世界の環境センシング&モニタリング技術市場

当商品の販売は、2011年10月22日を持ちまして終了しました。

アップデート版はこちらになります。

原文目次

Abstract

This Report:

• The global market for environmental sensing and monitoring technologies was worth $9.1 billion in 2008 and an estimated $10.1 billion in 2009. This should reach $13 billion in 2014, for a compound annual growth rate (CAGR) of 5.2%.
• Radon, GPS, remote sensing and new technologies have the largest share of the market, generating $4.9 billion in 2008 and an estimated $5.1 billion in 2009. This segment is expected to be worth $6.8 billion in 2014, for a CAGR of 6.2%.
• Terrestrial sensing and monitoring technologies combine for the second-largest market share, generating $2.6 billion in 2008 and an estimated $2.7 billion in 2009. This is expected to grow at a CAGR of 4.7% to reach $3.4 billion in 2014.

INTRODUCTIONON

The global environmental remediation and monitoring business is huge. In just the United States market, each year some $250 billion of economic output stems from all pollution control and monitoring activities. Among the faster growing segments of this "clean-up" business is the market for sophisticated sensors, monitoring equipment, large scale networks such as satellite, GPS and remote sensing, associated networking equipment and ancillaries, and a large slate of new technologies. Globally, the markets for environmental sensors and the related sub-segments noted above (e.g., monitoring, networks, remote sensing, etc.), account for approximately $15 billion of economic activity at present with a projected average annual growth of 5% through 2014.

The purpose of this report is to measure and forecast the demand for sensor equipment, systems, and networks that are sold for terrestrial, oceanic, and atmospheric environmental sensing. The report defines markets for sensors and/or sensor "systems", including monitoring networks and, separately, defines markets for the advanced materials and advanced sensor concepts that represent markets of the future. In regard to cutting edge developments, nanotechnology, where considerable EPA research dollars have been expended, is covered. An additional purpose of this report is to assess the needs of long-term environmental monitoring applications and to summarize the capabilities of emerging sensor technologies.

Environmental sensors come in a thousand or more forms and are based on a wide range of physical and chemical principles, and with various types of usable outputs. Typical contaminants monitored for are metals, volatile organic compounds, biological contaminants, and radioisotopes. The field applications of sensors are extremely varied, too. Among the key trends in the environmental sensors business is miniaturization (down to the nano scale), continuous and/or real time sensing capabilities, wireless networked operation, rapid processing, and increased sensitivity or flexibility. Examples of report environmental focus areas include: vehicular emissions, combustion of fossil fuels, agricultural runoff, industrial and mine waste disposal, ocean spills and dumping, as well as climate change and weather monitoring.

Environmental sensors and monitoring technologies have not only become a substantial high technology business but future growth is almost pre-ordained due to the fact that economies around the world will either have to manage their environmental impact or eventually destroy themselves. At the same time that environmental clean-up is more or less forced onto the policy-making agenda, technology revolutions in nanotechnology, semiconductors (lab-on-a-chip) and communications are facilitating sensor product development and implementation.

SCOPE OF STUDY

This BCC study focuses on key environmental sensor technologies and applications, and provides data about the size and growth of numerous sensor markets, company profiles and industry trends. Cutting edge developments, research priorities and potential business opportunities are a key focus.

The report contains coverage of:

• The environmental sensor industry and its structure, and the many companies involved in providing these products.
• The markets for environmental sensors including passive, active, electromechanical and semiconductors.
• Sensor applications in, for example, temperature sensing and chemical detection.
• Company profiles including overseas manufacturers.
• Patent activity.

INTENDED AUDIENCE

With its broad scope and in-depth analyses, this study will prove to be a valuable resource, particularly for anyone involved with or interested in the environmental sensors. It will be particularly useful for researchers, laboratory and government personnel working in research or company settings, as well as business professionals, such as marketing managers, strategic planners, forecasters, new product and business developers, who are involved with most aspects of the sensors industry. It also will be of value to potential investors and members of the general public who are interested in acquiring a business-oriented view of the use of sensors in environmental monitoring. The projections, forecasts and trend analyses found in this report provide readers with the necessary data and information for decision-making.

METHODOLOGY

The research methodology was both quantitative and qualitative in nature. Market data was derived from trade sources, self reported data by companies, and government statistics covering the pollution control markets and the sensor/instrumentation markets. The most recent academic literature on environmental sensors was reviewed. Other key market information sources include sensor magazines and journals and related books, trade literature, marketing literature, other product/promotional literature, annual reports, security analyst reports, government and other publications. A patent search and analysis was conducted.

