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市場調查報告書

M2M/IoT和可見光通訊(VLC:Visible Light Communications)

M2M/IoT and Visible Light Communications

出版商 Practel, Inc. 商品編碼 316348
出版日期 內容資訊 英文
商品交期: 最快1-2個工作天內
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M2M/IoT和可見光通訊(VLC:Visible Light Communications) M2M/IoT and Visible Light Communications
出版日期: 2014年10月16日 內容資訊: 英文
簡介

網際網路創造出稱為IoT(物聯網)的環境,提供無數的機器和物體的連接可能性。這整合M2M服務平台和WSN等各種技術。

本報告提供智慧感應器(SS)和無線SS,無線感測器網路(WSN)的發展情形,IoT(物聯網)及M2M通訊創造的TCP/IP所扮演的角色,無所不在網路的創造中的可見光通訊(VLC:Visible Light Communications的)重要性等相關驗證。

第1章 簡介

第2章 無線智慧感應器與WSN

  • IoT與M2M通訊:簡介
  • 情報:定義
  • 結構與零組件
  • 傳感器介面模組(TIM)
  • 支援網路應用處理器(NCAP:Network Capable Application Processor)
  • 趨勢
  • WSN:必要條件
  • 網路
  • 從WSN到USN

第3章 市場特異性:WSS/WSN

  • 前提條件
  • 調查結果
    • WSS統計
    • WSN統計

第4章 智慧物件IP

  • IETF、IP/WSN
    • Roots
    • 配合措施
      • 主要課題與解決方案
    • 主要計劃
      • 動機
    • 6LoWPAN WG
      • 定義
      • 規定
      • M2M、6LoWPAN
      • 引進的特異性
      • 詳細內容
      • 適應
      • 高層
      • 連接性
      • 產業的支援
      • NanoStack
    • ROLL WG
  • IPSO Alliance
  • 圖解:ISA100.11a:運作中的WSN-IP
    • ISA100
    • 核准
    • 展望
    • 基礎設施
    • 市場估計
  • 供應商
    • Cisco
    • Honeywell
    • Linear Technology
    • Nivis
    • NXP
    • Panasonic
    • Sensinode(ARM收購)
    • TI
    • 橫河電機

第5章 M2M通訊

  • 特殊需求
    • 頻譜
    • 摘要
  • 標準化:產業的配合措施
    • IEEE
    • ETSI
    • ITU
    • oneM2M Alliance
      • 服務層架構
      • 優點
    • Telefonica multi-Operators Alliance
    • M2M Alliance
    • OMA(Open Mobile Alliance)
    • GSC MSTF
    • Wave2M
      • 目的
      • 平台
    • 摘要
  • 市場
    • 資料
    • 估計
  • 產業的創新
    • Arqiva/Sensus
    • Kore Telematics
    • Link Labs
    • M2M Spectrum Networks
    • On-Ramp
    • SigFox/Telit
    • Telensa/Plextek

第6章 IoT

  • M2M和IoT
  • Open Interconnect Consortium
  • Industrial Internet Consortium
  • IoT:市場
  • IoT平台
  • IoT和ITU
  • IoT Forum
  • IEEE和IoT:P2413
  • ISO/IEC
  • 階層結構

第7章 IoT和可見光通訊(VLC)

  • VLC:IoT的中介
  • LED的特異性
    • 一般
    • 頻譜
  • 類型
  • LED調變
    • 規定
  • LED Evolution
    • 概要:雙重的功能
    • 發展的過程
    • 技術/經濟特性
  • 可見光通訊(VLC:Visible Light Communications)
    • 概要
    • 推進因素
    • 產業的配合措施
      • 案例:UC-Light Center
    • VLC規格的發展
    • IEEE 802.15.7
      • 考察
      • 計劃
    • JEITA(日本電子情報技術產業協會)
      • JEITA CP-1221
      • JEITA CP-1222
      • JEITA CP-1223 (2013)
    • 可見光傳播協會(VLCC)
      • 概要
      • 實驗的系統:VLCC計劃
    • ECMA 397-2010
    • Li-Fi Consortium
    • VLC途徑:詳細內容
      • 概要
      • 通訊途徑
      • 傳送器
      • 接收器
    • 主要的特徵
      • 概要
      • 調變
      • VLC途徑:特徵的摘要
      • 新興領域
      • 規定
    • 引進處:摘要
    • 企業、團體
      • ByteLight
      • 卡西歐
      • LVX
      • Luciom
      • 那賀川研究所
      • 日本電氣
      • Oledcomm
      • Omega Project
      • Outstanding Technology
      • PureLi-Fi
      • Renesas
      • Siemens
      • Supreme Architecture
      • TCL
      • 田村
    • 主要的引進處
      • ITS
      • 光無線LAN
      • 醫療
      • 本土化
      • 城市無線網路
      • 摘要
    • 市場

