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マイクロ無線通信の進歩:技術・市場の評価

Advances in Microwave Radio Communications: Assessments Technologies and Markets

発行 Practel, Inc. 商品コード 262972
出版日 ページ情報 英文
納期: 即日から翌営業日
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マイクロ無線通信の進歩:技術・市場の評価 Advances in Microwave Radio Communications: Assessments Technologies and Markets
出版日: 2013年01月31日 ページ情報: 英文
概要

当レポートでは、マイクロ波無線プロジェクトの開発動向について調査し、高周波通信システムの開発における先進動向を分析しており、SONET/SDHマイクロ波無線(2GHz-40GHz)、パケットマイクロ波無線(2GHz-40GHz)、60GHz無線、Eバンドマイクロ波無線、4.9GHz公共安全無線、ワイヤレスファイバーシステム(THz)といった各技術と関連市場の分析などをまとめ、概略以下の構成でお届けします。

第1章 イントロダクション

第2章 規格

  • ITU規格
  • 実例
  • ETSI規格
  • マイクロ無線vs.専用回線

第3章 アプリケーション

  • モバイルネットワークバックホール
  • ラストマイルアクセス
  • プライベートネットワーク
  • 災害復旧
  • デジタルディバイド(情報格差)
  • 途上国
  • ユーティリティネットワーク
  • 緊急無線

第4章 スペクトル

  • 指定
  • 無認可無線

第5章 SONET/SDHマイクロ波

  • 概要
  • フォーマット
  • 構造
  • 多様性
  • SONET/SDH無線市場
  • セキュリティ
  • SONET/SDHマイクロ波産業

第6章 マイクロ波パケット無線

  • 要件・アプリケーション
  • ハイブリッド
  • マイクロ波パケット無線のメリット
  • 市場
  • 産業

第7章 ミリ波無線

  • 概要
  • ファクター:60GHz無線
  • Eバンド
  • 目標
  • 60GHz無線技術・市場
  • 仕様
  • 前進
  • 60GHz固定ワイヤレスのラストマイル
  • 60GHz無線のIEEE802.15.3cおよび競合
  • Eバンド無線:技術・市場

第8章 公共安全:4.9GHz無線

  • 概要
  • スペクトル配分
  • 4.9GHz公共安全無線のアプリケーション
  • FCCプロセス
  • 国際
  • 資格
  • 条件
  • 周波数分配
  • ユーザー
  • 4.9GHz帯のメリット
  • 4.9GHz無線規格・関連技術
  • 4.9GHz無線市場
  • 4.9GHz無線産業

第9章 ワイヤレスファイバー通信(WFC):技術

  • 概要
  • 主な特徴
  • 保護
  • アプリケーション
  • 要件
  • WFCのメリット・デメリット:サマリー
  • 設計の問題
  • 顧客
  • WFC市場
  • 産業

第10章 結論

  • 参考資料

図表リスト

目次

This report updates and revises information that was provided by Practel, Inc in 2008-2012 reports further developing the microwave radio project.

The goal was to analyze advanced trends in the developing of high-frequencies communications systems. The goal was achieved through addressing a wide range of technologies and related markets.

Particular, this report concentrates on:

  • SONET/SDH microwave radio: 2 GHz-40 GHz
  • Packet microwave radio: 2 GHz-40 GHz
  • 60 GHz radio
  • E-Band microwave radio
  • 4.9 GHz Public Safety radio
  • Wireless Fiber Systems: THz.

The common denominator for all these technologies is utilization of the microwave spectrum. The analysis of Wireless Fiber Systems helps to further understand the abilities of a microwave path with protection; and the analysis of 4.9 GHz Public Safety radio specifics provides an example of microwave radio important application.

The report emphasizes specifics of each technological group, their applications, benefits and disadvantages; it also analyzes related markets and industries.

