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News Article | February 15, 2017
Site: co.newswire.com

New Patented Sensor Technology can accurately detect gunpowder that is found in gunpowder bombs, and modern shotguns, handguns and rifles. ​​There were 476 Mass Shootings in 2016 alone! Further, there were more than 150,000 plus gun violence incidents or deaths from 2013-2016, and already 40 mass shootings this year! Solution Sensors, Inc Introduces technology for the of the first-ever portable gunpowder detector that can detect gunpowder across barriers and from a considerable distance. Thanks to its easy portability, the revolutionary sensor can be used virtually anywhere. Their patented technology was first used by members of the Solution Sensors Inc. team to search for survivors of catastrophic events such as mine collapses. Some of their team was even searching for survivors at the World Trade Center after the 9/11 attacks. Although the team advanced the technology for gunpowder detection and other lifesaving uses, the original device; LifeGuard™ continues to be used to search for survivors of earthquakes and mine collapses, stowaways in shipping containers, etc. Over the past few years Solution Sensors, Inc. has been refining the technology and are now moving towards developing a personal detection device. Solution Sensors, Inc. had proven the technology works, demonstrated its capabilities with law enforcement, and received their input.  They have finalized the development plan that will get them to their next major milestone. Their next step is to accelerate the execution of their development plan. They will do this by expanding their technical team and working with their development partners to digitize and test the sensor. The detection device powered by their technology can accurately detect gunpowder that is found in all modern shotguns, handguns and rifles. Additionally, the detector can identify smokeless gunpowder bombs and loaded firearms among a huge crowd, inside cars in traffic stops or behind doors and walls. After completing initial version of the sensor, the Solution Sensors, Inc. team had multiple interviews with officials from law enforcement, security companies, and government departments, and all are hopeful and confident about the revolutionary gunpowder detector sensor.  You may check out the science here. Solution Sensors, Inc is set to launch a video talking about today's alarming Mass Shooting Statistics to raise awareness to the unprecedented number of mass shootings in the US alone. See the PSA independent of our dramatic informational video. *Mass Shooting Statistics according to Mass Shootings Tracker. Gun Violence incidents or deaths during the same three years published on Gun Violence Archive.


