首頁 產業/市場分類 出版商一覽 Email 通知 GII媒體代理會議 公司簡介 聯絡我們
- English Japanese Korean
首頁 > 市場調查報告書 > 通訊 > 次世代無線通信 > 無線ICT及高速公路交通系統(ITS):目前及未來趨勢
產業/市場分類
通訊 (11616)
企業概況 (774)
光纖網路 (265)
次世代無線通信 (543)
行動用戶 (129)
行動設備 (764)
軟體 (1034)
電子商務 (209)
網路 (677)
網路與進入設備 (268)
數位廣播 (305)
數據中心 (345)
寬頻 (392)
衛星遠程通信 (141)
線上廣告 (144)
整合 (177)
整合通訊 (305)
機上盒 (63)
聯繫中心 (135)
Contents (627)
IT安全性 (503)
IT委外 (323)
LBS (160)
NFC (152)
RFID (215)
Web服務 (554)
WLAN/WiMAX (568)
市場調查報告書

無線ICT及高速公路交通系統(ITS):目前及未來趨勢

Wireless ICT and Intelligent Transportation Systems: Current and Future Trends

出版商 Practel, Inc.
出版日期 2011年06月 商品編碼 203188
內容資訊 英文  
價格
US $ 3990 Read Only PDF By E-mail (Single User License)
US $ 4100 Printable PDF by E-mail (Single User License)
US $ 5700 PDF by E-mail (Enterprise License)


無線ICT及高速公路交通系統(ITS):目前及未來趨勢 是由出版商Practel, Inc.在2011年06月所出版的。 這份英文市場調查報告書價格從美金3990起跳。

簡介

本報告為,調查分析邁向4G時代之ITS(高速公路交通系統)及無線ICT最新趨勢,並匯整ITS概要、5.9GHzDSRC(窄域通訊)技術及市場、WSN(無線感測器網路)發展及市場等分析,以下列摘要形式闡述。

第1章 簡介

  • 目的
  • 範圍
  • 調查方式
  • 對象讀者

第2章 高速公路交通系統(ITS)

  • 概要
  • ITS歷史:美國
  • ITS架構:美國
  • 全球ITS之發展:簡介
    • 歐洲
    • 日本
    • 標準化
  • 技術
  • ITS應用

第3章 5.9 GHz DSRC之基礎

  • 概要
  • IEEE 802.11p
    • 概要
    • 目的及情形
    • 內容
  • IEEE 1609
    • 概要
    • 概況
    • IEEE 1609之實用舉例
  • 摘要

第4章 5.9 GHz DSRC之發展

  • 概要
  • 歷史
  • 設備
  • 內容:窄域通訊(DSRC)
  • 指定頻道
  • 地點
  • 應用
  • 摘要:DSRC(5.9GHz)送訊特徵(美國)
  • 運用之DSRC
    • 服務分類
    • 要件:DSRC
  • 法規
    • 授權
  • 比較

第5章 DSRC國際標準活動

  • 概要
    • 調整
  • 進行情況

第6章 5.9 GHz DSRC之優點及限制

  • 概要
    • 過路費產業之優勢
  • 限制

第7章 市場:5.9 GHz DSRC

  • 市場驅力
  • 市場要件
  • 數據
  • 市場預測

第8章 DSRC設備供應商

第9章 CALM:中廣域無線通訊介面

  • 目的
    • 車輛:基礎設施
  • 規格
  • ISO TC 204 WG 16
    • IPv6及NEMO
  • CALM:國際活動
  • CALM:應用
  • 主要特徵
  • 挑戰

第10章 CEN及ITU

  • 概要
  • CEN及ITS
  • ITU

第11章 ETSI

第12章 IETF

第13章 4G技術

  • 無線為革命或是進步?
    • 3G之後而來之4G
  • 要件
  • 典型特徵
  • 選項

第14章 長期演進(LTE):技術及市場

  • 3GPP及LTE
    • LTE之行程表
    • 長期演進無線通訊:各種階段
    • LTE標準化:業界合作
  • LTE之主要特徵
    • 內容
    • 優點
  • SAE/EPS
    • 功能結構
  • 市場
    • 需求:無線寬頻
    • LTE市場預測
  • 供應商
  • LTE及ITS

第15章 智慧感測器技術:ITC規格

  • 智慧感測器結構
    • 分類:智慧感測器
    • 內容
  • 網路
    • 網狀結構之特徵
    • 優點及限制
  • 應用內容:WSN
  • 標準化:IEEE 1451
    • 概要
    • 家庭
    • 內容
  • ITS及WSN
  • 挑戰
  • 市場特徵
    • 概要
    • 市場推測
    • 趨勢
  • WSN設備供應商

第16章 結論

附錄I:ISO之ITS標準

附錄II:ITS相關各國及國際標準

圖表

目錄

Abstract

Brief

This report is written for a wide audience of technical and managerial staff who are working on wireless ICT-related Intelligent Transportation Systems projects. The report aim is to present for such specialists advanced directions and trends in wireless ICT that can lead ITS into the 4G era.

