1. | EXECUTIVE SUMMARY |
1.1. | Current status of 5G |
1.2. | 5G network deployment strategy |
1.3. | 5G commercial/pre-commercial services by frequency (2021) |
1.4. | Summary of 5G status and roadmap in 5 key regions (U.S., China, Japan, South Korea, and Europe) |
1.5. | 5G standalone (SA) vs non-standalone (NSA) rollout update (2021) |
1.6. | The main technique innovations in 5G |
1.7. | 5G base station design trend |
1.8. | 5G base station types: macro cells and small cells |
1.9. | Competition landscape for key 5G infrastructure/system vendors |
1.10. | Current status of Open RAN global deployment |
1.11. | Open RAN disruption in the market? |
1.12. | Are legacy 5G system vendors embracing Open RAN? |
1.13. | The business model of Open RAN |
1.14. | 5G mmWave commercial/pre-commercial services (mid 2021) |
1.15. | List of telecom carriers and selected vendors for the installation of 5G mmWave base stations |
1.16. | Four main pain points in mmWave industry (1 - Talents) |
1.17. | Four main pain points in mmWave industry (2.1 - Cost) |
1.18. | Four main pain points in mmWave industry (2.2 - Cost) |
1.19. | Four main pain points in mmWave industry (3.1 - Power) |
1.20. | Four main pain points in mmWave industry (3.2 - Power) |
1.21. | Four main pain points in mmWave industry (4 - Customizability) |
1.22. | Five forces analysis of the 5G mmWave base station market |
1.23. | Overview of challenges, trends and innovations for mmWave 5G devices |
1.24. | Benchmark of commercialised low-loss organic laminates |
1.25. | Key semiconductor properties |
1.26. | Power amplifier technology benchmark |
1.27. | Benchmarking different filter technology for 5G |
1.28. | Five forces analysis of the 5G mmWave RF module market |
1.29. | Key Buying Factors (KBF) of 5G mmWave antennas. What are the changes in KBF between sub-6 GHz and mmWave antenna? |
1.30. | 5G mmWave phased array antenna start-ups on the rise |
1.31. | mmWave phased array antenna module key items and ecosystem |
1.32. | Landscape of key chipset players involved in the telecom/mobile industry |
1.33. | System on chip (SoC) for 5G handsets global market share |
1.34. | 5G applications overview |
1.35. | 5G private industrial network deployment on the rise |
1.36. | Detailed Comparison of Wi-Fi and Cellular based V2X communications |
1.37. | Value chain of chipset industry |
1.38. | Landscape of C-V2X supply chain |
1.39. | 5G market forecast for mobile services 2018-2032 |
1.40. | 5G mid-band macro base station number forecast (2019-2032) by region (Cumulative - 1) |
1.41. | 5G mmWave street macro base station number forecast (2019-2032) by region (Cumulative - 1) |
1.42. | 5G small cells number forecast (2019-2032) (cumulative - 1) |
2. | INTRODUCTION TO 5G |
2.1. | Evolution of mobile communications |
2.2. | 5G commercial/pre-commercial services (Jun 2021) |
2.3. | 5G, next generation cellular communications network |
2.4. | 5G standardization roadmap |
2.5. | Global snapshot of allocated/targeted 5G spectrum |
2.6. | Two types of 5G: sub-6 GHz and mmWave |
2.7. | Spectrum Strategy for Foundation Network: the Role of Low Band Spectrum in 5G |
2.8. | 5G network deployment strategy |
2.9. | Low, mid-band 5G is often the operator's first choice to provide 5G national coverage |
2.10. | Approaches to overcome the challenges of 5G limited coverage |
2.11. | Frequency duplex division (FDD) vs. Time duplex division (TDD) |
2.12. | 5G commercial/pre-commercial services by frequency |
2.13. | 5G mmWave commercial/pre-commercial services (mid 2021) |
