02 system components r4 1

Motorola Confidential – Do Not Redistribute

Section 2

DIPC R4.1

System Components

Document Location: MOL – Resource Centre : TETRA Infrastructure / Dimetra IP Compact Partner / Dimetra IP Compact – Accredited Partner Resources / System Planners

Issue O Section 2 © Motorola 2010 12th August 2010 DIPC R4.1 - System Components 1-51


Revision History

Issue Date Author(s) Amendment History Change Note Number

O 12th August 2010

Motorola

Author’s Notes

If any further detail is required please ask your local Motorola Sales Representative

This document uses bookmarks within the text. If you click on a reference to a section number or figure in the text, you will jump to that location.



Table of Contents Contents

Revision History 2

Author’s Notes 2

Sections

2 System Components 6

2.1 Introduction 6

2.1.1 Summary 6

2.1.2 Changes Introduced in R4.1 6

2.2 Common Server Platform 7

2.2.1 Sun Fire X4170 Server 7

2.2.2 Sun Netra X4250 Server 8

2.3 MSO Components 9

2.3.1 Compact Zone Server/Small Zone Server 9

2.3.2 LAN Switch 10

2.3.3 Combined Core/Gateway/(Exit) Router 12

2.3.4 Cooperative WAN Routing Relay Panel 13

2.3.5 VPN Router 15

2.3.6 VPN Client Software 15

2.3.7 Redundant Zone Controller 16

2.3.8 Redundant Core/Gateway/(Exit) Router 16

2.3.9 Backhaul Switch 17

2.3.10 Motorola Telephone Interconnect Gateway 17

2.3.11 Echo Canceller 18

2.3.12 Packet Data Gateway 19

2.3.13 GGSN 19

2.3.14 Short Data Router 20

2.3.15 Redundant Short Data Router 20

2.3.16 KVM Switch 20

2.3.17 Border Router 21

2.3.18 Redundant Border Router 22

2.3.19 Authentication Centre 22



2.3.20 Provisioning Centre (PrC) 22

2.3.21 Air Interface Encryption Key Variable Loader 22

2.3.22 Key Management Facility (KMF) 23

2.3.23 End-to-End Encryption KVL 23

2.3.24 Network Time Server 23

2.3.25 Backup/Restore Collector 23

2.4 Control Site Components 24

2.4.1 Network Management Terminal 24

2.4.2 Network Management Printer 24

2.4.3 Dispatch Console 24

2.4.4 Logging Recorder Components 36

2.4.5 Control Site Router 39

2.5 DIPC Cabinets 39

2.6 Base Stations 41

2.6.1 MTS2 41

2.6.2 MTS4 43

2.6.3 MTS 4 Outdoor Cabinet 46

2.7 Mobile Stations 46

2.7.1 Portables 48

2.7.2 Mobiles 49

2.8 Export Control Requirements 51

Table of Figures Figure 1: Sun Fire X4170 server 8

Figure 2: Sun Netra X4250 server 9

Figure 3: HP Procurve Switch 2610-48 11

Figure 4: HP Gigabit LX-LC mini GBIC 12

Figure 5: HP Gigabit LH-LC mini GBIC 12

Figure 6: ST6000 router Interface 13

Figure 7: ST6615A 12-port E1 WAN interface module 13

Figure 8: CWR Relay Panel 14

Figure 9: Netgear Pro Safe FVX538 VPN Firewall 15



Figure 10: Tellabs 3100M Echo Canceller 18

Figure 11: Gateway GPRS Support Node 20

Figure 12: KVM unit 21

Figure 13: ST6000 router 21

Figure 14: GPIOM front view 25

Figure 15: GPIOM connections 25

Figure 16: MCC 7500 loudspeaker 26

Figure 17: MCC 7500 headset jack 27

Figure 18: MCC 7500 headset 28

Figure 19: PTT Amplifier Module 28

Figure 20: MCC 7500 desktop microphone 29

Figure 21: MCC 7500 foot switch 29

Figure 22: Beacon 30

Figure 23: Motorola E2EE Console CryptR module 31

Figure 24: VX222HR-MIC Soundcard 32

Figure 25: MCC 7500S Headset USB Soundcard 33

Figure 26: MCC 7500S Local Logging USB Soundcard 33

Figure 27: MCC 7500S loudspeaker 34

Figure 28: MCC 7500S headset 34

Figure 29: MCC 7500S desktop microphone 35

Figure 30: USB Footswitch Adapter 35

Figure 31: DIPC Cabinets (not to scale) 40

Figure 32: MTS2 42

Figure 33: MTS 4 44

Figure 34: MTS 4 Outdoor Cabinet 46

Figure 35: MTM5400 49

Figure 36: MTM800 Enhanced 50




2 System Components

DIPC R4.1 re-uses the 24 RU1 (enhanced) and 38 RU (extended) cabinet based configurations from previous releases.

2.1 Introduction This section provides a description of each of the components used within and with a DIPC system.

The section is structured into the following main headings:

• Common Server Platform • MSO Components • Control Site Components • DIPC Cabinets • Base Stations • Mobile Stations

2.1.1 Summary This section of the System Planner includes the following information:

• A description of each component used in DIPC R4.1 systems. • A statement of how many of each component is required and whether they are

optional. Where quantities of equipment for Geographically Redundant configurations are different from the quantities for Regular configurations then this is highlighted in the descriptions. If it is not highlighted then the quantities are the same for either system configuration, however they may be split between the two locations. See the Introduction, Overview and Architecture Section of the System Planner for details.

• Basic specifications for each component including physical size, weight, power consumption and connection types Note where power consumption figures are quoted these have been taken from a variety of sources including manufacturer’s data, Motorola system test, Motorola System Integration and from a single system in the field, except where they are listed as measured figures, they should be used as guidance only.

More detailed information on the DIPC R4.1 architecture can be found in the other sections of the System Planner.

2.1.2 Changes Introduced in R4.1 System Component changes introduced in DIPC R4.1 and clarifications that have been covered in this section include:

• Sun Fire X4170 server replacing Netra 240 for Compact/Small Zone Server and Redundant Zone Controller.

1 RU = rack unit = 44.45 mm



• Unified Event Manager replaces FullVision. • USB to serial port converters added to Compact/Small Zone Server and Redundant

Zone Controller. • Ethernet Core Routers - for IP over Ethernet links. • Introduction of Ethernet based Telephone Interconnect. • Aggregation LAN switch added. • Support for MTS 1 base station. • Backhaul Switches - used for the connection of Ethernet site links. • New PC client - HP Z200 replacing the XW4600. • server weights and rack weights revised • server power consumptions revised

2.2 Common Server Platform DIPC uses the two common server platforms from full Dimetra IP.

2.2.1 Sun Fire X4170 Server The main common server is the Sun Fire X4170 Server with the following specification:

• Intel Xeon Quad-Core Processor E5520/2.26 GHz, 8 MB cache, 5.86 GT/s Intel QPI

• 4 Gbyte RAM - 2x2GB PC2-5300, 1066 MHz, DDR3 DIMM • DVD +/- RW drive • Four Gigabit LAN ports • Two 146 GB hot-swappable disk drives, configured for Redundant Array of

Independent Drives (RAID) 1 (disk mirroring) operation2 • Dual hot-swappable power supplies • Redundant hot-swappable fans • Five USB 2.0 ports • An Integrated Lights Out Management (ILOM) facility is included to facilitate remote

diagnostics and problem resolution The Sun Fire X4170 server is used for:

• The Compact Zone Server/Small Zone Server • The Redundant Zone Controller • Ethernet based Motorola Telephone Interconnect Gateway (MTIG-IP) • Packet Data Router • Radio Network Gateway • Short Data Router • NICE Logging Recorder • NICE INFORM Server

2 Two 300 GB hot swappable disk drives on the Logging Recorder.


• NICE Storage Centre • Key Management Facility The photograph below shows the Sun Fire X4170 server:

Figure 1: Sun Fire X4170 server

Unit Specifications*

LAN Ports (x4) 10/100/1000 Base-T Ethernet, RJ45

Monitor output, keyboard and mouse SVGA connector, USB connectors

AC input voltage 100 - 120 / 200 - 240 VAC

AC input frequency 50 - 60 Hz nominal

AC input power 229 W( measured under 100% processor load)

Length / Depth 686 mm

Width 426 mm

Height 43 mm (1 Rack Unit)

Weight 19.5 kg (including rails) * Unused interfaces are not listed.

2.2.2 Sun Netra X4250 Server The other common server platform used in DIPC R4.1 is the Sun Netra X4250 with the following specification:

• Intel Xeon Quad-Core Processor L5408/2.13 GHz, 12 MB L2 cache, 1066 MHz FSB.

• 4 Gbyte RAM - 2x2GB PC2-5300, 667 MHz, ECC, Fully Buffered, DDR2 DIMM. • 8 x DVD +/- RW drive • 4 Gigabit LAN ports • Each server is fitted with two 146 Gbyte hot- swappable disk drives. Configured for

Redundant Array of Independent Drives (RAID) 1 operation. • Two USB 2.0 ports • Dual power supplies are used for redundancy. • The Netra server Integrated Lights Out Management (ILOM) facility is included to

facilitate remote diagnostics and problem resolution.



The Netra X4250 server is used for:

• E1 based Motorola Telephone Interconnect Gateway (MTIG-E1) • Authentication Centre The photograph below shows the Sun Netra X4250 server:

Figure 2: Sun Netra X4250 server

Unit Specifications


LAN Port (x1) for Network Management 10 Base-T Ethernet, RJ45

Console Port RS232, RJ45

Monitor output, keyboard and mouse SVGA connector, USB connectors

AC input voltage 100 - 240 VAC


AC input power 290 W (measured under 100% processor load)

Length / Depth 526 mm (including PSU handles)

Width 445 mm

Height 87 mm (2 Rack Units)

Weight 20.5 kg (including rails) * Unused interfaces are not listed.

