The present disclosure provides a measuring device, a measurement system, and a measuring method for a dielectric constant of a liquid crystal. The measuring device includes: a first substrate and a second substrate opposite to each other; a conductive layer disposed on a side of the first substrate facing the second substrate, wherein the conductive layer is configured to receive a first voltage signal; a resonant structure layer disposed on a side of the second substrate facing the first substrate, the resonant structure layer being configured to receive a second voltage signal and configured to transmit the microwave signal; a frame disposed between the first substrate and the second substrate, the frame cooperating with the first substrate and the second substrate to form a cavity for accommodating the liquid crystal to be measured.

A system for monitoring dielectric constant of a substrate includes a resonator structure formed on a surface of the substrate. A distal end of a waveguide is coupled to the resonator structure and spaced apart from the resonator structure such that a gap is provided between the distal end of the waveguide and the resonator structure. An excitation energy is coupled to the resonator structure out of the waveguide, and a response energy from the resonator structure is coupled into the waveguide and is detected at a proximal end of the waveguide. A detector detects the response energy received at the proximal end of the waveguide and generates a signal indicative of the detected response energy. A processor is coupled to the detector for receiving the signal indicative of the detected response energy and processing the signal to determine dielectric constant of the substrate.

A method for determining optimum parameters with respect to transmission and/or reflection of a surface is provided. The method comprises the steps of applying the surface to a transformer material in order to form a sample arrangement, and obtaining at least one measurement parameter of electromagnetic relevance with respect to the surface of the sample arrangement with the aid of an electromagnetic excitation signal generated by a measurement equipment. In this context, the transformer material comprises at least two dimensions for varying a contribution of at least one sample parameter of electromagnetic relevance over the surface.

The plant water Anomalous Phase sensor can determine moisture levels in plant leaves, stems and wood. The sensors described include several embodiments of the sensor, all of which estimate moisture levels by determining changes in the phase spectrum of an anomalous-phase resonator. Two embodiments include a planar transmitting antenna array with two slightly detuned patch antennas and a detector. In a first embodiment, the detector is a dipole antenna centered and out of plane with the transmitting antenna array. In a second embodiment, the detector is a singular rectangular patch antenna coplanar with the transmitting antenna array. The third embodiment is similar to the second embodiment, but is formed on a flexible substrate, so that the sensor can be wrapped about a twig, branch or other plant structure, in a non-coplanar arrangement. To compensate for temperature affects, a reference sensor may be integrated with an active sensor.

A composition ratio estimation device estimates a composition ratio of a content having mixed substances with different boiling points in a tank. The content is retained as a liquid in the tank lower part. The substances are partially floatable as a gas or liquid in a space in the tank upper part. The device includes a reference object disposed in the space, a transmitting-receiving unit that transmits radar waves toward the reference object and the surface of the liquid and receives reflected radar waves, a temperature measuring unit that acquires a level at which a boiling point of a floating substance is reached, a dielectric constant calculating unit that stores in advance a physical distance between the unit and the object and calculates a dielectric constant of a space between the unit and the object, and a composition ratio derivation unit that derives a composition ratio of the liquid.

A method for determining optimum parameters with respect to transmission and/or reflection of a surface is provided. The method comprises the steps of applying the surface to a transformer material in order to form a sample arrangement, and obtaining at least one measurement parameter of electromagnetic relevance with respect to the surface of the sample arrangement with the aid of an electromagnetic excitation signal generated by a measurement equipment. In this context, the transformer material comprises at least two dimensions for varying a contribution of at least one sample parameter of electromagnetic relevance over the surface.

The present invention provides a system and method for multi-phase flow decomposition using electrical capacitance imaging techniques. The present invention provides a system and method to obtain permittivity distributions at a plurality of frequency markers using volume tomography image reconstruction to determine volume fraction of each phase and to produce images of the volume fraction for each phase.

The present invention provides a system and method for multi-phase flow decomposition using electrical capacitance imaging techniques. The present invention provides a system and method to obtain permittivity distributions at a plurality of frequency markers using volume tomography image reconstruction to determine volume fraction of each phase and to produce images of the volume fraction for each phase.

A calculation method includes acquiring N matrices corresponding to N sets, each of N matrices being a matrix of a circuit network including first and second terminals, each of N sets being a set of first voltage applied to first terminal and second voltage applied to second terminal, and extracting values of L parameters based on N matrices using a first model of an intrinsic circuit and a second model of a distributed constant circuit. First model is represented by a function of at least one of first voltage and second voltage, each of L/2 impedance elements includes first end connected to one of first to sixth terminals, and second end connected to terminal other than the one of first to sixth terminals, and second model is represented by values of L parameters including two real number parameters related to impedance of each of L/2 impedance elements.

Non-contact type measuring apparatus able to detect a difference in signal intensity by transmitting a radio frequency (RF) signal having a predetermined frequency through one of two coil antennas and receiving an induced RF current signal transmitted via a medium through the other coil antennas and detect conductivity and a variation in characteristic of a non-conductor by comparing the signal intensity with a signal intensity comparison table for each frequency, which is stored in a controller by measuring a signal intensity for each frequency in advance, on the basis of the signal intensity for each frequency. The non-contact type measuring apparatus can accurately measure not only various elements using a characteristic in which conductivity is varied according to total dissolved solid, temperature, and an amount of a conductive medium and permittivity change characteristic of a non-conductor, but also conductivity and variation in characteristic of the non-conductor.