber board rack will extend the number of lines with up to 176.

Single stage

CB901 Single Stage.jpg


  • 64 subscribers in a basic board rack
  • Up to 240 subscribers with additional subscriber board rack
  • 15 internal conversation links

Double stage

CB901 Double Stage.jpg


  • Up to 480 subscribers with subscriber board racks
  • 15 internal conversation links in each 240 number node
  • 8 conversation links between the nodes
  • Node interconnection via 1 x 18 pairs twisted cable or 2 x optical multimode fiber cables

Triple stage

CB901 Triple Stage.jpg


  • Up to 720 subscribers with subscriber board racks
  • 15 internal conversation links in each 240 number node
  • 8 conversation links between each node
  • Node interconnection via 3 x 18 pairs twisted cable or 3 x 1 pair optical multimode fibers
  • Nodes are interconnected in a triangle configuration

Multistage

CB901 Multistage.jpg


  • Up to 30 x 240 (7200) subscribers
  • 15 internal conversation links in each 240 number node
  • Nodes are connected to a Digital Network Controller (DNC) in a star configuration via one pair optical multimode fiber cable
  • 8 conversation links between each node and the DNC
  • There are no subscribers connected to the DNC

AlphaCom XE

AlphaCom cabinets have a fixed position for the AMC-IP Computer Board and the APC Program and Clock Board (XE20 and XE26 only). All other boards including ASLT Line Boards and AGA Audio Interface Boards can be put in any free position.

It is strongly recommended to insert the ASLT boards starting from the lowest board position and the AGA boards from the highest.

XE7 – single module

CB901 E7 - single module.jpg


  • Up to 36 traditional stations + IP stations as required.
  • 6 free positions for AGA or other boards.
  • Each AGA board will reduce the number of traditional stations by 6 per board.
  • 1 internal conversation link per ASLT line board.

XE20 – single module

CB901 E20 - single module.jpg


  • Up to 102 traditional stations + IP stations as required.
  • 17 free positions for AGA or other boards.
  • Each AGA board will reduce the number of traditional stations by 6 per board.
  • 1 internal conversation link per ASLT line board.

XE26 – single module

CB901 E26 - single module.jpg


  • Up to 138 traditional stations + IP stations as required.
  • 23 free positions for AGA or other boards.
  • Each AGA board will reduce the number of traditional stations by 6 per board.
  • 1 internal conversation link per ASLT line board.

Multi-modules

CB901 Multi-modules.jpg


  • Up to 4 modules (1 master + 1-3 slaves) can be interconnected to act as one exchange node with extended number of analogue subscriber lines.
  • 4 x XE7 can have up to 144 subscribers
  • 4 x XE20 can have up to 408 subscribers
  • 4 x XE26 can have up to 552 subscribers
  • The modules are normally interconnected via an IP network but connection using AE1 boards and E1/T1 signaling is also possible
  • The number of audio channels depends on the purchased AlphaNet VoIP licenses, max. 30 per module

AlphaNet

CB901 AlphaNet.jpg


  • Up to 254 AlphaCom XE exchanges can be interconnected in one network
  • The exchanges are interconnected via an IP network
  • The total number of global directory numbers is limited to 8700
  • The number of audio channels depends on the purchased AlphaNet VoIP licenses, max. 30

Interconnection

General

The AlphaCom XE and Ring-Master systems are interconnected via

  • One or two RS232 serial ports
  • One or several 4-wire, 0 dBm audio links.

The physical interfacing between the Ring-Master and AlphaCom XE exchanges depends on the configuration on both sides, but the general configuration is the same.

The following examples show the most typical situations. The AlphaCom shown is an XE7, but the general connection to XE20 and XE26 is the same.


Single stage CB901 with ETP data link

CB901 Single Stage CB901 with ETP data link.jpg


  • This configuration will give normal call, Group Call and 6 audio links.
  • Privacy indication and Call Request is NOT supported.
  • Display in RM stations is supported. (Subscriber boards NFE1813 only).
  • Pocket Paging must be connected to AlphaCom XE.

Single stage CB901 with ETP and SIO data links

CB901 Single Stage CB901 with ETP and SIO data links.jpg


  • This configuration will give normal call, Group Call and 6 audio links.
  • Privacy indication and Call Request is supported.
  • Option 1: Display in RM stations is NOT supported.
  • Option 2: One current loop port must be modified to RS232 in CB901

Dual stage CB901 with ETP data link

CB901 Dual stage CB901 width ETP data link.jpg


  • This configuration will give normal call, Group Call and 12 audio links.
  • Privacy indication and Call Request is NOT supported.
  • Display in RM stations is supported. (Subscriber boards NFE1813 only).
  • Pocket Paging can be connected to RM stage 2 or be connected to AlphaCom.


Dual stage CB901 with ETP and SIO data links

CB901 Dual stage CB901 width ETP and SIO data links.jpg


  • This configuration will give normal call, Group Call and 12 audio links.
  • Privacy indication and Call Request is supported.
  • Display in RM stations is supported. (Subscriber boards NFE1813 only).
  • Pocket Paging must be connected to AlphaCom XE.

Triple stage CB901

  • The ETP and SIO data links are connected to the first two stages like in a two stage configuration.
  • Each stage can supply 6 audio links by adding an AGA board in the AlphaCom exchange.

Processor board NFE1683 location

In order to connect the serial data links to the processor board NFE1683, there must be a P2 connector on the motherboard in board position 19.

Old systems using processor boards type NFE1515 or NFE1592 does not have this P2 connector. The new processor board NFE1683 can then be installed in position 20 if there are long pins on the back plane for the serial port connections.

If there are no connection pins for board connector 19 or 20 on the back plane, the whole cabinet must be changed to type DP979.

Note: If the processor board is plugged into position 20 in an old rack, a piece of the cabinet profile must cut out in order to get room for the battery RAM on the board.

ETP data link

Use RS232 serial port 4 on the processor board NFE1683 in stage no.1 for the ETP data-link connection to AlphaCom XE. This link is controlling the RM station connections.

CB901, non EMC cabinet

CB901 ETP data link.jpg


  • Insert the upper connectors from the CPU terminal block on board connector P2-19. Leave the upper 4 pair of pins unconnected.
  • Connect 3 wires to the terminal block pos. 18, 19 and 20.
  • Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom XE according to the table below.
Signal AlphaCom D-sub Terminal block Board no. 19
TX 2 20 19A
RX 3 18 20A
GND 5 19 20B

Port 0 in AlphaCom XE20 and XE26 need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.


CB901, EMC approved cabinet

CB901 ETP data link2.jpg


  • Use the 3 m external RS232/Subscriber cable BF952.
  • Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
  • Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
Signal AlphaCom D-sub Wire color Wire pair
RX 3   RED 8
GND 5   GREEN
TX 2   RED 9
- NC   BROWN

Complete connection table for BF952 is found in Appendix 7.1


SIO data link, non EMC cabinets

This port is used for optional functionality data like Privacy info and Call Request.

Single stage CB901 without display stations

CB901 SIO data link, non EMC cabinets1.jpg


The SIO data link cable can be connected to serial port 3 since this port is not in use for display stations.

