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量子センサー市場:2018年以降の展望

Quantum Sensors Markets, 2018 And Beyond

出版日: | 発行: Inside Quantum Technology | ページ情報: 英文 | 納期: 即納可能 即納可能とは

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量子センサー市場:2018年以降の展望
出版日: 2019年01月14日
発行: Inside Quantum Technology
ページ情報: 英文
納期: 即納可能 即納可能とは
  • 全表示
  • 概要
  • 目次
概要

当レポートでは、量子センサー市場の展望を調査し、市場および技術の定義と概要、製品・技術の進化の動向、主なエンドユーズ産業および用途、主要製品・用途別の10カ年成長予測などをまとめています。

エグゼクティブサマリー

第1章 イントロダクション

第2章 製品・技術の進化

  • センサー産業の動向:量子センサー市場を推進
  • 量子センサー製品としての原子時計
    • 技術動向・10カ年予測
    • セシウム原子時計
    • ルビジウム原子時計
    • チップスケール原子時計 (CSAC)
    • 量子時計と光格子時計
    • 供給構造:ADVA・Microsemi・その他
  • 量子光検出器
    • 10カ年予測:量子光検出器
    • 単一光子検知器
    • PARセンサー
  • 量子磁力計
    • 10カ年収益予測
    • SQUID
    • SERF磁力計
    • NVセンター磁力計
    • プロトン磁力計・オーバーハウザー磁力計
    • 蒸気セル (光ポンピング) 磁力計
    • チップスケール原子磁力計
  • 量子重力計
    • 10カ年予測
    • 価格動向
    • 企業・ワーキンググループ
  • 量子ライダー・量子レーダー
    • 10カ年予測
    • 量子レーダー
    • 量子ライダー
  • 新興技術の量子センサー市場への影響
    • 量子技術のメカニカルセンサーへの影響
    • 量子センサーのための量子フォトニクス
    • 量子センサーとしての原子
    • 量子センサーとスピントロニクス
    • 量子電子顕微鏡の展望
  • 量子センサーの新素材
    • ダイヤモンド・ナノダイヤモンド
    • グラフェン
    • 炭化ケイ素
  • 本章の要点

第3章 10カ年予測:各種用途別

  • 輸送市場:自動運転車の用途・世界における位置づけ
    • 自動車産業における量子センサー
    • 自動運転車における量子ライダーの役割:10カ年予測
    • GPS:10カ年予測
    • 航空交通管制・空港用原子時計:10カ年予測
    • 輸送市場における量子重力センサー
  • 農業・造園・水産養殖
    • 農業・関連におけるPARセンサー:10カ年予測
  • ネットワーキング市場と原子時計へのニーズ
    • 公共通信網:10カ年予測
    • 電力産業:スマートグリッド - 10カ年予測
  • 金融取引における原子時計:タイムスタンプ
    • 10カ年予測
  • 建設・測量・石油&ガス
    • 石油・ガス市場向け量子センサー:10カ年予測
    • 建設市場向け重力センサー:10カ年予測
  • 医療・ヘルスケア
    • 10カ年予測
    • 脳磁図(MEG)
    • SQUIDの他の用途
    • 量子断層撮影
    • ヘルスケアにおける量子レーダーの利用
    • 医療におけるNVセンター磁力計の役割
    • 量子センサー・医療ウェアラブル:10カ年予測
  • 防衛・航空宇宙
    • PRCにおける量子技術
    • 10カ年予測
    • 軍における量子ナビゲーション
    • 量子レーダー/ライダー・その他の量子画像システム
    • 武器検出のための量子磁力計・重力計
  • 科学研究・R&Dにおける量子センサー
    • 量子情報科学・量子技術
    • 天文学・天体物理学
    • 地質・材料科学
    • 10カ年予測
  • 量子センサーとIoT
    • 10カ年予測
    • IoTにおける用途
  • 本章の要点
目次
Product Code: IQT-QS-0119

Quantum sensors are a class of sensors that offer a particularly high level of sensitivity based on certain quantum phenomena, such as quantum de-coherence and quantum entanglement. Some of these devices - such as PAR sensors - represent relatively mature technology. Others - gravity sensors and quantum LiDAR - are only beginning to make an impact. IQT Research believes, however, that all quantum sensor technology has strong commercial prospects ahead of it and that the business will benefit increasing levels of government and VC funding for quantum technology in general. There is also emerging technology - such as quantum photonics - that will lead to new kinds of sensor products being developed in the near future.