Table of Contents

Chapter-1: SUMMARY 4

• MAJOR FINDINGS 5
• KEY FINDINGS OF THIS STUDY 6
• SUMMARY TABLE GLOBAL ENVIRONMENTAL SENSOR AND MONITORING BUSINESS BY MARKET CATEGORY, THROUGH 2014 ($ BILLIONS) 7
• SUMMARY FIGURE GLOBAL ENVIRONMENTAL SENSOR AND MONITORING BUSINESS BY MARKET CATEGORY, 2007-2014 ($ BILLIONS) 8

Chapter-2: OVERALL ENVIRONMENT MARKET CONTEXT FOR SENSORS 5

• THE OVERALL ENVIRONMENT MARKET CONTEXT 9
• TABLE 1 U.S. INDUSTRIES WITH LARGEST TOTAL ENVIRONMENTAL EXPENDITURES, 2008 ($ BILLIONS) 10
• TABLE 2 TOTAL U.S. ENVIRONMENTAL MONITORING AND TESTING MARKET: OPERATING COSTS EXCLUSIVE OF EQUIPMENT PURCHASES, 2008 ($ MILLIONS) 10
• SENSOR MARKET CLASSIFICATION 10
• ENVIRONMENTAL PRESSURES ARE THE KEY DRIVING FORCE VARIABLE UNDERPINNING FUTURE GROWTH 11
• OTHER KEY MARKET TRENDS 12
• OTHER KEY MARKET TRENDS (CONTINUED) 13

Chapter-3: REGULATORY DRIVERS AND MONITORING INITIATIVES 4

• OVERVIEW 14
• GOVERNMENT ENVIRONMENTAL MONITORING SPENDING TRENDS 14
• EPA ENVIRONMENTAL STRICTURES 15
• EPA ENVIRONMENTAL STRICTURES (CONTINUED) 16
• AIR MONITORING 17
• TYPES OF ENVIRONMENTAL NETWORKS 17
• NATIONAL ECOLOGICAL OBSERVATORY NETWORK 17
• ATMOSPHERIC RADIATION MEASUREMENT CLIMATE RESEARCH FACILITY 18

Chapter-4: CATEGORIES OF ENVIRONMENTAL SENSORS 3

• OVERVIEW 19
• ANALOG VERSUS DIGITAL ENVIRONMENTAL SENSORS 19
• TYPES OF ENVIRONMENTAL SENSING 20
• TABLE 3 TYPES OF ENVIRONMENTAL SENSING AND NUMBERS OF COMPANIES INVOLVED, 2009 20
• TABLE 3 (CONTINUED) 21

Chapter-5: MARKET SEGMENTS IN THE ENVIRONMENTAL SENSOR BUSINESS 11

• OVERVIEW 22
• TABLE 4 TYPES OF SENSORS USEFUL IN ENVIRONMENTAL DETECTION AND MONITORING 22
• TABLE 4 (CONTINUED) 23
• DISCUSSION OF PRINCIPAL TYPES 23
• FLAME IONIZATION DETECTORS 23
• IN-SITU PERMEABLE FLOW SENSOR 24
• LASER-INDUCED FLUORESCENCE 25
• METAL OXIDE SEMICONDUCTOR SENSORS 25
• PHOTO IONIZATION DETECTOR 26
• RIBBON NAPL SAMPLER 26
• CATALYTIC BEAD SENSORS 27
• ELECTROCHEMICAL SENSORS 27
• SURFACE GAMMA RADIATION DETECTION 28
• The 3-D Gamma Modeler 28
• RadScan 600 Gamma-Ray Imaging System 28
• In-Situ Gamma Spectroscopy with ISOCS (an In-Situ Object Counting System). 29
• Infrared Sensors 29
• Laser-acoustic Sensor 29
• Microwave Radiometer 30
• Visible Sensors 30
• Ultraviolet Sensors 31
• Radar 31
• MARKET SALES BY TYPE 31
• TABLE 5 GLOBAL SALES OF ENVIRONMENTAL SENSORS BY TYPE WITHIN MARKET CATEGORIES, THROUGH 2014 $ MILLIONS 32

