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市場調查報告書

IoT通訊的進步 - 技術、市場、應用

Advances in IoT Communications - Technologies, Markets and Applications

出版商 Practel, Inc. 商品編碼 620834
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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IoT通訊的進步 - 技術、市場、應用 Advances in IoT Communications - Technologies, Markets and Applications
出版日期: 2018年04月02日 內容資訊: 英文
簡介

本報告提供IoT/M2M通訊的新技術及相關市場相關調查,LPWA (省電力廣域) 通訊 (1 GHz以下),3GPP 蜂巢式 LPWA (LTE,GSM),產業團體/標準化機關等的分析、 各通訊協定分類的主要企業,市場預測等彙整資料。

第1章 簡介

第2章 IoT/M2M通訊規格

  • 概要
  • 環境
  • 現狀
  • 必要條件
  • 頻譜必要條件
  • 摘要

第3章 IoT用通訊技術的開發

  • 概要
  • Weightless 技術
    • Weightless SIG
    • Weightless 技術比較
  • RPMA
    • 主要的功能
    • 普及
    • 零組件、結構
    • 利用案例
  • LoRa
    • 聯盟
    • 技術結構要素
    • 產業
  • SigFox
    • 企業
    • 技術 - 詳細內容
    • 涵蓋範圍
    • 利用案例
    • 產業
  • Thread
    • 概要:從智慧家庭到商業大樓
    • 課題
    • 通訊協定
    • 主要的功能
    • 規格的摘要
    • 零組件
    • 產業
    • 比較

第4章 IoT技術:現有技術的引進

  • Wi-Fi
    • IoT通訊和Wi-Fi
    • 802.11ah (Wi-Fi HaLow)
  • 3GPP、IoT通訊
    • 3GPP的地位
    • IoT的通訊必要條件和LTE
    • LTE Rel. 12的開發與IoT通訊
    • 3GPP LTE Rel. 13/14的開發與IoT通訊
    • 進一步強化
    • LTE/IoT 功能的摘要
    • NB-IoT的標準化
    • 涵蓋範圍的擴張 - GSM - 物聯網 (EC-GSM-IoT)
    • 產業
    • 摘要 - 比較
  • Bluetooth Mesh
    • 概要
    • 規格
    • 可能性
    • 主要的功能
    • 優點
    • 產業

第5章 全球標準化組織

  • ETSI
    • 配合措施
    • 低容許量網路
  • ITU
    • SG 20
  • oneM2M
  • ISO/IES
  • IEEE P2413

第6章 IoT通訊:市場發展

  • 統計
  • 估計
    • IoT/M2M 通訊量
    • IoT/M2M 通訊市場
    • IoT連接
    • IoT通訊服務
    • 蜂巢式IoT用戶
    • IoT/M2M 技術、應用市場
    • 智慧家庭:IoT/M2M 設備數
    • 全球LPWAN市場

第7章 結論

附錄AI-IV

目錄

This report addresses novel technologies and related markets designed for IoT/M2M communications.

Due to multiplicity of factors that should be considered in the developing IoT networks (applications, battery requirements, and traffic specifics, etc.) there is only a very remote possibility that a single technology will resolve all IoT communications issues. So far, the picture is very fragmented with multiple organizations developing specific technologies.

There are two main tracks to wide-area public-network connectivity. The first is the evolution of LTE (and some other cellular technologies) to support IoT applications: longer battery life, longer range, lower cost in exchange for lower throughput. The second track includes narrow-band (NB) and ultra-narrow band (UNB) technologies promoted as a clean slate solution for IoT connectivity.

Mesh technologies (typically based on ZigBee) and Wi-Fi extensions (e.g. 802.11ah) have typically been used in private networks and have a separate evolution path (as examples, the report addresses 802.11ah, Bluetooth Mesh and Thread). Bluetooth Mesh is bringing many important to IoT communications features utilizing well established hardware platforms.

New proprietary technologies, such as LoRa, SigFox and other came into the market before standardized technologies; and they have already gained the sufficient market share. 3GPP standards are being approved gradually in Releases 12-14.

Despite of this, it is expected that modified LTE and GSM will be able relatively fast to gain power- for these techniques, vast amount of cellular infrastructure is ready, and adaption to IoT communications requirements can be done usually through software upgrade. The report compares advantages and weaknesses of each method.

For the purpose of this report analysis, we distinguished the following groups of technologies:

1. Low Power Wide Area (LPWA) communications (Sub-1 GHz):

  • LoRA
  • SigFox
  • Weightless (W, N, P)

2. 3GPP cellular LPWA (LTE, GSM):

  • NB-IoT
  • LTE Cat - M
  • EC-GSM-IoT
  • Other

3. Industry Groups/Standardizations Organizations:

  • IEEE802.11ah (Sub-1 GHz)
  • Thread
  • Bluetooth Mesh
  • ETSI LTN
  • Ingenu.

LPWA communication is split into two separate sub-categories. On the one hand, there are the current proprietary LPWA technologies, such as SigFox and LoRa, which typically operate on unlicensed sub -1 GHz spectrum. On the other hand, there are the forthcoming 3GPP standardized cellular IoT technologies, which typically operate on licensed spectrum (3GPP Rel. 12, 13 and up).

