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TETRA

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Terrestrial Trunked Radio
Company typeIncentive
IndustryEuropean Telecommunications Standards Institute
professional mobile radio
trunked radio system
Founded1995
Europe
HeadquartersEurope

Terrestrial Trunked Radio[1] (TETRA; formerly known as Trans-European Trunked Radio), a European standard for a trunked radio system, is a professional mobile radio[2] and two-way transceiver specification. TETRA was specifically designed for use by government agencies, emergency services, (police forces, fire departments, ambulance) for public safety networks, rail transport staff for train radios, transport services and the military.[3] TETRA is the European version of trunked radio, similar to Project 25.

TETRA is a European Telecommunications Standards Institute (ETSI) standard, first version published 1995; it is mentioned by the European Radiocommunications Committee (ERC).[4]

Description

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TETRA uses time-division multiple access (TDMA) with four user channels on one radio carrier and 25 kHz spacing between carriers. Both point-to-point and point-to-multipoint transfer can be used. Digital data transmission is also included in the standard though at a low data rate.

TETRA Mobile Stations (MS) can communicate direct-mode operation (DMO) or using trunked-mode operation (TMO) using switching and management infrastructure (SwMI) made of TETRA base stations (TBS). As well as allowing direct communications in situations where network coverage is not available, DMO also includes the possibility of using a sequence of one or more TETRA terminals as relays. This functionality is called DMO gateway (from DMO to TMO) or DMO repeater (from DMO to DMO). In emergency situations this feature allows direct communications underground or in areas of bad coverage.

In addition to voice and dispatch services, the TETRA system supports several types of data communication. Status messages and short data services (SDS) are provided over the system's main control channel, while packet-switched data or circuit-switched data communication uses specifically assigned channels.

TETRA provides for authentication of terminals towards infrastructure and vice versa. For protection against eavesdropping, air interface encryption and end-to-end encryption is available.

The common mode of operation is in a group calling mode in which a single button push will connect the user to the users in a selected call group and/or a dispatcher. It is also possible for the terminal to act as a one-to-one walkie talkie but without the normal range limitation since the call still uses the network. TETRA terminals can act as mobile phones (cell phones), with a full-duplex direct connection to other TETRA Users or the PSTN. Emergency buttons, provided on the terminals, enable the users to transmit emergency signals, to the dispatcher, overriding any other activity taking place at the same time.

Security vulnerabilities

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An in-depth review published in July 2023 by the company Midnight Blue of the TETRA standard and encryption algorithms, the first made public in the last 20 years, has found multiple security flaws, collectively referred to as TETRA:BURST. A total of 5 flaws were filed to the CVE database:[5]

  • The Air Interface Encryption (AIE) keystream generator is vulnerable to decryption oracle attacks due to the use of publicly-broadcast network time[5]—keystream reuse can be triggered.[6]
  • TEA1 contains a secret reduction step that effectively downgrades the cryptographic strength from 80 to 32 bits, allowing anyone to break the cipher and subsequently decrypt the signal in as little as one minute using a consumer laptop. "There's no other way in which this can function than that this is an intentional backdoor," "This constitutes a full break of the cipher, allowing for interception or manipulation of radio traffic", according to the news report posted on ComputerWeekly.[7] The deliberately weakened TEA1 flaw seems to be known in intelligence circles and is referred to in the famous 2006 Wikileaks dump of US diplomatic communications [citation needed].
  • AIE contains no authentication for the ciphertext, making malleability attacks possible.[5]
  • The cryptographic anonymization scheme is weak and can be partially reversed to track users.[5]
  • The authentication algorithm allows attackers to set the Derived Cypher Key (DCK) to 0,[5] circumventing session authentication.[6]

In addition, the Midnight Blue team spots a "peculiarity regarding the TEA3 S-box", but has yet to determine whether it constitutes a weakness.[6]

These vulnerabilities remained publicly unknown for 28 years after TETRA's publication because TETRA does not make definitions of its cryptographic algorithms public, an example of security through obscurity. The Midnight Blue team gained access to TETRA's cryptographic code by attacking the trusted execution environment on a TETRA-enabled radio. The team points to a list of previously broken cryptographic systems relying on obscurity and argues that the Kerckhoffs's principle should have been followed: the system would have been safer when its structure is publicly known.[6]

Advantages

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The main advantages of TETRA over other technologies (such as GSM) are:

  • The much lower frequency used gives longer range, which in turn permits very high levels of geographic coverage with a smaller number of transmitters, thus cutting infrastructure costs.
  • During a voice call, the communications are not interrupted when moving to another network site. This is a unique feature, which dPMR networks typically provide, that allows a number of fall-back modes such as the ability for a base station to process local calls. So called 'mission critical' networks can be built with TETRA where all aspects are fail-safe/multiple-redundant.
  • In the absence of a network, mobiles/portables can use 'direct mode' whereby they share channels directly (walkie-talkie mode).
  • Gateway mode - where a single mobile with connection to the network can act as a relay for other nearby mobiles that are out of range of the infrastructure. A dedicated transponder system isn't required in order to achieve this functionality, unlike with analogue radio systems.
  • TETRA also provides a point-to-point function that traditional analogue emergency services radio systems did not provide. This enables users to have a one-to-one trunked 'radio' link between sets without the need for the direct involvement of a control room operator/dispatcher.
  • Unlike cellular technologies, which connect one subscriber to one other subscriber (one-to-one), TETRA is built to do one-to-one, one-to-many and many-to-many. These operational modes are directly relevant to the public safety and professional users.
  • Security TETRA supports terminal registration, authentication, air-interface encryption and end-to-end encryption.[citation needed]
  • Rapid deployment (transportable) network solutions are available for disaster relief and temporary capacity provision.
  • Network solutions are available in both reliable circuit-switched (telephone like) architectures and flat, IP architectures with soft (software) switches.

Further information is available from the TETRA Association (formerly TETRA MoU) and the standards can be downloaded for free from ETSI.

Disadvantages

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Its main disadvantages are:

  • Serious security issues have been identified, including an intentional weakening of the TEA1 cipher, constituting a full break within a minute on consumer hardware. (See Description)
  • Requires a linear amplifier to meet the stringent RF specifications that allow it to exist alongside other radio services.
  • Data transfer is slow by modern standards.

Up to 7.2 kbit/s per timeslot, in the case of point-to-point connections, and 3.5 kbit/s per timeslot in case of IP encapsulation. Both options permit the use of between one and four timeslots. Different implementations include one of the previous connectivity capabilities, both, or none, and one timeslot or more. These rates are ostensibly faster than the competing technologies DMR, dPMR, and P25 are capable of. Latest version of standard supports 115.2 kbit/s in 25 kHz or up to 691.2 kbit/s in an expanded 150 kHz channel. To overcome the limitations many software vendors have begun to consider hybrid solutions where TETRA is used for critical signalling while large data synchronization and transfer of images and video is done over 3G / LTE.[8]

Technical details

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Radio aspects

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For its modulation TETRA, uses π4 differential quadrature phase-shift keying. The symbol (baud) rate is 18,000 symbols per second, and each symbol maps to 2 bits, thus resulting in 36,000 bit/s gross.

