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市場調查報告書

初期應變人員:室內通訊及本土化 - 技術與市場

First Responders: In-building Communications and Localization- Technologies and Markets

出版商 Practel, Inc. 商品編碼 324706
出版日期 內容資訊 英文 124 Pages
商品交期: 最快1-2個工作天內
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初期應變人員:室內通訊及本土化 - 技術與市場 First Responders: In-building Communications and Localization- Technologies and Markets
出版日期: 2015年02月20日 內容資訊: 英文 124 Pages
簡介

本報告提供建築物,隧道及類似的建造物內部,支援初期應變人員的工作的無線通訊、本土化技術的規格相關調查分析,關聯的產業,適用規格,及市場相關的系統性資訊。

第1章 簡介

第2章 PSC頻譜

  • 美國
  • EU
  • 全球

第3章 特別的考慮

  • 必要條件:初期應變人員室內通訊
  • 選擇
  • 室內通訊的規格

第4章 發展趨勢

  • 小型基地台

第5章 分散式天線系統 (DAS)

  • 概要
  • 分類
  • DAS的優點
  • 論壇
  • 公共安全性通訊的DAS的規格
  • 市場
  • 產業 (17家)

第6章 室內無線通訊:市場估計

第7章 室內本土化

  • 標準化活動
  • 產業 (18家)
  • 市場估計

第8章 FirstNet及室內通訊

第9章 比較

  • DAS
  • C-RAN小型基地台
  • 小型基地台的課題

第10章 結論

目錄

Target Audience

This report is important for the government agencies involved in the first response to critical situations. It is necessary for technical departments of such agencies to have a document, which explains the radio technology and architectures of networks supporting public safety communications inside of buildings, tunnels and similar structures. They also need to have market statistics and to know the major players and their portfolios to select the proper equipment.

For vendors, this report provides valuable information on competition. It also supports these vendors with the market assessment. For building owners and network providers this report may provide information on additional sources of revenue from in-building communications and localization services.

BRIEF

This report addresses specifics of wireless communications and localization technologies that support first responders operations inside of enclosures such as buildings, tunnels and similar constructions. It also addresses related industries, applicable standards and markets.

Increasingly, public safety entities, commercial wireless service providers, and wireless users require reliable communications inside buildings. For public safety, reliable coverage is often essential throughout a broad jurisdiction, including coverage on-street, in-building, and in-tunnel. In such cases, there is no substitute for a properly designed dedicated mission-critical communications system with sufficient transmit sites to provide the level of signal required for reliable coverage anywhere within the jurisdiction, whether on-street or indoors.

Indoor wireless communications environments usually do not allow using traditional PSC (Public Safety Communications) networking based on TETRA, P25 or LTE. Building materials attenuate signals and this makes communications unreadable. Localization based on GPS techniques is becoming also questionable due to weak satellite signals inside of a construction.

All these factors make it necessary to develop special methods to extend outdoor communications channels inside of enclosures. Two such methods are analyzed in this report; and they are based on utilization:

  • Small Cells
  • DAS - Distributed Antenna Systems.

Small Cells base stations are small in size, lightweight and designed to serve up to several tens of users. They may be conveniently spread throughout a building, covering each corridor, hall, corners and so on. The technology relatively recently became commercialized and brought multiple benefits to users.

DAS is used for in-building signals distributions for at least twenty years. The report concentrates on advances in this technology, its specifics and issues.

Standard organizations activities, the in-depth market analysis and survey of the industry are also studied in this report.

There are multiple methods suggested for in-building localization of first responders as well as other people or objects in the operational area. They are based on utilization of sensors, RF signatures in a building, amplification of GPS signals and other. The report concentrates on commercialized methods, and provides details of their advantages and issues. The report also addresses marketing aspects of in-building localization.

The report is written for a wide audience of technical and managerial staff involved in the development of reliable PSC and localization inside buildings or similar enclosures.