Chapter-6: INTERNATIONAL MARKETS 24

• OVERVIEW 33
• TAIWAN: WIRELESS SENSORS MARKET FOR ENVIRONMENTAL MONITORING AND CONTROL 33
• MARKET DEMAND 33
• SPECIFIC EXPORT PROSPECTS 34
• KEY SUPPLIERS 35
• Key Suppliers (Continued) 36
• CHINA MARKET: SENSORS AND MONITORING INSTRUMENTS 37
• TABLE 6 TYPES OF WATER QUALITY MONITORING EQUIPMENT MOST IN DEMAND IN CHINA 37
• TABLE 6 (CONTINUED) 38
• CHINESE GOVERNMENT ENVIRONMENTAL STRATEGY 38
• MARKET DEMAND 39
• GOVERNMENT ROLE IN ENVIRONMENTAL MONITORING INITIATIVES 39
• Government Role in Environmental ...(Continued) 40
• IMPORTS FROM THE UNITED STATES 41
• TABLE 7 PRINCIPAL COUNTRIES OF ORIGIN FOR WATER MONITORING AND SENSORS IMPORTED BY CHINA IN APPROXIMATE RANK, 2008 41
• KEY SUPPLIERS TO CHINA' S MARKET 42
• TABLE 8 LIST OF PRINCIPAL FIRMS ACTIVE IN SELLING WATER QUALITY MONITORING TECHNOLOGIES IN CHINA 43
• TABLE 8 (CONTINUED) 44
• CATEGORIES OF PROSPECTIVE BUYERS 44
• MEP 44
• China National Environmental Monitoring Center 45
• MARKET ISSUES AND OBSTACLES 45
• Low Quality Domestic Equipment 45
• The WTO 45
• CANADA ENVIRONMENTAL INDUSTRY/WASTEWATER MANAGEMENT SENSORS AND MONITORING 46
• TABLE 9 DISTRIBUTION OF ENVIRONMENTAL REVENUES BY PROVINCE (%) 46
• MARKET DEMAND 46
• TABLE 10 WATER FILTRATION EQUIPMENT/SEWAGE INCLUDING MONITORING EXPENDITURES ($ MILLIONS) 47
• BELGIAN MARKET FOR AIR POLLUTION SENSORS AND MONITORING SYSTEMS 47
• MARKET OVERVIEW 48
• Brussels Region 49
• Wallonia 49
• Flanders 50
• MARKET DEMAND AND TRENDS 50
• Particulates 50
• Indoor Air Quality 50
• TABLE 11 MONITORING AND SENSOR EXPORT POSSIBILITIES TO BELGIUM 51
• COMPETITION AND MARKET ENTRY 51
• KOREAN SENSOR INDUSTRY 52
• MARKET DEMAND 52
• TABLE 12 SIZE OF THE SENSOR MARKET IN KOREA, 2007 AND 2008 ($ MILLIONS) 53
• KEY SUPPLIERS 54
• TABLE 13 INDENTIFICATION OF KEY SENSOR SUPPLIERS IN THE KOREAN MARKET 55
• MARKET ENTRY STRATEGIES 56

Chapter-7: OTHER LARGE SEGMENTS OF THE ENVIRONMENTAL SENSING AND MONITORING 12

• OVERVIEW 57
• GLOBAL POSITIONING SYSTEM (GPS) FOR ENVIRONMENTAL MONITORING 57
• GLOBAL POSITIONING SYSTEM (CONTINUED) 58
• TABLE 14 GLOBAL MARKET DEMAND FOR ENVIRONMENT RELATED APPLICATIONS OF GPS TECHNOLOGIES, THROUGH 2014 ($ MILLIONS) 59
• FIGURE 1 GLOBAL MARKET DEMAND FOR ENVIRONMENT RELATED APPLICATIONS OF GPS TECHNOLOGIES, 2007-2014 ($ MILLIONS) 60
• THE RADON MONITORING AND TESTING MARKET 60
• TABLE 15 GLOBAL MARKET DEMAND FOR RADON TESTING AND MITIGATION TECHNOLOGIES, THROUGH 2014 ($ MILLIONS) 61
• FIGURE 2 GLOBAL MARKET DEMAND FOR RADON TESTING AND MITIGATION TECHNOLOGIES, 2007-2014 ($ MILLIONS) 62
• ENVIRONMENTAL APPLICATIONS OF REMOTE SENSING 62
• SCOPE OF APPLICATION 62
• PASSIVE VERSUS ACTIVE DATA COLLECTION 63
• PRINCIPAL ENVIRONMENTAL APPLICATIONS OF REMOTE SENSING DATA 63
• Principal Environmental Applications ...(Continued) 64
• MARKET DEMAND 65
• TABLE 16 MARKET DEMAND FOR ENVIRONMENT RELATED REMOTE SENSING TECHNOLOGIES, THROUGH 2014 ($ BILLIONS) 66
• FIGURE 3 MARKET DEMAND FOR ENVIRONMENT RELATED REMOTE SENSING TECHNOLOGIES, 2007-2014 ($ BILLIONS) 66
• THE REMOTE SENSING SOFTWARE MARKET 66
• GOVERNMENT INITIATIVES RELEVANT TO REMOTE SENSING 67
• R&D FOCUS 67
• TABLE 17 PRINCIPLE ADVANCES EXPECTED IN ENVIRONMENTAL MONITORING ASPECTS OF REMOTE SENSING, 2008-2015 67
• TABLE 18 TOP FORECASTED ENVIRONMENTAL MONITORING APPLICATIONS FOR REMOTE SENSING 68
• R&D Focus (Continued) 68

