Upload
zeu-silva
View
66
Download
3
Embed Size (px)
Citation preview
nten
ts
AMENDMENTS ................................................................................................2
PREFACE...........................................................................................................3
1. INTRODUCTION ............................................................................................4
2. ANALOGUE LINE CIRCUITS .........................................................................5
2.1. ALC-A/B ..................................................................................................................... 52.2. ALC-E ......................................................................................................................... 52.3. ALC-F ......................................................................................................................... 72.4. ALC-G ...................................................................................................................... 102.5. ALC-GP .................................................................................................................... 142.6. ALC-G(R) ................................................................................................................. 142.7. ALC-GM/GD ............................................................................................................ 15
3. KEY TELEPHONE LINE CIRCUITS ..............................................................18
3.1. KTLC01/02/03 .......................................................................................................... 183.2. KTLC-A/E ................................................................................................................. 22
4. DIGITAL LINE CIRCUITS ..............................................................................27
4.1. DLC-A/B/C/D ........................................................................................................... 274.2. DLC-U ...................................................................................................................... 284.3. DLC-I ....................................................................................................................... 304.4. DTX-I ....................................................................................................................... 324.5. DTX-I(R) .................................................................................................................. 374.6. DLX-U ..................................................................................................................... 394.7. DLX-L ...................................................................................................................... 41
5. ANALOGUE TRUNK UNITS ........................................................................43
5.1. ATU-SS ..................................................................................................................... 435.2. ATU-AS .................................................................................................................... 44
5.2.1. ATU-AS36 ................................................................................................... 455.3. ATU-EM ................................................................................................................... 47
5.3.1. ATU-EM (2-Wire) ........................................................................................ 485.3.2. ATU-EM (4 Wire) ........................................................................................ 575.3.3. ATU-EM-D .................................................................................................. 65
5.4. ATU-CH ................................................................................................................... 705.4.1. ATU-CH02 .................................................................................................. 71
5.5. ATU-LD0K ............................................................................................................... 725.6. ATU-PSI ................................................................................................................... 725.7. ATU-ST .................................................................................................................... 75
5.7.1. ATU-ST02/12 .............................................................................................. 75
i
Tab
le o
f Co
ii
Table of C
ontents
5.7.2. ATU-ST03 ....................................................................................................765.7.3. ATU-ST26 ....................................................................................................79
5.8. ATU-IL ......................................................................................................................825.8.1. ATU-IL01/IL03/IL13/IL31 .............................................................................825.8.2. ATU-IL23 .....................................................................................................83
5.9. ATU-LB .....................................................................................................................855.9.1. ATU-LB12 ....................................................................................................88
5.10. ATU-G ......................................................................................................................885.10.1. ATU-G2 ........................................................................................................925.10.2. ATU-G3 ........................................................................................................935.10.3. ATU-G4 ......................................................................................................1005.10.4. ATU-G5 ......................................................................................................1015.10.5. ATU-G6 ......................................................................................................1025.10.6. ATU-Gx Board layout ................................................................................103
6. DIGITAL TRUNK UNITS ............................................................................107
6.1. DTU-CC .................................................................................................................1076.2. DTU-CA .................................................................................................................1096.3. DTU-PR ..................................................................................................................1116.4. DTU-PU .................................................................................................................1136.5. DTU-BA ..................................................................................................................1206.6. DTU-PH .................................................................................................................1236.7. DTU-VC .................................................................................................................1286.8. DTU-G ....................................................................................................................133
7. LINE TERMINATING UNITS ......................................................................139
7.1. LTU-2 .....................................................................................................................1397.2. LTU-C .....................................................................................................................1437.3. LTU-F .....................................................................................................................149
8. METERING CIRCUIT AND EMERGENCY SWITCH-OVER UNITS ..........158
8.1. MC(E)-D (16 circuit version) ..................................................................................1588.2. MC(E)-F ..................................................................................................................1588.3. MC(E)-G .................................................................................................................1598.4. ESU-LG ...................................................................................................................160
9. MODEM LINE UNIT ....................................................................................162
10. RECEIVER SENDER FOR TONES ...............................................................167
10.1. RST-KD-1C .............................................................................................................16710.2. RST-SL ....................................................................................................................168
nten
ts
11. INTEGRATED ANNOUNCEMENT SERVER ..............................................169
12. IN SYSTEM GATEWAY .............................................................................. 171
13. PM CONTROLLER BOARDS ......................................................................172
13.1. PSC-G ..................................................................................................................... 17213.2. PMC-HR ................................................................................................................. 17313.3. PMC-MC ................................................................................................................ 17713.4. PMC-G ................................................................................................................... 181
14. CPU3000 / VIC3000 .....................................................................................187
15. COMMUNICATION INTERFACE EXTERNAL ......................................... 191
15.1. CIE .......................................................................................................................... 191
16. CENTRAL CONTROL SLICE .......................................................................195
17. POWER SUPPLY UNIT ...............................................................................196
17.1. PSU-MLD(02) ......................................................................................................... 196
18. CONFERENCE BOARD ...............................................................................198
iii
Tab
le o
f Co
iv
Table of C
ontents
1
Release date : 01/Oct/2007
SOPHO iS3000 Series (SIP@Net) - Maintenance Manual Part 3 (Board
Interfaces & Strap Settings)
2
AMENDMENTS
The items that follow are incorporated in the update of this manual from issue 0301 to 0307:
The items that follow are incorporated in the update of this manual from issue 0502 to 0603:
The items that follow are incorporated in the update of this manual from issue 0603 to 0811:
CHAPTER/SECTION
DESCRIPTION
12. "IN SYSTEM GATEWAY"
ISG added.
CHAPTER/SECTION
DESCRIPTION
6.8. "DTU-G" DTU-G added.
CHAPTER/SECTION
DESCRIPTION
2.7. "ALC-GM/GD" ALC-GM/GD added.
3
PREFACE
This manual is valid for SOPHO SIP@Net (previously known as Call@Net), running on all ISPBX models of the SOPHO iS3000 Series. All of these systems will further be referred to as "ISPBX".
This manual describes the interface connectors, DIL switch and strap settings of the printing wiring boards used in the various ISPBXs.
NOTICE TO THE USER
Unless stated otherwise (in text and figures), the term :
- ALC-G represents the ALC-G, ALC-GP or ALC-G(R).- DTX-I represents the DTX-I or DTX-I(R).- PMC represents the PMC-HR, PMC-MC or PMC-G :
- PMC-HR represents the PMC-HR or PMC-G (with NCC-HR).- PMC-MC represents the PMC-MC or PMC-G (with or without NCC-MC).
- DTU-PH represents the DTU-PH or DTU-G.- DTU-PU represents the DTU-PU or DTU-G.- CPU3000 represents the CPU3000 or CPU4000.
For more details of the CPU4000, see the Customer Engineer Manual “How to install the CPU4000 (including upgrade)“.
4
1. INTRODUCTION
A number of boards in the ISPBX system have DIL switches and/or straps, which have to be set in the correct position during installation or replacement of the boards. This chapter contains all the boards which do have those switches/straps. Also directions are given how to set those switches/straps to suit a particular mode of application. In general the PCT boards have more than one circuit mounted; so in that case the switches/straps have to be set for each circuit individually.
5
2. ANALOGUE LINE CIRCUITS
2.1. ALC-A/B
An ALC-A/B provides the 2-wire line interface between an analogue extension and the ISPBX; see the figure below. The ALC-A board has 8 of those interfaces (circuits).
Figure 2-1 ALC Interfaces
The a/b wires of the ALC-A/B are connected to the MDF via front connector FBC.
Figure 2-2 Layout Front Connector FBC
2.2. ALC-E
An ALC-E provides the 2-wire line interface between an analogue extension and the ISPBX. The ALC-E board has 16 of those interfaces (circuits).
It is possible to use only eight of the ALC-E circuits by means of strap X1-1. In this way an ALC-E can also be used as an ALC-A.
The strap is drawn in position 101-102 for 16 ALC-E circuits: for 8 ALC circuits the strap must be placed in position 102-103.
ALC
ISPBX
Extension line
MDF
Extension
a0......7 : a-wires for extension lines 0....7b0......7 : b-wires for extension lines 0....7
117
FBC
317
124
a0b0a1b1a2b2a3b3
a4b4a5b5a6b6a7b7
6
Figure 2-3 Strap Location
The a/b wires of the ALC-E are connected to the MDF via front connectors FAD & FCA.
Mark
BP
BB
FCA
FAD
X1-1
103 101
7
Figure 2-4 Layout Front Connector FAD & FCA
2.3. ALC-F
An ALC-F provides the 2-wire line interface between an analogue extension and the ISPBX.
The ALC-F board has 16 of those interfaces (circuits).
The ALC-F is dedicated for analogue 'hotel' extensions with message waiting indication.
The software determines the transmission plan for the ALC-F and the use of polarity reversal (for message waiting indication).
a0......15 : a-wires for extension lines 0....15b0......15 : b-wires for extension lines 0....15
125
FAD
325
132
a0b0a1b1a2b2a3b3
a4b4a5b5a6b6a7b7
101
FCA
301
108
a8b8a9b9
a10b10a11b11
A12b12a13b13a14b14a15b15
8
Figure 2-5 Strap Locations on the ALC-F board
Strap X1.2 determines whether the ringing current is balanced or unbalanced:
- 101-102 = ringing current unbalanced (default setting for hotel extensions).- 102-103 = ringing current balanced.
Straps on position X2.1 are used to determine the transmission plan; see the table below.
Mark
BP
BB
FCA
FAD
X1-2103
102101
X2-1101201
102202
103203
104204
9
Table 2-1 Strap Settings for ALC-F
The a/b wires of the ALC-F are connected to the MDF via front connectors FAD & FCA.
Figure 2-6 Layout Front Connector FAD & FCA
TRANSMISSION PLAN STRAP X2.1
204-104 203-103 202-102 201-101
01 = International - - - - - - - - - Installed
02 = Germany - - - - - - Installed - - -
03 = UK - - - - - - Installed Installed
04 = Belgium - - - Installed - - - - - -
05 = Not Used - - - Installed - - - Installed
06 = Austria - - - Installed Installed - - -
07 = Sweden - - - Installed Installed Installed
08 = France Installed - - - - - - - - -
0K = South Africa Installed - - - - - - Installed
0A = Not Used Installed - - - Installed - - -
0B = The Netherlands Installed - - - Installed Installed
0C = Spain Installed Installed - - - - - -
0D = Italy Installed Installed - - - Installed
0E = Switzerland Installed Installed Installed - - -
0F = China Installed Installed Installed Installed
a0......15 : a-wires for extension lines 0....15b0......15 : b-wires for extension lines 0....15
125
FAD
325
132
a0b0a1b1a2b2a3b3
a4b4a5b5a6b6a7b7
101
FCA
301
108
a8b8a9b9
a10b10a11b11
A12b12a13b13a14b14a15b15
10
2.4. ALC-G
An ALC-G provides the 2-wire line interface between an analogue extension and the ISPBX. The ALC-G replaces all versions of the ALC-E and ALC-F. It can not be used instead of the ALC-A.
The ALC-G is a board with 16 interfaces (circuits). Connectors are fitted to the board for a possible future extension board. The hardware is designed in such a way that the adjustment range of the transmission characteristics matches with the currently known country requirements. The maximum line current is 35 mA and reverse polarity is supported.
Note: The line polarity of the ALC-A and the ALC-E is the opposite of the line polarity of the ALC-F and the ALC-G.
Two packages can exist on a card, an initial and a downloaded package. The initial package is factory-installed and can only be modified in the factory.
PPU systems and systems of PMC release < or equal 405.08/505.08 only use an initial package on the board, even if another package is downloaded. The transmission plan is set by means of the DIL-switches.
As from SSW 805.28 and PMC packages 405.10/505.10,. the ALC-G uses only the downloaded package. In this case the DIL-switches are not used for the transmission plan.
Without downloading, the card can be used on SSW 640/SSW2xx/SSW300/SSW7xx/SSW8xx up to PMC 405.08/505.08 (and not with PMC 405.09/505.09).
• Transmission PlansAn ALC-G board can simultaneously contain two downloaded transmission plans, each circuit can have either one of these transmission plans. The transmission plan is specified with the bytes 13 and 14 of signalling group 32xx. When bytes 13 and 14 are 0 (default), then the used transmission plan is specified with the bytes 33 and 34 of signalling group 9800. Bytes 33 and 34 are 1 by default.A circuit can alternate between the two downloaded transmission plans.Example:Byte 13 of signalling group 3205 = 3 (English), transmission plan A.Byte 14 of signalling group 3205 = 1 (International), transmission plan B.Bit 4 of sigalling group 3205 = 0, so 3205 uses plan ABit 4 of signalling group 3204 = 1, so 3204 uses plan BBit 4 of signalling group 3210 = 0, so 3210 uses plan A.ASBRDS:11,1,6,3205,35;all circuits have plan A.CHPCTB:11,1,12,3204;only circuit 12 uses plan B.
11
CHPCTB:11,1,15,3210;circuit 15 uses plan A.
• Signalling ParametersSignalling parameters are downloaded for all circuits on an ALC-G board, two of these signalling parameters are projectable for each individual circuit: on/off hook debouncing and ground key debouncing time.
Figure 2-7 LED and Connector Locations on the ALC-G
The ALC-G has two LEDs; the meaning is given in the table below.
Mark
BP102
BB
Factory test
X2-5
X2-2
X2-3
X2-1
X2-4
Red
GreenLEDs
201 208
108 101
201 208
108 101
101 108
201 101
208 108
208 201
101 108
208 201
On
OffS1-1
FBA
FBD
8 1
12
Table 2-2 LEDs on ALC-G
Country characteristics can be set with the 8 DIP switches of S1. All DIP switch settings not listed should not be used.
MEANING LEDS
GREEN RED
No power Off Off
Internal test is active Off On
Internal test failure Off Blinking
Waiting for initialisation from PMC On On
SW package and parameter downloading or SW package deleting
On Blinking
Operational On Off
13
Table 2-3 DIP Switch Settings on the ALC-G
Connector blocks X1.1 and X2.1 up to X2.5 are not relevant (for future use) in the
TRANSMISSSION PLAN PMC INDEX SWITCH S1.
8 7 6 5 4 3 2 1
Initialisation by PMC 0 0 0 0 0 0 0 0
1 International (600 Ohm) 01 0 0 0 0 0 0 0 1
2 Germany 02 0 0 0 0 0 0 1 0
3 UK 03 0 0 0 0 0 0 1 1
4 Belgium 04 0 0 0 0 0 1 0 0
5 Denmark 05 0 0 0 0 0 1 0 1
6 Austria 06 0 0 0 0 0 1 1 0
7 Sweden 07 0 0 0 0 0 1 1 1
8 France 08 0 0 0 0 1 0 0 0
B Netherlands 0B 0 0 0 0 1 0 1 1
C Spain 0C 0 0 0 0 1 1 0 0
D Italy 0D 0 0 0 0 1 1 0 1
E Switzerland 0E 0 0 0 0 1 1 1 0
F China 0F 0 0 0 0 1 1 1 1
K South Africa 13 0 0 0 1 0 0 1 1
M Brazil 15 0 0 0 1 0 1 0 1
3' New Zealand 17 0 0 0 1 0 1 1 1
2' Czech Republic 18 0 0 0 1 1 0 0 0
TBR 38_00
Li = 0.0 dBr / Lo = - 5.0 dBr 19 0 0 0 1 1 0 0 1
TBR 38_00
Li = 0.0 dBr / Lo = - 7.0 dBr 1A 0 0 0 1 1 0 1 0
TBR 38_00
Li = 3.7 dBr / Lo = - 5.3 dBr 1B 0 0 0 1 1 0 1 1
3 (special) UK 1C 0 0 0 1 1 1 0 0
1=ON; 0=OFF.
14
operational state of the board.
The a/b wires of the ALC-G are connected to the MDF via front connectors FBA & FBD.
Figure 2-8 Layout Front Connector FBA & FBD
2.5. ALC-GP
The ALC-GP board (ALC-General Protected, 12NC: 9600 040 28000) has the same functionality as the ALC-G except for a protection circuit per line to fulfil the requirements for the Chinese market (YD/T 950-1998). These requirements include the ITU-T K.20:1996 recommendation.
2.6. ALC-G(R)
The ALC-G(R) is the redesigned version of the ALC-G and ALC-GP.The ALC-G(R) has the same functionality as the ALC-GP : it provides the 2-wire line interface between an analogue extension and the ISPBX.The board contains 16 interfaces (circuits). The ALC-G(R) replaces all versions of the ALC-G and ALC-GP. It can not be used instead of the ALC-A. See the description of the ALC-G for more details of the LEDs, connectors and DIP Switch Settings.
101 301 125 325
FBA FBD
a0 … 15: a-wires for extension lines 0 … 15
b0 … 15: b-wires for extension lines 0 … 15
a0
b0
a1
b1
a2
b2
a3
b3
a8
b8
a9
b9
a10
b10
a11
b11
a4
b4
a5
b5
a6
b6
a7
b7
a12
b12
a13
b13
a14
b14
a15
b15108 308 132 332
15
2.7. ALC-GM/GD
The ALC-GM/GD replaces all versions of the ALC-E, ALC-F and ALC-G/GP/G(R). See the description of the ALC-G for more details of the LEDs, connectors and DIP Switch Settings. The ALC-GM/GD provides the 2-wire line interface between an analogue extension and the ISPBX :
- the ALC-GM is a mother board with 16 interfaces (circuits).- the ALC-GD is a daughter board with 16 interfaces (circuits).
When the daughter board (ALC-GD) is present on the mother board (ALC-GM), the combination offers 32 interfaces in total.
The ALC-GM fits in a PM2500 shelf just like an ALC-E or ALC-F (all 16 circuits). However the combination ALC-GM plus the daughter board ALC-GD is mechanically to wide to fit in a PM2500 board position.
Note that the ALC-G/GP/G(R) can not be used as a motherboard to mount the ALC-GD daughterboard !!!
Projecting aspects :
- the ALC-GM with the daughter board ALC-GD has to be projected as one ALC with 32 circuits, board type 59 and signaling group 321C.
- the ALC-GM without the daughter board ALC-GD has to be projected as one ALC with 16 circuits, board type 6 and signaling group 3205 or 3210.
- signalling group 321C is supported from PMC packages 405.10.01 en 505.10.01 and all PMC-G 810 packages.Board type 59 is supported from SW805.28 onwards.
16
Figure 2-9 LED and Connector Locations on the ALC-GM/GD
Mark
BP102
BB
Factory test
X2-2
X2-3
X2-1
X2-4
Red
Green
LEDs
201 208
108 101
201 208
108 101
101 108
208 201
101 108
208 201
On
OffS1-1
FBA
FBD
8 1
FAB
FCC
crt 0
crt 7
crt 8
crt 15
crt 23
crt 16
crt 31
crt 24
Connector on daughter board
Connector on daughter board
17
Figure 2-10 Layout Front Connector FBA & FBD on the ALC-GM
Figure 2-11 Layout Front Connector FAB & FCC on the ALC-GD
101 301 125 325
FBA FBD
a0 … 15: a-wires for extension lines 0 … 15
b0 … 15: b-wires for extension lines 0 … 15
a0
b0
a1
b1
a2
b2
a3
b3
a8
b8
a9
b9
a10
b10
a11
b11
a4
b4
a5
b5
a6
b6
a7
b7
a12
b12
a13
b13
a14
b14
a15
b15108 308 132 332
117 317 109 309
FCC FAB
a16 … 31: a-wires for extension lines 16 … 31
b16 … 31: b-wires for extension lines 16 … 31
a16
b16
a17
b17
a18
b18
a19
b19
a24
b24
a25
b25
a26
b26
a27
b27
a20
b20
a21
b21
a22
b22
a23
b23
a28
b28
a29
b29
a30
b30
a31
b31124 324 116 316
18
3. KEY TELEPHONE LINE CIRCUITS
3.1. KTLC01/02/03
The KTLC provides a 4-wire interface between up to 8 SOPHO SETs of the K series (K160, K260, K261, K365) and the ISPBX. The a/b wires are used for voice; the c/d wires are used for control information from/to the SOPHO SET.
All four wires are connected to the MDF via front connectors FBA & FBD.
Figure 3-1 Layout Front Connector FBA & FBD
There are two types of KTLCs: the 8 circuits per board versions with a fixed transmission plan and the 8 circuits per board version with a software selectable transmission plan.
The fixed transmission plan KTLCs are:
- KTLC01 :according to transmission plan 01 (e.g. required for the Netherlands);- KTLC02 :according to transmission plan 02 (e.g. Germany);- KTLC03 :according to transmission plan 03 (e.g. United Kingdom).
The software selectable transmission plan KTLC is KTLC-A: transmission plan set by the signalling block. The transmission plans supported by the KTLCs can also be used in other countries next to the ones listed above.
The KTLC to be used in a specific country depends on the local transmission plan. The transmission levels of the various KTLC boards are selected by means of strap settings; see figurefor the location of the straps.
a0......7 : a-wires for extension lines 0....7b0......7 : b-wires for extension lines 0....7c0......7 : c-wires for extension lines 0.....7d0......7 : d-wires for extension lines 0....7
101
FBA
301
108
a0b0a1b1a2b2a3b3
c0d0c1d1c2d2c3d3
125
FBD
325
132
a4b4a5b5a6b6a7b7
c4d4c5d5c6d6c7d7
19
• Strap X1.1The straps of X1.1 are used to set the mode of operation of the KTLC; see the table below. For normal operation of the key telephones, all straps of X1.1 must be installed.
Table 3-1 KTLC Mode of Operation
• Strap X2.1This strap is used to connect or disconnect the back-up battery of the memory circuits on the KTLC board. With the battery connected these circuits retain user-defined data during a system power failure. User defined data is also retained when the board is removed from the shelf, but only if the shelf has been powerless during removal!User defined data is not retained when the board is removed from the system.- operation with battery back-up (normal operation):strap on position 101-102.- operation without battery back-up (factory setting):strap on position 102-103.When removing the KTLC from an operational system, remove and re-install the strap on 101-102 for about one second to clear the contents of the memory in order to avoid the possible corruption of the user programmed data.
Note: When the board is stored the strap must be positioned on 102-103 to prevent a fully discharged battery.
• Strap X3.1The straps of X3.1 are used to select the correct transmission levels; the setting of X3.1 depends on the type of KTLC and the local transmission plan.Tablegives the strap settings for the transmit levels; tablegives the settings for the receive levels. Both tables indicate the strap settings per transmission plan for a few countries. For countries not mentioned in the tables one should use the default settings of the KTLC; these settings are:- KTLC01 : the settings for the Netherlands.
MODE OF OPERATION X1.1
101-201
102-202
103-203
104-204
105-205
Normal Operational Mode (strapped in factory)
Inst. Inst. Inst. Inst. Inst.
Debug Test Mode Inst. Inst. - Inst. Inst.
Terminal Communications Test - Inst. Inst. Inst. Inst.
Loopback Test: Control - to Terminal Processor
- Inst. - Inst. Inst.
Loopback Test: Control Processor to PPU - - Inst. Inst. Inst.
20
- KTLC02 : the settings for Germany.- KTLC03 : the settings for United Kingdom.
Note: Make sure that the settings of X3.1 corresponds to the local transmission plan before installing the board.
• FusesNew KTLC types have 8 fuses (0.2 A, 8.5 Ohm) to give extra protection to the data circuits. Fuse F1.1 belongs to the extension connected to the first output, F1.2 to the second extension etc.
Table 3-2 Transmit Levels
TRANSMIT LEVEL (dBr) X3.1
KTLC01 KTLC02 KTLC03 105-205 106-206 107-207 108-208
- 8.4*) - 7.6*) - 2.8*) - - - -
- 6.9 - 6.2 - 1.3 - - - Inst.
- 5.4 - 4.6 0.2 - - Inst. -
- 3.9 - 3.2 1.7 - - Inst. Inst.
- 2.4 - 1.5 3.25) - Inst. - -
- 0.91) 0.04) 4.7 - Inst. - Inst.
0.62) 1.5 6.2 - Inst. Inst. -
2.13) 2.9 7.7 - Inst. Inst. Inst.
