Techniques to provide a unified system for fluid pressure and fluid flowrate measurement are described. Upstream and downstream transducers include piezo devices, and are in contact with a fluid flow, such as in a pipe within a metering device. In an example, a first signal is sent from the upstream transducer to a downstream transducer, and time-of-flight of the first signal is measured. A second signal is sent from the downstream transducer to the upstream transducer, and a time-of-flight of the second signal is measured. A flowrate of the fluid flowing within the passage is calculated, based on the times of flight of the first and second signals. An electrical signal is sent to the first transducer. Upon conclusion of the electrical signal, a pressure of the fluid flowing within the passage is calculated, based at least in part on time of decay of a second electrical signal generated by vibration of the first transducer.

The present invention relates to a device, containing a first sensor, designed and arranged for sensing a first measurement variable of a fluid, and a second sensor, designed and arranged for sensing a second measurement variable of the fluid, a first electrode assembly has a substrate and a first planar electrode overlying the substrate. A second electrode assembly has a second planar electrode. The first planar electrode and the second planar electrode are dielectrically spaced apart from each other. The first electrode assembly and the second electrode assembly form a first capacitor as the first sensor such that a first capacitance, formed by the first planar electrode and the second planar electrode, can be varied under the influence of a fluid and in accordance with a flow velocity of the fluid as the first measurement variable.

An apparatus comprises an electrically active layer having a first plurality of substantially parallel electrodes and a second plurality of substantially parallel electrodes, wherein the first plurality of electrodes are not parallel to the second plurality of electrodes, such that there exists a matrix of intersection points between the electrodes. A signal generator is configured to generate excitation signals and is connected to the first plurality of electrodes, and a signal detector is configured to detect output signals from the second plurality of electrodes, wherein an output signal from one of the second plurality of electrodes is indicative of the degree of capacitive coupling to one of the first plurality of electrodes on application of an excitation signal thereto. A flexible top layer is sealed to the electrically active layer to define at least one hermetic void between portions of the top layer and portions of the electrically active layer.

A pressure sensing unit is provided. The pressure sensing unit includes a membrane and a pressure sensing pad group. The membrane has a first surface and a second surface. The pressure sensing pad group includes a first pressure sensing pad, a second pressure sensing pad, and a ground pad that are spaced apart from one another. The ground pad and one among the first pressure sensing pad and the second pressure sensing pad are located at the first surface of the membrane, another one among the first pressure sensing pad and the second pressure sensing pad is located at the second surface of the membrane, and an orthographic projection of the ground pad projected onto a reference plane is located between orthographic projections of the first pressure sensing pad and the second pressure sensing pad that are projected onto the reference plane.

The invention relates to a method for monitoring the function of a capacitive pressure measuring cell (10) comprising a measuring capacitor (C.sub.M) and a reference capacitor (C.sub.R) as well as a temperature element, wherein in an evaluation unit the pressure measurement value p is obtained by forming the quotient Q from the capacitance values of the reference capacitor (C.sub.R) and the measuring capacitor (C.sub.M). The method is characterized by the following method steps: in a matching procedure the characteristic curve of the quotient Q and the capacitance values of the measuring capacitor (C.sub.M) are each stored in a lookup table versus the pressure and at different temperature scenarios; then the corresponding absolute value of the quotient Q and of the capacitance value of the measuring capacitor (C.sub.M) from the lookup table are continuously assigned respectively to the determined pressure measurement value p at the temperature detected at this moment by the temperature element; the behavior of the course of the two absolute values of the quotient Q as well as of the capacitance value of the measuring capacitor (C.sub.M) is compared with each other; in the case of a significant deviation from an expected behavior, the evaluation unit is temporarily switched into a safety mode and meanwhile the gradient of the temperature element is detected and evaluated; in the case of a significant increase of the gradient of the temperature element, a temperature compensation is initiated; or in the case of an unchanged gradient of the temperature element, an error signal is generated.

A pressure sensor system is provided. In another aspect, a wireless intraocular pressure sensor includes a deformable or stretchable inductor. A further aspect of an intraocular pressure sensing system includes a deformable inductor sized to contact an eye. Another aspect provides an organ pressure sensing system including a passive inductor with a wavy, serpentine or undulating shape.

Methods and devices are provided for processing image data on a sub-frame portion basis using layers of a convolutional neural network. The processing device comprises memory and a processor. The processor is configured to receive frames of image data comprising sub-frame portions, schedule a first sub-frame portion of a first frame to be processed by a first layer of the convolutional neural network when the first sub-frame portion is available for processing, process the first sub-frame portion by the first layer and continue the processing of the first sub-frame portion by the first layer when it is determined that there is sufficient image data available for the first layer to continue processing of the first sub-frame portion. Processing on a sub-frame portion basis continues for subsequent layers such that processing by a layer can begin as soon as sufficient data is available for the layer.

A pressure sensing device (1000) comprises first and second electrodes (10, 20) spaced from each other by a distance. At least one of the electrodes is formed of/comprises a unitary piece of non-metallic conductive material. The distance is changeable in response to a pressure/force applied to the first and/or second electrode. The device comprises a measurement module (500) connected to the first/second electrode at a plurality of sensing points (S1 . . . ). The measurement module is configured to measure a change in capacitance between the first and second electrodes, in response to a change in the distance when a pressure/force is applied to the first and/or second electrode, at each sensing point individually and/or at all sensing points simultaneously. The measurement module is configured to determine the location, area and amount of applied pressure on the first and/or second electrode from the individual measurements, and/or the amount of the applied pressure from the simultaneous measurement.

A space-saving pressure sensor for a metal or plastics processing tool is configured to perform date stamping during injection molding with the processing tool. The pressure sensor is configured to be inserted into a single drilled hole of the tool. A first cast-compatible mark and a second cast-compatible mark of the pressure sensor may be adjusted against one another in such a way that a variety of different date marks can be created, which may then be applied to different injection-molded products. The pressure sensor may be used within the framework of manufacturing an injection-molded product.

The invention relates to a sensor mat (4) for an area sensor system (1.2), particularly for monitoring a room (101) of a building (100), comprising a flexible base unit (10) that has a first carrier element (11) with a planar extension and a first main side (11.1) and a second main side (11.2), and at least one detection means (30) for detecting an event (3). In addition, the invention relates to an area sensor system (1.2) for detecting an event (3), and to a method (200) for producing a sensor mat (4).