Research and Markets has announced the addition of the "Global Automotive Sensors Market Analysis & Trends - Industry Forecast to 2025" report to their offering. The Global Automotive Sensors Market is poised to grow at a CAGR of around 8.4% over the next decade to reach approximately $48.3 billion by 2025. This industry report analyzes the market estimates and forecasts for all the given segments on global as well as regional levels presented in the research scope. The study provides historical market data for 2013, 2014 revenue estimations are presented for 2015 and forecasts from 2016 till 2025. The study focuses on market trends, leading players, supply chain trends, technological innovations, key developments, and future strategies. With comprehensive market assessment across the major geographies such as North America, Europe, Asia Pacific, Middle East, Latin America and Rest of the world the report is a valuable asset for the existing players, new entrants and the future investors. Some of the trends that the market is experiencing include need for fuel efficient and reduction for carbon footprint, growing adoption of automotive cruise control systems, developing fully autonomous and semi autonomous automobiles and emerging technologies like combo sensors and wafer-level packaging technologies. Depending on application, market is divided into Chassis, Body Electronics, Exhaust, Powertrain, Safety and Control, Telematics, Vehicle Lighting Control and Ignition Control Applications and Other Applications. Based on sensor type the market is categorized into Inertial Sensors, Image Sensors, Nox Sensor, Oxygen Sensors, Pressure Sensors, Temperature Sensors, Position Sensors, Level Sensor, Torque Sensor and Other Sensors. Inertial Sensors segment is subdivided into Gyroscopes and Accelerometers. The Image Sensors segment is further broken down into Charge-Coupled Device (CCD) and Complementary Metal-Oxide Semiconductor (CMOS). Other Sensors segment is diverged into Particulate Matter Sensors, Proximity Sensors, Radar Sensors, Rain Sensors, Relative Humidity Sensors and Ultrasonic Sensors. Based on working principle market is segmented into Inductive, Magnetic, Capacitive, Piezoelectric and Optical. On the basis of technology, market is categorised into Microelectromechanical Systems (MEMS), Non-Electro Mechanical Systems (Non-MEMS), Nano-Electro-Mechanical Systems (NEMS) and Hall Effect Technology. The Microelectromechanical Systems (MEMS) technology is subdivided into Fuel Injector Pressure Sensor, Airbag Sensor, Roll over Detection Sensor, Vehicle Dynamic Control (VDC) sensor and Throttle position sensor. Non-Electro-Mechanical Systems (Non-MEMS) segment is also broken further into Magnetic Sensor, Battery sensor and Optical Sensor. By vehicle type the market is bifurcated into Cars, Buses, Two-wheelers and Trucks. The cars segment is further divided into Coupes, Hatchback Cars, Sedan Cars, SUV and Wagons. Trucks segment is sub divided into Light-duty truck, Light light-duty truck, Heavy-duty vehicle and Heavy light-duty truck. Report Highlights: - The report provides a detailed analysis on current and future market trends to identify the investment opportunities - Market forecasts till 2025, using estimated market values as the base numbers - Key market trends across the business segments, Regions and Countries - Key developments and strategies observed in the market - Market Dynamics such as Drivers, Restraints, Opportunities and other trends - In-depth company profiles of key players and upcoming prominent players - Growth prospects among the emerging nations through 2025 - Market opportunities and recommendations for new investments Key Topics Covered: 1 Market Outline 2 Executive Summary 3 Market Overview 3.1 Current Trends 3.1.1 Need for fuel efficient and reduction for carbon footprint 3.1.2 Growing adoption of automotive cruise control systems 3.1.3 Developing fully autonomous and semi autonomous automobiles 3.1.4 Emerging technologies like combo sensors and wafer-level packaging technologies 3.2 Drivers 3.3 Constraints 3.4 Industry Attractiveness 4 Automotive Sensors Market, By Application 4.1 Chassis 4.1.1 Chassis Market Forecast to 2025 (US$ MN) 4.2 Body Electronics 4.2.1 Body Electronics Market Forecast to 2025 (US$ MN) 4.3 Exhaust 4.3.1 Exhaust Market Forecast to 2025 (US$ MN) 4.4 Powertrain 4.4.1 Powertrain Market Forecast to 2025 (US$ MN) 4.5 Safety and Control 4.5.1 Safety and Control Market Forecast to 2025 (US$ MN) 4.6 Telematics 4.6.1 Telematics Market Forecast to 2025 (US$ MN) 4.7 Vehicle Lighting Control 4.7.1 Vehicle Lighting Control Market Forecast to 2025 (US$ MN) 4.8 Ignition Control Applications 4.8.1 Ignition Control Applications Market Forecast to 2025 (US$ MN) 4.9 Other Applications 4.9.1 Other Applications Market Forecast to 2025 (US$ MN) 5 Automotive Sensors Market, By Sensor Type 5.1 Inertial Sensors 5.1.1 Inertial Sensors Market Forecast to 2025 (US$ MN) 5.1.1.1 Gyroscopes 5.1.1.1.1 Gyroscopes Market Forecast to 2025 (US$ MN) 5.1.1.2 Accelerometers 5.1.1.2.1 Accelerometers Market Forecast to 2025 (US$ MN) 5.2 Image Sensors 5.2.1 Image Sensors Market Forecast to 2025 (US$ MN) 5.2.1.1 