3.6 4.5 9.2 Inst. - - -
5.1 4.5 10.7 Inst. - - Inst.
6.6 6.0 12.2 Inst. - Inst. -
8.1 7.5 13.7 Inst. - Inst. Inst.
9.6 9.0 15.2 Inst. Inst. - -
11.1 12.0 16.7 Inst. Inst. - Inst.
12.6 13.5 18.2 Inst. Inst. Inst. -
14.1 15.0 19.7 Inst. Inst. Inst. Inst.
*) Factory setting 2) Italy 4) Germany
1) Belgium 3) The Netherlands 5) United Kingdom
21
Table 3-3 Receive Levels
RECEIVE LEVEL (dBr) X3.1
KTLC01 KTLC02 KTLC03 101-201 102-202 103-203 104-204
7.8 2.0 2.2 - - - -
6.3 0.5 0.7 - - - Inst.
4.8 - 1.1 - 0.8 - - Inst. -
3.3 - 2.6 - 2.3 - - Inst. Inst.
1.8 - 4.1 - 3.8 - Inst. - -
0.3 - 5.5 - 5.3 - Inst. - Inst.
- 1.2 - 7.14) - 6.85) - Inst. Inst. -
- 2.72) - 8.5 - 8.3 - Inst. Inst. Inst.
- 4.2 - 10.1 - 9.8 Inst. - - -
- 5.7 - 11.6 - 11.3 Inst. - - Inst.
- 7.21) - 13.1 - 12.8 Inst. - Inst. -
- 8.73) - 14.6 - 14.3 Inst. - Inst. Inst.
- 10.2 - 16.1 - 15.8 Inst. Inst. - -
- 11.7 - 17.6 - 17.3 Inst. Inst. - Inst.
- 13.2 - 19.1 - 18.8 Inst. Inst. Inst. -
- 14.7 - 20.6 - 20.3 Inst. Inst. Inst. Inst.
*) Factory setting 2) Italy 4) Germany
1) Belgium 3) The Netherlands 5) United Kingdom
22
Figure 3-2 Strap Location on the KTLC-01/02/03
3.2. KTLC-A/E
The KTLC-A/E provides a 4-wire interface between up to 8 or 16 SOPHO SETs of the K series (K160, K260, K261, K365) and the ISPBX. The a/b wires are used for voice; the c/d wires are used for control information from/to the SOPHO SET.
The KTLC-A is an 8 circuit board, consisting of a single (mother) board. The KTLC-A is delivered with an on-board memory backup battery.
The KTLC-E is a 16 circuit board and is a combination of the KTLC-A (mother board) and a daughter board. KTLC-E does not have an on-board memory backup battery; the battery cannot be fitted onto the mother-board if used as a KTLC-E.
Mark
BP
BB
X2-1
FBD
FBA
101102
103
F1.1
F1.2
F1.3
F1.4
F1.5
F1.6
F1.7
F1.8
X3-1
108208
101201
X1-1
105205
101201
23
Figure 3-3 Front Layout of the KTLC-A and KTLC-E (Mother Board and Daughter Board)
All wires are connected to the MDF via front connectors FBA & FBD.
Daughter board
KTLC-A
100
KTLC-E
100
100FAA
FAB
FAC
FAD
FBA
FBB
FBC
FBD
FCA
FCB
FCC
FCD
FBA
FBD
FAB
FCC
Mother board
24
Figure 3-4 Layout Front Connector FBA & FBD (on mother-board)
Figure 3-5 Layout Front Connector FAB & FCC (on daughter-board)
The KTLC-A and KTLC-E have electronic 'automatic recovery' fuses, so no replaceble fuses are used.
The transmission plan and the transmission levels are set by the software in the signalling block. Refer to the Signalling Data Manual for further details concerning the meaning and possible settings of the signalling group bytes.
The default value for the KTLC-A signalling block (2304) is transmission plan 01.
The on-board memory of the KTLC may contain user data. If a mains power failure might
a0......7 : a-wires for extension lines 0....7b0......7 : b-wires for extension lines 0....7c0......7 : c-wires for extension lines 0.....7d0......7 : d-wires for extension lines 0....7
101
FBA
301
108
a0b0a1b1a2b2a3b3
c0d0c1d1c2d2c3d3
125
FBD
325
132
a4b4a5b5a6b6a7b7
c4d4c5d5c6d6c7d7
a8......15 : a-wires for extension lines 8....15b8......15 : b-wires for extension lines 8....15c8......15 : c-wires for extension lines 8.....15d8......15 : d-wires for extension lines 8....15
101
FAB
301
108
a8b8a9b9
a10b10a11b11
c8d8c9d9c10d10c11d11
101
FCC
301
108
a12b12a13b13a14b14a15b15
c12d12c13d13c14d14c15d15
25
occur this memory has a back-up power supply via an on board battery.
• Strap X2.1This strap is used to connect or disconnect the back-up battery of the memory circuits on the KTLC board. With the battery connected these circuits retain user-defined data during a system power failure.User defined data is also retained when the board is removed from the shelf, but only if the shelf has been powerless during removal!In all other circumstances this strap has to be removed for a while before inserting the board into the shelf. An example of such a situation is when removing the board with the shelf powered up. The data stored in the on-board processor and associated memory is mutilated in that case: the strap should be removed before re-inserting it so that the processor and memory can be reset.- Operation with battery back-up (normal operation):strap present;- Operation without battery back-up (factory setting):strap not present.
• Strap X2.2This strap must be placed (watchdog active)
• Strap X3.1Strap 101-201 of X3.1 must not be placed; the board is then configured as KTLC-A.The remaining straps of X3.1 must be placedfor normal operation; they are used for factory testing.
26
Figure 3-6 Strap Location on the KTLC-A/E Motherboard
Mark
BP
BB
FBD
FBA
106206
X3-1
101201
X2-2101201
X2-1
102101
27
4. DIGITAL LINE CIRCUITS
4.1. DLC-A/B/C/D
The Digital Line Circuit-A or B (DLC-A, DLC-B) provides a number of two-wire 2B+D accesses to the ISPBX. Each access is a Philips proprietary Usinterface at a nominal bit rate of 152 kbit/s. The Usinterfaces can be used to connect terminal equipment, such as SOPHO-SET S-range and LAMs. The DLC-A/B/C/D can operate in combination with a Line Driver Card (LDC) when line powered terminals are connected.
The DLC-A controls a maximum of 3 DLC-Bs placed in the same Unit Group; the DLC-C controls one DLC-D placed in the same Unit Group: controlling is done via frontcabling; see figure.
The number of Usinterfaces of the DLC boards is:
- DLC-A : 3x(2B+D) Usinterfaces.- DLC-B : 4x(2B+D) Usinterfaces.- DLC-C : 7x(2B+D) Usinterfaces.- DLC-D : 8x(2B+D) Usinterfaces.
Figure 4-1 Layout Front Connector FCD on DLC-A and DLC-B
DLC-A
Line 0...3 : U -interface 0....3s
DLC-B
125
FCD
325
132
125
FCD
325
132
Line 0
Line 1
Line 2
Line 0
Line 1
Line 2
Line 3
28
Figure 4-2 Layout Front Connector FCC on DLC-C and DLC-D
Figure 4-3 Front Cabling of DLC-A/B - LDC and DLC-C/D - LDC
4.2. DLC-U
The Digital Line Circuit-U-interface (DLC-U) (9561 158 55110) provides 15 two-wire 2B+D
DLC-C
Line 0...7 : U -interface 0....7s
DLC-D
125
FCC
325
132
101
FCC
301
108
Line 1
Line 2
Line 3
Line 0
Line 1
Line 2
Line 3
Line 4
Line 5
Line 6
Line 7
Line 4
Line 5
Line 6
Line 7
1) Not used2) Special cable which is only used for connecting the combination of a DLC-A / DLC-B to an LDC.3) When no LDC is used, the cables of FCC and FCD of the DLCs are directly connected to the MDF.
FBA
FBB
FBC
FBD
100
DLC-B
100
DLC-B
100
DLC-B
100
DLC-A
100
LDC
To MDF
To MDF
FBA
FBD
FCC
FAA
FAB
FAC
FAD
To MDF
To MDF
FCC
FCD
FAA
FAB
FAC
FAD
100
DLC-C
100
DLC-D
100
LDC
1)
1)
1)
1)
1)
1)
1)
1)
0
1)
1)
1)
1)
3)
3) 3)
3) 3) 3)
2)
1 0 1
29
accesses to the ISPBX. Each access is a Philips proprietary Usinterface with a nominal bit rate of 152 kbit/s. The Usinterfaces can be used to connect terminal equipment, such as the SOPHO-SET S-range and LAM. The DLC-U has the functions of a DLC-C/D combined with an LDC. This DLC-U can therefore be used for line-powered digital extensions with Usinterfaces. The board contains no straps.
The terminal equipment is connected to the DLC-U via the front connectors FAD and FCA; these connections are made via the MDF.
Figure 4-4 Layout Front Connector FAD & FCA.
The Digital Line Circuit-U-interface (DLC-U) (9561 158 55200) provides 15 two-wire 2B+D accesses to the ISPBX. Each access is a Philips proprietary Usinterface with a nominal bit rate of 152 kbit/s. The Usinterfaces can be used to connect terminal equipment, such as the SOPHO-SET S-range and LAMs. The DLC-U has the functions of a DLC-C/D combined with an LDC. This DLC-U can be strapped for line power/no line power. See figure.
Note: There is also a stripped version of the DLC-U which provides 7 two-wire 2B+D Usinterfaces. This type of DLC-U occupies half the UG.DLC-U (7), without straps: 9562 158 64110.DLC-U (7), with straps: 9562 158 64200.
• Straps on the DLC-U(9562 158 55200 and 9562 158 64200)Jumper MK1 connected: No line power.Jumper MK2 connected: Line power.
Line 0...14 : U -interface 0....14s
125
FAD
325
132
101
FCA
301
108
Line 1
Line 2
Line 3
Line 8
Line 9
Line 10
Line 11
Line 12
Line 13
Line 14
Line 4
Line 5
Line 6
Line 7
Line 0
30
Figure 4-5 Straps of the DLC-U (9562 158 55200 and 9562 158 64200)
4.3. DLC-I
The Digital Line Circuit-ISDN (DLC-I) has 7 digital 2B+D interface lines. These lines are four wire basic rate S0interfaces between the ISPBX system and ISDN terminal equipment according to CCITT Rec. I.430. The ISDN terminal equipment is connected to the DLC-I via the front connectors FBA and FBB. These connections are made via the MDF.
Mark
BP
BB
FCA
Not present on DLC-U (7)
Not present on DLC-U (7)
EHWA Port2...17
EHWA Port18...31
FAD
X3.2
Port
X3.1
X3.5
X3.6
X3.8
X3.7
X3.4
X3.3
X3.10
X3.9
X3.13
X3.15
X3.14
X3.12
X3.11
MK 2MK 1 4 & 5
MK 2MK 1 2 & 3
MK 2MK 1 10 & 11
MK 2MK 1 12 & 13
MK 2MK 1 16 & 17
MK 2MK 1 14 & 15
MK 2MK 1 8 & 9
MK 2MK 1 6 & 7
MK 2MK 1 20 & 21
MK 2MK 1 18 & 19
MK 2MK 1 26 & 27
MK 2MK 1 30 & 31
MK 2MK 1 28 & 29
MK 2MK 1 24 & 25
MK 2MK 1 22 & 23
31
Figure 4-6 Layout Front Connector FBA & FBB
The DLC-I is used as Network Terminator (NT): it operates as the master and it provides the synchronisation clock for the Terminal Equipment (TE). Therefore straps X4.1 and X4.2 must be placed on positions 102-103.
TX0...6 : Outgoing balanced linesRX0...6 : Incoming balanced lines
The positive poles of the RX/TX S interfaces are indicated with a“ +”.These indications do not refer to the polarity of the S interface phantom power supply.
0
0
101
FBA
301
108
RX0 + +
TX0
101
FBB
301
108
RX1 +
RX2 +
RX3 +
RX4 +
RX5 +
RX6 +
+
TX1
+
TX2
+
TX3
+
TX4
+
TX5+
TX6
32
Figure 4-7 Strap Location DLC-I
4.4. DTX-I
The Digital Trunk eXtension-ISDN (DTX-I) provides 15 four-wire 2B+D accesses to the ISPBX. Each access contains an S0interface which can be configured as follows:
- as a network interface to connect ISDN terminal equipment;- as a trunk/tie line interface to make a connection to the ISDN.
The following S0-line interfaces are supported:
- an extension interface;- a remote extension interface;- an 1TR6 trunk line interface;
Mark
BP
BB
FBD (not used)
Factorytest only
FBA
FBB
FBC (not used)
103102101
X4.1
103102101
X4.2
33
- an 1TR6 tie line interface;- a DPNSS tie line interface.
The ISDN equipment is connected to the DTX-I via the front connectors FAB, FBA, FBD & FCC. These connections are made via the MDF.
Figure 4-8 Layout Front Connector FAB, FBA, FBD & FCC
The DTX-I can replace a DLC-I or DTU-BA. When operating as a DLC-I or DTU-BA, only 7 circuits are used.
Note: There is also a stripped version of the DTX-I which provides 7 four-wire 2B+D S0 interfaces:the DTX-I (7).
Each line of the DTX-I has two straps of 3 pins which connect the power supply to the center taps of the transmission line transformers for phantom power feeding purposes and for the selection of master or slave, when used as a trunk connection; see the figure below.
SRn = Receiver of S line interface number nSXn = Transmitter of S line interface number n
The positive poles of the RX/TX S interfaces are indicated with a“ +”.These indications do not refer to the polarity of the S interface phantom power supply.
0
0
109
FAB
309
116
125
FBD
325
132
SR9+ +
SX9+
SX1SR1+
SR10+ +
SX10+
SX2SR2+
SR11+ +
SX11+
SX3SR3+
SR12+ +
SX12+
SX4SR4+
101
FBA
301
108
117
FCC
317
124
SR13+ +
SX13+
SX5SR5+
SR14+ +
SX14+
SX6SR6+
SR15+ +
SX15+
SX7SR7+
+
SX8SR8+
34
Figure 4-9 Meaning of strap X5.1 ... X5.30
The strap at the receiver side has the reference Rn and at the transmit side Tn: R stands for receiver, T for transmit and n is the related line number.
When the DTX-I is used as a DTU-BA, the DTU-BA can operate either as Terminal Equipment (TE) or as Network Terminator (NT) in a network. When changing over from TE to NT (or vice versa) also the projecting data has to be changed. Check the projecting data to see how the DTU-BA is projected.
• Strap SettingsEach circuit of the DTX-I can be used to connect:
When a DTX-I is projected as a DLC-I or a DTU-BA the following restrictions apply:- A maximum of 7 lines (0 ... 6) can be used, even in case of a DTX-I(15);- No mix of trunk and terminal circuits is allowed;- The board is not downloadable.
WARNING: BE SURE THAT BOTH THE RN AND TN STRAPS OF A LINE ARE MOUNTED ON EQUAL POSITIONS. IT IS NOT ALLOWED TO
- a terminal : connect, on Rn and Tn side, the straps 101&102 to deliver the line power;
- a trunk line (TE side) : connect, on Rn and Tn side, the straps 102&103: no line power, no sync. (=slave);
- a trunk line (NT side : on Rn and Tn side, no straps made: no line power, sync. is delivered (=master).
Rn : odd numbered straps (X5.1...X5.29)
Tn : even numbered straps (X5.2...X5.30)
Master / SlaveSystem Ground
Receive
DTX-I
Transmit
103102101
Rn
Not connected-40V
103102101
Tn
35
HAVE ONE STRAP MOUNTED ON POSITION 101&102 AND THE OTHER STRAP ON POSITION 102&103.DO NOT MOUNT A STRAP ON X2.1 AND X3.1. THIS WILL DAMAGE THE PROCESSOR AND POWER SUPPLY.
• Terminal EquipmentWhen the DTU-BA is used as interface to the PSTN or another PBX it operates as a TE. It expects to receive an external clock reference from an NT to synchronise with. This means that a clock signal is available on frontconnector FC 101; this clock signal can be used as the input clock for a CRU, when necessary.
• Network TerminatorWhen the DTU-BA is used as an NT, it operates as the master and it provides the synchronisation clock for the TE. This means that no clock signal is available on front-connector FC 101.
When two DTX-I (used as DTU-BAs) form one transmission link (max. distance 1000 meters) one DTX-I must be strapped as DTU-BA NT and the other as a TE.
36
Figure 4-10 Strap Location on DTX-I
Figure 4-11 Details of strap X5.1 ... X5.30
Mark
BP
BB
FBD
FBA
FAB
101
201101
204104
FCC
Not present
on DTX-I (7)
FC101
X5.2 Line 0
Line 1X5.1X5.4X5.3X5.6X5.5X5.8X5.7X5.10X5.9X5.12X5.11X5.14X5.13X5.16X5.15X5.18X5.17X5.20X5.19X5.22X5.21X5.24X5.23X5.26X5.25X5.28X5.27X5.30X5.29
Line 2
Line 3
Line 4
Line 5
Line 6
Line 7
Line 8
Line 9
Line 10
Line 11
Line 12
Line 13
Line 14
102
Lab/FactoryTest only
X2.1
X3.1
X5.2Line 0
X5.1
X5.4
X5.3Etc.
103102101
103102101103102101
103102101
Line 1
37
4.5. DTX-I(R)
The DTX-I(R) is the redesigned version of the DTX-I. The DTX-I15(R) provides 15 four-wire 2B+D accesses to the ISPBX. Each access contains an S0 interface which can be configured as follows :
- as an extension interface (network side) to connect ISDN terminal equipment;- as a trunk/tie line interface (user side) to make a connection to the ISDN.
Note: There is also a stripped version of the DTX-I(R) which provides 7 four-wire 2B+D S0 interfaces : the DTX-I7(R).
Strap Settings
Note that a strap summary is printed on the DTX-I(R) board between connectors FBA and FBD. Each circuit of the DTX-I(R) can be used as :
- an EXTension to connect ISDN terminalsThe straps must be placed on position 101&102 (factory setting).The transmit and receive pairs of an interface are connected to -40 V and system ground respectively, in order to power the connected terminals.
- a Trunk lineThe straps should be parked in the position 102&103.The transmit and receive pairs are isolated from -40 V and ground, in order to avoid high ground currents flowing between two systems.
38
Figure 4-12 Layout Front Connector FAB, FBA, FBD & FCC
Front connectors
At the front of the DTX-I(R) four F122 connectors (FAB, FBA, FBD & FCC) are available to connect the four-wire S0 interfaces. The pinning of these connectors is identical to the DTX-I.
Clock Reference
When the DTX-I(R) is used as interface to the PSTN or another PBX it operates as a slave (TE). The PBX may need an external clock reference from the master network (NT) to synchronise with. For this purpose a clock signal is available on front connector FC 101; this clock signal can be used as the input clock for a CRU, when necessary.
Mark
BP
BBFBD
FBA
FAB
FCC
Not present
on DTX-I(7) (R)
FC101
Lab/FactoryTest only
Line 1
Line 2
Line 3
Line 4
Line 5Line 6
Line 7
Line 8
Line 9
Line 10
Line 11Line 12
Line 13
Line 14
Line 15
BIST connector101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
103
103
103
103
103
103
103
103
103
103
103
103
103
103
103
X1.1
X1.3
X1.5
X1.7
X1.9
X1.11
X1.13
X1.15
X1.2
X1.4
X1.6
X1.8
X1.10
X1.12
X1.4
39
4.6. DLX-U
The Digital Line eXtensions - Upninterface (DLX-U) provides 2 wire accesses for extensions with Upninterface. There are two types: the DLX-U(15) and DLX-U(31).
The DLX-U(15) provides 15 accesses.
The accesses are 2B+D types which can be used in two different modes (the 'board type' and the 'signalling group' in the projecting data determine the mode):
The DLX-U(31) provides 31 accesses. The accesses are 2B+D types, but only one B-channel is applied. This is called the 1B mode.
The circuits in relation to the lines differ per DLX-U and operating mode:
- 1B mode : This means that only one B-channel is applied and the second remains unused.
- 2B mode : This means that both B-channels are applied.
- DLX-U(15) in 1B mode:circuit 0: PPU - DLX-U control channel (IMP)circuit 1 ... 15: access 1 ... 15
- DLX-U(15) in 2B mode:circuit 0: PPU - DLX-U control channel (IMP)circuit 1: not usedcircuit 2 & 3: access 1circuit 4 & 5: access 2
|| ||circuit 30 & 31: access 15
- DLX-U(31) in 1B mode:circuit 0: PPU - DLX-U control channel (IMP)circuit 1 ... 31: access 1 ... 31
40
Figure 4-13 Layout Front Connector FBA & FBD (mother board)
Figure 4-14 Layout Front Connector FAB & FCC (daughter board)
Access 1...15 : U -interface 0....15p n
101
FBA
301
108
125
FBD
325
1324
Access 1
Access 2
Access 3
Access 1
Access 5
Access 6
Access 7
Access 8
Access 9
Access 10
Access 11
Access 12
Access 13
Access 14
Access 15
Access 27
Access 16...31 : U -interface 16....31p n
109
FAB
309
116
117
FCC
317
124
Access 24
Access 25
Access 26
Access 28
Access 29
Access 30
Access 31
Access 16
Access 17
Access 18
Access 19
Access 20
Access 21
Access 22
Access 23
41
Figure 4-15 DLX-U(15) and DLX-U(31) mother/daughter board
4.7. DLX-L
The Digital Line eXtension-Long line interface provides accesses for extensions with a Uk0 (2B1Q) interface.
The DLX-L provides 15 accesses with 2B+D interface of which :
- one B-channel is used (1B mode, Philips proprietary)- two B-channels are used (2B, ITU compatible).
The mode depends on the signalling group and board type. Mixed mode (1B and 2B) on one board is not possible.
The DLX-L has the following characteristics:
- It has Uk0 interfaces: a 2-wire, 98 ohms balanced, 2B1Q interface with a datarate of 144 kbits/s;
- On layer 3, it supports TMP, 1TR6 and Euro (ETSI): protocol selection on layer 3 is automatic;
- It is able to support power to the terminals, nominal -58 volts with a current of 45 mA;- It is intended to service voice and data terminals;- When no Uk0 terminal is available, the board can be connected via a Private Network
100
FAB
FBA
FBD
FCC
DLX-U
31
100
FBA
FBD
DLX-U
15
42
Terminator for Long lines (PNT-L), which converts the Uk0 (2B1Q) into an S0bus;- Under optimal conditions, the DXL-L with a PNT-L supports a maximum line length of 3.5
km (0.4mm cable) or 5.5 km with 0.5mm cable (Filotex 0.5 cat.3).
The layout of the front connectors of the DLX-L is the same as for the DLX-U.
The LEDs on the board have the following meanings:
Table 4-1 Meaning of the LEDs
• PNT-LThe PNT-L is a private network terminator that converts the Uk0 (2B1Q) 2-wire interface provided by the DLX-L into a standard 4-wire S0bus. The use of a PNT-L for connecting terminals to the DLX-L is necessary when no terminal with the Uk0 (2B1Q) interface is available. The PNT-L is mains-powered and provides power to the connected terminal(s). The interface between DLX-L and PNT-L is powered by the DLX-L. The PNT-L is transparent for the layer 3 protocols (TMP, 1TR6 and Euro-ISDN).
Figure 4-16
MEANING LEDs
GREEN RED
No power Off Off
Internal test active Off On
Waiting for command from PM On On
Communication with PM On Off
Software downloading/deleting or no package Blinking On
DLX-L PNT-LUk0 (2B1Q) 2-wire S0 4-wire
43
5. ANALOGUE TRUNK UNITS
5.1. ATU-SS
The ATU-SS (Subscriber Signalling) is a 2-wire line interface which connects the ISPBX system to a PSTN. The a/b wires of the ATU-SS, when not interworking with a Metering Circuit (MC) or Emergency Switch-over Unit (ESU), are directly connected to the MDF via front connector FBC.
When the ATU-SS interworks with MCs and/or ESUs the a/b wires are, via a front connector, first connected to an MC, MCE or ESU card and via that card to the MDF.