2.14. | 5G deployment: standalone (SA) vs non-standalone (NSA) |
2.15. | 5G transition from NSA mode to SA mode |
2.16. | Technical comparison of NSA and SA 5G |
2.17. | Economic comparison of NSA and SA 5G |
2.18. | Different deployment types in the same network |
2.19. | 5G standalone (SA) vs non-standalone (NSA) rollout update |
2.20. | The main technique innovations in 5G |
2.21. | 3 types of 5G services |
2.22. | 5G for mobile consumers market overview |
2.23. | 5G for industries overview |
2.24. | 5G investments at three stages |
2.25. | 5G supply chain overview |
2.26. | Summary: Global trends and new opportunities in 5G |
3. | 5G ROADMAP AND OUTLOOK: ANALYSIS OF 5 KEY REGIONS |
3.1.1. | 5G roadmap and outlook: analysis of 5 key regions (the U.S., China, Japan, South Korea, and Europe) |
3.2. | United States of America |
3.2.1. | U.S 5G national strategy |
3.2.2. | Overview of U.S. telecom operators' financial and network deployment status (mid-2021) |
3.2.3. | U.S. 5G spectrum update (mid-2021) |
3.2.4. | U.S. 5G mid band rollout roadmap |
3.2.5. | U.S. telecom operator: T-Mobile's revenue & expenditure |
3.2.6. | U.S. telecom operator: T-Mobile 5G status & strategy |
3.2.7. | U.S. telecom operator: AT&T - world's top telecom operator: revenue & expenditure |
3.2.8. | U.S. telecom operator: AT&T - 5G status & strategy |
3.2.9. | U.S. telecom operator: AT&T - 5G applications |
3.2.10. | U.S. telecom operator: Verizon - world's second telecom operator: revenue & expenditure |
3.2.11. | U.S. telecom operator: Verizon - 5G status & strategy |
3.2.12. | U.S. base stations - historical trend |
3.3. | China |
3.3.1. | China 5G environment, rollout status, and future outlook |
3.3.2. | China 2G - 5G Technology trend |
3.3.3. | China 5G spectrum at a glance |
3.3.4. | Is the 6 GHz band the future of 5G? |
3.3.5. | China 5G telecom operators performance |
3.3.6. | China 5G investment volume from three major operators |
3.3.7. | Case study: expected 5G investment for infrastructure in China |
3.3.8. | 5G "key performance indicator (KPI) " and roadmap in China |
3.3.9. | 5G private network development focus in China |
3.3.10. | Key 5G vertical applications identified by Chinese government |
3.3.11. | Demonstrations of 5G verticals by Chinese telecom operators |
3.3.12. | Impact of US-China trade war on 5G |
3.3.13. | 5G wrestle between China and the West |
3.3.14. | How did the 5G battle between China and the U.S. start? |
3.3.15. | Washington's strategy to combat China |
3.3.16. | How has the situation evolved? |
3.3.17. | Political, Economic, Socio-Cultural, and Technological analysis on the U.S. and China 5G environment |
3.3.18. | 5G commercial deals by 5G key system vendors (2019-Q2 2021) |
3.3.19. | 5G infrastructure market share by key vendors |
3.3.20. | China 5G base station bid result (2021) |
3.3.21. | Huawei: Banned and permitted in which countries? (Updated Jun. 2021) |
3.3.22. | Huawei's performance in the last fiscal year (2020) |
3.3.23. | Huawei's strategy to survive - will it survive? |
3.3.24. | Ericsson's performance in the last fiscal year (2020) |
3.4. | Japan |
3.4.1. | Japan base stations - historical trend |
3.4.2. | Japan 5G NR spectrum at a glance |
3.4.3. | Japan 5G spectrum in use |
3.4.4. | Japan 5G environment, rollout status, and future outlook |
3.4.5. | NTT DOCOMO 5G rollout plan |
3.4.6. | NTT DOCOMO 5G solutions |
3.4.7. | SoftBank 5G rollout plan |
3.4.8. | SoftBank 5G development |
3.4.9. | SoftBank 5G solution case study |