Charge-Coupled Device (CCD) 5.2.1.1.1 Charge-Coupled Device (CCD) Market Forecast to 2025 (US$ MN) 5.2.1.2 Complementary Metal-Oxide Semiconductor (CMOS) 5.2.1.2.1 Complementary Metal-Oxide Semiconductor (CMOS) Market Forecast to 2025 (US$ MN) 5.3 Nox Sensor 5.3.1 Nox Sensor Market Forecast to 2025 (US$ MN) 5.4 Oxygen Sensors 5.4.1 Oxygen Sensors Market Forecast to 2025 (US$ MN) 5.5 Pressure Sensors 5.5.1 Pressure Sensors Market Forecast to 2025 (US$ MN) 5.6 Temperature Sensors 5.6.1 Temperature Sensors Market Forecast to 2025 (US$ MN) 5.7 Position Sensors 5.7.1 Position Sensors Market Forecast to 2025 (US$ MN) 5.8 Level Sensor 5.8.1 Level Sensor Market Forecast to 2025 (US$ MN) 5.9 Torque Sensor 5.9.1 Torque Sensor Market Forecast to 2025 (US$ MN) 5.10 Other Sensors 5.10.1 Other Sensors Market Forecast to 2025 (US$ MN) 5.10.1.1 Particulate Matter Sensors 5.10.1.1.1 Particulate Matter Sensors Market Forecast to 2025 (US$ MN) 5.10.1.2 Proximity Sensors 5.10.1.2.1 Proximity Sensors Market Forecast to 2025 (US$ MN) 5.10.1.3 Radar Sensors 5.10.1.3.1 Radar Sensors Market Forecast to 2025 (US$ MN) 5.10.1.4 Rain Sensors 5.10.1.4.1 Rain Sensors Market Forecast to 2025 (US$ MN) 5.10.1.5 Relative Humidity Sensors 5.10.1.5.1 Relative Humidity Sensors Market Forecast to 2025 (US$ MN) 5.10.1.6 Ultrasonic Sensors 5.10.1.6.1 Ultrasonic Sensors Market Forecast to 2025 (US$ MN) 6 Automotive Sensors Market, By Working Principle 6.1 Inductive 6.1.1 Inductive Market Forecast to 2025 (US$ MN) 6.2 Magnetic 6.2.1 Magnetic Market Forecast to 2025 (US$ MN) 6.3 Capacitive 6.3.1 Capacitive Market Forecast to 2025 (US$ MN) 6.4 Piezoelectric 6.4.1 Piezoelectric Market Forecast to 2025 (US$ MN) 6.5 Optical 6.5.1 Optical Market Forecast to 2025 (US$ MN) 7 Automotive Sensors Market, By Technology 7.1 Microelectromechanical Systems (MEMS) 7.1.1 Microelectromechanical Systems (MEMS) Market Forecast to 2025 (US$ MN) 7.1.1.1 Fuel Injector Pressure Sensor 7.1.1.1.1 Fuel Injector Pressure Sensor Market Forecast to 2025 (US$ MN) 7.1.1.2 Airbag Sensor 7.1.1.2.1 Airbag Sensor Market Forecast to 2025 (US$ MN) 7.1.1.3 Roll Over Detection Sensor 7.1.1.3.1 Roll Over Detection Sensor Market Forecast to 2025 (US$ MN) 7.1.1.4 Vehicle Dynamic Control (VDC) sensor 7.1.1.4.1 Vehicle Dynamic Control (VDC) sensor Market Forecast to 2025 (US$ MN) 7.1.1.5 Throttle position sensor 7.1.1.5.1 Throttle position sensor Market Forecast to 2025 (US$ MN) 7.2 Non-Electro-Mechanical Systems (Non-MEMS) 7.2.1 Non-Electro-Mechanical Systems (Non-MEMS) Market Forecast to 2025 (US$ MN) 7.2.1.1 Magnetic Sensor 7.2.1.1.1 Magnetic Sensor Market Forecast to 2025 (US$ MN) 7.2.1.2 Battery sensor 7.2.1.2.1 Battery sensor Market Forecast to 2025 (US$ MN) 7.2.1.3 Optical Sensor 7.2.1.3.1 Optical Sensor Market Forecast to 2025 (US$ MN) 7.3 Nano-Electro-Mechanical Systems (NEMS) 7.3.1 Nano-Electro-Mechanical Systems (NEMS) Market Forecast to 2025 (US$ MN) 7.4 Hall Effect Technology 7.4.1 Hall Effect Technology Market Forecast to 2025 (US$ MN) 8 Automotive Sensors Market, By Vehicle Type 8.1 Cars 8.1.1 Cars Market Forecast to 2025 (US$ MN) 8.1.1.1 Coupes 8.1.1.1.1 Coupes Market Forecast to 2025 (US$ MN) 8.1.1.2 Hatchback Cars 8.1.1.2.1 Hatchback Cars Market Forecast to 2025 (US$ MN) 8.1.1.3 Sedan Cars 8.1.1.3.1 Sedan Cars Market Forecast to 2025 (US$ MN) 8.1.1.4 SUV 8.1.1.4.1 SUV Market Forecast to 2025 (US$ MN) 8.1.1.5 Wagons 8.1.1.5.1 Wagons Market Forecast to 2025 (US$ MN) 8.2 Buses 8.2.1 Buses Market Forecast to 2025 (US$ MN) 8.3 Two-wheelers 8.3.1 Two-wheelers Market Forecast to 2025 (US$ MN) 8.4 Trucks 8.4.1 Trucks Market Forecast to 2025 (US$ MN) 8.4.1.1 Light-duty truck 8.4.1.1.1 Trucks Market Forecast to 2025 (US$ MN) 8.4.1.2 Light light-duty truck 8.4.1.2.1 Trucks Market Forecast to 2025 (US$ MN) 8.4.1.3 Heavy-duty vehicle 8.4.1.3.1 Trucks Market Forecast to 2025 (US$ MN) 8.4.1.4 Heavy light-duty truck 8.4.1.4.1 Trucks Market Forecast to 2025 (US$ MN) 9 Automotive Sensors Market, By Geography 10 Key Player Activities 10.1 Acquisitions & Mergers 10.2 Agreements, Partnerships, Collaborations and Joint Ventures 10.3 Product Launch & Expansions 10.4 Other Activities 11 Leading Companies - Allegro Microsystems Inc - American Sensor Technologies Inc. - Analog Devices Inc. - Bosch Sensortec Gmbh - China Automotive Systems Inc. - Continental Ag - Corrsys-Datron Sensorsysteme Gmbh - Delphi Corp - Freescale Semiconductor Inc - Hitachi Automotive Systems - Jumo Gmbh & Co. Kg - Motion Sensors Inc - Novotechnik U.S. Inc - Nxp Semiconductors - Omron Corp - Raltron Electronics Corp - Sensonar Technologies As - The Shanghai Nicera Sensor Co. Ltd - Trw Automotive Holdings Corp - Visteon Corp - Hella Kgaa Hueck & Co - Xensor Corp - OSRAM Opto Semiconductors Gmbh - Hamamatsu Photonics KK - Melexis Microelectronic Integrated Systems For more information about this report visit http://www.researchandmarkets.com/research/pzbm2z/global_automotive Research and Markets Laura Wood, Senior Manager press@researchandmarkets.com For E.S.T Office Hours Call +1-917-300-0470 For U.S./CAN Toll Free Call +1-800-526-8630 For GMT Office Hours Call +353-1-416-8900 U.S. Fax: 646-607-1907 Fax (outside U.S.): +353-1-481-1716