Designed specifically for low bandwidth, low-power IoT applications, LPWAs structures are poised to see huge growth over the next few years, with stakeholders across the industry now talking about LPWA technologies as a core enabler of the IoT.

LPWA profile IoT applications include metering, agriculture, vehicle telematics, tracking, healthcare, consumer products, and others. It is estimated that 3-4 billion LPWA connections will be in place by 2020, with hardware, network and service revenues reaching $9-$11 billion.

The report also analyzes the related work of such standards bodies as the IEEE, ITU, ETSI and other.

The report goals are also to identify major players in each protocol category; and estimate (5-year forecast) major marketing characteristics of still young IoT communications industry.

The survey of related patents is also presented in the report.

The report was developed for a wide audience of managerial and technical staff of organizations that are working on IoT/M2M communications projects.

Table of Contents

1.0 Introduction

  • 1.1 Definition
  • 1.2 General
  • 1.3 Scope
    • 1.3.1 Major Goal
  • 1.4 Research Methodology
  • 1.5 Target Audience

2.0 IoT/M2M Communications Specifics

  • 2.1 General
    • 2.1.1 Main Tracks
  • 2.2 Environment
  • 2.3 Current Situation
  • 2.4 Requirements
  • 2.5 Spectrum Requirements
  • 2.6 Summary

3.0 Developing Communications Technologies for IoT

  • 3.1 General
  • 3.2 Weightless Technologies
    • 3.2.1 Weightless SIG
      • 3.2.1.1 Common Features
      • 3.2.1.2 Weightless-W
        • 3.2.1.2.1 White Spaces Communications - Principles
        • 3.2.1.2.2 Definition
        • 3.2.1.2.3 Rational
        • 3.2.1.2.4 Ecosystem and Use Cases
        • 3.2.1.2.5 Weightless-W Details
      • 3.2.1.3 Changes
      • 3.2.1.4 Weightless-N
        • 3.2.1.4.1 General
        • 3.2.1.4.2 Open Standard
        • 3.2.1.4.3 Nwave
        • 3.2.1.4.4 Initial Deployments
        • 3.2.1.4.5 Summary
      • 3.2.1.5 Weightless-P
        • 3.2.1.5.1 General
        • 3.2.1.5.2 Details
        • 3.2.1.5.3 M2COMM
    • 3.2.2 Comparison of Weightless Technologies
  • 3.3 RPMA
    • 3.3.1 Major Features
    • 3.3.2 Proliferation
    • 3.3.3 Components and Structure
    • 3.3.4 Use Cases
  • 3.4 LoRa
    • 3.4.1 Alliance
      • 3.4.1.1 Open Protocol
    • 3.4.2 Technology Building Blocks
      • 3.4.2.1 Layered Structure - Illustration
      • 3.4.2.2 Modulation
      • 3.4.2.3 Long Range
      • 3.4.2.4 Applications
      • 3.4.2.5 Network Architecture
      • 3.4.2.6 Classes
      • 3.4.2.7 LoRaWAN
      • 3.4.2.8 Major Characteristics
    • 3.4.3 Industry
      • Actility
      • Advantech
      • Amiho
      • Cisco
      • Embit
      • Kerlink
      • Link Labs
      • LORIOT.io
      • Microchip Technology
      • MultiTech
      • Murata
      • Sagemcom
      • Semtech
      • STMicroelectronics
      • Tektelic
  • 3.5 SigFox
    • 3.5.1 Company
    • 3.5.2 Technology - Details
      • 3.5.2.1 Uplink
      • 3.5.2.2 Downlink
      • 3.5.2.3 SmartLNB
    • 3.5.3 Coverage
    • 3.5.4 Use Cases
    • 3.5.5 Industry
      • Adeunis RF
      • Atmel (acquired by Microchip in 2016)
      • Innocomm
      • Microchip
      • On Semiconductor
      • Telit
      • TI
  • 3.6 Thread
    • 3.6.1 General: From Smart Home to Commercial Buildings
    • 3.6.2 Challenges
    • 3.6.3 Protocol
    • 3.6.4 Major Features
    • 3.6.5 Specification Summary
    • 3.6.6 Components
    • 3.6.7 Industry
      • CEL
      • Digi
      • NXP (Qualcomm)
      • Silicon Labs
    • 3.6.8 Comparison