Table of Contents

1.0. Introduction

  • 1.1. History
  • 1.2. Why Microwave?
  • 1.3. SONET/SDH
  • 1.4. mm-Wave Radio
  • 1.5. Microwave Packet Radio
  • 1.6. Wireless Fiber Systems
  • 1.7. 4.9 GHz Public Safety Radio
  • 1.8. Scope and Goals
  • 1.9. Research Methodology
  • 1.10. Target Audience

2.0. Standards

  • 2.1. ITU Standards
  • 2.2. Examples
    • 2.2.1. Backbone Standards
    • 2.2.2. Access Standards
    • 2.2.3. Equipment Protection
  • 2.3. ETSI Standards
  • 2.4. Microwave Radio vs. Leased Line

3.0. Applications

  • 3.1. Mobile Networks Backhaul
  • 3.2. Last-Mile Access
  • 3.3. Private Networks
  • 3.4. Disaster Recovery
  • 3.5. The Digital Divide
  • 3.6. Developing Nations
  • 3.7. Utilities Networks
  • 3.8. Emergency Radio

4.0. Spectrum

  • 4.1. Designations
  • 4.2. Unlicensed Radio

5.0. SONET/SDH Microwave Radio

  • 5.1. General
  • 5.2. Format
  • 5.3. Structure
  • 5.4. Diversity
  • 5.5. SONET/SDH Radio Market
    • 5.5.1. Market Projections
      • 5.5.1.1. Model Assumptions
      • 5.5.1.2. Forecast
  • 5.6. Security
    • 5.6.1. General
    • 5.6.2. Types of Attacks
      • 5.6.2.1. Passive Attacks
      • 5.6.2.2. Active Attacks
  • 5.7. SONET/SDH Microwave Radio Industry
    • ABB
    • Agilis
    • Airlinx
    • Alcatel-Lucent
    • Aviat Networks
    • Ceragon
    • Ericsson
    • Exalt
    • Fujitsu
    • Microwave Data Systems (GE MDS)
    • Microwave Networks
    • NEC
    • SAF
    • Nokia Siemens Networks
    • SIAE (SIAE MICROELETTRONICA LTD)
    • Thales
    • Westica
    • ZTE

6.0. Microwave Packet Radio

  • 6.1. Requirements and Applications
    • 6.1.1. Mobile Technologies - Microwave Packet Radio Market Drivers
  • 6.2. Hybrid
  • 6.3.Benefits of Microwave Packet Radio
  • 6.4. Market
    • 6.4.1. Estimate
    • 6.4.2. Geography
  • 6.5. Industry
    • Alcatel-Lucent
    • Aviat
    • Cambridge Broadband
    • Ceragon
    • Comba
    • DragonWave
    • Ericsson
    • Exalt
    • Huawei
    • NEC
    • Nokia Siemens Networks
    • Positron
    • Trango Systems

