CONTENTS - Report ITU-R BT.2386-4 (03/2023) - Digital terrestrial broadcasting: Design and implementation of single frequency networks (SFN)

Report ITU-R BT.2386-4
Policy on Intellectual Property Right (IPR)
Part 1� Overview of single frequency networks
�1�� Definition and characteristics of single frequency networks
�� 1.1�� Definition of single frequency networks
�� 1.2�� Benefits of single frequency networks
�� 1.3�� Requirements and limitations of single frequency networks
�� 1.4�� Type of SFN
�� 1.5�� Consideration of network structures for SFN
�� 1.6�� Classification of transmitting stations
�� 1.7�� Spectrum utilization
�2�� Coverage criteria
�� 2.1�� Reception modes
�� 2.2�� Pixel coverage, area coverage, population coverage
�� 2.3�� Full area vs. partial coverage
�3�� Statistical aspects and Network Gain in SFN planning
�� 3.1�� Statistical Aspects of Coverage Prediction
�� 3.2�� Effect of OFDM Multipath Capability on Coverage Prediction
�� 3.3�� Network Gain
�� 3.3.1�� General
�� 3.3.2�� Definitions related to network gain
�� 3.3.3�� Example of network gain
�� 3.3.4�� Network gain and coverage measurements in SFN
�4�� Layer definition
�5�� Broadcasters� requirements
�� 5.1�� Service area requirements
�� 5.2�� Coverage requirements
�� 5.3�� Operational/Network requirements
�6�� Implementation of the transmitter network
�� 6.1�� Coordination
�� 6.2�� Conformity with the Plan Entry
�� 6.3�� Self interference
�� 6.4�� Transmitter synchronisation
�� 6.5�� Frequency synchronisation
�� 6.6�� Timing synchronisation
�� 6.7�� Effect of synchronisation loss
Part 2� SFN application and implementation of DVB-T, DVB-T2, ATSC 3.0� and DAB system
�1�� Multipath capability of DVB‑T, DVB‑T2, ATSC 3.0 and DAB
�� 1.1�� General
�� 1.2�� Inter‑symbol interference
�� 1.3�� Guard interval
�� 1.4�� Contributing and interfering signal components with inter‑symbol interference
�2�� FFT‑window synchronisation
�� 2.1�� General
�� 2.2�� Synchronisation strategies
�� 2.3�� Strongest signal
�� 2.4�� First signal above a threshold level
�� 2.5�� Centre of gravity
�� 2.6�� Quasi‑optimal
�� 2.7�� Maximum C/I
�3�� Site selection and management
�4�� Coverage and interference management
�� 4.1�� General
�� 4.2�� Wanted coverage prediction
�� 4.3�� Out‑going interference management
�� 4.3.1�� General
�� 4.3.2�� Calculation of out‑going DAB interference
�� 4.3.3�� Calculation of out‑going DVB‑T/DVB-T2 and ATSC 3.0 interference
�5�� Post implementation of the network
�� 5.1�� Network coverage and improvement
�� 5.2�� Network problems
�6�� Impact of DVB‑T parameters on SFN performance
�� 6.1�� Constellation
�� 6.2�� Code rate
�� 6.3�� 2k/8k FFT
�� 6.4�� Guard interval
�� 6.5�� Data rate versus guard interval
�7�� Impact of ATSC 3.0 parameters on SFN performance
�� 7.1�� Constellation
�� 7.2�� Code rate
�� 7.3�� 8k/16k/32k FFT
�� 7.4�� Guard interval
�� 7.5�� Data rate versus guard interval
�� 7.6�� Robust co-channel interference tolerance
�8�� Distribution networks for SFNs
�9�� DVB-T case studies
�� 9.1�� National DVB-T SFN deployment in Italy
�� 9.1.1�� Example of a very large SFN: RAI multiplex A
�� 9.1.2�� Operating the network
�� 9.1.3�� SFN and propagation phenomena on the warm sea
�� 9.1.4�� SFN and propagation phenomena on the ground
�� 9.1.5�� SFN and reflection/scattering phenomena
�� 9.1.6�� Optimization of SFN � DFREE experience
�� 9.1.7�� Parameters details
�� 9.1.8�� Final technical considerations on SFN design
�� 9.1.9�� Examples of 1-SFN
�� 9.1.10�� Special applications for SFN
10�� Overview
11�� Spectral efficiency and spectrum consumption of DVB-T2 networks
�� 11.1�� Spectral efficiency and spectrum consumption
�� 11.2�� Spectral efficiency of DVB-T2
� ��11.3�� Layer spectrum efficiency of DVB-T2
�� 11.4�� Re-use distances for DVB-T2 networks
12�� DVB‑T2 Lite
13�� DVB-T2 and DVB-T2 Lite case studies
�� 13.1�� Theoretical study on maximum achievable data rates for large DVB T2 SFN areas
�� 13.1.1�� Introduction
�� 13.1.2� ��Planning parameters and network structure
�� 13.1.3�� DVB‑T2 modes
�� 13.1.4�� Maximum data rate to cover large areas with DVB‑T2 theoretical SFNs for mobile, portable and fixed reception
�� 13.1.5�� Minimum required guard interval for various inter‑site distances and C/N values
�� 13.1.6�� Summary and conclusions
�� 13.2�� DVB-T2 and DVB-T2 Lite: Experimental tests in Italy (Aosta Valley)
DVB-T2 Base
DVB-T2 Lite
�� 13.3�� Case study on large DVB-T2 SFN in Denmark
�� 13.3.1�� Introduction
�� 13.3.2�� Loss of capacity in an SFN
�� 13.3.3�� Size of SFN
�� 13.3.4�� Limitation in local/regional programming
�� 13.3.5�� Large (national) SFN, example of Denmark
�� 13.3.6�� How do spectrum requirements change with larger SFNs?
