6G will arrive in 2028 at the earliest.
6G Market 2023-2043: Technology, Trends, Forecasts, Players
6G, sub-THz, 6G technology benchmarking, Non-Terrestrial Networks (NTN), LEO, Reconfigurable Intelligent Surface (RIS), cell-free massive MIMO, THz components, low-loss materials, packaging, heterogeneous integration, player landscape
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5G mmWave is yet to take off, however, the 6G research already started long ago. But what is 6G exactly?
The frequency matters
Let's start from the most basic level - the frequency band. In 5G, we know that the sub-6 GHz (3.5-6 GHz) and millimetre wave (mmWave, 24-100 GHz) bands are the two new bands among the spectrum covered. In 6G, the frequency ranges under consideration include 7 to 20 GHz frequency band, W-band (above 75-110 GHz), D-band (110 GHz to 175 GHz), bands between 275 GHz and 300 GHz, and in the THz range (0.3-10 THz). The bands between 7 and 20 GHz are taken into consideration because of the need for coverage that will enable mobile and "on the go" applications for numerous 6G use cases. The W and D bands are of interest for both 6G access and Xhaul (e.g. fronthaul, backhaul) networks. A solution that meets the objectives of both services is to be considered. As of September 2022, worldwide spectrum allocations do not go beyond 275 GHz; nevertheless, frequency bands in the range 275-450 GHz have been identified for the implementation of land mobile and fixed service applications, as well as radio astronomy and Earth exploration-satellite service, and space research service in the range 275-1,000 GHz.
An overview of 6G spectrum deployment strategy is shown in the figure below. Note that even though by definition the THz band runs from 300 GHz to 10 THz, telecom professionals have found it simpler to classify beyond-100 GHz applications as THz communications.
Source: "6G Market 2023 - 2043: Technology, Trends, Forecasts, Players " from IDTechEx
What does 6G promise and what are the challenges?
By exploiting the large bandwidth in THz frequency band, 6G is expected to enable 1 Tbps data rate. However, this rate is very challenging to achieve as a large continuous bandwidth is required but in reality, bandwidths that are available for use are limited and split over different bands. Another aspect is that spectral efficiency makes a direct trade-off with the required Signal to Noise Ratio (SNR) for detection. The higher the required SNR, the shorter the respective range becomes due to transmitted power limitations at high frequencies as well as added noise. As an example, Samsung's state-of-the-art D-band phase array transmitter prototype currently demonstrates the furthest travel distance of 120m but only achieving 2.3 Gbps. Other groups show higher data rate, but the over-the-air travel distance is only at centimetre level.
To further improve link range as well as enhance data rate, several requirements are needed to be considered when designing a 6G radio. For example, selecting appropriate semiconductors to boost link range is critical; as is picking low-loss materials with a small dielectric constant and tan loss to prevent substantial transmission loss. To further reduce transmission loss, a new packaging strategy that tightly integrates RF components with antennas is required. However, one must remember that as devices get increasingly compact, power and thermal management become even more critical.
In addition to device design, network deployment strategy is also a crucial area to research in order to address NLOS and power consumption challenges. Establishing a heterogeneous smart electromagnetic (EM) environment, for example, is being investigated utilising a wide range of technologies, such as reconfigurable intelligent surfaces (RIS) or repeaters.
6G applications
One significant change of 6G to previous communication generations is that it will now include non-terrestrial networks, which is a key development that enables conventional 2D network architectures to function in 3D space. Low Altitude Platforms (LAPs), High Altitude Platforms (HAPs), Unmanned Aerial Vehicles (UAVs), and satellites are examples of non-terrestrial networks (NTNs). We saw China send the world's first 6G satellite in November 2020. In 2022, Huawei tested the NTN 6G networks using LEO (Low Earth Orbit) satellites. More and more activities in this area show that NTN networks will be a key development trend.