Note: Depending on the type of ATU-SS the card accommodates 4 or 6 ATU-SS circuits.
Figure 5-1 Layout Front Connector FBC
If Metering Circuits are used, the outputs of the detectors are connected to the ATU-SS card via a separate front connector. The wires to the metering level detectors on the ATU card are MD1 ... 6 and GND1 ... 6.
a0......5 : a-wires for trunk lines 0....5b0......5 : b-wires for trunk lines 0....5
117
FBC
317
124
a0b0a1b1a2b2a3b3
a4b4a5b5
44
Figure 5-2 Layout Front Connector FAA
5.2. ATU-AS
The ATU-AS (Dutch Subscriber Signalling known as 'ALS70') is a 2-wire line interface which connects the ISPBX system and a PSTN.
The a/b wires of the ATU-AS, when not interworking with a Metering Circuit (MC) or Emergency Switch-over Unit (ESU), are directly connected to the MDF via front connector FBC.
When the ATU-AS interworks with MCs and/or ESUs the a/b wires are, via a front connector, first connected to an MC, MCE or ESU card and via that card to the MDF. It comprises four ATU-AS circuits.
Figure 5-3 Layout Front Connector FBC
If Metering Circuits are used, the outputs of the detectors are connected to the ATU-AS card via a separate front connector. The wires to the metering level detectors on the ATU card are MD1 ... 6 and GND1 ... 6.
MD1......6 : metering detector information from the metering pointGND1......6 : accompanying ground from the metering circuits
101
FAA
301
108
MD1GND1
MD2GND2
MD3GND3
MD4GND4
MD5GND5MD6GND6
a8......15 : a-wires for trunk lines 8....15b8......15 : b-wires for trunk lines 8....15
117
FCA
317
124
a8b8a9b9
a10b10a11B11
a12b12a13b13a14b14a15B15
45
Figure 5-4 Layout Front Connector FAA
5.2.1. ATU-AS36
On the ATU-AS36 straps are used to select the required signalling system (GSD or UFS) and to select the long or short trunk line.
• Long Line Adjustment
Table 5-1 Long Line Adjustment
• Short Line Adjustment
Table 5-2 Short Line Adjustment
CIRCUIT JUMPER TO BE INSTALLED JUMPER POSITION 'OPEN'
1 X1-13 X1-9
2 X1-14 X1-10
3 X1-15 X1-11
4 X1-16 X1-12
CIRCUIT JUMPER TO BE INSTALLED JUMPER POSITION 'OPEN'
1 X1-9 X1-13
2 X1-10 X1-14
3 X1-11 X1-15
4 X1-12 X1-16
MD1......6 : metering detector information from the metering circuitsGND1......6 : accompanying ground from the metering circuits
101
FAA
301
108
MD1GND1
MD2GND2
MD3GND3
MD4GND4
46
• Impulse Dialling InTo enable 'impulse dialling in', install the following jumpers (in case of GSD). If a jumper position is left open 'impulse dialling in' is disabled (in case of UFS, 12KHz).
Table 5-3 Impulse Dialling In
• The Wetting CircuitIf a jumper is installed the 'wetting circuit' (43 kOhm) is enabled (in case of UFS).If a jumper is not installed the 'wetting circuit' is disabled (in case of GSD).
Table 5-4 Wetting Circuit Jumper
CIRCUIT A-WIRE DETECTION B-WIRE DETECTION
1 X1-17 X1-5
2 X1-18 X1-6
3 X1-19 X1-7
4 X1-20 X1-8
CIRCUIT WETTING CIRCUIT JUMPER
1 X1-1
2 X1-2
3 X1-3
4 X1-4
47
Figure 5-5 Strap Location on ATU-AS36
5.3. ATU-EM
The ATU-EM is a 2 or 4-wire line interface which connects the ISPBX system to another PBX. The signalling used consists of two unidirectional 2-wire DC signalling links: the m/mm wires for sending and the e/ee wires for the receipt of signals. There is no difference in signalling between the 2 and 4-wire version.
All wires of the ATU are directly connected to the MDF via front connector:
- FBC:2-wire ATU-EM- FAD:4-wire ATU-EM
Mark
BP
BB
FAA
FBC
X1-9X1-13
X1-10X1-14
X1-16X1-12
X1-15X1-11
X1-5X1-17X1-1
X1-6X1-18X1-2
X1-7X1-19X1-3
X1-8X1-20X1-4
48
Figure 5-6 Layout Front Connector FAD & FBC
The m/mm and e/ee wires of both the 2 and 4-wire version are directly connected to the MDF via front connector FCA.
Figure 5-7 Layout Front Connector FCA
5.3.1. ATU-EM (2-Wire)
Note: The second identifier of the straps (1 ... 4) indicates the ATU circuit 0 ... 3.
a0......3 : a-wires for trunk lines 0....3b0......3 : b-wires for trunk lines 0....3c0......3 : c-wires for trrunk lines 0.....3d0......3 : d-wires for trunk lines 0....3
125
FAD
4 wire version 2 wire version
325
132
a0b0a1b1a2b2a3b3
c0d0c1d1c2d2c3d3
117
FBC
317
124
a0b0a1b1a2b2a3B3
101
FCA
301
108
e0ee0e1
ee1e2
ee2e3
Ee3
m0mm0m1mm1m2mm2m3Mm3
e0...3ee0...3m0...3
mm0...3
: e-wires for trunk lines 0...3: ee-wires for trunk lines 0...3: m-wires for Extension lines 0...3: mm-wires for Extension lines 0...3
49
Figure 5-8 Strap Location
Mark
BP
BB
FCA
FBC
X4.1X4.2X4.3X4.4X6.1X6.2X6.3X6.4X7.1X7.2X7.3X7.4
X3.1X3.2X3.3X3.4
X1.1X1.2X1.3X1.4X2.1X2.2X2.3X2.4
X9.1X9.2X9.3X9.4
X8.1X8.2X8.3X8.4
= Open
X5.1X5.2X5.3X5.4
= Closed
50
Figure 5-9 Logical positions of ATU-EM (2-wire) straps
E-WIREDETECTOR
TransformerOf hybrid
TransformerOf hybrid
E-WIREDETECTOR
620 Ohm
ATU-EM
a-Wire
a-Wire
b-Wire
b-Wire
e-Wire
m-Wire
ee-Wire
mm-Wire
m-Wire
e-Wire
X1
X1
m
m
X2
X2
mm-Wire
ee-Wire
X3
X4
X5
X3
X4
X5
X6X7
X6X7
ATU-EM
620 Ohm
620 Ohm 620 Ohm
540 Ohm
540 Ohm
51
Table 5-5 Survey of E&M Signal Possibilities
The different strap settings of the signal possibilities mentioned in the table are given in the tables below.
The meaning of the different straps are:
E&M Sign. Situation no.
Description of E&M Signals ATU-EM puts on the M-wire
If command bit M is '1'
If command bit M is '0'
1 tone on idle and mains failure earth open line
2 tone on busy and mains failure open line earth
3 tone on busy, not on mains failure open line earth
4 tone on idle, not on mains failure earth open line
5 tone on idle and mains failure batt. minus open line
6 tone on busy and mains failure open line batt. minus
7 tone on busy, not on mains failure open line batt. minus
8 tone on idle, not on mains failure batt. minus open line
9 tone on idle and mains failure closed m/mm loop
open line
10 tone on busy and mains failure open line closed m/mm loop
11 tone on busy, not on mains failure open line closed m/mm loop
12 tone on idle, not on mains failure closed m/mm loop
open line
Bit M = 1 is Inactive (idle state); Bit M = 0 is Active (busy state).
X1 for signalling between earth and open lineX2 for signalling between battery minus and open lineX3 mains failure gives earth or battery minus on m-wire or closed m/mm loop (tone)X4 mains failure gives an open m-wire (no tone)X5 for signalling between closed m/mm loop and open lineX6/X7 shortcircuits a part of the m-wire resistance
52
Table 5-6 Strapsettings X1...X5 and X9 for signal transmission. Tone on idle and on mains failure
X8 Sets message bit E active or inactiveX9 Operates or releases the M-relay
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
1 + - - + - - 1 released
earth 3) tone
5 - + - + - - 1 released
batt. minus
tone
9 - - + + - - 1 released
m/mm loop 3)
tone
1 + - - + - - 0 operated
open line 3)
no tone
5 - + - + - - 0 operated
open line no tone
9 - - + + - - 0 operated
open line 3)
no tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
53
Table 5-7 Strapsettings X1...X5 and X9 for signal transmission. Tone on idle and not on mains failure
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
4 + - - - + + 1 operated
earth 3) tone
8 - + - - + + 1 operated
batt. minus tone
12 - - + - + + 1 operated
m/mm loop 3)
tone
4 + - - - + + 0 released
open line 3)
no tone
8 - + - - + + 0 released
open line no tone
12 - - + - + + 0 released
open line 3)
no tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
54
Table 5-8 Strapsettings X1...X5 and X9 for signal transmission. Tone on busy and on mains failure
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
2 + - - + - + 1 operated
open line 3) no tone
6 - + - + - + 1 operated
open line no tone
10 - - + + - + 1 operated
open line 3) no tone
2 + - - + - + 0 released
earth 3) tone
6 - + - + - + 0 released
batt. minus tone
10 - - + + - + 0 released
m/mm loop 3)
tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
55
Table 5-9 Strapsettings X1...X5 and X9 for signal transmission. Tone on busy and not on mains failure
Table 5-10 Straps X6 and X7
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
3 + - - - + - 1 released
open line 3) no tone
7 - + - - + - 1 released
open line no tone
11 - - + - + - 1 released
open line 3) no tone
3 + - - - + - 0 operated
earth 3) tone
7 - + - - + - 0 operated
batt. minus tone
11 - - + - + - 0 operated
m/mm loop 3)
tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
Resistance in Ohms between M and Strap X6 Strap X7
Earth - Vb MM
1240 1780 1240 - -
620 1160 620 + -
620 1160 620 - +
0 540 0 + +
56
Table 5-11 Strapsettings X8 for signal reception
E&M Sign. Situation No.
E&M Sign. Type
Carrier Eq. (if present) receives
ATU-EM receives on E-wire
Strap X8 1)
Message bit E is 2)
1, 4, 5, 8, 9, 12
tone on idle
tone earth or e/ee loop 3)
+ 0
tone open line - 0
no tone open line 3) + 1
no tone earth or e/ee loop - 1
2, 3, 6, 7, 10, 11
tone on busy
tone earth or e/ee loop 3)
- 1
tone open line + 1
no tone open line 3) - 0
no tone earth or e/ee loop + 0
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
57
5.3.2. ATU-EM (4 Wire)
Figure 5-10 Strap Location
Note: The second identifier of the straps (1 ... 4) indicates the ATU circuit 0 ... 3.
Mark
BP
BB
FCA
FAD
X4.1X3.1X10.1X11.1
X1.1X5.1
101102103
101102103
X13.1
101102103
= Open (-)
X12.1
X12.2
X12.3
X12.4
X13.2
X13.3
X13.4
X7.1X6.1X2.1
X1.2X5.2
X7.2X6.2X2.2
X4.2X3.2X10.2X11.2
X1.3X5.3
X7.3X6.3X2.3
X4.3X3.3X10.3X11.3
X1.4X5.4
X7.4X6.4X2.4
X4.4X3.4X10.4X11.4
X9.1X9.2X9.3X9.4
X8.4X8.3X8.2X8.1
101102103
= Closed (+)
58
Figure 5-11 Logical positions of the ATU-EM (4-wire) straps
E-WIREDETECTOR
From levelAdaptors
a-Wire
From levelAdaptors
To levelAdaptors
To levelAdaptors
E-WIREDETECTOR
620 Ohm
ATU-EM4-WIRE
c-Wire
b-Wire
d-Wire
c-Wire
a-Wire
d-Wire
b-Wire
e-Wire
m-Wire
ee-Wire
mm-Wire
m-Wire
e-Wire
X1
X1
x
x
m
m
X2
X2
mm-Wire
ee-Wire
X3
X4
X5
X3
X4
X5
X6X7
X6X7
X10X10
X11
X10
X11
X10
ATU-EM4-WIRE
620 Ohm
620 Ohm 620 Ohm
540 Ohm
540 Ohm
59
Table 5-12 Survey of E&M Signal Possibilities
The different strap settings of the signal possibilities mentioned in the table are given in the tables below.
The meaning of the different straps are:
E&M Sign. Situation no.
Description of E&M Signals ATU-EM puts on the M-wire
If command bit M is '1'
If command bit M is '0'
1 tone on idle and mains failure earth open line
2 tone on busy and mains failure open line earth
3 tone on busy, not on mains failure open line earth
4 tone on idle, not on mains failure earth open line
5 tone on idle and mains failure batt. minus open line
6 tone on busy and mains failure open line batt. minus
7 tone on busy, not on mains failure open line batt. minus
8 tone on idle, not on mains failure batt. minus open line
9 tone on idle and mains failure closed m/mm loop
open line
10 tone on busy and mains failure open line closed m/mm loop
11 tone on busy, not on mains failure open line closed m/mm loop
12 tone on idle, not on mains failure closed m/mm loop
open line
Bit M = 1 is Inactive (idle state); Bit M = 0 is Active (busy state).
X1 for signalling between earth and open lineX2 for signalling between battery minus and open lineX3 mains failure gives earth or battery minus on m-wire or closed m/mm loop (tone)X4 mains failure gives an open m-wire (no tone)X5 for signalling between closed m/mm loop and open lineX6/X7 shortcircuits a part of the m-wire resistanceX8 Sets message bit E active or inactive
60
Table 5-13 Strapsettings X1...X5 and X9 for signal transmission. Tone on idle and on mains failure
X9 Operates or releases the M-relayX10/X11 Depending on bit x of the 4-wire command byte: mm-wire becomes earth or notX12 Incoming voice direction via c/d wires is aplified/unamplifiedX13 Incoming voice direction via a/b wires is aplified/unamplified
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
1 + - - + - - 1 released
earth 3) tone
5 - + - + - - 1 released
batt. minus tone
9 - - + + - - 1 released
m/mm loop 3)
tone
1 + - - + - - 0 operated
open line 3) no tone
5 - + - + - - 0 operated
open line no tone
9 - - + + - - 0 operated
open line 3) no tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
61
Table 5-14 Strapsettings X1...X5 and X9 for signal transmission. Tone on idle and not on mains failure
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
4 + - - - + + 1 operated
earth 3) tone
8 - + - - + + 1 operated
batt. minus tone
12 - - + - + + 1 operated
m/mm loop 3)
tone
4 + - - - + + 0 released
open line 3) no tone
8 - + - - + + 0 released
open line no tone
12 - - + - + + 0 released
open line 3) no tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
62
Table 5-15 Strapsettings X1...X5 and X9 for signal transmission. Tone on busy and on mains failure
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
2 + - - + - + 1 operated
open line 3) no tone
6 - + - + - + 1 operated
open line no tone
10 - - + + - + 1 operated
open line 3) no tone
2 + - - + - + 0 released
earth 3) tone
6 - + - + - + 0 released
batt. minus tone
10 - - + + - + 0 released
m/mm loop 3)
tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
63
Table 5-16 Strapsettings X1...X5 and X9 for signal transmission. Tone on busy and not on mains failure
Table 5-17 Straps X6 and X7
E&M Sign. Situation No.
Straps 1) Command bit M is 2)
M-relay is
ATU-EM puts on M-wire
Carrier eq. (if present) transmits
X1 X2 X5 X3 X4 X9
3 + - - - + - 1 released
open line 3)
no tone
7 - + - - + - 1 released
open line no tone
11 - - + - + - 1 released
open line 3)
no tone
3 + - - - + - 0 operated
earth 3) tone
7 - + - - + - 0 operated
batt. minus tone
11 - - + - + - 0 operated
m/mm loop 3)
tone
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
Resistance in Ohms between M and Strap X6 Strap X7
Earth - Vb MM
1240 1780 1240 - -
620 1160 620 + -
620 1160 620 - +
0 540 0 + +
64
Table 5-18 Strapsettings X8 for signal reception
Table 5-19 Straps X10 and X11
E&M Sign. Situation No.
E&M Sign. Type
Carrier Eq. (if present) receives
ATU-EM receives on E-wire
Strap X8 1)
Message bit E is 2)
1, 4, 5, 8, 9, 12
tone on idle
tone earth or e/ee loop 3)
+ 0
tone open line - 0
no tone open line 3) + 1
no tone earth or e/ee loop - 1
2, 3, 6, 7, 10, 11
tone on busy
tone earth or e/ee loop 3)
- 1
tone open line + 1
no tone open line 3) - 0
no tone earth or e/ee loop + 0
1) + = strap present; - = strap absent
2) 1 = inactice (idle state); 0 = active (busy state)
3) Corresponds with E&M signalling via physical lines.
Strap X10
Strap X11
Meaning
- + Bit x of 4-wire command byte = 0 (MM-wire goes to earth for compander)
+ - Bit x of 4-wire command byte = 1 (MM-wire goes to earth for compander)
- - Strap present when X5 is present
+ + Not allowed
+ = strap present; - = strap absent
65
Table 5-20 Straps X12 and X13
5.3.3. ATU-EM-D
The ATU-EM-D is designed for special projects only.
This board serves as an interface between the SOPHO and equipment using a digital (64 kbit/sec) interface as described in the ITU recommendations G703.1.
The board contains 4 circuits. The data channels are 4-wire for a co-directional connection (2 pairs: one in each direction) and 8-wire in case of a contra-directional interface (2 pairs for data, one in each direction, and 2 pairs for timing signals, one in each direction). The signalling is E&M signalling via separate E&M wires as is used on the ATU-EM boards. The synchronisation can be extracted from the incoming data stream (circuit 0 only) or from the special input connector on the board.
Strappings/connectors
shows the connector layouts. The strappings and the connector locations are shown in. The connector/circuit relation is as follows:
Strap X12 Strap X13 Incoming Voice Direction via
Mode
n.a. + a/b wires unamplified
n.a. - a/b wires amplified
- n.a. c/d wires amplified
+ n.a. c/d wires unamplified
+ = strap present: - = strap absent; n.a. = not applicable
Connector FAB Circuit 0 (data)Connector FAD Circuit 1 (data)Connector FBB Circuit 2 (data)Connector FBD Circuit 3 (data)Connector FCB Circuits 0-3 (Signalling)Connector X9.1 External clock inputConnector X9.2 Clock output
66
Figure 5-12 Layout of the connectors
The meanings of the abbreviations mentioned in the figureare:
ABBREV. MEANING INTERFACEDA, DB Data transmitter Co- and contra directionalTA, TB Timing outgoing datra Contra directionalDC, DD Data receiver Contra directionalTC, TD Timing incoming data Contra directionalTC, TD Data receiver Co-directionalSH Shield to earthE, EE Incoming signallingM, MM Outgoing signalling
CIRCUIT E&M SIGNALLING
67
Figure 5-13 Board layout with strap locations
Note: On delivery of this board, four spare jumpers are present on the locations: X1-1/2/3/4 over the pins 203-204.
Mark
Line Interface 1
Line Interface 0
CommonControlCircuitsLine Interface 2
Line Interface 3
E&M Interface 1
E&M Interface 3
E&M Interface 0
E&M Interface 2
X9.1
X9.2
BB
BP
FAB
FBD
FCB
FBB
FAD
Clock Ref. Circuit
X5101
106
X8
103 102 101
1234
X2X1
101
103 201 204
X6101
103
201
203
101 104 101 103
201 203
X3X4
X7
68
Table 5-21 Meanings of the straps X1 and X2 (part 1)
Table 5-22 Meaning of the straps X2 (part 2)
Table 5-23 Meanings of the straps X3 and X4
STRAPS SIGNALLING CONDITION
X1 X2
101-201 103-203 202-203 M to earth 'tone on idle'
101-202 103-203 202-203 M to earth 'tone on busy'
101-201 104-204 202-203 M to -Vb 'tone on idle'
102-202 104-204 202-203 M to -Vb 'tone on busy'
101-201 - 201-202 M to MM 'tone on idle'
102-202 - 201-202 M to MM 'tone on busy'
STRAPS X2 SIGNALLING ON THE MM WIRE TO EARTH:
101-102 MM to earth 'tone on idle'
102-103 MM to earth 'tone on busy'
Absent Option not used
STRAPS INTERNAL RESISTANCE IN OHMS FROM M TO:
X3 X4 earth -Vb MM
101-102 101-102 0 540 0
101-102 102-103 680 1220 680
102-103 101-102 680 1220 680
102-103 102-103 1360 1900 1360
69
Table 5-24 meanings of the X5 straps
Table 5-25 Meaning of strap X6 (part 1)
Table 5-26 Meaning of strap X6 (part 2)
Table 5-27 Meaning of strap X7
STRAP X5 SELECTION
101-102 Detector output is not inverted
102-103 Detector output is inverted
104-105 Relay is energized by '1'
105-106 Relay is energized by '0'
STRAP X6 SELECTION TIMING MASTER/SLAVE
201-202 Timing slave
202-203 Timing master
STRAP X6 Selection co-directional/contra-directional
101-102 Co-directional interface
102-103 Contra-directional interface
STRAP X7 Selection clock synchronisation source
101-102 Clock extracted from circuit 0
102-103 Clock from external reference source X9.1
70
Table 5-28 Meanings of the straps X8
The meanings of the abbreviations in the table above are:
SDT: Shield data transmitter
SDR: Shield data receiver
STT: Shield timing (transmitter side)
STR: Shield data (receiver side)
5.4. ATU-CH
The ATU-CH (Cailho Signalling) is a 2-wire line interface which connects the ISPBX system to a PSTN. It is a symmetrical DC signalling, using phantom signals. The a/b wires are switched in parallel and have the same polarity (earth or minus). The soil is used for the common earth connection. The a/b wires of the ATU-CH are directly connected to the MDF via front connector FBC.
When the ATU-CH interworks with MCs and/or ESUs the a/b wires are, via a front connector, first connected to an MC, MCE or ESU card and via that card to the MDF.
SHIELD Connection
STRAP LINE 0 LINE 1 LINE 2 LINE 3
DA/DB (SDT) 102-103 X8.1 X8.5 X8.9 X8.13
DC/DD (SDR) 102-103 X8.2 X8.6 X8.10 X8.14
TA/TB (STT) 102-103 X8.3 X8.7 X8.11 X8.15
TC/TD (STR) 102-103 X8.4 X8.8 X812 X8.16
71
Figure 5-14 Layout Front Connector FBC
5.4.1. ATU-CH02
An ATU-CH02 can either be used for simultaneous signalling or loop signalling, selectable using straps.
Note: The second identifier of the straps (1 ... 4) indicates the ATU circuit 0 ... 3.The straps of ATU 0 and 1 are drawn in the simultaneous signalling position; the straps of ATU 2 and 3 are drawn in the loop signalling position.
a0......5 : a-wires for trunk lines 0....3b0......5 : b-wires for trunk lines 0....3
117
FBC
317
124
a0b0a1b1a2b2a3b3
72
Figure 5-15 Strap Location on ATU-CH02
5.5. ATU-LD0K
The ATU-LD0K contains four two wire analogue trunk lines with Loop-Disconnect signalling. This unit is specific to South Africa. The board can be used for DDI and normal outgoing calls when connected to the PSTN.
5.6. ATU-PSI
The ATU-PSI can be used in the remote door opener mode or in the common answering emergency service mode. By means of seven straps a discrimination can be made between the two modes. Care should be taken that no other connections are made than the interconnections mentioned on the following page.
Mark
BP
BB
X2.1
FBC
X1.1
X2.2
X2.3
X2.4
X1.2
X1.3
X1.4
73
Figure 5-16 Strap Location
Note: The straps are drawn in the position for remote door opener with intermitting M - contact after answering.
Mark
BP
BB
X1-2
106206
101201
X1-1
106206
101201
FBC
74
Figure 5-17 Layout Front Connector FBC
• Remote Door Opener ModeThe following straps are interconnected:
Also one of the four following ways of door opening (=operation of the M relay) must be selected by interconnecting the following pins of X1-2:
• Common Answering Emergency Service ModeThe following straps are interconnected:
-M relay activated intermitting, only after answering : 101 & 102;103 & 104.