As a form of phase shift keying is used to transmit data during each burst, it would seem reasonable to expect the transmit power to be constant. However it is not. This is because the sidebands, which are essentially a repetition of the data in the main carrier's modulation, are filtered off with a sharp filter so that unnecessary spectrum is not used up. This results in an amplitude modulation and is why TETRA requires linear amplifiers. The resulting ratio of peak to mean (RMS) power is 3.65 dB. If non-linear (or not-linear enough) amplifiers are used, the sidebands re-appear and cause interference on adjacent channels. Commonly used techniques for achieving the necessary linearity include Cartesian loops, and adaptive predistortion.

The base stations normally transmit continuously and (simultaneously) receive continuously from various mobiles on different carrier frequencies; hence the TETRA system is a frequency-division duplex (FDD) system. TETRA also uses FDMA/TDMA (see above) like GSM. The mobiles normally only transmit on 1 slot/4 and receive on 1 slot/4 (instead of 1 slot/8 for GSM).

Speech signals in TETRA are sampled at 8 kHz and then compressed with a vocoder using algebraic code-excited linear prediction (ACELP). This creates a data stream of 4.567 kbit/s. This data stream is error-protection encoded before transmission to allow correct decoding even in noisy (erroneous) channels. The data rate after coding is 7.2 kbit/s. The capacity of a single traffic slot when used 17/18 frames.

A single slot consists of 255 usable symbols, the remaining time is used up with synchronisation sequences and turning on/off, etc. A single frame consists of 4 slots, and a multiframe (whose duration is 1.02 seconds) consists of 18 frames. Hyperframes also exist, but are mostly used for providing synchronisation to encryption algorithms.

The downlink (i.e., the output of the base station) is normally a continuous transmission consisting of either specific communications with mobile(s), synchronisation or other general broadcasts. All slots are usually filled with a burst even if idle (continuous mode). Although the system uses 18 frames per second only 17 of these are used for traffic channels, with the 18th frame reserved for signalling, Short Data Service messages (like SMS in GSM) or synchronisation. The frame structure in TETRA (17.65 frames per second), consists of 18,000 symbols/s; 255 symbols/slot; 4 slots/frame, and is the cause of the perceived "amplitude modulation" at 17 Hz and is especially apparent in mobiles/portables which only transmit on one slot/4. They use the remaining three slots to switch frequency to receive a burst from the base station two slots later and then return to their transmit frequency (TDMA).

Radio frequencies

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Chart to visualize the bands used for TETRA in Europe
TETRA frequencies in South America
Number Frequency pair (MHz)
Band 1 Band 2
Emergency systems
1 380–383 390–393
2 383–385 393–395
Civil systems
1 410–420 420–430
2 870–876 915–921
3 450–460 460–470
4 385–390 395–399.9
TETRA frequencies in other countries
Country Allocation Frequency pairs (MHz)
France Civilian/private 410–430
Emergency services 380–400
Belgium Emergency services/civilian 380–386.5, 390–396.5
Commercial 410-420
the Netherlands Emergency services 380–386.5, 390–396.5
Civil/Commercial 410-430
Germany Emergency services 380–385, 390–395, 406 - 410 for DMO
Ireland[9] Civilian/private 385–389.9, 395–399.9
Emergency services 380–385, 390–395
Italy Emergency services / armed forces 380–390
Civilian/private 462
Norway[10] Emergency services 380–385, 390–395, 406.1–426, 870–876
Slovenia Emergency services 380-385 (MS), 390-395 (BS)
South Africa Emergency services, Public works 420-423
Sweden Emergency services 380-395
Civilian/airport/public transportation 425-429
UK Airwave 390.0125–394.9875, 380.0125–384.9875
Airwave (London only) 420.0125-421.9875, 410.0125–412.9875
Prison service 450, 460 / 452, 462
AirRadio 454, 464 or 460
Offshore Oil platforms 423, 413
Hong Kong[11] Emergency services 382.65–399.9, 410–430
Civil/Private 806–818, 851–863
Portugal SIRESP - Public Safety 380–395
Commercial/Private 420-430
Saudi Arabia 350–370, 380–395, 385–399.99, 410–430, 450–470, 870–921

Air interface encryption

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To provide confidentiality the TETRA air interface is encrypted using one of the TETRA Encryption Algorithm (TEA) ciphers. The encryption provides confidentiality (protect against eavesdropping) as well as protection of signalling.

Currently 4 different ciphers are defined, TEA1 up to TEA4. These TEA ciphers should not be confused with the block cipher Tiny Encryption Algorithm. The TEA ciphers have different availability due to export and use restrictions. Few details are published concerning these proprietary ciphers. Riess[12] mentions in early TETRA design documents that encryption should be done with a stream cipher, due to the property of not propagating transmission errors. Parkinson[13] later confirms this and explains that TEA is a stream cipher with 80-bit keys. The algorithms were later reversed and it appeared that TEA1 reduces its key strength to 32 bits.[14] TEA1 and TEA4 provide basic level security, and are meant for commercial use.[15] The TEA2 cipher is restricted to European public safety organisations. The TEA3 cipher is for situations where TEA2 is suitable but not available.[16]

Cell selection

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Cell re-selection (or hand-over) in images

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RSSI SRT FRT cell limit (propagation delay exceed)

This first representation demonstrates where the slow reselect threshold (SRT), the fast reselect threshold (FRT), and propagation delay exceed parameters are most likely to be. These are represented in association with the decaying radio carrier as the distance increases from the TETRA base station.

From this illustration, these SRT and FRT triggering points are associated to the decaying radio signal strength of the respective cell carriers. The thresholds are situated so that the cell reselection procedures occur on time and assure communication continuity for on-going communication calls.

Initial cell selection

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Cell initial selection

The next diagram illustrates where a given TETRA radio cell initial selection. The initial cell selection is performed by procedures located in the MLE and in the MAC. When the cell selection is made, and possible registration is performed, the mobile station (MS) is said to be attached to the cell. The mobile is allowed to initially select any suitable cell that has a positive C1 value; i.e., the received signal level is greater than the minimum receive level for access parameter.

The initial cell selection procedure shall ensure that the MS selects a cell in which it can reliably decode downlink data (i.e., on a main control channel/MCCH), and which has a high probability of uplink communication. The minimum conditions that shall have to be met are that C1 > 0. Access to the network shall be conditional on the successful selection of a cell.