�� 13.4�� Case study on DVB-T2 service areas in Sweden
�� 13.4.1�� Introduction
�� 13.4.2�� Parameters
�� 13.4.3�� Network planning
�� 13.4.4�� Population coverage calculation
�� 13.4.5�� Discussion
�� 13.4.6�� Conclusions
�� 13.5�� Practical DVB-T2 based scenarios exploring the interdependence of coverage, capacity, transmission mode and network configuration
�� 12.5.1�� Methodology
�� 13.5.2�� Results
�� 13.6�� Case study on DVB-T2 MFN vs. SFN in the UK
�� 13.6.1�� Introduction
�� 13.6.2�� Background
�� 13.6.3�� Discussion
�� 13.6.4�� Summary
�� 13.7�� DVB-T/DVB-T2 planning exercise with limited spectrum resources in the UK
�� 13.8�� Effect of sea path propagation � An example in the UK
�� 13.8.1�� Optimising the guard interval in a national SFN
�� 13.8.2�� Results and analysis
�� 13.8.3�� Summary
�� 13.9�� Optimisation of a DVB‑T2 SFN in Malaysia
�� 13.10�� DVB-T2 SFNs Networks and an Extended T2-MIP: a BBC study
14�� Impact of DAB parameters on SFN performance
�� 14.1�� General
�� 14.2�� Constellation
�� 14.3�� Code rate
�� 14.4�� FFT
�� 14.5�� Guard interval
�� 14.6�� Data rate versus guard interval
15�� DAB case studies
�� 15.1�� Italy implementation
�� 15.1.1�� DAB SFNs in Trentino Alto Adige region
�� 15.1.2�� Tests on DAB receivers
�� 15.2�� Static timing in the UK DAB network
�� 15.3�� Static timing in the Bavarian DAB+ network
Part 3� SFN application and implementation of ISDB system
�1�� Principle of SFN reception
�2�� Case study for Japan
�3�� Design of SFN
�� 3.1�� Site location
�� 3.2�� Effective radiation power
�� 3.3�� Antenna radiation pattern
�� 3.4�� Transmission timing adjustment
�� 3.5�� Tools for network design
Part 4� SFN application and implementation of DTMB system
�1�� Overview
�2�� Case study for DTMB
�� 2.1�� Local area SFN
�� 2.1.1�� Deployment of DTMB in Single Frequency Network of Hong Kong
Annex A� SFN Transmitting Stations completed by the end of 2009
Annex B
Annex C
Annex D
Annex E� Location of the Digital Terrestrial Television (DTT) stations� and the estimated coverage (January 2011)
�� 2.1.2�� Deployment of DTMB SFN in Shanghai
�� 2.2�� Deployment of DTMB SFN based on satellite program distribution networks
�� 2.2.1�� System structure
�� 2.2.2�� Satellite distribution networks
�� 2.2.3�� SFN adapter
�� 2.2.4�� Laboratory and field tests
�� 2.2.5�� Conclusion
�� 2.3�� Synchronization scheme of DTMB SFN using IEEE1588v2 standard and time of days
�� 2.3.1�� Introduction
�� 2.3.2�� General
�� 2.3.3�� System structure
�� 2.3.4�� Time distribution network
�� 2.3.5�� SFN adapter
�� 2.3.6�� Lab test
�� 2.3.7�� Field test
�� 2.3.8�� Conclusion
�� 2.4�� Large area single frequency network optimization method
�� 2.4.1�� Overview
�� 2.4.2�� Single frequency network optimization
�� 2.4.3�� Field trial verification
�� 2.4.4�� Conclusion
Part 5� SFN application and implementation of DTMB-A system
�1�� SFN Field trial for DTMB-A
�� 1.1�� Background
�� 1.2�� Field trial structurer
�� 1.3�� Field trial result
�� 1.4�� Conclusions