Sensors these five technologies break through in 2017 accelerating the IoT process

In 2017, all kinds of sensors received new breakthroughs, including new biosensors for instant detection, smart phones with miniaturized molecular spectral sensors and the successful development of the world's first high-spectral mobile sensor in Finland. Sensor is the first step to realize automatic detection and automatic control, breakthrough Finland successfully developed the world's first high-spectral mobile sensor the Finnish VTT National Technology Research Center successfully developed the world's first hyperspectral mobile device by converting the iphone camera into a new optical sensor This will bring new perspectives to consumer applications for low-cost hyperspectral imaging, such as consumers who will be able to use mobile phones for food quality testing or health monitoring.

650) this.width=650; "Src=" https://s1.51cto.com/wyfs02/M00/A5/4F/wKioL1m7QPrRxG2PAAHNA2MLlDs711.jpg-wh_500x0-wm_ 3-wmp_4-s_1400027345.jpg "title=" timg. jpg "alt=" wkiol1m7qprrxg2paahna2mllds711.jpg-wh_50 "/>

Spectral imaging is widely used in all kinds of object sensing and material attribute analysis. Hyperspectral imaging enables a wide range of measurements by spectral analysis of each pixel in the image. Hyperspectral cameras have been used for medical, industrial, spatial and environmental sensing in harsh environmental conditions, but at an expensive price.

VTT developed a high-spectral mobile device that integrates smart sensors with the Internet by integrating an adjustable micro MEMS filter with the iphone's camera lens and synchronizing its adjustment function with the camera's image capture system. This makes it possible to develop new mobile applications using cost-effective optical MEMS spectroscopy, such as the use of vehicles and drones for consumer applications such as environmental observation, health monitoring and food analysis.

Breakthrough two The world's first compact molecular spectrum sensor smartphone released recently, Changhong released the world's first molecular recognition cell phone-Changhong H2, which is the first smart phone with a miniaturized molecular spectrum sensor, can realize fruit and vegetable sugar, moisture, drug authenticity, skin age, wine quality and other testing, Become a personalised health management integration terminal with carry-on.

It is understood that Changhong will be laboratory-grade spectrometer capabilities and precision integrated into the daily use of the mobile phone for people to effectively improve the quality of daily life of users. For example, in the detection of food safety is also a great help, H2 mobile phone to the small high-resolution infrared spectral sensor installed issued instructions to the object under test "near infrared absorption spectrum" , and the spectral data transfer to the cloud Platform for analysis, calculation, processing, to obtain qualitative, quantitative analysis results, Mobile phone will be data and graphical results presented to the user, and to the user to give recommendations and recommendations, H2 mobile phone can directly identify the molecular properties of the substance.

650) this.width=650; "Src=" https://s3.51cto.com/wyfs02/M01/A5/4F/wKioL1m7QQuw0awlAABELPw4dSI704.jpg-wh_500x0-wm_ 3-wmp_4-s_2219420918.jpg "title=" timg (+). jpg "alt=" wkiol1m7qquw0awlaabelpw4dsi704.jpg-wh_50 "/>

This will be able to identify the safety of food, play a role in ensuring safety. Breakthrough three NM sensor atom-level drug input cells hit the development of nano-robots to the atomic level of drug input cells. The operation of the nano-sensors has aroused people's attention, can be done at very small scale, the traditional robot cannot achieve a variety of observation, characterization and control operations, called "meticulous."

By using nanotechnology, atomic-level drug input cells can be used to observe the effects of these drugs on the cells. The Nano-operating robot features a position detection sensor for automatic programmable motion and a wide range of powerful additional modules. Compared with the traditional robot, the nano-operation robot has the characteristics of super-sensitivity, ultra-high precision and so on, it can accomplish all kinds of observation, characterization and operation which the traditional robot can't achieve at very small scale.

Breakthrough four new optical biosensors to identify infectious diseases in seconds recently, Russian scientists have developed a new laser technology for the manufacture of novel optical biosensors that can identify infectious diseases within seconds. The device uses infrared light to display harmful bacteria and viruses, which can be widely used in large transport hubs, such as airports, which require constant monitoring of a large number of passengers. This rapid analysis is likely to be widely used in large transport hubs, such as airports, where the need for continuous health monitoring of circulating passengers is needed.

650) this.width=650; "Src=" https://s4.51cto.com/wyfs02/M02/A5/4F/wKioL1m7QSCzirFQAACSf9h-EXA503.jpg-wh_500x0-wm_ 3-wmp_4-s_78345817.jpg "title=" timg (+). jpg "alt=" wkiol1m7qsczirfqaacsf9h-exa503.jpg-wh_50 "/>

For now, this is achieved by tracking the body temperature with a thermal imaging camera. A passenger with a fever may be a potential source of infection. In this case, a clear analysis is necessary to identify whether the person is actually sick, or what other reasons. Using existing methods to investigate biological materials, such as the polymerase chain reaction method, takes several days. By contrast, this new technology can provide immediate results for testing. Breakthrough five The world's first wafer-level sensor chip or a revolution in spectrometer applications January 17, 2017, leading high-performance sensor solutions and analog IC supplier AMS Semiconductor (AMSAG) announces the world's first cost-effective multichannel spectral on-chip sensor solution, A new generation of spectral analyzers for consumer and industrial applications opens the way.

The multi-spectral sensor adopts new manufacturing technology, so that the nanometer optical interference filter attaches to the CMOS silicon wafer very precisely. The interference filter technology used by the sensor is highly accurate and stable, and is not affected by the time and temperature of use, and is smaller and more cost-effective than the components that are now commonly used in various spectrum analyzers.

Sensors these five technologies break through in 2017 accelerating the IoT process