2.3 MSO Components 2.3.1 Compact Zone Server/Small Zone Server

The Compact Zone Server or Small Zone Server (CZS or SZS) use the Sun Fire X4170 Common Server Platform described in 2.2.1. DIPC will use either a CZS or an SZS. The hardware is the same for both types of servers; the only difference is the CZS runs an additional server function. The CZS is used in single zone DIPC as well as in the first zone of a multizone DIPC system, the SZS is used in additional zones in a multizone DIPC system.

In the CZS and SZS, the following server functions are consolidated into a single physical server.

• Zone Controller (ZC) – main call processing component in the system.



• Zone Database Server (ZDS) – holding the configuration of the infrastructure in the system.

• User Configuration Server (UCS) – mainly holding the configuration of all subscribers and talkgroups in the system. Only installed in a CZS.

• Unified Event Manager Server (UEM) – fault management in the system. • Zone Statistics Server (ZSS) – processing statistics data for all calls in the system. • Air Traffic Router (ATR) – collecting call processing information and acting as a front

end to the ZC. A technology from Sun called Solaris Containers is used, which permits the six server functions to run as virtual servers on the same physical hardware. In order to support Solaris Containers, Solaris 10 operating system is used. As the combined server hosts a total of six servers, the impact of a disk failure is increased significantly resulting in a higher Mean Time To Repair (MTTR). Therefore, the availability of call processing is increased by adding a second hard disk and enabling disk mirroring (RAID 1) on these two disks.

If the NTS subsystem is not used then the ZDS acts as a server for the Network Time Protocol (NTP). All other devices will synchronise their time with this server using NTP. It is also possible to synchronise the system from an external NTP server, but only if SDS and a border router is included.

If the system supports Air Interface Encryption (AIE), a USB to serial port converter is required to connect the server to the KVL.

Quantity The Compact Zone Server or Small Zone Server comprises one Sun Fire X4170 Server. One USB to serial port converter is also required on an AIE system.

2.3.2 LAN Switch Every DIPC system requires a Core LAN Switch. Regular systems with Core Redundancy also require a Redundant LAN Switch. Geographically Redundant systems require two Core LAN Switches and two Redundant LAN Switches.

2.3.2.1 Core LAN Switch The Core LAN switch is the main Ethernet switch used to interconnect all of the system elements in the Core Subsystem plus the optional subsystems.

In addition to the normal LAN connections, the Core LAN switch has a connection to an Integrated Lights Out Management (ILOM) service port on each server for diagnostics purpose.

The Core LAN switch consists of a single HP2610-48 switch. The HP ProCurve Switch 2610-48 is a low-cost, multi-layer, managed 50-port switch with 48 10/100 ports, two 10/100/1000Base-T ports and two mini-GBIC slots.

Quantity See table in section 2.3.2.4 for quantities.



Figure 3: HP Procurve Switch 2610-48

Unit Specifications

LAN Ports (x48) 10/100 Base-T Ethernet, RJ45


Console Port (x1) RS232, RJ45

Gigabit Port (x2) open mini-GBIC (SFP) slots

AC input voltage 100 - 120 / 200 - 240 VAC


AC input power 100 Watt


Width 442 mm

Height (each chassis) 43.9 mm (1 Rack Unit)

Weight 4.88 kg

2.3.2.2 Redundant LAN Switch In a Redundant DIPC system, the Redundant LAN switch is the main Ethernet switch used to interconnect all of the elements within the Core Redundancy Subsystem to the Core Subsystem and some of the optional subsystems. In a Geographically Redundant DIPC system it is used together with the Core LAN switch to interconnect elements of the SplitZone Core Subsystem and some of the optional subsystems.

The Redundant LAN switch consists of an HP2610-48 switch and is connected to the Core LAN switch using two Gigabit Ethernet trunks for redundancy. The Redundant LAN switch has the same specification as the Core LAN switch described in 2.3.2.


2.3.2.3 GigaBit Interface Converter For Geographical Redundancy each switch is fitted with a mini GBIC (GigaBit Interface Converter) module to link with the equivalent switch at the other location. The module is either an HP Procurve Gigabit LX-LC mini GBIC or an HP Procurve Gigabit LH-LC mini GBIC.

• The HP Procurve Gigabit LX-LC mini GBIC will support a full duplex gigabit link between 2 m and 10 km (single-mode) in length. The cable specification is 9/125 µm (core/cladding) diameter, graded-index, 1310 nm, low metal content, single mode fibre optic cables, complying with the ITU-T G.652 and ISO/IEC 793-2 Type B1 standards. Multimode cables can also be used, but they will require a mode conditioning patch cord at both ends and are limited to 550 m maximum length.

• The HP Procurve Gigabit LH-LC mini GBIC will support a full duplex gigabit link between 10 m and 70 km (single-mode) in length. The cable specification required is 9/125 µm (core/cladding) diameter, graded-index, 1310 nm, low metal content,



single mode fibre optic cables, complying with the ITU-T G.652 and ISO/IEC 793-2 Type B1 standards. For distances less than 20 km, a 10 dB attenuator must be used. For distances between 20 km and 40 km, a 5 dB attenuator must be used. The HP GBIC modules do not support repeaters so 70 km is the maximum length of the links.

• The link requires “dark” fibres (fibres that are not used for any other purpose apart from the Dimetra IP locations’ Gigabit links).

• Two fibres are required for each link (one for each direction). So a Geographically redundant system will require a total of four fibres to link the LAN switches at each location.


The photographs below show the HP mini GBIC Modules:

Figure 4: HP Gigabit LX-LC mini GBIC

Figure 5: HP Gigabit LH-LC mini GBIC

2.3.2.4 Quantities of LAN Switches and mini GBIC Modules The following table summarises the total number of switches (Core and Redundant) and mini GBIC modules required for each configuration. In Geographically Redundant systems each switch is fitted either with one HP Procurve Gigabit LX-LC mini GBIC or with one HP Procurve Gigabit LH-LC mini GBIC. NA is Not Applicable.

System Configuration Distance between

Geographically Redundant Locations

Quantity of HP 2610-48

Qty of LX-LC mini GBIC modules

Qty of LH-LCmini GBIC modules

Regular without Core Redundancy

NA 1 NA NA

Regular with Core Redundancy

NA 2 NA NA

Geographically Redundant Up to 10 km 4 4 0

Geographically Redundant 10 km to 70 km 4 0 4

2.3.3 Combined Core/Gateway/(Exit) Router In the Combined Core/Gateway/(Exit) Router (CGE Router), the following router functions are consolidated into a single physical router.

• Core Router – the WAN interface and the multicast router for the voice multicast groups.

• Gateway Router – routing packets between different virtual LANs and the multicast router for the call control multicast groups.



• Exit Router – the WAN interface for InterZone traffic. Only used in multizone systems. See the Introduction, Overview and Architecture section of the System Planner for a definition of which configurations support InterZone traffic.

The combined router performs all IP routing functionalities in the system, and provides the WAN interface to remote RF sites and remote control sites. The WAN connections can be Ethernet, E1 or channelised/fractional E1. X.21 is not supported.

For systems using Ethernet WAN connections, the CGE Router uses a Motorola ST6000 series router. Connections are made to all three Ethernet ports, two are connected back to the Core LAN switch and the third connects to a Backhaul Switch, which provides the connection to the GBN for the Ethernet site links and inter zone links. For MSOs with collocated zones the CGE Router communicates with the collocated zones via the Backhaul switch as though they were at different MSOs.

For systems using E1 WAN connections, the CGE Router uses a Motorola ST6000 series router fitted with a single 12-port E1 WAN interface that connects to the Cooperative WAN Routing Relay Panel described in 2.3.4. In Regular systems with core redundancy operating in CWR mode a second 12-port E1 module may be installed to enable a ring connection to be set up if linking with other zones.

Quantity For systems using Ethernet WAN links, one ST6000 router

For systems using E1 WAN links, one ST6000 router fitted with one or two ST6615A 12-port E1 WAN interface modules.

The photographs below show the ST6000 Core Router and the 12-port E1 module:

Figure 6: ST6000 router Interface

Figure 7: ST6615A 12-port E1 WAN interface module

Unit Specifications

LAN Port (x3) 10 / 100 Mbit/s Ethernet, RJ45

Console Port (service access) RS232 serial data, 9 pin D connector



AC input power 40 Watts


Width 430 mm


Weight 4.6 kg maximum

2.3.4 Cooperative WAN Routing Relay Panel The Cooperative WAN Routing (CWR) Relay Panel switches 12 x E1 connections from a single or a pair of Combined Core/Gateway/(Exit) Routers to the remote sites and



other zones. The panel is also known as a Cooperative WAN Routing panel or CWR panel.

The CWR Relay Panel uses latching relays which do not require power to retain their switch position. All power to operate these relays comes from the routers. The relays are located on two CWR Modules. The two modules are electrically independent of each other and each module switches 12 E1 lines.

The CWR Modules can operate in either CWR mode or non-CWR mode. In CWR mode two routers connect to the same module and the relays switch all twelve E1 lines when needed. In non-CWR mode only one router is connected to the module and the relays are fixed in one position.

In Regular systems without Core Redundancy a single CWR panel with one CWR Module is used. The CGE Router connects to the CWR Module using 12 E1 lines. The relays in the CWR Module are locked in place (non CWR mode).

In Regular systems with Core Redundancy but without redundant site links a single CWR panel with one CWR Module is used. The CGE Router and Red CGE Router are connected to the CWR Module using 12 E1 lines. The relays in the CWR switch between the routers as and when needed (CWR mode). This is the only configuration that can be used to support multizone systems with the Exit Router functionality.

In Regular systems with Core Redundancy and redundant site links a single CWR panel with two CWR Modules is used. The CGE Router connects to one CWR Module using 12 E1 lines and the Red CGE Router connects to the other CWR Module using another 12 E1 lines. The relays in both CWR Modules are locked in place (non CWR mode).