第8章 總論

圖表

目錄

Practel, Inc. has published several research/marketing reports on the Smart Sensors (SS) and Wireless SS (WSS) developments and, in particular, on their networking (Wireless Sensors Networks - WSNs). This report aims to further analyze WSS networking trends; with emphasis on the TCP/IP role in the creation the "Internet of things - IoT" and M2M communications. It also emphasizes the importance of Visible Light Communications in the creation of ubiquitous networking.

The Internet offers the potential to connect billions of machines and objects, creating what are known as the 'Internet of Things'(IoT). This integrates various technologies including, Machine-to-Machine service platforms and WSNs.

The sufficient part of this report is dedicated to the analysis of Visible Light Communications (VLC) and its role to support ubiquitous communications necessary for the IoT/M2M development. VLC is still in the starting position, but promises inexpensive, high-speed communications with a wide variety of applications to connect smart objects.

The report details standardization activity on IoT/M2M, analyzes their markets and the evolving industry.

Up-to-date analysis of VLC technologies, applications, markets and the industry shows the important role that is placed on this type communications in support of IoT/M2M.

This report is based on data and information sourced from proprietary databases, primary and secondary research and in-house analysis by Practel's team.

The report is written for a wide audience of technical, marketing and sale specialists working in the area WSN, IoT/M2M and VLC developments.

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.

Target Audience

This report is important for organizations involved in the development related to IoT/M2M and VLC technologies. They need to understand the market dynamics and to be familiar with vendors' portfolios to make a right choice in selection of equipment.

For vendors, this report provides valuable information on competition. It also supports these vendors with the market assessments.

Table of Contents

1.0Introduction

  • 1.1 General
  • 1.2 Scope and Goals
    • 1.2.1 Layered Approach
  • 1.3 Research Methodology
  • 1.4 Target Audience

2.0 Wireless Smart Sensors and WSN

  • 2.1 IoT and M2M Communications - Introduction
  • 2.2 Intelligence-Definition
  • 2.3 Structure and Components
  • 2.3.1 Transducer Interface Module (TIM)
  • 2.3.2 Network Capable Application Processor (NCAP)
  • 2.4 Trends
  • 2.5 WSN: Requirements
  • 2.6 Networking
  • 2.7 From WSN to USN

3.0 Market Specifics - WSS/WSN

  • 3.1 Assumptions
  • 3.2 Results
    • 3.2.1 WSS Statistics
    • 3.2.2 WSN Statistics

4.0 IP for Smart Objects

  • 4.1 IETF and IP/WSN
    • 4.1.1 Roots
    • 4.1.2 Efforts
      • 4.1.2.1 Major Issues and Solutions
    • 4.1.3 Major Projects
      • 4.1.3.1 Motivation:
    • 4.1.4 6LoWPAN WG
      • 4.1.4.1 Definition
      • 4.1.4.2 Limitations
      • 4.1.4.3 M2M and 6LoWPAN
      • 4.1.4.4 Applications Specifics
      • 4.1.4.5 Details
      • 4.1.4.6 Adaptation
      • 4.1.4.7 Upper Layers
      • 4.1.4.8 Connectivity
      • 4.1.4.9 Industry Support
      • 4.1.4.10 NanoStack
    • 4.1.5 ROLL WG
  • 4.2 IPSO Alliance
  • 4.3 Illustration: ISA 100.11a - WSN-IP at Work
    • 4.3.1 ISA100
    • 4.3.2 Approvals
    • 4.3.3 Scope
    • 4.3.4 Infrastructure
    • 4.3.5 Market Estimate
  • 4.4 Vendors
    • Cisco
    • Honeywell
    • Linear Technology
    • Nivis
    • NXP
    • Panasonic
    • Sensinode (acquired by ARM in 2013)
    • TI
    • Yokogawa

