Fabricio Lira Figueiredo Coordinator of Pre-Standards Commission at 5G Brasil
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5G Pre-Standards Committee
Project: 5G Brasil
Research and Use Cases Committee
Pre-Standard Committee
Vertical Regulatory Actions Committee
Backhaul Infrastructure Committee
Future Frequency Band Committee
Trials Committee
TELEBRASIL BOARD
5G BRASIL PROJECT Executive Board
SECRETARY
5G Pre-Standards Committee
Goal is to prioritize 5G pre-standards and contributing for 5G standardization process,
aiming at supporting relevant requirements for Brazilian market and society
Coordination:
Action Plan
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5G Pre-Standards Committee
1. 5G Pre-Standards Prospection
2. Definition of Criteria for Pre-Standards Selection and Prioritization
3. Evaluation of 3GPP activities related to the high priority requirements for Brazilian market,
and opportunities for contribution
4. Defining collaboration and contribution actions for 3GPP, ITU and IEEE
5G 3GPP Requirements
3GPP, 5G PPP, IEEE
Key Contribution Topics for 5G Brasil Project
Urban Mobility
3 of 50 cities with the worst traffic in the world are in Brazil!
Traffic management Public transportation optimization Collaborative transportation
Demands and Requirements for 5G in Brazil
Apresentador
Notas de apresentação
GFDM Asynchronous burst transmissions. Block based structure. Can be set to mimic CP-OFDM. Proved support for High-order modulation (HOM) and Tactile Internet. In contrast to CP-OFDM, it can benefit from transmitting multiple symbols per sub-carrier. Reduced OOB emissions due to adjustable pulse shaping filters. Relax the current requisites of oscillator accuracy of 0.1 ppm in LTE up to 10-100 times (1-10 ppm). Dismisses complex synchronization procedures and reduces signaling overhead, i.e., of simpler transmitters. Allows equalization in the frequency domain. Favorable to short burst applications. Contributes to reduce the power consumption of the terminals. UFMC Differently from CP-OFDM, which applies filtering on the whole band, UFMC applies filtering on a per resource block basis. Higher spectral efficiency and robustness against time and frequency offsets when compared to CP-OFDM. In case of fragmented spectrum, UFMC supports non-contiguous sub-bands. Highly reduced OOB emissions. Short filter lengths, which implies in low latency. Reduced overhead. Improved MTC support. Very efficient to transmit both long sequences and short bursts/frames. FBMC Excellent frequency localization. CP can be removed and subcarriers can be better localized, thanks to more advanced prototype filter design. Instead of digitally filtering the complete band, the modulator includes a filtering functionality on a per subcarrier basis. FBMC does not employ a CP, which results in high time-frequency efficiency. FBMC is not orthogonal with respect to the complex plane. OQAM is used to attain orthogonality. Very efficient to transmit long sequences however it suffers to transmit short bursts/frames. BFDM Replaces orthogonality of the set of transmit and receive pulses by biorthogonality, which is a weaker form of orthogonality. Well suited to sporadic traffic, since the PRACH symbols are relatively long so that transmission is very robust. It is well suited to be used in the random access scenario (PRACH). Can exploit the capabilities of advanced sparsity-aware signal processing. Robust to frequency offsets in the transmission which, as well-known, typically sets a limit to the symbol duration in CP-OFDM transmission. Completely asynchronous users, with time offsets larger than the CP duration in standard PRACH can be far better supported. Excellent and controllable tradeoff between performance degradation due to time and frequency offsets. Leads to a slightly reduced interference in PUSCH when using (previously unused) guard bands for data transmission. DFT-s-OFDM Replaces the CP with a set of very low power samples (zero-tail). Zero-tail can be set according to the estimated delay spread of the channel without compromising symbol length. Preserves the orthogonality of the data subcarriers at the receiver. Low implementation complexity (approximately the same when compared to a LTE transceiver). Significantly lower OOB emissions than CP-OFDM. Lower PAPR than CP-OFDM. Enables coexistence among systems designed for different environments (e.g., indoor/outdoor).
Energy Efficiency
Public street lighting consumes about 4% of all electrical energy in Brazil!