At mobile switch on, the mobile makes its initial cell selection of one of the base stations, which indicates the initial exchanges at activation.

  • Refer to EN 300 392 2 16.3.1 Activation and control of underlying MLE service
  • Note 18.5.12 Minimum RX access level

The minimum receive access level information element shall indicate the minimum received signal level required at the SwMI in a cell, either the serving cell or a neighbour cell as defined in table 18.24.

Cell improvable

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Cell improvable

The next diagram illustrates where a given TETRA radio cell becomes improvable. The serving cell becomes improvable when the following occurs: the C1 of the serving cell is below the value defined in the radio network parameter cell reselection parameters, slow reselect threshold for a period of 5 seconds, and the C1 or C2 of a neighbour cell exceeds the C1 of the serving cell by the value defined in the radio network parameter cell reselection parameters, slow reselect hysteresis for a period of 5 seconds.

Cell usable

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Cell usable

The next diagram illustrates where a given TETRA radio cell becomes usable. A neighbour cell becomes radio usable when the cell has a downlink radio connection of sufficient quality.

The following conditions must be met in order to declare a neighbour cell radio usable: The neighbour cell has a path loss parameter C1 or C2 that is, for a period of 5 seconds, greater than the fast reselect threshold plus the fast reselect threshold, and the service level provided by the neighbour cell is higher than that of the serving cell. No successful cell reselection shall have taken place within the previous 15 seconds unless MM requests a cell reselection. The MS-MLE shall check the criterion for serving cell relinquishment as often as one neighbour cell is scanned or monitored.

The following conditions will cause the MS to rate the neighbour cell to have higher service level than the current serving cell:

  • The MS subscriber class is supported on the neighbour cell but not on the serving cell.
  • The neighbour cell is a priority cell and the serving cell is not.
  • The neighbour cell supports a service (that is, TETRA standard speech, packet data, or encryption) that is not supported by the serving cell and the MS requires that service to be available.
  • The cell service level indicates that the neighbour cell is less loaded than the serving cell.

Cell relinquishable (abandonable)

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Cell relinquishable

The next diagram illustrates where a given TETRA radio cell becomes relinquishable (abandonable). The serving cell becomes relinquishable when the following occurs: the C1 of the serving cell is below the value defined in the radio network parameter cell reselection parameters, fast reselect threshold, for a period of 5 seconds, and the C1 or C2 of a neighbour cell exceeds the C1 of the serving cell by the value defined in the radio network parameter cell reselection parameters, fast reselect hysteresis, for a period of 5 seconds.

No successful cell reselection shall have taken place within the previous 15 seconds unless Mobility Management (MM) requests a cell reselection. The MS-MLE shall check the criterion for serving cell relinquishment as often as one neighbour cell is scanned or monitored.

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Radio down-link failure

When the FRT threshold is breached, the MS is in a situation where it is essential to relinquish (or abandon) the serving cell and obtain another of at least usable quality. That is to say, the mobile station is aware that the radio signal is decaying rapidly, and must cell reselect rapidly, before communications are terminated because of radio link failure. When the mobile station radio-signal breaches the minimum receive level, the radio is no longer in a position to maintain acceptable communications for the user, and the radio link is broken.

Radio link failure: (C1 < 0). Using the suggested values, this would be satisfied with the serving cell level below −105 dBm. Cell reselection procedures are then activated in order to find a suitable radio base station.

Infrastructure TETRA parameters guide[a]
Coverage Parameter Distance (km) Type of communication
City < 4 < 8 Pedestrian/metro
Sub-urban 10–18 20–36 Bus/train
Countryside 18–31 36–62 Inter-regional train
In Air > 32 > 64 In flight
  1. ^ Data to be verified

Man-machine interface (MMI)

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Virtual MMI for terminals

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Any given TETRA radio terminal using Java (Java ME/CLDC) based technology, provides the end user with the communication rights necessary to fulfil his or her work role on any short duration assignment.

For dexterity, flexibility, and evolution ability, the public transportation radio engineering department, have chosen to use the open sources, Java language specification administered by Sun and the associated work groups in order to produce a transport application tool kit.

Service acquisition admits different authorised agents to establish communication channels between different services by calling the service identity, and without possessing the complete knowledge of the ISSI, GSSI, or any other TETRA related communication establishment numbering plan. Service acquisition is administered through a communication rights centralised service or roll allocation server, interfaced into the TETRA core network.

In summary, the TETRA MMI aims are to:

  • Allow any given agent while in exercise, to exploit any given radio terminal without materiel constraint.
  • Provide specific transportation application software to the end-user agents (service acquisition, fraud, and aggression control).

This transport application tool-kit has been produced successfully and with TETRA communication technology and assures for the public transport application requirements for the future mentioned hereafter.

The home (main) menu presents the end user with three possibilities:

  1. Service acquisition,
  2. Status SDS,
  3. End-user parameters.

Service acquisition provides a means of virtually personalising the end user to any given radio terminal and onto TETRA network for the duration the end user conserves the terminal under his possession.

Status SDS provides the end user with a mechanism for generating a 440 Hz repeating tone that signals a fraud occurrence to members within the same (dynamic or static) Group Short Subscriber Identity (GSSI) or to a specific Individual Short Subscriber Identity (ISSI) for the duration of the assignment (an hour, a morning patrol or a given short period allocated to the assignment). The advantage being that each of the end users may attach themselves to any given terminal, and group for short durations without requiring any major reconfiguration by means of radio software programming tools. Similarly, the aggression feature functions, but with a higher tone frequency (880 Hz), and with a quicker repetitious nature, so to highlight the urgency of the alert.

The parameters tab provides an essential means to the terminal end-user allowing them to pre-configure the target (preprogrammed ISSI or GSSI ) destination communication number. With this pre-programmed destination number, the end-user shall liaise with the destination radio terminal or roll allocation server, and may communicate, in the group, or into a dedicated server to which the service acquisition requests are received, preprocessed, and ultimately dispatched though the TETRA core network. This simplifies the reconfiguration or recycling configuration process allowing flexibility on short assignments.

The parameters tab also provides a means of choosing between preselected tones to match the work group requirements for the purposes of fraud and aggression alerts. A possibility of selecting any given key available from the keypad to serve as an aggression or fraud quick key is also made possible though the transport application software tool kit. It is recommend to use the asterisk and the hash keys for the fraud and aggression quick keys respectively. For the fraud and aggression tones, it is also recommend to use 440 Hz slow repeating tone (blank space 500 milli-seconds) and 880 Hz fast repeating tone (blank space 250 milliseconds) respectively. The tone options are as follows: 440 Hz, 620 Hz, 880 Hz, and 1060 Hz.