Chapter-8: TECHNOLOGY AND PRODUCT DEVELOPMENT 29

• NEW SENSOR TECHNOLOGIES 69
• TABLE 19 ECONOMIC ACTIVITY (PRODUCT AND R&D) ATTRIBUTABLE TO NEW ENVIRONMENTAL SENSOR/MONITORING TECHNOLOGIES, THROUGH 2014 ($ MILLIONS) 69
• TABLE 19 (CONTINUED) 70
• REAL TIME MONITORING APPROACHES 70
• NANOSENSORS 71
• CARBON NANOTUBE SENSORS 72
• Carbon Nanotube Sensors (Continued) 73
• NANOWIRES AS INEXPENSIVE SENSORS 74
• ENVIRONMENTAL NANOSENSOR MARKET PROSPECTS 74
• SENSORS FOR HEAVY METAL DETECTION 75
• DIODE LASER BASED SENSORS 76
• DIODE LASER BASED SENSORS (CONTINUED) 77
• DIODE LASER BASED SENSORS (CONTINUED) 78
• MILLIHERTZ/TERAHERTZ SENSOR TECHNOLOGY 79
• PRINTED AND ORGANIC SENSORS 80
• LAB ON A CHIP CONCEPTS 80
• LOW VOLTAGE CHIPS 81
• BIOSENSORS 82
• BIOSENSORS (CONTINUED) 83
• SYSTEMS AND NETWORKING APPROACHES 84
• CISCO/NASA SENSOR NETWORKING PROJECT 84
• DELAWARE ENVIRONMENTAL OBSERVING SYSTEM (DEOS) 85
• Delaware Environmental ...(Continued) 86
• GLACSWEB PROJECT 87
• SOIL MONITORING SYSTEMS 87
• TIDE STATION DATA SHARING NETWORKS 88
• SENSOR MANAGEMENT FOR APPLIED RESEARCH TECHNOLOGIES (SMART) 88
• INTEGRATED SENSOR WEB APPROACH FOR NATURAL HAZARD APPLICATIONS 88
• DYNAMIC LARGE-SCALE SENSOR NETWORKS 89
• OTHER SENSOR NETWORKING INITIATIVES 89
• MASS SPECTROMETRY BASED DEVICES 90
• ACOUSTIC WAVE SENSORS 91
• TEMPERATURE SENSOR 92
• MASS SENSOR 92
• DEW POINT/HUMIDITY SENSOR 92
• VAPOR CHEMICAL SENSOR: COATED AND UNCOATED 92
• MEMS SENSORS 93
• ADAPTATION OF SPACE PROGRAM SENSORS FOR TERRESTRIAL USE 93
• RADIOISOTOPE SENSORS 94
• VOLATILE ORGANIC COMPOUND SENSORS 95
• ADVANCED SENSOR COMPUTATIONAL TECHNIQUES 96
• ADVANCED SENSOR ... (CONTINUED) 97

