In one embodiment, a gas sensor includes a sensing layer having a first region containing PdCuSi, and a second region which is provided outside the first region and contains PdCu.

The present invention comprises a novel foldable and intrinsically safe plate capacitive sensor to measure liquid depths, solids in liquid depths, and two different liquids depths. This invention is used in onsite wastewater management systems (OWTS) to monitor depths of solids, oil, and effluent in a wastewater tank. The plates are configured to allow for solids, liquids and gases to surround the plates. A number of plates are hung in series from near the OWTS tank lid to at least 18 inches below the output baffle to measure the different materials at different depths in the OWTS tank. The capacitive sensors are capable of use with various materials to measure solids, oil, and effluent depths in an OWTS tank.

Sensors are configured to capture measurement data representing dissolved oxygen (DO) measurements of an environment and capacitance measurements of a medium of the environment. A memory includes computer-executable instructions. One or more processors are communicatively coupled to the one or more sensors and configured to execute the computer-executable instructions to carry out operations comprising: generating, using first measurement data captured by the one or more sensors, a model based on a relationship between the first set of DO measurements and the first set of capacitance measurements; receiving, from the one or more sensors, second measurement data; predicting, using the model and based on the new capacitance measurement, an expected DO measurement; determining whether to use the expected DO measurement or the new DO measurement; and controlling, a valve to cause the determined oxygen input amount to flow into the environment based on the expected DO measurement.

According to a further embodiment, a fluid sensor includes a fluid sensor element with a substrate including a recess for receiving a fluid to be examined, wherein the substrate surrounding the recess is formed, at least in parts, as a substrate electrode, an isolation layer arrangement between a floating gate electrode of a transistor and the substrate electrode and a sensor layer in the recess and adjacent to the floating gate electrode, an additional electrode at an opening area of the recess, wherein the additional electrode is arranged electrically isolated from the sensor layer, the substrate electrode and the floating gate electrode and is connected or connectable to a control potential and a processor configured to provide the control potential at the additional electrode such that an electric field between the additional electrode and the sensor layer is at least reduced or compensated during operation of the fluid sensor.

Methods for determining an electrical conductivity of an operating liquid in an operating liquid container for a motor vehicle. The operating liquid container includes at least one capacitor which is fastened to a container wall of the operating liquid container and has a first electrode and a second electrode opposite said first electrode. A first method determines the electrical conductivity of the operating liquid by means of a frequency-dependent phase progression of the impedance of the at least one capacitor. Another method determines the electrical conductivity of the operating liquid by means of a frequency-dependent capacitance profile of the at least one capacitor. An operating liquid container which is designed for carrying out the methods.

A resin impregnation measurement system includes first electrodes, second electrodes, a measurement controller, and an impregnation ratio deriving unit. The first electrodes extend in parallel. The second electrodes are disposed so as to oppose to the first electrodes across a container and extend in a direction intersecting the first electrodes. The container is configured to be filled with a resin. The measurement controller is configured to sequentially switch between the first electrodes and the second electrodes and measure electrostatic capacities of measurement regions where the first electrodes are opposite to the second electrodes. The impregnation ratio deriving unit is configured to derive an impregnation ratio of the resin to the fiber base material in the container on a basis of a distribution of the electrostatic capacities of the measurement regions.

Described herein are dielectric fluid testers for determining dielectric breakdown of fluid samples, systems comprising such testers, and methods using thereof. A dielectric fluid tester comprises a container and two electrodes. The test heads of these electrodes protrude inside the container and face each other, forming a gap. In some examples, one or both electrodes are movable for adjusting the gap and/or the volume inside the container available for a fluid sample. For example, the container includes two internal seals, one of which has a fixed position and is slidably coupled to a respective electrode. The other seal is slidably coupled to the container and moves together with the corresponding electrode. The container comprises an access port, providing a fluid communication between the fluid sample and an external pressure-controlling source. In some examples, the access port is used to deliver and remove the fluid sample from the container.

A sensor having a sensor head including a unibody construction, a first electrode, and at least one second electrode is provided. The first electrode can include a first pair of sensing elements coupled to each over via at least one bridge element extending from a first sensing element to a second sensing element. The at least one second electrode can include a second pair of sensing elements interleaved with the first pair of sensing elements. The second pair of sensing elements can be coupled to each other via at least one second bridge element extending from a third sensing element to a fourth sensing element. A method of manufacturing the sensor is also provided.

An agricultural machine has a capacitive sensor that includes a transmitter assembly having a signal driver, at least one guard driver, and at least one sensing circuit configured to detect an output of the signal driver. At least one sensing electrode is powered by the signal driver. At least one guard electrode is powered by the guard driver. The guard electrode is oriented such that a first electric field emanating from the sensing electrode is shaped at least in part by a second electric field emanating from the guard electrode. A method includes broadcasting a first electric field from a sensing electrode into a volume containing crop material, broadcasting a second electric field from a guard electrode, measuring an attribute related to the first electric field, and correlating the measured attribute related to the first electric field to a property of the crop material in the volume.

A system and method for quantifying white blood cells in a blood sample is described. The system includes a sample medium for depositing the same blood. The sample medium is positioned between a first electrode and a second electrode. The system also includes an electrical analyser for supping pulsing sweeping voltage across the electrodes through the sample medium. The electrical analyser is also configured for measuring capacitance across the sample medium before and after adding a chemical analyte. The system also includes a general processor in electrical or wireless communication with the electrical analyser configured for quantifying the white blood cells in the blood sample based on the generated capacitance-voltage profile. The method is described to operate the system and to quantify the white blood cells in a blood sample.