The parameters page provides an aid or help menu and the last tab within parameters describes briefly the tool kit the version and the history of the transport application tool kit to date.

TETRA Enhanced Data Service (TEDS)

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The TETRA Association, working with ETSI, developed the TEDS standard, a wideband data solution, which enhances TETRA with a much higher capacity and throughput for data. In addition to those provided by TETRA, TEDS uses a range of adaptive modulation schemes and a number of different carrier sizes from 25 kHz to 150 kHz. Initial implementations of TEDS will be in the existing TETRA radio spectrum, and will likely employ 50 kHz channel bandwidths as this enables an equivalent coverage footprint for voice and TEDS services. TEDS performance is optimised for wideband data rates, wide area coverage and spectrum efficiency.[17]

Advances in DSP technology have led to the introduction of multi-carrier transmission standards employing QAM modulation. WiMAX, Wi-Fi and TEDS standards are part of this family.

Refer also to:

  • JSR-118;
  • Mobile Information Device Profile, JSR-37;
  • Wireless Messaging API, JSR120;
  • Connected Limited Device Configuration, JSR-139; and
  • Technology for the Wireless Industry, JTWI-185.

Comparison to Project 25

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Project 25 and TETRA are utilised for the public safety Radio network and Private Sector Radio network worldwide however, it has some differences in technical features and capacities.[18][19][20]

  • TETRA: It is optimized for high population density areas, with spectral efficiency (4 time slots in 25 kHz: four communications channels per 25 kHz channel, an efficient use of spectrum). It is suitable for high population density areas and supports full duplex voice, data and messaging. but, it is generally unavailable for simulcast, VHF band - however particular vendors have introduced Simulcast and VHF into their TETRA platform..
  • P25: it is optimized for wider area coverage with low population density, and support for simulcast. however, it is limited to data support. (Phase 1 P25 radio systems operate in a 12.5 kHz analogue, digital or mixed mode, and P25 Phase II will use a 2-timeslot TDMA structure in 12.5 kHz channels.

Currently, P25 deployed to more than 53 countries and TETRA deployed to more than 114 countries.

Professional usage

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At the end of 2009 there were 114 countries using TETRA systems in Europe, Middle East, Africa, Asia Pacific, Caribbean and Latin America.[21]

The TETRA-system is in use by the public sector in the following countries. Only TETRA network infrastructure installations are listed. TETRA being an open standard, each of these networks can use any mix of TETRA mobile terminals from a wide range of suppliers.

Continent Country Supplier Name Agency Status
Asia China mainland EADS/Cassidian/Airbus Shenyang Metro Transport In use: Line 1
Rolling out: Line 2[22]
DAMM TetraFlex Guangzhou Electric Power Utility - Guangzhou Electric Power Emergency Communication In use 2010
EADS/Cassidian/Airbus Shenzhen Metro Transport Ordered 5/2010[23]
EADS/Cassidian/Airbus Guangzhou 16th Asian Games in 2010 Ordered 2010[23]
Hong Kong[24] EADS/Cassidian/Airbus[25] Hong Kong International Airport (HKIA) 2008 Beijing Olympics and Paralympic Games (Hong Kong Equestrian Event) Used from July 2008 to October 2008
EADS/Cassidian/Airbus Hong Kong Fire Services Department Fire service and ambulance In use
Motorola / Dimetra Hong Kong Police Force Police In use
Motorola Correctional Services Department Law enforcement In use
Motorola Immigration Department Law enforcement In use
Motorola Mass Transit Railway (MTR)[26] Transport In use
Motorola / Dimetra Hong Kong International Airport (HKIA) Transport In use since Feb 2009[27]
Motorola CLP Power Hong Kong Limited Electric In use
Hongkong Electric Co., Limited Electric In use
Modern Terminals Limited Container port In use
Hong Kong International Terminals Limited Container port In use
Liaison Office of the Central People Government in the HKSAR Diplomacy In use
India Artevea Military College of Telecommunication Engineering (MCTE) Indian Army In use since 2004 at Mhow, Indore, Madhya Pradesh
Motorola / Dimetra Delhi Metro Rail Corporation Ltd. Transport The First TETRA in India, in use since 2002
DAMM TetraFlex / Consort Digital Pvt Ltd Mumbai Mono Rail, Mumbai Metropolitan Region Development Authority (MMRDA) Mass transport - India's first monorail project - Mumbai Awarded 2010[28]
C-DAC TETRA with Automatic Dial 100 (AD100) Kerala police In use by police, Trivandrum city, since 2008
DAMM TetraFlex / Consort Digital Pvt Ltd Tamil Nadu police Police and internal security and safety Awarded 2011[29]
HCL & Motorola Secure Communication Network Delhi government Integrated Communication System used by various departments under government of Delhi and Delhi police since 2010.
DAMM TetraFlex / Consort Digital Pvt Ltd Gas Authority of India Limited (GAIL) Gas pipeline - safety, telemetry and security Awarded 2011[30]
THALES Portugal S A & Motorola With PSTN call integration designed by Thales Group for BMRCL BMRCL Bangalore Metro Corporation Limited Transport, in use since March 2011
Sepura & Rohde and Schwarz TETRA with Automatic Dial 100 (AD100) Gurgaon police In use by police, Gurgaon city[31] Since 2009. In Salem from August 2011.
Sepura & Rohde and Schwarz TETRA with Automatic Dial 100 (AD100) Faridabad police In use by police, Faridabad city, since 2012
Indonesia Motorola / Dimetra, installed & maintained by PT. Mobilkom Telekomindo SCADA PT. Chevron Pacific Indonesia HOOU In use since 2009 at Duri, Riau, Indonesia.
Rohde & Schwarz / Accessnet - T Anti Corruption Agency Anti Corruption Agency Operational
Rohde & Schwarz / Accessnet-T Jakarta State Government Network Jakarta Capital City Jakarta Operational, Installed since 2007
Macao Artevea Melco-Crown Entertainment Casino-Hotels: Altira (formerly Crown Macau),[32] and City of Dreams In use since 2007
Motorola / Dimetra Forças de Segurança de Macau All emergency services In use
Malaysia EADS/Cassidian/Airbus Segi Maju (SEGI) Public operator In use[33]
Motorola / Dimetra Sungai Buloh–Kajang line. Transport In use[34]
Motorola / Dimetra Sungai Buloh–Serdang–Putrajaya line. Transport Operational 2021
Maldives Motorola / Dimetra Maldives Police Service (MPS) Police In use
Pakistan Motorola / Dimetra NITRS Nationwide Integrated Trunk Radio System Project for Police under Ministry of Interior, Government of Pakistan Police In use Since 2009
Philippines Motorola Dimetra/GA Technology and Systems Inc. Shell Exploration Oil and gas In use October 2013, Phase 2 On Shore Gas Plant for Implementation
Motorola Dimetra/GA Technology and Systems Inc. Globe Telecom Telecommunications carrier Implementation on Going Project Finish Dec 2013
Rohill (TetraNode) SynTech Systems Inc. Meralco Electric company Implemented Nov 2014
Rohill (TetraNode) SynTech Systems Inc. Manila Line 2 Transport (Manila Light Rail Transit System Line 2) Implemented Oct 2015
South Korea EADS/Cassidian/Airbus Korea Electric Power Corporation (KEPCO) Electricity In use[35]
Taiwan Taiwan Railways Administration Transport In use
Taiwan High Speed Rail Transport In use
Taipei Metro Transport In use
Kaohsiung Mass Rapid Transit Transport In use
Coast Guard Administration (Taiwan) Republic of China Armed Forces In use
Africa Algeria Rohde & Schwarz Sonatrach Oil & gas company In use since 2003.
Sepura Sonelgaz Power utility In use.
Morocco Rohill ADM Highway authority Rolling out / Almost completed.
Nigeria Dizengoff/Motorola IL (Dimetra IP) Nigeria LNG Oil & gas Since 2006
Cisan International Limited/Rohill (TetraNode) Mobil Ng Oil Since 2014
Dizengoff/Motorola IL (Compact-Tetra IP) Shell Ng Oil Since 2010
Satcomm Integrated Resources LLC SatCom IRL/EADS [36] Nigerian Ports Authority, Nigeria (rolling out) Rolling out
Rohill (TetraNode) Bayelsa State Government Since June 2012
Briscoe Technologies[37] / Hytera Accessnet Lagos / Abuja / Port Harcourt Oil industry / airports / security companies In use Since 2006
Namibia Artevea Namibian Police Force[38] Police In use, nationwide
South Africa Motorola Solutions DIMETRA Police, traffic police SAPS Gauteng Gauteng province
Motorola Solutions DIMETRA Municipality, fire, and ambulance. City of Cape Town Cape Peninsula
Rohill (TetraNode) Mbombela Local Municipality Nelspruit, Mpumalanga Complete
Rohill (TetraNode) City Power Johannesburg, Gauteng Complete
Rohill (TetraNode) City of Tshwane Municipality Pretoria, Gauteng Complete
Rohill (TetraNode) Rustenburg Platinum Mine Potgietersrus, Limpopo Complete
Sudan Artevea Ministry of Interior Police In use, nationwide
Egypt Motorolasolutions