Table of Contents

1.0 Introduction

  • 1.1 Need
    • 1.1.1 Outdoor Environment
    • 1.1.2 Indoor Environment
      • 1.1.2.1 Legislation
      • 1.1.2.2 Examples
    • 1.1.3 Transparency
  • 1.2 Unified In-Building Wireless
  • 1.3 Public Safety Communications Specifics
  • 1.4 Scope and Goals
  • 1.5 Research Methodology
  • 1.6 Target Audience

2.0 PSC Spectrum

  • 2.1 U.S.
    • 2.1.1 FCC - General
    • 2.1.2 800 MHz Band
    • 2.1.3 700 MHz Band
      • 2.1.3.1 700 MHz Nationwide Network - FirstNet
  • 2.2 EU
  • 2.3 Global

3.0 Special Considerations

  • 3.1 Requirements: First Responders In-building Communications
    • 3.1.1 General
    • 3.2 Choices
      • 3.2.1 Classes
      • 3.2.2 Properties
        • 3.2.2.1 Regulations
        • 3.2.2.2 Who Benefits?
        • 3.2.2.3 Factors
  • 3.3 Specifics of In-building Communications
    • 3.3.1 Extended Coverage

4.0 Developmental Trends

  • 4.1 Small Cells
    • 4.1.1 General
    • 4.1.2 Nomenclature
    • 4.1.3 Groups
      • 4.1.3.1 C-RAN SC
    • 4.1.4 Applications
      • 4.1.4.1 Indoor Use Cases
      • 4.1.4.2 Outdoor Use Cases
      • 4.1.4.3 Public Safety Communications
    • 4.1.5 Benefits and Issues
    • 4.1.6 Small Cell Market
      • 4.1.6.1 Drivers
      • 4.1.6.2 Market Geography
      • 4.1.6.3 Estimate
    • 4.1.7 Standardization
      • 4.1.7.1 3GPP Rel.12 and SCs
    • 4.1.8 Small Cell Industry (29 companies)

5.0 Distributed Antenna System (DAS)

  • 5.1 General
    • 5.1.1 Definition
  • 5.2 Classification
    • 5.2.1 Utilization
  • 5.3 DAS Benefits
  • 5.4 Forum
  • 5.5 Specifics of DAS in Public Safety Communications
  • 5.6 Market
    • 5.6.1 General
    • 5.6.2 Cost Efficiency
    • 5.6.3 Market Drivers
    • 5.6.4 Forecast
  • 5.7 Industry (17 companies)

6.0 In-Building Wireless Communications: Market Estimate

7.0 In-building Localization

  • 7.1 Standardization Activity
    • 7.1.1 In-Location Alliance
  • 7.2 Industry (18 companies)
  • 7.3 Market Estimate

8.0 FirstNet and Indoor Communications

9.0 Comparison

  • 9.1 DAS
  • 9.2 C-RAN Small Cells
  • 9.3 Small Cells Issues

10.0 Conclusions

  • Figure 1: FCC PSC Spectrum Allocation
  • Figure 2: 800 MHz Reconfiguration Plan
  • Figure 3: 700 MHz Band
  • Figure 4: In-building Communications Systems - Classification
  • Figure 5: Macro vs. Small BS
  • Figure 6: Base Stations Characteristics - Illustration
  • Figure 7: Estimate: Global SC Shipments (Mil. Units)
  • Figure 8: Estimate: Global SC Shipments ($B)
  • Figure 9: Projections: Indoor Femtocells Shipments (Mil. Units)
  • Figure 10: Rel. 12 Enhancements
  • Figure 11: Scenario 1
  • Figure 12: Scenario 2
  • Figure 13: Differences
  • Figure 14: Active DAS
  • Figure 15: Passive DAS
  • Figure 16: Hybrid DAS
  • Figure 17: General Layout
  • Figure 18: TAM: DAS Equipment Sales - Global ($B)
  • Figure 19: Market Segments - DAS Types
  • Figure 20: Estimate: Global Market - In-Building Wireless Communications ($B)
  • Figure 21: Indoor Ranging - Standardization Activity (2012)
  • Figure 22: Estimate: Global Indoor Location Market ($B)
  • Figure 23: Estimate: Global Indoor Location Market - First Responders ($B)
  • Figure 24: Technical Characteristics
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