  • Insert the lower connector from the CPU terminal block on board connector P2-19. Leave 1 pair of pins unconnected between the two connectors.
  • Connect 3 wires to the terminal block pos. 22, 23 and 24.
  • Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 1 in AlphaCom XE according to the table below.
Signal AlphaCom D-sub Terminal block Board no.19
TX 2 24 16A
RX 3 22 17A
GND 5 23 17B

Port 1 in all AlphaCom XE exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.


Single stage CB901 with display stations

CB901 SIO data link, non EMC cabinets2.jpg


If the CB901 exchange has display stations, serial port 3 will be in use.

Use the serial 20mA current loop port no.1. The processor board NFE1683 must be modified and re-programmed to change the port to RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1 for modification procedure.

  • Insert the lower connector from the CPU terminal block on board connector P2-19 from pin 1 upwards.
  • Connect 3 wires to the terminal block pos. 39, 40 and 41.
  • Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 1 in AlphaCom ZE according to the table below.
Signal AlphaCom D-sub Terminal block Board no.19
TX 2 40 1A
RX 3 38 2A
GND 5 39 2B

Port 1 in all AlphaCom XE exchanges need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.


Dual and Triple stage CB901

CB901 SIO data link, non EMC cabinets3.jpg


Use RS232 serial port 4 on the processor board NFE1683 in stage no.2 for the SIO data-link connection to AlphaCom XE.

  • Insert the upper connector from the CPU terminal block on board connector P2-19 in stage 2. Leave the upper 4 pair of pins unconnected.
  • Connect 3 wires to the terminal block pos. 18, 19 and 20.
  • Solder a male 9 pin D-sub plug to the other end of the cable for connection to port 0 in AlphaCom XE according to the table below.
Signal AlphaCom D-sub Terminal block Board no.19
TX 2 20 19A
RX 3 18 20A
GND 5 19 20B

Port 0 in AlphaCom XE20 and XE26 need an RJ45 – 9-pin D-sub Serial Cable Adapter type A100A08010.


SIO data link, EMC approved cabinet

Single stage CB901 without display stations

SIO data link, EMC approved cabinet1.jpg


The SIO data link can be connected to serial port 3 since this port is not in use for display stations. If the rear side of the motherboard has green straps for display station modification, remove the two straps at 19A and 20A on card pos. 19.

  • Use the 3 m external RS232/Subscriber cable BF952.
  • Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
  • Select the RS232 port no.3 wires at the cable end and solder to a male 9-pin D-sub plug.
Signal AlphaCom D-sub Wire color Wire pair
RX 3   BLACK 11
GND 5   BLUE
TX 2   BLACK 12
- NC   ORANGE

Complete connection table for BF952 is found in Appendix 7.1


Single stage CB901 with display stations

SIO data link, EMC approved cabinet2.jpg


If the CB901 exchange has display stations, serial port 3 will be in use.

Use the serial 20mA current loop port no.1. The processor board NFE1683 must be modified and re-programmed to change the port to RS232. This modification involves 5 cuts and 6 straps. See section 6.1.1 for modification procedure.

  • Use the 3 m external RS232/Subscriber cable BF952.
  • Connect the 37 pin D-sub connector to the processor board terminal on the cabinet rear (upper right).
  • Select the RS232 port no.1 wires at the cable end and solder to a male 9-pin D-sub plug.
Signal AlphaCom D-sub Wire color Wire pair
RX 3   YELLOW 17
GND 5   ORANGE
TX 2   YELLOW 18
- NC   GREEN

Dual and Triple stage CB901

SIO data link, EMC approved cabinet3.jpg


Use RS232 serial port no.4 on the processor board NFE1683 in stage 2 for the SIO data-link connection to AlphaCom XE.

  • Use the 3 m external RS232/Subscriber cable BF952.
  • Connect the 37 pin D-sub connector to the processor board terminal on the stage 2 cabinet rear (upper right).
  • Select the RS232 port no. 4 wires at the cable end and solder to a male 9-pin D-sub plug.
Signal AlphaCom D-sub Wire color Wire pair
RX 3   RED 8
GND 5   GREEN
TX 2   RED 9
- NC   BROWN


Complete connection table for BF952 is found in Appendix 7.1


Data links, AlphaCom XE

AlphaCom XE7

CB901 Data links, AlphaCom E.jpg


In the AlphaCom XE7 serial port 0 is a 9-pin D-sub connector and port 1 is an RJ45 connector.

In order to connect the 9-pin D-sub plug (SIO signal) to the exchange, an RS232-RJ45 Interface Cable type A100A08010 must be used.


AlphaCom XE20 and XE26

CB901 Data links, AlphaCom E 2.jpg


The AlphaCom XE20 and XE26 have a filter board with two RJ45 serial ports and two Ethernet RJ45 connectors.

The upper connector is serial port 0 for ETP signals, and the next is serial port 1 used for SIO signals.

In order to connect the 9-pin D-sub plugs to the exchange, an RS232-RJ45 Interface Cable type A100A08010 must be used.


RS232 – RJ45 Interface Cable

CB901 Data links, AlphaCom E 3.jpg


The internal connection in the A100A08010 interface cable is:

RJ45 pin no. D-sub pin no. Signal
3 2 TX
4+5 5 GND
6 3 RX

Audio interlinks, CB901 side

The NFE1545 Audio Interface Board shall be installed in board position no.11 in the CB901 basic board rack of stage 1.

The AGA Audio Interface Board can be installed in any free subscriber board position in AlphaCom XE. Pos. 20-23 is recommended in E26 to avoid modifications of the backplane.

Please see section 3.2.2 for available board slots, and the AlphaCom XE installation manual for further installation details.

The NFE1545 board has 8 interlinks, but since the corresponding AGA board in AlphaCom XE has 6, only the 6 first interlinks on the NFE1545 board will be used.

If more interlinks are required in a multi stage system, additional NFE1545 boards can be installed in the other stages. Use slot no.11 in all stages.

The number of AGA boards in the AlphaCom XE exchange is only limited by the number of subscriber board positions.

  • The address programming jumpers on the NFE1545 board shall be put in positions E2-E3 and E5-E6. The hex addresses for the 6 board positions will then be from E0 to E5.