Communications aside, 6G is expected to tap into the world of sensing, imaging, wireless cognition, and precise positioning. In 2021, Apple patented its THz sensor technology for gas sensing and imaging in iDevice. Huawei also tested several Integrated Sensing and Communication (ISAC) prototypes. Many more studies and trials are underway to fully leverage the potential of 6G THz frequency bands.
To learn more about 6G's technology, applications, market, please read IDTechEx's 6G market research report. "6G Market 2023-2043: Technology, Trends, Forecasts, Players". This 6G report is built on our expertise, covering the latest 6G technology development trends, key applications, player activities, and market outlook, aiming to provide the reader with a comprehensive understanding of 6G technology and market.
Key aspects in the report:
This report includes a comprehensive review of the technology, players, use case studies, and market for 6G.
1. 6G development and activities,
a. by five key regions (US, EU, China, Japan, South Korea
b. by key players (Ericsson, Nokia, Samsung, Huawei, Apple, NTT DOCOMO)
2. 6G Technology trends
a. 6G Radio system analysis
b. 6G Power consumption analysis
c. Semiconductor technologies for THz communication:
i. Si-based semiconductor (CMOS, SOI, SiGe),
ii. GaAs and GaN,
iii. InP
d. Phase array module design for 6G
e. Examples of state-of-the-art D-band (110 - 175 GHz) phase array modules
f. Packaging trend for 6G
g. Low-loss materials for mmWave and THz
h. Metamaterials
3. Network deployment strategy
a. Cell-free massive MIMO
b. Reconfigurable intelligent surfaces (RIS)
c. Non-terrestrial networks (NTN)
4. 6G use cases beyond mobile communication
a. Sensing
b. Imaging
c. Wireless cognition
5. Market Forecasts:
a. 6G base stations.
b. 5G base stations segmented by frequency (sub-6 vs mmWave)
c. Reconfigurable intelligent surfaces (RIS) forecast, segmented by three types of RIS (Active RIS, Semi-passive RIS, and Passive RIS)
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Further information
If you have any questions about this report, please do not hesitate to contact our report team at research@IDTechEx.com or call one of our sales managers:
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| 1. | EXECUTIVE SUMMARY |
| 1.1. | 6G spectrum and network deployment strategy |
| 1.2. | 6G performance with respect to 5G |
| 1.3. | Global 6G government-aided initiatives - an overview |
| 1.4. | Summary of key 6G activities and future roadmap |
| 1.5. | DoCoMo, NTT sign 6G pact with Fujitsu, NEC, Nokia |
| 1.6. | Overview of key technologies that enable THz communication |
| 1.7. | Challenges regarding semiconductor for THz communications |
| 1.8. | Overview of Si vs III-V semiconductors for 6G |
| 1.9. | Overview of transistor performance metrics of different semiconductor technologies |
| 1.10. | Overview of semiconductor technology choice for THz RF |
| 1.11. | Power amplifier benchmark in beyond 200 GHz frequency band |
| 1.12. | State-of-the-art InP power amplifiers - the performance and the players |
| 1.13. | Three approaches to integrate InP on CMOS to make a >100 GHz beamforming transmitter |
| 1.14. | Summary table of key THz Technologies |
| 1.15. | Technology benchmark of phase antenna array in 28, 90, and 140 GHz. |
| 1.16. | 140 GHz THz prototype from Samsung and UCSB - IC and antenna fabrication details |