5.0 M2M Communications

  • 5.1 Special Needs
    • 5.1.1 Spectrum
    • 5.1.2 Summary
  • 5.2 Standardization - Industry Activities
    • 5.2.1 IEEE
    • 5.2.2 ETSI
    • 5.2.3 ITU
    • 5.2.4 oneM2M Alliance
      • 5.2.4.1 Service Layer Architecture
      • 5.2.4.2 Benefits
    • 5.2.5 Telefonica multi-Operators Alliance
    • 5.2.6 M2M Alliance
    • 5.2.7 Open Mobile Alliance (OMA)
    • 5.2.8 GSC MSTF
    • 5.2.9 Wave2M
      • 5.2.9.1 Aim
      • 5.2.9.2 Platform
    • 5.2.10 Summary
  • 5.3 Market
    • 5.3.1 Data
    • 5.3.2 Estimate
  • 5.4 Industry-Innovations
    • Arqiva/Sensus
    • Kore Telematics
    • Link Labs
    • M2M Spectrum Networks
    • On-Ramp
    • SigFox/Telit
    • Telensa/Plextek

6.0 IoT

  • 6.1 M2M and IoT
  • 6.2 Open Interconnect Consortium
  • 6.3 Industrial Internet Consortium
  • 6.4 IoT - Market
  • 6.5 IoT Platforms
  • 6.6 IoT and ITU
  • 6.7 IoT Forum
  • 6.8 IEEE and IoT - P2413
  • 6.9 ISO/IEC
  • 6.10 Layered Structure

7.0 IoT and Visible Light Communications (VLC)

  • 7.1 VLC - Bridge to IoT
  • 7.2 LED Specifics
    • 7.2.1 General
    • 7.2.2 Spectrum
  • 7.3 Types
  • 7.4 LED Modulation
    • 7.4.1 Limitations
  • 7.5 LED Evolution
    • 7.5.1 General - Dual Functionality
    • 7.5.2 Developments - History
    • 7.5.3 Technical/Economic Characteristics
  • 7.6 Visible Light Communications
    • 7.6.1 General
    • 7.6.2 Drivers
    • 7.6.3 Industry Activity
      • 7.6.3.1 Example: UC-Light Center
    • 7.6.4 VLC Standards Development
    • 7.6.5 The IEEE 802.15.7 Standard
      • 7.6.5.1 Considerations
      • 7.6.5.2 Project
        • 7.6.5.2.1 Coexistence
        • 7.6.5.2.2 Scope
        • 7.6.5.2.3 Base
        • 7.6.5.2.4 Use Cases
        • 7.6.5.2.5 Physical Layer
          • 7.6.5.2.5.1 General
          • 7.6.5.2.5.2 Responsibilities
          • 7.6.5.2.5.3 Types
          • 7.6.5.2.5.4 Error Protection
          • 7.6.5.2.5.5 Rates
          • 7.6.5.2.5.6 Frequency Plan
          • 7.6.5.2.5.7 PHY Services
          • 7.6.5.2.5.8. Regulations
        • 7.6.5.2.6 MAC Layer
          • 7.6.5.2.6.1 Responsibilities
          • 7.6.5.2.6.2 Functionalities
          • 7.6.5.2.6.3 Channel Access
        • 7.6.5.2.7 Security
    • 7.6.6 JEITA (Japan Electronics and Information Technology Industries Association
      • 7.6.6.1 JEITA CP-1221
      • 7.6.6.2 JEITA CP-1222
      • 7.6.6.3 JEITA CP-1223 (2013)
    • 7.6.7 Visible Light Communications Consortium (VLCC)
      • 7.6.7.1 General
      • 7.6.7.2 Experimental Systems- VLCC Projects
    • 7.6.8 ECMA 397-2010
    • 7.6.9 Li-Fi Consortium
    • 7.6.10 VLC Channel-Details
      • 7.6.10.1 General
      • 7.6.10.2 Communications Channel
      • 7.6.10.3 Transmitter
      • 7.6.10.4 Receiver
        • 7.6.10.4.1 Image Sensors
        • 7.6.10.4.2 LED as Receiver
    • 7.6.11 Major Characteristics
      • 7.6.11.1 General
      • 7.6.11.2 Modulation
      • 7.6.11.3 VLC Channel: Characteristics Summary
      • 7.6.11.4 Emerging Areas
      • 7.6.11.5 Limitations
    • 7.6.12 Applications: Summary
    • 7.6.13 Companies and Organizations
      • ByteLight
      • Casio
      • LVX
      • Luciom
      • Nakagawa Laboratories
      • NEC
      • Oledcomm
      • Omega Project
      • Outstanding Technology
      • PureLi-Fi
      • Renesas
      • Siemens
      • Supreme Architecture
      • TCL
      • Tamura
    • 7.6.14 Major Applications
      • 7.6.14.1 ITS
      • 7.6.14.2 Optical Wireless LAN
      • 7.6.14.3 Medical
      • 7.6.14.4 Localization
      • 7.6.14.5 City Wide Wireless Network
      • 7.6.14.6 Summary
    • 7.6.15 Market

