Physical description of a mobile terminal A142d ..........57 2.7.2 Overview of a mobile terminal A142d ..............58 CAPACITY 61 2.7.3 NeXspan C/S/L/D ....................61 2.7.4 NeXspan 50, NeXspan 500 ................. 62 2.7.5 Aastra X series ....................62 AMT/PTD/TR/0020/2/7/FR 10/2008 Page 1-4...
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Chapitre 3 - Deployment principles ........64 OVERVIEW ........................64 DETERMINING THE RADIO COVERAGE ..............65 3.2.1...
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Connecting base stations ..................99 BASE STATION SYNCHRONISATION ..............101 Chapitre 5 - Hardware implementation on Aastra X series ....104 INTERFACE CARDS ....................104 Chapitre 6 - Implementation of hardware on NeXspan 50 ....106 INTERFACE CARD ....................106...
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6.5.1 Reading of the LDT card register content............126 6.5.2 Reading of the LDS card register content............127 Chapitre 7- Hardware implementation on NeXspan 500 ....130 INTERFACE CARD ....................130 CONFIGURING THE LDT CARD ................130 7.2.1...
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SYNCHRONISATION ON NEXSPAN 50/500 WITH CSI .........159 8.5.1 Principle ......................159 8.5.2 Configuration ..................... 160 8.5.3 Wiring of synchronisation ports................162 EXAMPLES ......................163 8.6.1 F1/F2 or F6/F2 contiguous multi-site configuration ........... 163 8.6.2 F2/F2 or F4/F2 contiguous multi-site configuration ........... 164 8.6.3 F1/F2/F4 or F6/F2/F4 contiguous multi-site configuration .........
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11.13 DECLARE THE DECT SUBSCRIBERS ..............197 Chapitre 12 - Programming for Aastra X series PBXs ..... .198 12.1 INTRODUCTION ......................198 12.2 DECT MANAGEMENT MENU .................199...
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13.1.1 Contiguous multi-site configuration..............210 13.1.2 Non-contiguous multi-site configuration............211 13.2 DECLARING THE RADIO ZONES ON NEXSPAN 50/ NEXSPAN 500 ....211 13.3 PROGRAMMING THE DECT PARAMETERS ............212 13.4 MULTI-SITE CONFIGURATION WITH OCT4 ............213 13.5 SPECIAL CASE OF A MULTI-SITE CONFIGURATION WITH UCT-S/UCT-L/UCT-D .. 13.5.1 Simplex mode ....................
NeXspan PBXs which correspond to iPBX earlier than R5.1 • NeXspan C/S/L/D • NeXspan 50 • NeXspan 500 Aastra X series PBXs corresponding to iPBXs R5.1 and later • Aastra XD • Aastra XL • Aastra XS, Aastra XS12 and Aastra XS6...
This chapter describes the programming steps to put in service the integrated DECT service for NeXspan 50 and NeXspan 500 PBXs. Chapter 12: Programming for Aastra X series PBXs Describes the programming steps to implement the integrated DECT service for AXD, AXL, AXS, AXS12 and AXS6 PBXs.
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Aastra Management Portal AXD – AXL – AXS – AXS12 – AXS6– Aastra 5000 Server Operating Manual (AMT/PTD/PBX/0080) • AXD - AXL - AXS - AXS12 - AXS6 - Aastra 5000 Server Installation and Maintenance Manual (AMT/PTD/PBX/0058) • A5000 Multi-site management (AMT/PTD/PBX/0081) Terminals related documents •...
Abbreviations Authentication Code ADPCM Adaptative Differential Pulse Code Modulation Access Right Identity DECT Ciphering Key Cyclic Redundancy Checking DECT Digital Enhanced Cordless Telecommunications Equipment Installation Code Equipment Manufacturer Code PBX range including M6501 R/L IP PBX, M6501 RM IP PBX and Succession 6500 Media Gateway M6540 IP PBX range PBX range including MC6530, MC6530E, MC6550, and M6550 IP PBX,...
Definitions 1.5.1 Definitions concerning deployment • Coverage area: The coverage area refers to the space within which the user of a mobile must be able to transmit and receive calls. This area can include coverage both inside and outside a building. •...
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• case 2: ¨B1, B2, and B3 are base stations, each with its own radio area. Each time a cordless handset is located at the intersection of these three areas, it recognises the three base stations with the same radio level. •...
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• Radio area: The radio area is the basic element in radio coverage. The radio area is the zone in which a base station transmits and receives signals. However, depending on the traffic conditions (number of simultaneous calls required within the same office), it may be necessary to install multiple base stations adjacent to one another covering virtually the same radio area.
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• Roaming: mechanism for changing the channel for a cordless handset during communication or when no call is set up (roaming). • Handover: mechanism for changing the base station during communication. radio area 8-base station cell DECT base centre of radio area overlapping base stations...
1.5.2 Overlapping radio areas The radio coverage of a site is established by positioning basic radio areas next to each other. However, to guarantee quality of service for the entire site, the radio areas must overlap on the horizontal and vertical axes. This overlap is required so the roaming and handover phases take place in good radio conditions.
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• Case of theoretical limits RSSI (Hex) RSSI (Hex) Bx: base station studied Dn: direction chosen CRC Err Err CRC distance Graph of Bx for direction Dn Graph of Bx for direction Dn The vertical axis represents the RSSI level of the base station back studied, as seen by the mobile (in mode DEBUG) The horizontal axis represents the distance between the mobile...
FOR A SINGLE-SITE PBX MANAGING LESS THAN 32 CELLS: A single PARI assigned to all the base stations is provided by Aastra. Authorisation access is performed by testing the PARK registered in the cordless handsets which must correspond to the PARI.
1.5.4 Constructing the authentication key The User Authentication Key (UAK) is generated separately for the mobile and the PBX during registration, using the DSAA (DECT Standard Authentication Algorithm). The following data is used to generate the key: • the authentication code (AC), a concatenation limited to 4 digits of the directory number plus the installer’s password, •...
Chapter 2 - Description Overview The integrated DECT is meant to be used on NeXspan PBXs earlier than R5.1 and on Aastra X series PBXs. The DECT system contains the following items: • The mobile terminal which gives the user access to PBX telephony features •...
DECT radio base stations 2.2.1 Physical description A DECT base station consists of a plastic housing and an electronic card. The electronic card manages the ISDN interface. One radio module mounted on the card manages the radio interface. A DECT base station is equipped as standard with two quarter-wave antennas integrated into the unit.
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Figure 2-2: Presentation of a DECT base station If the base station is mounted on a "metal structure" partition, the base station must be 60 to 80 cm from the partition using an extension bracket. Connection The maximum cable distance permitted between a base station and the PBX is 800 meters (principle of the point-to-point S0 bus).
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In cases where old wire is to be reused, it is recommended to carry out 4 tests: cross-talk measurements at 100 kHz (decoupling check and detection of any cross-talk) near-end cross-talk measurements (> or = 60dB) degeneration measurements at 10khz (alpha < 6 dB) loop resistance measurements (R loop = R termination + R cable) To facilitate connection to the base station, it is recommended to use: •...
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• J202: power supply jack used to supply power locally to the base station. J201 S202 J202 The black square represents the position of the switch. Figure 2-3: Overview of the electronic card on the old M6241 base station New M6241 base station connections The base station is connected to its environment using 5 connectors: •...
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• J5: power supply jack used to supply power locally to the base station. The black square represents the position of the switch. Figure 2-4: Overview of the electronic card on the new M6241 base station The cable used to connect a base station to an S0 wall jack must conform to the France Telecom CSE B31-21 standard: •...