Dimetra IP

MERC Ministry of Interior, Suez Canal Authority, Oil& GAS and commercial users In use, Nationwide
Europe Austria Motorola / Dimetra TETRON Police, fire, ambulance, and local train company. In use, in all states except Tyrol and Vorarlberg (still rolling out).
Belgium EADS/Cassidian/Airbus/Since 1998 nl:A.S.T.R.I.D. fr:A.S.T.R.I.D. Police, fire, ambulance, customs, coast guard, hospitals, Red Cross, department of Justice, utility companies, airports, ports, lifeguard service, military. Nationwide network
Rohde & Schwarz since 2011/ ACCESSNET-T ENTROPIA DIGITAL Commercial & private security users.[39] Flanders & Brussels
Croatia Motorola / Dimetra MUPNet Police, fire brigades, ambulance service Nationwide coverage (99,5%) in use
Denmark DAMM TetraFlex DONG Energy Power Plants - 11 Power Plants across Denmark Utilities - safety, security, telemetry Awarded 2009[40]
Motorola / Dimetra SINE[41] All emergency authorities, incl. police, fire, and ambulance. Nationwide coverage (99,5%) in use
Estonia EADS/Cassidian/Airbus ESTER Police and border guard, fire, ambulance, and customs Nationwide network
Finland Nokia; now EADS/Cassidian/Airbus VIRVE Police, fire, ambulance, customs, defence forces, and border guard Nationwide network
HelenNet Energy company Helsingin Energia, tram operator HKL-Raitioliikenne, and several bus operators on HRTA's lines. Also used by some security guard companies, mostly securing HRTA's transport. Available for lease for various short-term uses. In use, covers greater Helsinki region
Germany EADS/Cassidian/Airbus BOSNET Police, fire, ambulance, customs, and coast guard. Nationwide
DAMM TetraFlex Global Tech 1 Offshore Wind GmbH. Utility Windfarm - Telemetry, Security and Safety Critical communications Awarded 2012[42]
Greece Motorola / Dimetra COSMOTE TETRA Services
Formerly branded OTElink (2009).
Business critical, public protection & disaster relief (PPDR) communications, public utility and oil-gas companies, seaports, airports, public and private transportation companies, public and private sector security personnel, other. Data applications nationwide including SCADA, AVL, M2M. Extensive nationwide footprint,
70% population coverage in 2014, in use since 2002
SEPURA Teltronic Police, Fire Services, Coast Guard Nationwide roll-out in progress.
Hungary Pro-M Ltd. EDR (acronym for Unified Digital Radiosystem) Ambulance, army, Central Office for Administrative and Electronic Public Services, Civil Defence, Hungarian Prison Service, Hungarian Customs and Finance Guard, disaster management, fire, Hungarian Secret Services, Ministry of Environment and Water, and police In-use
Iceland Motorola / Dimetra TETRA Iceland Police, fire services, ambulances, Search and Rescue units, Red Cross, bus service (Strætó Bs.), The Icelandic National Broadcasting Service, most utility companies, municipalities and private users such as excursion companies. In-use
Ireland Motorola / Dimetra TETRA Ireland An Garda Siochana, HSE National Ambulance Service, Irish Prison Service, Irish Naval Service, Customs & Excise, civil defense (only a few units), Irish Coast Guard, mountain rescue (only a few units), Order of Malta Ambulance Corps, Irish Red Cross, St John Ambulance, National Emergency Office, Port of Cork, Revenue Commissioners and Office of Public Works. Nationwide roll-out network complete. The fire services are planning to implement in the coming years. As of July 2011, TETRA Ireland now operates the national Paging System.
Italy DAMM TetraFlex Lombardi Ambulance Emergency Services Ambulance - security, safety, communication Awarded 2010[43]
SELEX ELSAG Rete Interpolizie Polizia di Stato (Italian state police), Carabinieri (military police), Guardia di Finanza (financial police), Polizia Penitenziaria (prison police), and Corpo Forestale Italiano (Italian forest brigades) Rolling out
DAMM TetraFlex Rome International Airport Airport - security, safety, commercial, fire, customs, police Awarded 2009[44]
Latvia Artevea Ventamonjaks Serviss Ltd, Ventspils[45] Oil and gas In use since 2007
Motorola / Dimetra (SIA DAN Communications) Riga Municipal Police[46] Local law enforcement in Riga Ordered in 2016[47]
Motorola / Dimetra (SIA DAN Communications) State Police[48] National law enforcement
Luxembourg Motorola / Dimetra Renita[49] Government; police, fire brigade, ambulance services and others Start building 2014, Operational since 2015
Motorola / Dimetra ConnectCom[50] Commercial network Operational
Motorola / Dimetra ConnectCom[50] Public Transport, city of Luxembourg Operational
Motorola / Dimetra ConnectCom[50] European Union Operational
North Macedonia Hytera Fire brigade of city Skopje Fire department In use
Malta Marconi Civil Protection Force[citation needed] July 2001
Monaco Motorola Sûreté Publique (Police), Carabiniers (military police), fire brigades, ambulance Nationwide coverage (including indoor public buildings)
Montenegro Motorola / Dimetra Wireless Montenegro d.o.o. Police, military, fire brigades, ambulance In use since November 2012 Podgorica area only. Rolling out elsewhere.
Netherlands Motorola / Dimetra until 2019, Hytera / AccessNet-T since 2019 C2000[51] Police, fire, and ambulance Nationwide network
Motorola / Dimetra ENTROPIA DIGITAL Commercial users.[39] National license
Motorola / Dimetra until 2019 ?, Hytera AccessNet-T since 2019 ?? HTM Public transport The Hague Regional network
Motorola / Dimetra CCTN / GVB Public transport Amsterdam Regional network
Rohill RET Public transport Rotterdam Regional network
Rohill Schiphol Airport Schiphol Group, KLM, and other businesses Local network
Sepura TATA steel Europe Hoogovens Local network
Norway Motorola / Dimetra Norwegian Public Safety Radio Police, fire, ambulance, civil defense and search and rescue Nationwide rollout completed September 2015
Motorola Ruter/Sporveien Public Transport, Oslo Established before 2003
Portugal Motorola SIRESP Police (PSP and GNR), fire, ambulance and civil protection Nationwide roll-out, in use since 2007
Motorola Lisbon International Airport (LPPT) Transport - Ground operations Local Network
Poland Motorola Ministry of Interior, Polish army, and Warsaw police Police, fire, public transport, airports, and army.[52] Local TETRA Networks in use since 2000; national roll-out expected to start in 2011.
Rohill (TetraNode) Szczecin, Warsaw and Kraków police Roll-out ongoing. Modern IP based TETRA solution for 3 cities
Romania Motorola / Dimetra Special Telecommunications Service (STS) Police, fire, and search and rescue Nationwide
Motorola Dimetra Ministry of Administration and Interior (MAI) / Romanian Border Police (RBP) In use since 2008 for police, emergency and search and rescue agencies from Romanian border counties-wide
EADS/Cassidian/Airbus TETRA EADS Ministry of Administration and Interior (MAI) / Romanian Border Police (RBP) In use since 2010 for police, emergency and search and rescue agencies from Romanian border counties-wide
Hytera/Motorola/Sepura HamTetra Network Romania Amateur radio users engage in both DMO (Direct Mode Operation) and TMO (Trunked Mode Operation) modes, both within the country and globally, connecting through gateways such as Zello and SVXLink.