Wireless sensors are self configuring and self powered sensors that are used for sensing environmental data and perform actuation functions efficiently and accurately. Wireless sensors deployed with intelligent sensor-interface monitors, informs, and offers granular control of agriculture and environment situations in real-time. The use wireless sensing technology (wireless sensors) help in monitoring environmental characteristics such as barometric pressure, atmospheric humidity, underground water level, wind direction, rainfall, and wind speed, allowing end-users located remotely to manage this information. Thus, wireless sensors are expected to be the major driving force behind the growth of environment and agriculture monitoring market. Wireless sensors when combined with big data processing and cloud computing offers opportunity to achieve easy-human-system interaction. High cost of the wireless technology and uncertainty over reliability of wireless systems are the biggest challenges faced by this market. In industrial street lighting applications, wireless sensors are coupled to the lighting points or lamp posts so as to control the lighting at these points and get information on its operations, diagnostics, and failures. The use of wireless sensors improves industrial street lighting service and reduces power consumption. Thus, wireless sensors are expected to be the major driving force behind the growth of intelligent lighting systems in the coming decade. The wireless sensor for environmental and agricultural monitoring market is segmented on the basis of type, and geography. The wireless sensor for environmental and agricultural monitoring market is segmented on the basis of its types into three major categories, namely- physical sensors (humidity sensors, temperature sensors, pressure sensors, acoustic sensors, and so on), mechanical sensors (proximity sensors, position sensors, motion sensors, and so on), and chemical sensors (gas sensors, bio-sensors, and so on) The wireless sensor for environmental and agricultural monitoring market is segmented on the basis of geography into North America, Asia Pacific, Europe, and Rest of World (ROW). Request for Sample Report and Table of content @ http://www.persistencemarketresearch.com/samples/5096 Some of the key players in the wireless sensor for environmental and agriculture monitoring market include American Sensor Technologies, Inc., (U.S.), Avir Sensors, (U.S.), YSI Incorporated, (U.S.), Coastal Environmental Systems, Inc., (U.S.), E.S.I. Environmental Sensors Inc., (Canada),  Measurement Specialties Inc., (U.S.), STMicroelectronics N.V., (Switzerland), MEMSIC Inc., (U.S.), Sutron Corporation, (U.S.), Meridian Environmental Technology, Inc., (U.S.),  and ASM Automation Sensornik Messtechnik GmbH, (Germany) among others.