7.0. mm-Wave Radio

  • 7.1.General
  • 7.2. Factors: 60 GHz Radio
    • 7.2.1. Regulatory Climate: FCC, ETSI, ITU
  • 7.3. E-band
  • 7.4. Goals
    • 7.4.1. Progress in the Chip Technology for mm-Wave Radio
  • 7.5. 60 GHz Radio Technology and Market
    • 7.5.1. General
    • 7.5.2. Spectrum Specifics
    • 7.5.3. Oxygen Absorption
    • 7.5.4. Antenna
    • 7.5.5. Radiation Limiting at 60 GHz
    • 7.5.6. Combined Effect
    • 7.5.7. Modulation
  • 7.6. Specifics
    • 7.6.1. Indoor Behavior
    • 7.6.2. Wi-Fi and 60 GHz Radio
  • 7.7. Progress
  • 7.8. 60 GHz Fixed Wireless-Last Mile
    • 7.8.1. General
    • 7.8.2. Details-Characteristics
    • 7.8.3. Place
    • 7.8.4. Addressable Market
      • 7.8.4.1. General
      • 7.8.4.2. Drivers
      • 7.8.4.3. Forecast
    • 7.8.5. Industry
      • BridgeWave
      • Comotech
      • LightPointe
      • Solectek
      • Sub10 Systems
      • Vubiq
  • 7.9. 60 GHz Radio-IEEE 802.15.3c and Competition
    • 7.9.1. General
    • 7.9.2. Demand
    • 7.9.3. Specifics
    • 7.9.4. Benefits for WPAN
    • 7.9.5. Applications
    • 7.9.6. Challenges
    • 7.9.7. Standardization and Development: WirelessHD, IEEE 802.15.3c and Other
      • 7.9.7.1. WirelessHD: General
      • 7.9.7.2. Details: WirelessHD Technology
        • 7.9.7.2.1. Completion
        • 7.9.7.2.2. Summary
    • 7.9.8. IEEE 802.15.3c
      • 7.9.8.1. Scope
      • 7.9.8.2. Current Status
      • 7.9.8.3. Benefits
      • 7.9.8.4. Details
    • 7.9.9. IEEE Very High Throughput Group- IEEE 802.11ad/WiGig
      • 7.9.9.1. General
      • 7.9.9.2. Scope
    • 7.9.10. Market
      • 7.9.10.1. General: Applications
      • 7.9.10.2. Market Development: Specifics
      • 7.9.10.3. Forecast
    • 7.9.11. Players and Projects
      • Cables to Go
      • Gefen
      • IBM
      • IMEC
      • LG
      • NEC
      • Phiar-Motorola
      • Panasonic
      • SiBeam (Silicon Image)
      • Vubiq
    • 7.9.12. 60 GHz WPAN: Example
  • 7.10. E-band Radio: Technology and Market
    • 7.10.1. General: FCC and ITU
    • 7.10.2. Benefits
    • 7.10.3. Regulations
    • 7.10.4. Frequency Plan
    • 7.10.5. Additional Characteristics
    • 7.10.6. Major Applications
    • 7.10.7. Market Prospective
      • 7.10.7.1. Last Mile
      • 7.10.7.2. Estimate
    • 7.10.8. Vendors
      • ADC - TE Connectivity
      • Athena
      • Bridgewave
      • Ceragon
      • ComoTech
      • Dragonwave
      • E-band Communications
      • ElvaLink
      • G4 Networks
      • Fujitsu
      • LightPointe
      • Loea Corporation
      • Nokia Siemens
      • Sub10 Systems
      • Solectek

8.0. Public Safety - 4.9 GHz Radio

  • 8.1. General
  • 8.2. Spectrum Allocation
  • 8.3. 4.9 GHz Public Safety Radio Applications
  • 8.4. FCC Process
  • 8.5. International
  • 8.6. Eligibility
  • 8.7. Conditions
  • 8.8. Frequencies Allocations
    • 8.8.1. Public Safety Bands
  • 8.9. Users
  • 8.10. Benefits of the 4.9 GHz Band
  • 8.11. 4.9 GHz Radio Standards and Related Technologies
    • 8.11.1. FCC
    • 8.11.2. Mesh Networks
      • 8.11.2.1. Specifics
      • 8.11.2.2. IEEE 802.11s
    • 8.11.3. OFDM
    • 8.11.4. Multi-radio Platforms
    • 8.11.5. WiMax
  • 8.12. 4.9 GHz Radio Market
    • 8.12.1. General
    • 8.12.2. Forecast
  • 8.13. 4.9 GHz Radio Industry
    • Airaya
    • Alvarion
    • Aperto
    • Azuretec
    • Belair (acquired by Ericsson in 2012)
    • Carlson Wireless
    • Cisco
    • Exalt
    • Firetide
    • Fluidmesh Networks
    • Hautespot Networks
    • MeshDynamics
    • Motorola Solutions
    • Proxim Wireless
    • Redline
    • RadWin
    • SkyPilot - Trilliant
    • Solectek
    • Strix
    • Teletronics
    • Trango Systems
    • Tranzeo
    • Tropos (acquired by ABB in 2012)