-M relay activated intermitting, regardless of answering : 101 & 102;103 & 203.
-M relay activated continuously, only after answering : 101 & 201;103 & 104.
-M relay activated continuously, regardless of answering : 101 & 201;103 & 203.
a0 / b5 : for connection to an ALCa1 / b1 : for connection to a door opener or accoustic alarma2 / b2 : for connection to a door microphonea3 / b3 : for connection to a door telephone
117
FBC
317
124
a0b0a1b1a2b2a3b3
X1-2
106206
101201
X1-1
106206
101201X1-1 :
X1-2 :
101 & 201;103 & 203;104 & 204;106 & 206.105 & 106.
75
Also one of the two following ways of emergency service signalling (=operation of the M relay) must be selected by interconnecting the following pins of X1-2:- M relay activated intermitting while accoustic alarm is sounded : 101 & 102.
M relay activated continuously while accoustic alarm is sounded : 101 & 201.
5.7. ATU-ST
5.7.1. ATU-ST02/12
The ATU-Special Type 02 or 12 (ATU-ST02 or ATU-ST12) is a 2-wire line interface which connects the ISPBX system to a PSTN. The line signalling which is in use in this type of ATU is an asymmetrical type of signalling with different potentials on the a&b-wires. The signalling voltage is -60 V; it is derived from the PSU-D and supplied to the ATU-ST card via a line feed connector FCC and FCD.
Note: The ATU-ST02/12 type is subdivided into a version with 2 or 4 ATU-ST02/12 circuits.
Figure 5-18 Layout Front Connector FBC
If Metering Circuits are used (only for the 2 circuit versions), the outputs of the detectors are connected to the ATU-ST card via a separate front connector. The wires to the metering level detectors on the ATU card are MD1&2 and GND1&2.
X1-2
106206
101201
X1-1
106206
101201X1-1 :
X1-2 :
201 & 202;103 & 103;204 & 205;105 & 106.103 & 203;105 & 205
a0....3 : a-wires for trunk lines 0...3b0....3 : b-wires for trunk lines 0...3
117
FBC
317
4 Circuit version 2 Circuit version
124
a0b0a1b1a2b2a3b3
117
FBC
317
124
a0b0a1b1
76
Figure 5-19 Layout Front Connector FAA
5.7.2. ATU-ST03
The ATU-ST03 is a line interface which connects the ISPBX system to a PSTN. The DC line signalling can be done via 2 or 4-wires.
- 2-wire mode:signalling via the a/b wires- 4-wire mode:signalling in phantom mode via the a/b wires and c/d wires
The a/b and c/d wires of the ATU-ST are directly connected to the MDF via front connector FBC.
Figure 5-20 Layout Front Connector FBC
To adapt each of the four ATU-ST03 circuits to the 2-wire or 4-wire mode of operation the straps has to be set according to the table below.
MD1 & 2 : metering detector information from the metering circuitsGND1 & 2 : accompanying ground from the metering circuits
101
FAA
301
108
MD1GND1
MD2GND2
a0...3 : a-wires for trunk lines 0...3b0...3 : b-wires for trunk lines 0...3c0...3 : c-wires for trunk lines 0...3d0...3 : d-wires for trunk lines 0...3
117
FBC
317
124
a0b0a1b1a2b2a3b3
c0d0c1d1c2d2c3d3
77
In figure and figure below the straps LKA ... LKK are given as A ... K; the prefix indicates the circuit number; e.g. strap 3.D indicates strap LKD of circuit 3.
Table 5-29 Settings for 2-wire or 4-wire mode
The straps LKA ... LKK serve the following:
- LKA and LKB serve for the selection of DC signalling via the a and b wires (2-wire) or the a/b and c/d wires (4-wire).
- LKC and LKD select the source and terminating impedances.- LKE selects the transformer DC current cancellation for 2-wire mode.- LKF selects the duplexor circuit (hybrid) for the 2-wire mode.- LKG selects the level adaptors for the 2-wire or 4-wire mode.- LKJ and LKK serve for reversed connection of the polarized seizure detector, which is
necessary for correct functioning due to the cross connected a/b and c/d wires in the 4-wire mode.
- LKH determines whether the pads for an unamplified line are included or not in the 4-wire mode. For long line compensation or in case of an unamplified line the strap is absent, otherwise present.
In the figures below the circuits are strapped for unamplified lines.
STRAPS 2-WIRE MODE 4-WIRE MODE
LKA Absent Present
LKB Pin 1 & 2 Pin 2 & 3
LKC Pin 2 & 3 Pin 1 & 2
LKD Pin 2 & 3 Pin 1 & 2
LKE Pin 1 & 2 Pin 2 & 3
LKF Present Absent
LKG Present Absent
LKH Absent/Present Absent/Present
LKJ Pin 1 & 2 Pin 2 & 3
LKK Pin 1 & 2 Pin 2 & 3
78
Figure 5-21 ATU-ST03, 2-Wire Mode Strap Setting
Mark
BP
BB
FBC
2.B 2.A
3.C
2.K 2.J
4.K 4.J
1.B 1.J
1.K
1.A
1.G
1.H
1.D
1.F1.C1.E
2.H2.G2.E
2.D
4.D
2.F2.C
3.D3.H3.G
3.F4.E3.E
3.B
3.A 4.H
4.A
4.G3.K3.J
4.B
4.F4.C
79
Figure 5-22 ATU-ST03, 4-Wire Mode Strap Setting
5.7.3. ATU-ST26
The ATU-ST26 is a 3-wire bi-directional line interface which connects the ISPBX system to the final selector of a PSTN. The c-wire is used as test-wire. The line signalling which is in use in this type of ATU is an asymmetrical type of signalling with different potentials on the a&b-wires. The signalling voltage is -60 V; it is derived from the PSU-D and supplied to the ATU-ST card via a line feed connector FCC and FCD.
The a/b and c-wires of the ATU-ST are directly connected to the MDF via front connector FBC.
Mark
BP
BB
FBC
2.B 2.A
3.C
2.K 2.J
4.K 4.J
1.B 1.J
1.K
1.A
1.G
1.H
1.D
1.F1.C1.E
2.H2.G2.E
2.D
4.D
2.F2.C
3.D3.H3.G
3.F4.E3.E
3.B
3.A 4.H
4.A
4.G3.K3.J
4.B
4.F4.C
80
Figure 5-23 Layout Front Connector FBB
• Long Line Adjustment
Table 5-30 Long Line Adjustment
• Short Line Adjustment
Table 5-31 Short Line Adjustment
• Test/Hold Current
CIRCUIT INSTALLED OPEN INSTALLED
1 X1-1 X1-5 X2-1 / 101-102
2 X1-2 X1-6 X2-2 / 101-102
3 X1-3 X1-7 X2-3 / 101-102
4 X1-4 X1-8 X2-4 / 101-102
CIRCUIT INSTALLED OPEN INSTALLED
1 X1-5 X1-1 X2-1 / 102-103
2 X1-6 X1-2 X2-2 / 102-103
3 X1-7 X1-3 X2-3 / 102-103
4 X1-8 X1-4 X2-4 / 102-103
a0...3 : a-wires for trunk lines 0...3b0...3 : b-wires for trunk lines 0...3c0...3 : c-wires for trunk lines 0...3
109
FBB
309
116
a0b0a1b1a2b2a3b3
c0
c1
c2
c3
81
Table 5-32 Test/Hold Current
Figure 5-24 Strap Location on ATU-ST26
CIRCUIT 40/23 mA 22/12 mA
JUMPER INSTALLED ON JUMPER INSTALLED ON
1 X2-5 / 101-102 X2-5 / 102-103
2 X2-6 / 101-102 X2-6 / 102-103
3 X2-7 / 101-102 X2-7 / 102-103
4 X2-8 / 101-102 X2-8 / 102-103
Mark
BP
BB
X1.1
X1.3
FBB
X2.5
103
X2.1
101 103 101
X2.6
103
X2.2
101 103 101
X2.7
103
X2.3
101 103 101
X2.8
FCC
103
X2.4
101 103 101
X1.2
X1.4
X1.5 X1.6
X1.7 X1.8
FCD
-60V line signalling voltage
82
5.8. ATU-IL
The ATU-Inter-register L1 (ATU-IL) is a 4-wire line interface which connects the ISPBX system to another PBX. The signalling used is an inter-register signalling (L1) intended for long distances and connections via leased lines. It is an AC signalling system consisting of inband tone signals. Two unidirectional 2-wire links are used for transmission of both voice and signalling tone in either direction. Per link voice and signalling is never sent at the same time.
All wires of the ATU are directly connected to the MDF via front connector FBB.
Figure 5-25 Layout Front Connector FBB
5.8.1. ATU-IL01/IL03/IL13/IL31
The straps on these ATUs are used to select the short/long line operation and the direction: transmit or receive.
The first identifier of the straps (1 ... 4) indicates the ATU circuit 0 ... 3.
For all circuits the following applies:
- X.-1 : not installed : Long Line Outgoing (transmit);installed : Short Line Outgoing (transmit).
- X.-2 : not installed : Long Line Incoming (receive);installed : Short Line Incoming (receive).
- X.-3 : may never be installed (factory test only).- X.-4 : may never be installed (factory test only).
a0...3 : a-wires for trunk lines 0...3b0...3 : b-wires for trunk lines 0...3c0...3 : c-wires for trunk lines 0...3d0...3 : d-wires for trunk lines 0...3
109
FBB
309
116
a0b0a1b1a2b2a3b3
c0d0c1d1c2d2c3d3
83
Figure 5-26 Strap Location on ATU-IL01/IL03/IL13/IL31
5.8.2. ATU-IL23
The straps X1.1 ... X1.8. are used to select the long line (unamplified) or short line (amplified) application of the trunk lines; in figure below the straps are drawn for the short line application of all four trunk lines.
Mark
BP
BB
FBC
X1.4
X1.3X1.1
X1.2X2.3
X2.4X2.1
X2.2
X3.3
Build up board (ATU-IL 13 only)
X3.4
X4.4
X4.3 X4.1
X4.2
X3.2
X3.1
84
Table 5-33 Long Line and Short Line Adjustment
The straps X1.9 and X1.10 are used to select the type of signalling of all four trunk lines and to select a test mode.
Table 5-34 Signalling Type and Test Selection
LINE DIRECTION STRAP LONG LINE STRAP POSITION
SHORT LINE STRAP POSITION
0 Receive (outgoing) X1.1 101-102 102-103
Transmit (incoming) X1.2 101-102 102-103
1 Receive (outgoing) X1.3 101-102 102-103
Transmit (incoming) X1.4 101-102 102-103
2 Receive (outgoing) X1.7 101-102 102-103
Transmit (incoming) X1.8 101-102 102-103
2 Receive (outgoing) X1.7 101-102 102-103
Transmit (incoming) X1.8 101-102 102-103
LINE STRAP X1.9 STRAP X1.10
AC-15-A 101-102 102-103
AC-15-D / CEPT-L1 102-103 102-103
Selftest 101-102 101-102
Factory test 102-103 101-102
85
Figure 5-27 Strap Location on ATU-IL23
5.9. ATU-LB
An ATU-Local Battery (ATU-LB) is a 2-wire line interface which connects the ISPBX system to another PBX or a telephone set with local battery signalling. The a/b wires of the ATU-LB are directly connected to the MDF via front connector FBC.
Mark
BP
BB
FBC
103
101
X1.1
103
101
X1.2
103
101
X1.3
103
101
X1.4
103
101
X1.5
103
101
X1.6
103
101
X1.7
103
101
X1.8
103
101
X1.10
103
101
X1.9
86
Figure 5-28 Layout Front Connector FBC
Strap X1-1 is only valid for the ATU-LB01 with 12NC code 9562 151 4520 only. This version of ATU-LB01 is compatible with the already installed ATU-LB01: the strap must be placed on position 101 - 102.
To be able to use the PPU command interface of ATU-LB12 for ATU-LB01, strap X1-1 must be placed on position 102 - 103.
a0...3 : a-wires for trunk lines 0...3b0...3 : b-wires for trunk lines 0...3
117
FBC
317
124
a0b0a1b1a2b2a3b3
87
Figure 5-29 Strap Location on ATU-LB01
Mark
BP
BB
101102103
X1.1
ATU-LB01 PPU Type Module running
FBC
ATU-LB12 PPU Type Module running
88
5.9.1. ATU-LB12
Figure 5-30 Strap Location
The 50 Hz ringing current can be supplied either via the front connector (by PSU-F) or back panel connector.
5.10. ATU-G
The Analogue Trunk Unit-General (ATU-G) can replace a number of ATUs with signalling types AS (ALS70/EO), SS and PD; see the table below. Additionally the ATU-G provides the metering and emergency switch-over functions and therefore it can replace a few Metering
-Via front connector :X1-1 and X1-2 must be placed on position 102-103.-Via back panel connector:X1-1 and X1-2 must be placed on position 101-102.
Mark
BP
BB
FBC
103X1.1
101
BU2
BU1
X1.2103 101
89
Circuit (MC) and Metering Circuit-Emergency Switch-over Unit (MCE) boards.
Table 5-35 Boards Replaced by ATU-G
All a/b wires of the ATU are directly connected to the MDF via front connector FCA. Front connector FAD is used to connect the ALC and extension used for the ESU function.
COUNTRY ATU REMARKS MC(E)
International AS01 A/D/F/G
SS01
PD11
Italy AS21 Also combination possible: D
SS01 4xSS01 + 4xAS21
Belgium AS24 Also combination possible: F
SS04 4xAS24 + 4xSS02
Extra Long Line adaptation included
Netherlands AS0B Extra Long Line adaptation A
SS0B included
Switzerland AS2E SS0E replaces the PD2E. D
SS0E
PD2E
90
Figure 5-31 Layout Front Connector FAD & FCA
The 8 DIP switches (S1.1 ... S1.8) can be used to select the required signalling type and transmission plan; see the table below. When the DIP switches are used the information for initialisation of the ATU-G is loaded from a ROM on the board.
In the table below the DIP switches are depicted. See figure for the location of the DIP switches.
Note: The required signalling type and transmission plan can also be downloaded from the PPU with PPU package 142 or higher. Then all 8 switches must be set to OFFThe ATU-Gs support transmission rates up to 19.2 kbits/s. Note that this figure depends on other elements (e.g. the quality of the PSTN line). When higher rates are used, it is advised to test thoroughly in advance.
101 125
FCA FAD
301 325
108 132
a0b0a1b1a2b2a3b3
Ext-a0
ALC-a0b0
b0a1b1a2b2
Ext-
ALC-Ext-Ext-Ext-Ext-
a4b4a5b5a6b6a7b7
a0...7b0...7
ALC-a0...1ALC-b0...1Ext-a0...1Ext-b0...1
: a-wires for trunk lines 0...7: b-wires for trunk lines 0...7: a-wires for Extension lines 0 & 1: b-wires for Extension lines 0 & 1: a-wires for Extension lines 0 & 1: b-wires for Extension lines 0 & 1
91
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
ATU-SS04 no metering 0 0 0 1 0 0 0 1
ATU-SS04 16 kHz MD 0 0 0 1 0 0 1 0
Belgium ATU-AS24 no metering 0 0 0 1 0 0 1 1
4xAS24+ 4xSS04
16 kHz MD 0 0 1 1 0 0 1 1
ATU-SS04 no metering 0 0 1 0 1 0 1 1
Belgium-Extra Long Lines
ATU-SS04 16 kHz MD 0 0 1 0 1 1 0 0
ATU-AS24 no metering 0 0 1 0 1 1 0 1
4xSS04 + 4xAS24
16 kHz MD 0 0 1 1 0 1 0 1
ATU-SS01 no metering 0 0 0 0 0 0 0 1
ATU-SS01 50 Hz MD1 0 0 0 0 0 0 1 0
ATU-SS01 50 Hz MD2 0 0 0 0 0 0 1 1
International ATU-SS01 12 kHz MD1 0 0 0 0 0 1 0 0
ATU-SS01 12 kHz MD2 0 0 0 0 0 1 0 1
ATU-SS01 16 kHz MD1 0 0 0 0 0 1 1 0
ATU-SS01 16 kHz MD2 0 0 0 0 0 1 1 1
ATU-AS01 no metering 0 0 0 0 1 0 0 0
ATU-AS01 50 Hz MD1 0 0 0 0 1 0 0 1
International ATU-AS01 50 Hz MD2 0 0 0 0 1 0 1 0
ATU-AS01 16 kHz MD1 0 0 0 0 1 0 1 1
ATU-AS01 16 kHz MD2 0 0 0 0 1 1 0 0
ATU-PD11 no metering 0 0 0 1 0 1 0 0
ATU-PD11 50 Hz MD1 0 0 0 1 0 1 0 1
ATU-PD11 50 Hz MD2 0 0 0 1 0 1 1 0
International ATU-PD11 12 kHz MD1 0 0 0 1 0 1 1 1
ATU-PD11 12 kHz MD2 0 0 0 1 1 0 0 0
92
Table 5-36 Settings for Signalling Type and Transmission Plan for ATU-G
5.10.1. ATU-G2
The Analogue Trunk Unit-General (ATU-G2) resembles the ATU-G, however small adaptations have been made in order to agree with the requirements for Sweden and New
ATU-PD11 16 kHz MD1 0 0 0 1 1 0 0 1
ATU-PD11 16 kHz MD2 0 0 0 1 1 0 1 0
ATU-SS01 no metering 0 0 0 0 0 0 0 1
ATU-SS01 12 kHz MD 0 0 0 0 0 1 0 0
8xAS21 no metering 0 1 0 0 0 1 0 0
Italy 8xAS21 12 kHz MD 0 1 0 0 0 1 0 1
4xSS01 + 4xAS21
no metering 0 0 1 0 0 1 1 0
4xSS01 + 4xAS21
12 kHz MD 0 0 1 0 0 1 1 1
ATU-SS0B no metering 0 0 0 1 1 0 1 1
ATU-SS0B 50 Hz MD 0 0 0 1 1 1 0 0
Netherlands ATU-AS0B no metering 0 0 0 1 1 1 0 1
ATU-AS0B 50 Hz MD 0 0 0 1 1 1 1 0
ATU-SS0B no metering 0 0 1 0 1 1 1 0
Netherlands-Extra Long Lines
ATU-SS0B 50 Hz MD 0 0 1 0 1 1 1 1
ATU-AS0B no metering 0 0 1 1 0 0 0 0
ATU-AS0B 50 Hz MD 0 0 1 1 0 0 0 1
ATU-SS0E no metering 0 0 1 0 0 0 1 1
Switzerland ATU-SS0E 12 kHz MD 0 0 1 0 0 1 0 0
ATU-AS2E no metering 0 0 1 0 0 1 0 1
MD = Metering Detection
MD1 = MD High SensitivityMD2 = MD Low Sensitivity
1 = ON, 0 = OFF
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
93
Zealand. Metering is not possible with the ATU-G2. Emergency switch-over is available on the ATU-G2.
The table below shows the boards which can be replaced by the ATU-G2. See figure for the location of the DIP switches.
Table 5-37 Boards Replaced by ATU-G2
The 8 DIP switches (S1.1 ... S1.8) can be used to select the required signalling type and transmission plan; see the table below. When the DIP switches are used the information for initialisation of the ATU-G2 is loaded from a ROM on the board.
In the table below the DIP switches are depicted.
Note: The required signalling type and transmission plan can also be downloaded from the PPU with PPU package 142 or higher. Then all 8 switches must be set to OFF.
Table 5-38 Settings for Signalling Type and Transmission Plan for ATU-G2
5.10.2. ATU-G3
• ATU-G3 (9562 158 81000)The Analogue Trunk Unit-General 3 (ATU-G3) resembles the ATU-G, however small adaptations have been made in order to agree with the requirements for Germany, South Africa, Spain and China. Emergency switch-over is available on the ATU-G3. The firmware package is P104 or P105. Only in Spain package P200 is used.
COUNTRY ATU
New Zealand EL03NZ
Sweden SS01
PD07
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU - - - - - - 0 0 0 0 0 0 0 0
Sweden ATU-PD07 no metering 0 0 1 1 0 1 1 0
Sweden ATU-SS07 no metering 0 0 1 1 1 1 0 1
New Zealand ATU-PD23 no metering 0 0 1 1 0 1 1 1
1=ON; 0=OFF.
94
The table below shows the boards which can be replaced by the ATU-G3 (9562 158 81000):
Table 5-39 Boards Replaced by ATU-G3 (9562 158 81000)
The 8 DIP switches (S1.1 ... S1.8) can be used to select the required signalling type and transmission plan; see the table below. When the DIP switches are used the information for initialisation of the ATU-G3 is loaded from a ROM on the board.In the table below the DIP switches are depicted. See figure for the location of the DIP switches.
Note: The required signalling type and transmission plan can also be downloaded from the PPU with PPU package 142 or higher. Then all 8 switches must be set to OFF.
COUNTRY ATU METERING
Germany ATU-SS02 MC(E)-C
South Africa ATU-SS03 MC(E)-A/F
ATU-SS0K MC(E)-A/F
Spain ATU-PD1C/SS0C1) MC(E)-A/D1)The PD1C replaces the SS0C.
95
Table 5-40 Settings for Signalling Type and Transmission Plan for ATU-G3 (9562 158 81000)
The frequency ranges (freq. 2 and freq. 3) as mentioned in the table in the column 'Call Detect', indicate the frequency ranges of the ringing signals detected by the Call Detector. The Call Detector detects ringing signals within the following four selectable frequency ranges:
- Range 1:14...21 Hz;- Range 2:21...31 Hz;- Range 3:31...62,5 Hz;- Range 4:14...62,5 Hz (default).
• ATU-G3 (9562 158 81100)
REMARKS TYPE OF ATU
METERING CALL DETECT
SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - - - - 0 0 0 0 0 0 0 0
ATU-SS02 no metering Freq. 2 * 0 0 0 0 1 1 0 1
Germany ATU-SS02 16 kHz Freq. 2 * 0 0 0 0 1 1 1 0
ATU-SS02 no metering Freq. 3 * 0 0 0 0 1 1 1 1
ATU-SS02 16 kHz Freq. 3 * 0 0 0 1 0 0 0 0
China ATU-SS0F no metering 0 0 1 1 1 0 0 0
ATU-SS03 no metering 0 0 1 1 1 1 1 0
ATU-SS03 50 Hz 0 0 1 1 1 1 1 1
ATU-SS03 16 kHz 0 1 0 0 0 0 0 0
South Africa ATU-SS0K no metering 0 1 0 0 0 0 0 1
ATU-SS0K 50 Hz 0 1 0 0 0 0 1 0
ATU-SS0K 16 kHz 0 1 0 0 0 0 1 1
ATU-PD1C no metering 0 0 1 0 0 0 0 0
Spain ATU-PD1C 50 Hz 0 0 1 0 0 0 0 1
ATU-PD1C 12 kHz 0 0 1 0 0 0 1 0
France ATU-SS08 no metering 0 1 0 0 0 1 1 0
1=ON; 0=OFF.
* See text for explanation of the frequency ranges.
96
This board has the same characteristics as the 9562 158 81000 (mentioned in previous paragraph), but some requirements for Germany and Spain have been added. The firmware package used is P110 or higher. This package is not downwards compatible but it is applicable for all settings in table.
Table 5-41 Functionality of the ATU-G3 (9562 158 81100)
The ATU-G3 (9562 158 81100) replaces the following boards:
Compared with the replaced boards the ATU-G3 (9562 158 81100) offers for Belgium and the Netherlands a new functionality: special transmission behaviour for extra long trunk lines (ELL).
COUNTRY ATU-DDO ATU-DDOATU-DDI
ATU-DDI METERING/ES
International SS01/PD11 AS01 MC(E)-A, D, F, G
Belgium SS04 AS24 MC(E)-F
France SS08
Netherlands SS0B AS0B MC(E)-A
Spain PD1C MC(E)-A, D
Switzerland SS0E AS2E MC(E)-D
China SS0F
South-Africa SS03 MC(E)-A, F
South-Africa SS0K
MC(E)-A = 50 Hz Metering Circuit with ESU,
MC(E)-D = kHz Metering Circuit with ESU,
MC(E)-F = 16 kHz Metering Circuit with ESU,
MC(E)-G = 12 kHz Metering Circuit with ESU.