News Article | November 15, 2016
Site: www.newsmaker.com.au

The report “Environmental Monitoring Market by Product (Monitors, Sensors, and Software), Application (Air, Gas, Water, Soil, and Noise Pollution) and by Region - Global Trends and Forecasts to 2020” analyzes and studies the major market drivers, restraints, opportunities, and challenges in North America, Europe, Asia-Pacific, and the Rest of the world (RoW). Browse 68 market data tables and 44 figures spread through 162 pages and in-depth TOC on “Environmental Monitoring Market by Product (Monitors, Sensors, and Software), Application (Air, Gas, Water, Soil, and Noise Pollution) and by Region - Global Trends and Forecasts to 2020" http://www.marketsandmarkets.com/Market-Reports/environmental-monitoring-market-216846315.html Early buyers will receive 10% customization on reports. The Global Environmental Monitoring Market is poised to grow at a CAGR of 7.5% during 2015-2020, and is expected to reach a value of $20.5 Billion b 2020. Based on the type of products, the global environmental monitoring market is classified into three major segments, namely, environmental monitors (fixed and portable), environmental sensors, and environmental software. Moreover, based on type of sampling method, the global environmental monitoring market is classified into four segments, namely, intermittent monitoring, continuous monitoring, passive monitoring, and active monitoring. The global environmental sensors market is further classified based on product type (analog and digital) and application (temperature sensing, moisture detection, biological detection, chemical detection, and noise measurement). Additionally, the global environmental monitoring market is segmented based on applications into air pollution, water pollution, soil pollution, and noise pollution monitoring applications. A number of factors such as growing global population, development of policies and initiatives aimed to reduce air, soil, and water pollution, increasing government funding towards pollution prevention and control, growing construction of environmental monitoring stations, growing initiative towards the development of environment-friendly industries, and reduction in export tariff on environmental monitoring technologies in emerging and developed markets are fuelling the growth of the global environmental monitoring market. On the other hand, high cost of environmental monitoring solutions, slow implementation of pollution control reforms, and high export barrier on environmental technologies in emerging markets are some of the key factors hampering the market growth. As of 2015, North America is expected to hold the largest share of the environmental monitoring market, followed by Europe. However, the Asia-Pacific market is expected to grow at highest CAGR during 2015 to 2020. A number of factors such as large-scale industrialization, development of new environmental policies, and growing need to comply with various environmental safety regulations across the region are stimulating the growth of the environmental monitoring market in the Asia-Pacific region. Agilent Technologies, Inc. (U.S.), TE Connectivity Ltd. (Switzerland), Danaher Corporation (U.S.), E.S.I. Environment Sensors Inc. (Canada), Honeywell International, Inc. (U.S.), Lockheed Martin Corporation (U.S.), Ball Aerospace and Technologies Corporation (U.S.), The Raytheon Company (U.S.), Siemens AG (Germany), and Thales Group (France) are the major players in the global environmental monitoring market.