In this report:

IQT Research forecasts future technology evolution in the quantum sensors business and considers it from both the perspective of the conventional sensor industry and the budding quantum computing sector. Quantum sensors considered in this report include atomic clocks, single-photon detectors, PAR sensors, quantum LiDAR and quantum radar, gravity sensors, atomic interferometers, magnetometers, quantum imaging devices, spin-qubit-based sensors, and quantum rotation sensors. We also take a look at materials used for quantum sensors, especially diamond and graphene

We identify the primary opportunities in the quantum sensor space, exploring the commercial future of the technology and the firms that are supplying it. While these firms include many pure play sensor firms, IQT Research also notes that some industry giants have taken a stake in the sector including Bosch, Honeywell, HP, Microsemi, ST Microelectronics and Texas Instruments.

We examine in which end-user markets there will be the most significant opportunities including:

  • Transportation (Autonomous vehicles, navigation, GPS and air traffic control
  • Agriculture, horticulture and aquaculture
  • Networked industries (telecom and smart grids)
  • Construction and surveying
  • Financial trading
  • Medical imaging
  • Defense and aerospace
  • Research and development

This report also explores how quantum sensors will fit into the Internet-of-Things

IQT Research provides highly granular ten-year market forecasts in this report in both revenue and (where possible) volume shipment terms. Each type of quantum sensor is forecast with a breakout by application, and each end-user sector is forecast by the type of quantum sensors being used. The report also includes a breakout of the market for quantum sensors by the geographical regions in which they are located.

This report is part of a new series of IQT Research reports covering the commercial opportunities in the emerging markets for quantum computing products. Previous reports in this space include industry analysis studies on quantum key encryption, Quantum Networks and quantum computing.

Table of Contents

Executive Summary

  • E.1 Quantum Sensor Evolution: Three Generations and an Arms Race
    • E.1.1 Sensors and the Quantum Arms Race
    • E.1.2 Quantum Sensors: Mature and Novel
  • E.2 Emerging Demand for Quantum Sensors: Five Key Opportunities
    • E.2.1 Defense and Aerospace Markets for Quantum Sensors: Quantum Radar and Quantum Gravity Sensors
    • E.2.2 Opportunities for Next-Generation Atomic Clocks
    • E.2.3 Quantum Sensors in Construction and the Oil and Gas Industry
    • E.2.4 Medical Opportunities for Quantum Sensors
    • E.2.5 Agriculture, Horticulture and Aquaculture
    • E.2.6 Possible Future Markets for Quantum Sensors: Autonomous Vehicles and the Internet-of-Things
  • E.3 Market Potential for Quantum Sensors: Ten-year Forecasts
    • E.3.1 Summary of Ten-year Quantum Sensor Markets by Type of Sensor
    • E.3.2 Summary of Ten-year Quantum Sensor Markets by Type of End User/Application
    • E.3.3 Summary of Ten-year Quantum Sensor Revenues by Geography
  • E.4 Five Companies that will Shape the Future of the Quantum Sensor Business: Some Speculations

Chapter One: Introduction

  • 1.1 Background to this Report: Why Quantum Sensors Present a New Business Opportunity
    • 1.1.1 Two Ways to Consider Quantum Sensor Opportunities: "Quantum" and "Sensors"
    • 1.1.2 Quantum Sensors May be a Relatively Low-Risk Path for Quantum Technology Investment
    • 1.1.3 The Demand for Quantum Sensors Seems to be Real
  • 1.2 Objective and Scope of this Report
  • 1.3 Methodology of this Report
  • 1.4 Plan of this Report