| 1.17. | D-Band (110 to 175 Hz) Phased-Array-on-Glass Modules from Nokia |
| 1.18. | Building a 140 GHz phase antenna array - what are the key factors? |
| 1.19. | An example of antenna processing unit designed for cell-free mMIMO |
| 1.20. | IDTechEx outlook of low-loss materials for 6G |
| 1.21. | Phased-array antenna module design trend for 6G |
| 1.22. | Benchmark of different types of non-terrestrial (NTN) technologies |
| 1.23. | Huawei test non-terrestrial 6G networking using LEO satellites |
| 1.24. | Metamaterials for RIS in telecommunication |
| 1.25. | 6G - an overview of key applications |
| 1.26. | Apple's patents on THz sensor for gas sensing and imaging |
| 1.27. | Integrated Sensing and Communication (ISAC) prototype from Huawei |
| 1.28. | 6G base stations market forecast |
| 1.29. | 5G base stations market forecast |
| 1.30. | Reconfigurable intelligent surfaces in telecommunications: Forecasts segments |
| 1.31. | Summary: Global trends and new opportunities in 6G |
| 2. | 6G INTRODUCTION |
| 2.1. | The evolution of mobile communications |
| 2.2. | Evolving mobile communication focus |
| 2.3. | 6G visions |
| 2.4. | 5G&6G development and standardization roadmap |
| 2.5. | 6G spectrum - which bands are considered? |
| 2.6. | Bands vs Bandwidth |
| 2.7. | Spectrum characteristics from 2G to 6G |
| 2.8. | 6G spectrum and network deployment strategy |
| 2.9. | 6G performance with respect to 5G |
| 2.10. | Beyond 5G Wireless - the pros and the cons |
| 2.11. | 6G - an overview of key applications |
| 2.12. | An overview of potential 6G services |
| 2.13. | 6G - Overview of key enabling technologies (1) |
| 2.14. | 6G - Overview of key enabling technologies (2) |
| 2.15. | Evolution of hardware components from 5G to 6G: technology benchmark of different communication frequencies |
| 2.16. | Summary: Global trends and new opportunities in 6G |
| 2.17. | DoCoMo, NTT sign 6G pact with Fujitsu, NEC, Nokia |
| 2.18. | Fujitsu teams with NTT and Docomo for 6G trials |
| 3. | 6G DEVELOPMENT ROADMAP IN 5 KEY REGIONS (CHINA, US, EU, JAPAN, AND SOUTH KOREA) |
| 3.1. | Global 6G government-aided initiatives - an overview |
| 3.2. | 6G development roadmap - South Korea |
| 3.3. | 6G development roadmap - Japan |
| 3.4. | 6G development roadmap - China |
| 3.5. | 6G development roadmap - EU |
| 3.6. | 6G development roadmap - US |
| 3.7. | Funding models to research the next mobile communication infrastructure |
| 4. | 6G INDUSTRY KEY ACTIVITIES/KEY ANNOUNCEMENT |
| 4.1. | Nokia's 6G activity |
| 4.2. | Ericsson's 6G activity (1) |
| 4.3. | Ericsson's 6G activity (2) |
| 4.4. | Huawei's 6G activity |
| 4.5. | Samsung's 6G activity |
| 4.6. | Samsung's strategy to 6G |
| 4.7. | DoCoMo, NTT sign 6G pact with Fujitsu, NEC, Nokia |
| 4.8. | Fujitsu teams with NTT and Docomo for 6G trials |
| 4.9. | Apple is planning ahead for 6G |
| 5. | 6G DEVICE TECHNOLOGY TREND |
| 5.1. | Overview of key technologies that enable THz communication |
| 6. | 6G RADIO SYSTEM ANALYSIS |
| 6.1. | Short and long term technical targets for 6G radio |
| 6.2. | Potential 6G transceiver architecture |
| 6.3. | Overview of key technical elements in 6G radio system |
| 6.4. | Bandwidth and Modulation |
| 6.5. | Bandwidth requirements for supporting 100 Gbps - 1 Tbps radios |
| 6.6. | Bandwidth and MIMO - challenges and solutions |