9.0. Wireless Fiber Communications (WFC): Technology

  • 9.1. General
  • 9.2. Major Characteristics
  • 9.3. Protection
  • 9.4. Applications
  • 9.4. Requirements
  • 9.5. WFC Benefits and Limitations: Summary
  • 9.6. Design Issues
  • 9.7. Customers
  • 9.8. WFC Market
    • 9.8.1. General
    • 9.8.2. Market Drivers
    • 9.8.3. Competition
      • 9.8.3.1. Fiber Optics Systems
      • 9.8.3.2. Microwave
      • 9.8.3.3. PONs
    • 9.8.4. Forecast
      • 9.8.4.1. General
      • 9.8.4.2. Model Assumptions
      • 9.8.4.3. Structure
      • 9.8.4.4. Market Estimate
  • 9.9. Industry
    • CableFree
    • Canon USA
    • CBL
    • Dailianxu Engineering Company
    • Dominion Laserbeam-SkyFiber
    • fSONA
    • GeoDesy
    • LightPointe
    • LSA
    • Optel
    • Plaintree
    • RedLine

10.0. Conclusions

  • References

List of Figures:

  • Figure 1: Spectrum Assignment
  • Figure 2: SONET Frame (OC-1)
  • Figure 3: Simplified - SSMR Structure
  • Figure 4: TAM: SSMR Global Sales ($B)
  • Figure 5: TAM: SSMR and Associated Equipment Global Sales (Unit 000)
  • Figure 6: SSMR Market Granularity - Rate of Transmission
  • Figure 7: SSMR Market Granularity - Frequency Bands
  • Figure 8: Geographical Segmentation of SONET/SDH Radio Market
  • Figure 9: Segmentation by Method of Protection: SONET/SDH Radio Market
  • Figure 10: Passive Attack
  • Figure 11: Backhaul - Microwave
  • Figure 12: TAM: Microwave Packet Radio Global Sales ($B)
  • Figure 13: Microwave Packet Radio Market Geography (2012)
  • Figure 14: Unlicensed Bands
  • Figure 15: ITU-R - Channelization
  • Figure 16: 60 GHz Connections
  • Figure 17: 60 GHz: Frequency Allocations
  • Figure 18: 60 GHz: Spectrum Details
  • Figure 19: mm-Wave Energy Attenuation in 60 GHz Band
  • Figure 20: 60 GHz: Absorption Details
  • Figure 21: Frequency Bands Features Comparison
  • Figure 22: TAM: 60 GHz Radio Global Sales - Outdoors Fixed ($M)
  • Figure 23: TAM: 60 GHz Radio Global Sales Outdoors Fixed (Units)
  • Figure 24: 60 GHz “Open” Spectrum
  • Figure 25: IEEE Group Structure: 802.15
  • Figure 26: Configuration
  • Figure 27: TAM: U.S. WPAN 60 GHz Radio Sales ($M)
  • Figure 28: 60 GHz WPAN Example
  • Figure 29: Frequency Allocation
  • Figure 30: TAM - US-E-band Radio-Last Mile Access ($M)
  • Figure 31: Addressable Market-US-E-band Radio-Last Mile Access (Units 000)
  • Figure 32: Mesh Network Diagram
  • Figure 33: TAM: U.S. Mobile and Hand-held 4.9 GHz Radio Sales ($B)
  • Figure 34: 4.9 GHz Network Infrastructure Dynamics
  • Figure 35: Simplified WFC Device Diagram
  • Figure 36: WFC Market Segments
  • Figure 37: TAM: U.S. WFS Sales ($M)
  • Figure 38: TAM: U.S. WFS Sales (Unit 000)
  • Figure 39: WFS Market Geography

List of Tables:

  • Table 1: Microwave Frequencies Bands
  • Table 2: ISM - ITU Designation
  • Table 3: SONET/SDH Rates
  • Table 4: Licensed and Unlicensed SONET/SDH Radio Proportion
  • Table 5: Differentiation by Path Length: SONET/SDH Radio
  • Table 6: Antenna Directivity
  • Table 7: 60 GHz Links Characteristics
  • Table 8: Characteristics Details
  • Table 9: Attenuation
  • Table 10: Properties
  • Table 11: Required Speed
  • Table 12: Modulation Characteristics
  • Table 13: FCC Regulations
  • Table 14: Emergency Services
  • Table 15: Requirements
  • Table 16: Power Limits
  • Table 17: Frequencies Allocations: 4.9 GHz Band
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