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市場調査レポート

世界の中赤外センサー市場:戦略・予測 2016-2022年

Mid IR Sensors: Market Strategies and Forecasts, Worldwide, 2016-2022

発行 WinterGreen Research, Inc. 商品コード 219337
出版日 ページ情報 英文 529 Pages
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世界の中赤外センサー市場:戦略・予測 2016-2022年 Mid IR Sensors: Market Strategies and Forecasts, Worldwide, 2016-2022
出版日: 2016年07月09日 ページ情報: 英文 529 Pages
概要

当レポートでは、世界の中赤外センサー市場の現状と見通しについて調査分析し、中赤外センサーのエンドユーズ産業・応用分野・応用製品/システム、実現技術・応用技術、中赤外レーザーの市場シェア推計、出荷高および出荷台数の予測、主要製品の概要、主要企業のプロファイルなどをまとめ、お届けいたします。

エグゼクティブサマリー

第1章 市場概要・市場力学

  • 中赤外センサーは波長同調性・高光パワーを提供する位置に
  • 赤外線分光法
  • 赤外線センシングサーモバイルのアプリケーション
  • 軍用中赤外センサー
  • 中赤外波長で動作する半導体ダイオードレーザー
  • 赤外半導体レーザー
  • 中赤外センサー型ビルシステムは高価なビル管理システムにとって代わる
  • ビル管理の標準化
  • バイオメディカル・ケミカル中赤外SPR型センサー
  • 中赤外センサー用途の新しい分野と見通し
  • ゾルゲル法コーティングによる中赤外光ファイバーセンサー
  • 飲食部門向け磁性ナノ粒子中赤外病原菌センサー

第2章 市場のシェア・予測

  • 中赤外レーザーセンサーシステム
  • 中赤外センサーの市場シェア
  • 中赤外センサーの市場予測
  • 中赤外センサーの用途
  • 中赤外センサーの市場機会
  • 近赤外光学の区分
  • 中赤外センサーのサンプル価格
  • 中赤外センサーの地域別出荷高

第3章 製品概要

  • FLIR
  • IP Control
  • Daylight Solutions
  • SenseAir
  • Acuity Brands Inc.
  • Structured Materials Industries
  • Block Engineering
  • Sofradir
  • Ekips Technologies
  • JonDeTech AB
  • Micropelt
  • EnOcean
  • Agiltron / SensArrayInfrared
  • Mirthe
  • Emerson / Cascade Technologies
  • Bosh
  • Thorlabs/ Maxion
  • VIASPACE Ionfinity
  • Power Technology
  • M Squared
  • Thermo Fischer Scientific / NovaWave Technologies
  • GE
  • PNNL
  • 浜松ホトニクス
  • AdTech Optics
  • Opto Solutions
  • Sentinel Photonics
  • Newport Corporation /ILX Lightwave
  • Aerocrine
  • Telops、ほか

第4章 技術

  • 動力技術の中赤外センサー用途
  • 小型中赤外センサー技術の動向
  • 赤外線医術
  • 量子カスケードレーザー (QCL) の線幅・同調性
  • 用途
  • 中赤外レーザー分光
  • 地雷の遠隔検知
  • サーモパイル
  • ナノ粒子分散
  • 中赤外レーザーによる狭い波長の放出
  • 顕微鏡法の技術動向
  • 中赤外センサーのバッテリー技術
  • 呼気分析器による疾患の検出
  • 医療用インプラント向けバイオマテリアルの改良
  • QC技術
  • 中赤外トレースガスセンサーの概略図
  • 中赤外センサー規格
  • ビルオートメーションの促進要因
  • 近赤外線ナイトビジョンセンサー
  • 中赤外による非侵襲性医療システム
  • University of Oklahomaのハイテク呼気検査
  • 物理蒸着によるナノ粒子の合成
  • MIRTHEのロードマップ

第5章 企業プロファイル (57社)

図表

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目次
Product Code: SH25722114

Next generation Mid IR Sensors are leveraging new technology. The 2016 study has 885 pages, 390 tables and figures. Worldwide mid IR sensor markets are poised to achieve significant growth as the Internet of things creates demand for more and more sensors. Everything needs a sensor to be connected to the Internet and available to smart phone apps.

Mid IR sensors can measure chemical composition of materials and gas. The efficiency is unmatched by any other technology; cost is increasingly competitive. Mid IR is extending use beyond military applications to commercial systems, including the Internet of things where sensors become part of network systems.

Mid IR sensors are the base of the Internet of Things initiatives, they form the building blocks for all different types of imaging and controls. Drones, robots, industrial robots, machines, cameras, buildings, fire departments, traffic lights, traffic control, the military, the border patrol, law enforcement, healthcare, asthma treatment, virtually everyone will increasingly use mid IR sensors.

The Internet of Things (IoT) does not work without sensors, mid IR sensors provide a significant aspect of modern visualization and sensing. Drones use mid IR sensors for cameras and for navigation. Robots use mid IR cameras for navigation. The intelligence community has used this mid IR sensor technology for a long time and the technology is now gaining traction in the commercial markets.

Mid IR sensors can measure chemical composition of materials and gas. The efficiency is unmatched by any other technology; cost is increasingly competitive. Mid IR has extended use beyond military applications to commercial systems, including the Internet of things where sensors become part of network systems.

Mid-IR QCL systems have achieved price performance levels that are increasingly attractive. Vendors bring sensing capabilities to a broad range of applications, including: spectroscopic and bio-medical imaging; materials characterization; standoff explosive detection; microscopy; and non-destructive testing. Spectroscopy and imaging measurements are easier, faster and more cost-effective leveraging advances in mid IR sensing.

Mid-infrared sensors and imaging applications depend on quantum cascade laser (QCL) technology. Daylight Solutions quantum cascade laser (QCL) technology has been delivered to more systems for more customers in more applications than all other QCL-based solutions combined. Advances in QC laser technology and spectrometer hardware are combined with spectroscopic techniques. Intra pulse spectroscopy and similar techniques provide a major step change in sensitivity, speed of operation, fingerprinting capability, size and cost. They offer a major improvement on methods of gas detection. Recent advances in spectrometer hardware relate to QC gas sensors.

Advances exploit recent technological advances including miniaturized integrated electronic systems, plug and play interfaces and micro optics. These will progressively replace unwieldy, fragile and expensive instrumentation. The lasing wavelength for QCL's is determined by the choice of semiconductor material. By adjusting the physical thickness of the semiconductor layers new functionality is achieved. This removes the material barriers associated with conventional semiconductor laser technology.

An infrared spectroscopic laser source has no need for cryogenic cooling, provides high output powers, has large spectral coverage, provides excellent spectral quality, and has good tunability. The removal of the noise floor provides competitive advantage because it can be implemented without the need of complex fringe removal techniques. It can be done without expensive optical isolators. The feature that allows manageable removal of the noise floor enables the laboratory performance of technology to be commercialized.

Mid IR analyzers in process control are expected to save trillions of Btus annually in the petrochemical sector. Process control and environmental monitoring potential applications are evolving for this technology.

Examples of mid IR applications follow.

  • Combustion emissions analysis
  • Fugitive emissions control
  • Contraband detection
  • Improved safety conditions for plant workers
  • On-site detection of chemicals

Medical applications include human breath monitoring, glucose sensing, cancer detection and diagnostics, eye surgery, and environmental health monitoring. Medical and industrial monitoring utilizes trace detection of benzene, toluene or xylene. Medical applications account for a growing mid-IR laser market. The medical area is evolving in both diagnostics and treatment. Improved diagnostics are made possible through photonic technologies. Mid IR sensors deliver a better understanding of disease: Optical molecular imaging is anticipated to be significant.

Mid IR sensors hold the possibility of making medicine much more advanced because of the visibility into patient conditions that will be possible. As visibility into patient condition is refined, so also remedies will be much more refined. Energy efficiency and clean, renewable energy will mean a stronger economy, a cleaner environment, and greater energy independence. Working with a wide array of state, community, industry, and university partners, the U.S. Department of Energy's Office of Energy Efficiency and Renewable Energy invests in a diverse set of energy technologies.

Mid-IR sensor systems have achieved price to performance levels adequate to assure rapid adoption. Capabilities address a broad range of applications, including: location of people as targets, spectroscopic and bio-medical imaging; materials characterization; standoff explosive detection; microscopy; non-destructive testing. Spectroscopy, and imaging measurements. These are easier, faster, and cost-effective.

Military applications account for a significant portion of mid IR sensor markets. The remaining part of revenue comes from CO2 sensors, building sensors, and units for a range of different markets. Markets at $4.19 billion in 2015 are anticipated to reach $30 billion by 2022 as price performance increases and unit costs decrease from $3,000 per unit to $2,000 per high end unit. $300 per mid-range sensor has dropped to $200. $8 has dropped to $6 per unit providing price points that make the sensors affordable. or less per unit on average drive further interest from commercial buyers.

The decrease in size of units from bench size devices to portable units makes them more useful across the board in every industry.

Table of Contents

MID IR SENSORS EXECUTIVE SUMMARY

  • Mid-Infrared (IR) Laser Sensor Systems
    • Quantum Cascade Laser (QCL)
    • High-Performing Tunable External Cavity Tunable Laser
    • Mid IR Sensor Market Driving Forces
    • Benefits of Mid IR Sensors
  • Mid IR Sensor Market Shares
  • Mid IR Sensor Market Forecasts

1. MID IR SENSOR MARKET DESCRIPTION AND MARKET DYNAMICS

  • 1.1. Mid IR Sensors Positioned To Provide Wavelength Tunability And High Optical Power
    • 1.1.1. ECqcL Expressed As A QC Semiconductor Chip
    • 1.1.2. Advances Of Mid-Infrared Based Trace Gas Sensor
  • 1.2. Infrared Spectroscopy
    • 1.2.1. FTIR Spectroscopy Used To Establish Purity Of Chemical Compounds
  • 1.3. Applications of Infrared Sensing Thermopiles
    • 1.3.1. Process Controls Using Mid IR Sensors: Preventive and Predictive Maintenance 88
    • 1.3.2. Residential Control Systems
    • 1.3.3. White Goods (Home Appliances)
    • 1.3.4. Medical and Health
    • 1.3.5. Industrial Process Control
    • 1.3.6. Security and Surveillance
    • 1.3.7. Mid-Infrared Sensor Applications
    • 1.3.8. Clinical Requirements and Markets for Medical Mid-IR Products
    • 1.3.9. Mid IR Sensors Implement IoT on Smart Phones
    • 1.3.10. Integrated IoT Change Management
    • 1.3.11. Sensors Play A Role In Research On The Role Of Ammonia In Air Quality
  • 1.4. Mid IR Sensors for the Military
    • 1.4.1. Daylight Solutions and Northrop Grumman Partner for Missile Warning Systems
    • 1.4.2. Mid IR Sensor Target Acquisition Minefield Detection System
  • 1.5. Semiconductor Diode Lasers Operating At Midwave-Infrared (Mid-IR) Wavelengths
  • 1.6. Infrared Semiconductor Lasers
  • 1.7. Mid IR Sensor Based Building Systems Replace Expensive Building Control Systems
  • 1.8. Building Control Standardization
  • 1.9. Biomedical And Chemical Mid-IR SPR Based Sensor
    • 1.9.1. Development Of Mid-Infrared Surface Plasmon
    • 1.9.2. Sensors Utilizing Surface Plasmon Resonance (SPR)
    • 1.9.3. Mid IR Waveguides
    • 1.9.4. Miniaturized IR Gas Sensors
  • 1.10. Emerging New Fields of Mid IR Sensor Application And Outlook
  • 1.11. Sol-Gel-Coated Mid-Infrared Fiber-Optic Sensors
  • 1.12. Magnetic Nanoparticle Mid-Infrared Pathogen Sensor for Food Matrixes