3.4.10. | KDDI 5G rollout plan |
3.4.11. | KDDI 5G solution outlook |
3.5. | South Korea |
3.5.1. | South Korea 5G environment, rollout status, and future outlook |
3.5.2. | South Korea 5G NR spectrum at a glance |
3.5.3. | 5G growth in South Korea |
3.5.4. | Key 5G industries identified by the South Korean government |
3.5.5. | Key 5G B2B business in development by the South Korean telecom operators |
3.6. | Europe |
3.6.1. | 5G rollout status in EU |
3.6.2. | 5G spectrum released status in EU |
3.6.3. | 5G vertical trials in EU by segments |
3.6.4. | EU public funding for Digitalization |
3.6.5. | Financial overview of 4 key EU telecom operators |
3.6.6. | Deutsche Telekom: 5G commercial rollout Overview |
3.6.7. | Deutsche Telekom: 5G commercial rollout in Germany |
3.6.8. | Deutsche Telekom - Financial status |
3.6.9. | Deutsche Telekom - 5G strategy |
3.6.10. | Vodafone: 5G Overview |
3.6.11. | Vodafone: 5G commercial rollout status |
3.6.12. | Vodafone: Enterprise 5G rollout |
3.6.13. | Telefónica: 5G commercial rollout overview |
3.6.14. | Orange: 5G Overview |
3.6.15. | Orange deploying 5G networks for various enterprise |
3.6.16. | Orange: 5G status and strategy |
3.6.17. | Summary of 5G status and roadmap in 5 key regions (U.S., China, Japan, South Korea, and Europe) |
4. | OVERVIEW OF 5G INFRASTRUCTURE |
4.1. | From 1G to 5G: the evolution of cellular network infrastructure |
4.2. | Architecture of macro base stations |
4.3. | Key challenges for 5G macro base stations |
4.4. | 5G base station design trend |
4.5. | 5G base station types: macro cells and small cells |
4.6. | Drivers for Ultra Dense Network (UDN) Deployment in 5G |
4.7. | Challenges for ultra dense network deployment |
4.8. | 5G small cells will see a rapid growth |
4.9. | 5G infrastructure: Huawei, Ericsson, Nokia, ZTE, Samsung and others |
4.10. | Competition landscape for key 5G infrastructure vendors |
5. | 5G OPEN RAN |
5.1.1. | Why Open RAN becomes so important in 5G |
5.1.2. | Why Open RAN is getting more and more attention? |
5.2. | Open RAN introduction |
5.2.1. | 5G network architecture: virtualized and disaggregated base stations |
5.2.2. | Why splitting the baseband unit (BBU) is necessary in 5G |
5.2.3. | High and Low layer split of the 5G network |
5.2.4. | More functional splits to support diverse 5G use cases |
5.2.5. | Evolution of RAN functional split |
5.2.6. | Pros and Cons of RAN functional splits |
5.2.7. | Trade offs for Different functional splits |
5.3. | Open RAN technology insights |
5.3.1. | What is Open Radio Access Network (Open RAN)? |
5.3.2. | The benefits and challenges of radio access networks (RAN) decomposition and disaggregation |
5.3.3. | Traditional RAN vs Open RAN |
5.3.4. | Open interface is key - but what is it? |
5.3.5. | Evolution of Open RAN functional split |
5.3.6. | Open RAN functional split: Split 6 or Split 7.2x ? |
5.3.7. | Open RAN case study - the world's largest Open RAN deployment |
5.3.8. | Open RAN case study - 5G Open RAN + private network for logistics use cases |
5.3.9. | Open RAN case study: 5G emergency services networks |
5.4. | Open RAN market insights |
5.4.1. | Open RAN global deployment at a glance |
5.4.2. | Open RAN disruption in the market? |
5.4.3. | Four major challenges of Open RAN |
5.4.4. | Are legacy 5G system vendors embracing Open RAN? |
5.4.5. | Open RAN hardware commoditization risk? |
5.4.6. | How much does an Open RAN base station cost compared to a legacy one? |
5.4.7. | The business model of Open RAN |
