White Paper on Critical and Massive Machine Type Communication towards 6G
By 2030, our societies will become digitalized and data-driven, supported by key verticals like connected industries, intelligent transport systems, smart cities, etc. Machine Type Communication (MTC) encompassing its massive and critical aspects, and near instant unlimited wireless connectivity are among the main enablers of such digitalization at large.
The recently introduced 5G New Radio is the first wireless standard natively designed to support both aspects of MTC. However, it is evident that some of the more demanding requirements cannot be fully supported by 5G networks. Alongside, further development of the society towards 2030 will give rise to new and more stringent requirements on wireless connectivity in general, and MTC in particular.
The next generation wireless network, namely 6G, should therefore be an agile and efficient convergent network designed to meet the diverse and challenging requirements imposed by the societal trends towards 2030.
This white paper explores the main drivers and requirements of an MTC-optimized 6G network, and presents a set of research directions for different aspects of MTC that can be synthesized through the following six key research questions:
- Will the main performance indicators of 5G, namely reliability-latency-scalability, continue to dominate in 6G; or will emerging metrics such as energy-efficiency, end-to-end (E2E) performance measures and sensing become more important?
- How can different E2E service mandates with different KPI requirements be delivered through a multi-disciplinary approach jointly considering optimization at the physical up to the application layer?
- What are the key enablers towards designing ultra-low power receivers and highly efficient sleep modes to support ultra-low-cost ultra-low-power or even passive MTC devices?
- How can a disruptive rather than incremental joint design of a massively scalable waveform and medium access policy be tackled to efficiently support global connectivity for MTC?
- How can new service classes characterizing mission-critical and dependable MTC in 6G be supported through multifaceted connectivity and non-cellular centric wireless solutions?
- What are the potential enablers of long-term secure schemes considering the heterogeneous requirements and capabilities of MTC devices? How can lightweight and flexible usable ways of handling privacy and trust be designed in MTC by combining the user perspective with the technical perspective?
This white paper has been written by an international expert group, led by the Finnish 6G Flagship program at the University of Oulu, within a series of twelve 6G white papers published in their final format in 2020.
Read the Full Paper in Jultika
- We present the main drivers, potential use cases, key requirements and new service classes pertinent to MTC in 6G networks.
- We provide a bird’s eye view of a holistic end-to-end MTC Network Architecture.
- We discuss the challenges and potential 6G enablers of ultra-low power, massive and critical MTC.
- We touch upon privacy, security and trust concerns in an MTC optimized 6G network.
Watch the webinar
List of Contributors
- Nurul H. Mahmood, University of Oulu, Finland
- Onel Lopez, University of Oulu, Finland
- Ok-Sun Park, ETRI, South Korea
- Ingrid Moerman, imec – Ghent University, Belgium
- Konstantin Mikhaylov, University of Oulu, Finland
- Eric Mercier, CEA-Leti, France
- Andrea Munari, German Aerospace Center (DLR), Germany
- Federico Clazzer, German Aerospace Center (DLR), Germany
- Stefan Böcker, TU Dortmund, Germany
- Hannes Bartz, German Aerospace Center (DLR), Germany
- Riku Jäntti, Aalto University, Finland
- Ravikumar Pragada, InterDigital, USA
- Yihua Ma, ZTE, China
- Elina Annanperä, University of Oulu, Finland
- Christian Wietfeld, TU Dortmund, Germany
- Martin Andraud, Aalto University, Finland
- Gianluigi Liva, German Aerospace Center (DLR), Germany
- Yan Chen, Huawei Technologies, Canada
- Eduardo Garro, Universitat Politècnica de València, Spain
- Frank Burkhardt, Fraunhofer IIS, Germany
- Hirley Alves, University of Oulu, Finland
- Chen-Feng Liu, University of Oulu, Finland
- Yalcin Sadi, Kadir Has University, Turkey
- Jean-Baptiste Dore, CEA-Leti, France
- Eunah Kim, ETRI, South Korea
- JaeSheung Shin, ETRI, South Korea
- Gi-Yoon Park, ETRI, South Korea
- Seok-Ki Kim, ETRI, South Korea
- Chanho Yoon, ETRI, South Korea
- Khoirul Anwar, Telkom University, Indonesia
- Pertti Seppänen, University of Oulu, Finland