| 6.7. | Key parameters that affect the 6G radio's performance |
| 6.8. | Proof of concepts - achieving beyond 100 Gbps |
| 6.9. | Radio link range vs system gain |
| 6.10. | Hardware Gap |
| 6.11. | The biggest bottleneck in THz region |
| 6.12. | Saturated output power vs frequency (all semiconductor technologies) - 1 |
| 6.13. | Saturated output power vs frequency (all semiconductor technologies) - 1 |
| 6.14. | Receiver noise - hardware challenges |
| 6.15. | Choices of semiconductor for low noise amplifiers (LNA) in 6G |
| 6.16. | Phase noise - hardware challenges |
| 6.17. | Digital signal processing |
| 6.18. | Summary table of key THz Technologies |
| 6.19. | Summary table - key THz Characteristics |
| 7. | POWER CONSUMPTION ANALYSIS OF 6G RADIO |
| 7.1. | Building blocks for sub-THz radio |
| 7.2. | Power consumption calculation |
| 7.3. | Power consumption of PA scale with frequency |
| 7.4. | Higher frequency poses significant challenges in transmission distance |
| 7.5. | Power consumption in the transceiver side (1) |
| 7.6. | Power consumption in the transceiver side (2) |
| 7.7. | Power consumption in the receiver side |
| 7.8. | Summary (1) |
| 7.9. | Summary (2) |
| 8. | SEMICONDUCTORS FOR 6G |
| 8.1. | Introduction |
| 8.1.1. | What to consider when choosing semiconductor technologies for 6G applications |
| 8.1.2. | State of the art RF transistors performance |
| 8.2. | Si-based semiconductor: CMOS, SOI, SiGe |
| 8.2.1. | CMOS - the performance limitation |
| 8.2.2. | CMOS technology - Bulk vs SOI |
| 8.2.3. | State-of-the-art RF CMOS technology in research and industry |
| 8.2.4. | FDSOI Ecosystem - key players |
| 8.2.5. | Summary - RF CMOS SOI Technology |
| 8.2.6. | SiGe |
| 8.2.7. | State-of-the-art RF SiGe technology in research and industry (1) |
| 8.2.8. | Europe's effort in SiGe development |
| 8.2.9. | Infineon and STMicroelectronics approaches to next generation SiGe BiCMOS |
| 8.2.10. | Summary - RF SiGe technology |
| 8.3. | GaAs and GaN |
| 8.3.1. | Wide Bandgap Semiconductor Basics |
| 8.3.2. | GaN's opportunity in 6G |
| 8.3.3. | GaN-on-Si, SiC or Diamond for RF |
| 8.3.4. | GaN-on-Si power amplifier for 100 GHz? |
| 8.3.5. | State of the art GaN power amplifier |
| 8.3.6. | Summary of RF GaN Suppliers |
| 8.3.7. | RF GaN Fabrication Lines |
| 8.3.8. | GaAs's opportunity for 6G |
| 8.3.9. | State-of-the-art GaAs based amplifier |
| 8.3.10. | Summary of GaAs suppliers |
| 8.3.11. | GaAs vs GaN for RF Power Amplifiers |
| 8.3.12. | Power amplifier technology benchmark |
| 8.4. | InP |
| 8.4.1. | State-of-the-art InP technology |
| 8.4.2. | InP HEMT vs InP HBT |
| 8.4.3. | InP opportunities for 6G |
| 8.4.4. | Heterogenous integration of InP with SiGe BiCMOS |
| 8.4.5. | State-of-the-art InP power amplifiers - the performance and the players |
| 8.5. | Summary of semiconductors for THz communication |
| 8.5.1. | Overview of Si vs III-V semiconductors for 6G |
| 8.5.2. | Challenges regarding semiconductor for THz communications |
| 8.5.3. | Overview of transistor performance metrics of different semiconductor technologies |
| 8.5.4. | Power amplifier benchmark in beyond 200 GHz frequency band |
| 8.5.5. | Power amplifier benchmark in beyond 200 GHz frequency band (2) |
| 8.5.6. | Power amplifier technology benchmark in D band (110 GHz - 170 GHz) |
| 8.5.7. | Overview of semiconductor technology choice for THz RF |
| 8.5.8. | Summary |