Increasing street lighting efficiency Large scale energy metering and automation Distributed energy generation
Demands and Requirements for 5G in Brazil
Apresentador
Notas de apresentação
GFDM Asynchronous burst transmissions. Block based structure. Can be set to mimic CP-OFDM. Proved support for High-order modulation (HOM) and Tactile Internet. In contrast to CP-OFDM, it can benefit from transmitting multiple symbols per sub-carrier. Reduced OOB emissions due to adjustable pulse shaping filters. Relax the current requisites of oscillator accuracy of 0.1 ppm in LTE up to 10-100 times (1-10 ppm). Dismisses complex synchronization procedures and reduces signaling overhead, i.e., of simpler transmitters. Allows equalization in the frequency domain. Favorable to short burst applications. Contributes to reduce the power consumption of the terminals. UFMC Differently from CP-OFDM, which applies filtering on the whole band, UFMC applies filtering on a per resource block basis. Higher spectral efficiency and robustness against time and frequency offsets when compared to CP-OFDM. In case of fragmented spectrum, UFMC supports non-contiguous sub-bands. Highly reduced OOB emissions. Short filter lengths, which implies in low latency. Reduced overhead. Improved MTC support. Very efficient to transmit both long sequences and short bursts/frames. FBMC Excellent frequency localization. CP can be removed and subcarriers can be better localized, thanks to more advanced prototype filter design. Instead of digitally filtering the complete band, the modulator includes a filtering functionality on a per subcarrier basis. FBMC does not employ a CP, which results in high time-frequency efficiency. FBMC is not orthogonal with respect to the complex plane. OQAM is used to attain orthogonality. Very efficient to transmit long sequences however it suffers to transmit short bursts/frames. BFDM Replaces orthogonality of the set of transmit and receive pulses by biorthogonality, which is a weaker form of orthogonality. Well suited to sporadic traffic, since the PRACH symbols are relatively long so that transmission is very robust. It is well suited to be used in the random access scenario (PRACH). Can exploit the capabilities of advanced sparsity-aware signal processing. Robust to frequency offsets in the transmission which, as well-known, typically sets a limit to the symbol duration in CP-OFDM transmission. Completely asynchronous users, with time offsets larger than the CP duration in standard PRACH can be far better supported. Excellent and controllable tradeoff between performance degradation due to time and frequency offsets. Leads to a slightly reduced interference in PUSCH when using (previously unused) guard bands for data transmission. DFT-s-OFDM Replaces the CP with a set of very low power samples (zero-tail). Zero-tail can be set according to the estimated delay spread of the channel without compromising symbol length. Preserves the orthogonality of the data subcarriers at the receiver. Low implementation complexity (approximately the same when compared to a LTE transceiver). Significantly lower OOB emissions than CP-OFDM. Lower PAPR than CP-OFDM. Enables coexistence among systems designed for different environments (e.g., indoor/outdoor).
Public Health
We have about 1.9 physicians per inhabitant in Brazil (OECD: 3.2)!
Remote patient monitoring Emergency services optimization Minimizing timing for assistance
Demands and Requirements for 5G in Brazil
Apresentador
Notas de apresentação
GFDM Asynchronous burst transmissions. Block based structure. Can be set to mimic CP-OFDM. Proved support for High-order modulation (HOM) and Tactile Internet. In contrast to CP-OFDM, it can benefit from transmitting multiple symbols per sub-carrier. Reduced OOB emissions due to adjustable pulse shaping filters. Relax the current requisites of oscillator accuracy of 0.1 ppm in LTE up to 10-100 times (1-10 ppm). Dismisses complex synchronization procedures and reduces signaling overhead, i.e., of simpler transmitters. Allows equalization in the frequency domain. Favorable to short burst applications. Contributes to reduce the power consumption of the terminals. UFMC Differently from CP-OFDM, which applies filtering on the whole band, UFMC applies filtering on a per resource block basis. Higher spectral efficiency and robustness against time and frequency offsets when compared to CP-OFDM. In case of fragmented spectrum, UFMC supports non-contiguous sub-bands. Highly reduced OOB emissions. Short filter lengths, which implies in low latency. Reduced overhead. Improved MTC support. Very efficient to transmit both long sequences and short bursts/frames. FBMC Excellent frequency localization. CP can be removed and subcarriers can be better localized, thanks to more advanced prototype filter design. Instead of digitally filtering the complete band, the modulator includes a filtering functionality on a per subcarrier basis. FBMC does not employ a CP, which results in high time-frequency efficiency. FBMC is not orthogonal with respect to the complex plane. OQAM is used to attain orthogonality. Very efficient to transmit long sequences however it suffers to transmit short bursts/frames. BFDM Replaces orthogonality of the set of transmit and receive pulses by biorthogonality, which is a weaker form of orthogonality. Well suited to sporadic traffic, since the PRACH symbols are relatively long so that transmission is very robust. It is well suited to be used in the random access scenario (PRACH). Can exploit the capabilities of advanced sparsity-aware signal processing. Robust to frequency offsets in the transmission which, as well-known, typically sets a limit to the symbol duration in CP-OFDM transmission. Completely asynchronous users, with time offsets larger than the CP duration in standard PRACH can be far better supported. Excellent and controllable tradeoff between performance degradation due to time and frequency offsets. Leads to a slightly reduced interference in PUSCH when using (previously unused) guard bands for data transmission. DFT-s-OFDM Replaces the CP with a set of very low power samples (zero-tail). Zero-tail can be set according to the estimated delay spread of the channel without compromising symbol length. Preserves the orthogonality of the data subcarriers at the receiver. Low implementation complexity (approximately the same when compared to a LTE transceiver). Significantly lower OOB emissions than CP-OFDM. Lower PAPR than CP-OFDM. Enables coexistence among systems designed for different environments (e.g., indoor/outdoor).