8.0 Conclusions

  • Figure 1: Layered View
  • Figure 2: WSS Structure
  • Figure 3: TIM/NCAP and IEEE 1451
  • Figure 4: IoT Illustration
  • Figure 5: TAM - WSS Sales - Global ($B)
  • Figure 6: TAM: WSS Sales - Global (Mil. Units)
  • Figure 7: TAM: WSN Equipment Sales - Global ($B)
  • Figure 8: Standardization
  • Figure 9: 6LoWPAN Protocol Stack
  • Figure 10: Header Stacks
  • Figure 11: 6LoWPAN Network Scenario
  • Figure 12: ISA 100.11a Protocol Stack
  • Figure 13: TAM - ISA100.11a-based IA WSN ($M)
  • Figure 14: ETSI Activity
  • Figure 15: High-level Architecture
  • Figure 16: M2M Layers
  • Figure 17: Summary
  • Figure 18: M2M Applications
  • Figure 19: Projections: M2M Traffic Growth (PB/Month)
  • Figure 20: TAM: M2M Communications Revenue ($B)
  • Figure 21: TAM: Mobile Operators Revenue in M2M ($B)
  • Figure 22: TAM: M2M Communications - Satellite Segment ($B)
  • Figure 23: Projections: IoT Technologies and Applications Market ($T)
  • Figure 24: Projections - Number of Smart Devices in Households - Global (Bil. Units
  • Figure 25: IoT - Layered Structure
  • Figure 26: LED Structure
  • Figure 27: Spectrum (450-750 nm - visible)
  • Figure 28: LED Properties Illustration
  • Figure 29: TAM: U.S. LED Sales ($B)
  • Figure 30: TAM: U.S. LED Sales (Bil. Units)
  • Figure 31: Cost and Brightness- Light Sources
  • Figure 32: WPAN/WLAN Family and VLC
  • Figure 33: Illustration-VLC Channel
  • Figure 34: Applications
  • Figure 35: TAM: VLC Technology ($B)
  • Table 1: WSN - Major Short Range RF Technologies Characteristics
  • Table 2: Applications Segments (2014)
  • Table 3: Key M2M Elements
  • Table 4: Use Cases
  • Table 5: Wavelengths (nm)
  • Table 6: Laser vs. LED
  • Table 7: Use Cases
  • Table 8: Devices and Characteristics
  • Table 9: Frequency Plan
  • Table 10: VLC Properties
  • Table 11: VLC, IR and RF Communications ITS Applications Comparison
  • Table 12: Locations Technologies-VLC Place
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