Giannelli R.A.,U.S. Environmental Protection Agency | Fulper C.,U.S. Environmental Protection Agency | Hart C.,U.S. Environmental Protection Agency | Hawkins D.,U.S. Environmental Protection Agency | And 9 more authors.
SAE International Journal of Commercial Vehicles | Year: 2010

Because of U.S. EPA regulatory actions and the National Academies National Research Council suggestions for improvements in the U.S. EPA emissions inventory methods, the U.S. EPA' Office of Transportation and Air Quality (OTAQ) has made a concerted effort to develop instrumentation that can measure criteria pollutant emissions during the operation of on-road and off-road vehicles. These instruments are now being used in applications ranging from snowmobiles to on-road passenger cars to trans-Pacific container ships. For the betterment of emissions inventory estimation these on-vehicle instruments have recently been employed to measure time resolved (1hz) in-use gaseous emissions (CO 2, CO, THC, NO x) and particulate matter mass (with teflon membrane filter) emissions from 29 nonroad construction vehicles (model years ranging from 1993 to 2007) over a three year period in various counties in Iowa, Missouri, and Kansas. In coincidence with the pollutant measurements exhaust flow, engine speed, and in a few cases engine power from the vehicle engine control module have been measured. From these exhaust and engine operation measurements pollutant mass emission rates, mass concentrations, mass per fuel use, and mass per energy (work or brake specific) emissions have been determined. The brake specific emissions were estimated from the engine speed measurements and brake specific fuel consumption (bsfc) curves. There were about 35 tests completed on these 33 vehicles ranging in time from about 10 to 600 minutes with an average test time of about 220 minutes. © 2010 SAE International.


Patent
Sensors Incorporated | Date: 2013-01-28

A system, including: a sensor that monitors containers as the containers move along a production line; a rejection device; a controller communicatively connected to the sensor and the rejection device, wherein the controller is programmed to determine whether a container is associated with a match condition in response to a signal received from the sensor, the match condition reflecting that the container is associated with predetermined properties or characteristics, in response to a match condition, determine a pass result, and otherwise determine a fail result, determine a velocity of the production line, dynamically determine a correction amount for a reject position, track a position of the container on the production line, and in response to the fail result, outputs a signal to actuate the rejection device that removes the container from the production line based on the velocity of the production line, the dynamically determined correction amount, and the position of the container on the production line.


Patent
Sensors Incorporated | Date: 2011-11-14

Some embodiments for a fault detection apparatus may include one or more monitors to detect at least three operating states of a sensor, such as pass, fail, and inoperative so as to enable a manufacturing facility to differentiate between situations in which a container does not have the appropriate machine readable label and situations wherein the sensor is actually inoperative. The fail state may be indicative of an object on a conveyor system not matching a predetermined description, identity or characteristic. The pass state may be indicative of an object on a conveyor system matching the predetermined description, identity or characteristic. The inoperative state may be indicative of a sensor output associated with a malfunction in the sensor itself. The fault detection apparatus may also include a fail-to-safe controller configured to detect these operating states.


Patent
Sensors Incorporated | Date: 2015-08-14

A system, including: a sensor that monitors containers as the containers move along a production line; a rejection device; a controller communicatively connected to the sensor and the rejection device, wherein the controller is programmed to determine whether a container is associated with a match condition in response to a signal received from the sensor, the match condition reflecting that the container is associated with predetermined properties or characteristics, in response to a match condition, determine a pass result, and otherwise determine a fail result, determine a velocity of the production line, dynamically determine a correction amount for a reject position, track a position of the container on the production line, and in response to the fail result, outputs a signal to actuate the rejection device that removes the container from the production line based on the velocity of the production line, the dynamically determined correction amount, and the position of the container on the production line.


A calibration method for a flow measuring device used with a vehicle exhaust analysis system includes the flow measuring device being connected with the vehicle exhaust system wherein exhaust gases are directed through the flow measuring device. A portable flow calibration device is connected in a manner that exhaust gases of the vehicle exhaust system are directed through the portable flow calibration device. The vehicle is operated so that exhaust gas flows through the flow measuring device and the flow calibration device. The flow measuring device is calibrated with the portable flow calibration device. The flow measuring device includes a Pitot tube assembly in a flow tube wherein gas flowing through the flow tube passes the Pitot tube assembly. The Pitot tube assembly includes a sensing tube and at least one pressure sensing port connected with the sensing tube. The sensing tube includes a plurality of sensing openings that are positioned at different portions of gas flowing through the flow tube.


Trademark
Sensors Inc. | Date: 2011-01-11

Vehicle exhaust emission analyzers. Automobile emission testing services; automobile fuel economy testing services; automobile emission data review and analysis for others. Generation of reports for submission to regulatory authorities for others, namely, preparing environmental compliance reports for others.

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