Ham Tetra Romania Network Architecture was developed and published along with users map and equipment used on the YO8TEH website

Tetra gear in ham radio was initially introduced by YO8TEH in 2014 in DMO (Direct Mode Operation). Subsequently, it evolved into gateways through platforms like Zello and Teamspeak. In 2021, a part of the system was split and migrated to svxlink, along with its classic application. The first Tetra Repeater for Ham Radio use in Romania was licensed under the call sign YO8TEH-1, while the second TMO repeater was licensed under the call sign YO8Q.
Russia DAMM TetraFlex Moscow Metro (second most heavily used rapid transport system in the world) Transport - rail - telemetry, safety, security, police, ambulance, fire Awarded 2011[53]
Sepura Unified system of operational trunking radio (Единая Система Оперативной Транкинговой Радиосвязи) Fire, ambulance and partially, police Launched in 2008
DAMM TetraFlex Russias Kaliningrad Power Plant. Utility power plant - safety and security - telemetry and commercial agents Awarded 2009[54]
DAMM TetraFlex St Petersburg and North West Russia. Government - ambulance and emergency services, police, healthcare facilities, utility services, St. Petersburg Authorities and the regional civil defense Awarded 2011[55]
Serbia Motorola / Dimetra Ministry of Interior Police, fire brigades, ambulance Fully rolled out as of 2009
Slovenia Selex/OTE/Marconi Ministry of Interior Police In central Slovenia
Spain Motorola Basque Country Mainly police In use since 2006
Teltronic Basque Country Mainly municipalities and public services In use since 2009
EADS/Cassidian/Airbus Catalonia Police, fire brigades, civil protection, ambulances, forest guards, water agency, gas company, road maintenance service and other public agencies In use since 2006
Sweden SAAB, Cassidian, Eltel Networks RAKEL Managed by the Civil Contingencies Agency - MSB. For use by the emergency services and others in the fields of civil protection, public safety and security, emergency medical services and healthcare, road services, nuclear facilities. In operation, covering 99.8% of Sweden's population and 95% of its territory
Motorola Tetra Stockholm public transport: used by transport security officers for dispatch internal communications, Transport Police ("Tunnelbanepolisen") and other police forces for liaison with transport officials. Roll-out stage for train operations on underground. In operation / roll-out
Rohde & Schwarz Got1 Got1 is a modern IP based Tetra network used in the west parts of Sweden. Mainly in the Gothenburg region. With customers like SKF and Volvo Trucks. In operation
United Kingdom Motorola / Dimetra / Sepura Airwave Police, fire, NHS ambulance services, Border Force, immigration enforcement, some armed forces, National Highways traffic officers, civil contingency services, HM Coastguard, St John Ambulance, St John Cymru, British Red Cross, Highland Council, and miscellaneous emergency services. Full emergency service rollout complete
Hytera Tetra Prison Service Operational
Motorola / Dimetra Connect Transport for London (London Underground) Used by all Tube staff and relaying Airwave for BTP when underground
AirRadio AR-en Use by some services at some major airports (Heathrow, Birmingham, Manchester, Glasgow, Aberdeen)
Middle East Israel Motorola[56] Mountain Rose Israel Defense Forces (IDF) In use by IDF, country-wide
Turkey DAMM TetraFlex Alacer Gold Mine Mining - safety and security critical communications Awarded 2012[57]
United Arab Emirates EADS/Cassidian/Airbus Nedaa Police, emergency services, and professional communications Dubai, Sharjah, Ajman, Umm Al-Qaiwain, Ras Al-Khaimah, and Fujairah operational
EADS/Cassidian/Airbus Polikom Police, emergency services, and professional communications Abu Dhabi
Qatar EADS/Cassidian/Airbus Ministry of Interior, army, police, air force search and rescue, EMS (medical). Initial use for the 15th Asian Games all games venues inclusive of transportation routes for "blue light" services, later extended to cover the State of Qatar, in use since 2006, national roll out complete by 2008. Known as Qatar Secure TETRA Radio System (QSTRS).
Latin America Mexico Rohde & Schwarz / Sepura Mazatlán, Sinaloa Police & Emergency Services Police, emergency services operational Operational
South America Brazil[58] Motorola América Latina Logística Railroad, communication and licensing. Operational
Teltronic / Motorola Polícia Rodoviária Federal Road patrol, country-wide In operation / national roll-out in progress
Teltronic / Motorola 12 states[59] Public Safety Agencies In operation, 600+ stationary stations.
Caribbean Windward Islands and Leeward Islands Rohill Zenitel, C3 since 2005 Police, emergency services, oil and professional communications Aruba, Bonaire, Curaçao, Sint Maarten, Saint Martin, Saba, Sint Eustatius, and Anguilla operational
Dominican Republic Hytera Metro of Santo Domingo, and