The reports updates and revises Practel reports that were researching WICT-related ITS features; and were published between 2006 and 2010.

In particular, this report:

  • 1. Provides the analysis of ITS specifics.
  • 2. Analyzes technologies and markets for 5.9 GHz Short Reach Dedicated Communications (DSRC). 5.9 GHz DSRC was originally developed for the U.S. market; and currently it is at the beginning of commercialization. The report addresses this technology specifics and benefits - recently, EU also approved 5.9 GHz band for its DSRC systems. Currently, the major application for DSRC is electronic tolling; it is expected that the range of applications will grow significantly with maturing of the technology.
  • 3. Analyzes the specifics of CALM (Continuous Air-interface, Long and Medium Range) technology and its applications. This technology aims for creation of an “universal” platform for ITS services. Such a platform will be able to support multiple wireless standards.
  • 4. Concentrates on the standardization process for WICT in the ITS environment.
  • 5. Analyzes technologies and market for Long Term Evolution (LTE); the technology is being standardized and appreciated as the 4G era wireless technology. It opens a wide range of applications for ITS; currently, the auto industry R&D together with manufacturers are working on the concept of the LTE - equipped car. The technology allows creating of ITS infrastructural networking with high bit rate, QoS and other important features. Major service providers are offering LTE-based services.
  • 6. Analyzes specifics of Wireless Sensors Networks (WSNs), their development and markets and how they apply to ITS. It is expected that in the near - future Smart Sensors will create a basis for establishing an intelligent source of information for processing in the ITS control centers. The report provides details of WSN features and benefits.

The report addresses latest and near-future trends in wireless ICT for ITS and how the 4G developments apply to them.

Target Audience

This report is important to a wide population of researches, technical and sales staff involved in the developing of high-speed wireless services and products for transportation. It is recommended for both service providers and vendors that are working with related technologies. The report also helps to understand relationship between ITS wireless communications and other technologies.

Research Methodology

Considerable research was done using the Internet. Information from various Web sites was studied and analyzed. Evaluation of publicly available marketing and technical publications was conducted. Telephone conversations and interviews were held with industry analysts, technical experts and executives. In addition to these interviews and primary research, secondary sources were used to develop a more complete mosaic of the market landscape, including industry and trade publications, conferences and seminars.

The overriding objective throughout the work has been to provide valid and relevant information. This has led to a continual review and update of the information content.

Table of Contents

1.0 Introduction

  • 1.1. Goal
  • 1.2. Scope
  • 1.3. Research Methodology
  • 1.4. Target Audience

2.0 Intelligent Transportation Systems

  • 2.1. General
  • 2.2. ITS History: U.S.
  • 2.3. ITS Architecture: U.S.
  • 2.4. Global ITS Development-Introduction
    • 2.4.1. Europe
    • 2.4.2. Japan
    • 2.4.3. Standardization
      • 2.4.3.1. National Transportation Communications for ITS Protocol (NTCIP)
  • 2.5. Technologies
  • 2.6. ITS Applications

3.0 5.9 GHz DSRC Basis

  • 3.1. General
  • 3.2. IEEE 802.11p
    • 3.2.1. General
    • 3.2.2. Objectives and Status
    • 3.2.3. Details
      • 3.2.3.1. ASTM Standard
  • 3.3. IEEE 1609
    • 3.3.1. General
    • 3.3.2. Overview
    • 3.3.3. IEEE 1609 in Use
  • 3.4. Summary

4.0 5.9 GHz DSRC Development

  • 4.1. General
  • 4.2. History
  • 4.3. Equipment
  • 4.4. Details: Dedicated Short Range Communications
  • 4.5. Channel Designation
  • 4.6. Place
  • 4.7. Applications
  • 4.8. Summary: DSRC (5.9 GHz) Transmission Characteristics (U.S.)
  • 4.9. DSRC at Work
    • 4.9.1. Service Categories
    • 4.9.2. Requirements: DSRC
  • 4.10. Regulation
    • 4.10.1. Licensing
  • 4.11. Comparison