In Geographically Redundant systems a single CWR panel with one CWR Module is used in each location. The CGE Router connects to the CWR Module at the first location using 12 E1 lines and the Red CGE Router connects to the CWR Module at the second location, using another 12 E1 lines. The relays in both CWR Modules are locked in place (non-CWR mode).

All E1 connections and relay control signals are fed to the Relay Panel using 62 pin connectors.

Quantity One or two 24-port Relay Panels with one or two 12-port CWR Modules

The photograph below shows the CWR Relay Panel with two CWR Modules:

Figure 8: CWR Relay Panel

Unit Specifications

WAN Ports (x24) E1, RJ45

Router Connection Ports (x4) 62 Pin AMP high density connector


Width 440 mm




2.3.5 VPN Router As part of the remote access solution for service and maintenance the VPN router allows a service technician to run a remote desktop on the NM Client. The service technician can then work on the entire system using both standard Dimetra NM tools and the pre-installed additional service tools. In addition, it is possible to access most system elements via Telnet on VPN remote access if NM client is unavailable. Any service technician with a corresponding VPN client and the correct security credentials shall be able to access the system. This will normally be a Motorola service technician. The VPN Router will allow a minimum of 128kbps remote connection, depending on the bandwidth of the available network connection.

The VPN router connects to a broadband modem provided by the customer.

The VPN Router used is the Netgear Pro Safe FVX538 VPN Firewall, which uses Stateful Packet Inspection, Denial of Service technology and it includes an 8-port LAN switch.

Quantity One Netgear ProSafe FVX538 VPN Firewall

The photograph below shows the Netgear Pro Safe FVX538 VPN Firewall:

Figure 9: Netgear Pro Safe FVX538 VPN Firewall

Unit Specifications


LAN Port (x1) 10 / 100 / 1000 Mbit/s Ethernet, RJ45

WAN Port (x2) 10 / 100 Mbit/s Ethernet, RJ45




AC input power 9 W (measured)


Width 330 mm



2.3.6 VPN Client Software The VPN Client software is used by a service technician to gain remote access to the DIPC system via the VPN Router. The service technician will usually be a Motorola technician or in certain cases may be an authorised distributor.



The VPN client software is TheGreenBow IPSec VPN Client V4.0. The VPN client software is loaded onto a service laptop which can then connect to the DIPC system via the internet.

2.3.7 Redundant Zone Controller The Redundant Zone Controller (Red ZC) uses the Sun Fire X4170 Common Server Platform described in section 2.2.1.

The Red ZC provides redundant Zone Controller functionality to the Compact Zone Server or Small Zone Server. Should the Compact Zone Server or Small Zone Server fail, then all call processing operation continues on the Redundant ZC Server after an automatic switchover. It does not provide redundancy to any of the NM servers

If the system supports Air Interface Encryption (AIE), a USB to serial port converter is required to connect the server to the KVL.

Quantity The Red ZC comprises one Sun Fire X4170 Server. One USB to serial port converter is also required on an AIE system.

2.3.8 Redundant Core/Gateway/(Exit) Router The Redundant Core/Gateway/(Exit) Router (Red CGE Router) provides redundant routing functionality and WAN connectivity, together with the CGE Router.

For systems using Ethernet WAN connections, the Red CGE Router uses a Motorola ST6000 series router. Connections are made to all three Ethernet ports, two are connected back to the Redundant LAN switch and the third connects to a second Backhaul Switch, which provides the connection to the GBN for the Ethernet site links and inter MSO links. For MSOs with collocated zones the Red CGE Router communicates with the collocated zones via the Backhaul switch as though they were at different MSOs. In Geographically Redundant DIPC systems, the CGE Router and one Backhaul switch are at Location A and the Red CGE Router and the second Backhaul Switch are at Location B.

For systems using E1 WAN connections, the Red CGE Router uses a Motorola ST6000 series router fitted with a 12-port E1 WAN interface that connects to the Cooperative WAN Routing Relay Panel described in 2.3.4. In Regular systems with core redundancy operating in CWR mode a second 12-port E1 module may be installed to enable a ring connection to be set up if linking with other zones. The Red CGE Router has the same specification as the CGE Router described in 2.3.2.2 In Regular DIPC systems only one router connects to the remote sites at any one time. In Geographically Redundant DIPC systems redundant MTS and Control site links are connected via CWR panels to both the CGE Router and Red CGE Router; control sites and MTS sites with single links can be distributed across both the CGE Router and Red CGE Router.

Quantity For single zone Regular systems using Ethernet WAN links, one optional ST6000 router

For Multizone Regular systems using Ethernet WAN links, one mandatory ST6000 router

For Geographically Redundant systems using Ethernet WAN links, one mandatory ST6000 router



For single zone Regular systems using E1 WAN links, one optional ST6000 router fitted with one ST6615A 12-port E1 WAN interface modules

For Multizone Regular systems using E1 WAN links, one mandatory ST6000 router fitted with one ST6615A 12-port E1 WAN interface modules

For Geographically Redundant systems using E1 WAN links, one mandatory ST6000 router fitted with one ST6615A 12-port E1 WAN interface modules

2.3.9 Backhaul Switch The Backhaul Switch is an HP2610-48 switch used to interconnect the Combined Core/Gateway/(Exit) Router or the Redundant Core/Gateway/(Exit) Router using Ethernet WAN interfaces to the Ground Based Network (GBN). The Backhaul Switch is compulsory for any MSO with Ethernet WAN connections.

For Regular systems without core redundancy only a single Backhaul Switch is required.

For Regular systems with core redundancy a pair of Backhaul Switches is required. One connected to the Core/Gateway/(Exit) Router and one connected to the Redundant Core/Gateway/(Exit) Router.

In Geographically Redundant systems one Backhaul Switch is placed at each location.

In systems with multiple collocated zones the Backhaul Switch is used for connection of all zones at one MSO to the GBN. Multiple clusters at the same MSO will require a Backhaul Switch per cluster. A cluster that is split over several MSOs will require a Backhaul Switch per MSO. See the Architecture and the Networking sections of the System Planner for more information.

Quantity One HP Procurve Switch 2610-48 in Regular system configurations without core redundancy

Two HP Procurve Switch 2610-48 in Regular system configurations without core redundancy

Two HP Procurve Switch 2610-48 in Geographically Redundant system configurations (one in each location)

2.3.10 Motorola Telephone Interconnect Gateway The Motorola Telephone Interconnect Gateway (MTIG) serves two purposes: first it acts as a gateway in the Telephone Interconnect architecture and secondly it provides two way transcoding of voice between the external PABX and the Dimetra IP network. There are two types of MTIG available, MTIG-E1 and MTIG-IP. It is not possible to use an MTIG-E1 in the same zone as an MTIG-IP, but they can be mixed in a cluster so one zone uses MTIG-E1 and another uses MTIG-IP.

2.3.10.1 MTIG-IP The MTIG-IP uses the Sun X4170 server described in 2.2.1.

The MTIG-IP communicates with a PABX using SIP signalling over Ethernet. The MTIG-IP connects to the external PBX via the Core LAN switch and Border Router. The MTIG-IP does not require an Echo Canceller.

The MTIG-IP runs under the Solaris 10 x86 operating system.



Quantity One or two Sun X4170 servers. Each MTIG-IP can support up to 60 telephone interconnect calls to give a maximum of 120 per zone. Two MTIG-IPs are supported either in a Regular system with extended cabinet or in a Geographically Redundant system with one at each Location.

2.3.10.2 MTIG-E1 The MTIG-E1 uses the Sun Netra x4250 server described in section 2.2.2 fitted with an E1 interface card, an H.100 bus cable and a voice card.

The E1 card is used for connection to the telephone network using 2.048 Mbit/s PCM. The voice card performs the translation from PCM voice to vocoded speech used by the Dimetra radio system. The MTIG-E1 requires an Echo Canceller to connect to the PABX.

The MTIG-E1 runs under the Windows XP Operating System.

Quantity One or two Sun Netra x4250 servers fitted with an E1 interface capable of supporting one E1, an H.100 bus cable and a voice card. Each MTIG-E1 can support up to 60 telephone interconnect lines (two E1s) to give a maximum of 120 per zone.. Two MTIG-E1s are supported either in a Regular system with extended cabinet or in a Geographically Redundant system with one at each Location.

2.3.11 Echo Canceller The round trip audio delay from a Mobile Station (MS) to the PABX and back again is significant, and any echo of the MS user’s voice, which is generated in the external telephone network, can be severely distracting. The Echo Canceller is used to reduce the acoustic echo that can occur on telephone interconnect calls so that it does not trouble the radio user. This echo is due to the vocoder delays, telephone system delays, imbalance in the telephone network and acoustic feedback in the subscriber environment.

The Echo Canceller (EC) is a Tellabs 3100M which can process two E1 30-channel PCM voice streams. This provides a capacity to process 60 telephone calls. Telephone Interconnect operation also requires an MTIG-E1 as described above. One EC is required per MTIG-E1. The EC is not used with the MTIG-IP.

Quantity One or two Echo Canceller chassis, each including a Dual E1 Echo Canceller Module (ECM), a Network Control Module (NCM), a Power Supply Unit and a Fan Unit. Two ECs are supported either in a Regular system with extended cabinet or in a Geographically Redundant system with one at each Location.