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HT6116A Connection kit for external antenna AASTRA Table3: References of antennas used by DECT base stations A 50-centimeter cable equipped with a male TNC connector is provided with the bidirectional antenna (MA821X12). To retain the gain/directivity character of this antenna, do not add cables between the antenna and the base station.
The internal antenna comprises an MMS connector (1), a KX21 coaxial cable (2) and a radiating element (3). The external antenna is connected using a cable (4-5-6) consisting of a male MMS connector (4), a KX21 coaxial cable (5) and a female TNC connector (6). Radial gives losses of less than one dB (guaranteed).
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DECT base stations are connected to the PBX using standard S0 interface cards with a 144 kb/s throughput and a 2-pair cable (S0 point to point pinout). Base station synchronization The various base stations in a radio system are synchronised. If the synchronisation is faulty or inexistent, the "handover"...
2.2.3 Characteristics The characteristics of the DECT base station are as follows: • Frequency band: 1880 -1900 MHz. • Number of radio channels: 10. • Transmission power: 250 mw maximum / 10 mw average. • Instantaneous throughput of the channel: 1152 kbit/s •...
2.2.4 Configuration of the old M6241 DECT base station • Configuration of the switches on the base station’s electronic card (see figure 3 page 28): Switches CA1 Status description CA1-1 on ON activation of the adaptation resistor on the synchronisation pair (factory configuration) CA1-2 on ON the base station reset is only activated when the base station or...
2.2.5 Configuration of the new M6241 DECT base station • Configuration of the switches on the base station’s electronic card (see figure 4 page 29): Switches CA1 Status description CA1-1 on ON activation of the adaptation resistor on the synchronisation pair (factory configuration) CA1-2 on ON the base station reset is only activated when the base station or...
Mobile terminals M90x 2.3.1 Physical description of mobile terminal M90x Overview The M90x mobile terminal comprises: • The portable handset with its battery • A charger • A power supply cable and mains power unit • A belt clip kit. Figure 2-6: View of an M90x mobile terminal For more details, refer to Reference documents , page 13.
2.3.2 Configuring an M90x mobile terminal Registering an M90x mobile terminal A. Check that the mobile has not already been registered. The portable handset must not contain any "parasite" registrations (for example, from previous use on another DECT system). In the standard case where the mobile is to be used on one DECT system only, it must not be registered on any other base at the outset.
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Deregistering an M90x mobile terminal Press the Menu key Press the middle key until “Personalize” is displayed Press the Personalize key Press the middle key several times until "Declare" is displayed Press the Declare key The display shows: Declare base number? 1 2 3 4 Press the key to select the base to be deleted and confirm by pressing the OK...
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M90x mobile DEBUG mode The debug menu is used to view the radio quality of the base stations detected by the mobile terminal. This mode consists of two screens: the first screen gives information about the current base station, whereas the second screen provides information on other base stations detected by the mobile terminal.
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Definition of the debug screen corresponding to the current base station B S I Figure 2-7: Debug screen for the current base station of an M90x mobile terminal • XX: RPN Indicates the number of base station used by the mobile •...
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Definition of the debug screen corresponding to other base stations detected by the mobile terminal Figure 2-8: Debug screen for other base stations detected by the M90x mobile terminal • C3C3/R3R3: RPN and RSSI Indicates the third best available base station for handover in cell XX •...
Mobile terminals M910 / M915 2.4.1 Physical description of a mobile terminal M910/M915 Overview The mobile terminal M910/M915 comprises: • a terminal • a charging unit • an adapter • 3 AAA-NiMH batteries • 2 User Guides (in French and English) Figure 2-9: View of an M910 mobile terminal For more information on the use of a mobile terminal M910/M915, refer to Reference documents , page 13.Error! No bookmark name given.Error! No bookmark name given.
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Characteristics of M915 • Weight: 150 grams. • Dimensions: 135 x 51 x 29 mm. • Autonomy: 10 hours talktime, 100 hours in standby mode. • Registration of terminal with a maximum of four 4 DECT/GAP base stations • Display unit (LCD): 2 lines x 12 characters + 1 line for icons. •...
2.4.2 Configuring a mobile terminal M910/M915 Registering a mobile terminal M910/M915 It is important to follow the procedure below when registering the M910 for the first time. On the mobile terminal, the line "Register" is displayed. Press the Menu key, select System keys and confirm with OK.
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Keypad lock function The keypad lock function is accessible via the “Security” menu. Use this menu with caution. If the user forgets his PIN code, the only way the code can be reactivated is by resetting the mobile with a special tool. The mobile terminal needs to be sent to the manufacturer’s repair centre for this to be done.
M92x mobile terminals 2.5.1 Physical description of an M92x mobile Overview Although mobile terminals M92x and M90x are physically identical, mobile terminals M92x offer the following hardware and software upgrades: • Replacement of obsolete components • Introduction of new functions: •...
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Characteristics • Weight: 120 grams • Dimensions: 135 x 58 x 19 mm. • Autonomy: 10 hours talktime, 72 hours in standby mode. • GAP compatibility (CTR22 standard). • Charger: wall or mobile unit. • Full graphic display: 3 lines x 12 characters with 14 icons. •...
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New features in M92x Note: For more detailed information on the use of an M92x mobile terminal, refer to document Reference documents , page 13.Error! No bookmark name given.Error! No bookmark name given. The new features available in the M92x mobile terminal are: •...
2.5.2 Configuring an M92x mobile terminal Registering an M92x mobile terminal A. Check that the mobile has not already been registered. The portable handset must not contain any "parasite" registrations (for example, from previous use on another DECT system). In the standard case where the mobile is to be used on one DECT system only, it must not be registered on any other base at the outset.
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Deregistering an M92x mobile terminal Press the Menu key Enter the installer code 9995. Press the middle key several times until "Declare" is displayed Press the Declare key The display shows: Declare base number? 1 2 3 4 Press the key to select the base to be deleted and confirm by pressing the OK The set displays: Delete base n...
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M92x mobile DEBUG mode The debug menu is used to view the radio quality of the base stations detected by the mobile terminal. This mode consists of two screens: the first screen gives information about the current base station, whereas the second screen provides information on other base stations detected by the mobile terminal.
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Definition of the debug screen corresponding to the current base station A44:0 A44:0 A44:0 HI:0 HI:0 HI:0 B S I B S I B S I A A A A A A A A A A A A Figure 2-12: Debug screen for the current base station of an M92x mobile terminal •...
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Definition of the debug screen corresponding to other base stations detected by the mobile terminal A44:0 A44:0 A44:0 HI:0 HI:0 HI:0 Figure 2-13: Debug screen for other base stations detected by the M92x mobile terminal • C3C3/R3R3: RPN and RSSI Indicates the third best available base station for handover in cell XX •...
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"RFPI display" mode The RFPI (Radio Fixed Part Identity) is 40 bits information (for example 10.06.F0.FF.4A). The first 4 bytes give the device’s PARI, and the last byte the RPN (Radio fixed Part Number). The RFPIs of the detected tags are recorded in a table. The "RFPI display" mode is activated by changing to debug mode and by using the directory key to display the RFPI screen.
Functional description of M90x, M910 and M92x mobile terminals A NeXspan or Aastra X series PBX manages terminal mobility with the following functions: Authentication Mobile authorization procedure. The decision to initiate the procedure is controlled by the PBX. Each mobile has: •...
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Location Roaming is the procedure by which a mobile locks itself to the authorised base station emitting the best signal. The terminal decides to change base station via the "Roaming" or "Handover" procedures. A mobile set can be in standby mode (standard status: detach) in which case it is considered to be non-located.
Aastra mobile terminals 142d 2.7.1 Physical description of a mobile terminal A142d Overview Figure 2-16: View of a mobile terminal A142d The mobile terminal A142d comprises the following items: • A portable handset with its battery • A charger •...