The lowest LED on the NFE1545 board will be ON. This is just an indication for the free hex address FF.

adress programming jumpers



Audio links, non EMC cabinets

CB901 Audio links, non EMC cabinets.jpg


  • Use a 12 pair twisted cable for the audio link between the CB901 and the AlphaCom XE exchange. The connections are made on the Krone terminal block.
  • The two 20 pin connectors are connected to P1 on the NFE1545 board (the lower connector on the motherboard).
  • Leave two unconnected pair of pins above the upper connector
  • Leave four unconnected pair of pins between the two connectors
LINK BOARD 11
P1
TERMINAL
BLOCK
ALPHACOM
No. Direction XE7 XE20/26
1 RM>ACE 30 A-B 2-3 31 a-b 1 a-b
ACE>RM 29 A-B 4-5 31 c-d 1 c-d
2 RM>ACE 28 A-B 6-7 32 a-b 2 a-b
ACE>RM 27 A-B 8-9 32 c-d 2 c-d
3 RM>ACE 26 A-B 10-11 33 a-b 3 a-b
ACE>RM 25 A-B 12-13 33 c-d 3 c-d
4 RM>ACE 24 A-B 14-15 34 a-b 4a-b
ACE>RM 23 A-B 16-17 34 c-d 4c-d
5 RM>ACE 16 A-B 22-23 35 a-b 5a-b
ACE>RM 15 A-B 24-25 35 c-d 5c-d
6 RM>ACE 14 A-B 26-27 36 a-b 6a-b
ACE>RM 13 A-B 28-29 36 c-d 6c-d

Audio links, EMC approved cabinets

CB901 Audio links, EMC approved cabinets.jpg


  • The audio link between the CB901 and the AlphaCom exchanges are made by means of an external 3 meter open-end subscriber cable type BF952. Identify the D-sub connector on the exchange rear coming from the NFE1545 board in pos. no. 11.
    See section Audio for complete interconnection cable table.
LINK CABLE ALPHACOM
No. Direction Color w.1 Color w.2 Pair no. XE7* XE20/26*
1 AC>RM   White   Blue 1 31 a-b 1 a-b
RM>AC   White   Orange 2 31 c-d 1 c-d
2 AC>RM   White   Green 3 32 a-b 2 a-b
RM>AC   White   Brown 4 32 c-d 2 c-d
5 AC>RM   White   Grey 5 33 a-b 3 a-b
RM>AC   Red   Blue 6 33 c-d 3 c-d
4 AC>RM   Red   Orange 7 34 a-b 4 a-b
RM>AC   Red   Green 8 34 c-d 4 c-d
5 AC>RM   Black   Blue 11 35 a-b 5 a-b
RM>AC   Black   Orange 12 35 c-d 5 c-d
6 AC>RM   Black   Green 13 36 a-b 6 a-b
RM>AC   Black   Brown 14 36 c-d 6 c-d

See section Audio interlinks, AlphaCom XE side for AlphaCom XE connection terminals.


Audio interlinks, AlphaCom XE side

  • Connect the 12-pair twisted cable from the non EMC CB901 cabinet to the AlphaCom XE terminals. Make a coding table for connection on both sides.

Or

  • Connect the 20-pair cable from the EMC CB901 approved cabinet to the AlphaCom XE terminals. See table in section 3.3.7 for wire pair color coding
  • The a and b wires are audio FROM AlphaCom XE
  • The c and d wires are audio TO AlphaCom XE

These lines are balanced; the twisted pairs may be connected either way.


Audio links, AlphaCom XE7

CB901 Audio links, AlphaCom E7.jpg


Even if the AGA board can be placed in any subscriber board position, it is good practice to choose slot no. 6 (line no. 31-36).

The audio connection to CB901 is made by six 4-way plug-on screw terminals, one link per terminal.


AlphaCom XE20 and XE26

CB901 AlphaCom E20 and E26 .jpg


Use the same filter board with cable and connection board as the ASLT Subscriber Board.

The connection board has six 4-way push-on terminals marked 1-6 corresponding to the link numbers.


PROGRAMMING

The programming procedures in this chapter will only concentrate on the procedures concerning the interface between Ring-Master CB901 and AlphaCom XE. Further instructions are found in the system programming manuals.

Purpose of programming

Individual programming will be carried out in each system via a locally connected data terminal (laptop).

Note: One system cannot be programmed from the other.
  • Set the data of the serial port used for CB901
  • Identify the 6 hex positions where the NFE1545 board is connected
  • Identify the CB901 stage(s) where the interlink NFE1545 board(s) is(are) installed
  • Specify the communication via the SIO port in CB901
  • Remote dialing for connection of privacy test station positions
  • Remote dialing for cancelling the privacy test connection
  • Remote dialing for call request camp-on to a program channel in CB901.
  • Remote dialing for program channel cancelling
  • Receive event for privacy time-out
  • Receive event for call button press (8 digit for identification of pager call)
  • Set the data of the serial port used for AlphaCom
  • Program the feature code for access to the numbers in AlphaCom XE. If the feature code is one digit (F), then a call to a number (AAA) in
    AlphaCom E will be F A A A
  • Select the four numbers used for privacy test

Programming CB901

  • Connect a PC to the D-sub in front of the RM CPU board NFE1683 via a crossed 3-wire D-sub cable.
CB901 Programming.jpg


  • Define the PC as a hyperterminal, Baud rate = 9600/8/n/1
  • Log in to the CB901 central by using the super-user command hPsaB

The super-user status is needed to adjust the two test timers later on in the process.

Ring-Master Configuration Commands

The CB901 system must be configured before the ETP feature can be executed. The configuration process is carried out through a number of SVT commands. See the SVT manual for details.

  • Start by un-define the line equipment positions where the ETP trunks will be connected. This is done with the SLEU command:
SLEU E0-E5
  • Continue to define which line equipment positions to be allocated as ETP trunk positions. This is done with the SETP command:
SETP 1 E0 <stage no>
SETP 2 E1 <stage no>
SETP 3 E2 <stage no>
SETP 4 E3 <stage no>
SETP 5 E4 <stage no>
SETP 6 E5 <stage no>
  • Define which first digit(s) to be used as ETP call number(s). This is done via the two commands, SCDU and SFC.
    In this example 7 is used as first digit in the call numbers in AlphaCom XE (ETP).
  • Un-define 7 as first call digit for normal calls:
SCDU 7
  • Define 7 as feature code for ETP. The feature ID numbers reserved for ETP are from 81 until 89.
    In this example we will only define ETP call digit for feature ID 87:
SFC 87 7

(87 is selected just to make it easier to remember the call number 7).

The call number series starting with 7 as first digit has been programmed to be associated with the ETP trunks.

All numbers starting with 7 will now be in the AlphaCom XE. The call numbers must have a total of 4 digits (7xxx).

  • Define which of the Ring-Master call numbers shall be able to make ETP calls (calls into the AlphaCom XE system). Use the SFA command to give access to dial feature code 7 (feature ID 87):
SFA 1000-1999 87 +

All stations in the range of 1000-1999 can call in the example above.

Refer to the SVT programming manual for general configuration of the Ring-Master CB901 system.

Privacy test call numbers SIO

CB901 Privacy test.jpg


This position (call number) will be used by AlphaCom XE to call the stations in CB901. This must be programmed with privilege no.20, ‘Remote dial receive’.

The remote dialing in CB901 via the SIO port is automatically controlled by the RM Daemon in AlphaCom XE.

The disconnect event must programmed for both the SIO number C (A side, event 12) and the called number D (B side, event 64). Please see Privacy Test explanation in section RMD Privacy links and Subscriber board modification in Subscriber boards.

SPT  20 +

( 20 is ‘Remote dial receive’ )

SSE  12,64 +
  • These events must now be programmed into all RM stages by the command Set Status Output:
SSO <event no.12> <stage no.> <output to PC port><stage where the PC port is used><stop>


Example

Stage 1:
SSO 12 1 C 1 U        Disconnect C (SIO)
SSO 64 1 C 1 U        Disconnect D
Stage 2:
SSO 12 2 C 2 U        Disconnect C (SIO)
SSO 64 2 C 2 U        Disconnect D
Stage N:
SSO 12 N C 2 U        Disconnect C (SIO)
SSO 64 N C 2 U        Disconnect D

These events are used to ensure complete cancellation of the audio link when a called Ring-Master station (D) presses the X button, or automatic reset at timeout.