The photograph below shows the Tellabs 3100M Echo canceller:

Figure 10: Tellabs 3100M Echo Canceller



Unit Specifications

Telephone network 2 x 2.048 Mbit/s E1 PCM, 120 ohm balanced

Telephone gateway 2 x 2.048 Mbit/s E1 PCM, 120 ohm balanced


AC input frequency 47 - 63 Hz

AC input power 72 W @ 230 VAC


Width 430 mm

Height 90 mm (2 Rack Units)

Weight 7 kg

2.3.12 Packet Data Gateway This gateway supports the Packet Data Service (PDS).

The Packet Data Gateway (PDG) consists of the Radio Network Gateway (RNG) and Packet Data Router (PDR). The RNG handles the TETRA advanced link communication with the Mobile Stations (MSs), whereas the PDR handles the routing of IP datagrams to and from the GPRS Gateway Support Node (GGSN), which provides the communication with external IP networks using the PDS. The PDR also tracks mobility of the subscribers.

The PDG uses two Sun x4170 servers described in section 2.2.1. The PDG runs the Linux Operating System.

Quantity Two Sun x4170 servers

2.3.13 GGSN The General Packet Radio Service (GPRS) is defined and standardized by the European Telecommunication Standards Institute (ETSI) and is an IP packet-based data service developed for Global System for Mobile Communications (GSM) networks. GPRS uses two major network elements:

• Serving GPRS support node (SGSN) • Gateway GPRS support node (GGSN) In DIPC systems the GGSN functionality for interfacing the Packet Data Service to external networks is re-used from full Dimetra IP. In Dimetra, the Packet Data Gateway acts as the equivalent to the SGSN.

The GGSN forwards packets destined for subscribers to the appropriate PDR, which keeps track of subscriber mobility.

The GGSN function uses a Motorola ST6000 series router with GGSN firmware. This router provides 3 LAN interfaces.

Quantity One ST6000 router with GGSN firmware



The photograph below shows the ST6000 router:

Figure 11: Gateway GPRS Support Node

Unit Specifications

LAN Port (x3) 10 / 100 Base-T Ethernet, RJ45




AC input power 40 W


Width 430 mm



2.3.14 Short Data Router The SDR supports the Short Data Transport Service by enabling routing of short data messages within the system based on TETRA Short Subscriber Identities (ISSIs and GSSIs). All short data packets to be delivered via the TETRA Short Data Service (SDS) are sent to the SDR. For short data messages to be delivered to MSs, the SDR forwards the short data message to the appropriate BTS. For short data messages to be delivered to an (external) fixed host, the SDR maps the TETRA addressing to an IP address and forwards the short data message to the host using IP. A Linux Operating System is utilised.

The SDR uses a Sun x4170 server described in section 2.2.2. The SDR runs the Linux Operating System.

Quantity One Sun x4170 server

2.3.15 Redundant Short Data Router In a Geographically Redundant DIPC system the Redundant Short Data Router can be used to provide a resilient SDR solution with manual switchover. It uses the same hardware configuration as the Short Data Router described in section 2.3.14.


2.3.16 KVM Switch The KVM (Keyboard, Video and Mouse) switch is a Black Box ServView 17 and consists of a keyboard, touchpad or trackball, LCD monitor and interface switch. The unit allows the human interface to be shared across up to eight or sixteen servers. Switchover between the servers is accomplished using keyboard commands. The KVM is used to access all servers in the rack it is installed in. The KVM switch is optional in the extended cabinets only; it cannot be fitted in the enhanced cabinets.



Quantity One ServView 17 per enhanced MSO cabinet comprising keyboard, touchpad or trackball, LCD monitor and switching unit. Adapter cables supplied convert from 25 pin D connector to SVGA and USB connectors.

The photograph below shows the KVM:

Figure 12: KVM unit

Unit Specifications

Keyboard / mouse / video 25 pin D female connector *


AC input frequency 47 - 63 Hz

AC input power 66 W maximum


Width 440 mm (19 " rack mount)

Height 44 mm ( 1 Rack Unit)

Weight 18 kg

2.3.17 Border Router The Border Router provides an interface to the Customer Enterprise Network (CEN) both for the data services and for the APIs available in CEN. The APIs can only be used if the Short Data Subsystem which includes the Border Router is ordered.

For network security reasons, a firewall is enabled in the Border Router, so only the specified traffic will be allowed through. The Border Router WAN function uses a Motorola ST6000 series router. This router provides 3 LAN interfaces.

Quantity One ST6000 router

The photograph below shows the ST6000 Border router:

Figure 13: ST6000 router



Unit Specifications





AC input power 40 Watts


Width 430 mm



2.3.18 Redundant Border Router In a Geographically Redundant DIPC system the Redundant Border Router can be used to provide a resilient solution. It uses the same hardware configuration as the Border Router described in section 2.3.17.

CEN connection to both the Border Router and the Redundant Border Router is supported. Connection of the CEN to a distant location will be the customer’s responsibility.

Quantity One ST6000 router

2.3.19 Authentication Centre DIPC uses a single Authentication Centre (AuC) and crypto card.

The AuC client application is accessed on the AuC server through remote desktop from the Network Management Terminal.

The crypto card is subject to export control as described in 2.8

A USB to serial port converter is required to provide a serial port on the AuC for local connection of the KVL.

Quantity One Sun NX4250 server and a T6809 Crypto card, with a USB to serial converter.

2.3.20 Provisioning Centre (PrC) The Encrypted PrC is subject to export control as described in 2.8. The Clear PrC is exempt from the export control process.

Quantity One HP Z200 desktop computer, keyboard and mouse

One Crypto Card

One LCD monitor

2.3.21 Air Interface Encryption Key Variable Loader The Air Interface Encryption KVL is subject to export control as described in 2.8



Quantity Minimum one Air Interface Encryption KVL, preferably two (one for infrastructure one for subscribers).

2.3.22 Key Management Facility (KMF) DIPC uses a KMF server and KMF CryptR module. Dedicated KMF Clients are not used in DIPC; however the KMF client application is installed on the Network Management Terminal.

The KMF CryptR module is available with one or two algorithms (AES-128 and AES-256). The appropriate versions should be chosen for the end customer and must match the versions used with the other CryptR modules in the system. The KMF CryptR module comes with an external power supply. The KMF CryptR module is subject to export control as described in 2.8


One CryptR Module

2.3.23 End-to-End Encryption KVL The KVL is ordered with one of two encryption algorithms. AES-128 is used for voice or short data, AES-256 is used for voice, short data or packet data. A system with E2EE packet data and either E2EE voice or E2EE short data could require two E2EE KVLs, one with each algorithm.

The subscribers are ordered either with AES-128 or AES-256, but not both. It is important to ensure the KVL is ordered with the correct option for the matching algorithm.

The End-to-End Encryption KVL is subject to export control as described in 2.8

Quantity One or two End to End Encryption KVLs

2.3.24 Network Time Server The Network Time Server (NTS) provides a timing reference to the Dimetra IP Compact system. It acts as a Network Time Protocol (NTP) server providing a UTC time and date reference to all IP connected system elements (NTP clients) that support the Network Time Protocol (NTP).

Quantity One S300 Network Time Server

2.3.25 Backup/Restore Collector The Backup/Restore Collector is an application used to make backups of certain devices in the MSO. These devices are the Zone Controller (ZC), the Packet Data Router (PDR), the Short Data Router (SDR), the Zone Database Server (ZDS), the User Configuration Server (UCS) and the Unified Event Manager server (UEM). It is run on a local Network Management Terminal (NMT) in the MSO so that it can be used to restore cold standby devices to operation after the failure of an active device. It is strongly recommended that the Backup/Restore Collector application is installed on an NMT at Location B in a Geographically Redundant configuration. It is recommended that it is also installed on an NMT in Location A.



2.4 Control Site Components Control Sites are the locations where the fixed users of the system (dispatchers and network managers) access the Dispatch Consoles and/or the Network Management Terminals (NMTs). A Control Site may have just Dispatch Consoles or NMTs or it may have both depending on the requirements. The control site components can, if required, be located at an MSO, but are usually located at a remote Control Site. In this section both local and remote Control Sites are covered.

2.4.1 Network Management Terminal Network Management Terminals (NMT) are fitted with a DVD +/- RW drive, which allows the system backups stored on the NMT to be copied and stored off site.

A single NMT is always required at the master site for service. Additional NMTs may be installed at remote control sites within the limits given in the Performance and Capacity section of the planner.

Quantity One HP Z200 desktop computer, keyboard and mouse

One LCD monitor

2.4.2 Network Management Printer An optional HP Color LaserJet 3505N is used as the Network Management Printer.

Quantity One HP Colour LaserJet CP3525N

2.4.3 Dispatch Console Both clear and End to End Encrypted (E2EE) consoles can be used on DIPC systems.

2.4.3.1 Clear Consoles MCC 7500 Clear Dispatch Consoles may be installed at the master site or at remote control sites within the limits given in the Performance and Capacity section of the System Planner.

Quantity One HP Z200 desktop computer fitted with a voice card, keyboard and mouse

One LCD monitor

One General Purpose Input/Output Module (GPIOM) - that provides the audio interfaces (microphone, loudspeakers and analogue logging output) for the dispatcher.

Loudspeakers, headset jacks, headset, PTT amplifier module, desk microphones and footswitches as required.

2.4.3.2 PC and Monitor The Dispatch Console uses a standard PC client with a Logitech keyboard and Microsoft USB mouse. The PC is fitted with a Motorola voice card.

Quantity One HP Z200 computer fitted with a voice card, keyboard and mouse

One LCD monitor



2.4.3.3 GPIOM The GPIOM is used with MCC 7500 Dispatch Console positions and serves as a connection interface between the operator position computer and the microphone, speakers, headset jack box, and footswitch, as well as other external hardware.

The GPIOM receives data and control signalling from a dispatch console voice card through an IEEE–1394a bus interface (maximum length 4.5 m). Digitized audio, local auxiliary input/output (I/O) status information (for footswitch, headset and microphone PTT and monitor functions), and low-level control information flows on the IEEE-1394 bus.

A microphone connected to the GPIOM transmits audio to the dispatch console voice card where the audio is encoded (analogue-to-digital conversion) and then placed onto the IP network. The dispatch console operator hears radio traffic audio received at the voice card where it is decoded (digital-to-analogue conversion) and sent to the speakers attached to the GPIOM.