| 9. | PHASE ARRAY ANTENNAS FOR 6G |
| 9.1. | Antenna types in 6G |
| 9.2. | Antenna approaches |
| 9.3. | Challenges in 6G antennas |
| 9.4. | Antenna gain vs number of arrays |
| 9.5. | Trade off between power and antenna array size |
| 9.6. | 5G phase array antenna |
| 9.7. | mmWave BFIC suppliers for 5G infrastructures |
| 9.8. | 6G 90 GHz phase array antenna - demonstration from Nokia |
| 9.9. | Technology benchmark of phase array in 28, 90, and 140 GHz. |
| 9.10. | 140 GHz phase array - transceiver analysis |
| 9.11. | 140 GHz phase array - the choice of semiconductor |
| 9.12. | Considerations when building a 140 GHz phase array |
| 10. | EXAMPLES OF STATE-OF-THE-ART D-BAND (110 - 175 GHZ) PHASE ARRAY MODULES |
| 10.1. | Samsung's latest THz prototyping wireless Platform with Adaptive Transmit and Receive Beamforming |
| 10.2. | 140 GHz THz prototype from Samsung - device architecture |
| 10.3. | 140 GHz THz prototype from Samsung and UCSB - IC and antenna fabrication details |
| 10.4. | UCSB 135 GHz MIMO hub transmitter array tile module |
| 10.5. | Mounting InP PA to the LTCC Carrier |
| 10.6. | Fully Integrated 2D Scalable TX/RX Chipset for D-Band (110 to 170GHz) Phased-Array-on-Glass Modules from Nokia |
| 10.7. | A proof-of-concept 130 GHz wireless 2x2 line-of-sight (LoS) MIMO - 1 |
| 10.8. | A proof-of-concept 130 GHz wireless 2x2 line-of-sight (LoS) MIMO - 2 |
| 10.9. | A 136-147 GHz Wafer-Scale Phased-Array Transmitter demo from UCSD - 1 |
| 10.10. | A 136-147 GHz Wafer-Scale Phased-Array Transmitter demo from UCSD - 2 |
| 10.11. | State-of-the-art D-band transmitters benchmark |
| 11. | PACKAGING TREND FOR 6G |
| 11.1. | Overview |
| 11.1.1. | Phased-array antenna module design trend for 6G generations |
| 11.1.2. | Three approaches to integrate InP on CMOS to make a >100 GHz beamforming transmitter |
| 11.1.3. | Trade-off among different integration technologies |
| 11.1.4. | Multiple transmitter coexistence for 5G and 6G RF FEM (from Skyworks Solutions) (1) |
| 11.1.5. | Multiple transmitter coexistence for 5G and 6G RF FEM (from Skyworks Solutions) (2) |
| 11.1.6. | Evolution of hardware components from 5G to 6G: antenna module design |
| 11.1.7. | Packaging challenges for freq. > 100 GHz base stations |
| 11.2. | Choices of antenna packages |
| 11.2.1. | High frequency integration and packaging trend |
| 11.2.2. | Example: Qualcomm mmWave antenna module |
| 11.2.3. | High frequency integration and packaging: Requirements and challenges |
| 11.2.4. | Three ways of mmWave antenna integration |
| 11.2.5. | Technology benchmark of antenna packaging technologies |
| 11.2.6. | AiP development trend |
| 11.2.7. | Two types of AiP structures |
| 11.2.8. | Two types of IC-embedded technology |
| 11.2.9. | Two types of IC-embedded technology - Players |
| 11.2.10. | Two types of IC-embedded technology - Players |
| 11.2.11. | University of Technology, Sydney: AME antennas in packages for 5G wireless devices |
| 11.2.12. | Additively manufactured antenna-in-package |
| 11.2.13. | Novel antenna-in-package (AiP) for mmWave systems |
| 11.2.14. | Design concept of AiP and its benefits (1) |
| 11.2.15. | Design concept of AiP and its benefits (2) |
| 11.2.16. | Stack-up AiP module on a system board |
| 11.2.17. | PCB embedding process for AiP |
| 11.2.18. | Section summary and remarks |
| 12. | LOW-LOSS MATERIALS FOR MMWAVE AND THZ |