  • Program Group Call using the following commands:
SGCN:           Program the call number for each group. 

These numbers shall also be programmed into the RMD WEB interface in AlphaCom XE in order to set the relation between the internal groups in CB901 and the global group numbers in AlphaCom XE.

SGCM:           Program the receivers in each group in CB901.
SPT:            Privilege to manage Group Call and All Call

Adjust test timers no. 1 and 2

  • First check the settings via the command LTT.
    The value should be 70 (7 seconds) for both timers:
LTT
Time id <1,-,50/*> 1,2
Time ID Timer Current time
1 ETP heartbeat timeout 70
2 Wait for ETP answer 70
  • Use the command STT to correct the values if they are different from 70.

CB901 communication serial port

As default there is only one serial port available in each CB901 stage for communication with AlphaCom. This is port 4, which is programmed to support Pocket Paging as default

This port must be re-programmed to support the ETP.

Note: The setup procedures for a single stage CB901 and a multi stage CB901 are different


CB901 single stage

  • Program port 4 to be ETP via the SD command
  • Program the communication data for port 4 via the command STTY and select E for ETP.
  • Specify the following:
Baud              : 9600
Bits              : 8
Parity            : N
Stop bits         : 1


CB901 Multi stage

  • Use the command STTY, and select P for Pager.
  • Specify the following:
Baud       : 9600
Bits       : 8
Parity     : N
Stop bits  : 1
  • Use the command SD (Set Driver) to change port 4 from Pager to ETP.
  • Use the command LTTY to verify that the ETP is now identified for port 4 with the data: 9600/8/N/1.
Note: The data for port 4 cannot be changed when the driver is specified for ETP. In order to modify the data you must re-define port 4 as Pager port via the command SD.

Programming in AlphaCom XE

Configuration programs

The AlphaCom XE configuration is partly made from AlphaPro and partly from the embedded Web browser AlphaWeb.

The configuration includes the following steps:

AlphaPro:

  • Create virtual Ring-Master node(s) which defines a data link between the AlphaCom XE node and the virtual Ring-Master node (RMD)
  • Create AlphaCom XE <-> Ring-Master audio links
  • Create RM call numbers as Global numbers
  • Call Request
  • Group Call
  • Update the exchange

AlphaWeb:

  • Insert license for the Ring-Master interface
  • Configure the virtual Ring-Master node

AlphaPro configuration

AlphaPro is an off-line tool used to configure AlphaCom XE. All parameters can be entered without being connected to the exchange. Once all parameter are entered, AlphaPro can be connected to the exchange and the parameters can be sent. AlphaPro can also upload configuration information from an exchange.

See the AlphaCom XE technical manual “Alphacom XE Installation, Configuration & Operation” A100K10805 for further programming procedure.

Connect a PC to the exchange

Insert the HW dongle

  • Insert the hardware dongle in the PC’s USB port.
  • Leave the dongle in the PC during programming and transferring of data to the exchange.

Ethernet connection

AlphaProConnection 1.png


AlphaCom XE exchanges communicate with the AlphaPro PC over the IP network. Eth0 is the default management port unless the configuration has been changed.

When the AlphaPro communication icon is pressed, AlphaPro will prompt you for user name and password before login to the AlphaCom.

Create RM-ACE network

From the AlphaPro Main Menu:

  • Press the ‘+’ button next to ‘Select Network’
Select Network 1.PNG


  • Give the network a name, i.e. “AC-RM”
  • Give the first exchange a name, i.e. “AlphaCom”
  • The ‘Node Number’ shall be “1”
  • Be sure the ‘AlphaNet Adm. Here’ check box is ticked
  • The default IP address 169.254.1.5 is used when the AlphaWeb PC is connected directly to the AlphaCom XE node on the Eth0 port. If a remote PC is connected via a network for AlphaWeb programming, this address must be changed. Contact the IT administrator to get this address.
Create RM AC Node 1.PNG


Note: Make a note of this IP address as it must be entered manually in AlphaWeb!
  • Click [OK] to confirm
    The new network name will appear in the ‘Select Network’ pull-down list and the given exchange name is automatically put in the ‘Select Exchange’ pull-down list.

Create virtual Ring-Master node(s)

From the AlphaPro Main Menu:

  • Press the ‘+’ button next to ‘Select Exchange’
Select Network 1.PNG


  • Type the name of the new RM node i.e. “RM Node 101
  • Type in the node no. i.e. “101
  • Select [Ringmaster Node] from the ‘Type’ list
  • Leave the [Adm. Here] flag unchecked
Create Virtual RM Node 1.PNG


Note: The Ring-Master node must be assigned a higher node number than the AlphaCom node. Suggested node number is 101.

In Ring-Master systems consisting of two or more stages, you need to create more Ring-Master nodes in order to have more audio lines. Each NFE1545 / AGA board connection is considered one node.

Create the second Ring-Master node in the same way as the first, but with node number 102 and so on.

Define the data- and audio link

  • Select [Exchange & System] in the Main Menu
Menu 1.PNG


  • Select [AlphaCom] in the ‘Exchange Information’ window
  • Select [Net Routing]
Exchange Information 1.PNG


  • Select [Insert]
NetRouting 1.PNG


  • Select the new ‘RM node’ and click the [Select] button
NetRouting 2.PNG


  • Select [RMD link] from the ‘Primary route’ Data ACDP link
NetRouting 3.PNG


  • The audio should be on node number ‘101’
  • Click [OK] to save the record
  • Click the [Close] button to get back to the Main Menu

Create AlphaCom / Ring-Master audio links

  • Select [Exchange & System] in the Main Menu
  • Select [AlphaCom] in the ‘Exchange Information’ window
  • Select [Net Audio]
NetAudio 1.PNG


  • Select [Insert]
NetAudio 2.PNG


  • Check that Ring-Master is the destination node and click on [Select]
NetAudio 3.PNG


  • Enter the AGA board physical link number and a channel number starting from ‘1’ on the first link, ‘2’ on the second link and so on
NetAudio 4.PNG


  • Repeat this operation until all audio links are defined
    Example: An XE7 has two AGA boards in pos. 5 and 6. The first physical link number is (4x6)+1=25 and the last link number is 36.
  • Click [OK] to save the record
  • Click the [Close] button to get back to the Main Menu

Tone test

The AGA audio links are by default supervised by a test tone transmitted on the line at regular intervals.

As this test is not supported when interfacing to the Ring-Master system, the test must be disabled to prevent the links from being taken out of service.

  • Select [Exchange & System]
  • Click on [System]
System 1.PNG


  • Select [Logs and Errors]
  • Check that [Enable Tone Test] is NOT checked
  • Set [Audio Test Period] to 65 535 (= Test OFF)
Logs and Errors 1.PNG


The audio links require further configuration from the RMD configuration page in AlphaWeb.