2. MID IR SENSORS MARKET SHARES AND MARKET FORECASTS

  • 2.1. Mid-Infrared (IR) Laser Sensor Systems
    • 2.1.1. Quantum Cascade Laser (QCL)
    • 2.1.2. High-Performing Tunable External Cavity Tunable Laser
    • 2.1.3. Mid IR Sensor Market Driving Forces
    • 2.1.4. Benefits of Mid IR Sensors
  • 2.2. Mid IR Sensor Market Shares
    • 2.2.1. Mid IR Sensor Market Share Analysis
    • 2.2.2. Infrared Radiation Variation of Measuring Techniques
    • 2.2.3. FLIR Systems Multi-Sensor Mission Equipment
    • 2.2.4. FLIR Sensing Materials
    • 2.2.5. GE Sensors / SenseAir
    • 2.2.6. Senseair Test & Measurement Carbon Dioxide Sensors
    • 2.2.7. SenseAir Test & Measurement Carbon Dioxide Sensors
    • 2.2.8. Structured Materials Industries
    • 2.2.9. Daylight Solutions FTIR Spectroscopy
    • 2.2.10. Sofradir
    • 2.2.11. JonDeTech AB Applications of Infrared Sensing Thermopiles
    • 2.2.12. Agiltron
    • 2.2.13. Aerocrine
    • 2.2.14. Bosch
    • 2.2.15. Block Engineering
    • 2.2.16. II-VI Incorporated (NASDAQ: IIVI)
    • 2.2.17. MIRTHE Center
    • 2.2.18. Infrared Fiber Systems Infrared Transmitting Fibers Medical Market
    • 2.2.19. M Squared Next-Generation Bio-Medical Lasers Firefly-IR
    • 2.2.20. Raytheon and Lockheed Drone Mid-Infrared Lasers
    • 2.2.21. Market Consolidation of Mid IR Sensor Companies
  • 2.3. Mid IR Sensor Market Forecasts
    • 2.3.1. Mid IR Sensors Market Forecasts, Units
    • 2.3.2. Mid IR Sensors: Dollars and Units, High End, Mid Range, and Low End, Shipments, Worldwide, 2013-2019
    • 2.3.3. Mid IR Spectrum Unit Size Categories
  • 2.4. Mid IR Sensor Applications
    • 2.4.1. Military Mid IR Sensors
    • 2.4.2. Military Mid IR Sensor Market Forecasts
    • 2.4.3. Military and Border Patrol Mid Infrared (IR) Sensors Market Forecasts
    • 2.4.4. Automotive Sector Mid IR Sensor Market Shares
    • 2.4.5. Automotive Mid IR Sensor Market Forecasts
    • 2.4.6. Smart Building Mid IR Sensor Market Shares
    • 2.4.7. Smart Building Mid IR Sensor Market Forecasts
    • 2.4.8. Laser Mid IR Sensor Market Shares
    • 2.4.9. Laser Mid IR Sensor Market Forecasts
    • 2.4.10. Thermal Camera Mid IR Sensor Market Shares
    • 2.4.11. Thermal Camera Mid IR Sensor Market Forecasts,
    • 2.4.12. Occupancy Mid IR Sensors and Photocell Devices Market Shares
    • 2.4.13. Occupancy Mid IR Sensors and Photocell Devices Market Forecasts
    • 2.4.14. Oil and Gas Mid IR Sensor Market Shares
    • 2.4.15. Oil and Gas Mid IR Sensor Market Forecasts
    • 2.4.16. CO2 Mid IR Sensor Market Shares
    • 2.4.17. Carbon Dioxide Gas Mid IR Sensing Market Forecasts
    • 2.4.18. Nitric Oxide (NO) Mid IR Sensor Market Shares
    • 2.4.19. Nitric Oxide (NO) Mid IR Sensor Market Forecasts
    • 2.4.20. Healthcare Screening Using Commercial Mid IR Sensors
    • 2.4.21. Healthcare Breathalizer Mid IR Sensor Markets
    • 2.4.22. Machine Process Measuring and Detection Sensors Using Mid IR, Market Shares
    • 2.4.23. Machine Process Measuring And Detection Sensors Using Mid IR, Market Forecasts
    • 2.4.24. Fire Gas Detection Mid IR Sensors Market Shares
    • 2.4.25. Fire Gas Detection Mid IR Sensors Market Forecasts
    • 2.4.26. Temperature Mid IR Sensors Market Shares
    • 2.4.27. Temperature Mid IR Sensors Market Forecasts
    • 2.4.28. Automation Using Mid IR Sensors
    • 2.4.29. Security and Homeland Security Mid IR Sensors
    • 2.4.30. Law Enforcement Mid IR Sensor Markets
    • 2.4.31. Smart Electrical Grid Moves to Electronics and Sensors from Purely Mechanical Infrastructure
    • 2.4.32. Smart Grid Networking
    • 2.4.33. Mid Infrared IR Sensor Technologies Basis for Measuring Chemical Composition 208
    • 2.4.34. Nanoparticles The Base For Mid IR Sensor Evolution
    • 2.4.35. Miniaturization Significant For The Development Of Mid IR Applications 210
  • 2.5. Mid IR Sensor Market Opportunity
    • 2.5.1. Mid IR Sensors: Dollars and Units, High End, Mid Range, and Low End, Shipments, Worldwide, 2016-2022
    • 2.5.2. Integration Software Market Driving Forces
    • 2.5.3. Building a Robust Data Sensor Network Integration Layer
    • 2.5.4. Internet Network Base for Sensor Data Consolidation
    • 2.5.5. Mid IR Sensor Enabled Device Market Driving Forces
    • 2.5.6. Smart Phone Apps Implement a Transaction Based Mid IR Sensor Services Distribution Network
  • 2.6. Near-Infrared Optics Segment
  • 2.7. Mid IR Sensor Sample Prices
    • 2.7.1. SenseAir® NDIR (Non-dispersive Infra-Red) Technology
    • 2.7.2. MIRTHE QC Laser Based Sensors
    • 2.7.3. JonDeTech
    • 2.7.4. Aerocrine
  • 2.8. Mid IR Sensor Regional Shipments