• Storage batteries: 3 AAA cells, NiMH, 1.2 V / 700 mAh • Charging time for unloaded storage batteries: 5 to 6h • Admissible room temperatures for using the mobile terminal: 5° C to 40° C • Environmental conditions for •...
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Step13.Dial the subscriber’s number, completed by the network password number with the following rules: •If the identification number is a 4-digit number, and the subscriber’s number 3 digits, complete it with the 1st digit of the network password number. •If the identification number has 4 digits and the subscriber’s number 4 digits, you do not need to add any digit.
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Deleting a recording Follow the registration procedures in steps 1 to 6 then: Step 1.Select the Delete column. Step 2.A confirmation screen Sure? opens. Step 3. Press the Yes softkey to confirm. Step 4.A screen: Please wait.. opens then Success. Step 5.The Registration screen opens;...
Capacity The radio network capacity depends on the PBX S0 interface card and the power supply. Attention: do not connect other ISDN equipment on the S0 (BRI) bus when the bus has 48 V power supply. 2.8.3 NeXspan C/S/L/D S0 interface cards Power supply Capacity NeXspan D (XD)
4 base stations ADS150X 4 channels AXS6 EXT1-S6 + ADPCM16 48 V supplied by 2 base stations ADS150X 4 channels Table11: Radio network capacities of Aastra X series systems The maximum number of DECT mobile terminals is 500. AMT/PTD/TR/0020/2/7/EN 10/2008 Page 2-62...
Chapter 3 - Deployment principles Overview Before beginning deployment procedures ensure that the following studies have been conducted: • Radio coverage for the entire site. It must be possible to send and receive calls within the coverage area. • Site traffic study. The number of simultaneous calls must be determined according to the number of users and their habits.
Determining the radio coverage This section describes the principles of the site survey for positioning base stations in order to achieve complete coverage of the area. The purpose of deployment is to determine where to locate the base stations. This cannot be achieved using only building plans;...
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Metal structures found in conference halls and production rooms can also cause radio waves to be reflected due to their large metal structures. The resulting interference reduces the base station’s range. Once the nature of the materials has been identified in the coverage areas, the size of the radio areas can be evaluated, taking the following information into account: Average range Type of premises...
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Measure the horizontal range on the floor below. Without moving the radio base station, go to the floor directly below and measure the horizontal coverage again. Note: If the building allows good radio signal penetration, the vertical coverage could extend to one floor above or below the one where the base station is located.
Method of determining the number of base stations according to predicted traffic This method allows you to determine the number of base stations required to provide service in a coverage area. Proceed as follows: Identify the traffic areas and divide them into two categories: •...
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Dimensioning for a 4-channel base station: Number of radio base stations for a given area according to traffic mobility parameters, and the ratio of the number of mobiles to the number of radio areas in the coverage area. MEDIUM HIGH (0,2) (0,5) (0,8)
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Example: 20 handsets 10 handsets 60 handsets DECT base cell 2 radio area cell 3 cell 4 cell 0 cell 1 Homogeneou Homogenous area Homogenous area area 2 Figure 3-1: Example of deployment The deployment study produced the following information: •...
Grouping radio areas into cells Since the cell is the mechanism by which the PBX locates the cordless handsets, it is necessary to group the radio areas into cells. The following criteria used to group radio areas into the same cell do not taken into account whether the area is homogenous or special, but consider only geographic proximity: •...
Installing and connecting the base stations 3.5.1 Installing the base stations • The base stations must be positioned at the exact point determined by the deployment study. Moving the position of the base station by 1 or 2 meters may have a detrimental effect on transmission and reception within the radio area.
Chapter 4 - Hardware implementation on NeXspan C/S/L/D Conventions used for card names All expansion cards exist in two physical formats: • One format fitted with an extraction handle and Stocko connectors. The Stocko cards have the name of the card followed by the extension ST (example: LD4 ST, LD4NX ST). •...
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LD4 and LD4NX cards. The LD4 et LD4NX cards have four T0/S0 interfaces and are used to manage 2- or 4-channel DECT base stations. The T0/S0 interfaces are configured by MMC: • as T0 for connection of an ISDN network basic rate interface, •...
(Factory) configuration of the LD4 ST card with Stocko format The black square represents the position of the switch. Figure 4-1: Top view of the LD4 ST card AMT/PTD/TR/0020/2/7/EN 10/2008 Page 4-76...
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Figure 4-2: Top view of the LD4 ST card Page 4-77 10/2008 AMT/PTD/TR/0020/2/7/EN...
4.3.2 Description of the switches CA1.1 to CA1.4 : these switches are used to adapt lines (factory setting, leave set to ON). CA2 (located on the copper side): configure according to the card's location and mode (master/ slave). For LD4 ST in T0 CA2.1 Function (VALH)
Selects the 40 V power supply Table4: Description of switches SW7 and SW8 on the LD4 ST card 4.3.3 LD4 ST card layout The possible slots and restrictions for the LD4 card in a NeXspan cabinet are the same as for the LD4NX card (see Section 4.6.5).
8-pin STOCKO connector RJ45 connector Pin 1 (ED1) Pin 4 Table5: S0 interface link of an LD4 ST card with a DECT base station (Factory) configuration of the LD4 RJ card with RJ45 format Figure 4-4: Overview of the LD4 RJ card 4.4.1 Description of RJ45 connectors •...
M40 V NED3 NED2 NED1 NED0 NRD3 NRD2 NRD1 NRD0 P40 V Table6: S0 connector pinout on the LD4 RJ card Note: 40 V can also be supplied on connector T3 (connect the 40 V supply unit to connector T3, and the base station to connector S3). 4.4.2 Switch settings CA1.1 to CA1.4 (ADAPT) : these switches are used for line adaptation.
Table8: Description of switches SW3 to SW6 on the LD4 RJ card SW7 and SW8: the jumpers allow the selection of a 40 V or 48 V power supply. Note: The power supply units of the NeXspan range do not supply ISDN 40 V. To supply 40 V to sets and/or base stations, connect an external power supply unit to the T3 connector on the LD4 RJ card.
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units do not supply ISDN 40 V. To supply 40 V to sets and/or base stations, connect an external power supply unit to the T3 connector on the LD4 RJ card. CONSOLE LD4 X RJ45 DECT base station Figure 4-6: Connecting a base station to an S0 interface of an LD4 RJ card S0 interface link with DECT base station: LD4 RJ card RJ45 connector Base station RJ45 connector...
(Factory) configuration of the LD4NX ST card with Stocko format 1 2 3 J1-1 J2-1 J1-2 J2-2 DISA CA1 HVAL J1-3 J2-3 J1-4 J2-4 5 10 CA1 HVAL CA1.1 = ON HVAL CA1.1 = OFF H not validated CA1.2 = not wired Figure 4-7: Top view of the LD4NX ST card Two operating modes can be configured on the LD4NX ST card: •...
4.5.1 Description of the connectors NAME FUNCTIONS/CHARACTERISTICS CONTACTS 96-pin connector: backplane connection. STOCKO male connector, 2 pins: receives the ISDN 40 V remote power supply when the latter is • Pin 1: M40V not available on the PBX backplane (40 V only •...
4.5.2 Switch settings Note: The Master/Slave micro-switch of the previous LD4 cards no longer exists. The LD4NX ST card is always in DECT slave mode; it cannot generate the DECT clock. The LD4NX ST card has no micro-switch for downloading the flash memory with a BOF3 type tool (automatic detection).
4.5.3 Description of the diodes Name Colour Function Green Shows the operating status of the card DISABLED Orange Not used Table13: Description of LD4NX ST card LED 4.5.4 LD4NX ST card layout The possible slots and restrictions for the LD4NX card in LD4N mode in a NeXspan cabinet are the same as for the LD4 card (see Section 4.6.5).