5.0 DSRC Worldwide Standard Activity

  • 5.1. General
    • 5.1.1. Coordination
  • 5.2. Process

6.0 5.9 GHz DSRC Benefits and Limitations

  • 6.1. General
    • 6.1.2. Toll Industry Benefits
  • 6.2. Limitations

7.0 Market: 5.9 GHz DSRC

  • 7.1. Market Drivers
  • 7.2. Market Requirements
  • 7.3. Data
  • 7.4. Market Estimate

8.0 DSRC Equipment Vendors

  • Arinc
  • Kapsch
  • Mark IVHS (Acquired by Kapsch in 2010)
  • Oki
  • Q-Free
  • Raytheon
  • Savari
  • Sirit
  • TransCore
  • TechnoCom

9.0 CALM: Continuous Air-interface, Long and Medium Range

  • 9.1. Goals
    • 9.1.1. Vehicle- Infrastructure
  • 9.2. Specifics
  • 9.3. ISO TC 204 WG 16
    • 9.3.1. IPv6 and NEMO
  • 9.4. CALM: International Efforts
  • 9.5. CALM: Applications
  • 9.6. Major Features
  • 9.7. Issues

10.0 CEN and ITU

  • 10.1. General
  • 10.2. CEN and ITS
  • 10.3. ITU

11.0 ETSI

12.0 IETF

13.0 4G Technologies

  • 13.1. Wireless Revolution or Evolution?
    • 13.1.1. 4G as 3G Successor
  • 13.2. Requirements
  • 13.3. Typical Features
  • 13.4. Choice

14.0 Long Term Evolution (LTE): Technology and Market

  • 14.1. 3GPP and LTE
    • 14.1.1. LTE Timetable
    • 14.1.2. Broadband Wireless Communications-Phases
    • 14.1.3. LTE Standardization - Industry Collaboration
      • 14.1.3.1. Industry Initiative
  • 14.2. Key Features of LTE
    • 14.2.1. Details
      • 14.2.1.1. Evolved UMTS Radio Access Network (E-UTRAN)
      • 14.2.1.2. Evolved Packet Core (EPC)
      • 14.2.1.3. LTE Advanced
      • 14.2.1.4. SON
    • 14.2.2. Benefits
      • 14.2.2.1. Voice Support
        • 14.2.2.1.1. VoLTE
  • 14.3. SAE/EPS
    • 14.3.1. Functional Structure
    • 14.3.2. Interfaces
  • 14.4. Market
    • 14.4.1. Demand: Wireless Broadband
    • 14.4.2. LTE Market Projections
  • 14.5. Vendors
    • 4M Wireless
    • Agilent
    • Altair Semiconductor
    • Alcatel-Lucent-NEC
    • Altera
    • Aricent
    • Axis
    • Commagility
    • Ericsson
    • Fujitsu
    • Infineon
    • Huawei
    • Lime Microsystems
    • mimoON
    • Motorola
    • Nokia Siemens Networks
    • NXP
    • picoChip
    • Qualcomm
    • Samsung
    • Starent (Cisco)
    • TI
    • Sequans
    • Signalion
    • ZTE
  • 14.6. LTE and ITS

15.0 Smart Sensors Technology - ITS Specifics

  • 15.1. Smart Sensor Structure
    • 15.1.1. Classification - SMART SENSOR
    • 15.1.2. Details
      • 15.1.2.1. WSN-SMART SENSOR
      • 15.1.2.2. Requirements
  • 15.2. Networking
    • 15.2.1. Features of Mesh Structures
    • 15.2.2. Benefits and Limitations
  • 15.3. Details of Applications - WSN
  • 15.4. Standardization: IEEE 1451
    • 15.4.1. General
    • 15.4.2. Family
    • 15.4.3. Details
  • 15.5. ITS and WSN
  • 15.6. Challenges
  • 15.7. Market Characteristics
    • 15.7.1. General
    • 15.7.2. Market Estimate
    • 15.7.3. Trends
  • 15.8. WSN Equipment Vendors
    • BAE Systems
    • BBN
    • Crossbow - Moog Crossbow (WSN)
    • Crane - WMS (Acquired by Textron in 2010) (WSN-ZigBee)
    • Dust Networks (USG-Mesh)
    • Elta (Sensors)
    • Exensor (WSN nodes)
    • Intel (Chipsets)
    • Freescale (Sensors)
    • Harris (SMART SENSOR)
    • IWT (Mesh)
    • L3 (SMART SENSOR)
    • McQ (SMART SENSOR)
    • MeshDynamics (Mesh)
    • Millennial Net (Mesh-SMART SENSOR)
    • MeshNetics-Atmel (WSN Software)
    • Newtrax (WSN-mesh, SMART SENSOR)
    • Nelco (Sensors Systems)
    • NorthropGrumman (SMART SENSOR)
    • Octave Technologies (SW, WSN)
    • Qual-Tron (Sensors)
    • Rheinmetall (SMART SENSOR)
    • Selex (SMART SENSOR)
    • Sensys (ITS Sensors)
    • Sensicast (WSN)
    • Smart Sensor Systems (Sensor Modules)
    • SmartMicro (Radars Sensors - ITS)
    • Strix (Mesh)
    • Telonics (Sensors)
    • TextRon (SMART SENSOR)
    • Thales (SMART SENSOR)
    • Trident (SMART SENSOR-UWB)
    • Wavetronix (Sensors - ITS)
    • Zeltech (SMART SENSOR)

