A system for passive microwave remote sensing using at least one microwave radiometer includes a fixed body portion, the fixed body portion being configured to attach to a mobile platform, and a mobile body portion, the mobile body portion being configured for rotatably coupling with the fixed body portion for rotation about a rotation axis. The mobile body portion is configured for supporting the at least one microwave radiometer therein such that the at least one microwave radiometer rotates about the rotation axis when the mobile body portion is rotated about the rotation axis such that a polarization axis of the at least one radiometer is aligned with an earth axis. The fixed body portion includes a motor mechanism for effecting rotation of the mobile body portion such that the at least one microwave radiometer provides a vertical scanning below and above the mobile platform.

Methods and systems for RF pulse monitoring and RF pulsing parameter optimization at a manufacturing system are provided. A radio frequency (RF) signal is pulsed within a processing chamber in accordance with a set of process parameters. Sensor data is received from one or more sensors that indicates a RF pulse waveform detected within the processing chamber. One or more RF signal characteristics are identified in the detected RF pulse waveform. Each identified RF signal characteristic corresponds to at least one RF signal pulse of the RF signal pulsing within the processing chamber. A determination is made, based on the identified one or more RF signal characteristics, whether the detected RF pulse waveform corresponds to the target RF pulse waveform. An indication of whether the detected RF pulse waveform corresponds to the target RF pulse waveform is provided to a client device.

Methods and systems for RF pulse monitoring and RF pulsing parameter optimization at a manufacturing system are provided. A radio frequency (RF) signal is pulsed within a processing chamber in accordance with a set of process parameters. Sensor data is received from one or more sensors that indicates a RF pulse waveform detected within the processing chamber. One or more RF signal characteristics are identified in the detected RF pulse waveform. Each identified RF signal characteristic corresponds to at least one RF signal pulse of the RF signal pulsing within the processing chamber. A determination is made, based on the identified one or more RF signal characteristics, whether the detected RF pulse waveform corresponds to the target RF pulse waveform. An indication of whether the detected RF pulse waveform corresponds to the target RF pulse waveform is provided to a client device.

An apparatus for measuring flowable substance which has at least three microwave sensor elements arranged at separate locations in a measurement chamber in contact with the flowable substance. The sensor elements operate as at least two transmitter-receiver pairs, which transmit and receive microwave radiation via at last two paths of different lengths, through layers of dirt on the sensor elements and the flowable substance for eliminating an effect of dirt layers on the sensor elements from the measurement result. A signal processing unit has a controller which is configured to control feed of at least one substance which has an effect on the measured value of the flowable substance to the chamber on the basis of the measured value of the desired property of the flowable substance.

An apparatus for measuring flowable substance which has at least three microwave sensor elements arranged at separate locations in a measurement chamber in contact with the flowable substance. The sensor elements operate as at least two transmitter-receiver pairs, which transmit and receive microwave radiation via at last two paths of different lengths, through layers of dirt on the sensor elements and the flowable substance for eliminating an effect of dirt layers on the sensor elements from the measurement result. A signal processing unit has a controller which is configured to control feed of at least one substance which has an effect on the measured value of the flowable substance to the chamber on the basis of the measured value of the desired property of the flowable substance.

The present invention relates to a detector device for detection of unauthorised objects or substances, comprising a support base (110) designed to receive at least one foot covered by its shoe, of an individual to be controlled, characterised in that it comprises in combination microwave sender/receiver means (140), measuring means (150) of the width of an element inserted in between the microwave sender/receiver means (140), analysis means of at least one parameter of the transmission time between the microwave sender/receiver means (140) and/or the amplitude of the signal transmitted between the microwave sender/receiver means (140), and standardisation means of the abovementioned analysis relative to a size unit of standard width obtained on the basis of the width-measuring means (150).

Nano-electromechanical systems (NEMS) devices that utilize thin electrically conductive membranes, which can be, for example, graphene membranes. The membrane-based NEMS devices can be used as sensors, electrical relays, adjustable angle mirror devices, variable impedance devices, and devices performing other functions.

A method for determining at least one characteristic variable of a particle size distribution in a moving flow of particles includes structuring at least one microwave resonator to determine at least two measured values for the moving flow of particles. At least one quantile of the particle size distribution is further determined from the at least two measured values. Moreover, a device for generating a moving flow of particles includes a measuring apparatus having at least one microwave resonator that determines at least two measured values for the flow of particles. The measuring apparatus evaluates at least one quantile of a particle size distribution from the at least two measured values of the microwave resonator.

Methods and apparatus for examining a material are provided. One example method generally includes disposing the material in a dielectric contrast analysis structure, wherein the dielectric contrast analysis structure comprises a bulk dielectric substance and a plurality of receptacles in the bulk dielectric substance, wherein the material is disposed in one or more of the plurality of receptacles; exposing the dielectric contrast analysis structure to incident electromagnetic radiation; detecting resultant radiation from the exposed dielectric contrast analysis structure; and analyzing the detected resultant radiation to estimate at least one of a phase fraction and a phase distribution in the material. One example system generally includes an electromagnetic radiation source; a dielectric contrast analysis structure comprising a bulk dielectric substance and a plurality of receptacles in the bulk dielectric substance for receiving the material; and an electromagnetic radiation detector, wherein the analysis structure is between the radiation source and the detector.

Methods and apparatus for examining a material are provided. One example method generally includes disposing the material in a dielectric contrast analysis structure, wherein the dielectric contrast analysis structure comprises a bulk dielectric substance and a plurality of receptacles in the bulk dielectric substance, wherein the material is disposed in one or more of the plurality of receptacles; exposing the dielectric contrast analysis structure to incident electromagnetic radiation; detecting resultant radiation from the exposed dielectric contrast analysis structure; and analyzing the detected resultant radiation to estimate at least one of a phase fraction and a phase distribution in the material. One example system generally includes an electromagnetic radiation source; a dielectric contrast analysis structure comprising a bulk dielectric substance and a plurality of receptacles in the bulk dielectric substance for receiving the material; and an electromagnetic radiation detector, wherein the analysis structure is between the radiation source and the detector.