4.0 IoT Communications: Adaption Existing Technologies

  • 4.1 Wi-Fi
    • 4.1.1 IoT Communications and Wi-Fi
    • 4.1.2 802.11ah (Wi-Fi HaLow)
      • 4.1.2.1 Requirements
      • 4.1.2.2 Goal and Schedule
      • 4.1.2.3 Attributes
      • 4.1.2.4 Use Cases
      • 4.1.2.5 PHY
        • 4.1.2.5.1 Bandwidth
        • 4.1.2.5.2 Channelization
        • 4.1.2.5.3 Transmission Modes and MIMO
        • 4.1.2.5.4 Relay Mode
      • 4.1.2.6 MAC Layer
      • 4.1.2.7 Summary
      • 4.1.2.8 Industry
      • Aviacomm/Newracom
      • Morse Micro
      • Orca
      • Aegis-IP
  • 4.2 3GPP and IoT Communications
    • 4.2.1 3GPP Position
    • 4.2.2 IoT Communications Requirements and LTE
    • 4.2.3 3GPP LTE Rel. 12 Developments and IoT Communications
    • 4.2.4 3GPP LTE Rel. 13/14 Developments and IoT Communications
    • 4.2.5 Further Enhancements
    • 4.2.6 Summary of LTE/IoT Features
    • 4.2.7 NB-IoT Standardized
      • 4.2.7.1 Scope
        • 4.2.7.1.1 Scalable LTE IoT Platform
    • 4.2.8 Extended Coverage - GSM - Internet of Things (EC-GSM-IoT)
    • 4.2.9 Industry
      • Altair (Sony Group Company)
      • Aeris
      • Ericsson
      • Gemalto
      • Kore Telematics
      • Mistbase (acquired by ARM in 2017)
      • Orca
      • Sequans
      • Qualcomm
      • u-blox
      • WNC
    • 4.2.9 Summary - Comparison
  • 4.3 Bluetooth Mesh
    • 4.3.1 General
    • 4.3.2 Specifications
      • 4.3.2.1 Mesh Profile Specification
      • 4.3.2.2 Mesh Model Specification
      • 4.3.2.3 Mesh Device Property Specification
    • 4.3.3 Potentials
      • 4.3.3.1 Concept
    • 4.3.4 Major Features
    • 4.3.5 Benefits
    • 4.3.6 Industry

5.0 Global Standardization Organizations

  • 5.1 ETSI
    • 5.1.1 Efforts
    • 5.1.2 Low Throughput Network
      • 5.1.2.1 Weightless and ETSI
  • 5.2 ITU
    • 5.2.1 SG 20
  • 5.3 oneM2M
  • 5.4 ISO/IES
  • 5.5 IEEE P2413

6.0 IoT Communications - Market Development

  • 6.1 Statistics
  • 6.2 Estimate
    • 6.2.1 IoT/M2M Traffic Volume
    • 6.2.2 IoT/M2M Communications Market
    • 6.2.3 IoT Connections
    • 6.2.4 IoT Telecom Services
    • 6.2.5 Cellular IoT Subscribers
    • 6.2.6 IoT/M2M Technologies and Applications Market
    • 6.2.7 Smart Home - Volume of IoT/M2M Devices
    • 6.2.8 Global LPWAN Market

7.0 Conclusions

Attachment I: 802.11ah - related Patents Survey (2016-2018)

Attachment II: LPWAN - related Patents Survey (2016-2018)

Attachment III: LoRa - related Patents Survey (2016-2018)

Attachment IV: Comparison

  • Figure 1: IoT Environment
  • Figure 2: Iceni Characteristics
  • Figure 3: Nwave Characteristics Comparison
  • Figure 4: Weightless Technologies Comparison
  • Figure 5: RPMA Use Cases
  • Figure 6: LoRa Protocol Architecture
  • Figure 7: LoRa Architecture
  • Figure 8: LoRa Classes
  • Figure 9: Battery Lifetime
  • Figure 10: Regional Differences
  • Figure 11: Uplink Frame Format
  • Figure 12: Downlink Frame Format
  • Figure 13: Thread Protocol Stack and Related Standards
  • Figure 14: Thread Protocol Major Features
  • Figure 15: 802.11ah Use Cases
  • Figure 16: Frequency Spectrum (sub-1 GHz)
  • Figure 17: 802.11ah - Channelization Plan in U.S.
  • Figure 18: Transmission Characteristics - 802.11ah
  • Figure 19: 802.11ah Features Summary
  • Figure 20: CAT-0 and CAT-1 Characteristics
  • Figure 21: Time Schedule - 3GPP
  • Figure 22: Modem Complexity
  • Figure 23: IoT Communications Technologies Characteristics Comparison
  • Figure 24: Evolution of LTE IoT Communications
  • Figure 25: Cellular-based IoT Technologies
  • Figure 26: IoT Communications Technologies Comparison
  • Figure 27: BT Mesh Architecture
  • Figure 28: ETSI Activity - IoT/M2M Communications
  • Figure 29: Use Cases
  • Figure 30: M2M Applications
  • Figure 31: Estimate - IoT/M2M Traffic Volume (PB/Month)
  • Figure 32: Estimate: Global Market - IoT/M2M Communications ($B)
  • Figure 33: Estimate: Number of IoT Connections (Bil.)
  • Figure 34: Estimate: IoT Telecom Services - Global ($B)
  • Figure 35: Estimate: Number of Cellular IoT Subscribers (Bil.)
  • Figure 36: Estimate: IoT/M2M Technologies and Applications Market - Global ($T)
  • Figure 37: Estimate: Number of Smart Devices in Smart Homes-Global (Bil.)
  • Figure 38: Estimate - Global LPWAN Market ($B)
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