3. MID IR SENSORS PRODUCT DESCRIPTION

  • 3.1. FLIR
    • 3.1.1. FLIR Thermal Sensors for Traffic Applications
    • 3.1.2. FLIR TrafiOne
    • 3.1.3. FLIR Smart City Sensor
    • 3.1.4. FLIR TrafiSense
    • 3.1.5. FLIR Intersection Control
    • 3.1.6. FLIR FC-T Series
    • 3.1.7. FLIR Thermal Imaging Sensors For Traffic Monitoring
    • 3.1.8. FLIR D-Series ITS
  • 3.1.9. IP Control
    • 3.1.10. FLIR PT-Series ITS
    • 3.1.11. FLIR MWIR FPAs
    • 3.1.12. FLIR Photon HRC
    • 3.1.13. Flir Photon HRC
    • 3.1.14. FLIR Thermal Imaging Predictive Maintenance Systems
    • 3.1.15. FLIR Building Inspection
    • 3.1.16. FLIR Gas Detection
    • 3.1.17. FLIR Emerging Markets
    • 3.1.18. FLIR Technology
    • 3.1.19. FLIR System Design and Integration
    • 3.1.20. FLIR Sensing Materials
    • 3.1.21. FLIR Lasers and Laser Components
    • 3.1.22. FLIR Tactical Platforms
    • 3.1.23. FLIR Tau Outputs NTSC Video
    • 3.1.24. FLIR Mid IR Sensors
    • 3.1.25. FLIR Government Systems Airborne MEP
    • 3.1.26. FLIR Government Systems Airborne - Talon
    • 3.1.27. FLIR Government Systems Unmanned - Star SAFIRE QWIP
    • 3.1.28. FLIR Government Systems Unmanned - Star SAFIRE III
    • 3.1.29. FLIR Government Systems Unmanned TacFLIR II
    • 3.1.30. FLIR Government Systems - Products - Maritime - Star SAFIRE III
    • 3.1.31. FLIR Government Systems - Products - Maritime - SeaFLIR II
    • 3.1.32. FLIR Government Systems - Products - Land - RWSS
    • 3.1.33. FLIR Government Systems - Products - Land - WideEye II
    • 3.1.34. FLIR Government Systems Force Protection
    • 3.1.35. FLIR EO/IR
  • 3.2. Daylight Solutions
    • 3.2.1. Daylight Solutions ChemDetect™ High-Speed Mid-IR Molecular Sensor
    • 3.2.2. Daylight Solutions Über Tuner™ Broad Tuning Pulsed Lasers
    • 3.2.3. Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser
    • 3.2.4. Daylight Solutions Aries™ Series - High Power, Multi-Wavelength Mid-IR Laser Systems
    • 3.2.5. Daylight Solutions MIRcat™ Ultra-Broadly Tunable Mid-IR Laser
    • 3.2.6. Daylight Solutions Mid-IR QCL Systems
    • 3.2.7. Daylight Solutions Modularity Brings Flexibility
    • 3.2.8. Daylight Solutions Tunable Laser Fully Automated, Hands-free Operation
    • 3.2.9. Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser
    • 3.2.10. Daylight Solutions TLS-41000-MHF Next Generation Mode Hop-Free (MHF) Lasers
    • 3.2.11. Daylight Solutions Aries™ Series - High Power, Multi-Wavelength Mid-IR Laser Systems
    • SOURCE: WINTERGREEN RESEARCH, INC.
    • 3.2.12. Daylight Solutions Lasers For Gas Sensing Instrumentation
    • 3.2.13. Daylight Solutions Mid-IR HgCdTe Detectors
    • 3.2.14. Daylight Solutions Thermal Laser Pointers
    • 3.2.15. Daylight Solutions Tunable Laser
    • 3.2.16. Daylight Solutions Broadly Tunable, Room-Temperature, Mid-IR Laser
    • 3.2.17. Daylight Solutions Fixed Wavelength Pulsed and CW Mid-Infrared Lasers 306
    • 3.2.18. Daylight Solutions Mid-IR HgCdTe Detectors
    • 3.2.19. Daylight Solutions Room-Temperature, Low-Noise Amplified MCT Detector Core Technology
    • 3.2.20. Daylight Solutions Digital Object Identifier
    • 3.2.21. Daylight Solutions Power Technology Applications
    • 3.2.22. Daylight Solutions Power Technology Sensors Integrated With Wireless Capability
    • 3.2.23. Daylight Solutions Power Technology ECqcL Used For Illumination Applications
  • 3.3. SenseAir
    • 3.3.1. SenseAir CO2 Engine®K30
    • 3.3.2. SenseAir CO2 Engine®ICB
    • 3.3.3. SenseAir CO2 Engine®K30 3%
    • 3.3.4. SenseAir CO2 Engine®K30 FR
    • 3.3.5. SenseAir CO2 Engine®K30 LP
    • 3.3.6. SenseAir® S8
    • 3.3.7. SenseAir® S8-4B
    • 3.3.8. SenseAir CO2 Engine®K30
    • 3.3.9. SenseAir CO2 Engine® BLG
    • 3.3.10. Senseair Test & Measurement Carbon Dioxide Sensors
    • 3.3.11. Senseair Temperature Proportional To Carbon Dioxide Level
  • 3.4. Acuity Brands Inc. / Sensor Switch Occupancy Sensor Products
    • 3.4.1. Sensor Switch WSX 2P
    • 3.4.2. Sensor Switch SSD
    • 3.4.3. Sensor Switch Technology Engineering Driven Company
    • 3.4.4. Sensor Switch Passive Infrared
    • 3.4.5. Sensor Switch Wall Switch Sensor Dual Technology
  • 3.5. Structured Materials Industries
    • 3.5.1. Structured Materials Industries SpinCVDJ Metal Organic Chemical Vapor Deposition
  • 3.6. Block Engineering Quantum Cascade Laser Products
    • 3.6.1. Block Engineering LaserSense-SC™: Compact Gas Detection System the Semiconductor Industry
    • 3.6.2. Block Engineering LaserWarn™: Open-Path Chemical Detection System
    • 3.6.3. Block Engineering Mini-QCL™: OEM Quantum Cascade Laser Module
    • 3.6.4. Block Engineering LaserTune: Widely Tunable Mid-Infrared Laser Source
    • 3.6.5. Block Engineering MCT IR Detector Module™: Spectral Acquisition Detection
    • 3.6.6. Block Engineering MCT (Mercury-Cadmium-Telluride) IR (infrared) Detector Module
    • 3.6.7. Block Engineering Quantum Cascade Laser (QCL) LaserScan™
    • 3.6.8. Block Engineering Quantum Cascade Laser (QCL) LaserScope™
  • 3.7. Sofradir
    • 3.7.1. Sofradir Mid IR AXIR MW 640x512
    • 3.7.2. Sofradir Mid IR AXIR MW OEM 640x512
    • 3.7.3. Sofradir Mid IR DAPHNIS-HD MW 1280x720
    • 3.7.4. Sofradir Mid IR DAPHNIS-XGA MW 1280x720
    • 3.7.5. Sofradir Mid IR GALATEA MW 640x512
    • 3.7.6. Sofradir Mid IR INSPIR MW 384x288
    • 3.7.7. Sofradir Mid IR LEO-LP MW 640x512
    • 3.7.8. Sofradir Mid IR SCORPIO MW JT 640x512
    • 3.7.9. Sofradir Mid IR LEO MW 640X512
    • 3.7.10. Sofradir Mid IR MARS MW 320x256
    • 3.7.11. Sofradir Mid IR SCORPIO MW 640x512
    • 3.7.12. Sofradir Mid IR URANUS MW 640x512
    • 3.7.13. Sofradir Mid IR AQUILA JT 384X288
    • 3.7.14. Sofradir Mid IR JUPITER MW 1280x1024
    • 3.7.15. Sofradir Jet IR Product
    • 3.7.16. Sofradir EPSILON MW
    • 3.7.17. Sofradir ROIC Modes:
  • 3.8. Ekips Technologies
    • 3.8.1. Ekips Technologies Breath-meter
    • 3.8.2. Ekips Technologies Lasers
    • 3.8.3. Ekips Technologies Laser Spectrometers
    • 3.8.4. Ekips Technologies Mid-Infrared Lasers
    • 3.8.5. Ekips Technologies Challenge In Quantifying Chemical Molecules
  • 3.9. JonDeTech AB
    • 3.9.1. JonDeTech AB Applications of Infrared Sensing Thermopiles
    • 3.9.2. JonDeTech AB Preventive and Predictive Maintenance
    • 3.9.3. JonDeTech Thermopile Products
    • 3.9.4. JonDeTech Surface Mount Plastic Thermopiles
    • 3.9.5. JonDeTech Thermopiles
    • 3.9.6. JonDeTech Horizontal Thermocouple
    • 3.9.7. JonDeTech Advantage Of Nanotechnology Vertical Thermocouple
  • 3.10. Micropelt Energy Harvesting
    • 3.10.1. Micropelt mNODE
    • 3.10.2. Micropelt Thermo-generator
    • 3.10.3. Micropelt Two Micro Thermo-generators In Series
    • 3.10.4. Micropelt Thermo-harvester
  • 3.11. EnOcean
    • 3.11.1. EnOcean ECO 200 - Motion Energy Harvesting
    • 3.11.2. EnOcean ECT 310 - Thermo Energy Harvesting
    • 3.11.3. EnOcean Energy Harvesting Wireless Sensor Solutions
  • 3.12. Agiltron / SensArrayInfrared
    • 3.12.1. Agiltron Infrared Detector Products
    • 3.12.2. Agiltron Lead Sulfide Infrared Detector Array
    • 3.12.3. Agiltron Lead Selenide Infrared Detectors
    • 3.12.4. Agiltron Lead Selenide Infrared (Pbse) Detector Array
  • 3.13. Mirthe Mid IR Sensor Breath Analyzers
    • 3.13.1. Mirthe Engineered Systems for Mid-IR Laser Absorption Spectroscopy
    • 3.13.2. Mirthe Strategic 3-Level Framework
  • 3.14. Emerson / Cascade Technologies
    • 3.14.1. Cascade Technologies Mid Infrared Countermeasures ICM100
    • 3.14.2. Cascade Technologies CT2100 - OnStack Multigas Analyzer
    • 3.14.3. Cascade Technologies CT3400 - Extractive Multigas Analyzer
    • 3.14.4. Cascade Technologies
    • 3.14.5. Cascade Technology Implementation
  • 3.15. Bosh Automotive Mid IR
  • 3.16. Thorlabs/ Maxion
    • 3.16.1. Thorlabs Adaptive InfraRed Imaging Spectroradiometer
    • 3.16.2. Thorlabs LWIR AIRIS Chemical Vapor Sensor Applications
    • 3.16.3. Thorlabs IR Camera Compatibility
    • 3.16.4. Maxion Technologies Infrared Semiconductor Lasers
    • 3.16.5. Maxion Technologies Turn-Key Mid-IR Laser Systems
    • 3.16.6. Maxion Technologies Turn-Key Mid-IR Laser Quantum Cascade (QC) and Interband Cascade (IC) Sensors
    • 3.16.7. Maxion Distributed Feedback (DFB) Single-Mode and Fabry-Perot (FP) Multi-Mode Lasers
    • 3.16.8. Maxion C-Mount and NS-Mount Lasers
  • 3.17. VIASPACE Ionfinity
    • 3.17.1. VIASPACE Ionfinity Soft Ionization Membrane
  • 3.18. Power Technology Quantum-Cascade Lasers
    • 3.18.1. Power Technology Quantum-Cascade Lasers Blue, Violet, & UV Diode Lasers
    • 3.18.2. Power Technology Infrared Viewing Devices
    • 3.18.3. Power Technology Laser Modules for OEM
  • 3.19. M Squared Next-Generation Bio-Medical Lasers
    • 3.19.1. M Squared Firefly-IR
    • 3.19.2. M Squared SolsTiS cw Ti Sapphire Laser
    • 3.19.3. M Squared Lasers Firefly-IR
    • 3.19.4. M Squared Lasers Firefly-THz
    • 3.19.5. M Squared Firefly-THz: Compact, Widely Tunable, Pulsed Terahertz Laser Source
    • 3.19.6. M Squared Lasers Product Families
    • 3.19.7. M Squared ICE-BLOC® Photonic Controllers
    • 3.19.8. M Squared Laser Systems
    • 3.19.9. M Squared Dependable Innovation
    • 3.19.10. M Squared SolsTiS™: Ultra-compact, Widely Tunable, Narrow Linewidth CW Ti: Sapphire Laser
  • 3.20. Thermo Fisher Scientific / NovaWave Technologies
    • 3.20.1. NASA Applications for Compact UV Laser-Based Sensor Instrument
    • 3.20.2. Novawave Technology Mid-Infrared Laser Source Real-time, Multispecies Greenhouse Gas Sensor
    • 3.20.3. Novawave Technology Canary in a Beam Line
    • 3.20.4. Novawave Technology Quasi-phase-matched DFG Lasers for Sensing
  • 3.21. GE Sensors
    • 3.21.1. GE Wireless Sensor Networks
    • 3.21.2. GE Applications for Wireless Sensor Networks
  • 3.22. Pacific Northwest National Laboratory (PNNL) Electronics and Systems Integration
    • 3.22.1. Pacific Northwest National Laboratory PNNL's Electronics And Systems Integration Capability
  • 3.23. Hamamatsu
    • 3.23.1. Hamamatsu InGaAa PIN photodiodes
    • 3.23.2. Hamamatsu InGaAs photodiode arrays
    • 3.23.3. Hamamatsu Infrared Detector
    • 3.23.4. Hamamatsu QCL for Continuous Wave Operation At Room Temperature
    • 3.23.5. Hamamatsu Laser
  • 3.24. AdTech Optics
  • 3.25. Opto Solutions
    • 3.25.1. Opto Solutions - IR Photonics
  • 3.26. Sentinel Photonics
    • 3.26.1. Sentinel Photonics Spatial Resolution
    • 3.26.2. Sentinel Photonics Competitive Differentiation
  • 3.27. Newport Corporation / ILX Lightwave
  • 3.28. Aeroci Aerocrine
    • 3.28.1. Aerocrine Expanding Into New Markets Beyond US
  • 3.29. Telops IR Sensors
    • 3.29.1. Telops TS-IR Thermal Scientific IR Camera
    • 3.29.2. Telops HDR-IR High Dynamic Range IR Camera
    • 3.29.3. Telops FAST-IR 2K Rapid IR Camera
    • 3.29.4. Telops HD-IR High Definition IR Camera
    • 3.29.5. Telops MS-IR Multispectral IR Camera
    • 3.29.6. Telops Airborne Platform For Hyperspectral Imaging
    • 3.29.7. Telops TEL-1000 MW Infrared Camera
  • 3.30. Ulis Pro Series Ulir Pico640P Thermal Image Sensors
    • 3.30.1. Ulis Elite Series Pico1024ET Thermal Image Sensors
  • 3.31. Advanced Photonix Photodiodes
  • 3.32. Marktech Optoelectronics Sensors
  • 3.33. MKS / Newport Corporation Mid-Infrared Sensor Cards
  • 3.34. Xenics XCO-640 - Midwave Infrared (MWIR) OEM Camera Core
    • 3.34.1. Xenics Onca-MWIR-InSb Camera
  • 3.35. Vigo System S.A. 2-11 μm IR Photoconductors
    • 3.35.1. Vigo System S.A. 2-13 μm IR Photoconductors Thermoelectrically Cooled
    • 3.35.2. Vigo System 2-11 μm Photoelectromagnetic Detectors
    • 3.35.3. Vigo System S.A. 2-11 μm Photo-electromagnetic Detectors Optically Immersed
    • 3.35.4. Vigo System S.A. 3-8 μm IR Photovoltaic Detectors
    • 3.35.5. Vigo System S.A. 2-8 μm IR Photovoltaic Detectors Optically Immersed
    • 3.35.6. Vigo System S.A. 8-11 μm IR Photovoltaic Multiple Junction Detectors
    • 3.35.7. Vigo System S.A. 8-11 μm IR Photovoltaic Multiple Junction Detectors Optically Immersed
  • 3.36. Opto Diode Corporation UV, Visible, Near-IR LEDs
    • 3.36.1. Opto Diode High Power Near-IR LEDs
    • 3.36.2. Opto Diode IR Emitters & Controllers
  • 3.37. Horiba Scientific InGaAs Detector for the NIR 0.8-2.6 Micrometer