International :ATU-SS01, ATU-PD11, ATU-AS01;Belgium :ATU-SS04, ATU-AS24;Netherlands :ATU-SS0B, ATU-AS0B;Spain :ATU-SS0C;Switzerland :ATU-PD2E, ATU-AS2E;South-Africa :ATU-SS03
97
The DIP-switch settings are given in the table below. See figure for the location of the DIP switches.
Note: For the international transmission plan 01 an extra transmission level setting has been added for applications with digital P-sets. This option can be selected by projecting the next setting: Cpad=1 and Tpad=1.
98
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
ATU-SS04 no metering 0 0 0 1 0 0 0 1
ATU-SS04 16 kHz MD 0 0 0 1 0 0 1 0
Belgium ATU-AS24 no metering 0 0 0 1 0 0 1 1
4xAS24+4xSS04 16 kHz MD 0 0 1 1 0 0 1 1
ATU-SS04 no metering 0 0 1 0 1 0 1 1
Belgium-Extra Long Lines
ATU-SS04 16 kHz MD 0 0 1 0 1 1 0 0
ATU-AS24 no metering 0 0 1 0 1 1 0 1
4xSS04 + 4xAS24
16 kHz MD 0 0 1 1 0 1 0 1
China ATU-SS0F no metering 0 0 1 1 1 0 0 0
ATU-SS01 no metering 0 0 0 0 0 0 0 1
ATU-SS01 50 Hz MD1 0 0 0 0 0 0 1 0
ATU-SS01 50 Hz MD2 0 0 0 0 0 0 1 1
International ATU-SS01 12 kHz MD1 0 0 0 0 0 1 0 0
ATU-SS01 12 kHz MD2 0 0 0 0 0 1 0 1
ATU-SS01 16 kHz MD1 0 0 0 0 0 1 1 0
ATU-SS01 16 kHz MD2 0 0 0 0 0 1 1 1
ATU-AS01 no metering 0 0 0 0 1 0 0 0
ATU-AS01 50 Hz MD1 0 0 0 0 1 0 0 1
International ATU-AS01 50 Hz MD2 0 0 0 0 1 0 1 0
ATU-AS01 16 kHz MD1 0 0 0 0 1 0 1 1
ATU-AS01 16 kHz MD2 0 0 0 0 1 1 0 0
ATU-PD11 no metering 0 0 0 1 0 1 0 0
ATU-PD11 50 Hz MD1 0 0 0 1 0 1 0 1
ATU-PD11 50 Hz MD2 0 0 0 1 0 1 1 0
99
International ATU-PD11 12 kHz MD1 0 0 0 1 0 1 1 1
ATU-PD11 12 kHz MD2 0 0 0 1 1 0 0 0
ATU-PD11 16 kHz MD1 0 0 0 1 1 0 0 1
ATU-PD11 16 kHz MD2 0 0 0 1 1 0 1 0
France ATU-SS08 no metering 0 1 0 0 0 1 1 0
ATU-SS0B no metering 0 0 0 1 1 0 1 1
Netherlands ATU-SS0B 50 Hz MD 0 0 0 1 1 1 0 0
ATU-AS0B no metering 0 0 0 1 1 1 0 1
ATU-AS0B 50 Hz MD 0 0 0 1 1 1 1 0
ATU-SS0B no metering 0 0 1 0 1 1 1 0
Netherlands-Extra Long Lines
ATU-SS0B 50 Hz MD 0 0 1 0 1 1 1 1
ATU-AS0B no metering 0 0 1 1 0 0 0 0
ATU-AS0B 50 Hz MD 0 0 1 1 0 0 0 1
ATU-PD1C no metering 0 0 1 0 0 0 0 0
Spain ATU-PD1C 50 Hz MD 0 0 1 0 0 0 0 1
ATU-PD1C 12 kHz MD 0 0 1 0 0 0 1 0
ATU-SS03 no metering 0 0 1 1 1 1 1 0
South-Africa (old) ATU-SS03 50 Hz MD2 0 0 1 1 1 1 1 1
ATU-SS03 16 kHz MD1 0 1 0 0 0 0 0 0
ATU-SS0K no metering 0 1 0 0 0 0 0 1
South-Africa ATU-SS0K 50 Hz MD2 0 1 0 0 0 0 1 0
ATU-SS0K 16 kHz MD1 0 1 0 0 0 0 1 1
ATU-SS0E no metering 0 0 1 0 0 0 1 1
Switzerland ATU-SS0E 12 kHz MD 0 0 1 0 0 1 0 0
ATU-AS2E no metering 0 0 1 0 0 1 0 1
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
100
Table 5-42 Settings for Signalling Type and Transmission Plan for ATU-G3 (9562 158 81100)
5.10.3. ATU-G4
The ATU-G4 board has almost the same characteristics as the ATU-G3 (9561 158 81100) board but it has special adaptions to fulfil the Italian requirements.
The ATU-SS01 and the ATU-AS21 cover the international transmission plan, the ATU-SS0D and the ATU-AS2D cover a specific Italian transmission plan.
Table 5-43 Functionality of the ATU-G4
The settings of the DIP switches can be found in the table below. See figure for the location of the DIP switches.
ATU-AS2E no metering 0 0 1 0 0 1 0 1
MD = Metering Detection
MD1 = MD High SensitivityMD2 = MD Low Sensitivity
1 = ON, 0 = OFF
COUNTRY ATU-DDO ATU-DDI METERING/ES
TRANSM. PLAN
Italy SS01 AS21 X 1
Italy SS0D AS2D X D
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
101
Table 5-44 Settings for Signalling Type and Transmission Plan for ATU-G4
5.10.4. ATU-G5
The ATU-G5 board has the same characteristics as the ATU-G3 (9561 158 81100) board but it has special adaptions which cover the Brazilan transmission plan.
In Brazil the ATU-SS01 and the ATU-AS01 are succeeded by the ATU-SS0M/PD1M and the ATU-AS0M.
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
ATU-SS01 no metering 0 0 0 0 0 0 0 1
ATU-SS01 12 kHz MD 0 0 0 0 0 1 0 0
Italy 4xAS21+4xSS01
no metering 0 0 1 0 0 1 1 0
4xAS21+4xSS01
12 kHz MD 0 0 1 0 0 1 1 1
Italy ATU-AS21 no metering 0 1 0 0 0 1 0 0
ATU-AS21 12 kHz MD 0 1 0 0 0 1 0 1
ATU-SS0D no metering 0 0 1 1 1 0 0 1
ATU-SS0D 12 kHz MD 0 0 1 1 1 0 1 0
Italy 4xAS2D+4xSS0D
no metering 0 0 1 1 1 0 1 1
4xAS2D+4xSS0D
12 kHz MD 0 0 1 1 1 1 0 0
Italy ATU-AS2D no metering 0 1 0 0 1 0 1 0
ATU-AS2D 12 kHz MD 0 1 0 0 1 0 1 1
ATU-AS2E no metering 0 0 1 0 0 1 0 1
MD = Metering Detection 1 = ON, 0 = OFF
102
Table 5-45 Functionality of the ATU-G5
The ATU-G5 replaces in Brazil the STU-SS01, the ATU-SS01 + polarity detector and the ATU-AS01.
The DIP switches can be found in the table below. See figure for the location of the DIP switches.
Table 5-46 Settings for Signalling Type and Transmission Plan for ATU-G5
5.10.5. ATU-G6
The ATU-G6 board has the same characteristics as the ATU-G3 (9561 158 81100) board but it has special adaptions for Germany concerning the requirement specifications for trunk types. The ATU-G6 replaces the ATU-SS02 in Germany.
Table 5-47 Functionality of the ATU-G6
COUNTRY ATU-DDO ATU-DDOATU-DDI
TRANSM. PLAN
Brazil SS0M M
Brazil PD1M M
Brazil AS0M M
REMARKS TYPE OF ATU METERING SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - 0 0 0 0 0 0 0 0
ATU-SS0M no metering 0 1 0 0 0 1 1 1
Brazil ATU-AS0M no metering 0 1 0 0 1 0 0 0
ATU-PD1M no metering 0 1 0 0 1 0 0 1
ATU-AS2E no metering 0 0 1 0 0 1 0 1
MD = Metering Detection 1 = ON, 0 = OFF
COUNTRY ATU-DDO METERING/ES TRANSM. PLAN
Germany SS02 x 2
103
The DIP switch settings can be found in the table below. Refer to figure for the location of the DIP switches.
The default Call Detection (CD) frequency range is 14-62 Hz unless a different frequency has been specified.
Table 5-48 Settings for Signalling Type and Transmission Plan for ATU-G6
5.10.6. ATU-Gx Board layout
The layout of the ATU-Gx board (with the DIP switch locations) is given in the figure below.
REMARKS TYPE OF ATU
METERING CALL DETECT
SWITCH S1.1 2 3 4 5 6 7 8
Initialisation by PPU
- - - - - - - - - 0 0 0 0 0 0 0 0
ATU-SS02 no metering CDF2 0 0 0 0 1 1 0 1
Germany ATU-SS02 16 kHz MD CDF2 0 0 0 0 1 1 1 0
ATU-SS02 no metering CDF3 0 0 0 0 1 1 1 1
ATU-SS02 16 kHz MD CDF3 0 0 0 1 0 0 0 0
MD = Metering Detection CDF2 = CD Range 21-32 Hz
1 = ON
CD = Call Detection CDF3 = CD Range 32-64 Hz
0 = OFF
104
Figure 5-32 DIP Switch Location on the ATU-Gx
The ASU-G is for special projects only.
The Analogue Subscriber line Unit General (ASU-G) is a multi functional board which contains 16 trunk lines. These 16 two-wire analogue interfaces connect the SOPHO iS3000 system to the PSTN. Compared to the ATU-Gx, the ASU-G has no metering function and no emergency switch function. Also, the ring frequency, the ring detection level and the DC resistance range are not projectable.
The ASU-G supports two signalling types:
- Subscriber Signalling (SS): this is the signalling normally used between the PSTN and a subscriber. An ISPBX using the ASU-G subscriber signalling, is treated as a normal subscriber by the PSTN.
Mark
BP
BBFCA
Line connection
ESU connection
Factory testconnector
FAD
Off
OnS1
8 1
105
- Polarity Detect Signalling (PD): This signalling type takes also the polarity changes of the transmission line into account.
The ASU-G is designed according to the transmission standards as specified in ETSI ETS 300 004. Furthermore specific (country-dependent) parameter values are possible for:
- Input and output levels;- AC impedance;- Balance impedance.
The transmission table, which is country-dependent, is downloaded when the board is plugged in or switched on. Only downloading of a transmission plan is possible. Only one transmission plan can be active on the board.
The board contains one LED. During normal operation the LED is off. When the board is not operational or there is a hardware error during operation, the LED is on. Also when downloading takes place, the LED is on.
The ASU-G may be placed in any standard PCT position, maximum 2 boards per Unit Group.
The ASU-G has two F122 front connectors 16-pins (FAD and FCA) to connect to the subscriber lines.
Figure 5-33 Layout Front Connector FAD
a0......7 : a-wires for trunk lines 0....7b0......7 : b-wires for trunk lines 0....7
117
FAD
317
124
a0b0a1b1a2b2a3b3
a4b4a5b5a6b6a7b7
106
Figure 5-34 Layout Front Connector FCA
a8......15 : a-wires for trunk lines 8....15b8......15 : b-wires for trunk lines 8....15
117
FCA
317
124
a8b8a9b9
a10b10a11B11
a12b12a13b13a14b14a15B15
107
6. DIGITAL TRUNK UNITS
6.1. DTU-CC
The straps are used to connect the cable shields of the incoming and outgoing cable to ground or to leave the cable shields floating.
The cable shields are grounded, when the straps are on the positions as shown in the diagram below.
Figure 6-1 Strap Location DTU-CC
• Interface between DTU-CC and LTUThe interface between the DTU and the LTU comprises the following signals on front connector FBA:
Mark
BP
BB
FBD
FBA
FBB
FBC
X1.1
X1.2
Factorytest only
FC101
108
• Interface between DTU-CC and the Switching Network (SN)The interface between the DTU and the SN comprises the following signals on front connector FBB:
• Interface between DTU-CC and the PSC in the RPMThe interface between the DTU and the PSC in the RPM comprises the following signals on front connector FBC:
• Interface between the master DTU-CC and the slave DTU-CCThe interface between the master and slave DTU comprises the following signals on front connector FBD:
• Interface between DTU-CC and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC 101:
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing-LAS :LTU Alarm Signal
-DATALOC/I :Data from SN-DATALOC/O :Data to SN-LOCCLK :System Clock-LOCSYN :Frame Synchronization-LOCSENS :Switching Module Sense : is not really connected to the SN but
the sense detects the presence of the SN-DTU connection
-DATAREM/I :Data from PSC-DATAREM/O :Data to PSC-REMCLK :System Clock-REMSYN :Frame Synchronization-MASSENS :Master Slave Sense-REMSENS :Remote Sense
-MSLK :Clock from master DTU-MSSYN :Frame Synchronization from master DTU-SLCLK :Clock to slave DTU-SLSYN :Frame Synchronization to slave DTU
-RCS :Reference Clock Signal
109
Figure 6-2 Layout Front Connector FB
6.2. DTU-CA
The straps are used to connect the cable shields of the incoming and outgoing cable to ground or to leave the cable shields floating.
The cable shields are grounded, when the straps are on the positions as shown in the diagram below.
101
FBA
301
108109
FBB
309
116117
FBC
317
124125
FBD
325
132
TLI 120 OhmTLI 120 Ohm
Shield
TLI 75 OhmTLI 75 Ohm
LAS
TLO 120 OhmTLO 120 OhmShield
TLO 75 OhmTLO 75 Ohm
LOCCLKLOCCLKLOCSYNLOCSYN
DATALOC/IDATALOC/I
DATALOC/ODATALOC/O
REMCLKREMCLKREMSYNREMSYN
DATAREM/ODATAREM/O
DATAREM/IDATAREM/I
MSLK
MSSYN
LOCSYNLOCSYNMASSENS
SLCLK
SLSYN
REMSENSREMSENS
110
Figure 6-3 Strap Location DTU-CA
• Interface between DTU-CA and LTUThe interface between the DTU and the LTU comprises the following signals on front connector FBA:
• Interface between DTU-CA and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC 101:
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing-LAS :LTU Alarm Signal
-RCS :Reference Clock Signal
Mark
BP
BB
X1.1
Factorytest only
FC101
FBA
203 201
103 101
111
Figure 6-4 Layout Front Connector FBA
6.3. DTU-PR
The straps are used to connect the cable shields of the incoming and outgoing cable to ground or to leave the cable shields floating.
The cable shields are grounded, when the straps are on the positions as shown in the diagram below.
101
FBA
301
108
TLI 120 OhmTLI 120 Ohm
Shield
TLO 120 OhmTLO 120 OhmShield
TLI 75 OhmTLI 75 Ohm
LAS
TLO 75 OhmTLO 75 Ohm
112
Figure 6-5 Strap Location DTU-PR
• Interface between DTU-PR and LTUThe interface between the DTU and the LTU comprises the following signals on front connector FBA:
• Interface between DTU-PR and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC 101:
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing-LAS :LTU Alarm Signal
-RCS :Reference Clock Signal
Mark
BP
BB
X1.1
Factorytest only
FC101
FBA
203 201
103 101
113
Figure 6-6 Layout Front Connector FBA
6.4. DTU-PU
The Digital Trunk Unit for Primary Rate Universal (DTU-PU) can operate as a DTU-CA, DTU-CC or DTU-PR. There are two versions of the DTU-PU: version 1 and 2. The DTU-PU version 2 offers the DTU-CC networking applications when it is placed in a standard PCT position in the PM1100; this is not possible with version 1. You can recognize a DTU-PU version 2 by the presence of a DIP-switch marked "CC".
The DTU-PU carries a DIP switch block (S.1) and a group of eight straps (X1.1).
Table 6-1 Strap Settings X1.1
• Version 1(see table below.)The mode of operation (DTU-CA, CC or PR) of the DTU-PU is selected as follows:
- S1. : the functions are given in table(version 1) and table(version 2).- X1.1 : used to change the impedance of the transmission interface from 75 Ohm
to 120 Ohm and vice versa; see the table below.
STRAP X1.1 DEFAULT SETTING CHANGE
101-201 and 102-202 not placed : 120 Ohm Outgoing
placed : 75 Ohm Outgoing
103-203 and 104-204 not placed : 120 Ohm Incoming
placed : 75 Ohm Incoming
105-205 and 106-206 placed : 120 Ohm Outgoing not placed : 75 Ohm Outgoing
107-207 and 108-208 placed : 120 Ohm Incoming not placed : 75 Ohm Incoming
101
FBA
301
108
TLI 120 OhmTLI 120 Ohm
Shield
TLO 120 OhmTLO 120 OhmShield
TLI 75 OhmTLI 75 Ohm
LASGND
TLO 75 OhmTLO 75 Ohm
114
Table 6-2 DIP Switch Settings S1.1 ... S1.8 (DTU-PU version 1)
- DTU-CA : close switch S1.4 (enable the Channel Associated Mode);- DTU-CC : open switch S1.4 (disable the CA mode): when the DTU-PU is
placed outside a unit group, it operates as a DTU-CC;- DTU-PR : open switch S1.4 (disable the CA mode): when the DTU-PU is
placed in a unit group, it operates as a DTU-PR.
SWITCH
SIGNAL NAME
MEANING OPEN / OFF CLOSED / ON
S1.1 SH-BER Determines if French BER detection levels (shift BER) are used.
Disable shift BER *)
Enable shift BER
S1.2 EN-CLK Determines if backpanel clock reference is to be used (always clock signal at frontconnector).
No clock reference at back panel. *)
Clock also routed to back panel.
S1.3 SETLOOP Offers a remote test loop to the other side (DTU input connected to DTU output).
Disable remote test loop. *)
Enable remote test loop.
S1.4 CA-MODE Determines if DTU operates in the transparent mode or in CA mode.
Disable Channel Associated Mode. *)
Enable Channel Associated Mode.
S1.5 DIS-CRC Determines if 4 bit CRC check is used on bit 1 of TS0.
Enable CRC4. *)
Disable CRC4.
S1.6 Isolation purpose. - -
S1.7 SH-OUT Determines if outgoing transmission shield is connected to ground.
Outgoing shield not connected to GND.
Outgoing shield connected to GND.*)
S1.8 SH-IN Determines if incoming transmission shield is connected to ground.
Incoming shield not connected to GND.
Incoming shield connected to GND.*)
*) means 'default setting'.
115
• Version 2(see table below.)The mode of operation (DTU-CA, CC or PR) of the DTU-PU is selected as follows:
- DTU-CA : close switch S1.4 (enable the Channel Associated Mode);- DTU-CC : close switch S1.5 (enable the Common Channel mode);- DTU-PR : open switch S1.4 & S1.5 (disable the CA mode & CC mode).
116
Table 6-3 DIP Switch Settings S1.1 ... S1.8 (DTU-PU version 2)
Note: The DTU-PU version 2 must be configured as DTU-PR when it is used as
- a 'remote DTU-CC' in an RPM1100 or RPM255
- a 'local DTU-CC' for RPM connection in an iS3010, iS3030, iS3050.When the DTU-PU is used in an APNSS link it must be strapped as a DTU-PR. This
SWITCH
SIGNAL NAME
MEANING OPEN / OFF CLOSED / ON
S1.1 SH-BER Determines if French BER detection levels (shift BER) are used.
Disable shift BER. *)
Enable shift BER
S1.2 not used. - -
S1.3 SETLOOP Offers a remote test loop to the other side (DTU input connected to DTU output).
Disable remote test loop. *)
Enable remote test loop.
S1.4 CA-MODE Determines if DTU operates in the transparent mode or in CA mode.
Disable Channel Associated Mode. *)
Enable Channel Associated Mode.
S1.5 CC-MODE Determines if DTU operates in the transparent mode or in CC mode.
Disable Common Channel Mode. *)
Enable Common Channel Mode.
S1.6 DIS-CRC Determines if 4 bit CRC check is used on bit 1 of TS0.
Enable CRC4. *)
Disable CRC4.
S1.7 SH-OUT Determines if outgoing transmission shield is connected to ground.
Outgoing shield not connected to GND.
Outgoing shield connected to GND. *)
S1.8 SH-IN Determines if incoming transmission shield is connected to ground.
Incoming shield not connected to GND.
Incoming shield connected to GND. *)
*) means 'default setting'.
117
means that the CRC4 must be disabled. Set in the DTU-PU V1 switch S1.5 to ON and in the DTU-PU V2 switch S1.6 to ON.
Figure 6-7 Strap Location DTU-PU (strapped for 120 Ohm)
Figure 6-8 Detail of DIP Switch S1
It is possible to change the DIP switch settings while the board is in service. However it is recommended to put the board in 'not installed' (OM command SETNIN), change the settings of S1 and put the board back in service again (OM command SETINS).
Mark
BP
BA
BB
FBD
FBA
FBB
FBC
X1.1208
1
FC1011
Fuse (250mA)for connector FCD
FC1012
FC1013
S1
FCD
8108
201 101
Off
On
1 2 3 4 5 6 7 8
118
• Interface between DTU-PU and LTUThe interface between the DTU and the LTU comprises the following signals on front connector FBA:
• Interface between DTU-PU and the Switching Network (SN)The interface between the DTU and the SN comprises the following signals on front connector FBB:
• Interface between DTU-PU and the PMC/PSC in the RPMThe interface between the DTU and the PMC/PSC in the RPM comprises the following signals on front connector FBC:
• Interface between the master DTU-PU and the slave DTU-PUThe interface between the master and slave DTU comprises the following signals on front connector FBD:
• Interface between DTU-PU and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC1011:
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing-LAS :LTU Alarm Signal
-DATALOC/I :Data from SN-DATALOC/O :Data to SN-LOCCLK :System Clock (2,048 MHz)-LOCSYN :Frame Synchronization (8 kHz)-LOCSENS :Switching Module Sense : is not really connected to the SN but
the sense detects the presence of the SN-DTU connection.
-DATAREM/I :Data from PMC/PSC-DATAREM/O :Data to PMC/PSC-REMCLK :System Clock (2,048 MHz)-REMSYN :Frame Synchronization (8 kHz)-MASSENS :Master Slave Sense (sense point for master/slave operation)-REMSENS :Remote Sense (sense point for remote mode setting)
-MASCLK :Clock from master DTU-MASSYN :Frame Synchronization from master DTU-SLCLK :Clock to slave DTU-SLSYN :Frame Synchronization to slave DTU
-RCS :Reference Clock Signal (2,048 MHz)
119
The coaxial front connectors FC1012 and FC1013 are used to connect the 75 Ohm trunk lines to the LTU. The connector at position FC1012 is the output of the transmission interface and the connector at position FC1013 is the input. Note that this input and output are also available at position FBA (TLI & TLO 75 Ohm).
Figure 6-9 Layout Front Connector FB
• Interface between DTU-PU and NT1The interface between the DTU and NT1 multiplexing equipment comprises the -48V signal for power feeding to NT1 multiplexing equipment (fuse located above FCD, 250 mA).