Chapter Two: Products and Technology Evolution

  • 2.1 Sensor Industry Trends Also Drive the Quantum Sensors Market
  • 2.2 Atomic Clocks as Quantum Sensor Products
    • 2.2.1 Technology Trends and Ten-year Forecasts for Atomic Clocks
    • 2.2.2 Cesium Clocks and their Impact on International Weights and Measures
    • 2.2.3 Rubidium Clocks: Opening the Way to New Markets? 20
    • 2.2.4 Chip-scale Atomic Clocks (CSACs): The Miniaturization of Atomic Clocks
    • 2.2.5 Quantum Clocks and Optical Lattice Clocks
    • 2.2.6 Analysis of Supply Structure for Atomic Clocks: ADVA, Microsemi, and the Others
  • 2.3 Quantum Light Detectors
    • 2.3.1 Ten-year Forecast of Quantum Light Detectors
    • 2.3.2 Single-Photon Detectors
    • 2.3.3 PAR Sensors
  • 2.4 Quantum Magnetometers
    • 2.4.1 Ten-year Market Forecast of Revenues from Quantum Magnetometers
    • 2.4.2 SQUIDs
    • 2.4.3 SERF Magnetometers
    • 2.4.4 NV-center Magnetometers
    • 2.4.5 Proton Precession Magnetometers and Overhauser Magnetometers
    • 2.4.6 Vapor Cell (Optically Pumped) Magnetometers
    • 2.4.7 Chip-Scale Atomic Magnetometers
  • 2.5 Quantum Gravimeters
    • 2.5.1 Ten-year Forecasts of Quantum Gravimeters
    • 2.5.2 Price Declines and New Markets Possible
    • 2.5.3 Companies and Groups Working on Quantum Gravimeters
  • 2.6 Quantum LiDAR and Quantum Radar
    • 2.6.1 Ten-year Forecasts of Quantum Radar and Quantum LiDAR
    • 2.6.2 Quantum Radar
    • 2.6.3 Quantum LiDAR
  • 2.7 The Impact of Emerging Technologies on Quantum Sensor Markets
    • 2.7.1 The Impact of Quantum Technology on Mechanical Sensors
    • 2.7.2 Quantum Photonics for Quantum Sensors
    • 2.7.3 Atoms as Quantum Sensors
    • 2.7.4 Quantum Sensors and Spintronics
    • 2.7.5 Prospects for Quantum Electron Microscopy
  • 2.8 New Materials for Quantum Sensors
    • 2.8.1 Diamonds and Nano-diamonds
    • 2.8.2 Graphene
    • 2.8.3 Silicon Carbide
  • 2.9 Key Points from this Chapter

Chapter Three: Applications and Ten-year Forecasts

  • 3.1 Transportation Markets: Applications in Autonomous Vehicles and Global Positioning
    • 3.1.1 Quantum Sensors in the Automotive industry
    • 3.1.2 The Role of Quantum LiDAR in Autonomous Vehicles: Ten-year Forecasts
    • 3.1.3 Global Positioning Systems: Ten-year Forecasts
    • 3.1.4 Atomic Clocks for Air Traffic Control and Airports: Ten-year Forecasts
    • 3.1.5 Quantum Gravity Sensors in Transportation Markets
  • 3.2 Agriculture, Horticulture and Aquaculture
    • 3.2.1 The market for PAR Sensors in Agriculture and Related Markets: Ten-year Forecasts
  • 3.3 Networking Markets and the Need for Atomic Clocks
    • 3.3.1 Public Telecommunications Networks - Ten-year Forecasts
    • 3.3.2 Electricity Industry: Smart Grids - Ten-year Forecasts
  • 3.4 Atomic Clocks in Financial Trading: Timestamping Trades
    • 3.4.1 Ten-year Forecasts for Atomic Clocks in Financial Trading
  • 3.5 Markets for Quantum Sensors in Construction, Surveying, Oil and Gas: An Immediate Use for Quantum Gravity and Imaging Sensors
    • 3.5.1 Oil and Gas Markets for Quantum Sensors: Ten-year Forecasts
    • 3.5.2 Construction Markets for Gravity Sensors: Ten-year Forecasts
  • 3.6 Medical and Healthcare
    • 3.6.1 Ten-year Forecasts of Quantum Sensors in Medical and Healthcare
    • 3.6.2 Magnetoencephalography (MEG)
    • 3.6.3 Other Applications for SQUIDs in Medicine and Healthcare
    • 3.6.4 Quantum Tomography
    • 3.6.5 Use of Quantum Radar in Healthcare
    • 3.6.6 Role of NV-center Magnetometers in Medicine
    • 3.6.7 Quantum Sensors and Medical Wearables: Ten-year Forecast
  • 3.9 Defense and Aerospace Markets for Quantum Sensors
    • 3.9.1 Quantum Technology in the PRC
    • 3.9.2 Ten-year Forecasts of Quantum Sensors in Defense
    • 3.9.3 Quantum Navigation and the Military
    • 3.9.4 Quantum Radar/LiDAR and other Quantum Imaging Systems
    • 3.9.5 Quantum Magnetometers and Gravimeters for Weapons Detection
    • 3.9.6 Quantum Detectors for Quantum Key Distribution
  • 3.10 Markets for Quantum Sensors in Scientific Research and R&D
    • 3.10.1 Quantum Information Science and Quantum Technology
    • 3.10.2 Astronomy and Astrophysics
    • 3.10.3 Geology and Material Science
    • 3.10.4 Ten-year Forecasts of Quantum Sensors in Scientific Research
  • 3.11 Coda: Quantum Sensors and the Internet-of-Things
    • 3.11.1 Ten-year Forecasts of Quantum Sensors in the Internet-of-Things
    • 3.11.2 Applications for Quantum Sensors in the Internet-of-Things
  • 3.12 Key Points made in this Chapter