National Emergency and Safety System 9-1-1

Metro: railroad communication, telemetry and PLC.

911: technical and power systems support communication, operations and dispatching, service agencies communication systems (police, Public health, firefighters, traffic control authority, road support).

Metro: First line operation started in 2008. 2nd line operation started 2013. 2nd line expansion (L2B) started in 2014 and started operation on August 8, 2018.

911: Operation started in 2014 in Santo Domingo, with expansions in 2015. In 2016, TETRA trunking radio expanded to Haina and San Cristobal, cities in the southwest of Santo Domingo. In 2017, the service expansion of 911 services using TETRA expanded to the north of the country, to cover large cities as Santiago, Puerto Plata and small villages. On August 3, 2018, service expanded to the province Peravia (West to the Capital) and on August 28, 2018, it started in the province of San Pedro de Macoris ( East to the capital).

Oceania Australia DAMM TetraFlex BHP Billiton Temco Smeltering Tasmania - mining, commercial, safety, security Awarded 2011
DAMM TetraFlex Rio Tinto Western Australia Mining Awarded 2009[60]
Rohill Tetra Inpex Ichthys LNG Infrastructure
Rohill Tetra BHP Billiton Macedon Gas Infrastructure
DAMM TetraFlex Origin Energy (APLNG)[61] Kordia Solutions Australian Pacific Project
Rohill Tetra Goldlinq Goldcoast rail Goldcoast infrastructure
DAMM TetraFlex Fortescue Metals group Open cut mining Awarded 2011[62]
DAMM TetraFlex Gorgon LNG Project, Chevron, Australia Gas and pipelines Awarded 2011[63]
Motorola BHP Billiton Pyrenees FPSO Awarded 2016
Motorola Zeon Local government Operational across Brisbane City Council, including the Brisbane State Emergency Service Unit
DAMM TetraFlex Australian Submarine Co Military, defence, comms, safety, security Awarded 2012
Motorola Zeon Tertiary education Used by Queensland University of Technology security staff.
Sepura Being used by several Mining Operations throughout Western Australia and Queensland - Terminals only - No Infrastructure.
New Zealand DAMM TetraFlex BHP One Steel Aluminium Smelter - ore production - safety, security, operations Awarded 2012
Kordia KorKor Airports Used by Wellington International Airport, Air New Zealand
Kordia KorKor Councils Used by Hutt City, Auckland Transport
Teltronic Widarcom Commercial network launched 2008 Used by University of Auckland, Westpac

Amateur Radio usage

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In the past decade, TETRA has seen an uptick in usage in the amateur radio community. The perceived higher audio quality compared to other digital voice modes, capacity for packet data, SDS, single frequency DMO repeaters, close proximity of the UHF (430-440MHz) amateur radio band and full duplex audio in TMO are motivating arguments to experiment contacts with this technology.

Multiple constraints have to be noted when using TETRA for amateur radio service:

  • In most countries, encryption cannot be used.
  • Most older (pre-2010) terminals don't cover the Region 1 amateur radio frequency range (430-440) natively, and must be modified via software with a possible impact on RF performance.[64]

Multiple amateur DMO[65] and TMO[66] networks are established throughout Europe.

Additionally, an open-source project aims to create a complete SDR-based TETRA stack, with a working DMO repeater proof of concept.[67]