Figure 6-10 Layout Front Connector FCD
101
FBA
301
108109
FBB
309
116117
FBC
317
124125
FBD
325
132
TLI 120 OhmTLI 120 Ohm
Shield
TLI 75 OhmTLI 75 Ohm
LASGND
TLO 120 OhmTLO 120 OhmShield
TLO 75 OhmTLO 75 Ohm
LOCCLKLOCCLKLOCSYNLOCSYN
DATALOC/IDATALOC/I
DATALOC/ODATALOC/O
REMCLKREMCLKREMSYNREMSYN
DATAREM/ODATAREM/O
DATAREM/IDATAREM/I
MASCLKGND
MASSYNGND
LOCSENSLOCSENSMASSENSMASSENS
SLCLKGNDSLSYNGND
REMSENSREMSENS
101
FCD
301
108
GND-48V
GND-48V
GND-48V
GND-48V
GND-48VGND-48VGND-48VGND-48V
To NTI multiplexing equipment
120
6.5. DTU-BA
The DTU-BA provides the interface between the digital switching system and a number of CCITT defined 192 kbit/s PCM lines, employing 2B+D, connected to an Integrated Services Digital Network (ISDN) exchange employing one of the following integrated networking protocol types: DPNSS/DASS or ISDN. Per DTU-BA seven trunk lines are available. The DTU-BA can operate either as Terminal Equipment (TE) or as Network Terminator (NT) in a network. Straps must be set to specify the TE or NT function:
- strap X4.1 is used for ISDN accesses 0 ... 2 or DPNSS circuits 2 ... 7;- strap X4.2 is used for ISDN accesses 3 ... 6 or DPNSS circuits 8 ... 15.
When changing over from TE to NT (or vice versa) also the projecting data has to be changed. Check the projecting data to see how the DTU-BA is projected.
• Terminal EquipmentWhen the DTU-BA is used as interface to the PSTN or another PBX it operates as a TE. It expects to receive an external clock reference from an NT to synchronise with. This means that a clock signal is available on frontconnector FC 101; this clock signal can be used as the input clock for a CRU, when necessary.One or both straps (X4.1 and/or X4.2) must be placed on positions 101-102.
• Network TerminatorWhen the DTU-BA is used as an NT, it operates as the master and it provides the synchronisation clock for the TE. This means that no clock signal is available on frontconnector FC 101.One or both straps (X4.1 and/or X4.2) must be placed on positions 102-103.
When two DTU-BAs form one transmission link (max. distance 1000 meters) one DTU-BA must be strapped as an NT and the other as a TE.
Note that ports 0...2 and port 3 are terminated on the FBA connector. Ports 4...6 are terminated at the FBB connector (see table below).
121
Table 6-4 Strap settings for NT or TE mode
STRAP TE (SLAVE) NT (MASTER)
PORT CONNECTOR
DPNSS CIRCUITS
0 FBA 2,3
X4.1 101-102 102-103 1 FBA 4,5
2 FBA 6,7
3 FBA 8,9
X4.2 101-102 102-103 4 FBB 10,11
5 FBB 12,13
6 FBB 14,15
122
Figure 6-11 Strap Location DTU-BA
The trunk lines are connected to the DTU-BA via the front connectors FBA and FBB. These connections are made via the MDF. The CRU is directly connected to the DTU-BA via a coaxial front connector at position FCA.
Mark
BP
BBX4.1
FBD
FBA
FBB
FBC
Factorytest only
FC101103102101
103102101
X4.2
123
Figure 6-12 Layout Front Connector FBA & FBB
6.6. DTU-PH
The Digital Trunk Unit-Protocol Handler (DTU-PH) converts an Integrated Networking protocol e.g. DPNSS1, DASS2 or 1TR6 into the Internal Message Protocol (IMP) and vice versa. The type of protocol that is handled is determined by the PROM package.
The DTU-PH carries a DIP switch block (S1.2), a group of eight straps (X4.1) and a group of five straps (X5.1).
-S1.2 : the functions are given in table below.-X4.1 : used to change the impedance of the transmission interface from 75 Ohm
to 120 Ohm and vice versa; see table below.-X5.1 : used to select the EPROM type; see figure below.
TX0...6 : Outgoing balanced linesRX0...6 : Incoming balanced lines
RX3 +
101
FBA
301
108
RX0 +
RX1 +
RX2 +
+
TX0
+
TX1+
TX2
+
TX3
101
FBB
301
108
RX4 +
RX5 +
RX6 +
+
TX4
+
TX5+
TX6
The positive poles of the RX/TX S interfaces are indicated with a“+a”. Theseindications do not refer to the polarity of the S interface phantom power supply.
0
0
124
Table 6-5 DIL Switch Settings S1.2.1 ... S1.2.8
SWITCH
SIGNAL NAME
MEANING OPEN / OFF CLOSED / ON
S1.2.1 SET-LP32 Offers a remote test loop to the other side (DTU input connected to DTU output).
Disable remote test loop. *)
Enable remote test loop.
S1.2.2 SET-LP31 Offers a local test loop (TS01 ... 31).
Disable local test loop. *)
Enable local test loop.
S1.2.3 CLK-REFB Determines if backpanel clock reference is to be used (always clock signal at frontconnector)
No clock reference at back panel. *)
Clock also routed to back panel.
S1.2.4 No function. - -
S1.2.5 No function. - -
S1.2.6 Isolation purpose. - -
S1.2.7 SH-OUT Determines if outgoing transmis-sion shield is connected to ground.
Outgoing shield not connected to GND.
Outgoing shield connected to GND. *)
S1.2.8 SH-IN Determines if incoming transmis-sion shield is connected to ground.
Incoming shield not connected to GND.
Incoming shield connected to GND. *)
*) means 'default setting'.
125
Table 6-6 Strap Settings X4.1
STRAP X4.1 DEFAULT SETTING CHANGE
101-201 and 102-202 placed : 120 Ohm Outgoing not placed : 75 Ohm Outgoing
103-203 and 104-204 placed : 120 Ohm Incoming not placed : 75 Ohm Incoming
105-205 and 106-206 not placed : 120 Ohm Outgoing
placed : 75 Ohm Outgoing
107-207 and 108-208 not placed : 120 Ohm Incoming
placed : 75 Ohm Incoming
126
Figure 6-13 Strap Location DTU-PH (strapped for 120 Ohm and 1 Mb EPROM)
Figure 6-14 Detail of DIP Switch S1.2
Figure 6-15 EPROM Type Selection (strap X5.1)
Mark
BP
BB
FBB
Factory testconnector
FC1011
Fuse (250mA)for connector FCD
FC1012
FC1013
FCD
1S1.2
8
X4.1201 101
208 108
X5.1201 101
204 104
Off
On
1 2 3 4 5 6 7 8
127
It is possible to change the DIP switch settings while the board is in service. However it is recommended to put the board in 'not installed' (OM command SETNIN), change the settings of S1.2 and put the board back in service again (OM command SETINS).
• Interface between DTU-PH and LTUThe interface between the DTU and the LTU comprises the following signals on front connector FBB:
Figure 6-16 Layout Front Connector FBB
• Interface between DTU-PH and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC1011:
The coaxial front connectors FC1012 and FC1013 are used to connect the 75 Ohm trunk lines to the LTU. The connector at position FC1012 is the output of the transmission interface and the connector at position FC1013 is the input. Note that this input and output are also available at position FBB (TLI & TLO 75 Ohm).
• Interface between DTU-PH and NT1The interface between the DTU and NT1 multiplexing equipment comprises the - 48V signal for power feeding to NT1 multiplexing equipment (fuse located above FCD, 250 mA).
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing
-RCS :Reference Clock Signal (2,048 MHz)
109
FBB
309
116
TLI 120 OhmTLI 120 Ohm
Shield
TLO 120 OhmTLO 120 OhmShield
TLI 75 OhmTLI 75 Ohm
GND
TLO 75 OhmTLO 75 Ohm
128
Figure 6-17 Layout Front Connector FCD
6.7. DTU-VC
The DTU-VC compresses a 64 kbit/s voice channel to a 16 kbps compressed channel. It is possible to send over one 64 kbit/s tie line three compressed voice channels, including framing and networking signalling.
Three of these compressed channels are combined on one DTU-VC line (64 kbps). There are 3 DTU-VC lines on a DTU-VC board, so a maximum of 964 kbps compressed voice channels can be handled via 3 DTU-VC 64 kbps lines.
The interface between the DTU-VC and up to three tie lines is provided by the TRunK board - Voice Compressed (TRK-VC). This TRK-VC is a plug on board and can be fitted onto a DTU-VC. When this board is used, the tie line interface can be selected (V.35 or G.703).
When the PPU software allows, the DTU-VC is able to use the loop back ports of the DTU-VC in order to use other ISPBX trunk ports. In this case the TRK-VC should not be installed.
The connection between two DTU-VCs can be made in two ways:
• Loopback Connection(without the TRK-VC)In this case the loopback channel is used and an existing digital route is used to transfer the 64 kbps channel(s) containing the 3 voice channels. This application uses other digital boards of the ISPBX to make a DTU-VC / DTU-VC connection. In this case the loopback channel is used to feed the 3 compressed voice channels to the backpanel as one 64 kbps channel.If the plug on board TRK-VC is absent this loopback is automatically made.
• TRK-VC ConnectionUsing the TRK-VC, which is a board plugged on the DTU-VC: this makes it possible to connect (G703 or V.35) 64 kbps tielines (DTU-VC lines). When the TRK-VC is present, the loopback line is de-activated. The connection in between the two DTU-VCs should be point-to-point.
101
FCD
301
108
GND-48V
GND-48V
GND-48V
GND-48V
GND-48VGND-48VGND-48VGND-48V
To NTI multiplexing equipment
129
If shielded cables are used to connect to the TRK-VC, the shields can be connected to ground using straps as shown in the table below.
Table 6-7 Meaning of strap X4.1 & X4.2
The software of the DTU-VC is stored in Flash EPROMs. Initially, this takes place in the factory. In the case that an update of the software is necessary, it can be downloaded via the PM bus.
Figure 6-18 Strap Location DTU-VC
STRAP POSITION STRAP X4.1 STRAP X4.2
101 - 102 connected DSP 2Mbit/s loopback testing
Clock source selectable (trunk 1, 2 or 3)
102 - 103 connected Normal operation Clock source is trunk 1
Mark
BP
BB
FC101Coaxial connector
LEDs
X4.1103 101
X4.2
103 101
103-102 = Normal Operation102-101 = Factory Loopback Test
130
Figure 6-19 Strap Location TRK-VC
FAA
FAB
FAC
101 X2.7
103
101 103X2.3X2.6X2.1
101 103X2.5X2.2X2.2
131
Table 6-8 Strap Settings for TRK-VC
The two connectors (X5.3 and 5.4) on the DTU-VC fit in the standard positions of the TRK-VC board. The other connectors on the DTU-VC board are currently not used. The tables below show the pin/signal allocation (RX means towards the PPU; TX means from the PPU).
STRAP G703 64 kbps LINES V.35 64 kbps LINES
101 - 102 102 - 103 101 - 102 102 - 103
X2.1 No screen connection
TX screen TRK 1 GND
Not allowed GND TRK 1
X2.2 No screen connection
RX screen TRK 2 GND
No screen connection
Screen to GND TRK 2
X2.3 No screen connection
TX screen TRK 3 GND
Not allowed GND TRK 3
X2.4 No screen connection
RX screen TRK 1 GND
No screen connection
Screen to GND TRK 1
X2.5 No screen connection
RX screen TRK 3 GND
No screen connection
Screen to GND TRK 3
X2.6 No screen connection
TX screen TRK 2 GND
Not allowed GND TRK 2
X2.7 Internal clock for TXD
Not allowed Not allowed External clock for TXD
* If shielded cables are used to connect to the TRK-VC, the shields can be connected to ground using straps as shown in the table.
132
Table 6-9 DTU-VC TTL Connector
Table 6-10 DTU-VC Power/Clock Connector
• Interface between the TRK-VC and the Tie linesThe connectors to the external lines are on the TRK-VC card. For some pins, the signals on the connector depends on the type of interface selected (V.35 or G.703). The connectors which can be reached at the front side, are three 16-pin connectors, located at the positions FAA, FAB and FAC. Position FAD is not present. The allocation of the pins is given in figure.To receive the reference clock signals there are two possibilities (depending on the straps of X4.2 on the DTU-VC):- The clock received via trunk 1 is always taken as the reference clock. This means that
trunk 1 always must be the first one to be used (advised strap setting);
ROW 1xx 2xx
01 GND GND
02 RXD1 TXD1
03 RXCLK1 TXCLK
04 RXD2 TXD2
05 RXCLK2 GND
06 RXD3 TXD3
07 GND RXCLK3
08 TRK Detect GND
ROW 1xx 2xx
01 GND INT_CLK
02 128 kHz +5V
03 GND +12V
04 256 kHz - 5V
05 GND - 12V
06 2.048 MHz GND
07 GND TXCLK1
08 TXCLK2 TXCLK3
133
- The TRK-VC searches for a connection with a tie line on the remote side. The first tie line connection made will be used as a clock reference.
In figurethe situation for V.35 is given. Note that in case of G.703 the connections indicated with asterisks have the following meaning:*) TXSCREEN_G703 and**) RXSCREEN_G703.
Figure 6-20 Front Connector Layout TRK-VC
• Clock Reference OutputWith the used voice compression and multiplexing techniques, frame slips could be noticeable. Therefore it is important that the ISPBX is synchronised with the network. For this purpose, a coaxial connector is accessible from the front of the DTU-VC. It provides a 2.048 MHz clock reference output.The clock reference output is derived from the network supplied clock which is taken from the a tie line (64 kbit/s). Depending on strap setting, this can be tie line 1 or the tie line which is used for the signalling. It is advised to select tie line 1 as clock reference source. The clock reference output may be connected to the appropriate SOPHO card to synchronise the ISPBX to the network clock. The clock reference signal is never used when the TRK-VC board is not fitted.
6.8. DTU-G
The Digital Trunk Unit Generic (DTU-G) can operate as a DTU-PU or a DTU-PH installed in all iS3000 systems with the exception of a SOPHO S2500 system or in (R)PM2500 shelves.Before the DTU-G is installed in a system, the protocol mode must be selected by means of the dipswitch (S1.1 till S1.3) on the board.
101
FAA
301
108109
FAB
309
116117
FAC
317
124
RXDA_V35_3RXDB_V35_3SCREEN_V35_3**DSR_V35_3RXCLKB_V35_3RXCLKA_V35_3RXDA_G703_3RXDB_G703_3
TXDA_V35_3TXDB_V35_3* GND_V35_3
RTS_V35_3TXCLKA_V35_3TXCLKB_V35_3TXDA_G703_3TXDB_G703_3
RXDA_V35_2RXDB_V35_2SCREEN_V35_2**DSR_V35_2RXCLKB_V35_2RXCLKA_V35_2RXDA_G703_2RXDB_G703_2
TXDA_V35_2TXDB_V35_2
* GND_V35_2RTS_V35_2
TXCLKA_V35_2TXCLKB_V35_2TXDA_G703_2TXDB_G703_2
RXDA_V35_1RXDB_V35_1SCREEN_V35_1**DSR_V35_1RXCLKB_V35_1RXCLKA_V35_1RXDA_G703_1RXDB_G703_1
TXDA_V35_1TXDB_V35_1* GND_V35_1
RTS_V35_1TXCLKA_V35_1TXCLKB_V35_1TXDA_G703_1TXDB_G703_1
GROUP 3
GROUP 2
GROUP 1
GROUP 3
GROUP 2
GROUP 1
134
Compared to its predecessors, the DTU-G supports downloading of operational packages.Downloading is only possible in DTU-PH mode, selected by the dipswitch (S1.1). The DTU-G does not support downloading in DTU-PU mode.
Table 6-11 DIP Switch Settings S1.1 ... S1.8
DIP Switch S1.6 has a direct relation to strap block X2.1 and is used to select a 120 ohm balanced interface or a 75 ohm unbalanced interface.
For a 120 ohm balanced interface:
- Set DIP switch S1.6 to OFF.- Put straps on X2.1 on pins 101/201, 102/202, 103/203 and 104/204. This selects the TLI
SWITCH
SIGNAL NAME
MEANING OFF ON
S1.1 BOARD MODE
Determines board mode DTU-PU see next tables *)
DTU-PH see next tables
S1.2 PROTOCOL MODE
Determines protocol mode see next tables *)
see next tables
S1.3 PROTOCOL MODE
Determines protocol mode see next tables*)
see next tables
S1.4 FRAMING MODE
Determines if 4-bit CRC check is used on bit 1 TS0
Enable CRC4 1) *)
Disable CRC4 1)
S1.5 Spare - -
S1.6 75 Input impedance 120 Ohm; see explanation below this table *)
75 Ohm; see explanation below this table
S1.7 SH-IN Incoming transmission shield Shield not connected to ground *)
Shield connected to ground
S1.8 SH-OUT Outgoing transmission shield Shield not connected to ground *)
Shield connected to ground
*) means 'default setting'1) switch S1.4 is only valid in DTU-PU mode
135
120 ohm and TLO 120 Ohm points of the FBA connector. See Figure 6-23 "Layout Front Connector FB".
For a 75 ohm unbalanced interface:
- Set DIP switch S1.6 to ON.- Put straps on X2.1 on pins 105/205, 106/206, 107/207 and 108/208. This selects either the
TLI 75 ohm and TLO 75 Ohm points of the FBA connector, see Figure 6-23 "Layout Front Connector FB" or the FC1012 and FC1013 connectors.
Table 6-12 DIP Switch Settings for protocol mode selection of DTU-G in DTU-PU mode
Table 6-13 DIP Switch Settings for protocol mode selection of DTU-G in DTU-PH mode
Board mode selection S1.1 S1.2 S1.3 Protocol mode selection
DTU-PU OFF OFF OFF PR
DTU-PU OFF OFF ON CC
DTU-PU OFF ON OFF CA
None 1) OFF ON ON None 1)
1) Non-valid settings of S1.1 to S1.3 results in the board NOT starting up
Board mode selection S1.1 S1.2 S1.3 Protocol mode selection
None 1) ON OFF OFF None 1)
DTU-PH ON OFF ON DPNSS/DASS
DTU-PH ON ON OFF ISDN (ETSI,QSIG,1TR6)
None 1) ON ON ON None 1)
1) Non-valid settings of S1.1 to S1.3 results in the board NOT starting up
136
Figure 6-21 Strap Location DTU-G (strapped for 120 Ohm)
Figure 6-22 Detail of DIP Switch S1
It is NOT possible to change the DIP switch settings while the board is in service. Therefore put the board in 'not installed' (OM command SETNIN), change the settings of S1 and put the board back in service again (OM command SETINS).
• Interface between DTU-G and LTUThe interface between the DTU and the LTU comprises the following signals on front
Mark
BP
BB
FBB
Factory testconnector
FC 1011
Fuse (T250mA 250V)for connector FCD
FC 1012
FCD
1S1
8
X2.1201 101
208 108
101 101
103 103
FBA
Connector for future use
FC 1013
Do not connect straps !
Off
On
1 2 3 4 5 6 7 8
137
connector FBA:
• Interface between DTU-G and the Switching Network (SN)The interface between the DTU and the SN comprises the following signals on front connector FBB:
• Interface between DTU-G and CRUThe interface between the DTU and the CRU comprises the following signal on front connector FC1011:
The coaxial front connectors FC1012 and FC1013 are used to connect the 75 Ohm trunk lines to the LTU. The connector at position FC1012 is the output of the transmission interface and the connector at position FC1013 is the input. Note that this input and output are also available at position FBA (TLI & TLO 75 Ohm).
-TLI :Trunk Line Incoming-TLO :Trunk Line Outgoing-LAS :LTU Alarm Signal
-DATALOC/I :Data from SN-DATALOC/O :Data to SN-LOCCLK :System Clock (2,048 MHz)-LOCSYN :Frame Synchronization (8 kHz)-LOCSENS :Switching Module Sense : is not really connected to the SN but
the sense detects the presence of the SN-DTU connection.
-RCS :Reference Clock Signal (2,048 MHz)
138
Figure 6-23 Layout Front Connector FB
• Interface between DTU-G and NT1The interface between the DTU and NT1 multiplexing equipment comprises the -48V signal for power feeding to NT1 multiplexing equipment (fuse located above FCD, 250 mA).
Figure 6-24 Layout Front Connector FCD
101
FBA
301
108109
FBB
309
116
TLI 120 OhmTLI 120 Ohm
Shield
TLI 75 OhmTLI 75 Ohm
LASGND
TLO 120 OhmTLO 120 OhmShield
TLO 75 OhmTLO 75 Ohm
LOCCLKLOCCLKLOCSYNLOCSYN
DATALOC/IDATALOC/I
DATALOC/ODATALOC/O
LOCSENSLOCSENS
101
FCD
301
108
GND-48V
GND-48V
GND-48V
GND-48V
GND-48VGND-48VGND-48VGND-48V
To NTI multiplexing equipment
139
7. LINE TERMINATING UNITS
7.1. LTU-2
The Line Terminating Unit-2 (LTU-2) is the unit between a Digital Trunk Unit (DTU) with 2 Mbit/s connection and the transmission line. The LTU-2 is mounted on a LTU-2 Mounting Unit. The LTU-2 Mounting Unit is an adaption board to adapt the unit to a PCT position. The LTU occupies two physical board positions.
Note: The LTU-2 is End-Of-Life, the LTU-C can be used instead: the LTU-C can bridge a longer distance than the LTU-2.
Figure 7-1 Front Layout of The LTU and U-Link Positions
LTU
130
FCB
FCD
Means led
Connector in :Upper position = normal operationLower position = test loop
Connector in :Upper position = test loopLower position = normal operation
Means U-links
Means Connector Position
LTU Mounting Unit
140
Figure 7-2 LTU Location on LTU Mounting Unit
Mark
COMPONENT SIDE
LTU
LTU MOUNTING UNIT
See figure 7.1.4.
BP
BA
FCD
FCB
141
Figure 7-3 Straps to be soldered.
Figure 7-4 Detail and Settings of U- links
• Line CharacteristicsThe characteristics of the line interface on the LTU-2 are according to the CCITT recommendations G.703. The maximum cable length between to LTUs is 1000 meters:
SOLDERING SIDE OF LTU
STATION CABLINGTRANSMIT SIDE
INPUT
STRAPS TO BE SOLDERED
A
C
G
F
H
B
D E
KJ
OUTPUT
UNBALANCED 75 OHM
BALANCED 120 OHM
A - C and D - E
A - B
F - H and J - K
F - G
BINARY ERROR RATE COMMAND
TRANSFERRED TO DTU
U-LINK INPOSITION
U1U1
U2
U3U4
U5
U6
U7
-NOT TRANSFERRED TO DTU
ALARM COMMAND
LOSS OF INPUT OR BINARY ERROR RATE >
NON-URGENTALARM
U5
BINARY ERROR RATE > 10- 5
ALARM INDICATION SIGNAL TO BE DELIVERED
AT>10 ALARM COMMAND- 5
U-LINK INPOSITION
U2
-CONSTANTLY, INDEPENDENT OF AN ALARM COMMAND
URGENTALARM
U3
U6
U4
U7
142
valid for coax cable with attenuation of -10 dB / km at 1Mhz.The LTU-2 is connected to a DTU and the Main Distribution Frame (MDF) by means of a cable. Each cable is plugged in at a front connector. Depending on the impedance of the DTU a 75 Ohms or a 120 Ohms connection can be used. The connection with the MDF has an impedance of 135 Ohms and is balanced.
• Interface between LTU-2 and DTUThe interface between the LTU and the DTU comprises the following signals:
• Interface between LTU-2 and MDFThe interface between the LTU and the MDF comprises the following signals:
• Back Panel InterfaceThe back panel connector on the LTU-2 carrier board is only used to derive power from the back panel. The only connector which is present is the BB connector. Therefore it is only possible to use this board in PCT positions. The following voltages are derived from the back panel:
• Front ConnectorsVia front connector FCB the connection between the LTU and the DTU is made. Front connector FCD connects the LTU and the MDF. The alarm interface of the LTU unit is converted into the OMC alarm signal for the DTU. This conversion is done on the carrier board.
-TLO : Trunk Line Outgoing-TLI : Trunk Line Incoming-OMC : Operating and Maintenance Center alarm
-TLOM : Trunk Line Outgoing via MDF-TLIM : Trunk Line Incoming via MDF
- - 48 V : Power for the LTU-2 unit- - 5V : Power for OMC output driver- +5V : Power for OMC output driver- Ground : Ground potential for all voltages
143
Figure 7-5 Layout LTU-2 Front Connector FAB & FAD on Carrier
• Alarm Indication and LEDsThe alarms are shown by means of three red LEDs (LA, LB & LC) at the front of the board. The Alarm Circuit is a part of the Supervising Section. The alarms generated by the Presence Detector and the Error Rate Detector are presented to the Alarm Circuit.If an alarm is applied to the Alarm Circuit the corresponding LED is lit.- LA:when there is a Loss Of Input (LOI) alarm- LB:when the Binary Error Rate (BER) is greater than 10-3
- LC:when the BER is greater than 10-5, measured in a predetermined period of time.