4.5.5 Connecting base stations Each terminal is connected to an ISDN S0 (BRI) interface of an LD4NX ST card, and uses two pairs: 1 transmit pair and 1 receive pair. Note: If there are a DECT base station and an S0 terminal (other than the base station) on the same card, the base station must be powered with a 40 V supply.
(Factory) configuration of the LD4NX RJ card with RJ45 format 1 2 3 J1-1 J2-1 J1-2 J2-2 CA1 HVAL J1-3 J2-3 J1-4 J2-4 CA1 HVAL CA1.1 = ON HVAL CA1.1 = OFF H not validated CA1.2 = not wired LD4NX Console Figure9: Overview of the LD4NX...
4.6.1 Description of the connectors NAME FUNCTIONS/CHARACTERISTICS CONTACTS 96-pin connector: backplane connection. HE14 connector - 1 x 8 male pins: used for not used loading programmable components "On Site" (reserved for manufacturer). J5 and J6 Two connectors AMP CMS 2 x 10 female pins: hosts an ADPCM16V daughter card.
4.6.2 Switch settings Note: The Master/Slave micro-switch of the previous LD4 cards no longer exists. The LD4NX RJ card is always in DECT slave mode; it cannot generate the DECT clock. The LD4NX RJ card has no micro-switch for downloading the flash memory with a BOF3 type tool (automatic detection).
4.6.3 Description of the diodes NAME STATUS EXPLANATION RUN (green) Flashing rapidly Card in service OFF (orange) Card can be removed while powered up Table18: Description of LD4NX RJ card LEDs Note: You are advised to disable the card before removing it. 4.6.4 Description of push buttons NAME EXPLANATION...
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An LD4 card or LD4NX card without ADPCM16 daughter card can be fitted in slots 00 to 13. An LD4NX card in LD4X mode with ADPCM16 daughter card can be fitted in slots 00 to 13 without restriction. An LD4N/LD4NX card (in LD4N mode) with ADPCM16 daughter card can be fitted in slots 6 and 7 without restriction.
4.6.6 Connecting base stations Each base station is connected to an ISDN S0 (BRI) interface of an LD4NX RJ card, and uses two pairs: 1 transmit pair and 1 receive pair. Note: If there are a DECT base station and an S0 terminal (other than the base station) on the same card, the base station must be powered with a 40 V supply..
Configuring S/T accesses of UCT-S, UCTS-12 and UCT-C cards 4.7.1 S/T access of a UCT-S card S.DECT P.DECT PARALLEL PORT MUSIC S/T-3 S/T-2 S/T-1 S/T-0 PRINTER CONSOLE ALARM / REMOTE CONTROL 10/100-TX Figure 4-14: Front panel of a UCT-S card The UCT-S card has four T0/S0 interfaces (4 RJ45 connectors) for connecting four 2-channel DECT base stations (to a first-generation UCT1-S ) and 4-channel DECT base stations (to a second-generation UCT2-S or third-generation UCT3-S card fitted with an ADPCM16 daughter...
The UCT-C card has four T0/S0 interfaces (4 RJ45 connectors) for connecting two 2-channel DECT base stations (to a first-generation UCT1-C card) and 4-channel DECT base stations (to a second-generation UCT2-S card fitted with an ADPCM16 daughter card). 4.7.4 Description of S/T connectors of UCT-S, UCTS-12 and UCT-C cards Pin no.
4.7.5 Configuring the remote power supply of S/T0 to S/T3 accesses UCT-S, UCTS-12 and UCT-C cards have 4 jumpers for configuring the remote power supply of the S/T0 to S/T3 accesses (one jumper block for each access). The jumpers are plugged into connectors J29 and J30 located on the front of the UCT-S, UCTS-12 and UCT-C cards.
The state of the jumpers can be viewed via MMC: Menu 3.2.4. ISDN BOARD SWITCHES STATUS SLOT TYPE DIREC/TG SYNC REMO-SUPL -------------------------------------------------- 0-02-00 0-02-01 DECT BASETG0 0-02-02 FT0-ETSI 0-02-03 FT0-ETSI 1-01-00 1-01-01 1-01-02 1-01-00 -------------------------------------------------- Figure 4-18: Status of ISDN card jumpers (Menu 3.2.4) Note: The status of LD4NX card jumpers in LD4X mode, available in the PBX, are equally displayed (card available in slot 1 –...
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A twisted cable or S0/T0 adaptor is required to connect DECT base stations. UCT-S/T-C 2 3 4 5 6 7 2 3 4 5 6 7 Standard point-point cable 2 3 4 5 6 7 Crossover Twisted cable 2 3 4 5 6 7 Standard point-point cable DECT base...
Base station synchronisation The base stations connected to the S0 accesses of an LD4/LD4NX card and to the integrated S0 accesses of a second-generation UCT2-S/UCT2S-12/UCT2-C or third-generation UCT3-S, UCT3S-12 card are synchronised in a software, through M bit and S frame. DECT base stations connected to integrated S0 accesses of a UCT1-S/UCT1S-12/UCT1-C card are synchronised by a third pair.
Chapter 5 - Hardware implementation on Aastra X series Interface cards The cards used to connect DECT base stations to Aastra X series devices are: • LD4/LD4NX equipment cards fitted with the ADPCM16 daughter card on AXD, AXL, AXS, AXS12 and AXS6. These cards are fitted on common card slots.
Chapter 6 - Implementation of hardware on NeXspan 50 Interface card LDS/LDT cards, possibly fitted with one or two ADPCM32 (LDS) and ADPCM32B (LDT) daughter cards are used to connect DECT base stations to a NeXspan 50. LDS/LDT cards have T0/S0 interfaces for managing 2- or 4-channel DECT base stations. There are two versions of each card: •...
6.2.2 Front panel REA5 REA6 + 5 V S0 to S15 Interface Activation Display (level 1) Address not recognised (Fault) REA5 Rapid LED flashing --> Card operational Slow LED flashing --> Card not operational REA6 Not significant (LED off) LED steady on--> Card operational LED off -->...
6.2.3 Equipment on top side power supply power supply 1 2 3 ADPCM32 ADPCM32 (2,3) (6,7) (10,11) (14,15) (0,1) (4,5) (8,9) (12,13) The black square represents the position of the switch. J6, J7, J8, J9: ADPCM32 daughter card equipment J10, J11, J12, J13: equipment of second ADPCM32 daughter card Figure 5-2: Top view of the LDS card AMT/PTD/TR/0020/2/7/EN 10/2008...
6.2.4 Equipment on bottom side The black square represents the position of the switch. Figure 5-3: Bottom view of the LDS card Page 6-109 10/2008 AMT/PTD/TR/0020/2/7/EN...
6.2.6 LDS card layout The LDS card can be fitted in the shelves in accordance with the configuration file. The card is connected to the synchronous bus via the AVADQ or AVLDT terminator inserted in a CFX front slot (corresponding to CLX slot on the LDS card). For more details, refer to "Reference documents"...
6.2.7 Connecting the LDS card The LDS card is connected to the distribution frame by a special cable, also used for the remote power supply connection and the RSU connection if a T0 interface is synchronising on the LDS card. If there is no synchronising T0 on the LDS card, cable HG4301A or B is used.
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PLDS board A PLDS card is required for each LDS card to be supplied with remote power. Fuses are positioned on the PLDS card to select either 40 V or 48 V voltage (48 V as standard unless an S0 interface supplied with remote power is to be configured on the card). The remote power is supplied to the LDS card interfaces via the part of the cable terminating with the J4 connector.