| 12.1. | IDTechEx outlook of low-loss materials for 6G |
| 12.2. | Research approaches for 6G low-loss materials by material category |
| 12.3. | Thermoplastics for 6G: Georgia Tech |
| 12.4. | PTFE for 6G: Yonsei University, GIST |
| 12.5. | Thermosets for 6G: ITEQ Corporation, INAOE |
| 12.6. | PPE for 6G: Taiyo Ink, Georgia Institute of Technology |
| 12.7. | Silica for 6G: University of Oulu, University of Szeged |
| 12.8. | Glass for 6G: Georgia Tech |
| 12.9. | LTCC for 6G: Fraunhofer IKTS |
| 12.10. | Sustainable materials for 6G: University of Oulu |
| 12.11. | Metal interposers for 6G: Cubic-Nuvotronics |
| 12.12. | Roadmap development for low-loss materials for 6G |
| 12.13. | More info about 5G and 6G Low Loss Materials |
| 13. | 6G CELL-FREE MASSIVE MIMO |
| 13.1. | Considerations for 6G massive MIMO |
| 13.2. | Cell-free massive MIMO (Large-Scale Distributed MIMO) |
| 13.3. | Why cell-free mMIMO? |
| 13.4. | Benchmark of cellular mMIMO, network mMIMO, and cell-free mMIMO |
| 13.5. | Benefits and challenges of cell-free mMIMO implementation |
| 13.6. | An example of antenna processing unit designed for cell-free mMIMO |
| 14. | 6G NON-TERRESTRIAL NETWORKS (NTN): HAPS, LEO, GEO |
| 14.1. | 6G Non-Terrestrial networks (NTN) - An Overview |
| 14.2. | Benchmark of different types of NTN technologies |
| 14.3. | Features comparison: HAPS vs LEO vs GEO |
| 14.4. | Use cases of NTN |
| 14.5. | LEOS - Starlink |
| 14.6. | Airbus Zephyr HAPS |
| 14.7. | Apple spent $450M on SOS via LEO satellites from Globalstar for iPhone 14 models |
| 14.8. | China launches the "first 6G" test satellite into space |
| 14.9. | Huawei test non-terrestrial 6G networking using LEO satellites |
| 14.10. | South Korea's roadmap to launch LEO satellites |
| 14.11. | Overview of enabling technologies for non-terrestrial networks |
| 15. | HETEROGENEOUS SMART ELECTROMAGNETIC (EM) ENVIRONMENT |
| 15.1. | Heterogeneous smart electromagnetic (EM) environment |
| 15.2. | Overview of the main characteristics and parameters of smart EM devices |
| 16. | RECONFIGURABLE INTELLIGENT SURFACE (RIS) |
| 16.1. | Overview |
| 16.1.1. | Reconfigurable intelligent surface (RIS) for 6G |
| 16.1.2. | Reconfigurable intelligent surface (RIS) - an overview |
| 16.1.3. | RIS operation phases |
| 16.1.4. | Possible functionalities of RIS |
| 16.1.5. | Key drivers for reconfigurable intelligent surfaces |
| 16.1.6. | Challenges for fully functionalized RIS environments |
| 16.2. | Reconfigurable intelligent surface (RIS) - hardware |
| 16.2.1. | RIS Architecture |
| 16.2.2. | RIS vs traditional reflecting array antennas |
| 16.2.3. | Passive, semi-passive, and active RIS |
| 16.2.4. | Active, semi-passive, passive RIS - benchmark |
| 16.2.5. | RIS vs Relay |
| 16.2.6. | Technology benchmark of RIS with other smart EM devices |
| 16.3. | Reconfigurable intelligent surface (RIS) - applications |
| 16.3.1. | Where RIS can be used? |
| 16.3.2. | Typical RIS applications in wireless network |
| 16.3.3. | RISs can be applied in multiple locations |
| 16.3.4. | Examples of RIS prototypes |
| 16.3.5. | NANOWEB is an example of passive RIS |
| 16.3.6. | Major companies have shown interest in RIS |
| 16.3.7. | mmWave-based RIS technology for coverage challenge from ZTE |
| 16.3.8. | ZTE's RIS prototypes for outdoor coverage |
| 16.3.9. | ZTE's RIS prototypes for indoor |