7.2. LTU-C
The Line Terminating Unit-Copper (LTU-C) is the unit between a Digital Trunk Unit (DTU) with 2 Mbit/s connection and the transmission line. The LTU-C is mounted on a LTU-C Mounting Unit. The LTU-C Mounting Unit comprises the LTU unit (type LAKU2M) and an adaption board to adapt the unit to a PCT position in a PM shelf.
The LTU on the board has a width of 56 mm. This means that the board requires four board positions in a shelf which has four board positions per Unit Group. In shelves with 2 PCT positions per Unit Group the LTU-C requires three board positions.
101
FCB
301
108
120 Ohm (a) 120 Ohm (b)
Shield TLOTLI
120 Ohm (a)120 Ohm (b)Shield
75 Ohm (a) * 75 Ohm (b) *
OMCShield
75 Ohm (a) * 75 Ohm (b) *
101
FCD
301
108
135 Ohm (a) 135 Ohm (b)
TLOM
* These signals are not present on the LTU mounting unit with the 12NC code: 9562 151 1210.
TLIM
135 Ohm (a)135 Ohm (b)
ShieldShield
ShieldShield
144
Figure 7-6 Front Layout of The LTU-C
Inside the LTU-C unit there are DIL switches and strap settings. If it is required to check the factory settings, consult the figure below and table. Note that these factory settings may not be changed.
LTU-C
100
Disconnecting Box
20V...75V
UB ( o u t )
-
Power
S2 m
LTU Mounting Unit
F2
F1
+
145
Figure 7-7 DIL Switches and Strap Settings on the LTU-C
Mark
CARRIER
LTU-C UNITBP
BB
8
DIL Switch S1
1
4
DIL Switch S31
M29
M31
X1.1102101
FAB
FAD
On Off
On Off
= Soldered strap X1-1 installed = Outgoing trunk line shield connected to groundX1-2 installed = incoming trunk line shield connected to ground= Changeable strap
M30S4M6
M34
M33 M32M3
M4 M5
M19 M18
M21 M20
X1.2102101
146
Table 7-1 Switch and Strap Settings
On the LTU-C carrier there are two strap settings; see figure.
Choose the setting which is required in your system.
SWITCH/STRAP FACTORY SETTING
S1.1 On
S1.2 Off
S1.3 Off
S1.4 Off
S1.5 On
S1.6 On
S1.7 On
S1.8 On
S3.1 On
S3.2 On
S3.3 Off
S3.4 Off
S4 Closed (on)
M31-M29-M34 M29-M34
M33-M30-M32 M30-M32
M4-M6 Closed
M3-M5 Closed
M18-M19 Closed
M20-M21 Closed
X1-1 : If installed, the cable shield of the trunk line interface outgoing is connected to Ground.If open, the cable shield of the trunk line interface outgoing is open (floating).
X1-2 : If installed, the cable shield of the trunk line interface incoming is connected to Ground.If open, the cable shield of the trunk line interface incoming is open (floating).
147
• Line CharacteristicsThe characteristics of the line interface on the LTU-C are according to the CCITT recommendations G.703. The maximum cable length between to LTU-Cs is 2500 meters with a cable with two 0,8 mm{sup2} wire pairs and a loss of 5... 10 dB in the MDF. The maximum allowed loss between two LTU-Cs is 40 dB.The LTU-C is connected to a Digital Trunk Unit and the Main Distribution Frame (MDF) by means of a cable. Each cable is plugged in at a front connector. The interface is a balanced (symmetrical) 120 ohms interface at the DTU side. The interface is 130 ohm balanced/symmetrical at the MDF side.
• Interface between LTU-C and DTUThe interface between the LTU and the DTU comprises the following signals:
The technical data of the TLO and TLI interface with the DTU are as follows:
• Interface between LTU-C and MDFThe interface between the LTU and the MDF comprises the following signals:
The technical data of the line interface are as follows:
• Back Panel InterfaceThe back panel connector on the LTU-C carrier board is only used to derive power from
-TLO : Trunk Line Outgoing-TLI : Trunk Line Incoming-OMC : Operating and Maintenance Centre alarm
-Bitrate : 2048 kbit/s 50 ppm.-Coding : HDB3-Automatic gain control (incoming) : 0 dB ... 6 dB-Output Voltage (mark peak) : 3 V, 10%-Line impedance : 120 ohm-Echo cancelling : 16 dB (0,1 MHz... 1 MHz)
10 dB (0,05 MHz... 1,5 MHz)
-TLOM : Trunk Line Outgoing via MDF-TLIM : Trunk Line Incoming via MDF
-Bitrate :2048 kbit/s 50 ppm.-Coding :HDB3-Automatic gain control (incoming) :5 dB ... 40 dB (at 1 MHz)-Output Voltage (mark peak) :2,36 V, 10%-Line impedance :130 ohm-Echo cancelling :16 dB (0,1 MHz... 1 MHz)
148
the back panel. The only connector which is present is the BB connector. Therefore it is only possible to use this board in PCT positions. The following voltages are derived from the back panel:
• Front ConnectorsVia front connector FA (position FAB) the connection between the LTU and the DTU is made. Front connector FB (position FAD) connects the LTU and the MDF. The alarm interface of the LTU-C unit is converted into the OMC alarm signal for the DTU. This conversion is done on the carrier board.
Figure 7-8 Layout LTU-F Front Connector FAB & FAD on Carrier
• Disconnecting BoxAt the front side of the LTU-C unit there is a disconnecting box. By means of this box the incoming and outgoing DTU lines can be disconnected.
- - 48 V : Power for the LTU-C unit- - 5V : Power for OMC output driver- +5V : Power for OMC output driver- Ground : Ground potential for all voltages
101
FAB
301
108
120 Ohm (a) 120 Ohm (b)
Shield
TLOTLI120 Ohm (a)120 Ohm (b)Shield
OMC
101
FAD
301
108
130 Ohm (a) 130 Ohm (b)
Shield *
TLOM
* Can be disabled/enabled by means of straps
TLIM 130 Ohm (a)130 Ohm (b)Shield *
OMC
149
Figure 7-9 Line Assignments on Disconnecting Box
• Alarm Indication and LEDsThe Alarm Circuit is a part of the Supervising Section. The alarms generated by the Presence Detector and the error Rate Detector are presented to the Alarm Circuit; see table below.
Table 7-2 Alarm Indications and Actions
7.3. LTU-F
The Line Terminating Unit-Fibre (LTU-F) is the unit between a Digital Trunk Unit (DTU) with 2 Mbit/s connection and a glass fibre transmission line. The LTU-F is mounted on a LTU-F
SIGNAL DIRECTION IN LTU-C
FAULT DESCRIPTION
AIS LED ALARM OUTPUT
TO MDF
TO DTU
PWR F1 F2 OMC
- - Normal operation - - - - On - - - - - -
From MDF to DTU
No input present - - AIS On On - - Active
Bit failure >10-3 - - AIS On On - - Active
AIS on input - - AIS On Blinking
On - -
From DTU to MDF
No input or Bit failure >10-3
AIS - - On - - On Active
AIS on input AIS - - On - - Blinking
- -
- - No Power - - - - - - - - - - Active
S (F2)2 m LTU-C SIDE
1
2
3
4
5
6
TLI (b)
TLI (a)
Shield
Shield
TLO (b)
TLO (a)
DTU LINE SIDE
150
Mounting Unit. The LTU-F Mounting Unit comprises the LTU unit (type LAGF2M) and an adaption board to adapt the LAGF2M to a PCT position in a PM shelf.
The LTU on the board has a width of 56 mm. This means that the board requires four board positions in a shelf which has four board positions per Unit Group. In shelves with 2 PCT positions per Unit Group the LTU-F requires three board positions.
Figure 7-10 Front Layout of The LTU-F
Inside the LTU-F unit there are DIL switches and strap settings. If it is required to check the factory settings, consult the figure and following tables.
Note that these factory settings may not be changed !!!
LTU-F
100
Disconnecting Box
UB
2 0 . . . 7 5 V
Power
S2 m
LTU Mounting Unit
F2
F1
F2
151
Figure 7-11 DIL Switches and Strap Settings on the LTU-F
Mark
CARRIER
LTU-F UNITBP
BB
DIL Switch S3.1
S3.8
DIL Switch S3.1FABOff Onf
Off On
= Soldered strap
M6 M3M4 M5
M19
M21 M20
S3.4
M18
152
Table 7-3 Switch and Strap Settings (LTU-F version 1)
SWITCH/STRAP FACTORY SETTING
S1.1 On
S1.2 On
S1.3 On
S1.4 Off
S1.5 Off
S1.6 Off
S1.7 Off
S1.8 Off
S3.1 On
S3.2 On
S3.3 Off
S3.4 Off
M4-M6 Closed
M3-M5 Closed
M18-M19 Closed
M20-M21 Closed
153
Table 7-4 Switch Settings for NT-PRA Mode (LTU-F version 2)
Table 7-5 Switch Settings for Unstructured LT Mode (LTU-F version 2)
SWITCH ON / OFF NT-PRA MODE (Factory Setting)
S1.2 ON CRC4 evaluation at S2Min deactivated
OFF 1) CRC4 evaluation at S2Min activated
S1.5 ON Sa6 = 1100 for S2M alarm
OFF 1) Sa6 = 1000 for S2M alarm
S1.7 ON Sa5 and Sa6 bits : transparent
OFF 1) Sa5 and Sa6 bits : insert new
S1.8 OFF 1) NT-PRA mode
S3.1 ON Clock output T3out activated
OFF 1) Clock output T3out deactivated
S3.2 ON Reporting of CRC4 errors at S2M in Sa6 bit activated
OFF 1) Reporting of CRC4 errors at S2M in Sa6 bit deactivated
S3.4 ON UG2 transmit clock derived from UG2in
OFF 1) UG2 transmit clock derived from S2Min1) = normal setting in each mode
All other switches must be OFF
SWITCH ON / OFF UNSTRUCTURED LT MODE
S1.7 ON UNSTRUCTURED LT MODE
S1.8 ON
All other switches must be OFF
154
Table 7-6 Switch Settings for LT-PRA Mode (LTU-F version 2)
• Line CharacteristicsThe characteristics of the line interface on the LTU-F are according to the CCITT recommendations G.703. The maximum cable length between to LTU-Fs depends on the loss factor of the glass fibre. The maximum allowed loss between two LTU-Fs is 24 dB.If a cable is used with a loss of 0,5 dB/km and a reserve of 5 dB is assumed, the maximum cable length will be 38 km. The reserve of 5 dB can be necessary to assure proper operation. If no reserve factor is taken into account, the maximum cable length is 48 km (loss factor of 0,5 dB/km).The LTU-F is connected to a DTU by means of cable and at the line side directly connected to a glass fibre cable. The DTU cable is plugged in at a front connector on the LTU-F carrier board. The glass fibre connectors are positioned at the LTU-F unit which is mounted at the carrier. The connectors are accessible at the front side.The interface to the DTU is a balanced (symmetrical) 120 ohms interface with a wiring for alarm signalling.
• Interface between LTU-F and DTUThe interface between the LTU and the DTU comprises the following signals:
The technical data of the TLO and TLI interface with the DTU are as follows:
SWITCH ON / OFF LT-PRA MODE
S1.2 ON Test loop detection deactivated
OFF 1) Test loop detection activated
S1.3 ON Alarm pattern AIS at V2Mout or UG2out
OFF 1) Alarm pattern AUXP at V2Mout or UG2out
S1.7 OFF 1) LT-PRA mode
S1.8 ON 1)1) = normal setting in each mode
All other switches must be OFF
-TLO : Trunk Line Outgoing-TLI : Trunk Line Incoming-OMC : Operating and Maintenance Centre alarm
-Bitrate : 2048 kbit/s 50 ppm.-Coding : HDB3
155
• Glass Fibre InterfaceThe glass fibre interface comprises the following signals:
The technical data of the line interface are as follows:
• Back Panel InterfaceThe back panel connector BB on the LTU-F carrier board is only used to derive power from the back panel. Therefore it is only possible to use this board in PCT positions. The following voltages are derived from the back panel:
• Front ConnectorsIn addition to the front connector FAB, there are two glass fibre connectors at the front
-Automatic gain control (incoming) : 0 dB ... 6 dB-Output Voltage (mark peak) : 3 V, 10%-Line impedance : 120 ohm-Echo cancelling : 16 dB (0,1 MHz... 1 MHz)
10 dB (0,05 MHz... 1,5 MHz)
-TLO : Trunk Line Outgoing via MDF-TLI : Trunk Line Incoming via MDF
-Bitrate : 2048 kbit/s 50 ppm.-Automatic gain control (incoming) : - 8 dB ... - 35 dB-Connector type : DIN 47256•Pigtail transmitter side : Single mode glass fibre diameter 9 ... 10 m•Pigtail receiver side : Multi mode glass fibre with diameter 50 3 m-Fibre type:•Single Mode FibreGlass fibre diameter : 9 ... 10 mShield diameter : 125 m•Multi Mode FibreGlass fibre diameter : 47 ... 53 m and 62,5 3 mShield diameter : 125 m-Wave length (transmitter) : within range 1270 ... 1340 nm-Band width (transmitter) : < 10 nm
- - 48 V :Power for the LTU-F unit- - 5V :Power for OMC output driver- Ground :Ground potential for all voltages- +5V :Power for OMC output driver
156
side of the LTU-F unit for the line connections. The alarm interface of the LTU-F unit is converted into the OMC alarm signal for the DTU. This conversion is done on the LTU-F carrier board.
Figure 7-12 Layout LTU-F Front Connector FAB on Carrier
• Disconnecting BoxAt the front side of the LTU-F unit there is a disconnecting box. By means of this box the incoming and outgoing DTU lines can be disconnected.
Figure 7-13 Line Assignments on Disconnecting Box
• Alarm Indication and LEDsThe Alarm Circuit is a part of the Supervising Section. The alarms generated by the Presence Detector and the error Rate Detector are presented to the Alarm Circuit; see table below.
101
FAB
301
108
120 Ohm (a) 120 Ohm (b)
Shield
TLOTLI120 Ohm (a)120 Ohm (b)Shield
OMC
S (F2)2 M LTU-F SIDE
1
2
3
4
5
6
TLI (b)
TLI (a)
Shield
Shield
TLO (b)
TLO (a)
DTU LINE SIDE
157
Table 7-7 Alarm Indications and Actions
SIGNAL DIRECTION IN LTU-F
FAULT DESCRIPTION
AIS LED ALARM OUTPUT
TO MDF
TO DTU
PWR F1 F2 OMC
- - Normal operation - - - - On - - - - - -
From Fibre to DTU
No input present - - AIS On On - - Active
Bit failure >10-3 - - AIS On On - - Active
AIS on input - - AIS On Blinking
On - -
From DTU to fibre
No input or bit failure >10-3
AIS - - On - - On Active
AIS on input AIS - - On - - Blinking
- -
- - No Power - - - - - - - - - - Active
158
8. METERING CIRCUIT AND EMERGENCY SWITCH-OVER UNITS
The Metering Circuit (MC) is used to detect the metering pulses from the public exchange and to pass the metering information on via the Analogue Trunk Unit (ATU) to the Peripheral Control.
The metering circuits are also available in combination with the Emergency Switch over Units, the so called MCE boards.
8.1. MC(E)-D (16 circuit version)
The MC(E)-D (16 circuit version) is used to detect the 12 kHz metering pulses sent by the public exchange.
The sensitivity of the MC(E)-D board can be selected (using strap X3.1) to match the electrical specifications of the metering pulses as defined by the local PTT; see table below.
Table 8-1 Strap Settings MC(E)-D
8.2. MC(E)-F
The MC(E)-F board contains 16 metering detection circuits to detect the 16 kHz metering pulses sent by the public exchange.
The sensitivity of the MC(E)-F board can be selected (using strap X3.1) to match the electrical specifications of the metering pulses as defined by the local PTT; see table below.
STRAP X3.1 LEVEL (mV)
101-201 33
102-202 42.5
103-203 66
104-204 75
159
Table 8-2 Strap Settings MC(E)-F
8.3. MC(E)-G
The MC(E)-G contains 16 metering detection circuits to detect the 12 kHz metering pulses sent by the public exchange.
Each detector is equipped with a band stop filter to attenuate the metering pulses towards the ATU. The detector impedance is 240 Ohm at 12 kHz.
The sensitivity of the MC(E)-G board can be selected (using strap X3.1) to match the electrical specifications of the metering pulses as defined by the local PTT; see table below.
Table 8-3 Strap Settings MC(E)-G
STRAP X3.1 LEVEL (mV)
101-201 46
102-202 75
103-203 not used
104-204 not used
STRAP X3.1 SENSITIVITY (mV)
OPEN CIRCUIT TERMINATED CIRCUIT (240 Ohm)
101-201 50 25
102-202 110 55
103-203 140 70
104-204 200 100
160
Figure 8-1 Strap Location on the MC(E)-D, MC(E)-F and MC(E)-G
8.4. ESU-LG
The ESU-LG contains 16 Emergency Switch Over circuits. In case of system failures (e.g. power down) the ESU connects a trunk line (with Subscriber Signalling) directly to an internal line. When the operational state is restored, the lines that are busy are guarded by the loop circuit and held in the emergency state. This prevents a busy line to be disconnected when the system becomes operational again. When the line becomes free, the extension is connected to the ALC and the trunk line to the ATU. This loop guarding option can be disabled by putting strap X1.1 on position 102-103.
Mark
BP
BB
X3.1
201
FBD
FBA
FBB
FBC
FAD
FAA
FAB
FAC
FCD
FCA
FCB
FCC
204
101104
161
Figure 8-2 Strap Location on ESU-LG (Strap on position Loop Guarding Active)
Mark
BBX1.1
FAD (Trunk)
FAA (ALC)
FAB (Extension)
FAC (ATU)
FCD (Trunk)
FCA (ALC)
FCB (Extension)
FCC (ATU)
101103
162
9. MODEM LINE UNIT
On an MLU card the following switches and jumper pads are present; see figure below :
- 8 DIL switches (S1.1... S1.8.), each comprising 8 positions;- 8 jumper pads (X1.1... X1.8.) for 2 or 4 wire selection;- 4 jumper pads (X2.1... X2.4.) for the selection of the detection level.
Figure 9-1 Location of DIL Switches and Jumper Pads
For each of the four MLU channels 2 switches and 2 jumper pads are reserved. Selection of modem and configuration parameters are done via the DIL switches. Selection of 2 or 4 wire use is done via the jumper pads.
• DIL SwitchesPer MLU channel the following DIL switches are reserved:
Mark
BP
BB
FBD
FBA
FBB
FBC
FCD
FCA
FCB
FCC
X1.1
X2.1
S1.5
X1.2
X1.3
X1.4
X1.5
X1.6
X1.7
X1.8
X2.2
X2.3
X2.4
S1.6 S1.7 S1.8
S1.1 S1.2 S1.3 S1.4
163
- Channel 0:S1.3 and S1.4;- Channel 1:S1.1 and S1.2;- Channel 2:S1.7 and S1.8;- Channel 3:S1.5 and S1.6;The DIL switches for one MLU channel are arranged according to figure below.Switches 13... 16 are reserved for future extensions.
Figure 9-2 DIL Switches for One MLU Channel
For setting the specific parameters like transmission speed, synchronous or asynchronous data transfer etc. for each MLU channel, consult figure and figure and follow the flow diagram in figure.
Note: Some modem types requires a delayed operation of CT108; this can be selected by setting switch 12 ON.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16On
Off
164
Figure 9-3 Setting the DIL-switches for One MLU Channel
• 2/4 wire selectionPer MLU channel the following jumper pads are reserved:
MLUDIP-switches
END
LegendCT 106 - V.24 signal CTSCT 109 - V.24 signal DCD
S5= on ;
Modemsends V.25
answer tone
Speed
6001200240048009600
1920038400480005600064000S7 = off
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
S8 = off
CT106 orCT109 = V.25
answer
S10 = off
Answer tone = 2100Hz
S6 = off 2225HzS6 = on
S9 = onS10 = on
S11 = on
S9 = off S9 = on
Modemsends V.25calling tone
S12 = on S12 = off
CT108 delayed(or MODEMSwith dial unit)
S7 = on
S1
onoffononononoffonoffon
S2
offononoffononoffoffonon
S3
offoffoffononoffonononon
S4
offoffoffoffoffononononon
S8= on
S11 = off
165
- Channel 0:X1.1 and X1.2;- Channel 1:X1.3 and X1.4;- Channel 2:X1.5 and X1.6;- Channel 3:X1.7 and X1.8.Both jumpers for one MLU channel should not be set into the same direction.- 2 wire selection:
X1.1, X1.3, X1.5 and X1.7 jumper placed on left hand pins.X1.2, X1.4, X1.6 and X1.8 jumper placed on right hand pins.
- 4 wire selection:X1.1, X1.3, X1.5 and X1.7 jumper placed on right hand pins.X1.2, X1.4, X1.6 and X1.8 jumper placed on left hand pins.
Figure 9-4 2 - Wire Selection
Figure 9-5 4 - Wire Selection
• Detection levels (answertone)The detection levels are adjustable per MLU channel.The following jumper pads are reserved:- Channel 0:X2.1;- Channel 1:X2.2;- Channel 2:X2.3;- Channel 3:X2.4.
X1.1X1.2X1.3X1.4X1.5X1.6X1.7X1.8
X1.1X1.2X1.3X1.4X1.5X1.6X1.7X1.8
166
Jumper placed on top pins : detection level = -25 dBr;Jumper placed on middle pins : detection level = -28 dBr;Jumper placed on bottom pins : detection level = -31 dBr.
167
10. RECEIVER SENDER FOR TONES
10.1. RST-KD-1C
There are two straps for test purposes; with these straps it is possible to test the two SKTs by sending a continuous tone instead of a tone burst.
Figure 10-1 Strap Location
-Sender keytone 06 : strap on 101-201 : burst tone;strap on 102-202 : continuous tone.
-Sender keytone 07 : strap on 103-203 : burst tone;strap on 104-204 : continuous tone.
Mark
BP
BB
X1.2
101104
201204
168
10.2. RST-SL
There are two straps on the RST-SL which are used to determine the whether the RST-SL is used for the French transmission plan or the Spanish transmission plan.
Figure 10-2 Strap Location
-French transmission plan : X1.1. strap on 102-103;X1.3. strap on 102-103.
-Spanish transmission plan : X1.1. strap on 101-102;X1.3. strap on 101-102.
Mark
BP
BB
101
103
X1.3
101
X1.1
103
169
11. INTEGRATED ANNOUNCEMENT SERVER
The Integrated Announcement Server (IAS) is a printed wiring board in an ISPBX shelf, providing announcements to applications like ACD and 'announcements on incoming trunks'. The IAS is controlled by the ISPBX CPU. Control information is exchanged between the CPU and the IAS via an IMP channel. Time slot 0 of the USO/USI interface of the IAS is used for IMP communication. Timeslot 1 is used for recording or listening to the announcements. The IAS has a direct connection to the Switching Network via a cable to an SCU or to an INC.
The Integrated Announcement Server - Autonomous (IASA) is based on the same hardware as the IAS board. The firmware differs between the IAS and the IASA and therefore the functionality. The IASA must be projected as a DLC-C board (14 or 30 ports) in the Unit Group. In contradiction to the IAS board, it cannot have a direct connection to the Switching Network although a connector for this purpose is present.
• Front Connector FACThe connection between the IAS and the Switching Network is done via front connector FAC. The IASA does not use this front connector but uses the USI/USO interface of the back panel. Strap X3.2. (see below) is used to select which interface is to be used.
• Front Connector FCCThere is V.24 circuitry on the IAS circuit board; it is accessed via front connector FCC. Standard bitrates from 300 to 9600 are permitted. The V.24 connector is intended for connection of a PC that is running IAS Download software or IAS Manager software. Connection can be made directly to front connector FCC or via a dialled connection using a LAM and SOPHO-SET.