Create Ring-Master station numbers

All station numbers in the Ring-Master system which should be accessed from the AlphaCom XE must be programmed in the AlphaCom directory table (Directory & Features) with feature 083 (Global numbers) and ‘Node’ = Ring-Master node number (e.g. 101).

In the example below, the station number 1258 is defined as Global Number for AlphaNet, feature 083. The display text will be shown in the AlphaCom station when calling the RM station. This text should be coordinated with the RM systems caller ID text for that RM station.

  • Click on [Directory & Features] in the main menu
Menu 2.PNG


  • Select feature 83 ‘Global Number for AlphaNet’ in the [Feature] pulldown list
  • Type the RM node number (‘101’) in the [Node] field
  • Type the RM call number in the [Directory Number] field
DirNo 1.PNG


  • A warning may appear if the selected number already exists, or if the number is masked by existing numbers. In this case directory number 125 must be deleted.
DirNo Masking.PNG


  • Type in the text which will be visible in the display of the calling AC station in the [Display Text] field
  • Click [OK]. The new global number will be updated in the table on the left

Repeat this procedure for each RM number to be defined in AlphaCom

Further configuration of the call numbers is required from the RMD configuration page in AlphaWeb.

AlphaCom station numbers

All station numbers in the AlphaCom XE which should be accessed from the Ring-Master system must be assigned a 4-digit directory number in AlphaCom (Users & Stations). First digit must be the feature code 7 as programmed in RM.

Note that there are a number of standard feature codes in the AlphaCom starting with digit 7, e.g. 70 (Station reset) and 71 (Call forwarding). These codes will mask any station numbers starting with the same digits. For example 70 will mask for all stations in the range 70xx, 71 will mask all stations in the range 71xx, and so on. When a station number is masked by a feature code it will not be possible to call the station. In this case the feature codes must be changed. It is recommended to put a one-digit in front of the standard number, i.e. change 70 to 070, 71 to 071 and so on.

Call Request group numbers

When the “CAS” function is wanted in the Ring-Master system, it must be converted to generate a Call Request to a group in AlphaCom XE. This “group” should include one or several guard station(s) to receive call request calls from RM as well as AC stations.

The directory no. of the group used for Call Request must be 4 digits and the first digit must be feature code 7 as programmed in RM.

Since Ring-Master has 64 group-call groups numbered from 1 - 64, groups from 65 - 100 should be used in AlphaCom XE for Call Request.

In the example below, the group 65 is used for call request and the directory number for this group is 7211.

  • Select [Groups], then [Local Groups]
Menu 3.PNG


  • Scroll down and select [Station Group 65]
GroupCall 1.PNG


  • Click on [Change]
  • Type the Call Request call number in the [Directory Number] field
  • Type in the display text in the [Display Text] field
GroupCall 2.PNG


  • Click on the [Members] field. This will be the guard stations (RM CAS operators)
GroupCall 3.PNG


  • Select the guard stations to be included in the group from the ‘Not Member’ list, and transfer to the ‘Members’ list
  • Click [OK]

Group Call numbers

In order to make Group Call in both RM and ACE simultaneously, the Global Group numbers must be specified. Follow the same routine as described for Call Request group numbers.

DTMF from AlphaCom XE to CB901, pulse operation

This is used for e.g. Door Opening Control.

Set the Door Open button

  • Click on [Directory Numbers & Features] on the main menu.
  • Click on [Insert]
  • Select feature 107 ‘DTMF during connection’ from the [Feature] pulldown list.
  • Type “5” in the ID field.
    This is the DTMF ID to be used. (Any digit from 0-9 may be used)
  • Type “6” in the [Directory Number] field.
    This is the button to be pressed during conversation

Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.

Duplicate directory number


  • Type “Open Door” in the display text field
DirNo DTMF 1.PNG


  • Click [OK] and [Close]

Adjust the DTMF pulse time

  • Select [Exchange & System] from the main menu
  • Click on [System]
  • Select [Timers]
  • Check that [RCO Pulse (Door Open) Time] is set to default 35 (3.5 sec.)
Timers 1.PNG


  • Click [OK] and [Close]

DTMF from AlphaCom XE to CB901, continuous

This will transmit a DTMF signal as long as a station button is pressed.

  • Click on [Directory & Features] on the main menu
  • Select feature ‘107 DTMF During Connection’ from the [Feature] pull-down list.
  • Click on [Insert]
  • Type “255” in the ID field
    This indicates that the digit specified below will enable the Continuous DTMF feature
  • Type “6” in the [Directory Number] field
    This is the button to press during conversation to enable continuous DTMF transmission
Note: A “Duplicate Directory Number” warning will appear. Answer “Yes”. It is then not possible to open doors with AlphaCom door stations.
Duplicate directory number


  • Type “Open Door” or actual initiated function in the display text field
DTMF 1.PNG


  • Click [OK] and [Close]

Any number key pressed after 6 will result in a continuous DTMF signal as long as the key is pressed. The DTMF signal will correspond to the depressed number key.

Update the exchange

  • Log on to the exchange and update the configuration by pressing the [SendAll] button. When the transfer is finished, the AlphaCom XE must be reset by activating the [Reset] button in the communication window.

AlphaNet

When there are several AlphaCom exchanges connected in a network (AlphaNet), the Ring-Master node will be related to one of these AlphaCom nodes. The other AlphaCom exchanges need to have routing information to the Ring-Master node.

When defining the data- and audio routing from a remote AlphaCom to a Ring-Master node, the AlphaCom node related to the Ring-Master node must be defined as a transit node.

Example:

The Ring-Master node is 101 and related to AlphaCom node 1.

A remote AlphaCom node 2 is connected in AlphaNet with AlphaCom node 1.

The routing from node 2 to the Ring-Master node 101 must go transit via node 1.

AlphaNet 1.PNG


Configuration from AlphaWeb

Connect to AlphaWeb

  • Connect the PC Ethernet port to the LAN port (Eth0) on the AMC-IP filter board.
CB901 Alpha Web.jpg


  • Use your web-browser to connect to the AlphaWeb. Enter http://169.254.1.5 (default address) in the address field1 Connection with the AMC is verified by the text: [Login] AlphaWeb
Note: This IP address must be entered manually in AlphaWeb.
  • Click on [Login]

User is prompted for user name and password

Login 1.PNG


Default user name: alpha
Default password: com

This login will give reading rights only.

To be able to change the configuration, the user must log in as an administrator. The default login will then be:

User name: admin
Password: alphaadmin

See further details on AlphaWeb in the AlphaCom XE technical manual A100K10805.


Insert license for Ring-Master

Log on to AlphaWeb and install the license to enable the Ring-Master interface.