4. MID IR SENSOR TECHNOLOGY

  • 4.1. Power Technology Mid IR Sensor Applications
    • 4.1.1. Molecular Responses Across the MIR Spectrum
    • 4.1.2. Technology Options Available in Mid IR
    • 4.1.3. Diagrams To Illustrate the Mid IR Technologies
    • 4.1.4. Comparison of Technology Options
    • 4.1.5. Products, In Which MIR Sensors Are Actually Deployed
    • 4.1.6. Market Trends & Key Companies
    • 4.1.7. Key Applications/Products Used By The Military
    • 4.1.8. Potential Technologies and Applications of MIR Sensors
    • 4.1.9. Uncooled IR Cameras
    • 4.1.10. Key Developments Are Required To Make Applications
    • 4.1.11. Characteristics Required
    • 4.1.12. Building a Robust Data Sensor Network Integration Layer
  • 4.2. Miniaturized Mid-Infrared Sensor Technologies Trends
    • 4.2.1. Nanophotonics
    • 4.2.2. Nanotechnology Is Significant
  • 4.3. Infrared Technology
    • 4.3.1. Daylight Solutions Core Technology
    • 4.3.2. Mid-Infrared Absorption Spectroscopy Based On Quantum Cascade Lasers
    • 4.3.3. Quantum Cascade Laser Technology
  • 4.4. Quantum Cascade Laser Linewidth & Tunability
  • 4.5. Applications
  • 4.6. Mid-Infrared (Mid-IR) Laser Spectroscopy
    • 4.6.1. Application of Infrared Lasers to Nanosecond Time-Resolved Condensed-Phase Samples
  • 4.7. Remote Detection Of Mines
  • 4.8. Thermopiles
    • 4.8.1. JonDeTech: Vertical VS. Horizontal Thermopile Lead Configuration
  • 4.9. Nanoparticle Dispersions
    • 4.9.1. Aqueous Dispersions
    • 4.9.2. JonDeTechs Thermopiles Based On Nanotechnology
    • 4.9.3. Nanotechnolgy Particle Size In The Range Of 1-100 Nanometers
    • 4.9.4. Nanoparticles
    • 4.9.5. Silicon In A Battery Swells As It Absorbs Lithium Atoms
    • 4.9.6. Different Shapes Of The Same Material Create Different Characteristics
    • 4.9.7. Optical Properties Integrated Into New Mid IR Sensor Technology
  • 4.10. Mid IR Laser Emits A Narrow Range Of Wavelengths
    • 4.10.1. Interband Cascade Laser (ICL) Based Spectroscopic Trace-Gas Sensor Provides For Simultaneous Detection Of Two Atmospheric Trace Gases
    • 4.10.2. Narrow Band Gap Semiconductor Laser Diodes
  • 4.10. Technological Trends in Microscopy
  • 4.11. Battery Technology for Mid IR Sensors
    • 4.11.1. Battery Chemistries Technology
  • 4.12. Breath Analyzers Detect Disease
    • 4.12.1. NTK Breathalizer
  • 4.13. Improving Biomaterials for Medical Implant Applications
    • 4.13.1. Bioactive Materials
    • 4.13.2. Forming A Chemical Bond with Bone
    • 4.13.3. Bioactivity Increased Through Surface Modification
    • 4.13.4. Biofilms Multilayered Colonies Of Bacteria
    • 4.13.5. Biofilm Formation
    • 4.13.6. Biofilms as A Major Contributor To Chronic Wounds
    • 4.13.7. Acute or Chronic Infection in Some Biomaterial Applications
    • 4.13.8. Biomaterials Research
  • 4.14. QC Technology
    • 4.14.1. Components of an ECqcL
  • 4.15. Schematic of Mid-Infrared Trace Gas Sensor
  • 4.16. Mid-IR Sensors Standards
  • 4.17. Driving Forces for Building Automation
  • 4.18. Near IR Night Vision Sensors
    • 4.18.1. Sensor Based Threat Detection
  • 4.19. Mid-IR Non-Invasive Medical Systems
  • 4.20. University of Oklahoma High-Tech Breath Test
    • 4.20.1. Nanotechnology Improves Laser Performance
    • 4.20.2. Nanotechnology Breath Analyzer for Kidney Failure
  • 4.21. Physical Vapor Nanoparticle Synthesis
    • 4.21.1. Nanophase Vapor Development Process
    • 4.21.2. Nanoparticle Coatings - Discrete Particle Encapsulation
    • 4.21.3. Nanoparticle Vapor Organic Dispersions
  • 4.22. MIRTHE Roadmap
    • 4.22.1. Near IR Laser Sensors:

5. MID INFRARED (IR) SENSORS COMPANY PROFILES

  • 5.1. Acuity Brands Inc.
    • 5.1.1. Acuity Brands Sustainable Business Practices
    • 5.1.2. Acuity Brands / Sensor Switch
  • 5.2. AdTech Optics
  • 5.3. Advanced Photonix
  • 5.4. Agiltron / SensArrayInfrared
    • 5.4.1. SensArrayInfrared
  • 5.5. Alpes Lasers / ALTechnologies
    • 5.5.1. Laser diodes
  • 5.6. Block Engineering
    • 5.6.1. Block Positioned To Expand Commercial Markets
    • 5.6.2. Block Engineering Contracts
    • 5.6.3. Block Engineering LaserScan™ Analyzer
    • 5.6.4. Block Engineering: Developer Of High Performance QCL and FT-IR Spectrometers
    • 5.6.5. Block MEMS Receives $4.5 Million Development Contract for MEMS Sensor
  • 5.7. Bosch Group
    • 5.1.1. Bosch Business Overview
    • 5.7.1. Bosch Motion Detectors
    • 5.7.2. Bosch Smart Sensors Simplify
  • 5.8. Circassia / Aerocrine
  • 5.9. Cymbet
    • 5.9.1. Cymbet Team:
    • 5.9.2. Cymbet Investors:
    • 5.9.3. Cymbet Partners, Sales and Distribution:
    • 5.9.4. Cymbet Manufacturing:
    • 5.9.5. Cymbet to Open World's Highest Volume Solid-State Battery Manufacturing Facility
    • 5.9.6. Cymbet Partnering with X-FAB
    • 5.9.7. Cymbet / X-FAB, Inc.
    • 5.9.8. Cymbet Expanding in Minnesota
    • 5.9.9. Cymbet / LEDA
    • 5.9.10. Cymbet Distribution Agreement EnerChip™ Eco-friendly Solid State Batteries
    • 5.9.11. Cymbet EVAL-09 Utilizes Harnessing Ambient Energy
    • 5.9.12. Cymbet Secures $31 Million in Private Financing
  • 5.10. Danaher Acquires Raytek
  • 5.11. Daylight Solutions
    • 5.11.1. Daylight Solutions Mid-IR
    • 5.11.2. $15Million Equity for Daylight Includes Northrop Grumman Funds
    • 5.11.3. Daylight Solutions Manufacturing Expansion
    • 5.11.4. Daylight Solutions Collaborations
    • 5.11.5. Daylight Solutions Quantum Cascade Laser Technology
  • 5.12. Digi International
    • 5.12.1. Digi International Revenue
    • 5.12.2. Digi International Business Highlights:
  • 5.13. Emerson
    • 5.13.1. Emerson Process Management
    • 5.13.2. Cascade Technologies
  • 5.14. EnOcean GmbH
    • 5.14.1. EnOcean Technology
    • 5.14.2. EnOcean Alliance
    • 5.14.3. EnOcean Technology
  • 5.15. Ekips Technologies
  • 5.16. Elliot Scientific
  • 5.17. Finmeccanica
    • 5.17.1. Finmeccanica / SELEX Galileo
    • 5.17.2. SELEX Galileo Inc.
    • 5.17.3. SELEX Galileo Technologies
  • 5.18. Ferro Solutions
    • 5.18.1. Ferro Solutions
  • 5.19. FLIR
    • 5.19.1. FLIR Systems Advanced Sensing Technologies
    • 5.19.2. FLIR Organized in Six Operating Segments:
    • 5.19.3. FLIR Training
    • 5.19.4. FLIR Sales and Distribution
    • 5.19.5. FLIR Sensor Systems
    • 5.19.6. FLIR Systems Thermography Products
    • 5.19.7. FLIR Systems Infrared Technology
    • 5.19.8. FLIR Systems
    • 5.19.9. FLIR Systems
    • 5.19.10. FLIR Systems Competitive Strengths
    • 5.19.11. FLIR Systems Commercial Operating Model
    • 5.19.12. FLIR Systems Vertically Integrated Manufacturing
    • 5.19.13. FLIR Systems Industry-Leading Market Position
    • 5.19.14. FLIR Systems Broad Product Line
    • 5.19.15. FLIR Systems Internally-Funded Innovation
    • 5.19.16. FLIR Systems Diverse Customer Base
    • 5.19.17. FLIR Systems Global Distribution Capabilities
    • 5.19.18. FLIR Systems Continually Reduces Costs
    • 5.19.19. FLIR Systems Expands Global Reach
    • 5.19.20. FLIR Systems Builds Application Awareness and Brand
  • 5.20. Fortive
    • 5.20.1. Danaher and Fortive.
  • 5.21. GE Sensors
    • 5.21.1. GE Wireless Sensor Networks
    • 5.21.2. GE's XMTC Thermal Conductivity Transmitter
    • 5.21.3. GE's 300 Pressure Series Sensors
    • 5.21.4. GE Applications for Wireless Sensor Networks
  • 5.22. Hamamatsu
    • 5.22.1. Hamamatsu Mid infrared LED L13201-0430M - Hamamatsu Photonics
    • 5.22.2. Hamamatsu Electron Tube Division
    • 5.22.3. Hamamatsu Solid State Division
    • 5.22.4. Hamamatsu Systems Division
    • 5.22.5. Hamamatsu Laser Group
    • 5.22.6. Hamamatsu Optical Communication Group
    • 5.22.7. Hamamatsu Central Research Laboratory
    • 5.22.8. Hamamatsu Tsukuba Research Laboratory
    • 5.22.9. Hamamatsu Sports Photonics Laboratory
    • 5.22.10. Hamamatsu PET Center
    • 5.22.11. Hamamatsu Revenue
  • 5.23. II-VI Incorporated / Marlow Industries
    • 5.23.1. II-VI Incorporated Revenue and Acquisitions
    • 5.23.2. II-VI Revenue
    • 5.23.3. II-VI Incorporated / Marlow Infrared and Near-Infrared Laser Optical Elements
    • 5.23.4. II-VI incorporated / Marlow Primary Products
    • 5.23.5. II-VI Infrared Optics Market
    • 5.23.6. II-VI One-Micron Laser Market
    • 5.23.7. II-VI Near-Infrared Optics Market.
    • 5.23.8. II-VI Thermoelectric Market
  • 5.24. InfraTec
  • 5.25. IPG Photonics
    • 5.25.1. IPG Photonics
  • 5.26. Johnson Controls Sensor Products
    • 5.26.1. Johnson Controls Valve Products
  • 5.27. JonDeTech
  • 5.28. Linear Technology / Dust Networks
    • 5.28.1. Dust Networks Self-Powered IPV6 Wireless Sensor Network
    • 5.28.2. Dust Networks
    • 5.28.3. Dust Networks Self-Powered IPV6 Wireless Sensor Network
  • 5.29. Lockheed-Martin
    • 5.29.1. Lockheed Argos®- Tunable Laser
    • 5.29.2. Lockheed-Martin Military Contractor
    • 5.29.3. Lockheed Martin Customer Base:
    • 5.29.4. Lockheed Martin Defense Department Positioning
  • 5.30. M Squared Next-Generation Bio-Medical Lasers
  • 5.31. Marktech Optoelectronics
  • 5.32. Micro-Epsilon
    • 5.32.1. Micro-Epsilon CapaNCDT 6222 Capacitive Controller
  • 5.33. Micropelt Energy Harvester
  • 5.34. MIRTHE (Mid-Infrared Technologies for Health and the Environment) National Science Foundation Engineering Research Center
    • 5.34.1. Mirthe Mid IR Sensor Breath Analyzers
    • 5.34.2. Mirthe Engineered Systems for Mid-IR Laser Absorption Spectroscopy
    • 5.34.3. Mirthe Strategic 5-Level Framework
  • 5.35. Mitre
  • 5.36. MKS Instruments
    • 5.36.1. MKS / Newport
    • 5.36.2. Newport Corporation / ILX Lightwave
    • 5.36.3. MKS Instruments Acquisition of Newport
    • 5.36.4. MKS / Newport Markets
    • 5.36.5. Newport Corporation / ILX Lightwave
    • 5.36.6. ILX Lightwave Product Innovation
  • 5.37. Nanophase Technologies
    • 5.37.1. Nanomaterials Technology Energy
    • 5.37.2. Nanomaterials Technology Aluminum Oxide
    • 5.37.3. Nanomaterials Technology
    • 5.37.4. Nanomaterials Technology First Quarter 2016 Financial Results
    • 5.37.5. Nanomaterials Technology Energy
    • 5.37.6. Nanomaterials Technology Aluminum Oxide
    • 5.37.7. Nanomaterials Technology
  • 5.38. Opto Diode Corporation
  • 5.39. Opto Solutions
  • 5.40. Pacific Northwest National Laboratory PNNL Electronics and Systems Integration
  • 5.41. Physical Sciences
  • 5.42. Power Technology
  • 5.43. Raytheon
    • 5.43.1. Raytheon Innovation
    • 5.43.2. Raytheon Integrated Defense Systems (IDS)
    • 5.43.3. Raytheon Intelligence and Information Systems (IIS)
    • 5.43.4. Raytheon Network Centric Systems (NCS)
    • 5.43.5. Raytheon Technical Services Company (RTSC)
    • 5.43.6. Raytheon Missile Systems (RMS)
    • 5.43.7. Raytheon Space and Airborne Systems (SAS)
    • 5.43.8. Raytheon / Structured Materials Industries
  • 5.44. SenseAir
  • 5.45. Sensor Switch
    • 5.45.1. SenseAir Applications
    • 5.45.2. SenseAir Collaborates with Ventilation Systems Suppliers
    • 5.45.3. SenseAir Measurement Platform Has Intelligence
    • 5.45.4. SenseAir Carbon Dioxide Sensors
    • 5.45.5. SenseAir Next Generation Driver Alcohol Detection Systems
  • 5.46. Sentinel Photonics
  • 5.47. Sick AG
    • 5.47.1. Sick AG Mid IR Product Family W27-3
    • 5.47.2. Sick Growth
  • 5.48. Sofradir
    • 5.48.1. Sofradir / ULIS
    • 5.48.2. Sofradir Subsidiary ULIS SAS: Shareholders Sofradir and GE Equity
    • 5.48.3. Sofradir: Leader in Cooled And Uncooled IR detectors
    • 5.48.4. Sofradir Subsidiary ULIS SAS
    • 5.48.5. Sofradir / Electrophysics
    • 5.48.6. Sofradir Infrared Company
    • 5.48.7. Sofradir Awarded Multi-Million Euro MUSIS/CSO Infrared contract
  • 5.49. Spectris / Omega Engineering
    • 5.49.1. Spectris / Omega Infrared Temperature Measurement Instruments
    • 5.49.2. Omega Engineering
    • 5.49.3. Omega Infrared Temperature Measurement Instruments
  • 5.50. Structured Materials Industries
    • 5.50.1. Structured Materials SMI Products
    • 5.50.2. Structured Materials SMI Customer Advantage
  • 5.51. Telops
    • 5.51.1. Telops Aerospace and Defense
  • 5.52. Thermo Fischer Scientific / NovaWave Technologies
    • 5.52.1. Thermo Fisher Scientific Revenue
    • 5.52.2. Thermo Fisher Scientific Acquires Laser-Based Gas Detection Company NovaWave Technologies
    • 5.52.3. NovaWave Selected for CPP Participation
    • 5.52.4. Thermo Fischer Scientific / NovaWave Technologies
  • 5.53. Thorlabs
    • 5.53.1. Thorlabs Acquires QCL Manufacturer Maxion Technologies
    • 5.53.2. Maxion Technologies
    • 5.53.3. Maxion and the University of Maryland, Baltimore County
  • 5.54. United Technologies
    • 5.54.1. Kidde Products Limited / Airsense Technology
  • 5.55. VIASPACE / Ionfinity
    • 5.55.1. VIASPACE / Ionfinity Product Focus
    • 5.55.2. VIASPACE / Ionfinity Next-Generation Chemical Analysis
  • 5.56. Vigo System S.A.
  • 5.57. Xenics
    • WINTERGREEN RESEARCH

List of Tables and Figures:

  • Table ES-1: Mid IR Sensor Market Driving Forces
  • Table ES-2: Technologies Impacting Mid IR Sensor Market
  • Table ES-3: Mid IR Sensors Market Shares, Dollars, Worldwide, 2015
  • Figure ES-4: Mid Infrared (IR) Sensor Shipments, Market Forecasts, Dollars, Worldwide, 2022
  • Table 1-1: Integrated IoT Change Management Market Driving Forces
  • Figure 1-2: Smarter Computing
  • Figure 1-3: Interband-Cascade (IC) Lasers
  • Table 1-4: Mid And Long-Wavelength (3-12 Microns) Infrared Semiconductor Lasers Types
  • Table 1-5: Applications Of Mid-Wavelength Infrared Semiconductor Lasers
  • Table 1-6: Applications For Mid IR Sensing
  • Table 1-7: Mid-Infrared Fiber-Optic Sensor Characteristics
  • Table 2-1: Mid IR Sensor Market Driving Forces
  • Table 2-2: Technologies Impacting Mid IR Sensor Market
  • Table 2-3: Mid IR Sensors Market Shares, Dollars, Worldwide, 2015
  • Table 2-4: Mid IR Sensors Market Shares, Dollars, Worldwide, 2015
  • Table 2-5: Key Features Of Some Mid IR Technology
  • Table 2-6: JonDeTech Thermopile Sensor Flexibility
  • Table 2-7: JonDeTech Thermopile Sensor Characteristics
  • Figure 2-8: Mid Infrared (IR) Sensor Shipments, Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-9: Mid IR Sensor Total Market Dollars, Worldwide, 2013-2019
  • Figure 2-10: Mid IR Sensor Market Forecasts, Units, Worldwide, 2016-2022
  • Table 2-11: Mid IR Sensor Market Forecasts, Units, Worldwide, 2016-2022
  • Table 2-13: Mid IR Sensors: Dollars and Units, High End, Mid-Range, and Low End, Shipments, Worldwide, 2013-2019
  • Table 2-14: Mid IR Sensor Market Forecasts, High End, Mid-Range, and Low End Units, Worldwide, 2016-2022
  • Table 2-15: Applications for Mid IR Sensors
  • Table 2-16: Mid IR Sensor Applications Market Segments, Dollars, Worldwide, 2016-2022
  • Table 2-17: Mid IR Sensor Applications Market Segments, Percent, Worldwide, 2016-2022154
  • Table 2-18: Mid IR Infrared Military and Border Patrol Sensors Market Shares, Dollars, Worldwide, 2015
  • Table 2-19: Mid IR Military and Border Patrol Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Figure 2-20: Military / Border Patrol Mid Infrared (IR) Sensors Shipments Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-21: Mid IR Infrared Automobile Sensor Market Shares, Dollars, Worldwide, 2016-2022
  • Table 2-22: Mid IR Automotive Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-23: Mid IR Infrared Building Inspection Market Shares, Dollars, Worldwide, 2015
  • Table 2-24: Mid IR Building Inspection Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-25: Smart Building Mid Infrared (IR) Sensor Uses
  • Table 2-26: Smart Building Mid Infrared (IR) Sensor Market Segments
  • Table 2-27: Mid IR Laser Sensors Market Shares Dollars and Units, Worldwide, 2015
  • Table 2-28: Mid IR Laser Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-29: Mid IR Thermal Camera Sensors Market Shares, Units and Dollars, Worldwide, 2015
  • Table 2-30: Mid IR Thermal Camera Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-31: Mid IR Occupancy Sensors and Photocell Devices Market Shares, Dollars, Worldwide, 2015
  • Table 2-32: Mid IR Occupancy / Photocell Sensor Market Forecasts, Dollars, Worldwide, 2022
  • Figure 2-33: Cascade Technologies CT2100 Analyzer
  • Table 2-34: Mid IR Oil and Gas Sensor Market Shares, Dollars, Worldwide, 2015
  • Table 2-35: Mid IR Oil and Gas Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-36: Mid IR CO2 Sensor Market Shares, Dollars, Worldwide, 2015
  • Table 2-37: Mid IR Carbon Dioxide CO2 Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-38: Mid IR Nitric Oxide (NO) Sensor Market Shares, Dollars, Worldwide, 2015
  • Table 2-39: Mid IR Nitric Oxide (NO) Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-40: Machine Process Measuring and Detection Sensors Using Mid IR, Market Shares Dollars, Worldwide, 2015
  • Table 2-41: Mid IR Machine Process Measuring and Detection Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-32: Mid IR Fire Gas Detection Market Shares. Dollars, Worldwide, 2015
  • Table 2-33: Mid IR Fire / Gas Detection Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-34: Mid IR Temperature Sensors Market Shares, Dollars, Worldwide, 2015
  • Table 2-35: Mid IR Temperature Sensor Market Forecasts, Dollars, Worldwide, 2016-2022
  • Figure 2-36: MIRTHE Compound and Vibrational Absorption Analysis
  • Figure 2-37: Mirthe Assessment of QC Laser Based Sensor Challenges
  • Table 2-38: Mid IR Sensors: High End, Mid Range, and Low End, Unit Shipments, Worldwide, 2016-2022
  • Table 2-39: Mid IR Sensor Market Forecasts, High End, Mid-Range, and Low End Sensors, Dollars and Units, Worldwide, 2016-2022
  • Table 2-40: Types of Internet Connected Devices Likely to be Using Using Mid IR Sensors That Need Software To Achieve Connectivity
  • Table 2-40 (Continued): Types of Internet Connected Devices Likely to be Using Using Mid IR Sensors That Need Software To Achieve Connectivity
  • Table 2-41: Mid IR Sensor Applications Market Segments, Dollars, Worldwide, 2016-2022
  • Table 2-42: Mid IR Sensor Applications Market Segments, Percent, Worldwide, 2016-2022216
  • Table 2-43: Advantages Offered by Intern Browsers for Network Collection of Mid IR Sensor Data
  • Table 2-44: App Based Smart Phone Services Benefits
  • Table 2-45: App Services Architecture Market Driving Forces
  • Figure 2-46: MIRTHE Mass Spectroscopy Pricing Assessment
  • Figure 2-47: MIRTHE Sensor Price Per Unit Analysis
  • Figure 2-48: Mid Infrared (IR) Sensor Regional Market Segments, Dollars, 2015
  • Table 2-49: Mid IR Sensor Regional Market Segments, 2015
  • Table 3-1: Video Camera Traffic Video Analysis Issues
  • Table 3-2: Video Camera Traffic Video Analysis Difficulties
  • Figure 3-3: FLIR TrafiOne
  • Figure 3-4: FLIR TrafiOne Benefits
  • Figure 3-5: FLIR TrafiOne
  • Figure 3-6: FLIR TrafiSense Benefits
  • Figure 3-7: FLIR FC-T Series
  • Figure 3-8: FLIR FC-T Series Benefits
  • Figure 3-9: FLIR D-Series ITS
  • Figure 3-10: FLIR TrafiOne
  • Figure 3-11: FLIR MWIR FPAs
  • Table 3-12: FLIR f Infrared Indium Antimonide (InSb) Component Features
  • Table 3-13: FLIR MWIR Arrays Advanced ROIC On-Chip Features
  • Figure 3-14: FLIR Photon HRC
  • Table 3-15: FLIR Thermal Imaging Applications
  • Table 3-16: FLIR Technology
  • Table 3-17: FLIR Technology Systems
  • Figure 3-18: FLIR Commercial Vision Systems
  • Table 3-19: Key Features of FLIR Tau 640 Camera
  • Figure 3-20: FLIR Scout Thermal Night Vision
  • Figure 3-21: FLIR Infrared Cameras
  • Table 3-22: FLIR Thermal Imaging Technology -- CBRNE, Cameras, and Industrial
  • Table 3-23: FLIR Thermal Imaging Technology - Surveillance, Police, and Science
  • Figure 3-24: FLIR Unmanned Laser Targeting Systems
  • Figure 3-25: FLIR MEP Reconnaissance, Surveillance, Target Acquisition Laser Designator IR Sensor
  • Figure 3-26: Daylight Solutions Über Tuner™ Broad Tuning Pulsed Lasers
  • Table 3-27: Daylight Solutions Über Tuner™ Broad Tuning Pulsed Lasers Features
  • Figure 3-28: Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser
  • Table 3-29: Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser Features
  • Figure 3-30: Daylight Solutions Aries™ Series - High Power, Multi-Wavelength Mid-IR Laser Systems
  • Table 3-31: Daylight Solutions Über Tuner™ Broad Tuning Pulsed Lasers Features
  • Figure 3-32: Daylight Solutions MIRcat™ Ultra-Broadly Tunable Mid-IR Laser
  • Table 3-33: Daylight Solutions Mid-IR QCL Systems Applications
  • Table 3-34: Daylight Solutions Tunable Laser Functions
  • Figure 3-35: Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser
  • Table 3-36: Daylight Solutions TLS-41000-MHF Mode Hop-Free (MHF) Laser Functions
  • Table 3-37: Daylight Solutions Enhanced-Stability CW-Mode Hop-Free Mid-IR Laser Features
  • Figure 3-38: Daylight Solutions Aries™ Series - High Power, Multi-Wavelength Mid-IR Laser Systems
  • Table 3-39: Daylight Solutions Aries™ Series - High Power, Multi-Wavelength Mid-IR Laser Systems
  • Table 3-40: Daylight Solutions Mid Infrared Sensor Applications
  • Figure 3-41: Daylight Solutions Mid IR Sensors
  • Table 3-42: Daylight Solutions Monitoring
  • Figure 3-43: Daylight Solutions Industry Specific Solutions
  • Table 3-44: Daylight Solutions Mid IR Detector Key Features
  • Figure 3-45: Daylight Solutions Tunable Laser Tuning
  • Figure 3-46: Daylight Solutions Narrow Tuning
  • Table 3-47: Daylight Solutions Gaussian Beam Profile
  • Table 3-48: Daylight Solutions EC-QCL Laser Gaussian Beam Profile
  • Table 3-49: Daylight Solutions Tunable Mid-IR External-Cavity CW-MHF Lasers
  • Table 3-49 (Continued): Daylight Solutions Tunable Mid-IR External-Cavity CW-MHF Lasers
  • Table 3-49 (Continued): Daylight Solutions Tunable Mid-IR External-Cavity CW-MHF Lasers
  • Figure 3-50: Daylight Solutions Mid-IR
  • Figure 3-51: Daylight Solutions Controller
  • Figure 3-52: Daylight Solutions Applications
  • Figure 3-53: Daylight Solutions Laserhead
  • Table 3-54: Daylight Solutions Tunable Mid-IR External Cavity Lasers Features
  • Table 3-55: Daylight Solutions Tunable Mid-IR External Cavity Lasers Advantages