• Strap X 3.1.The IAS circuit board is normally supplied with the NiCad batteries fitted but with the charging circuit disconnected. This ensures that the batteries retain their fully charged state while the circuit board is being transported or while it is not in use.Before the board is put into use, the charging circuit must be connected, so the battery charge is continuously maintained.
• Strap X 3.2.Strap X3.2. is used to select which interface is to be used.
-Batteries connected : Strap on position 101/102 (normal operation);-Batteries disconnected : Strap on position 102/103
-SCU/INC interface from connector FAC (IAS) :
strap on position 102 & 103. (this position is not allowed in case the IASA firmware is installed on the board)
-2Mbit/s PM bus from backpanel (IASA) :
strap on position 101 & 102. (for all ISPBXs)
170
Figure 11-1 Strap Location IAS and IASA
Mark
BP
BB
BA
FAC
V.24connector
to PC
to SN
BIST
FCC
1
X4.1
X5.1X1.1
Factorytest only
Extra memory board 3
Extra memory board 2 Extra memory board 1
8
X3.1103 101
X3.2103 101
120
X6.3
X2.5
1
120X2.6
324
120
X6.2
X2.3
1
120X2.4
324
120
X6.1
X2.
1
120X2.2
324
X3.1. 102-102 = Batteries connected to charging circuit (normal operation)
102-103 = Batteries not connected to charging circuit (during storage)
X3.2. 102-102 = Announcements/messages via back panel - required for
102-103 =
IASA.
Announcements/messages via SCU connector - required for IASA.
171
12. IN SYSTEM GATEWAY
The In System Gateway (ISG) replaces the InnovaPhone - DTU-PH (or DTX-I) products that are used for connecting the ErgoLine@Net terminals in TMP-mode. The architecture with an ISG board consist of a physical ISG board with a downloadable software package, an iTMP driver and ErgoLine@Net terminals.
The ISG board does not have straps.
Figure 12-1 ISG board layout
Mark
BP102
BB
GREENRED
Ethernet Interface
GREEN (LINK)
GREEN (RXD)GREEN (TXD)
Aluminium stripA sticker showing the Ethernet Addressis located on the other side
172
13. PM CONTROLLER BOARDS
13.1. PSC-G
The Peripheral Switch and Control-General (PSC-G) is derived from the PSC-A.
The PSC-G can serve a complete digital application of the PM shelf.
The PSC-G generates tones; the packet of tones for the various countries can be selected by setting the switches of S1.1; see table below. Switch S1.1.5 ... S1.1.8 are not used.
Table 13-1 Switch Settings for Tone Selection
COUNTRY GROUP
SWITCH SETTING COUNTRY TRANSMISSION PLANS1.1.
1S1.1.2
S1.1.3
S1.1.4
1 On On On On - - Standard
2 Off On On On South Africa 03
3 On Off On On Sweden 07
4 Off Off On On North America 01
5 On On Off On France 08
Other switch setting combinations are not allowed.
173
Figure 13-1 Strap Location PSC-G
Figure 13-2 Detail of DIP Switch S1
13.2. PMC-HR
The Peripheral Module Controller-High Range (PMC-HR) controls the PCTs in the Unit Groups in the Peripheral Module shelf (PM1100).
The PMC-HR provides the following functions:
Mark
BP
BB
BA
1
S1.1
8
FBC
FBA
FCB
FCC
1 2 3 4 5 6 7 8OffOn
174
- Control up to 8 Unit Groups (UGs) via the PM bus interface;- Control up to 2 Unit Groups (UGs) with PCTs that use IMP communication only;- Interface for CPU to PCT communication;- Generate DTMF and system tones;- Receive dial-tones and key-tones;- Generate and distribute a ISPBX system clock;- Monitor ISPBX system alarms;- Monitor Power supply alarms;- Three-Party Conference circuits (Add-on circuits);- Maximum 8x2 Mbits/s Network Interconnections (NIC) to interface the Switching
Network.
The PMC-HR can be extended with an optional plug-on board for either two analogue operator interfaces (AOC) or one digital operator interface (DOC).
There is no clock regeneration circuitry for connecting to a DTU; therefore the PMC-HR can not synchronise to an external clock source.
• Interface between PMC-HR and Switching NetworkThe PMC-HR is connected to the Switching Network (SCU or SNS) via the front connectors FCA ... FCD. The table below shows the NIC data streams and the relevant signals that appear on the front connectors. A PMC-HR has two NICs available on each front connector but an SCU has only one NIC on each front connector; it is therefore necessary to use a split cable for the connection of the two cards. One split cable may not be connected to front connectors that are on two different SCU cards.
175
Table 13-2 Network Interconnections available at the front connectors (PMC-HR)
The interface between the PMC-HR and Switching Network comprises the following signals:
Note: The PMC-HRs can not be connected together in a master - slave configuration.
FRONT CONNECTOR
2 Mb/s NICs 2 Mb/s INPUT SIGNALS * (at the front connector)
2 Mb/s OUTPUT SIGNALS * (at the front connector)
FCA NIC0 DATAI0 DATAO0
NIC1 DATAI1 DATAO1
FCB NIC2 DATAI2 DATAO2
NIC3 DATAI3 DATAO3
FCC NIC4 DATAI4 DATAO4
NIC5 DATAI5 DATAO5
FCD NIC6 DATAI6 DATAO6
NIC7 DATAI7 DATAO7
* Each signal uses two pins on the FCx connector; the pins connect to isolating transformers on the circuit board.
-DATI :Data In-DATO :Data Out-SCUCL :Switch and Control Unit Clock (or SNS clock)-SCUFS :Switch and Control Unit Frame Synchronisation (or SNS Frame
Synchronisation)
176
Figure 13-3 Layout Front Connector PMC-HR
Straps X1.1 is used to enable or disable the watchdog; default the watchdog is enabled: the strap is removed.
101
FCA
301
108109
FCB
309
116117
FCC
317
124125
FCD
325
132
SCUCL0SCUCL0SCUFS0SCUFS0
DATI0DATI0
DATO0DATO0
SCUCL1SCUCL1SCUFS1SCUFS1
DATI6DATI6
DATO6DATO6
DATI1DATI1DATO1DATO1
DATI2DATI2
DATO2DATO2
DATI2DATI2DATO2DATO2
0V0V0V0V
DATI4DATI4
DATO4DATO4
0V0V0V0VDATI5DATI5DATO5DATO5
0V0V0V0VDATI7DATI7DATO7DATO7
177
Figure 13-4 Strap Location PMC-HR
13.3. PMC-MC
The Peripheral Module Controller-Medium extended and inter-Connectable (PMC-MC) controls the PCTs in the Unit Groups in the (Remote) Peripheral Module shelf ((R)PM1100 or (R)PM255).
The PMC-MC provides the following functions:
- Control up to 8 Unit Groups (UGs) via the PM bus interface;- Control up to 2 Unit Groups (UGs) with PCTs that use IMP communication only;- Interface for CPU to PCT communication;- Generate DTMF and system tones;- Receive dial-tones and key-tones;
Mark
BP
BB
BA
FCD
FCA
FCB
FCC Factory testconnector
102
X3.1
Connectors forAOC or DCC daughterboard
X3.2
X3.3
X1.1
101
178
- Generate and distribute a ISPBX system clock;- Monitor ISPBX system alarms;- Monitor Power supply alarms;- Three-Party Conference circuits (Add-on circuits);- Maximum 6x4 Mbits/s Network Interconnections (NIC) to interface the Switching
Network.
The PMC-MC can be extended with an optional plug-on board for either two anologue operator interfaces (AOC) or one digital operator interface (DOC).
There is clock regeneration circuitry, so the PMC-MC can synchronise to an external clock source.
• Interface between PMC-MC and CSN, or master and slave PMCThe PMC-MC can be connected to:- another PMC-MC (in a master-slave configuration) or:- the Switching Network board CSN when more than two PMs are installed: in this case
all PMs are slaves.The PMC-MC cannot be connected to an SCU/SNS.Connection is made via the front connectors FCA ... FCD. The connection between the two circuit boards consists of two identical twisted-pair cables of standard configuration (8 pairs, one to one connection).
Network interconnections (2Mb/s data streams) are multiplexed into 4Mb/s data streams, tableshows the NIC data streams and the relevant signals that appear on the front connectors.
-master PMC :connect to FCA & FCB.-slave PMC :connect to FCC & FCD.
179
Table 13-3 Network Interconnections available at the front connectors (PMC-MC)
The interface between the master PMC-MC and the slave PMC-MC comprises the following signals:- TD:Transmit Data- RD:Receive Data- TC:Transmit Clock- RC:Receive Clock- TF:Transmit Frame Synchronisation- RF:Receive Frame Synchronisation
FRONT CONNECTOR
2 Mb/s NICs 4 Mb/s SIGNAL *(at the front connector)
FCA NICO0 + NICO1 TD0
NICO2 + NICO3 TD1
NICO4 + NICO5 TD2
NICI0 + NICI1 RD0
NICI2 + NICI3 RD1
NICI4 + NICI5 RD2
FCB NICO6 + NICO7 TD3
NICO8 + NICO9 TD4
NICO10 + NICO11 TD5
NICI6 + NICI7 RD3
NICI8 + NICI8 RD4
NICI10 + NICI11 RD5
* Each signal uses two pins on the front connector; the pins are labelled A and B and are connected to isolating transformers on the circuit board.
180
Figure 13-5 Layout Front Connector PMC-MC
Straps X1.1 is used to enable or disable the watchdog; default the watchdog is enabled: the strap is removed.
101
FCA
Master
Slave
301
108109
FCB
309
116117
FCC
317
124125
FCD
325
132
TD0ATD0BTD1ATD1BTD2ATD2BTCOATCOB
TD3ATD3BTD4ATD4BTD5ATD5BTC1ATC1B
RD0ARD0BRD1ARD1BRD2ARD2B
RCOARCOB
RD3ARD3BRD4ARD4BRD5ARD5BRC1ARC1B
RD0ARD0BRD1ARD1BRD2ARD2BTF0ATF0B
RD3ARD3BRD4ARD4BRD5ARD5BTF1ATF1B
TD0ATD0BTD1ATD1BTD2ATD2BRF0ARF0B
TD3ATD3BTD4ATD4BTD5ATD5BRF1ARF1B
181
Figure 13-6 Strap Location PMC-MC
13.4. PMC-G
The Peripheral Module Controller - General (PMC-G) with its daughter boards: Network Connection Card - Medium extended and interConnectable (NCC-MC) and Network Connection Card - High Range (NCC-HR) is a replacement for the PMC-MC and PMC-HR.
When no network interface is necessary, the PMC-G can be used without Network Connection Cards.
The PMC-G has a dedicated S0 interface which can only be used to connect one operator console like the SuperVisor 25 or 35. The board does not support the AOC and DOC daughter boards.
Mark
BP
BB
BA
FCD
FCA
FCB
FCC Factory testconnector
102
X3.1
Connectors forAOC or DOC daughterboard
X3.2
X3.3
X1.1
101
182
The PMC-G is able to control via the PM bus, 8 unit groups for all kinds of PCTs (UG0...7, 2 boards per UG) and 2 unit groups for PCTs without control data (UG8 and 9, 1 board per UG).
The PMC-G provides several basic telephony functions used to set up, maintain and release calls. All these functions are for common use.
The following basic telephony functions are provided on the PMC-G :
- 32 tone sources: - 16 tone sources are reserved for DTMF signals, compliant with CCITT
recommendation Q.23, and- 16 tone sources are free for customer projecting.
- 6 key tone receivers (RKT) : circuits 2, 3 & 4 and 7, 8 & 9.- 4 dial tone receivers (RDT) : circuits 5 & 6 and 10 & 11.- 32 three-party conference circuits (Add-On / Break-In circuit).- Peripheral switching network.- Protocol Co-Processor (PCP) providing 16 channels for Internal Message Protocol or
HDLC communication. Two of those 16 channels are reserved for CPU-PMC communication.
Clock (re)generation
The clock (re)generation circuit can operate in 2 different modes: master mode and slave mode.
In master mode the clock circuit either generates an internal clock signal or synchronises to an external clock signal. Two external clock inputs are available. The frequency of the external clock can be 2048 or 512 khz. A PMC-G operating in master mode can supply clock (2048 khz) and frame synchronisation signals for a second (slave) PMC-G or PMC-MC.
In slave mode the clock circuit either generates an internal clock signal or synchronises to a clock signal, received from another PMC-G, a PMC-MC or Switching Network via the network interconnection. Two network-clock input-signals are available. In an iS3070 or iS3090 system the clock circuit is always in slave mode.
A clock guard circuit continuously monitors the regenerated clock signal and the external clock inputs. Alarms are reported to software and used by hardware for autonomous clock source selection. The final selection of one of the clock sources is done by OM command ASCRUE.
The two clock signals are available via two coax connectors at the front : the top connector corresponds with PMC circuit 20 and the bottom connector with circuit 21.
183
Operator Interface
The PMC-G has an on-board S0 interface (PMC circuits 0 & 1, only circuit 0 is used) dedicated for one operator console : a SuperVisor 25 or 35. The interface can not be used for other purposes.
Signalling group 7D04 has to be assigned to the operator interface : PMC circuit 0.
Network Connection Card
• Network Connection Card - Medium extended and interConnectable (NCC-MC)On the NCC-MC an interface circuit is present for connection to another PMC-G, PMC-MC or to a CSN-BC of an iS3030 or iS3050 system. This interface is on basis of 4 Mb/s and the maximum number of 4 Mb/s network interfaces is 6. On the NCC-MC each 4 Mb/s network interface is demultiplexed and multiplexed into two 2 Mb/s signal to and from the mother board.The NCC-MC has 4 F122 connectors (FAA ... FAD).- FAA : master 1- FAB : master 2- FAC : slave 1- FAD : slave 2The cables must be plugged into positions, which comply with the master or slave status of the PMC-G.In case of the link to the CSN-BC the slave positions have to be used.
• Network Connection Card - High Range (NCC-HR)On the NCC-HR an interface circuit is present for connection of the peripheral switching network to the Switching Network of an iS3070 or iS3090 system. This interface is on basis of 2 Mb/s and the maximum number of these 2 Mb/s Network interfaces is 8.Those 8 interfaces are available on 4 F122 connectors : FAA ... FAD.- FAA : Network interface 0&1 (and Clock and Frame synchronisation signals)- FAB : Network interface 2&3- FAC : Network interface 4&5- FAD : Network interface 6&7 (and Clock and Frame synchronisation signals)
• Board Layout
184
Figure 13-7 PMC-G Board Layout
• Network Connection Card - Medium extended and interConnectable (NCC-MC)
OptionalNCC-HR/MC
GreenRedYellow
BA
Mark
BP
BB
Clock-B
Clock-A
BISTConnector
FABOperator Interface
(S0-bus)0
185
Figure 13-8 Front Connector NCC-MC
• Network Connection Card - High Range (NCC-HR)
101
FAA
301 RD0ARD0BRD1ARD1BRD2ARD2BTF0ATF0B
RD3ARD3BRD4ARD4BRD5ARD5BTF1ATF1B
TD0ATD0BTD1ATD1BTD2ATD2BTC0ATC0B
TD3ATD3BTD4ATD4BTD5ATD5BTC1ATC1B
108
FAB
109 309
116117
FAC
317
124125
FAD
325
132
TDRDTCRCTFRF
======
Transmit DataReceive DataTransmit ClockReceive ClockTransmit Frame SyncReceive Frame Sync
186
Figure 13-9 Front Connector NCC-HR
• Operator Interface
Figure 13-10 Front Connector Operator Interface
101
FAA
301 TERM9TERM10TERM11TERM12RD1ARD1BTD1ATD1B
TERM13TERM14TERM15TERM16RD3ARD3BTD3ATD3BTERM17TERM18TERM19TERM20RD5ARD5BTD5ATD5B
TERM21TERM22TERM23TERM24RD7ARD7BTD7ATD7B
RC0ARC0BRF0ARF0BRD0ARD0BTD0ATD0B
TERM1
RD2ARD2BTD2ATD2B
TERM2TERM3TERM4
TERM5
RD4ARD4BTD4ATD4B
TERM6TERM7TERM8
108
FAB
109 309
116117
FAC
317
124125
FAD
325
132
TDRDTCRCTFRFTERM
=======
Transmit DataReceive DataTransmit ClockReceive ClockTransmit Frame SyncReceive Frame SyncLine Termination
109
FAB
309 Transmit (+)TNot used
ransmit (-)
Not usedNot usedNot usedNot usedNot used
Receive (+)Receive (-)
Not usedNot usedNot usedNot usedNot usedNot used 116 316
187
14. CPU3000 / VIC3000
Some external devices can be connected on the CPU3000 of the SOPHO iS3000 series and SOPHO-S250/1000. The total number of V.24 device ports on the VIC3000 is limited to 6 when no Ethernet is available and 5 when the Ethernet connection is used on the CPU3000. The Ethernet port of the CPU3000 is half duplex.
In addition, there is a V.28 connection for alarming.
The V.24 ports are available on the VIC3000 daughter board. The numbering of the VIC3000 ports starts at the top. The lowest socket of the VIC3000 has no function and has no number.
There is a Vanadium Lithium battery fitted on the CPU3000 board.
- in an operational system strap X12.4 must be placed on position 102/103: battery connected.
- to prevent the complete unloading of the battery while the circuit board is being transported or while it is not in use strap X12.4 must be placed on position 101/102 : the charging circuit is disconnected.
The battery has a life-span of 7 years after which it must be replaced.
188
Figure 14-1 Layout of CPU3000 / VIC3000 board
Mark
BP102
BB
BA
Ethernet connector(RJ45)
VIC 3000
BATTERY
FEPROM (LBU)DRAM
PROCESSOR
AM3000
BISTConnector
Port 20
Port 25
not used FAA
FAB
FAC
FAD
FBA
FBB
FBC
FBD
Port 24
Port 23
Port 21
Port 22
Alarms V.28
X12.4 101 103
(fixed for SMPC) S
I
M
M
1
S
I
M
M
2
189
Figure 14-2 Layout of VIC3000 FA connector
101
FAA
301
108109
FAB
309
116117
FAC
317
124125
FAD
325
132
RTS
DCD
DSR
GNDTXD
RTS
DCD
DSR
GNDTXD
RTS
DCD
DSR
GNDTXD
Not used
Port 25
Port 24
Port 23
RXD
DTR
CTS
RXD
DTR
CTS
RXD
DTR
CTS
190
Figure 14-3 Layout of VIC3000 FB connector
Figure 14-4 Layout of CPU3000 ethernet connector
101
FBA
301
108109
FBB
309
116117
FBC
317
124125
FBD
325
132
GND
RTS
DSR
DCD
TXT
RXD
DTR
CTS
GND
AL_2
Port 22
Port 21
Port 20
Alarms
RTS
DSR
DCD
TXTGND
RTS
DSR
DCD
TXTGND
GNDGND
RXD
DTR
CTS
RXD
DTR
CTS
AL_1AL_0
RD-
RD+TD-TD+
191
15. COMMUNICATION INTERFACE EXTERNAL
15.1. CIE
The Communication Interface External (CIE) is an interface between the CSM Bus of the iS3070/3090 and the backup and Interface Module (BIM).
To communicate with the BIM a fast IEEE802.3 Ethernet interface is used. The Ethernet port of the CIE is half duplex. An RJ45 front connector is provided for a twisted wire (10BASE-T) connection to the BIM. The maximum length of this Ethernet cable is 100 meters.
Front connectors FCA ... FCD provides the interface of the 13 inputs and 10 outputs of the Switch and Sense Unit on the CIE.
It is possible to install a second CIE (or more) to obtain a more fault tolerant system (a BIM has to be connected to each additional CIE).
192
Figure 15-1 Layout of the CIE board (9562 155 54100)
Mark
BP102
BB
BA
Factory test
RedYellow
Green
COLL
TXDRXD
LINK
RJ45
FAB
FCA
FCD
FCC
FCB
193
Figure 15-2 Layout of the CIE board (9562 155 54200)
Mark
BP102
BB
BA
Factory test
RedYellow
Green
TXDRXD
LINK
LAN
BIM
FAB
FCA
FCD
FCC
FCB
RJ45
RJ45
194
Figure 15-3 Layout of front connector FCA ... FCD
101
FCA
301
108
109
FCB
309
116
117
FCC
317
124
125
FCD
325
132
SSR7CM
SSR8CMSSR8NO
SSR7NO
SI6DP
SI8RPSI8DPSI7RPSI7DPSI6RP
SI5RPSI5DP
SI4RP
SI2DP
SI4DPSI3RPSI3DPSI2RP
SI1RPSI1DP
SSR5CM
SSR6CMSSR6NO
SSR5NO
SSR3CM
SSR4CMSSR4NO
SSR3NO
BOFDP
BZNOBZCMSI12RPSI12DPBOFRP
SI11RPSI11DP
SI10DP
SDNOSDCMSDNC
SI10RP
SI9RPSI9DP
SSR1CM
SSR2CMSSR2NO
SSR1NO
195
16. CENTRAL CONTROL SLICE
The Central Control Slice (CCS) is the main processor board to control a SOPHO iS3000 system. The CCS operates in conjunction with three other CCSs (4/2 mode), or one other CCS (dual mode), or stand alone (single slice mode).
Figure 16-1 Strap Position on the CCS
When the strap is placed the CCS board operates in the single slice mode; in this mode a Memory Extension Card (MEC) of 32 MB is required (since Call@Net 2.9) to extend the total memory.
The MEC (8 MB or 16 MB) is required in an iS3090.
Mark
BP
BP
BB
BA
FBC (test only)
Memory Extension Card
196
17. POWER SUPPLY UNIT
17.1. PSU-MLD(02)
The Power Supply Unit-Medium Large Direct current (PSU-MLD or PSU-MLD02) is used in the PM1100 or PM255. The PSU-MLD(02) converts the -48V dc input voltage to +5V, -5V, +12V, -12V, 4VBAT, VCMOS and ringing output voltages. The PSU-MLD(02) can be strapped for 75V ac or 60V ac ringing voltage and 25Hz or 50Hz ringing frequency. There are five -48V dc outputs on the back panel.
Note: The ringing output voltage for the PSU-MLD used in CHINA (type number 9562 002 0200) has changed from 75 volts to 82.5 volts. This change does not apply to the rest of the world.
The difference between the PSU-MLD and PSU-MLD02 is an extra -60Vdc signalling voltage on the PSU-MLD02.
• StrapsStrap X1.1 is used to select the ringing frequency:- strap on 101-102 : 25Hz;- strap on 102-103 : 50Hz.Strap X1.2 is used to select the ringing voltage:- strap on 101-102 : 60V;- strap on 102-103 : 75V.
• Fuses and Leds
If any of the fuses on which there is a load, is blown, the relevant LED lights and an alarm is activated. Boards that have an on board power converter (like for example the DTX-I) will not cause such an alarm.Both the PSU-MLD and PSU-MLD02 have an extra 'PSU OK LED' indicating that all output voltages are within the tolerances.If the voltages are not within the tolerances, the 'PSU OK LED' will switch off and an alarm is activated.
PSU-MLD : there are five fuses (3, 15 A) with LEDs on the front panel; they are for the - 48V circuits supplied to the back panel.
PSU-MLD02 : there are six fuses with LEDs on the front panel. Five fuses (3, 15 A) with LEDs are for the - 48V circuits supplied to the back panel. The extra fuse (3, 15 A) with LED is for the - 60V signalling voltage.
197
Figure 17-1 Strap Location on the PSU-MLD(02)
PSU-MLD02
Only
-60V signallingVoltage
FCD
Fuses (3.15A)
PSU OK LED
101
101
X1.2
X1.1
Mark
BP
BP
BB
BA
103
103
198
18. CONFERENCE BOARD
The Conference Board (CFC) has 3 straps. One should not change those straps settings otherwise the board will fail. Leave the straps on the default factory settings as follows :
- strap X1.1 on position 101-102.- strap X1.2 on position 102-103 (parked).- strap X1.3 on position 101-102.
The front connectors are not relevant anymore.