Configuring the LDT card 6.3.1 References and equipment Description Reference LDTA 16 T0/S0 interfaces for 2- or 4-channel DECT base stations HJ4758A LDTB 8 T0/S0 interfaces for 2- or 4-channel DECT base stations HJ4758B ADPCM32B Daughter card for managing 8 x 4-channel DECT base HJ4402B stations AVADQ...
6.3.2 Front panel REA5 REA6 + 5 V S0 to S15 Interface Activation Display (level 1) Address not recognised (Fault) REA5 Rapid LED flashing --> Card operational Slow LED flashing --> Card operational REA6 Not significant (LED off) LED steady on--> Card operational LED off -->...
6.3.4 Switch settings Automatic resynchronisation switch CA1.2 = ON -> Automatic resynchronisation CA1.2 = OFF -> LDS operation without automatic resynchronisation Remote power supply configuration straps • J1 set to 1-2 = Remote power supply ON • J2 set to 1-2 = Remote power supply ON •...
6.3.6 Connecting the LDT card The LDT card is connected to the distribution frame by a special cable, also used for the remote power supply connection and the RSU connection if a T0 interface is synchronising on the LDT card. If there is no synchronising T0 on the LDT card, cable HG4301A or B is used.
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PLDS board A PLDS board is required for each LDT board to be remote supplied. Fuses are positioned on the PLDS card to select either 40 V or 48 V voltage (48 V as standard unless an S0 interface supplied with remote power is to be configured on the card). The remote power is supplied to the LDT card interfaces via the part of the cable terminating with the J4 connector.
6.3.7 Distribution frame wiring with cable HG4302A On the distribution frame end the cable has: • 4 yellow terminal strips (16 transmission/reception interfaces), • 1 red terminal strip (DECT synchronization ). Note: On an FPHBG2/CSI device, the synchronization signal is sent via the loop and transmitted to the LDT cards via the back plane (see Section 6.4).
Synchronisation The DECT radio base station synchronization method varies with the device used (FPHBG2/CSI or FPHBG/CSH) and the boards installed (LDS and/or LDT). The back plane assembly FPHBG2/ CSI and FPT30B/FPD30B allows the DECT clock to be sent on the loop and simplifies the DECT synchronization wiring in a single-site configuration.
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• For remote clusters: the transmission time compensation on the loop must be configured in the RMH board(s) of all the clusters that contain LDT boards to which DECT base stations are connected. This configuration is performed using 11 switches (binary value: ON = 0; OFF = •...
CA1 + CA3 + CA4 = ON Binary value: ON = 0; OFF = 1 RET11 RET0 Not used Figure 5-16: Default configuration (factory configuration) of switches CA1, CA3, and CA4 on the CSI card 6.4.2 For a NeXspan 50 equipped with an FPHBG back plane as well as CSH and LDS/LDT cards The LDS/LDT card manages DECT synchronization by sending the 800ms time signal to DECT base stations on the S0 interface (M bit multi-frame mechanism of the S interface).
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to be detected during the resynchronization phase, the 800 ms counter setting is not adjusted. Connecting the clocks Cable HG4302X is used to connect the DECT clock (800ms). This clock exits on 3 different V11 pairs (see LDS, LDT interfaces). All DECT V11 clock connections should be carried out on the 4G terminal strip.
Means of LDT/LDS card diagnosis on NeXspan 50 The method used to check that the LDT/LDS card configuration and wiring of DECT synchronisation clocks are correct is based on the reading of the content of certain registers accessible on these cards. The accessible registers are not the same for the LDT card and LDS card.
The NBRESYNC register gives the number of times the LDT card has changed to automatic resynchronisation. Its maximum value (FFH) is retained once attained so long as this register has not been re-read. Note: This register is only incremented if the LDT card is in automatic resynchronisation mode. The reading of this latter resets the counter.
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NADR12 .. NADR8 = Status of inputs fixing the number of the CLX position NA/B=0: card fitted with 16 accesses NA/B=1: card fitted with 8 accesses NMASTER=0: master LDS NMASTER=1: slave LDS ABSHDECT=0: The LDS card actually receives a DECT clock in input (for cards configured in slave mode).
Chapter 7- Hardware implementation on NeXspan 500 Interface card LDT cards, possibly fitted with one or two ADPCM32B daughter cards, are used to connect DECT base stations to NeXspan 500. LDT cards have T0/S0 interfaces for managing 2- or 4-channel DECT base stations. There are two versions of each card: •...
Note: New LDT cable to be used if the 800 ms DECT clock passes through the loop: PBX fitted with an FPS back plane, a CSI card and FPG back plane 7.2.2 Front panel of LDT card REA5 REA6 + 5 V S0 to S15 Interface Activation Display (level 1) Address not recognised (Fault) REA5...
7.2.4 Switch settings Automatic resynchronisation switch CA1.2 = ON -> Automatic resynchronisation CA1.2 = OFF -> LDS operation without automatic resynchronisation Remote power supply configuration straps • J1 set to 1-2 = Remote power supply ON • J2 set to 1-2 = Remote power supply ON •...
7.2.5 installing the ldt board Proceed as follows to install an LDT board: • Insert the LDT card in a CLX slot with synchronous bus access. • Connect it to the synchronous bus with a plug. • Connect it to a synchronizing clock input in the PBX in the case of a synchronizing T0 interface on the LDT card.
7.2.8 DECT clock interfaces The CSI board generates a DECT clock and sends this clock to all the PBX clusters. The synchronization signal is sent via the loop and extracted by the RMH boards. The DECT synchronization signal is then sent to the LDT boards via the back plane. The configuration rules are as follows: •...
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AHG0013X cable Note: New LDT cable to be used if the 800 ms DECT clock passes through the loop: PBX fitted with an FPS back plane, a CSI card and FPG back plane AMT/PTD/TR/0020/2/7/EN 10/2008 Page 7-136...
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HG4302X cable Note: This cable is used to convey the 800 ms DECT clock via the distribution frame. Page 7-137 10/2008 AMT/PTD/TR/0020/2/7/EN...
7.2.12Distribution frame wiring with cable HG4302A On the distribution frame end the cable has: • 4 yellow terminal strips (16 transmission/reception interfaces), • 1 red terminal strip (DECT synchronization ). Note: This cable is used to convey the 800 ms DECT clock via the distribution frame. RJ45 S0 / DECT NED0...
7.2.14Synchronisation The back plane set, FPS/CSI and FPG, allows the DECT clock to be sent on the loop and simplifies the DECT synchronization wiring in a single-site configuration. The CSI board generates a DECT clock and sends this clock to all the PBX clusters. The synchronization signal is sent via the loop and extracted by the RMH boards.
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• For remote clusters: the transmission time compensation on the loop must be configured in the RMH board(s) of all the clusters that contain LDT boards to which DECT base stations are connected. This configuration is performed using 11 switches (binary value: ON = 0; OFF = 1).
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CA1 + CA3 + CA4 = ON Binary value: ON = 0; OFF = 1 RET11 RET0 Not used Figure 6-9: Default configuration (factory configuration) of switches CA1, CA3, and CA4 on the CSI card AMT/PTD/TR/0020/2/7/EN 10/2008 Page 7-142...
Means of LDT/LDS card diagnosis on NeXspan 500 The method used to check that the LDT/LDS card configuration and wiring of DECT synchronisation clocks are correct is based on the reading of the content of certain registers accessible on these cards. The accessible registers are not the same for the LDT card and LDS card.
The NBRESYNC register gives the number of times the LDT card has changed to automatic resynchronisation. Its maximum value (FFH) is retained once attained so long as this register has not been re-read. Note: This register is only incremented if the LDT card is in automatic resynchronisation mode. The reading of this latter resets the counter.