See also

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References

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  1. ^ ETSI EN 300 392-2 v3.2.1
  2. ^ "TETRA Association". TETRA Association. 2012-03-22. Archived from the original on 2018-08-16. Retrieved 2012-03-28.
  3. ^ "TETRA - PST". PST. Archived from the original on 2018-02-28. Retrieved 2017-01-25.
  4. ^ "Guide to the R&TTE Directive 1999/5/EC (April 20, 2009)". pp. 9–10.
  5. ^ a b c d e Midnight Blue. "TETRA:BURST".
  6. ^ a b c d Midnight Blue (August 2023). All Cops Are Broadcasting: Breaking TETRA after decades in the shadows (slideshow) (PDF). Blackhat USA 2023.
    Carlo Meijer; Wouter Bokslag; Jos Wetzels (August 2023). All cops are broadcasting: TETRA under scrutiny (paper) (PDF). Usenix Security 2023.
  7. ^ Scroxton, Alex (25 Jul 2023). "Tetra radio users' comms may have been exposed for years". Computer Weekly. Archived from the original on 2023-07-26. Retrieved 2023-07-26.
  8. ^ "Smartphone app/apps over TETRA". Crystal Code AB. Archived from the original on 2014-05-29. Retrieved 2013-07-16.
  9. ^ "Radio Spectrum - Table of frequency allocations". ComReg. Archived from the original on 2016-03-04.
  10. ^ "National Table of Frequency Allocations". Post- og teletilsynet. Archived from the original on 2005-01-12.
  11. ^ Office of the Communications Authority (2022-05-25). "Table of Frequency Allocations of Hong Kong" (PDF).
  12. ^ "Cryptographic security for the new trans-European trunked radio (TETRA) standard". June 1994. pp. 3/1–3/5.
  13. ^ DW Parkinson (2001-07-01). "TETRA Security". BT Technology Journal. 19 (3): 81–88. doi:10.1023/A:1011942300054. S2CID 169255984.
  14. ^ Zetter, Kim. "Code Kept Secret for Years Reveals Its Flaw—a Backdoor". Wired. ISSN 1059-1028. Retrieved 2023-07-24.
  15. ^ Doug Gray, An Overview of TETRA Archived 2011-09-27 at the Wayback Machine, etsi.org.
  16. ^ Gert Roelofsen (1999). "Cryptographic algorithms in telecommunications systems". Information Security Technical Report. 4: 29–37. doi:10.1016/S1363-4127(99)80004-1.
  17. ^ "Walasey Components Ltd - Beijing".
  18. ^ Ammons, Keith. "Pros and Cons of TETRA vs. P25 and the Benefits of a Multi-technology Platform for TETRA, P25 Phase I / Phase II, and Mobile WiMax" (PDF). www.powertrunk.com.
  19. ^ "P25 and TETRA Technology Roundtable". 3 May 2012.
  20. ^ https://tandcca.com/fm_file/dubai06swancomparison-pdf/ [dead link]
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  22. ^ "Shenyang Metro". Railway Technology. 2011-06-15. Retrieved 2012-03-28.
  23. ^ a b "EADS Global Website - EADS Global Website". Archived from the original on 2013-02-21. Retrieved 2016-02-08.
  24. ^ Office of the Communications Authority (2022-09-13). "The Numbering Plan for Telecommunications Services in Hong Kong" (PDF).
  25. ^ "HOME". Cassidian.com. Archived from the original on 2011-05-26. Retrieved 2012-03-28.
  26. ^ "TETRA : Artevea Digital Limited : Digital Radio Communication". Artevea.com. Retrieved 2012-03-28.
  27. ^ "Motorola Media Center - Press Releases - Motorola Completes Upgrade to TETRA Digital Radio System for Hong Kong International Airport". Mediacenter.motorola.com. Retrieved 2012-03-28.
  28. ^ 1st Monorail Project in India awarded to DAMM. Damm.dk (2010-08-11). Retrieved on 2013-07-16.
  29. ^ Tamil Nadu Police. Damm.dk (2011-01-31). Retrieved on 2013-07-16.
  30. ^ DAMM chosen to provide communication for GAIL pipeline in India. Damm.dk (2011-07-12). Retrieved on 2013-07-16.
  31. ^ "Gurgaon Police goes Hi-Tech". Retrieved 2013-01-14.
  32. ^ "TETRA : Artevea Digital Limited : Digital Radio Communication". Artevea.com. Retrieved 2012-03-28.
  33. ^ "Launch of digital trunked radio service in Malaysia". mis-asia.com.
  34. ^ "Motorola to supply TETRA network for Malaysian rail project". 8 February 2018.
  35. ^ "TETRA Association". Archived from the original on November 30, 2010.
  36. ^ "SatCom IRL | Homepage". Archived from the original on 2013-03-23. Retrieved 2013-05-08.
  37. ^ "Hyperlinks". www.briscoetechnologies.com.
  38. ^ "TETRA : Artevea Digital Limited : Digital Radio Communication". Artevea.com. Retrieved 2012-03-28.
  39. ^ a b "Entropia – Critical concepts". www.entropia.eu.
  40. ^ DAMM supplies safe TETRA communication for DONG Energy Power Plants. Damm.dk (2009-09-02). Retrieved on 2013-07-16.
  41. ^ "SINE - About SINE". Archived from the original on 2012-04-27. Retrieved 2012-02-23.
  42. ^ Global Tech 1 Offshore Wind farm relies on DAMM Infrastructure. Damm.dk (2012-08-27). Retrieved on 2013-07-16.
  43. ^ TetraFlex for Public Safety in Lodi, Italy. Damm.dk (2010-02-02). Retrieved on 2013-07-16.
  44. ^ Rome International Airport chooses DAMM as supplier for Mission Critical Communication. Damm.dk (2009-09-14). Retrieved on 2013-07-16.
  45. ^ {{cite web|url=http://www.artevea.com/casestudies-detail.php?type=case&id=11 |title=TETRA : Artevea Digital Limited : Digital Radio Communication |publisher=Artevea.com |access-date=2012-03-28}}
  46. ^ "TETRA system for the Riga Municipal Police / DAN Communications". www.dan.lv. Retrieved 2020-06-21.
  47. ^ "Paziņojums par līgumu RPP 2016/31 "Par radiosakaru sistēmas uzturēšanu, tehnisko atbalstu un remontu"". Rīgas pašvaldības policija (in Latvian). Retrieved 2020-06-21.
  48. ^ "DAN COMMUNICATIONS, SIA". Prakse.lv. Retrieved 2020-06-21.
  49. ^ "Page Redirection". www.renita.lu.
  50. ^ a b c Sefrengo, CMS. "Radiocommunication sur mesure". www.connectcom.lu.
  51. ^ "MDC". www.c2000.nl.
  52. ^ "TETRA Forum Poland". Tetraforum.pl. 26 November 2010. Retrieved 2020-06-08.
  53. ^ Moscow Metro. Damm.dk (2011-01-04). Retrieved on 2013-07-16.
  54. ^ Kaliningrad biggest Power Plant chooses DAMM’s TetraFlex system for safety reasons. Damm.dk (2009-10-01). Retrieved on 2013-07-16.
  55. ^ DAMM deployed for regional network in North West Russia. Damm.dk (2011-08-22). Retrieved on 2013-07-16.
  56. ^ "Wide Area Military Voice & Data Infrastructure Solutions based on COTS technology" (PDF). Retrieved 2012-03-28.
  57. ^ DAMM's TetraFlex® chosen for Alacer Gold Mining operation. Damm.dk (2012-11-05). Retrieved on 2013-07-16.
  58. ^ "Builds Tetra Network in Brazil by Dr. Cristiano Torres do Amaral from Brazilian Police Academy" (PDF). Retrieved 4 March 2020.
  59. ^ "Tecnologia espanhola da Teltronic adiciona mais um estado à rede nacional TETRA implantada no Brasil". Retrieved 1 Jan 2023.
  60. ^ Rio Tinto Mining Group continues to deploy DAMM’s TetraFlex. Damm.dk (2009-08-03). Retrieved on 2013-07-16.
  61. ^ "Archived copy". Archived from the original on 2014-02-12. Retrieved 2014-02-13.{{cite web}}: CS1 maint: archived copy as title (link)
  62. ^ Fortescue Metals Group Ltd deploy DAMM. Damm.dk (2011-03-18). Retrieved on 2013-07-16.
  63. ^ World’s largest LNG project to roll-out DAMM’s TetraFlex®. Damm.dk (2010-04-26). Retrieved on 2013-07-16.
  64. ^ "Tetra Ham Documents | Stichting Telekom Techniek Arnhem" (in Dutch). Retrieved 2024-07-10.
  65. ^ "Tetra SVXLink dashboard". 10 July 2024.
  66. ^ "Tetrapack Map". 10 July 2024.
  67. ^ rats-ry/HamTetra, Radioamatööritekniikan seura r.y., 2024-06-11, retrieved 2024-07-10
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