| 16.3.10. | The current status of RIS |
| 16.3.11. | Huawei's 6G RIS prototype demo |
| 16.3.12. | Huawei's 6G RIS prototype demo results |
| 16.4. | RIS Forecast |
| 16.4.1. | Reconfigurable intelligent surfaces in telecommunications: Forecasts segments |
| 17. | METAMATERIALS |
| 17.1. | Metamaterials for RIS in telecommunication |
| 17.2. | Research history of metamaterials in RIS |
| 17.3. | Product segmentation: distinguishing between conductive and optical |
| 17.4. | Metamaterial tunability |
| 17.5. | Pivotal Commware: holographic beamforming in semi-active RIS |
| 17.6. | Materials and manufacturing for reconfigurable intelligent surfaces |
| 17.7. | Liquid crystal polymers (LCP) for RIS |
| 17.8. | Liquid crystal polymers (LCP) are a promising method for creating active metasurfaces |
| 17.9. | Alcan Systems develops transparent liquid crystal phased array antennas |
| 17.10. | Metamaterials in RIS: SWOT |
| 17.11. | Suitable materials for metamaterials in 5G and 6G RIS |
| 17.12. | Porter's five forces analysis of metamaterials in RIS |
| 17.13. | Multiple competing metamaterial manufacturing methods |
| 17.14. | RISE-6G investigates use of metamaterials in wireless communications |
| 17.15. | More info about Metamaterials |
| 18. | 6G USE CASES BEYOND MOBILE COMMUNICATION |
| 18.1. | 6G - an overview of key applications |
| 18.2. | Wireless cognition |
| 18.3. | THz Sensing - an overview |
| 18.4. | The principle of THz sensing and potential opportunities |
| 18.5. | Apple's patents on THz sensor for gas sensing and imaging |
| 18.6. | THz Imaging - an overview |
| 18.7. | THz sensing and imaging - examples from Terasense |
| 18.8. | THz precise positioning - an overview |
| 18.9. | Integrated Sensing and Communication (ISAC) prototype from Huawei (1) |
| 18.10. | Integrated Sensing and Communication (ISAC) prototype from Huawei (2) |
| 18.11. | Massive digital twinning for smart city |
| 18.12. | Overview of land-mobile service applications in the frequency range 275-450 GHz |
| 18.13. | Potential use cases in 275 - 450 GHz (1) |
| 18.14. | Potential use cases in 275 - 450 GHz (2) |
| 19. | MARKET FORECAST |
| 19.1. | 6G base stations market forecast |
| 19.2. | 5G base stations market forecast |
| 19.3. | More info about 5G |
| 19.4. | Reconfigurable intelligent surfaces in telecommunications: Forecasts segments |
| 20. | COMPANY PROFILES |
| 20.1. | Alcan systems |
| 20.2. | Ampleon |
| 20.3. | Atheraxon |
| 20.4. | Commscope |
| 20.5. | Ericsson (2020) |
| 20.6. | Ericsson (2021) |
| 20.7. | Freshwave |
| 20.8. | GaN Systems |
| 20.9. | Huawei |
| 20.10. | Kyocera |
| 20.11. | Metamaterials |
| 20.12. | Nokia |
| 20.13. | NXP Semiconductors |
| 20.14. | Omniflow |
| 20.15. | Picocom |
| 20.16. | Pivotal Commware |
| 20.17. | Renesas Electronics Corporation |
| 20.18. | Solvay |
| 20.19. | TMYTEK |
| 20.20. | ZTE |
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Report Statistics
| Slides | 307 |
|---|---|
| Forecasts to | 2043 |
| ISBN | 9781915514400 |
Preview Content
 RIS Webinar Slides
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Webinar Slides - EOY 2023
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Webinar Slides
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Webinar Slides - EOY 2022
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Sample pages
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