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NADR12 .. NADR8 = Status of inputs fixing the number of the CLX position NA/B=0: card fitted with 16 accesses NA/B=1: card fitted with 8 accesses NMASTER=0: master LDS NMASTER=1: slave LDS ABSHDECT=0: The LDS card actually receives a DECT clock in input (for cards configured in slave mode).
Chapter 8- Multi-site synchronisation (before R5.1) Note: The use of the DECT system in a heterogeneous environment (R4.2 and/or earlier) with Aastra X series R5.1 sites is not handled in this chapter. Principle 8.1.1 Contiguous multi-site configuration In a contiguous multi-site configuration, the base stations of site 1 can "hand over" to base stations of site 2.
Distributing DECT synchronisation to the base stations 8.2.1 Distribution by M bit Here the synchronisation signal is distributed to the base stations by the M bit of the S0 frame from the DECT interface card (LD4/LD4N cards for the M6501 L/R/RM IP PBX (F1), LD4/LD4NX (LD4N or LD4X mode) for NeXspan S/L/D (F6), LDT card for NeXspan 50 (F4) equipped with FPHBG2/CSI and LDT card for NeXspan 500 (F4) fitted with FPS/CSI.
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Wiring synchronisation with the REP16 repeater Description of the REP 16 repeater It is possible to connect: • only one base station per repeater output (two base stations on outputs 7 and 14) • one to four repeaters to the master base station. slave radio base station 1 slave...
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Wiring REP96 repeater synchronisation Description of REP 96 Up to four base stations may be connected per repeater output and from one to four repeaters may be connected to the master base station. syn+E23 syn-E17 Gray Gray syn+E22 syn-E18 Transparent syn-E19 syn+E21 Gray...
Synchronisation on M6501 L/R/RM IP PBX and Succession 6500 Media Gateway with OCT4/OCT4 I 8.3.1 Principle In a network containing several PBXs fitted with an OCT4 or OCT4 I card (M6501 L/R/RM IP PBX and Succession 6500 Media Gateway), it is not necessary to wire the DECT base stations with a third pair for synchronisation.
This delay can be made up for through MMC (see Chapter - Programmation multi-sites, § 11.4). Adjustment is made in 100 m steps on the slave PBXs, with the following formula applied: 8xN + totalL where N = number of slave PBXs from master PBX and totalL = total length of cable between master and slave PBX Example figure above: •...
Synchronisation on NeXspan S/L/D with UCT-S/UCT-L/UCT- Note: NeXspan S12 and NeXspan C have no synchronisation port but is capable of DECT multi-site synchronisation via a third pair. 8.4.1 Principle In a network containing several PBXs fitted with a UCT-S or UCT-L or UCT-D card (NeXspan S or NeXspan L or NeXspan D), it is not necessary to wire the DECT base stations with a third pair for synchronisation (unless the integrated S0 accesses of the first- generation NeXspan S CPU card (UCT1-S) are used).
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Indicators There are several LEDs on the front panel of UCT cards providing information about synchronisation clock operation and DECT multi-site synchronisation: Note: "S.DECT" and "MST DECT" LEDs are not available on the front panel of UCT-S12 and UCT-C cards. Note: For NeXspan D, "S.DECT"...
8.4.2 Wiring examples Series wiring in Simplex mode ADS300 ADS300 ADS300 Slave Esclave Priority Master Slave Maître Prioritaire Esclave ADS300 ADS300 Slave Esclave Esclave Slave Figure 7-8: Multi-site synchronisation with UCT-L/UCT-S in Simplex mode (series wiring) Series wiring in Duplex mode Maître Maître Priority...
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For series wiring (Simplex or Duplex mode), the following rules must be respected: • There are no particular positioning rules to be followed for the slaves behind the two "Master" PBXs. In Simplex mode in particular, all the slaves are wired in series behind a single Master PBX.
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For star wiring the following rules must be respected: • There are no particular positioning rules to be followed for the slaves behind the two "Master" PBXs. In Simplex mode in particular, all the slaves are wired in series behind a single Master PBX.
8.4.3 Wiring of synchronisation ports Important: DECT synchronization wiring between the two NeXspans must be done using only an STP5 cable. • Master - Slave and Slave - Slave wiring (ISDN straight wiring) RJ45 S DECT RJ45 P DECT Signal (J7B) (J7A) PHBIT...
Synchronisation on NeXspan 50/500 with CSI 8.5.1 Principle In a configuration comprising several (contiguous) PBXs fitted with a CSI card, you do not need to wire the DECT base stations with a third pair for synchronization. Multi-site DECT synchronization on NeXspan 50/500 requires the RHMIC/RHMIC2 and BCSI cards to be installed.
"Master" and "Slave" mode: The synchronization ports work in the following modes: • "Master» mode: the signals from the secondary port transmit the 2.048 MHz bit clock and reference DECT synchronization from the "master clock" CSI board to a PBX in slave mode. •...
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Configuration on a "Slave" PBX: • The types of PBX downstream and upstream of the "Slave" must be indicated (F1/F6 or F4, manual configuration). A switch (screen printing: GAVF1/6) on the BCSI is used to define the type of PBX downstream: •...
Indicator A BCSI LED on the front panel of the CSI card gives information about DECT multi-site synchronisation: STATE EXPLANATION No BCSI card connected Flashes green BCSI available but no incoming DECT synchronisation signal (case of master PBX) On steady green Incoming DECT synchronisation signal on the BCSI card (case of slave PBX) Table15: Meaning of DECT multi-site synchronisation on CSI card front panel...
Examples 8.6.1 F1/F2 or F6/F2 contiguous multi-site configuration The slave PBX must be synchronised via an inter-site link (2.048 MHz clock). The base stations must be wired in three pairs (F2 has no synchronization port + LD4/LDS, LD4NX/LDS combination). The synchronization pair carries the 800 ms clock. Note: The LD4X (removing jumper J14 from an LD4NX card and offering additional functions) is only compatible on the NeXspan S/L/D range and as of software release R4.1.
8.6.2 F2/F2 or F4/F2 contiguous multi-site configuration The slave PBX must be synchronised via an inter-site link (2.048 MHz clock). The base stations must be wired in two pairs. The synchronisation signal is carried by the M bit in the S frame. One LDS or LDT card must be declared master and the other slave.
8.6.3 F1/F2/F4 or F6/F2/F4 contiguous multi-site configuration The slave PBXs must be synchronised via inter-site links (2.048 MHz clock). The base stations must be wired in three pairs (F2 has no synchronization port + LD4/LDS, LD4NX/LDS combination). The synchronization pair carries the 800 ms clock. Note: F2 has no synchronization ports;...
8.6.4 F4/F4, F4/F6 or F4/F1 contiguous multi-site configuration Case of multisite F4/F4 device with an F4 equipped with an FPHBG back plane and CSH, LDS and/or LDT cards The slave PBX must be synchronised via an inter-site link (2.048 MHz clock). The base stations must be wired in two pairs.
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Case of multisite F4/F6 or F4/F1 device with F4 equipped with an FPHBG back plane and CSH, LDS and/or LDT cards The slave PBX must be synchronised via an inter-site link (2.048 MHz clock). The base stations must be wired in three pairs (combination of LD4 / LDS (or LDT), LD4N / LDS (or LDT), LD4X / LDS (or LDT)).
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Case of multisite F4/F4, F4/F6 or F4/F1 device with F4 equipped with an FPHBG2 back plane and CSI and LDT cards (NeXspan 50) The secondary port of the “Master” PBX is connected to the primary port of the “Slave” PBX. The base stations must be wired in two pairs.
8.6.5 F6/F1 or F6/F6 contiguous multi-site configuration in simplex mode The secondary port of the “Master” PBX is connected to the primary port of the “Slave” PBX. The base stations must be wired in two pairs. The synchronisation signal is carried by the M bit in the S frame.