  • Select [System Configuration] then [Licensing]
  • Input the RM license key string under [New License Key]
License 1.PNG


  • Press the [Insert new License Key] button
  • Verify that the license has become active in the License Configuration field
License 2.PNG



Configuration of the virtual Ring-Master node

  • Log on to AlphaWeb and select the [RM Configuration] page. The parameters for the Ring-Master node are configured from this page, such as:
  • RMD general parameters
  • Trunk lines
  • Call numbers
  • Group calls
  • Privacy links
  • Call Request groups
  • Click on [External Systems] and then select [RingMaster]
RMd 1.PNG


RMD General Parameters

  • Select [General Parameters]
RMD General Parameters


  • Specify the AMC Node no.
  • Specify the RMD Node no.
  • Specify the RM Master Node where the ETP link is connected (Example: “101”)
  • Specify the program distribution channel were the call request stations are camped on. This is a global PD channel for all stages within node 101.
  • Specify the AC Group-Call mode
    1 = No ‘gong’ in AC. 2 = ‘Gong’ in AC stations
  • Specify the Group Call length plus 5 - 10 seconds (more than the time set in CB901).
  • Press [Save] to save the changes

RMD Trunks

  • Select [Trunks]
RMD Trunk


  • Specify the numbers for the RM Trunks (NFE1545) and AGA trunks.
  • Press [Save] to save the changes

In this example there is 1 x AGA board in the AlphaCom XE.

AGA no.1 is connected with 6 trunks to the one NFE1545 in CB901 and these 6 trunks are identified as trunk 1 - 6 in RM node 101.

RMD Call Number Configuration

  • Select [Call Numbers]
  • Select the RMD node to be configured

RM call numbers for the selected node are already programmed in the AC via AlphaPro and listed in the left column.

RMD Call Number Configuration


The features for each station are specified in the following columns:

  • Normal.

Station to station direct call with transfer of display information only

  • Call Request.

The station shall make a call request (CAS) to an AC station. The station will be camped on to the globally programmed program distribution channel in CB901.

  • Specify if the stations shall be tested for privacy after Call Accept
  • Specify the time-out in minutes for queuing (Auto cancel if not accepted)
  • Specify if the calling station shall be removed from the call request queue after time-out.

If the [Cancel] field is not marked, the calling stations ID will be present in the guard stations display as an indication on who has called.

  • Privacy.
    The station shall be tested for privacy. This requires that there are at least two subscriber positions linked together for indirect privacy testing via remote dialing.
  • Press [Save] to save the changes

RMD Global Groups

Use global groups 1 - 64 in order to match the corresponding groups in CB901.

If more groups are required, the new groups must be specified via AlphaPro and SVT.

All Group Call numbers programmed in AlpaCom via AlphaPro are listed in the left column.

RMD Global Groups


  • Specify the corresponding RM Group Call number which is already programmed in CB901 via SVT
  • Press [Save] to save the changes

RMD Privacy links

RMD Privacy Links


  • Specify the loop connection between two subscriber positions in CB901 which will be used for the privacy test. All stations programmed to be tested for privacy will use the above specified link.

The number of specified links depends on the expected traffic. The calling AC station will receive a reject signal when no more “privacy test links” are available.

CB901 RMD Privacy links2.jpg
  • Privacy test link #1 is specified to be between B and C.
  • An AC station is calling the RM Station at D, which is specified to be privacy tested.
  • The RMD (Ring-Master Daemon) will make a connection between A and B via the ETP link, and one connection between C and D via remote dialing in the SIO port.
  • Position C has been programmed for “Remote Dialing Receive” via SVT.
  • If the RM station is in privacy, then the privacy tone will be transmitted to the calling AC station via the B-C link. The RMD in AC will select the first free link if more links are specified.


In a multi stage CB901 system there must be one privacy test subscriber board in each stage. The stations in each stage, which shall be tested for privacy, will use the privacy test positions in the local central.

See section Privacy test call numbers SIO on how to set Privacy test numbers and section 6.2 for Subscriber board modifications.

RMD Call Request Groups (CAS)

  • Specify the ETP call number to the group in AC where the guard stations are connected. The guard stations are programmed as members in these groups via AlphaPro.
RMD Call Request Groups


  • Press [Save] to save the changes
Note icon A save should be performed in every RMD menu, even if there is no programming done in that RMD menu.


Note icon The AlphaCom exchange must be reset after any change in the RMD configuration pages.


AUDIO LEVEL ADJUSTMENT

Audio switching control

There is no transfer of switching control signals between the AlphaCom and CB901. The audio switching is controlled locally in each system in both simplex and duplex.

Adjustment procedure

The audio transmit level in AlphaCom XE is fixed and cannot be adjusted. The receive level is adjusted by potentiometers on the AGA board.

The following procedure describes how to adjust the audio level between the audio interface board NFE1545 in the CB901 exchange and the AGA board in the AlphaCom XE exchange.

The NFE1545 board has 8 audio channels, but only the first 6 are used when communicating with the AGA board.

A DTMF signal generated in AlphaCom XE will be used as reference.

The adjustment has to be carried out on all new installations as a part of the commissioning procedure.

The AlphaCom XE exchange should be installed in the same room as the CB901 node where the audio interface board NFE1545 is located in order to simplify the adjustment.

AlphaCom XE level adjustment

Re-define the function of 6 audio ports in the AGA board using AlphaPro in order to perform a loop test. This test uses a tone generated internally in the AGA board. The input sensitivity of each AGA audio channel can now be adjusted by means of potentiometers on the AGA board.

The output level is fixed and cannot be adjusted.

Information in the display of the AlphaCom “super user” station (the first line point in AlphaCom XE) will be used as a reference for correct adjustment of the input level potentiometers.

When all channels are adjusted, the AlphaPro program must be used in order to set the audio channels back to “default”.

Note: This adjustment must be carried out on all new installations.
Note: The cable between the AGA board and the NFE1545 board must be disconnected during the adjustment.
  • In AlphaPro select [Exchange & System].
  • Select [Board]
Board 1.PNG


  • Click on the board number for the AGA board you want to adjust.
  • The AGA board no. is given by the board location in the cabinet.
  • In ACE7, start counting from the lower part of the cabinet.
  • The six ports from 2 until 7 on each installed AGA board are used.
  • Start by selecting [port 2] for the installed AGA board to adjust the input from link 1 until 6.
  • Select [Change]
Board 2.PNG


  • In the field [Port use], select [5 Gain adjust (Group call)] and press [OK]
  • Repeat the procedure until all 6 AGA channels are changed (port 3, port 4, etc.)
gain ajust


Adjusting the audio potentiometers 3, 5, 7, 9, 11 and 13.

CB901 AGA board.jpg


  • Dial 7872 from the Super User station and monitor the information in the stations display.
  • Station key 7: Scroll DOWN
  • Station key 9: Scroll UP
  • Adjust the potentiometer indicated in the display until “Full volume level” and “Attenuated volume level” is the same value.
Adjusting the Audio


  • After the adjustment is finished the [Port use] must be set to [Default] again via AlphaPro.


Note: During this test the output links are programmed as inputs and pot. meters 4, 6, 8, 10 and 12 will adjust the input level for thesereversed links.
This function is not used when interfaced to CB901, and you can disregard the adjustment of these pot.meters. This function is used when the AGA board is operating as an audio program (music) interface with only inputs.

Ring-Master level adjustment

The amplification in each channel on the audio interface board NFE1545 must be adjusted with the potentiometers R118-R618. VR1 is a common potentiometer for output adjustment of all 6 channels.