The photographs below show the connections and front view of the GPIOM:

Figure 14: GPIOM front view

Figure 15: GPIOM connections

Unit Specifications

Desktop Speaker RJ45, 600 Ohm

Headset Jack PJ7 (6-wire) headset PJ327 (4-wire) headset DB15, 600 Ohm

Desktop Microphone RJ45, 2000 Ohm

Footswitch RJ45

Logging Ports RJ45, 600 Ohm

Depth 270 mm

Width 406 mm

Height 44.5 mm (1 Rack Unit)

Weight 3.5 kg

AC Input Voltage 110/220 VAC

Power 21 W (max)/11 W (typical) (estimate)




Unit Specifications

Equipment Mounting Rack EIA 19” , 1U

Operating Temperature 5° to 35°C

Storing Temperature -10° to 60°C

Relative Humidity 0 to 90% (non-condensing) at 35°C

2.4.3.4 Accessories The certified accessories for the MCC 7500 console are listed below. Except where stated otherwise it is not certified to use accessories from the E2EE MCC 7500S console with the clear MCC 7500 console.

2.4.3.4.1 Loudspeaker The speaker is a self-contained unit that can be placed on a desktop, mounted in a rack/furniture, mounted on a wall, or mounted on a computer monitor. It contains an amplifier that provides a maximum of 2 Watts of power. The GPIOM provides power for the speakers via its interconnecting cable. A mounting bracket is included with the speaker.

The speaker is designed for use near computer monitors. The speaker provides the user with a continuous volume control. This serves as a master volume control for all the audio that appears in the speaker. When the user adjusts this volume control, all the audio in the speaker is increased or decreased by the same amount.

The speaker can be configured to provide either full muting or a fixed level (determined by the hardware and not user adjustable) when its volume control is set to its minimum level. The cable supplied with the speaker contains one end with two of the pins shorted together. When plugged into the speaker, this end causes the minimum volume to be set to full mute. If the other end of the cable is plugged into the speaker, the minimum volume is set to the minimum level.

The photograph below shows the MCC 7500 loudspeaker:

Figure 16: MCC 7500 loudspeaker

Unit Specifications

Depth 89 mm without brackets 146 mm with brackets

Width 102 mm



Unit Specifications Height 124 mm Weight 0.3 kg

2.4.3.4.2 Headset Jack The headset jack contains two volume controls: one for adjusting the level of received radio audio and one for adjusting the level of received telephone audio. A small dimple is moulded into the headset jack housing near the telephone volume control so a dispatch console user can tell them apart without having to look at them. The headset jack allows users to use headsets, which both decreases the ambient noise in a control room and reduces the effect of any ambient noise on dispatch console transmissions. This improves the quality of the audio being transmitted from the control room and allows the dispatch console users to hear received audio more clearly.

When a headset is plugged into a headset jack, the selected receive audio is typically removed from the speaker and routed to the headset earpiece. If two headsets are connected to a dispatch console, the same audio is heard in the earpieces of both headsets.

The photograph below shows the MCC 7500 Headset jack:

Figure 17: MCC 7500 headset jack

Unit Specifications

Depth 152 mm

Width 127 mm

Height 41 mm

Weight 0.5 kg

2.4.3.4.3 Headset The headset for DIPC is the Plantronics SupraPlus HW251N which is a wideband, lightweight, monaural style with noise cancelling microphone.

The headset plugs into a PTT amplifier module which also adapts the connector from the headset to the dual plug arrangement used on the headset jack. The PTT amplifier module is sometimes called a headset base and the headset is sometimes called a headset top.


The photograph below shows the MCC 7500 Headset:

Figure 18: MCC 7500 headset

2.4.3.4.4 PTT Amplifier Module The PTT Amplifier Module for Dimetra IP SR7.1 is the Plantronics SHS1890-15 which comes with a 4.5 m coiled cable.

The PTT amplifier module provides amplification of the microphone audio from the headset and is also used to adapt the connector from the headset type to the dual plug arrangement used on the headset jack. The PTT amplifier module is sometimes called a headset base and the headset is sometimes called a headset top.

The photograph below shows the PTT Amplifier Module:

Figure 19: PTT Amplifier Module

2.4.3.4.5 Desk Microphone The desk microphone can be permanently fastened down, or it can be left loose so the dispatch console user can pick it up while using it. The 450 mm long, flexible shaft allows the base to be placed behind a keyboard or writing area and still be able to position the microphone head within a few inches of the speaker’s mouth. If a desk microphone is connected to a dispatch console while no headsets are connected, the desk microphone is active whenever any transmit function is active. If a desk microphone is connected to a dispatch console while one or two headsets are



connected, the desk microphone is only active during a transmit function if its transmit button is pressed. This prevents the desk microphone from picking up unwanted background sound while the dispatch console user is using a headset to transmit.

The photograph below shows an MCC 7500 Desktop Microphone:

Figure 20: MCC 7500 desktop microphone

Unit Specifications Depth 168 mm

Width 121 mm

Height 114 mm

Weight 1.1 kg

2.4.3.4.6 MCC 7500 Foot Switch The footswitch allows users to operate console features with their feet so their hands are freed for other tasks. If desired, the footswitch can be permanently fastened to the floor.

The photograph below shows an MCC 7500 foot switch:

Figure 21: MCC 7500 foot switch



Unit Specifications

Connector to GPIOM RJ 45 plug

Depth 95 mm

Width 760 mm

Height 25 mm

Weight 1.2 kg

2.4.3.5 Beacon The optional beacon is connected via USB to a clear MCC 7500 console or an E2EE MCC 7500S console to indicate incoming emergency alarms visibly or unacknowledged alarms both visually and audibly.

The Beacon is IP65 rated. It doesn’t require an additional power supply; power is provided via the USB interface.

The beacon consists of red, yellow and green, LED light elements, a buzzer and a USB interface. The USB cable is not included and should be sourced locally to fit the specific operator position requirements. The maximum cable length is 5 m.

The photograph below shows an MCC 7500 beacon:

Figure 22: Beacon

Unit Specifications

Diameter 70 mm

Height 650 mm

Weight TBA kg

2.4.3.6 End to End Encrypted Consoles MCC 7500S E2EE Dispatch Consoles may be installed at the master site or at remote control sites within the limits given in the Performance and Capacity section of the System Planner.

Quantity One HP Z200 desktop computer (Call Control Entity) with a keyboard and mouse

One LCD monitor

One HP Z200 desktop computer (Audio Processing Entity) and mouse

One E2EE Console CryptR module




Accessories, such as headset USB soundcard, headset, two speakers, desk microphone, local logging recorder soundcard, USB footswitch adapter3 and footswitch. as required.

2.4.3.7 Call Control Entity and Monitor The Call Control Entity provides the call control for the E2EE console. This includes providing the GUI interface.

The CCE uses a standard PC client with a keyboard and mouse.

Quantity One HP Z200 computer with a keyboard and mouse

One LCD monitor

2.4.3.8 E2EE Console CryptR Module The E2EE Console CryptR module is a standalone device used to encrypt and decrypt audio. A metal bracket is provided with the E2EE Console CryptR module to allow secure mounting of the device, making removal difficult. Although the E2EE Console CryptR module is visually similar to the Packet Data Encryption Gateway (PDEG), Mobile Data Encryption Gateway (MDEG), Short Data Encryption Gateway (SDEG) and the KMF CryptR module used with the KMF server, it is a different device with a different model for ordering.

E2EE Console CryptRs use either the AES-128 or the AES-256 algorithm and require a KVL with the matching algorithm to load the keys. The MSs will also require the matching algorithm

The E2EE Console CryptR module comes with an external power supply. The E2EE Console CryptR module is subject to export control as described in 2.8.

Quantity One Motorola E2EE Console CryptR module

The photograph below show the Motorola E2EE Console CryptR module:

Figure 23: Motorola E2EE Console CryptR module

Unit Specifications Depth 90 mm Width 140 mm Height 29.5 mm Weight (including cables) 300 g CCE Port 10/100 Base-T Ethernet, RJ45 APE Port 10/100 Base-T Ethernet, RJ45 (uses cross over cable)

3 Also required for the desk microphone


2.4.3.9 Audio Processing Entity The Audio Processing Entity (APE) is used with the CCE and serves as a connection interface between the CCE computer and the microphone, speakers, headset USB soundcard, and footswitch, as well as other external hardware. The APE performs ACELP vocoding functions, audio summation for received audio, AGC, speaker output, microphone input and speech importance evaluation, in addition to other audio related tasks.

A Digigram VX222HR-MIC PCI desktop audio soundcard is installed in the APE for connection of the speakers and desk microphone. An optional Digigram UAX220 V2 card is used to provide connections for a Local Logging Recorder (LLR) or Instant Recall Recorder (IRR).

The APE uses a standard PC client with a keyboard and mouse. In normal use the APE does not need its own monitor and can share with the CCE if required during maintenance or installation.

Quantity One HP Z200 computer fitted with a voice card, keyboard and mouse.

One desktop audio soundcard.

The photograph below show theVX222HR-MIC soundcard:

Figure 24: VX222HR-MIC Soundcard

2.4.3.10 Accessories The certified accessories for the MCC 7500S console are listed below. Except where stated otherwise it is not certified to use accessories from the clear MCC 7500 console with the E2EE MCC 7500S console.

2.4.3.10.1 Headset USB Soundcard The MCC 7500S headset USB soundcard is used to connect the headset to the APE and includes the volume control. The MCC 7500S headset USB soundcard is the GN Netcom GN8120 USB desktop. The headset USB soundcard comes with a 1.8 m headset cable and a 1.22 m USB cable.



