Enabling Next-Generation Public Safety Operations with Mission-Critical Networks and Wearable Applications †
Abstract
:1. Introduction
- Identifying the solutions introduced by the 3rd Generation Partnership Project (3GPP) for the support of public safety communications. We review the identified solutions as enablers of cellular-based public safety networks, also referred to as next-generation public safety networks [4]. As part of this technology review, we track the enhancements of the identified technologies through the different 3GPP releases.
- Expanding and better illustrating the examples of IoLST use cases where cellular-enabled wearables can be employed.
- Complementing the latency evaluation in wearable-based MCPTT private and group calls with reliability results. We discuss the obtained results and shed light on the need for latency and reliability trade-off mechanisms in MCPTT applications.
- Providing standardization-related insights and future considerations for better support of the requirements of wearable-based MCPTT services in next-generation public safety networks.
2. Related Work
3. Toward Next-Generation Public Safety Networks
3.1. Public-Safety-Targeted Technologies
3.2. Additional Enabling Technologies
4. Wearable Technology in Next-Generation Public Safety Networks
5. Latency and Reliability Performance Evaluation in Wearable-Based MCPTT Applications
5.1. Evaluation Methodology and Parameters
5.2. Performance Evaluation Results
5.3. Future Considerations
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Technology | 3GPP Release | Brief Description |
---|---|---|
GCSE | Rel-12 | Mechanisms enabling both unicast and multicast transmissions for group communications |
ProSe | Rel-12 | Architecture and radio interface for the support of D2D communications |
IOPS | Rel-13 | Isolated mode of operation that ensures communications between users via base stations without backhaul links |
MCPTT | Rel-13 | Delivering voice services for public safety users |
MCData | Rel-14 | Delivering non-real-time data services for public safety users |
MCVideo | Rel-14 | Delivering real-time video services for public safety users |
Technology | 3GPP Releases | Main Improvements |
---|---|---|
ProSe | Rel-13–Rel-16 | ProSe discovery and direct communication features in EPS, UE-to-network relaying for IoT and wearables |
Rel-17 | Support of NR ProSe communications and UE-to-network relay over 5G networks | |
MCX | Rel-14 | User authentication, service authorization, media and control signaling encryption |
Rel-15 | Support of MBMS, interworking with LMR systems, and interconnection between cellular mission-critical systems | |
Rel-16–Rel-17 | Enhanced procedures and information flows in on-network and off-network architectures, identification of further requirements of MCX services |
Wearable Device-Related Parameters | Value |
UE category | LTE Cat M2 |
Max. bandwidth | 5 MHz |
Max. UL/DL modulation order | 4 (16-QAM) |
UE transmission mode | 1 (1 Tx/Rx antenna) |
UE power class | 5 |
UE transmit power | 20 dBm |
UE noise figure | 9 dB |
D2D-Related Parameters | Value |
Sidelink transmission mode | Mode-2 (autonomous) |
Sidelink MCS | 10 |
Sidelink allocation size | 5 RBs |
kTRP | 1 |
PSCCH period | 40 ms |
PSCCH/PSSCH ratio | 1/3, 1, 3 |
MCPTT Application-Related Parameters | Value |
Functional mode | Off-network |
Types of calls | private and basic group calls |
Message size | 60 bytes |
Inter-packet interval | 20 ms |
Device Capability | LTE Cat M2 | NR RedCap |
---|---|---|
Max. bandwidth | 5 MHz | 20 MHz |
Max. UL modulation order | 4 (16QAM) | 4 (16QAM) |
Max. DL modulation order | 4 (16QAM) | 6 (64QAM) |
UE transmission mode | 1 (1 Tx/Rx antenna) | 1 (1 Tx/Rx antenna) |
UE power class | 5 | 3 |
UE transmit power | 20 dBm | 23 dBm |
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Saafi, S.; Hosek, J.; Kolackova, A. Enabling Next-Generation Public Safety Operations with Mission-Critical Networks and Wearable Applications. Sensors 2021, 21, 5790. https://doi.org/10.3390/s21175790
Saafi S, Hosek J, Kolackova A. Enabling Next-Generation Public Safety Operations with Mission-Critical Networks and Wearable Applications. Sensors. 2021; 21(17):5790. https://doi.org/10.3390/s21175790
Chicago/Turabian StyleSaafi, Salwa, Jiri Hosek, and Aneta Kolackova. 2021. "Enabling Next-Generation Public Safety Operations with Mission-Critical Networks and Wearable Applications" Sensors 21, no. 17: 5790. https://doi.org/10.3390/s21175790
APA StyleSaafi, S., Hosek, J., & Kolackova, A. (2021). Enabling Next-Generation Public Safety Operations with Mission-Critical Networks and Wearable Applications. Sensors, 21(17), 5790. https://doi.org/10.3390/s21175790