Chapter-9: ENVIRONMENTAL SENSORS AND NANOTECHNOLOGY 11

• OVERVIEW 98
• PRINCIPAL NANOTECHNOLOGY RESEARCH INITIATIVES INVOLVING SENSING TECHNOLOGIES OR DEVICES FOR POLLUTANT AND MICROBIAL DETECTION 98
• NANOSENSOR FOR DETECTION OF SAXITOXIN 99
• CONDUCTING-POLYMER NANOWIRE IMMUNOSENSOR ARRAYS FOR MICROBIAL PATHOGENS 99
• COMPOUND SPECIFIC IMPRINTED NANOSPHERES FOR OPTICAL SENSING 100
• NANOMATERIAL-BASED MICROCHIP ASSAYS FOR CONTINUOUS ENVIRONMENTAL MONITORING 101
• M-INTEGRATED SENSING SYSTEM (M-ISS) BY CONTROLLED ASSEMBLY OF CARBON NANOTUBES ON MEMS STRUCTURES 102
• LOW COST ORGANIC GAS SENSORS ON PLASTIC FOR DISTRIBUTED ENVIRONMENTAL MONITORING 102
• THE SILICON OLFACTORY BULB: A NEUROMORPHIC APPROACH TO MOLECULAR SENSING WITH CHEMORECEPTIVE NEURON MOS TRANSISTORS (CNMOS) 103
• METAL BIOSENSORS: DEVELOPMENT AND ENVIRONMENTAL TESTING 103
• ADVANCED NANOSENSORS FOR CONTINUOUS MONITORING OF HEAVY METALS 104
• NANOSENSORS FOR DETECTION OF AQUATIC TOXINS 105
• ULTRASENSITIVE PATHOGEN QUANTIFICATION IN DRINKING WATER USING HIGHLY PIEZOELECTRIC PMN-PT MICROCANTILEVERS 106
• A NANOCONTACT SENSOR FOR HEAVY METAL ION DETECTION 106
• NANOSTRUCTURED POROUS SILICON AND LUMINESCENT POLYSILOLES AS CHEMICAL SENSORS FOR CARCINOGENIC CHROMIUM(VI) AND ARSENIC(V) 107
• MICROFLUIDICS 107
• MICROFLUIDICS (CONTINUED) 108

Chapter-10: PATENT ANALYSIS 14

• TABLE 20 DISTRIBUTION OF ENVIRONMENTAL SENSOR PATENTS BY CATEGORY OF ASSIGNEE, 2007-2008 109
• SAMPLE PATENTS FROM U.S. PATENT DATABASE 109
• SYSTEM AND METHOD FOR EFFICIENT AND COLLECTIVE ADJUSTMENT OF SENSOR REPORTING RANGES FOR LONG-LIVED QUERIES 109
• Abstract 109
• PHOTOLUMINESCENT POLYMETALLOLES AS CHEMICAL SENSORS 110
• Abstract 110
• SENSING AND ANALYSIS SYSTEM, NETWORK, AND METHOD 110
• Abstract 111
• IONIZATION-BASED DETECTION 111
• Abstract 111
• NANO-MECHANIC MICROSENSORS AND METHODS FOR DETECTING TARGET ANALYTES 111
• Abstract 112
• MICROSCOPIC BATTERIES FOR MEMS SYSTEMS 112
• Abstract 112
• MEMS BASED CONDUCTIVITY-TEMPERATURE-DEPTH SENSOR FOR HARSH OCEANIC ENVIRONMENT 112
• Abstract 112
• METHOD AND WIRELESS COMMUNICATING APPARATUS FOR ANALYSIS OF ENVIRONMENT 113
• Abstract 113
• SYSTEM AND METHOD FOR TRANSMITTING POLLUTION INFORMATION OVER AN INTEGRATED WIRELESS NETWORK 113
• Abstract 113
• METHOD OF AND DEVICE FOR DETECTING OIL POLLUTION ON WATER SURFACES 113
• Abstract 114
• GAN-BASED SENSOR NODES FOR IN SITU DETECTION OF GASES 114
• Abstract 114
• EMBEDDED PIEZOELECTRIC MICROCANTILEVER SENSORS 115
• Abstract 115
• MONITORING AN ENVIRONMENT USING A RFID ASSEMBLY 115
• Abstract 115
• ANALYZER 115
• Abstract 116
• LASER REMOTE SENSING OF BACKSCATTERED LIGHT FROM A TARGET SAMPLE 116
• Abstract 116
• METHOD FOR SELECTING REPRESENTATIVE ENDMEMBER COMPONENTS FROM SPECTRAL DATA 117
• Abstract 117
• METHOD FOR INTELLIGENT PARKING/POLLUTION AND SURVEILLANCE CONTROL SYSTEM 118
• Abstract 118
• IONIZATION SOURCE FOR MASS SPECTROMETER 118
• Abstract 118
• INTEGRATED NANOTUBE SENSOR 119
• Abstract 119
• NETWORK OF SENSOR NODES ASSEMBLIES AND METHOD OF REMOTE SENSING WITHIN LIQUID ENVIRONMENTS 119
• Abstract 119
• INTERSUBBAND SEMICONDUCTOR LASERS WITH ENHANCED SUBBAND DEPOPULATION RATE 120
• Abstract 120
• SURFACE-PLASMON-RESONANCE SENSING TECHNIQUE USING ELECTRO-OPTIC MODULATION 121
• Abstract 121
• METHOD FOR COLLECTING AND PROCESSING DATA USING INTERNETWORKED WIRELESS INTEGRATED NETWORK SENSORS (WINS) 121
• Abstract 122

