A method for analyzing particles in an air stream includes concentrating the particles in an interior region of the air stream and deflecting the concentrated particles in the air stream with a generated thermal gradient. Smaller particles in the air stream may be selectively deflected away from the interior region and towards a periphery of the air stream at a different rate than larger particles in the air stream. The generated thermal gradient may be controlled to deflect particles in a selected particle size range onto a surface of a particle detector. An effective mass of the collected particles and an aerosol mass concentration estimate of the particles within the selected particle size range may be generated. Systems for analyzing particles are also disclosed.

A device and a method for detecting fluid particle characteristics. The device comprises a fluid composition sensor configured to receive a volume of fluid and a controller. The fluid composition sensor comprises a collection media configured to receive one or more particles of a plurality of particles within the fluid; and an imaging device configured to capture an image of one or more particles of the plurality of particles received by the collection media. The controller is configured to determine a particle impaction depth of each of the one or more particles of the plurality of particles within the collection media; and, based at least in part on the particle impaction depth of each of the one or more particles of the plurality of particles, determine a particulate matter mass concentration within the volume of fluid.

A sensor device is provided for detecting an incidence and/or a concentration and/or an amount of an analyte in a sample. The sensor device includes a sensor, connection electronics and a housing. The sensor converts chemical and/or biochemical information of an analyte in a sample into an electrical signal. The sensor includes a test cantilever that has a base and a deformable part, where a receptor layer for selective reception of the analyte is applied at least to the deformable part. The sensor also includes a reference cantilever that has a base and a deformable part, where a reference layer for selective non-reception of the analyte is applied to the deformable part.

Various embodiments described herein relate to apparatuses and methods for detecting fluid particles and their characteristics. In various embodiments, a device for detecting fluid particles and their characteristics may comprise a fluid composition sensor configured to receive a volume of fluid. The fluid composition sensor has a collection media housing configured to receive a portion of a collection media, a pump for moving a volume of fluid over the collection media housing, an imaging device configured to capture an image of particles on the collection media, and a particle matter mass concentration calculation circuitry configured to calculate a total particle matter mass. The particle matter mass concentration calculation circuitry is connected with the imaging device and the pump. The particle matter mass concentration calculation circuitry is configured to adjust the volume of fluid over the collection media housing.

A method for using a biosensor to determine the concentration of a target analyte, that does not require a pre-test calibration step. Small variations between electrodes on different biosensors, even when the biosensors are designed to be identical and manufactured in as close a manner as possible, can lead to significant variations in output when the electrochemical method is applied. Therefore, existing biosensors are calibrated before use, either during manufacturing or just prior to use. Prior calibration is not feasible for disposable applications, and increases the complexity of use if required to be performed by the end-user. A self-parative calibration method is described in which certain constants are determined during testing of the biosensor, then applied to all uses of the biosensor, so that an additional calibration step is not required.

A particulate matter sensor includes a sensing element with a first electrode and a second electrode, an inner shield with the sensing element disposed therein, and an outer shield with the inner shield disposed therein. The inner shield includes a first portion with an inner shield inlet and a second portion which is smaller in diameter that the first portion such that the first and second electrodes are within the second portion. The outer shield includes an outer shield inlet which communicates exhaust gases to the inner shield inlet.

A system and methods of tracking and identifying airborne particles using sensing devices that may include a fan and a collection plate. The fan forces air through the sensing device and airborne particles onto the collection plate. An imaging device captures images of the particles on the collection plate for analysis and identification. An image processing device determines pre-identified particles in the images. The images of other particles are processed and identified by a neural network processing device. Recommendations based on particle counts are provided to a user device. The user device may automatically control one or more devices in response to the recommendations.

A method of manufacturing a particulate matter detection element for detecting particulate matter in a gas to be measured includes manufacturing flat-shaped conductor layers, flat-shaped insulating layers, a laminated structure in which the conductor layers and the insulating layers are alternately laminated, and a detecting unit having the conductor layers of different polarities as a pair of detection electrodes on a cross section of the laminated structure. The conductor layers each have a constant thickness, and include conductor layer planar portions having a stripped-pattern cross section, and tapered conductor layer end edge portions each having a triangular cross section, provided on both sides of the respective conductor layer planar portions.

A method for using a biosensor to determine the concentration of a target analyte, that does not require a pre-test calibration step. Small variations between electrodes on different biosensors, even when the biosensors are designed to be identical and manufactured in as close a manner as possible, can lead to significant variations in output when the electrochemical method is applied. Therefore, existing biosensors are calibrated before use, either during manufacturing or just prior to use. Prior calibration is not feasible for disposable applications, and increases the complexity of use if required to be performed by the end-user. A self-parative calibration method is described in which certain constants are determined during testing of the biosensor, then applied to all uses of the biosensor, so that an additional calibration step is not required.

A particulate matter (PM) sensor circuit arrangement includes a PM sensor. The sensor includes, integral therewith, a PM sensor resistor, a resistive temperature device (RTD) resistor, and a heater resistor. The PM sensor includes four terminal pins, of which a) a first terminal pin is connected to one terminal of the PM sensor resistor; a second terminal pin is connected to one terminal side of said RTD resistor; c) a third terminal pin being connected to one terminal of a heater resistor; and d) a fourth common terminal pin is connected to respective opposite terminals of the PM sensor resistor, RTD resistor, and heater resistor to the first, second, and third terminal pins. The fourth common terminal pin is operationally connected to a boost or voltage supply and the first pin is connected to a low side line.