CB901 Ring-Master level adjustment.jpg


The DTMF audio reference signal is generated in AlphaCom XE. See section 4.4.12 for instruction on how to program AlphaCom to transmit DTMF.

Select one Ring-Master and one AlphaCom master station situated close to the test site to perform the adjustment.

Use oscilloscope or electronic multi-meter to read the values.

Adjustment procedure, audio from AlphaCom XE to Ring-Master

  • Connect the instrument to the RM station audio line, screw terminals 4 and 5 in the RJ45 wall socket.
  • Make a call from the RM station to the AC station.
  • Press and hold the M key (microphone mute) in the RM station
  • Press the digit 5 key while the M key is depressed.
  • Check the signal level on the audio-pair from the RM station.
  • Note this value as the RM reference signal (Ref.level 1).
  • Make a call from the AC station to the RM station.
  • The selected audio channel is identified by the LED’s in front of NFE1545.
  • Press the digit 6 key in the AC station.
    This will result in a 5 sec. DTMF #5 pulse transmitted to the RM station.
  • Adjust the actual channel potentiometer (R118-618) until you read the same line level (Ref.level 2) as noted for Ref.level 1.
  • It may be needed to repeat the reading by pressing digit 6 again. The channel will not change as long as the station is not reset.
CB901 RM station audio line.jpg


  • Make a new call from the AC station to the RM station.
    The next channel will automatically be selected.
  • Repeat the adjustment (Ref.level 2 = Ref.level 1) for all 6 channels.


Adjustment procedure, audio from Ring-Master to AlphaCom XE

CB901 audio from Ring-Master to AlphaCom E.jpg


  • Connect the instrument to the a-b wire on the Channel 1 line between the AGA and NFE1545 boards on the AlphaCom XE side.
  • Make calls from AC to RM until Ch. 1 is selected.
  • Press the digit 6 key in the AC station and measure the DTMF #5 pulse level (Line level 1).
  • Move the measuring instrument to the c-d wire on the Channel 1 line between the AGA and NFE1545 boards on the AlphaCom side.
  • Make a call from the RM station to the AC station.
  • Press the M (mute) and digit 5 key on the RM station, thereby transmitting DTMF #5 to the AC station.
  • Adjust VR1 on the NFE1545 board until Line level 2 is the same as Line level 1.
    This is a common adjustment of the audio level from RM to AC for all six audio channels.
CB901 audio from Ring-Master to AlphaCom E2.jpg


MODIFICATIONS IN THE CB901 EXCHANGE

A hardware modification must be carried out on one subscriber board and on the processor board, depending on system configuration and feature programming.

Processor board

The board may need a modification in order to convert one current loop port to RS232 as two serial ports are needed for interconnection to AlphaCom XE.

  • The ETP port is used for normal dialing and display information
  • The SIO port is used for remote dialing

Modification IS NOT necessary in:

  • Single stage exchange with no display stations. The central is delivered before 1995 and has not been modified to use display stations. See section 3.3.4
  • Multi stage exchange with or without display stations. If the system is using display stations, the serial port 4 in stage 1 and 2 will be used for interface.


Modification IS necessary in:

  • Single stage with display stations.


Modification procedure, NFE1683

Modify data port no.1 from current loop to RS232.

Remove

  • IC U39
  • IC U40
CB901 Modifications in the CB901 exchange 1.jpg


Cut one track on the PCB component side

  • Cut connection between pin 1B and 3B on plug P2

Indicated by a circled X in the above image

Cut 4 tracks on the PCB solder side

Marked with circled X's in the below image

  • Connection to U34 pin 2
  • Connection to U34 pin 3
  • Connection to U32 pin 4
  • Connection to U32 pin 6
CB901 Modifications in the CB901 exchange 2.jpg


Mount 6 straps on the PCB solder side

As indicated with yellow wires in the above image

  • Between U34 pin 3 and connector P2 pinA1
  • Between U34 pin 2 and U29 pin 30
  • Between U32 pin 4 and connector P2 pin A2
  • Between U32 pin 6 and U29 pin 31
  • Between P2 pin B2 and U16 pin 7 (-5 VDC)
  • Between P2 pin B1 and D1 cat. (+5 VDC)

Subscriber boards

Two and two subscriber positions must be looped in order to create 4 privacy test links for the RM-ACE interface. This must be done on one subscriber board in each CB901 node in a RM system. If 4 privacy links are not sufficient, a second subscriber board must be modified in each central.

Positions 1-2, 3-4, 5-6 and 7-8 will be strapped.

The board can be plugged into any valid subscriber board position in the central, and the corresponding HEX address for each position must be programmed with individual call numbers.

  • ETP numbers are programmed for positions 1, 3, 5 and 7
  • SIO numbers are programmed for positions 2, 4, 6 and 8

Each ETP number is linked to one corresponding SIO number.

Stations can not be connected to these modified subscriber boards.


Modification procedure, NFE1813

Cut one track on the PCB solder side

  • Cut connection between pin 2 and 3 on U4

Mount 9 straps on the PCB solder side

  • U4 pin 2 and U4 pin 7
  • U102 pin 7 and common point for R222/R223/C223
  • U202 pin 7 and common point for R122/R123/C123
  • U302 pin 7 and common point for R422/R423/C423
  • U402 pin 7 and common point for R322/R323/C323
  • U502 pin 7 and common point for R622/R623/C623
  • U602 pin 7 and common point for R522/R523/C523
  • U702 pin 7 and common point for R822/R823/C823
  • U802 pin 7 and common point for R722/R723/C723
CB901 Modifications in the CB901 exchange 3.jpg


Modification procedure, NFE1625

PCB solder side

  • Cut the track between pin 2 and 3 on U4
  • Mount one strap between U4 pin 2 and U4 pin 7
CB901 Modifications in the CB901 exchange 4.jpg


PCB component side

There are 8 identical circuits that need a modification.

  • Remove 8 capacitors: C110, 210, 310, 410, 510, 610, 710 and 810.
  • Unsolder the lower leg on 8 capacitors: C109, 209, 309, 409, 509, 609, 709 and 809.
  • Solder a strap between the free leg on the Cx09 capacitors and pin 9 on the Ux02 ICs in the following way:
CB901 Modifications in the CB901 exchange 5.jpg
  • - C109 to U202
  • - C209 to U102
  • - C309 to U402
  • - C409 to U302
  • - C509 to U602
  • - C609 to U502
  • - C709 to U802
  • - C809 to U70


APPENDIX

Equipment List

The following equipment is required for the interconnection between CB901 and AlphaCom XE.

Ring-Master CB901

Basic board rack DP979 (Not EMC)

1 x NFE1545 Interlink B board including 8 audio lines. 6 lines will be used for audio communication with the AGA board in AlphaCom XE
2 x BF927 Interconnection cables for audio and serial data.

