Mioty

History and Origins

• Research into splitting wireless data transmissions into multiple short telegrams began in 2009 at the Fraunhofer Institute for Integrated Circuits, aimed at increasing robustness in low-power networks.
• Fraunhofer IIS filed a German patent in 2013 and subsequently a U.S. patent in 2014 for methods based on that research.
• The trademark MIOTY was registered by Fraunhofer IIS in 2015. In 2024, the mioty Alliance registered mioty.
• In June 2018, ETSI published the first complete specification of the TS-UNB protocol as TS 103 357, formalizing the technology underlying mioty.
• In November 2019, the mioty Alliance e.V. was formed by founding members including Fraunhofer IIS, Texas Instruments, Diehl Metering, Diehl Connectivity Solutions, ifm, Ragsol, Stackforce, and WIKA. The Alliance publicly launched in February 2020 at Embedded World in Nuremberg, with the objective of promoting an open, interoperable ecosystem for mioty in IoT applications. By mid-2022, it had grown to 10 full members and 25 associate members.
• In April 2020, Sisvel announced that it would manage a patent-pool for mioty, offering manufacturers a centralized licensing source for mioty-related patents.
• In June 2024, ETSI released TS 103 357-2, a major revision of the TS-UNB standard that further refines the Low Throughput Network protocol used by mioty.

Technology attributes

• Long range: The operating range of LPWAN technology varies from a few kilometers in urban areas to over 10 km in rural settings. It can also enable effective data communication in previously infeasible indoor and underground locations.
• Low power: Optimized for power consumption, LPWAN transceivers can run on small, inexpensive batteries for up to 20 years.
• Telegram splitting: Splits the packets of data under transport in small sub-packets at the sensor level. The small packets getting then transmitted over variable frequency and time.
• More than a million packets a day.
• Serving moving clients. It can serve data from clients moving at up to 120 km/h.

mioty physical layer (PHY)

mioty MAC and higher layers

• Addressing and authentication: devices are identified with persistent EUI-64 identifiers; the MAC carries compact address hints and authentication tags so that base stations can resolve device IDs and verify message integrity on partial receptions.
• Network and application security: the stack defines network-level encryption and supports application-level end-to-end encryption, with key management performed via the network service centre.
• Acknowledgements and retransmissions: the MAC supports acknowledgement strategies and retransmission management that leverage the PHY’s FEC and sub-packet diversity; because the PHY can reconstruct messages from partial receptions, the MAC may avoid unnecessary retransmissions in many collision or interference cases.
• Timing and duty-cycle compliance: uplink transmissions are asynchronous but the service-center and base station coordinate downlinks and duty-cycle budgets to comply with regional regulations; the MAC tracks timestamps and assigns downlink windows approximately seconds after an uplink reception to ensure correct delivery and regulatory compliance.
• Logical Link Control : a separate LLC layer handles attachment/detachment, over-the-air management, and service-center interactions for device provisioning and de-duplication of messages received by multiple base stations.
• Comparative behaviour versus other LPWAN MACs: unlike some LPWAN protocols whose MAC layer provides adaptive data-rate or tight channel coordination, many of mioty’s capacity and reliability properties stem from the telegram-splitting PHY rather than from heavy MAC-layer channel arbitration. This design favours massive concurrent access and interference resilience in dense sensor deployments.
• Performance, capacity and mobility: mioty documentation gives numerical performance examples. These figures are presented as examples in the Fraunhofer/mioty technical documents and ETSI TS-UNB profiles and depend on message size, duty-cycle limits and regional regulations.
• Standards and ecosystem: the TS-UNB protocol and telegram-splitting concept are formalised in ETSI TS 103 357 and the updated TS 103 357-2; the mioty Alliance publishes the public technical documents that describe PHY, MAC and higher layers and acts as an industry forum to promote interoperability and ecosystem adoption.

Applications

• Safety-critical monitoring, such as lone-worker protection, emergency alert systems or underground industrial environments, where robust uplink delivery is required even under harsh radio conditions.
• Utility metering, including water, gas and heat meters, as well as smart-city networked meters. Many deployments use mioty due to its long-range coverage and low power requirements.
• Industrial monitoring, such as vibration sensing, power monitoring, and factory automation in RF-challenging environments.
• Integration with metering standards, particularly through the inclusion of the mioty PHY in the OMS 5 LPWAN specification via "OMS Splitting Mode", enabling interoperable smart-metering solutions.
• Industrial communication systems, supported by collaboration agreements with automation consortia such as the IO-Link Community, enabling the use of mioty as a wireless transport layer in Industry 4.0 systems.
• Asset tracking and positioning in large industrial areas, ports or airports. mioty can support hybrid positioning methods, combining GNSS with TSMA-based link metrics, which provide additional ranging information from the telegram-splitting process.
• Smart-city and smart-building infrastructure, including environmental monitoring, leakage detection, fire protection and air-quality sensing.
• Hybrid LPWAN deployments, where cities or utilities combine mioty with LoRaWAN to leverage both ecosystems. Hybrid gateways and dual-technology LPWAN products are commercially available to support these deployments.