8.6.6 F6-F6/F6 or F6-F6/F1 contiguous multi-site configuration in duplex mode The two "Master" PBXs are connected via their primary port. The secondary ports of the “Master” PBXs are connected to the primary ports of the “Slave” PBXs. The base stations must be wired in two pairs. The synchronisation signal is carried by the M bit in the S frame.
Chapter 9 - Checking the installation Preliminary operations It is recommended to back up the customer configuration before beginning DECT programming. Be sure to have the following information available: • the PARI number, • deployment information and plans Note: The PARI number can be found on the PBX approval label. Procedure Before beginning implementation, check the conformity of the S0 interface cards, the power supplies, and the positions of the interface cards in the PBX and the configuration of the card...
9.2.1 Basic wiring checks Checking the continuity and configuration of the pairs • Visually check the configuration of each base station RJ45 connector and of each distribution frame. • Cable test. Isolate the S0 side at the distribution frame and note the impedance of the wiring + base station assembly for the 2 or 3 pairs.
Chapter 10 - Programming for NeXspan C/ S/L/D PBXs 10.1 Introduction The DECT service programming steps are described for NeXspan C/S/L/D PBXs Note: It is essential to follow the programming order given. PRELIMINARY OPERATIONS: • Check the "internal" type data routing (menu 2.5 "Data management/Routes") MANAGEMENT OF TOPOLOGY Declare the cells Declare the DECT parameters...
10.2 Management of topology MENU: 1.8.1 (Single-company management) or 1.9.1 (Multi-company management) WIRELESS: TOPOLOGY 1 NAMES OF FIRST CELLS 2 NAMES OF LAST CELLS 3 DECT PARAMETERS 10.2.1 Declare the cells This screen allows you to declare the cells that were defined during deployment. The maximum number of cells is fixed at 128 (for single-site configuration) and 254 (for multi-site configuration).
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• PARI VALUE: 9 digits maximum (the PARI number can be found on the PBX approval label). • RANDOM VAL RECORDED and RS VAL RECORDED: maximum 9 digits. 2 random values (must not be the same) registered in the mobile by the PBX when the mobile was registered on the DECT network.
10.3 Resources MENU: 1.8.2 (Single-company management) or 1.9.2 (Multi-company management) WIRELESS: RESOURCES 1 TRUNK GROUP NAMES 2 TRUNK GROUP DEFINITION 3 ALLOCATION OF BASE STATIONS 4 BASE STATION DISPLAY LIST 5 COVER DISPLAY ENTER YOUR CHOICE 10.3.1 Naming the trunk groups One trunk group must be associated with one cell only.
10.3.3 Selecting a trunk group MENU: 1.8.2.2 (Single-company management) or 1.9.2.2 (Multi-company management) TRUNK GROUP DEFINITION SELECTION BY NAME 10.3.4 Associating the trunk group with the base station TRUNK GROUP DEFINITION TG0 LOCATED IN CELL BLDG A Note: to declare a DECT trunk group in a cell, all base stations in the cell must be out of service.
10.4 Putting DECT cards and base stations in service Menus 1.8.2.3 (Single-company management) or 1.9.2.3 (Multi-company management) "Base station allocation" are used to declare and put in service 2- or 4-channel DECT base stations. Follow the instructions below before using this menu. 10.4.1 Preliminary operations and checks Before putting the base stations in service, carry out the preliminary operations below: •...
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2) Putting in service DECT interface cards of the UCT CPU card (UCT-S and UCT-C) MENU 3.2.2 : Example of an XS MOTHER BOARD MANAGEMENT - MIGRATION UCT: HARDWARE VIEW SOFTWARE VIEW XXS CONFIGURATION DIG. IN 0-00: IN SERVICE ..ANAL IN 0-01: IN SERVICE ..
10.5 Declaring and putting in service DECT base stations When declaring each base station note its position on the diagram (cabinet/card/channel). 10.5.1 Declaring and defining a base station Use Menu 1.8.2.3 or Menu 1.9.2.3 to select the DECT base station you wish to put in service. Three types of selection are proposed: •...
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• SYNCHRONIZATION: This parameter indicates the type of synchronisation • Synchronisation via M bit of the S frame. • External synchronisation using an additional pair (master base station). • External synchronisation using an additional pair (slave base station). Note: If the DECT base stations are connected to the integrated S0 accesses of the NeXspan S CPU card, a third pair is required for synchronisation (use external synchronisation via an additional pair).
10.6 Checking the programming 10.6.1 Display the base stations Displaying the base stations enables you to carry out a final check of the declared base stations. MENU: 1.8.2.4 (Single-company management) or 1.9.2.4 (Multi-company management) BASE STATION DISPLAY ....EQT. TYPE STATUS TK GR CELL ------------------------------------------...
10.7.1 Declaring a mobile in the PBX A mobile must be created for each subscriber. MENU 1.8.3.1 (Single-company management) or 1.9.3.1 (Multi-company management) CREATE MOBILE ----------------------- DIRECTORY NUMBER 7542. COMPANY Aastra. DEPARTMENT 115.. WIRELESS TYPE DECT REFERENCE CELL ..DIRECTORY...
10.7.2 Deleting mobiles from the PBX Mobiles are deleted from the PBX using the menu "Delete mobiles" MENU 1.8.3.2 (Single- company management) or 1.9.3.2 (Multi-company management). This menu is used to delete one or more cordless handset subscribers. DELETE MOBILES ------------------------ FIRST DIRECTORY NUMBER 7542.
Chapter 11 - Programming for NeXspan 50 or NeXspan 500 PBXs 11.1 Introduction The DECT service programming steps are described for NeXspan 50 or NeXspan 500 PBXs. Note: It is essential to follow the programming order given. Deactivate the fibre tests (loop tests) MMC XCALEN (Value 31) Check the "local"...
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Declare the DECT parameters MMC XLIGAB, Object: radio restrictions, Topic: DECT parameter. The PARI number that identifies the system is always shown on a label on the outer casing. The "RS" and "Rand f" numbers must be between 1 and 4 294 967 294 (they are used during registration of the mobile).
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Register a mobile password MMC XSYSTM Enter a 5-digit password: 12345 by default. Declare and register a mobile See "Registering an M90x mobile terminal" on page 37 If the procedure fails, check the following: • that the registration of the base station in service is authorised •...
11.2 Routing check MMC "XACHEM , Object: Routing, Action: Display" is used to check local routing. ROUTING AND ANALYSIS Obj.=ROUTING. Action=Display Routing=0.. ------------------------------------------------------------- Type of routing=LOCAL TO STANDARD SUBSCR. Back-up routing for routings.= Routing used for analysis= Operation complete For a multi-site configuration check that the network ID field for local analysis is set to yes. ROUTING AND ANALYSIS Obj.=ANALYSIS.
11.3 Declare the TELBOR server When being put in service for the first time, the base station is updated by downloading from the PBX, if necessary. The TELBOR server and a PLL are used for downloading from the PBX software. The MMC XTGTOT "Action=Extend"...
11.4 Declare the radio zones The MMC XSERVI is used to declare the radio zones. • The "Zone" field must be " .. " and routing "local site" for a single-site configuration. • For a multi-site configuration, a cluster routing must be created in all the sites containing base stations.
11.6 Put the cards in service The base stations are declared on the S0 accesses of the DECT interface cards. Depending on previous subscriber registrations, the subscribers declared on these accesses must be checked and, if necessary, deleted. To check the availability of the S0 accesses and delete any S0 subscribers present on the accesses to be used by the base stations, use the MMC XABONS, "Subscr S0"...