Rural Connectivity
Área de cobertura das redes celulares esperada para 2019 Círculos vermelhos indicam cobertura das estações rádio base
Área coberta esperada
FONTE: Apresentação do Ministério das Comunicações, realizada no evento LTE450 Global Seminar, em junho de 2014
Demands and Requirements for 5G in Brazil
São Paulo
Area: 248.209 km² Population: 44 Millions 20.961 BSs BS density 50 times higher than Mato Grosso! Source: Telebrasil, June/17
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5G Requirements for Brazilian Market
Rural Scenarios • Wide coverage • Transmission rates • Flexible architecture • High energy efficiency • Multiservice and Network Slicing • High precision location
• Flexible mobility profiles • High energy efficiency • Multi-RAT connectivity • Lean network entry for IoT devices • High capacity and throughput • Low latency
Urban Scenarios
Relevance for Brazilian Market Use Cases
o Health, Rural, Smart Cities, Utilities, Logistics, Transportations
X
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Key Contribution Topics for 5G Brasil Project
Work/Study Item Group Release Requirement Use Cases
New Radio Access Technology Air Interface R15 High Data Rates andTraffic Densities, Resource Efficiency, Low latency and reliability
Transportation / Smart Cities / Rural / Health / Utilities
Enhancing LTE CA Utilization Air Interface R15 High Data Rates and Traffic Densities Transportation / Smart Cities / Rural / Health / Utilities
5G System - Phase 1 Air Interface R15 High Data Rates andTraffic Densities, Resource Efficiency, Low latency and reliability
Transportation / Smart Cities / Rural / Health / Utilities
LTE Advanced high power TDD UE (power class 2) for Rel-15
Air Interface R15 Energy Efficiency Rural / Energy Efficiency / Transportation / Health
Study on using Satellite Access in 5G Air Interface R16 Multiple Access Technologies Transportation / Rural / Health / UtilitiesStudy on NR to support non-terrestrial networks
Air Interface R15 Multiple Access Technologies Transportation / Smart Cities / Rural / Health / Utilities
EPC enhancements to support 5G New Radio via Dual Connectivity
Architecture R15 Connectivity Models Smart Cities / Health / Utilities
Study on the Wireless and Wireline Convergence for the 5G system architecture
Architecture R15 Diverse Mobility Management Smart Cities / Health / Utilities
Study on system and functional aspects of Energy Efficiency in 5G networks Architecture R15 Energy Efficiency, Resource Efficiency
Transportation / Smart Cities / Rural / Health / Utilities
Study on architecture enhancements for 3GPP support of advanced V2X services Architecture R15 Low latency and reliability Transportation / Smart Cities / Rural
Study on QoE metrics for VR Architecture R15 Priority, QoS and Policy Control Smart Cities / HealthStudy on network policy management for mobile networks based on NFV scenarios
Architecture R15 Priority, QoS and Policy ControlTransportation / Smart Cities / Rural / Health / Utilities
Study on 5G message service for MIoT Services R16 Efficient User Plane Transportation / Smart Cities / Rural / Health / Utilities
Study on positioning use cases Services R16 Higher-accuracy positioning Transportation / Smart Cities / RuralStudy on Maritime Communication Services over 3GPP system
Services R16 Low latency and reliability Transportation
Terrestrial-Satellite Architectures for 5G
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Major Goals o Review and analysis of the satellite connection to service the 5G networks within the
context emerging technologies: SDN, NFV, CDN, ICN, and IDN. o Study of terrestrial-satellite interoperability to service the 5G networks within the
context of: (i) emerging techs; (ii) content distribution in multicast networks; (iii) aeronautical and maritime applications.
o Contributing to 3GPP standardization process to include satellite links in all aspects.
Preliminary Results o 5G to be built from terrestrial-satellite convergence, rather than separate networks. o 5G standardization should contemplate hybrid architecture. o Interoperability and integration of satellite links to 5G is a key requirement, with no
mooring or patching.
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Final Considerations
• 5G Brasil Project has achieved relevant results for 5G networks to attend most relevant use cases for Brazilian market and society.
• Pre-Standards Committee has evaluated, prioritized and analyzed 3GPP work and study items for attending such Brazilian use cases.
• Key potential contribution topics by 5G Brasil Project have been identified, based on the Pre-Standards Committee Action Plan.
• Hybrid terrestrial-satellite interoperability to be ensured in 5G network architecture.