List of Exhibits

  • Exhibit E-1: Three Generations of Quantum Sensors
  • Exhibit E-2: Summary of Ten-year Forecasts of Quantum Sensor Markets, by Type of Sensor ($ Millions)
  • Exhibit E-3: Summary of Ten-year Forecasts of Quantum Sensor Markets, by Type of End User Market
  • Exhibit E-4: Summary of Ten-year Forecasts of Quantum Sensor Markets, by Geography
  • Exhibit E-5: Six Companies to Watch the Quantum Sensor Market: Some Speculations
  • Exhibit 1-1: Seven Reasons Why Quantum Sensors are an Emerging Business Opportunity
  • Exhibit 2-1: Ten-year Forecasts of Quantum Sensor Markets: Atomic Clocks
  • Exhibit 2-2: Ten-year Forecasts of Quantum Sensor Markets: Quantum Light Detectors
  • Exhibit 2-3: Types of Quantum Magnetometers: Appropriate Applications
  • Exhibit 2-4: Ten-year Forecasts of Quantum Sensor Markets: Quantum Magnetometers
  • Exhibit 2-5: Ten-year Forecasts of Quantum Sensor Markets: Quantum Gravimeters
  • Exhibit 2-6: Ten-year Forecasts of Quantum Sensor Markets: Quantum Radar and Quantum LiDAR
  • Exhibit 3-1: Ten-year Forecasts of Quantum LiDAR in Autonomous Vehicles
  • Exhibit 3-2: Ten-year Forecasts of Atomic Clocks in GPS Systems
  • Exhibit 3-3: Ten-year Forecasts of Atomic Clocks in Airports and Air Traffic Control
  • Exhibit 3-4: Ten-year Forecasts of Gravity Sensors in Transportation
  • Exhibit 3-5: Ten-year Forecasts of Quantum Sensor Markets: Agriculture, Horticulture Aquaculture
  • Exhibit 3-6: Synchronization Standards for Telecom Networks
  • Exhibit 3-7: Ten-year Forecasts of Atomic Clocks in Public Telecom Networks
  • Exhibit 3-8: Ten-year Forecasts of Atomic Clocks in Public Telecom Networks
  • Exhibit 3-9: Ten-year Forecasts of Quantum Sensor Markets: Financial Trading
  • Exhibit 3-10: Applications for Quantum Sensors in Construction, Surveying and the Oil and Gas Industry
  • Exhibit 3-11: Ten-year Forecasts of Quantum Sensor Markets: Oil and Gas
  • Exhibit 3-12: Ten-year Forecasts of Quantum Sensor Markets: Construction
  • Exhibit 3-13: Use of Quantum Sensors in Healthcare
  • Exhibit 3-14: Ten-year Forecasts of Quantum Sensor Markets: Medical Imaging
  • Exhibit 3-15: Ten-year Forecasts of Quantum Sensor Markets: Medical Wearables
  • Exhibit 3-16: Quantum Sensors in the Military
  • Exhibit 3-17: Ten-year Forecasts of Quantum Sensor Markets: Defense
  • Exhibit 3-18: Ten-year Forecasts of Quantum Sensor Markets: Science
  • Exhibit 3-19: Ten-year Forecasts of Quantum Sensor Markets: IoT
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