Chapter-11: COMPANY PROFILES 30

• AGILENT TECHNOLOGIES 123
• AIRMAR TECHNOLOGY CORPORATION 123
• AIRTEST TECHNOLOGIES, INC 123
• ALLEGRO MICROSYSTEMS 124
• ANALOG DEVICES, INC. 124
• APPLIED GEOMECHANICS, INC 124
• APPLIEDSENSOR, INC. 125
• APPRISE TECHNOLOGIES 125
• CASELLA MEASUREMENT, LTD. 125
• CHELSEA TECHNOLOGIES GROUP LTD 126
• CIRRUS LOGIC, INC 126
• CODAR OCEAN SENSORS 126
• CORADYN BIOSYSTEMS, LLC 127
• CROSSBOW TECHNOLOGY, INC. 128
• CYRANO SCIENCES (DIVISION OF SMITHS DETECTION) 128
• DOLOMITE-US 129
• DUST NETWORKS, INC 129
• ELECTRONIC SENSOR TECHNOLOGY 130
• ENDEVCO 130
• ENSCO 130
• ENVIROMON.NET (A DIVISION OF NETMON) 131
• EPCOS AG 131
• ESI ENVIRONMENTAL SENSORS, INC. 132
• FLUID COMPONENTS, INTL. 132
• FREESCALE SEMICONDUCTOR, INC. 132
• GENEFLUIDICS 133
• GILL INSTRUMENTS, LTD 133
• HONEYWELL SENSING & CONTROL 134
• HYDROTECHNICS 134
• INFINEON TECHNOLOGIES, INC. 134
• INFOTONICS TECHNOLOGY, INC. 135
• INNOVA AIRTECH INSTRUMENTS A/S 135
• INTERNATIONAL SENSOR TECHNOLOGY 135
• INTERSIL CORPORATION 136
• KESTREL CORPORATION 136
• KMG2 SENSORS CORPORATION 137
• LANDAUER 137
• LINEAR TECHNOLOGY CORPORATION 138
• LOS ALAMOS NATIONAL LABORATORY 138
• MAXBOTIX INC. 138
• MAXIM INTEGRATED PRODUCTS, INC., 139
• MICROCHIP TECHNOLOGY, INC. 139
• NEXSENS TECHNOLOGY, INC. 139
• NASA GODDARD SPACE FLIGHT CENTER 139
• NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY (NIST) 140
• NATIONAL SEMICONDUCTOR CORPORATION 140
• NEXTECH MATERIALS, LTD. 140
• NXP SEMICONDUCTORS 141
• OCEAN SENSORS, INC. 141
• OCEANA SENSOR TECHNOLOGY 142
• ONSET COMPUTER 142
• OPTICAL SCIENTIFIC, INC. 143
• PACIFIC CREST CORPORATION 143
• PALL CORPORATION 143
• PCB PIEZOTRONICS, INC. 143
• PRECISION MEASUREMENT ENGINEERING, INC. 144
• QUANTITECH LTD 144
• QUIXOTE TRANSPORTATION TECHNOLOGIES, INC 145
• RENAISSANCE COMPUTING INSTITUTE (RENCI) 145
• RUPPRECHT & PATASHNICK 146
• SANDIA NATIONAL LABORATORIES 146
• SATLANTIC, INC. 147
• SENSATA TECHNOLOGIES, INC. 147
• SENSIRION, AG 147
• SENSOR PRODUCTS, INC. 148
• SENSORS, INC. 148
• SIEMENS AG 149
• SIERRA MONITOR CORPORATION 149
• STMICROELECTRONICS 149
• TRANZEO WIRELESS TECHNOLOGIES USA INC. (A DIVISION OF TRANZEO WIRELESS) TECHNOLOGIES INC. 150
• TRONICS MICROSYSTEMS 150
• VAISALA INC. 151
• VTI TECHNOLOGIES 151
• WAYNE STATE UNIVERSITY 151
• COMPUTER SCIENCE DEPARTMENT 151
• YSI INCORPORATED 152
• OTHER SENSOR INDUSTRY ORGANIZATIONS 152

関連商品