The photograph below show the MCC 7500S headset USB soundcard:

Figure 25: MCC 7500S Headset USB Soundcard

Unit Specifications Case Depth 22 mm Case Width 25 mm Case Height 107 mm Weight (including cables) 70 g

2.4.3.10.2 Local Logging USB Soundcard An optional external Digigram UAX220 V2 USB local logging USB soundcard is used to provide connection of a Local Logging Recorder (LLR) and Instant Recall Recorder (IRR). The LLR and IRR are to be provided by others.

The photograph below show the MCC 7500S local logging USB soundcard:

Figure 26: MCC 7500S Local Logging USB Soundcard

Unit Specifications Case Depth 144 mm Case Width 87 mm Case Height 34 mm USB cable 1.5 m Audio cables 0.75 m Logging Recorder outputs (x2) XLR3 male Audio inputs – unused (x2) XLR3 female Headphone output (used with Discreet Listening PC) 6.25 mm jack

2.4.3.10.3 Loudspeaker The loudspeaker for the E2EE MCC 7500S console is the Genelec 8020A. It contains bass and treble amplifiers which provide a maximum of 20 Watts of power each. The loudspeaker comes with a mains power cable.



The photograph below show the MCC 7500S loudspeaker:

Figure 27: MCC 7500S loudspeaker

Unit Specifications AC input voltage 100, 120, 220 or 230 VAC ± 10%


AC input power 50 VA max (manufacturer’s figure)

Depth 142 mm Width 151 mm Height 242 mm (including stand) Weight 3.7 kg

2.4.3.10.4 Headset The headset for the E2EE MCC 7500S console is the GN Netcom type GN2100 3 in 1, which is a lightweight monaural style with flexible boom and three different wearing styles (earhook, earloop or headband). Note the E2EE MCC 7500S supports a single headset.

The photograph below show the MCC 7500S headset:

Figure 28: MCC 7500S headset

2.4.3.10.5 Desk Microphone The MCC 7500S desktop microphone consists of a stand with PTT, a 38 cm gooseneck and cables. The desktop microphone can be ordered with either a standard microphone or a noise cancelling microphone.



The desktop microphone is an AKG GN30E gooseneck with either a CK31 or CK33 microphone. The PTT connects to the USB footswitch adapter described below.

The photograph below shows an MCC 7500S Desktop Microphone:

Figure 29: MCC 7500S desktop microphone

Unit Specifications Stand Depth 160 mm

Stand Width 150 mm

Stand Height 58 mm

Stand Weight 2.5 kg

2.4.3.10.6 Footswitch The MCC 7500S uses the same style of footswitch used with the clear MCC 7500, fitted with a 3.5 mm mono plug to connect to the MCC 7500S USB Footswitch Adapter.

2.4.3.10.7 USB Footswitch Adapter In order to connect the footswitch PTT and the desk microphone PTT to the APE, a USB footswitch adapter is required which converts from the PTT contacts to a USB input. The footswitch adapter is the Kinesis FS12J-USB.

The photograph below shows an MCC 7500S USB Footswitch Adapter:

Figure 30: USB Footswitch Adapter

Unit Specifications Case Depth 51 mm Case Width 140 mm Case Height 22 mm USB cable 2.9 m




Unit Specifications PTT Inputs (x2) 3.5 mm mono jack

2.4.3.11 Beacon The E2EE MCC 7500S console uses the same beacon as the clear MCC 7500 console.

2.4.4 Logging Recorder Components Voice logging is an optional feature in Dimetra.

The only certified solutions for voice logging on DIPC R4.1 are NICE Scenario Replay and NICE INFORM.

2.4.4.1 NICE Scenario Replay Logging Solution Scenario Replay can only be used for clear logging. Scenario Replay uses Logging Recorders, Archiving Interface Servers, Logging Replay Stations and Logging Admin PCs.

Note the AIS and Logging Recorder can only be deployed at a collocated control site; they cannot be deployed at a remote control site. The Logging Replay Stations can be located either at a collocated control site or at a remote control site.

2.4.4.1.1 Archiving Interface Server The Archiving Interface Server (AIS) collects audio and related information for call logging and audio archiving. The AIS passes the call events and audio to the Logging Recorder. The calls and events may then later be retrieved and played out on a Replay Station. An AIS must always be deployed with every Logging Recorder.

The AIS uses either a standard PC client or a rack mount PC. The PC includes a Logitech keyboard and Microsoft USB mouse. One AIS can be installed in the generic rack where it will use the keyboard/video/monitor switch in the rack.

Quantity One HP Z200 computer, keyboard and mouse and one LCD monitor (optional)

or

One SC811T-300 rack mount PC

2.4.4.1.2 Logging Recorder The Logging Recorder receives data from the AIS and stores the data for later retrieval. A Logging Recorder must always be deployed with an AIS.

The Logging Recorder uses the Sun Fire X4170 Server fitted with four hot-swappable 300 Gbyte Hard Disk Drives (HDD). It runs under the Windows 2003 server operating system.

Quantity One Sun Fire X4170 server with three DAT drives in two separate rack mount units.

2.4.4.1.3 Logging Replay PC The Logging Replay Station is used to access the recorded data. It can also run the admin application to define what items are recorded. It uses a standard PC client with a keyboard and mouse. A pair of Logitech V10 speakers is used with the Logging Replay Station.


Quantity One HP Z200 computer, keyboard and mouse

One LCD monitor

One pair of speakers

2.4.4.1.4 Logging Admin PC The Logging Admin PC runs the NICE Scenario Replay administration application. This can either be run on a Replay Station as above, or on a dedicated Logging Admin PC. A dedicated Logging Admin PC uses a standard PC client with a keyboard and mouse.


One LCD monitor


2.4.4.2 NICE INFORM Logging Solution INFORM can be used for both clear logging and E2EE logging. INFORM uses the Archiving Interface Server and the Logging Recorder, together with the INFORM Server, Storage Centre and Logging Replay Stations. For E2EE call logging, a console CryptR module and APE will also be required with each Logging Replay Station.

Note the components of the NICE INFORM logging solution can only be deployed at a collocated control site; they cannot be deployed at a remote control site. The INFORM Server, Storage Centre, Clear Logging Replay Stations, E2EE Logging Replay Stations, CryptR Modules and Audio Processing Entities must be located in the CEN after the Border Router.

2.4.4.2.1 Archiving Interface Server The Archiving Interface Server (AIS) collects audio and related information for call logging and audio archiving. The AIS passes the call events and audio to the Logging Recorder. The calls and events may then later be retrieved and played out on a Replay Station. An AIS must always be deployed with every Logging Recorder.

The AIS uses either a standard PC client or a rack mount PC. The PC includes a Logitech keyboard and Microsoft USB mouse. One AIS can be installed in the generic racks where it will use the keyboard/video/monitor switch in the rack.

Quantity One HP Z200 computer, keyboard and mouse and one LCD monitor (optional)

or

One SC811T-300 rack mount PC

2.4.4.2.2 Logging Recorder The Logging Recorder receives data from the AIS and stores the data for later retrieval. A Logging Recorder must always be deployed with an AIS.

The Logging Recorder uses the Sun Fire X4170 Server fitted with four hot-swappable 300 Gbyte Hard Disk Drives (HDD). It runs under the Windows 2003 server operating system.



Quantity One Sun Fire X4170 server with three DAT drives in two separate rack mount units.

2.4.4.2.3 INFORM Server The INFORM Server hosts the applications used to manage and configure the recording system and allocate user replay accounts and privileges.

The INFORM Server uses the Sun Fire X4170 Server. It runs under the Windows 2003 server operating system.

Quantity One Sun Fire X4170 server.

2.4.4.2.4 Storage Centre The Storage Centre provides long term storage of recorded channel hours.

The Storage Centre uses the Sun Fire X4170 Server. It runs under the Windows 2003 server operating system.

Quantity One Sun Fire X4170 server

2.4.4.2.5 Clear Logging Replay Station The Clear Logging Replay Station is used to access clear recorded data. It uses a standard PC client with a keyboard and mouse. A pair of Logitech V10 speakers is used with the Logging Replay Station


One LCD monitor


2.4.4.2.6 E2EE Logging Replay Station The E2EE Logging Replay Station is used to access clear or E2EE recorded data. It uses a standard PC client with a keyboard and mouse.

In addition an E2EE Console CryptR Module and an APE are required with the E2EE Logging Replay Station.


One LCD monitor

2.4.4.2.7 E2EE Console CryptR Module The E2EE Console CryptR module is the same device used in the MCC 7500S E2EE dispatch console. An E2EE Console CryptR module loaded with the correct algorithm is required with each E2EE Logging Replay Station.

Quantity One Motorola E2EE Console CryptR module



2.4.4.2.8 Audio Processing Entity -APE The APE is the same device used in the MCC 7500S E2EE dispatch console including a Digigram VX222HR-MIC PCI desktop audio soundcard installed in the APE for connection of the speakers. An APE is required with each E2EE Logging Replay Station. The APE serves as a connection interface between the E2EE Logging Replay Station and the speakers.

The APE uses a standard PC client with a keyboard and mouse and a pair of Genelec speakers. An optional Digigram UAX220 V2 card is used to provide connections for a Local Logging Recorder (LLR) or Instant Recall Recorder (IRR).

Quantity One HP Z200 computer fitted with a voice card, keyboard and mouse

One LCD monitor

One desktop audio soundcard


2.4.4.3 Third Party Logging Solutions Solutions from other third party suppliers can be provided using the MCC 7500 Application Programming Interface (API). All items apart from the AIS must be located in the CEN after the Border Router.

2.4.5 Control Site Router The router used in DIPC systems at a small remote control site is an ST2500. The Control Site Router can optionally be fitted with a four port analogue module to act as a Conventional Channel Gateway or with a second 4-port E1 WAN module to support redundant E1 site links. If the Control Site Router is connected to redundant E1site links or if it has a 10Base-T module supporting redundant Ethernet site links via the Control Site Ethernet Switch, then it cannot support the analogue module as well.