16.0 Conclusions

APPENDIX I: ISO ITS Standards

APPENDIX II: ITS-related National and International Standards

LIST OF FIGURES:

  • Figure 1: Wireless Communications: ITS Environment
  • Figure 2: ITS Architecture
  • Figure 3: ITS Standardization
  • Figure 4: NTCIP Structure
  • Figure 5: Communications Model: WAVE
  • Figure 6: Protocol Stack
  • Figure 7: Illustration - IEEE 1609 Standards
  • Figure 8: ITS-DSRC
  • Figure 9: 5.9 GHz DSRC: Spectrum Allocation Details
  • Figure 10: Channel Assignment - 5.9 GHz DSRC
  • Figure 11: Major Categories-5.9 GHz DSRC Services
  • Figure 12: Collision Detection/Avoidance System
  • Figure 13: Work Zone Warning
  • Figure 14: “Smart” Car
  • Figure 15: 5.9 GHz DSRC Rate vs. Distance
  • Figure 16: Logical Flow
  • Figure 17: DSRC Frequencies Planning
  • Figure 18: 5.9 GHz DSRC Program Schedule
  • Figure 19: N.A. 5.9 GHz DSRC Program
  • Figure 20: TAM U.S. 5.9 GHz DSRC Tag ($B)
  • Figure 21: TAM U.S. 5.9 GHz DSRC Tag (Units Mil.)
  • Figure 22: TAM U.S. 5.9 GHz DSRC Readers (Unit Mil.)
  • Figure 23: TAM U.S. 5.9 GHz DSRC Readers ($M)
  • Figure 24: CALM: Infrastructure-Vehicle
  • Figure 25: CALM Architecture
  • Figure 26: Evolution Path
  • Figure 27: Towards Wireless Mobile Broadband
  • Figure 28: LTE - IP
  • Figure 29: Projection: Global Broadband Mobile Subscribers Base (B)
  • Figure 30: LTE Market-Subscribers' Base (M)
  • Figure 31: Projection: LTE Global Equipment Sale ($B)
  • Figure 32: Service Operation Center
  • Figure 33: Two Groups
  • Figure 34: SMART SENSOR-Functions
  • Figure 35: SMART SENSOR Technologies
  • Figure 36: WSN-SMART SENSOR Node
  • Figure 37: TAM - WSN Nodes Sales-Commercial - Global ($B)
  • Figure 38: TAM-WSN Node Sales - Commercial -Global (M Units)
  • Figure 39: SMART SENSOR Market Geographical Segmentation
  • Figure 40: SMART SENSOR Network Sizing

LIST OF TABLES:

  • Table 1: Services
  • Table 2: 5.9 GHz DSRC U.S. Characteristics
  • Table 3: Events Priorities
  • Table 4: Requirements
  • Table 5: Service-related Characteristics
  • Table 6: 915 MHz and 5.9 GHz DSRC Differences
  • Table 7: 5.9 GHz DSRC Standards
  • Table 8: DSRC Advantages
  • Table 9: DSRC Benefits
  • Table 10: CALM-WG16
  • Table 11: ETSI ITS-related Standards
  • Table 12: 3G and 4G Features
  • Table 13: 3GPP Releases
  • Table 14: Major LTE Characteristics
  • Table 15: LTE Frequency Bands
  • Table 16: Release 8 Users Equipment Categories
  • Table 17: ITS-WSN Applications
  • Table 18: SMART SENSOR Node-Price Components
Back to Top