11.7 Declare the cells The MMC XCELLU, Object "Cells", is used to declare the cells. A cell must be a group of base stations with adjacent coverage. The maximum number of base stations per cell is 8 (you are advised to configure only 6, with a view to expansion in order to increase traffic flow).
11.8 Declare the DECT parameters Declare the DECT parameters in the MMC XLIGAB, object "radio zones" sub-object "DECT parameters". The SARI number is the same as the PARI number. The PARI number is unique. TELEPHONE SUBSCRIBERS Object=Radio Restrictions Radio Topic=DECT Parameters Action=Display -------------------------------------------------------------------------------- PARI 1=0268652584...
11.9 Trunk group/cell association Use the MMC XBORFA, Object "Radstions Tk gp", to associate a company profile and a trunk group number with a cell number. This trunk group represents the resources in the cell and is used to associate the cell number with a physical equipment interface. TRUNK GROUP AND TRUNKS Object=Radstions Tkgp Action=Display...
11.10 Declare the base stations The MMC XBORFA, Object "RadSta", is used to declare the base stations. • The fields "TS Frame assignment" and "Freq. assignment" must not be changed (both at 1). • The field "Anten. choice" must be "Automatic" if the base station has no external antenna. •...
11.11 Register a mobile password The MMC XSYSTM is used to register a mobile password. SYSTEM PARAMETERS (Ctrl H: Help) Object=Password Type of password=Cordless Registration Action=Modify ----------------------------------------------------------------------- Password=..Operation Password=..11.12 Declare and register a mobile See "Registering an M90x mobile terminal" on page 37 11.13 Declare the DECT subscribers Use the MMC XLIGAB, object "Telephone subscribers", to declare the Telephone subscribers.
For details about menus and parameter definitions, refer to the document Aastra Management Portal AXD - AXL - AXS - AXS12 - AXS6- Aastra 5000 Server – Operating manual (AMT/PTD/ PBX/0080). Note: It is essential to follow the programming order given.
12.2 DECT management menu From AMP, the menu TELEPHONY SERVICE /NETWORK AND LINK/Equipment/DECT Management gives access to the following columns: 12.2.1 Declare the cells This screen is accessible via NETWORK AND LINKS / Equipment / DECT management . This screen allows you to declare the cells that were defined during deployment. The maximum number of cells is fixed at 128 (for single-site configuration) and 254 (for multi-site configuration).
12.2.2 DECT parameters This screen is accessible via NETWORK AND LINKS / Equipment / DECT management . Note: For a multisite network, additional parameters appear, making it possible to define the list of sites on which the mobile terminals will be registered, see Chapitre 11. •...
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• DIR. BEGINNING ASSIGNED TO LLP: 4 digits maximum, 999 is the default. The base stations are connected to the PBX via an S0 Basic Rate Interface. One PLL (D channel) is used for signalling and downloading to the base stations. PLL directory numbers are comprised of digits recorded in this parameter followed by the base station declaration order number.
12.3 Resources 12.3.1 Naming the trunk groups This screen is accessible via NETWORK AND LINKS / Equipment / DECT management. One trunk group must be associated with one cell only. One cell contains from 1 to 8 base stations. This screen is used to display the names of declared trunk groups and to create new trunk groups.
12.3.3 Allocating base stations This screen is accessible via NETWORK AND LINKS / Equipment / DECT management . This screen is used to select a base station based on different criteria. Note: to declare a DECT trunk group in a cell, all base stations in the cell must be out of service.
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This parameter indicates the type of base station (2- or 4-channel). BELONG TO TRUNK GROUP This parameter indicates the name of the iPBX trunk group linked to the base station. MOBILE RECORDING ALLOWED The box must be ticked during mobile registration if the base station is used for registration. Conclude cordless handset registration by unticking the box in this field to avoid fraudulent registrations.
12.3.4 Display the base stations This screen is accessible via NETWORK AND LINKS / Equipment / DECT management . This screen is used to display the declared DECT base stations. EQUIPMENT NO. Indicates the equipment number: rack number, card number, circuit number BASE NB DECT base station number.
12.3.5 Base station moving This screen is accessible via NETWORK AND LINKS / Equipment / DECT management . ORIGINAL POSITION Indicates the equipment number: rack number, card number, circuit number NEW POSITION Indicates the new equipment number. NUMBER OF MOVES REQUESTED Indicates the number of base station moves that must be made.
Aastra Management Portal AXD – AXL – AXS – AXS12 – AXS6– Aastra 5000 Server Operating Manual (AMT/PTD/PBX/0080) • AXD - AXL - AXS - AXS12 - AXS6 - Aastra 5000 Server Installation and Maintenance Manual (AMT/PTD/PBX/0058) 12.5 Registration and putting in service 12.5.1 Declaring a DECT terminal in Aastra X series...
12.5.3 Deactivating the mobile registration authorisation From the menu NETWORK AND LINKS / Equipment / DECT management : Select the base station in question by clicking " Select item ". On the line MOBILE RECORDING ALLOWED • Untick the box in the parameter to prevent recordings. AMT/PTD/TR/0020/2/7/EN 10/2008 Page 12-208...
(before R5.1) Note: The use of the DECT system in a heterogeneous environment (R4.2 and/or earlier) with Aastra X series R5.1 sites is not handled in this chapter. 13.1 Precautions to be taken in a multisite configuration 13.1.1 Contiguous multi-site configuration For practical and operational reasons, it is essential to declare different cell numbers in the various sites (by allocating a range of numbers to each site).
13.1.2 Non-contiguous multi-site configuration It is not necessary to give the different cells different numbers in the MMCs. The following MMCs must be carried out: • Declare the same PARI on all the sites. • Same RANDOM registration number on all the sites. •...
13.3 Programming the DECT parameters For the NeXspan C/S/L range, menu 1.8.1.2 (single-company management) or 1.9.1.2 (multi- company management) is used to program the DECT parameters: DECT PARAMETERS PARI VALUE 0 999999999. RANDOM VAL RECORDED 86..RS VAL RECORDED 66..DIR.
13.4 Multi-site configuration with OCT4 In a multi-site configuration with OCT4 (or OCT4 I), one cabinet is declared "Reference Site": Menu 1.8.1.2 (Single-company management) or 1.9.1.2 (Multi-company management) DECT PARAMETERS PARI VALUE 0 999999999. RANDOM VAL RECORDED 86..RS VAL RECORDED 66..
13.5 Special case of a multi-site configuration with UCT-S/UCT- L/UCT-D In a multi-site configuration with UCT (UCT-S or UCT-L or UCT-D), one PBX (Simplex mode) or two PBXs (Duplex mode) are declared "Master". Note: NeXspan C has no synchronisation port but is capable of DECT multi-site synchronization via a third pair.
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For the other sites the programming is as follows: DECT PARAMETERS PARI VALUE 0 999999999. RANDOM VAL RECORDED 86..RS VAL RECORDED 66..DIR. BEGINNING ASSIGNED TO PLL 999. SEARCH MOBILES NOT REGISTERED IN THE LOCAL SITE OR IN ANOTHER SITE ..
13.5.2 Duplex mode In duplex mode, two PBXs are masters (one "Priority master” and the other “Not priority master”) and can provide the DECT synchronisation signal for the entire multi-site network. Other sites are configured as "Slaves". Menu 1.8.1.2 (Single-company management) or 1.9.1.2 (Multi-company management): one site is declared priority Master DECT PARAMETERS PARI VALUE 0...
For the other sites the programming is as follows: DECT PARAMETERS PARI VALUE 0 999999999. RANDOM VAL RECORDED 86..RS VAL RECORDED 66..DIR. BEGINNING ASSIGNED TO PLL 999. SEARCH MOBILES NOT REGISTERED IN THE LOCAL SITE OR IN ANOTHER SITE ..