Quantity One ST2500 router with one 4-port E1 WAN module or one 10Base-T Ethernet module. Optionally it may be fitted with one four port analogue module or a second WAN module

2.4.5.1 Control Site Ethernet Switch A Control Site Ethernet switch provides switching between multiple MCC 7500 consoles and NMTs within one control room. If more than one NMT, MCC 7500 Console or printer is required at the control site, then one HP Procurve Switch 2610-48 is required. The Control Site Ethernet Switch also provides the connection to single or dual Ethernet site links at sites with an Ethernet Control Site Router.

Quantity One HP Procurve Ethernet Switch 2610-48

2.5 DIPC Cabinets Regular DIPC systems are available either in enhanced (24 RU) cabinets or in extended (38 RU) cabinets. Geographically Redundant DIPC systems are available only in enhanced (24 RU) cabinets. The enhanced cabinet solution provides space for the majority of subsystems. The extended cabinet provides space for a second MTIG and Echo Canceller; a KVM switch; a rack mounted AIS and a second logging




recorder/AIS pair. The cabinet design has the same look and feel as the MTS cabinets.

The equipment in the DIPC cabinets uses a generic layout. The use of generic layouts reduce costs and cycle time for system staging and system documentation.

Figure 31: DIPC Cabinets (not to scale)

Cabinet Specifications Height (enhanced 24 RU): 1325 mm Width (enhanced 24 RU): 596 mm Depth (enhanced 24 RU): 973 mm Weight if fully equipped (enhanced 24 RU): 290 kg Maximum Power Requirements with minimum configuration (enhanced 24 RU):

400 W

Maximum Power Requirements if fully equipped (enhanced 24 RU):

2500 W

Height (extended 38 RU): 1847 mm Width (extended 38 RU):4 609 mm Depth (extended 38 RU): 1063 mm Weight if fully equipped (extended 38 RU): 538 kg Maximum Power Requirements if fully equipped (extended 38 RU):

4900 W

Environmental protection IP20

4 Extended cabinets can be installed at 600 mm width spacing by removing the side panels between cabinets and suiting them together.



2.6 Base Stations The majority of the Base Station components are contained within an equipment cabinet known as the Base Transceiver System (BTS). The only additional equipment typically required is the antenna system and a power supply and /or battery backup. The system supports three types of BTS:

• MTS 1 - a single BR base station which will be introduced towards the end of 2010/early 2011.

• MTS 2 – a small, very power efficient Base Station working without fans in a 10 W configuration or with fans in a 25 W configuration. The MTS 2 provides up to 8 channels in a single 61 cm high cabinet. It is available in the 380-430, 450-470 and 800 MHz frequency bands.

• MTS 4 - a high capacity Base Station replacing the EBTS. It is a full replacement for EBTS supporting all features and functions of EBTS PR 3.0 while much smaller and lighter. The MTS 4 provides up to 16 channels in a single 143 cm high cabinet or up to 32 channels in two cabinets. It is available in the 350-370, 380-430, 450-470 and 800 MHz frequency bands.

2.6.1 MTS2 The MTS2 Site consists of four major functional components:

• Base Radio (BR) • Site Controller (SC) • RF Distribution System (RFDS) • Power Supply The MTS 2 is supplied with the following items as an installation kit:

• DC plug • AC plug • Battery temperature sensor5 • Floor mounting plate

5 Sensor resistance/temperature curve to IEC 751 Pt1000 (1 kΩ at 0 °C).


The photograph below shows the MTS2:

Figure 32: MTS2

2.6.1.1 Base Radio (BR) The Base Radio (BR) provides a high powered RF interface.

If the station is ordered with a single BR or with two BRs and a dual duplexer it can provide up to 40W to the antenna system.

If ordered with a single duplexer, up to 25 Watts of RF power can be provided to the antenna system.

Finally a low power BR option is available delivering 10W to the antenna system after RFDS losses.

Each BR utilizes TDMA technology to provide 4 channels on a 25 kHz carrier. Configurations are available to meet capacity requirements ranging from 4 to 8 channels. A single MTS2 cabinet may hold up to two BRs. For greater than two BRs, an MTS4 is required.

The BR also incorporates diversity reception for increased talk-back range, performance and reliability. A combined three-receiver board is provided with each BR to allow for 2 or 3 branch antenna diversity.

2.6.1.2 Site Controller (SC) The Site Controller (SC) is a PowerPC based computer. It communicates with the MSO components over the X.21 or fractional E1 interface and controls the operation of the Base Radios. The SC also contains a time and frequency reference module. The module includes a high stability oscillator to provide the frequency reference and GPS receiver to provide the timing reference.

The SC is capable of providing all call processing functions necessary to enable the MTS2 to operate as a standalone single site TETRA system should the site become disconnected from the MSO.

2.6.1.3 Radio Frequency Distribution System (RFDS) The Radio Frequency Distribution System (RFDS) uses hybrid combiners to combine the outputs of the Base Radios into a single or dual transmit antenna connection using one or two duplexers. The RFDS also uses a receiver multicoupler to distribute the signal from each of the receive antenna connections to each of the Base Radios.




2.6.1.4 Power Supply Unit (PSU) The Power Supply Unit provides power to all of the units within the MTS 2. The PSU accepts 110/220 V AC or -48V DC inputs. In addition the PSU provides the facility to charge an external battery supply and to automatically switch to this battery source in the event of input power failure.

2.6.1.5 Alarms The MTS 2 provides connections for 15 external alarm inputs as well as 2 alarm/control outputs.

2.6.1.6 Cabinet Specifications

Parameter Specification

Antenna connectors6 DIN 7-16 female

X.21 Site Link 15 pin D male connector

E1 Site Link (x2) RJ457

GPS internal receiver N female GPS remote receiver 15 pin D female connector External alarm input (x12) 25 pin D female connector

12 V typical (open) 8 mA typical (short circuit)

Control output (x2) 25 pin D female connector8 alarm relay (normally open and common contacts)

Height: 610 mm Width: 450 mm Depth: 480 mm

Weight 45 kg (approx) Power Requirements: -48 V DC, 88 - 270 V AC Power Consumption (2BR) 310 W low power, 640 W high power (measured) Battery Charger output Voltage 40.5 – 57 V DC Battery Charger output Current 0-3 A (low power), 0-6 A (high power)

Operating Temperature: -30° to +55°C (without fans), -30° to +60°C (with fans) Storage Temperature: -40° to +85°C Operating Humidity: 5% to 95% relative humidity (non-condensing) Environmental protection IP20

2.6.2 MTS4 The MTS 4 Site consists of four major functional components:

• Base Radio (BR) • Site Controller (SC) • RF Distribution System (RFDS)

6 Quantity of antenna connectors depends on the duplexer and diversity configuration. 7 Single connector for both E1 lines. If separate RJ45 connections are required for each E1 line a y-adapter is required. 8 Shared with alarm inputs.



• Power Supply The MTS 4 is supplied with the following items as an installation kit:

• DC plug • AC plug (x2) • Battery temperature sensor (x2)9 • Floor mounting plate The photograph below shows the MTS4:

Figure 33: MTS 4

2.6.2.1 Base Radio (BR) The Base Radio (BR) provides a high powered RF interface.

It can provide up to 25 Watts of RF power to the antenna system after RFDS losses.

A low power BR option is also available delivering 10W to the antenna system after RFDS losses.

Each BR utilizes TDMA technology to provide 4 channels on a 25 kHz carrier. Configurations are available to meet capacity requirements ranging from 4 to 32 channels. A single MTS 4 cabinet may hold up to four BRs. For greater than four BRs, an expansion cabinet is required.

The BR also incorporates diversity reception for increased talk-back range, performance and reliability. A combined three-receiver board is provided with each BR to allow for 2 or 3 branch antenna diversity.

9 Sensor resistance/temperature curve to IEC 751 Pt1000 (1 kΩ at 0 °C).


2.6.2.2 Site Controller (SC) The Site Controller (SC) is a PowerPC based computer. It communicates with the MSO components over the X.21 or E1 interface and controls the operation of the Base Radios. The SC also contains a time and frequency reference module. The module includes a high stability oscillator to provide the frequency reference and GPS receiver to provide the timing reference.

The SC is capable of providing all call processing functions necessary to enable the MTS 4 to operate as a standalone single site TETRA system should the site become disconnected from the MSO.

2.6.2.3 Radio Frequency Distribution System (RFDS) The Radio Frequency Distribution System (RFDS) uses hybrid combiners, manual tune cavity combiners or auto tune cavity combiners to combine the outputs of the Base Radios into a one or two transmit antenna connection. The RFDS also uses a receiver multicoupler to distribute the signal from each of the three receive antenna connections to each of the Base Radios. The RFDS may also uses one or two duplexers to combine some of the receiver inputs with a transmit output.

2.6.2.4 Power Supply Unit (PSU) The Power Supply Unit provides power to all of the units within the MTS 4. The PSU accepts 110/220 V AC or -48V DC inputs. In addition the PSU also provides the facility to charge an external battery supply and to revert to this power source in the event of input power failure.