5.4.8. | Open RAN hardware suppliers |
5.4.9. | O-RAN Alliance operators |
5.4.10. | Open RAN deployment schedule - Will Open RAN establish itself first in the private network or in the macro network? |
5.4.11. | Open RAN status update (2021) |
5.4.12. | Open RAN key takeaways |
6. | OVERVIEW OF 5G CORE AND RADIO TECHNOLOGY INNOVATIONS |
6.1.1. | End-to-end technology overview |
6.2. | 5G core network technologies |
6.2.1. | 5G core network technologies |
6.2.2. | Comparison of 4G core and 5G core |
6.2.3. | Service based architecture (SBA) |
6.2.4. | Mobile Edge Computing (MEC) |
6.2.5. | End-to-end Network Slicing |
6.2.6. | Spectrum sharing |
6.2.7. | Why does 5G have lower latency radio transmissions |
6.2.8. | 5G new radio technologies |
6.3. | 5G new radio technologies |
6.3.1. | New multiple access methods: Non-orthogonal multiple-access techniques (NOMA) |
6.3.2. | Advanced waveforms and channel coding |
6.3.3. | Comparison of Turbo, LDPC and Polar code |
6.3.4. | High frequency communication: mmWave |
6.3.5. | Massive MIMO (mMIMO) |
6.3.6. | Massive MIMO enables advanced beam forming |
7. | 5G MASSIVE MIMO ACTIVE ANTENNA |
7.1. | Massive MIMO requires active antennas |
7.2. | Trends in 5G antennas: active antennas and massive MIMO |
7.3. | Antenna array architectures for beamforming |
7.4. | Structure of massive MIMO (mMIMO) system |
7.5. | Advantages of Massive MIMO |
7.6. | Samsung and Nokia sub-6 ghz mMIMO antenna teardown |
7.7. | Top 5G system venders are vertically integrated with antenna capabilities |
7.8. | Case study: Nokia AirScale mMIMO Adaptive Antenna |
7.9. | Case study: Ericsson 2G - 5G Hybrid Antenna |
7.10. | Key challenges for massive MIMO deployment |
7.11. | Challenges of implementing massive MIMO in frequencies way above 6 GHz |
8. | 5G MMWAVE INDUSTRY ANALYSIS |
8.1. | List of telecom carriers and selected vendors for the installation of 5G mmWave base stations |
8.2. | Challenges to overcome before we see notable adoption of mmWave |
8.3. | Four main pain points in mmWave industry (1 - Talents) |
8.4. | Four main pain points in mmWave industry (2.1 - Cost) |
8.5. | Four main pain points in mmWave industry (2.2 - Cost) |
8.6. | Four main pain points in mmWave industry (3.1 - Power) |
8.7. | Four main pain points in mmWave industry (3.2 - Power) |
8.8. | Four main pain points in mmWave industry (4 - Customizability) |
8.9. | Five forces analysis of the 5G mmWave base station market |
9. | 5G MMWAVE DEVICE CHALLENGES |
9.1.1. | Overview of challenges, trends and innovations for mmWave 5G devices |
9.2. | Low-loss materials for 5G |
9.2.1. | Overview of the high level requirements for high frequency operation |
9.2.2. | Overview of the low-loss materials |
9.2.3. | Where low-loss materials will be used: beam forming system in base station |
9.2.4. | Where low-loss material will be used: substrate of mmWave antenna module for smartphone |
9.2.5. | Where low-loss material will be used: multiple parts inside packages |
9.2.6. | Low-loss materials can also be used in radome cover or molding housing |
9.2.7. | Five important metrics for substrate materials will impact materials selection |
9.2.8. | Dielectric constant: benchmarking different substrate technologies |
9.2.9. | Loss tangent: benchmarking different substrate technologies |
9.2.10. | Benchmark of commercialised low-loss organic laminates |
9.2.11. | More info about 5G Low Loss Materials |
9.3. | mmWave 5G Power amplifiers |
9.3.1. | The choice of the semiconductor technology for power amplifiers |