  • Table 3-56: Daylight Solutions Products
  • Figure 3-57: Daylight Solutions Fixed-Wavelength Mid-IR External-Cavity Lasers
  • Table 3-58: Daylight Solutions Fixed-Wavelength Mid-IR External-Cavity Lasers Key Features
  • Table 3-59: Daylight Solutions Fixed-Wavelength Mid-IR External-Cavity Lasers Applications
  • Figure 3-60: Daylight Solutions Mid-IR HgCdTe Detectors
  • Table 3-61: Daylight Solutions Mid-IR HgCdTe Detectors Key Features
  • Table 3-62: Daylight Solutions Core Technology
  • Figure 3-63: Daylight Solutions' Core Technology
  • Table 3-64: Daylight Solutions Power Technology Mid IR Sensor Applications
  • Table 3-64 (Continued): Daylight Solutions Power Technology Mid IR Sensor Applications
  • Figure 3-65: Senseair Carbon Dioxide Sensors
  • Figure 3-66: SenseAir CO2 Engine®ELG
  • Table 3-67: SenseAir CO2 Engine®ELG Benefits
  • Figure 3-68: SenseAir CO2 Engine®ICB
  • Table 3-69: SenseAir CO2 Engine®ICB Benefits
  • Figure 3-70: SenseAir CO2 Engine®K30 3%
  • Table 3-71: SenseAir CO2 Engine®K30 3% Benefits
  • Figure 3-72: SenseAir CO2 Engine®K30 FR
  • Table 3-73: SenseAir CO2 Engine®K30 FR Benefits
  • Figure 3-74: SenseAir CO2 Engine®K30 LP
  • Table 3-75: SenseAir CO2 Engine®K30 LP Benefits
  • Figure 3-76: SenseAir® S8
  • Table 3-77: SenseAir®S8 Benefits
  • Figure 3-78: SenseAir® SB-4B CO2 Low Power Safety Switch
  • Table 3-79: SenseAir® S8-B4 Low Power CO2 Safety Switch Benefits
  • Figure 3-80: SenseAir CO2 Engine®ELG
  • Table 3-81: SenseAir CO2 Engine®ELG Benefits
  • Figure 3-82: SenseAir CO2 Engine® BLG
  • Table 3-83: SenseAir CO2 Engine® BLG Benefits
  • Table 3-84: SenseAir® CO2 Sensors
  • Table 3-85: SenseAir® CO2 Energy Saving Intelligent Sensors
  • Table 3-86: SenseAir® CO2 Process Sensor Applications
  • Table 3-87: SenseAir® CO2 Personal Safety Sensor Applications
  • Figure 3-88: SenseAir Products
  • Figure 3-89: SenseAir Carbon Dioxide Sensor
  • Figure 3-90: SenseAir Circuit Board
  • Figure 3-91: Sensor Switch WSX Wall Switch Occupancy
  • Figure 3-92: Sensor Switch SSD
  • Table 3-93: Sensor Switch Occupancy Detection SSD Features
  • Table 3-94: Sensor Switch Product Highlights
  • Figure 3-95: Sensor Switch Smart Buildings
  • Table 3-96: Sensor Switch Lighting Controls Technical Services
  • Table 3-97: Sensor Switch Engineering Advances
  • Figure 3-98: Sensor Switch WSX Family of Wall Switch Occupancy Sensors
  • Figure 3-99: Block Engineering LaserSense-SC
  • Table 3-100: Block Engineering LaserSense-SC Features
  • Figure 3-101: Block Engineering LaserWarn
  • Table 3-102: Block Engineering LaserWarn Features
  • Figure 3-103: Block Engineering Mini-QCL
  • Table 3-104: Block Engineering Mini-QCL Features
  • Figure 3-105: Block Engineering LaserTune
  • Table 3-106: Block Engineering LaserTune Key Benefits & Advantages
  • Figure 3-107: Block Engineering MCT IR Detector Module™: Spectral Acquisition Detection
  • Table 3-108: Block Engineering MCT IR Detector Module™: Spectral Acquisition Detection Key Benefits & Advantages
  • Figure 3-109: Block Engineering Quantum Cascade Laser
  • Table 3-110: Block Engineering Tunable Mid-IR Sources Products
  • Figure 3-111: Block Engineering LaserScope Target Size
  • Table 3-112: Block Engineering Quantum Cascade Laser Products
  • Table 3-113: Block Engineering Standoff Passive FTIR Spectroscopy Products
  • Table 3-114: Block Engineering Examples of LaserScan Functions:
  • Table 3-115: Block Engineering Laserscan Product Line Functions
  • Table 3-116: Block Engineering LaserScope Functions:
  • Table 3-117: Block Engineering Quantum Cascade Laser (QCL) LaserTune™
  • Figure 3-118: Sofradir Mid IR AXIR MW 640x512
  • Figure 3-119: Sofradir Mid IR AXIR MW OEM 640x512
  • Figure 3-120: Sofradir Mid IR DAPHNIS-HD MW 1280x720
  • Figure 3-121: Sofradir Mid IR DAPHNIS-XGA MW 1280x720
  • Figure 3-122: Sofradir Mid IR GALATEA MW 640x512
  • Figure 3-123: Sofradir Mid IR INSPIR 384x288
  • Figure 3-124: Sofradir Mid IR LEO-LP MW 640x512
  • Figure 3-125: Sofradir Mid IR SCORPIO MW JT 640x512
  • Figure 3-126: Sofradir Products
  • Figure 3-127: Sofradir Mid IR LEO MW 640X512
  • Figure 3-128: Sofradir Mid IR MARS MW 320x256
  • Figure 3-129: Sofradir Mid IR SCORPIO MW 640x512
  • Figure 3-130: Sofradir Mid IR URANUS MW 640x512
  • Figure 3-131: Sofradir Mid IR AQUILA JT 384X288
  • Figure 3-132: Sofradir Mid IR JUPITER MW 1280x1024
  • Figure 3-133: Sofradir Mid IR EPSILON MW 384x288
  • Table 3-134: Sofradir Mid IR EPSILON MW Applications
  • Figure 3-135: Sofradir Jet IR Product
  • Figure 3-136: Sofradir Vision IR Product
  • Figure 3-137: Sofradir Marine IR Product
  • Figure 3-138: Sofradir Helicopter IR Product
  • Figure 3-139: Sofradir EPSILON MW 384x288
  • Table 3-140: Sofradir Hand-Held Thermal Imaging UAV Applications
  • Table 3-141: Sofradir ROIC Modes:
  • Table 3-142: Sofradir Development Trends In Cooled Infrared Technology
  • Figure 3-143: Sofradir VEGA LW 384x288 QWIP (25μm pitch)
  • Figure 3-144: Eikips Technologies Biomarkers in Breath
  • Table 3-145: Ekips Technologies Category Examples Of Laser Emission Spectra
  • Table 3-146: JonDeTech AB Thermopile Features
  • Figure 3-147: JonDeTech AB Low-Cost, Surface Mount Thermopiles
  • Table 3-148: JonDeTech AB Consumer Electronics Mid IR Sensors
  • Table 3-149: JonDeTech AB Residential Control Systems Mid IR Sensors
  • Table 3-150: JonDeTech's Technology Competitive Advantages
  • Figure 3-151: JonDeTech AB JIRS3 Sensor
  • Table 3-152: JonDeTech AB Key Features of the Thermopile
  • Figure 3-153: JonDeTech AB JIRS5 Sensor
  • Figure 3-154: JonDeTech AB Close-up of JIRS5 Sensor
  • Figure 3-155: JonDeTech AB Nanowire Sensors
  • Figure 3-156: JonDeTech AB Linear Array of IR Sensorson Polyimide Foil
  • Table 3-157: JonDeTech Thermopile Applications
  • Figure 3-158: JonDeTech AB Vertical Heat Flow Model Of Jondetech Thermopiles
  • Figure 3-159: JonDeTech AB Vertical Heat Flow Model
  • Figure 3-160: Jondetech Thermopile Infrared Radiation Tetectors Generation Flex
  • Figure 3-161: Micropelt mNODE
  • Table 3-162: Micropelt mNODE Features
  • Figure 3-163: Micropelt Energy Harvester
  • Figure 3-164: Micropelt Energy Thermo-generator
  • Figure 3-165: Micropelt Energy Thermo-generator
  • Figure 3-166: Micropelt Thermo-harvester
  • Figure 3-167: EnOcean ECO 200 - Motion Energy Harvesting
  • Table 3-168: EnOcean ECO 200 - Motion Energy Harvesting
  • Figure 3-169: EnOcean ECO 100 - Motion Energy Harvesting
  • Table 3-170: EnOcean Energy Harvesting Motion Converter
  • Table 3-171: EnOcean ECT 310 Perpetuum
  • Table 3-172: EnOcean Thermo Converter
  • Table 3-173: EnOcean Energy Converters For Energy Harvesting Wireless Applications
  • Figure 3-174: Agiltron Room Temperature Automated Chemical Processing (ACP) Sensors
  • Figure 3- 175: Agiltron Typical Room Temperature Electrical Characteristics Of Automated Chemical Processing (ACP)
  • Table 3-176: Agiltron Response of PbS Detectors
  • Figure 3-177: Agiltron Infrared Detector Configurations
  • Figure 3-178: Agiltron Lead Sulfide Infrared (PbS) Detector Array
  • Figure 3-179: Quartz Resonator Photoacoustic Sensing Cell
  • Figure 3-180: Mass Spectrometry vs. Mirthe Mid IR Sensors For To Measuring Trace Gas At Ppm Or Ppb Sensitivity
  • Table 3-181: Mirthe Impact In Environment And Homeland Security:
  • Table 3-182: Mirthe Impact In Health:
  • Table 3-183: Mirthe Impact In Industrial Outreach:
  • Figure 3-184: Mirthe's Strategic 3-Level Framework
  • Figure 3-185: Cascade Technologies Mid Infrared Countermeasures ICM100
  • Table 3-186: Cascade Technologies Mid Infrared Countermeasures ICM100 Features
  • Figure 3-187: Cascade Technologies CT2100 Analyzer
  • Table 3-188: Cascade Technologies CT2100 Analyzer Measurements*
  • Table 3-189: Cascade Technologies Analyzers
  • Figure 3-190: Cascade Technologies Quantum Cascade Laser (QCL),
  • Table 3-191: Cascade Technologies Rapid Sweep Combined With High Duty Cycles Key Advantages
  • Figure 3-192: Thorlabs Adaptive InfraRed Imaging Spectroradiometer
  • Table 3-193: Physical Sciences Adaptive InfraRed Imaging Spectroradiometer Features
  • Figure 3-194: ThorlabsAdaptive InfraRed Unprocessed AIRIS Image Of Atmospheric Tracer Release Viewed From Above.
  • Figure 3-195: ThorlabsAIRIS Processed Image Showing Detected Tracer Plume Location
  • Figure 3-196: ThorlabsRelease Point, Emission, and Absorption of Detected Tracer Plume:
  • Table 3-197: Thorlabs Detected Tracer Plume Applications:
  • Table 3-198: THORLABS Adaptive InfraRed Imaging Spectroradiometer Applications
  • Figure 3-199: Thorlabs Maxion Laser Products
  • Figure 3-200: Maxion Products Single Mode Lasers
  • Table 3-201: Thorlabs / Maxion Turn-Key Laser System Integration Benefits
  • Table 3-202: Maxion Single Mode Laser Device Performance
  • Table 3-203: Maxion Technologies Infrared Semiconductor Laser Products Solutions Areas
  • Figure 3-204: Maxion Multimode Lasers High Heat Load Laser Package
  • Figure 3-205: Maxion Turnkey Laser System Single Mode Lasers
  • Figure 3-206: Maxion Linear Arrays Of IC and QC Lasers -- C-mount and NS-mount Lasers