2.6.2.5 Alarms The MTS 4 provides connections for 15 external alarm inputs as well as 2 alarm/control outputs.

2.6.2.6 Cabinet Specifications

Parameter Specification

Antenna connectors DIN 7-16 female

X.21 Site Link 15 pin D male connector

E1 Site Link (x2) RJ45

GPS internal receiver (x2) N female GPS remote receiver (x2) 15 pin D female connector External alarm input (x12) 25 pin D female connector

12 V typical (open) 8 mA typical (short circuit)

Control output (x2) 25 pin D female connector alarm relay (normally open and common contacts)

Height: 1430 mm Width: 550mm Depth: 570mm

Weight 148 kg (approx) per cabinet Power Requirements: -48 V DC, 88 - 270 V AC Power Consumption (4BR) 600 W low power, 1200 W high power (measured) Battery Charger output Voltage 40.5 – 57 V DC Battery Charger output Current 0-6 A




Parameter Specification Operating Temperature: -30° to +55°C (UHF without fans, 800 with or without

fans), -30° to +60°C (UHF with fans) Storage Temperature: -40° to +85°C Operating Humidity: 5% to 75% relative humidity (non-condensing) Environmental protection IP20

2.6.3 MTS 4 Outdoor Cabinet An outdoor cabinet design is available to take a single MTS 4 base station with up to 4 BRs. The outdoor cabinet has space for the MTS 4 on the right hand side with a heat exchanger mounted on the front door. The left hand side of the cabinet is for battery backup. There are options for either four or eight hour battery backup. If longer backup time is required there are also options for two or five bottle fuel cells which are mounted in an additional cabinet to the side of the MTS Outdoor Cabinet.

The picture below shows the MTS4 Outdoor Cabinet:

Figure 34: MTS 4 Outdoor Cabinet

2.7 Mobile Stations The Mobile Stations (MSs) provide the radio users with access to the radio communication services provided by the system. MSs communicate with the BTSs using the TETRA air interface protocol. In addition to providing access to the system


radio communication services, MSs provide various features that let users use these services efficiently.

The following radio models are certified to work with DIPC R4.1 systems:

Model Type Remarks MTP850 Portable Lightweight rugged portable radio with full keypad, colour graphic display,

built-in GPS receiver, multi-language support, optional UCM module for End-to-End encryption and complies with ETS 300 019- 1- 7 class 7.3E, 5M3 standard and IP55 for protection against dust and water ingress.

MTP850 Ex

Portable Rugged portable radio for hazardous environments. Includes large keypad format, man down alarm, GPS receiver, colour display and multi-language support. Complies with both the ATEX and IEC Ex standards for hazardous environments where there could be risk of explosive gas or dust.

MTH800 Portable Lightweight rugged portable radio with full keypad, colour graphic display, built-in GPS receiver, supports the UCM module for End-to-End encryption and complies with ETS 300 019- 1- 7 class 7.3E, 5M3 standard and IP54 for protection against dust and water ingress.

TCR1000 Covert Portable

Discreet radio and control unit designed to be worn by under cover officers. Includes built-in GPS receiver, optional UCM module for End-to-End encryption and wide range of covert accessories.

CEP400 Portable Lightweight rugged portable radio with virtual keypad, optional colour display and optional GPS receiver. Complies with ETS 300 019-1-7 class 7.3E for humidity, ETS 300 019-1-7 class 5M3 for shock, drop and vibration and IP54 for protection against dust and water ingress.

MTP750 Portable Ruggedised portable radio with full keypad and graphic display, Asian language support, complies with IP54 standard for protection against dust and water ingress.

MTM5400 Mobile TEDS capable, Gateway Repeater capable, E2EE capable, 10 Watt, rugged mobile radio with GPS receiver. Complies with IP54 standard for protection against dust and water ingress. (The motorcycle control head complies with the IP57 standard). Available as: dashboard mount, remote mount, desktop mount, motorcycle and data box models. Includes integrated GPS receiver, colour display and optional UCM module enabling End-to-End encryption.

MTM800 Enhanced

Mobile Enhanced Control Head version of the MTM800. It is fully compliant with the DIN-A standard for installation on a car dashboard. Multi-language support.

Each model is equipped with a Peripheral Equipment Interface (PEI) that provides external devices with access to the optional Short Data Transport and Packet Data Services. It also provides the interface for accessories.

Note: Further information on Dimetra Mobile Stations including ordering information can be found at Motorola OnLine.



2.7.1 Portables 2.7.1.1 MTP850

The MTP850 is a lightweight rugged portable MS with integrated GPS receiver and colour display. MTP850 is a wide band mobile covering 380-430 or 806-870 MHz range. Languages supported include English, German, Dutch, Spanish, Greek, Arabic, Russian, Swedish, French, Korean and Chinese (Simplified and Traditional). Available with Roman, Arabic or Cyrillic keypad.

The MTP850 is capable of 1 Watt RF output power.

2.7.1.2 MTP850Ex

The MTP850Ex is a rugged portable approved to both the ATEX and IEC Ex standards for hazardous environments where there could be risk of explosive gas or dust. Includes large keypad format for use with protective gloves, integrated man down alarm, integrated GPS receiver and colour display. MTP850Ex is a wide band mobile covering the 380-430 MHz range. Languages supported include Arabic, Chinese Simplified, Chinese Traditional, Dutch, English, French, German, Greek, Hungarian, Italian, Korean, Lithuanian, Norwegian, Portuguese Russian, Spanish and Swedish. Available with Roman, Arabic or Cyrillic keypad.

The MTP850Ex is capable of 1 Watt RF output power.

2.7.1.3 MTH800

The MTH800 is a lightweight rugged portable MS with integrated GPS receiver and colour display. MTH800 is also a wide band mobile covering 380-430 MHz range.

The MTH800 is capable of 1 Watt RF output power.



2.7.1.4 TCR1000

The TCR1000 is a discreet radio and control unit designed to be worn by under cover officers. It is small with a thin form factor to enable it to be easily hidden under clothing. Optional body worn double loop antenna increases range. Includes integrated GPS receiver, optional UCM for End-to-End encryption and whisper mode for discreet use. TCR1000 is a wide band, fully functional mobile covering the 380-430 MHz range.

The TCR1000 is capable of 1 Watt RF output power.

2.7.1.5 CEP400

The CEP400 is a lightweight, rugged portable MS with optional integrated GPS receiver and colour (or grey scale) display. It is designed with a cellular phone style and optimised user interface. The battery supports more than 23 hours operation on a 5/5/90 duty cycle. Languages supported include English, German, French, Spanish, Dutch, Swedish, Russian, Italian, Arabic, Chinese (Simplified & Traditional), Croatian, Danish, Greek, Hungarian, Lithuanian, Macedonian, Norwegian, Portuguese and Swedish.

The CEP400 is a wide band mobile covering 380-430 MHz range.

The CEP400 is capable of 1 Watt RF output power.

2.7.2 Mobiles 2.7.2.1 MTM5400

Figure 35: MTM5400

The MTM5400 is Motorola’s next generation mobile with the following features:

• TEDS capable • Gateway Repeater capable



• Reuses the control heads from the MTM800 Enhanced • Multiple control heads can be connected using Ethernet • Improved GPS performance • End-to-End Encryption capable • Multi-slot packet data capable • Bluetooth capable • WiFi capable • USB capable The control head includes a high resolution VGA display with wide viewing angle. It has a common user interface with the MTH800/MTP850 portables, simplifying user training.

The MTM5400 is designed to be mounted in a vehicle, although it can be supplied for fixed use with a tray and a power supply. For mounting in a vehicle it can be supplied as a dash mount (where the whole radio is mounted on the vehicle’s dashboard) or as a remote mount (where only the control head is mounted on the dashboard and the radio itself can be mounted remotely, usually in the boot). A motorcycle version is also available. To enable the user to access the radio communication services, the MTM5400 provides the user with a numeric keypad, various buttons, a visual display and an audio interface (microphone and loudspeaker). Languages supported include English, German, Dutch, Spanish, Greek, Arabic, Russian, Swedish, French, Korean and Chinese (Simplified and Traditional). Available with Roman, Arabic, Cyrillic, Taiwanese BoPoMoFo, Korean or Chinese stroke keypad.

MTM5400 is capable of 10 Watts of RF output power for voice calls and is available in the 380 to 430 MHz band.

2.7.2.2 MTM800 Enhanced

Figure 36: MTM800 Enhanced

The MTM800 Enhanced has all the features of the MTM800 including multi-slot packet data and End-to-End Encryption capability, with an enhanced DIN compatible control head. The control head includes a high resolution VGA display with wide viewing angle. It has a common user interface with the MTH800/MTP850 portables, simplifying user training.

The MTM800 Enhanced is designed to be mounted in a vehicle, although it can be supplied for fixed use with a tray and a power supply. For mounting in a vehicle it can be supplied as a dash mount (where the whole radio is mounted on the vehicle’s dashboard) or as a remote mount (where only the control head is mounted on the dashboard and the radio itself can be mounted remotely, usually in the boot). A motorcycle version is also available. To enable the user to access the radio




communication services, the MTM800 provides the user with a numeric keypad, various buttons, a visual display and an audio interface (microphone and loudspeaker). Languages supported include English, German, Dutch, Spanish, Greek, Arabic, Russian, Swedish, French, Korean and Chinese (Simplified and Traditional). Available with Roman, Arabic, Cyrillic, Taiwanese BoPoMoFo, Korean or Chinese stroke keypad.

MTM800 Enhanced is capable of 3 Watts of RF output power.

2.8 Export Control Requirements IMPORTANT NOTE FOR ALL ENCRYPTED ITEMS

All Motorola TETRA (Dimetra) encrypted infrastructure and encrypted subscriber, as well as encryption key distribution and encryption key management hardware and software products, including kits, spare parts and encryption upgrades are controlled for export and will generally require an approved export licence prior to shipment from the Motorola factory to any customer.

The export of TETRA encryption algorithms used for Air Interface encryption (TEA1, TEA2 and TEA3) and TETRA End-to-End (AES) encryption are export restricted by the United States Federal Government, the European Union and the German Federal Government, as well as by the governments of many other nations. Depending on the country of destination, there may be applicable national import restrictions.

Export Licence approvals are based on the country of final destination and the specific end user. Certain countries and certain end users will not be eligible for approval.

Any items that require an export licence are highlighted in this document. Contact your Local Export Control office if you are unfamiliar with the licensing process or to discuss any possible licensing restrictions before submitting bids, proposals, or accepting orders for encryption products.

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