9.3.2. | Key semiconductor properties |
9.3.3. | Power vs frequency map of power amplifier technologies |
9.3.4. | Pros and Cons of GaN |
9.3.5. | GaN to win in sub-6 GHz 5G (for macro and microcell (> 5W)) |
9.3.6. | GaN-on-Si, SiC or Diamond for RF |
9.3.7. | Power amplifier technology benchmark |
9.3.8. | Suppliers of RF GaN based power amplifiers |
9.3.9. | Suppliers of RF power amplifiers utilized in small cells |
9.3.10. | Semiconductor choices for power amplifiers in mmWave module |
9.4. | 5G filter technologies |
9.4.1. | Challenges for mmWave base stations |
9.4.2. | Filter requirements for mmWave base stations |
9.4.3. | Which filter technologies will work for mmWave 5G? |
9.4.4. | SAW and BAW filters are not suitable for mmWave 5G |
9.4.5. | Overview of transmission lines filters for 5G mmWave |
9.4.6. | Transmission lines filter (1): Substrate integrated waveguide filters (SIW) |
9.4.7. | Transmission lines filter (2.1): Single-layer transmission-line filters on PCB |
9.4.8. | Transmission lines filter (2.2): Single-layer transmission-line filters on ceramic |
9.4.9. | Transmission lines filter (2.3): Other substrate options: thin or thick film and glass |
9.4.10. | Transmission lines filter (3): Multilayer low temperature co-fired ceramic (LTCC) filters |
9.4.11. | Multilayer LTCC: production challenge |
9.4.12. | Examples of multilayer LTCC from key suppliers (1) |
9.4.13. | Examples of multilayer LTCC from key suppliers (2) |
9.4.14. | Benchmarking different filter technology for 5G |
9.4.15. | Benchmarking different transmission lines filters (1) |
9.4.16. | Benchmarking different transmission lines filters (2) |
9.4.17. | Benchmarking different transmission lines filters (3) |
9.4.18. | Radio frequency (RF) Front-end module |
9.5. | Radio frequency front end module (RF FEM) |
9.5.1. | Density of components in RFFE |
9.5.2. | RF module design architecture |
9.5.3. | RF FEM suppliers for LTE-advanced smartphone |
9.5.4. | mmWave radio frequency front end (RFFE) module suppliers |
9.5.5. | Qualcomm 5G NR Modem-to-Antenna module |
9.5.6. | Tear down of a mmWave Customer Enterprise Equipment (CPE) |
9.6. | RF frontend components in 5G mmWave base stations |
9.6.1. | Hybrid beamforming system for mmWave base stations |
9.6.2. | mmWave bits to mmWave radio system |
9.6.3. | mmWave RF beamformer (beamforming integrated circuit (BFIC)) |
9.6.4. | mmWave BFIC suppliers for 5G infrastructures |
9.6.5. | 5G mmWave RF modules supply chain dynamics |
9.6.6. | Five forces analysis of the 5G mmWave RF module market |
9.7. | mmWave phased array antenna module suppliers and supply chain dynamics |
9.7.1. | Demonstrations of 28GHz all-silicon 64 dual polarized antenna |
9.7.2. | Tear down of a mmWave femtocell |
9.7.3. | Tear down of a mmWave mobile station from Samsung |
9.7.4. | Tier 1 5G system vendors are vertically integrated with antenna capabilities |
9.7.5. | Intension of Ericsson acquired Kathrein antenna R&D department |
9.7.6. | 5G mmWave phased array antenna start-ups on the rise |
9.7.7. | mmWave phased array antenna module key items and ecosystem |
9.7.8. | Partnership between mmWave antenna suppliers and RF module suppliers |
9.7.9. | The likelihood for tier 1 system vendors to develop their own phased array antenna modules |
9.7.10. | Key Buying Factors (KBF) of 5G mmWave antennas: what are the changes in KBF between sub-6 GHz and mmWave antenna? |
10. | SI CHIPSET MARKET |
10.1. | Landscape of key chipset players involved in the telecom/mobile industry |