  • Figure 3-207: Maxion LED in a Dewar
  • Figure 3-208: VIASPACE Ionfinity SIM Ionizes The Sample Without Fragmentation
  • Figure 3-209: Ionfinity Industrial Process Control And Environmental Monitoring
  • Table 3-210: Power Technology Available Wavelengths & Output Powers
  • Table 3-211: Power Technology Applications For An Infrared Viewer
  • Table 3-212: Power Technology Quantum-Cascade Lasers Features
  • Table 3-213: Power Technology Quantum-Cascade Lasers Mechanical Dimensions
  • Figure 3-214: Power Technology Temperature Controlled Laser Diode Modules
  • Table 3-215: Power Technology Mid IR Sensor Applications
  • Figure 3-216: Power Technology Infrared Viewers
  • Figure 3-220: Power Technology Mid IR Specifications
  • Table 3-221: Power Technology Infrared Illuminator
  • Figure 3-222: Power Technology. Infrared Photosensivity
  • Table 3-223: Power Technology Near Infrared Viewer Power Densities
  • Figure 3-224: Power Technology Laser Modules for OEM
  • Figure 3-225: M Squared Firefly-IR
  • Figure 3-226: M Squared SolsTiS cw Ti Sapphire Laser
  • Figure 3-227: M Squared in Biomedicine Laser Device
  • Table 3-228: M Squared Firefly-IR Applications Positioning
  • Table 3-229: M Squared Firefly-THz features
  • Figure 3-230: Novawave Technology IRIS™ 1000 Tunable Laser System
  • Table 3-231: Novawave Technology System Features
  • Figure 3-232: GE Wireless Sensor Networks
  • Table 3-233: PNNL Electronics Products
  • Table 3-234: PNNL System Integration
  • Figure 3-235: Hamamatsu Infrared Detector
  • Figure 3-236: Hamamatsu InGaAs Photodiodes
  • Figure 3-237: Hamamatsu Detectors With Sensitivity To Wavelengths
  • Figure 3-238: Hamamatsu Continuous-Wave QCL For Room Temperature Operation
  • Table 3-239: Hamamatsu Laser Group Products
  • Figure 3-240: Opto Solutions Products
  • Table 3-241: Opto Solutions - IR Photonics Features and Applications
  • Figure 3-242: ILX Lightwave Laser Diode Instrumentation
  • Figure 3-243: Aerocrine NIOX MINO
  • Figure 3-244: Aerocrine NIOX FLEX
  • Figure 3-245: Telops TS-IR Thermal Scientific IR Camera
  • Table 3-246: Telops TS-IR Thermal Scientific IR Camera Features
  • Figure 3-247: Telops HDR-IR High Dynamic Range IR Camera
  • Table 3-248: Telops HDR-IR High Dynamic Range IR Camera Features
  • Table 3-249: Telops FAST-IR 2K Rapid IR Camera Features
  • Table 3-250: Telops Telops HD-IR High Definition IR Camera Features
  • Table 3-251: Telops MS-IR Multispectral IR Camera Features
  • Table 3-252: Telops Hyper-Cam Defense and Security Applications
  • Table 3-253: Telops Hyper-Cam Environmental Research Applications:
  • Table 3-254: Telops Hyper-Cam Fundamental Research Applications:
  • Table 3-255: Telops Hyper-Cam New Platform Applications
  • Figure 3-256: Telops TEL-1000 MW Infrared Camera
  • Table 3-257: Telops TEL-1000 MW Infrared Camera Key Benefits
  • Table 3-258: Telops TEL-1000 MW Infrared Camera Applications
  • Table 3-259: Telops TEL-1000 MW Infrared Camera Features
  • Figure 3-260: Ulis Pro Series Pico640P Thermal Image Sensors
  • Table 3-261: Ulis Pico640P Thermal Image Sensors
  • Figure 3-262: Ulis Elite Series Pico1024ET Thermal Image Sensors
  • Figure 3-263: Advanced Photonix Photodiodes
  • Figure 3-264: Newport Corporation Mid-Infrared Sensor Cards
  • Table 3-265: Newport Corporation Ulis Elite Series Pico1024ET
  • Figure 3-266: Vigo System S.A. 2-11 μm IR Photoconductors
  • Figure 3-267: Vigo System S.A. 2-13 μm IR Photoconductors Thermoelectrically Cooled
  • Figure 3-268: Vigo System S.A. 2-11 μm PHOTOELECTROMAGNETIC DETECTORS
  • Figure 3-269: Vigo System S.A. 2-11 μm Photo-electromagnetic Detectors Optically Immersed
  • Figure 3-270: Vigo System S.A. 3-8 μm IR PHOTOVOLTAIC DETECTORS
  • Figure 3-271: Vigo System S.A. 2-8 μm IR Photovoltaic Detectors Optically Immersed
  • Figure 3-272: Vigo System S.A. 8-11 μm IR Photovoltaic Multiple Junction Detectors
  • Figure 3-273: Vigo System S.A. 8-11 μm IR Photovoltaic Multiple Junction Detectors Optically Immersed
  • Figure 3-274: Horiba Scientific InGaAs Detector for the NIR 0.8-2.6 Micrometer
  • Table 4-1: Power Technology Mid IR Sensor Applications
  • Table 4-2: Mid IR Sensor Applications for the Technology
  • Table 4-3: Applications for Instrumentation That Unambiguously Detects Trace Levels Of A Targeted Compound In Real Time
  • Table 4-4: Mid IR Technology Quantum-Cascade Lasers Features
  • Figure 4-5: Daylight Solutions' Core Technology
  • Figure 4-6: Senseair Carbon Dioxide Sensors
  • Figure 4-7: Vertical Heat Flow Model Of Jondetech Thermopiles
  • Figure 4-8: Jondetech Thermopile Infrared Radiation Tetectors Generation Flex
  • Figure 4-9: Mass Spectrometry vs. Mirthe Mid IR Sensors For To Measuring Trace Gas At Ppm Or Ppb Sensitivity
  • Table 4-10: Mid IR Sensing Systems Components
  • Table 4-11: Daylight Solutions Basic Technologies
  • Figure 4-12: External Cavity Quantum Cascade Laser Design
  • Figure 4-13: Daylight Solutions Available Tuning Ranges For cw ECqcL™.
  • Figure 4-14: Transmission Of Light Through The Atmosphere From The Visible To The Mid- Infrared. Sources Of The Major Absorptions Are Indicated
  • Figure 4-15: Graphical Representation Of The Location Of Strong Absorptions Of Molecules Interest
  • Figure 4-16: Thermocouple Lead Structures Based On Nanotechnology
  • Figure 4-17: JonDeTechs Nanotechnology Thermopiles
  • Figure 4-18: Nanowire Battery Can Hold 10 Times The Charge Of Existing Lithium-Ion Battery
  • Table 4-19: Computerization Of Microscopic Manufacturing Procedure Benefits
  • Table 4-20: Battery Chemistries At The Forefront For Mid IR Sensors
  • Figure 4-21: Biofilm Formation
  • Figure 4-22: Mid IR Spectrum Wavenumber and Absorbance
  • Figure 4-23: Mid-Infrared Light Novel Mid-Infrared Materials
  • Figure 4-24: Mid-Infrared Light Sources
  • Figure 4-25: Mid IR Sensor Applications & Testbeds
  • Figure 4-26: University of Oklahoma High-Tech Breath Test
  • Figure 4-27: Physical Vapor Nanoparticle Synthesis Process
  • Figure 4-28: Nanophase Technologies Organic Dispersions In Manufacturing
  • Figure 4-29: Nanophase Technologies Organic Dispersions In Polar And Non-Polar Organic Fluids
  • Figure 5-1: AdTech Optics QC Laser Coverage
  • Table 5-2: Block Engineering LaserScope IR Microscope Key Benefits & Advantages
  • Table 5-3: Bosch Building Automation Sensors
  • Table 5-4: Bosch Building Automation Sensor Management Architecture
  • Figure 5-5: Danaher Family of Brands
  • Table 5-6: Selected Enocean Shareholders:
  • Figure 5-7: Ferro Solutions Energy Harvesters And Sensors
  • Figure 5-8: Ferro Solutions Energy Harvesters And Sensors Target Markets
  • Table 5-9: Ferro Solutions Selected Clients
  • Table 5-10: Ferro Solutions Energy Harvester Uses
  • Table 5-11: Ferro Solutions FS Energy Harvester Industrial & Process Automation and Utilities
  • Table 5-12: FLIR Systems Advanced Sensing Technologies Benefits
  • Table 5-13: FLIR Systems Thermal Imaging Infrared Cameras Target Markets
  • Table 5-14: FLIR Systems Commercial Vision Applications
  • Table 5-15: FLIR Systems Sensor Applications
  • Table 5-16: FLIR Systems Sensor Uses
  • Table 5-17: FLIR Systems Sensor Market Segments
  • Table 5-18: FLIR Detection System Sensor Applications
  • Table 5-19: FLIR Mid IR Thermal Imaging Systems Benefits
  • Figure 5-20: GE Wireless Sensor Networks
  • Table 5-21: II-VI Significant Materials Capabilities
  • Table 5-22: II-VI Specific Growth Strategies:
  • Table 5-23: Johnson Controls Sensors
  • Humidity:
  • Temperature:
  • Pressure:
  • Carbon Dioxide:
  • Occupancy:
  • Network Sensors:
  • Figure 5-24: Johnson Controls Sensor Products
  • Table 5-25: Johnson Controls Sensor Types
  • Table 5-26: Johnson Controls Valve Categories:
  • Figure 5-27: Lockheed Martin F35B In-Flight STOVL Operations
  • Figure 5-28: Lockheed Martin Autonomous Underwater Vehicles
  • Figure 5-29: Lockheed Martin C-139 J Cargo Plane
  • Figure 5-30: Lockheed Martin Next Generation Identification Systems
  • Figure 5-31: Lockheed Martin Linking Legacy Radio Waveforms to AMF JTRS
  • Figure 5-32: Micro-Epsilon Thermal Camera
  • Figure 5-33: Quartz Resonator Photoacoustic Sensing Cell
  • Figure 5-34: Mass Spectrometry vs. Mirthe Mid IR Sensors For To Measuring Trace Gas At Ppm Or Ppb Sensitivity
  • Table 5-35: Mirthe Impact In Environment And Homeland Security:
  • Table 5-36: Mirthe Impact In Health:
  • Table 5-37: Mirthe Impact In Industrial Outreach:
  • Figure 5-38: Mirthe's Strategic Multi-level Mid IR Sensor Framework
  • Table 5-39: OPTO Solutions Opto 22 Systems Markets
  • Table 5-40: Pacific Northwest National Laboratory (PNNL) Focus
  • Table 5-41: Pacific Northwest National Laboratory (PNNL) Electronics Products
  • Table 5-42: PNNL System Integration
  • Table 5-43: Power Technology Laser Applications
  • Figure 5-44: SenseAir Carbon Dioxide Sensors
  • Table 5-45: Sofradir Notable Accomplishments
  • Table 5-46: Maxion Technologies Laser Product Segment Positioning
  • Figure 5-47: Airsense Smart Building Monitor
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