Trans European Trunked RAdio

Description

Trans European Trunked RAdio (TETRA) is a digital trunked radio standard originally developed by ETSI for professional and governmental use, which has been incorporated into 3GPP specifications to facilitate interoperability and convergence with public cellular networks like LTE and 5G. Within 3GPP, TETRA is addressed in multiple technical specifications, including TS 22.179 (Mission Critical Push to Talk), TS 23.283 (Mission Critical Services Architecture), and TS 36.868 (LTE-based TETRA enhancements). The system operates in dedicated frequency bands (typically below 1 GHz) and uses Time Division Multiple Access (TDMA) with four time slots per carrier, offering efficient spectrum use and supporting voice, data, and short messaging services.

Architecturally, a standalone TETRA network comprises base stations (TBS), switching and management infrastructure (TETRA Infrastructure), and mobile stations (MS). Key components include the TETRA Terminal Equipment (TE) for user interface and the TETRA Mobile Equipment (ME) for radio functions. 3GPP's work focuses on integrating TETRA services with LTE/5G cores, enabling features like Mission Critical Push-to-Talk (MCPTT) over broadband. This involves defining interworking functions and gateways that map TETRA signaling and user plane traffic to 3GPP protocols, allowing dual-mode devices to access both TETRA and cellular networks seamlessly. For instance, group calls initiated on TETRA can be extended to LTE users via the MCPTT application server, leveraging IMS for session control.

TETRA's operation emphasizes reliability and security, with built-in encryption (air interface and end-to-end), fast call setup (under 300 ms), and direct mode operation (DMO) for device-to-device communication without infrastructure. In 3GPP contexts, these capabilities are enhanced through integration with EPS and 5GS. Specifications like TS 23.782 and TS 23.783 detail scenarios where TETRA networks interconnect with 3GPP systems for service continuity, such as using LTE for high-speed data while relying on TETRA for mission-critical voice. This hybrid approach ensures that public safety organizations benefit from broadband capabilities while maintaining the robust, proven performance of TETRA for life-critical communications.

Purpose & Motivation

TETRA was created to meet the stringent requirements of professional mobile radio users, such as police, firefighters, ambulance services, and transportation operators, who need secure, instant, and group-oriented communication beyond what commercial cellular networks offered. Prior to TETRA, analog PMR systems suffered from limited capacity, poor voice quality, and lack of encryption, making them unsuitable for critical missions. TETRA addressed these limitations with a digital, trunked design that provided efficient spectrum use, advanced features like group calling and priority preemption, and strong security—addressing the need for reliable coordination in emergency situations.

3GPP's adoption of TETRA-related specifications, starting in Rel-12, was motivated by the growing demand for broadband-enabled critical communications and the convergence of dedicated PMR networks with public cellular infrastructure. As LTE and 5G evolved, they offered high-speed data but initially lacked the mission-critical voice features inherent to TETRA. By standardizing TETRA integration, 3GPP enabled a migration path where organizations could leverage LTE/5G for applications like video streaming or data analytics while preserving TETRA's proven voice capabilities, thus solving the problem of technological transition without sacrificing operational effectiveness.

Furthermore, this integration supports regulatory and governmental initiatives for modernized public safety networks (e.g., FirstNet in the USA, ESN in the UK). It addresses the limitations of siloed systems by allowing interoperability between TETRA and 3GPP networks, facilitating cross-agency collaboration and resource sharing. The evolution through 3GPP releases ensures that TETRA's strengths—such as coverage in remote areas via DMO and resilience during network congestion—are complemented by cellular broadband, future-proofing critical communications for the era of IoT, smart cities, and advanced emergency services.

Key Features

• Digital trunked radio with TDMA (4 slots per carrier) for efficient spectrum use
• Secure communications with built-in encryption and authentication
• Group calling (push-to-talk) and direct mode operation (device-to-device)
• Fast call setup and priority preemption for critical users
• Integration with 3GPP LTE/5G networks for broadband data and MCPTT services
• Robust coverage and reliability for mission-critical applications

Evolution Across Releases

Defining Specifications