OR


Basic board rack DP991 (EMC approved)

1 x NFE1545 Interlink B board including 8 audio lines. 6 lines will be used for audio communication with the AGA board in AlphaCom XE
1 x BF950 Internal cable for audio from NFE1545
1 x BF957 Internal RS232 cable
2 x BF951 EMC filter
2 x BF952 3 m external cable for audio and serial data

STENTOFON AlphaCom XE

AlphaCom XE7

1 x 1009608100 XE7 package including 1 x ASLT line boards
1 x 2030010270 Mains transformer
1 x 1009501100 Connection kit ASLT/AGA
1 x 1009303001 AGA board for 6 audio channels
1 x A100A08010 RJ45 – 9-pin D-sub Serial Cable Adapter

OR


AlphaCom XE20

1 x 1009621000 XE20 exchange including 2 x ASLT line boards
1 x 1009303001 AGA board for 6 audio channels
1 x 1009501021 Filter board with 5 m connection cable

OR


AlphaCom XE26

1 x 1009627000 XE26 exchange including 2 x ASLT line boards
1 x 1009303001 AGA board for 6 audio channels
1 x 1009501021 Filter board with 5 m connection cable

AND


License

1 x 1009649001 License key; will enable the communication between CB901 and AlphaCom XE

Interconnection cable, EMC cabinet

The cable is a 20-pair twisted telephone cable with a 37-pin D-sub connector in one end and loose wires in the other.

CB901 Interconnection cable.jpg


Two types are available:

BF952 External RS232/Subscriber cable, 3 m
BF952A External RS232/Subscriber cable, 10 m

Data

This cable is used to transfer data between CB901 EMC board racks and AlphaCom XE exchanges. See actual interconnection in section ETP data link and SIO data link, EMC approved cabinet

Port #1 is converted to RS232 for SIO data if display stations are used, see section Processor board

The IEC color coding standard is used for wire pair identification.

PAIR
no
COLOR
A-wire
D-sub
PIN no.
DATA
signal
COLOR
B-wire
D-sub
PIN no.
DATA
signal
FUNCTION
 
1   WHITE 1 RTS   BLUE 20 CTS PORT #5
Service terminal RS232
(SVT) Fixed
2   WHITE 2 RX   ORANGE 21 GND
3   WHITE 3 TX   GREEN 22 DTR
4   WHITE 4 RTS   BROWN 23 CTS PORT #6
Printer RS232
Fixed
5   WHITE 5 RX   GREY 24 GND
6   RED 6 TX   BLUE 25 DTR
7   RED 7 RTS   ORANGE 26 CTS PORT #4
Radio paging RS232
8   RED 8 RX   GREEN 27 GND
9   RED 9 TX   BROWN 28 DTR
10   RED 10 RTS   GREY 29 CTS PORT #3
Display driver
11   BLACK 11 RX   BLUE 30 GND
12   BLACK 12 TX   ORANGE 31 DTR
13   BLACK 13 RX+   GREEN 32 RX- Serial input 20 mA current loop
14   BLACK 14 TX+   BROWN 33 TX- Serial output 20 mA current loop
15   BLACK 15 RX+   GREY 34 RX- PORT #2
20 mA current loop
16   YELLOW 16 TX+   BLUE 35 TX
17   YELLOW 17 RX+   ORANGE 36 RX- PORT #1
20 mA current loop
18   YELLOW 18 TX+   GREEN 37 TX
19   YELLOW 19     BROWN NC    
20   YELLOW NC     GREY NC    



Audio

This cable is used to transfer 6 audio channels between CB901EMC board racks and AlphaCom XE exchanges. See actual interconnection in section Audio interlinks, CB901 side

The IEC color coding standard is used for wire pair identification.

PAIR
no
COLOR
A-wire
D-sub
PIN no.
COLOR
B-wire
D-sub
PIN no.
CABLE
FUNCTION
1   WHITE 1   BLUE 20 Out LINK #1
2   WHITE 2   ORANGE 21 In
3   WHITE 3   GREEN 22 Out LINK #2
4   WHITE 4   BROWN 23 In
5   WHITE 5   GREY 24 Out LINK #3
6   RED 6   BLUE 25 In
7   RED 7   ORANGE 26 Out LINK #4
8   RED 8   GREEN 27 In
9   RED 9   BROWN 28 NC  
10   RED 10   GREY 29 NC  
11   BLACK 11   BLUE 30 Out LINK #5
12   BLACK 12   ORANGE 31 In
13   BLACK 13   GREEN 32 Out LINK #6
14   BLACK 14   BROWN 33 In
15   BLACK 15   GREY 34 NC  
16   YELLOW 16   BLUE 35 NC  
17   YELLOW 17   ORANGE 36 NC  
18   YELLOW 18   GREEN 37 NC  
19   YELLOW 19   BROWN NC NC  
20   YELLOW NC   GREY NC NC  

Interconnection, non EMC cabinet

Data from the CPU board

Port #1 is converted to RS232 for SIO data if display stations are used, see section Processor board

CPU
pin no.
BLOCK
no display
BLOCK
display
Data
signal
CPU
pin no.
BLOCK
no display
BLOCK
display
DATA
signal
FUNCTION
 
27A 4 4 RTS 27B 5 5 CTS PORT #5
Service terminal RS232
(SVT) Fixed
26A 6 6 RX 26B 7 7 GND
25A 8 8 TX 25B 9 9 DTR
24A 10 10 RTS 24B 11 11 CTS PORT #6
Printer RS232
Fixed
23A 12 12 RX 23B 13 13 GND
22A 14 14 TX 22B 15 15 DTR
21A 16 16 RTS 21B 17 17 CTS PORT #4
Radio paging RS232
(ETP)
20A 18 18 RX 20B 19 19 GND
19A 20 20 TX 19B 21 21 DTR
18A NC NC RTS 18B NC NC CTS PORT #3
Display driver
(SIO)
17A 22 NC RX 17B 23 NC GND
16A 24 NC TX 16B 23 NC DTR
7A-15A     - 7B-15B     - NC
6A NC 30 RX+ 6B NC 31 RX- Serial input 20 mA current loop
5A NC 32 TX+ 5B NC 33 TX- Serial output 20 mA current loop
4A NC 34 RX+ 4B NC 35 RX- PORT #2
20 mA current loop
3A NC 36 TX+ 3B NC 37 TX-
2A NC 38 RX+ 2B NC 39 RX- PORT #1
20 mA current loop (RS232/SIO)
1A NC 40 TX+ 1B NC 41 TX-

Audio from the Audio Interface board

See also section Audio interlinks, CB901 side


BOARD11
P1
TERMINAL
BLOCK
BOARD11
P1
TERMINAL
BLOCK
CABLE
DIRECTION LINK
31A-32A NC 31B-32B NC    
30A 2 30B 3 Out LINK #1
29A 4 29B 5 In
28A 6 28B 7 Out LINK #2
27A 8 27B 9 In
26A 10 26B 11 Out LINK #3
25A 12 25B 13 In
24A 14 24B 15 Out LINK #4
23A 16 23B 17 In
21A-22A 18-20 21B-22B 19-21 - NC
17A-20A NC 17B-22B NC - -
16A 22 16B 23 Out LINK #5
15A 24 15B 25 In
14A 26 14B 27 Out LINK #6
13A 28 13B 29 In
7A-12A 30-40 7B-12B 31-41 - NC
1A-6A NC 1B-6B NC - -