Provided herein is a method to detect, characterize and classify a particle. A light source and an ultrasound transducer are controlled to irradiate the particle with light and an ultrasound pulse. A feature associated with the particle is determined by processing ultrasound data resulting from the particle being irradiated. The feature is compared to a reference to determine at least one property of the particle. According to some non-limiting implementations, the feature comprises a power spectrum of the particle. According to some non-limiting implementations, the ultrasound data is processed to determine characteristics in a range of about 100 MHz to about 1000 MHz of the power spectrum. According to some non-limiting implementations, the ultrasound pulse is in a range of about 100 MHz to about 1000 MHz. A computing device to detect, characterize and classify a particle is also provided.

A method includes receiving multiplexed sensor data from a sensor array. The multiplexed sensor data includes first data from a first sensor of the sensor array and second data from a second sensor of the sensory array. The first data includes first frequency information of a first cantilevered element, the first cantilevered element including a coating material having an affinity for a compound and no diffusion barrier. The second data includes second frequency information of a second cantilevered element, the second cantilevered element including the coating material and a diffusion barrier. The diffusion barrier inhibits mass transfer to the second cantilevered element. The method also includes conditionally generating, based on an analysis of the first data and the second data, an output. The output is conditioned on the first frequency information and the second frequency information indicating more than a threshold amount of the compound present at the sensor array.

In accordance with a method for characterization of particles in a fluid-filled hollow structure, an ultrasound signal with a frequency spectrum, which exhibits a local maximum at a variable measurement frequency, is emitted in the direction of a part area of the hollow structure and reflected components are detected. The measurement frequency is tuned in a predetermined measurement interval, and depending on the detected reflected components, a spectral response curve is acquired as a function of the measurement frequency. Depending on the response curve, at least one characteristic property for a part of the particles located in the part area of the hollow structure is determined. The characteristic property includes a measure for an adhesion of the particles of the part of the particles located in the part area of the hollow structure.

Solid contents verification systems and methods are provided. The system includes a contents sensor unit, a container-carrying unit and a control unit. The contents sensor unit has at least one contents sensor configured to send and receive sonic pulses to determine a state of contents in a container. The contents sensor unit is configured to send a signal communicating a state of the contents in a container. The container-carrying unit is configured to hold a container in substantial alignment with the contents sensors to expose the contents to the sonic pulses. The control unit is operatively connected to the contents sensor unit. The control unit is configured to receive the signal communicating the state of the contents and to compare the state of the contents with a desired state of the contents.

A method includes receiving multiplexed sensor data from a sensor array. The multiplexed sensor data includes first data from a first sensor of the sensor array and second data from a second sensor of the sensory array. The first data includes first frequency information of a first cantilevered element, the first cantilevered element including a coating material having an affinity for a compound and no diffusion barrier. The second data includes second frequency information of a second cantilevered element, the second cantilevered element including the coating material and a diffusion barrier. The diffusion barrier inhibits mass transfer to the second cantilevered element. The method also includes conditionally generating, based on an analysis of the first data and the second data, an output. The output is conditioned on the first frequency information and the second frequency information indicating more than a threshold amount of the compound present at the sensor array.

An apparatus includes a communication interface configured to receive sensor data from a sensor device. The sensor device includes a resonator including a material having an affinity for a compound, and the sensor data is indicative of a vibrational frequency of the resonator. The apparatus also includes a processor to analyze the sensor data and to generate an output based on the sensor data.

A turbidity measurement device for measuring turbidity of a fluid flowing in a flow tube. A first transducer transmits ultrasonic signals through the fluid in the turbidity measurement section so as to provide a first ultrasonic standing wave between the first and second section ends. A receiver transducer receives the ultrasonic scattered response from particles in the fluid flowing through the turbidity measurement section. A control circuit operates the transducers and generates a signal indicative of the turbidity of the fluid in response to signals received from the receiver transducer. Preferably, the device may comprise a second transducer for generating a second ultrasonic standing wave with the same frequency, and further the two transducers may be used to generate a measure of flow rate by means of known ultrasonic techniques. This flow rate may be used in the calculation of a measure of turbidity. Both turbidity facilities and flow rate facilities may be integrated in a consumption meter, such as a heat meter or a water meter.

A sensor system is provided for measuring particle concentration and mass concentration in an aerosol. An optical sensor (33) is used for measuring a particle concentration and a mechanical sensor (32) is used for measuring a mass of collected particles. A particle concentration in the aerosol is monitored using the optical sensor (33), until detection of a particle generating event. Upon detection of a particle generating event, a mass measurement using the mechanical sensor (32) is performed and the mass measurement is used to calibrate the optical sensor (33). This approach enables the lifetime of the mechanical sensor to be extended, because it is only used when events are detected. The optical sensor, which typically is less accurate for mass sensing, is calibrated by the mechanical sensor.

An apparatus for analysing the particulate matter content of an aerosol includes an aerosol chamber configured to receive an aerosol, the particulate matter content of which should be analysed, at least one ultrasonic generator configured to produce ultrasonic waves in the aerosol received in the aerosol chamber, an ultrasonic detector configured to detect ultrasonic waves produced by the at least one ultrasonic generator in the aerosol, and an evaluator having a data exchange communication link with the ultrasonic detector and configured to ascertain the matter content on the basis of signals output by the ultrasonic detector. The ultrasonic generator and the ultrasonic detector are positioned relative to one another such that a path length to be traversed by ultrasonic waves between the ultrasonic generator and the ultrasonic detector is less than 1 cm.

An apparatus and method is disclosed to monitor the condition of a fluid flow including particulate matter and air or gas content fluid in the fluid flow as well as fluid quality. The apparatus includes a sensor array with an ultrasonic transducer, inductive sensor and fluid quality sensor. It also includes a cyclonic separator. The method includes sensing and sizing particulate matter, distinguishing air bubbles from the particle matter and assessing the quality of the fluid.