10.2. | System on Chip (SoC) |
10.3. | Value chain of chipset industry |
10.4. | Key chipset players involved in the telecom infrastructure |
10.5. | The intentions of 5G system vendors enter Si battleground |
10.6. | Key chipset players involve in the mobile SoC/Modem |
10.7. | System on chip (SoC) for 5G handsets global market share |
10.8. | Key chipset players involve in the key components related to wireless technology |
10.9. | Mobile RF frontend supply chain |
11. | INK-BASED EMI SHIELDING |
11.1. | What is electromagnetic interference shielding and why it matters to 5G |
11.2. | Components that require EMI shielding |
11.3. | Two types of EMI shielding |
11.4. | Challenges and key trends for EMI shielding for 5G devices |
11.5. | Package-level EMI shielding |
11.6. | Examples of package-level shielding in smartphones |
11.7. | Conformal coating: increasingly popular |
11.8. | Overview of conformal shielding technologies |
11.9. | Key suppliers and the technologies they utilized for EMI shielding |
11.10. | Suppliers targeting ink-based conformal EMI shielding |
11.11. | Compartmentalization of complex packages is also a key trend |
12. | 5G THERMAL MANAGEMENT |
12.1. | Thermal interface materials (TIM) |
12.1.1. | Thermal Interface Materials (TIM) Considerations |
12.1.2. | Properties of Thermal Interface Materials |
12.1.3. | TIM Suppliers Targeting 5G Applications |
12.2. | Thermal management for 5G infrastructure |
12.2.1. | Power Consumption in 5G |
12.2.2. | Thermal considerations for cell towers and base stations |
12.2.3. | Thermal considerations for small cells |
12.2.4. | Thermal management for antennas (1) |
12.2.5. | Thermal management for antennas (2) |
12.2.6. | TIM for 5G equipment example: Samsung 5G Access Point |
12.2.7. | TIM for 5G equipment example: Samsung Indoor CPE Unit |
12.2.8. | TIM Properties and Players for 5G Infrastructure |
12.3. | Thermal management for smart phones |
12.3.1. | Thermal management for smartphone: typical path for heat |
12.3.2. | Thermal management for smartphone: thermal throttling |
12.3.3. | Thermal management for smartphone: Materials selection |
12.3.4. | Thermal management for smartphone: Heat dissipation |
12.3.5. | Smartphone cooling now and in the future |
12.3.6. | Smartphone thermal material estimate summary |
12.3.7. | More info about 5G Thermal Management |
13. | 5G APPLICATIONS |
13.1.1. | 5G applications overview |
13.2. | 5G for consumers |
13.2.1. | Three primary 5G use cases for consumers |
13.2.2. | What's the purpose of Fixed Wireless Access (FWA)? |
13.2.3. | 5G for home: fixed wireless access (FWA) |
13.2.4. | Countries contributions in enabling 5G FWA market |
13.2.5. | 5G Customer Premise Equipment (CPE) |
13.2.6. | 5G CPE devices vendor landscape |
13.2.7. | 5G for XR (AR and VR) and gaming |
13.2.8. | 5G user equipment player landscape |
13.3. | 5G for Industry 4.0 |
13.3.1. | Three reasons why 5G networks enable connected industries and automation |
13.3.2. | 5G IoT and Private Networks for Industry 4.0 |
13.3.3. | 5G smart manufacturing overview |
13.3.4. | Updating existing industrial networks with wireless 5G in factories |
13.3.5. | Connectivity requirement of key Industry 4.0 use cases |
13.3.6. | 5G private industrial network deployment on the rise |
13.3.7. | 5G private network for Industry 4.0 case study: World's first mmWave smart factory in ASE group in Taiwan |
13.3.8. | 5G private network for Industry 4.0 case study: World's first mmWave smart factory in ASE group in Taiwan |
13.4. | NB-IoT and LTE-M |
13.4.1. | 5G incorporates NB-IoT and LTE-M |
13.4.2. | NB-IoT, eMTC and 5G will cover different aspects |
13.4.3. | Global deployment of NB-IoT and LTE-M |
13.4.4. | LTE-M vs NB-IoT |
13.4.5. | NB-IoT is a better solution for LPWAN |
13.4.6. | NB-IoT driven by the Chinese market |
13.4.7. | Low Band Coverage Boosts Development of VoLTE and NB-IoT (China Telecom) |
13.4.8. | Opportunities of Low Band Spectrum in 10 Vertical Industries identified by China Telecom |
13.4.9. | Hurdles to NB-IoT rollout |
13.4.10. | NB-IoT and LTE-M key players |
13.5. | 5G for autonomous driving and C-V2X |
13.5.1. | Vehicle-to-everything (V2X) |
13.5.2. | Two types of V2X technology: Wi-Fi vs cellular |
13.5.3. | Detailed Comparison of Wi-Fi and Cellular based V2X communications |
13.5.4. | Regulatory: Wi-Fi based vs C-V2X |
13.5.5. | Use cases and applications of C-V2X overview |
13.5.6. | C-V2X for automated driving use case |
13.5.7. | C-V2X includes two parts: via base station or direct communication |
13.5.8. | Evolution of C-V2X direct communication to 5G NR |
13.5.9. | Timeline for the deployment of C-V2X |
13.5.10. | C-V2X demonstrations from key players (1) |
13.5.11. | C-V2X demonstrations from key players (2) |
13.5.12. | C-V2X design and development challenges |
13.5.13. | Landscape of C-V2X supply chain |
13.6. | 5G mobile-enabled drones |
13.6.1. | Future Opportunities for 5G Mobile-Enabled Drones - 1 |
14. | 5G MARKET FORECAST BY SERVICES |
14.1.1. | Overview of the 5G forecast |
14.2. | 5G forecast by services |
14.2.1. | Forecast methodology for 5G services forecast |
14.2.2. | Mobile subscriptions historical trend |
14.2.3. | 5G market forecast for mobile services 2018-2032 |
14.2.4. | 5G mobile subscription forecast by regions 2018-2032 |
14.2.5. | Global smartphone shipment (2018-2021) by vendors |
14.2.6. | 5G mobile shipment units 2018-2032 |
14.2.7. | Fixed wireless access service revenue forecast 2018-2032 |
14.2.8. | Shipment of customer promised equipment (CPE) forecast by units 2018-2032 |
14.3. | 5G forecast by infrastructure |
14.3.1. | Forecast methodology |
14.3.2. | 5G mid-band macro base station number forecast (2019-2032) by region (Cumulative - 1) |
14.3.3. | 5G mid-band macro base station number forecast (2019-2032) by region (Cumulative - 2) |
14.3.4. | 5G mid-band macro base station number forecast (2019-2032) by region (New installation - 1) |
14.3.5. | 5G mid-band macro base station number forecast (2019-2032) by region (New installation - 2) |
14.3.6. | 5G mmWave street macro base station number forecast (2019-2032) by region (Cumulative - 1) |
14.3.7. | 5G mmWave macro base station number forecast (2019-2032) by region (Cumulative - 1) |
14.3.8. | 5G mmWave macro base station number forecast (2019-2032) by region (New installation - 1) |
14.3.9. | 5G mmWave macro base station number forecast (2019-2032) by region (New installation - 2) |
14.3.10. | 5G small cells number forecast (2019-2032) (cumulative - 1) |
14.3.11. | 5G small cells number forecast (2019-2032) (cumulative - 2) |
14.3.12. | 5G small cells will see a rapid growth |
14.4. | 5G forecast by infrastructure components and materials |
14.4.1. | Power amplifier and beamforming component forecast (2020 - 2032) |
14.4.2. | MIMO size forecast (2020-2032) |
14.4.3. | Antenna elements forecast (2020-2032) |
14.4.4. | Components forecast number (2020-2032) |
15. | COMPANY PROFILES |
15.1. | Links to 17 IDTechEx Portal Profiles |