A pressure measuring sensor having a ceramic pressure sensor includes a temperature transducer to provide a thermovoltage dependent on a temperature gradient. The temperature transducer includes two series-connected thermoelements, each of which has a galvanic contact between a wire of the thermoelement and a connecting conductor connecting the galvanic contacts of the two thermoelements to one another. The temperature transducer enables the compensation for a measuring error caused by a temperature gradient occurring along the pressure measuring sensor.

The invention relates to a pressure sensor and related method for the compensation of a pressure, wherein the pressure sensor has a pressure measuring cell, with a housing and an electronic sensor system and an electronic evaluation system disposed within the housing, as well as at least one first temperature sensor for measuring a first temperature and a second temperature sensor for measuring a second temperature, wherein the pressure sensor has a compensation unit connected to the at least two temperature sensors, and wherein the compensation unit determines a compensation for the pressure taking into account at least the first temperature and the second temperature.

A pressure sensor includes a first pressure sensing portion and a second pressure sensing portion, each including a first rigid electrode, a second rigid electrode, and a deflectable membrane structure, wherein the second rigid electrode is between the first rigid electrode and the deflectable membrane structure, and wherein the first rigid electrode, the second rigid electrode and the deflectable membrane structure are in a vertical configuration, and wherein the first and second rigid electrode of the first pressure sensing portion form a reference capacitor, and wherein the second rigid electrode and the deflectable membrane structure of the first pressure sensing portion form a sensing capacitor, and wherein the first and second rigid electrode of the second pressure sensing portion form a reference capacitor, and wherein the second rigid electrode and the deflectable membrane structure of the second pressure sensing portion form a sensing capacitor.

A polymeric fluid sensor includes an inlet configured to receive fluid and an outlet. A polymeric tube is fluidically interposed between the inlet and the outlet and has a first sensing location with a first sidewall thickness and a second sensing location, spaced from the first sensing location, with a second sidewall thickness. A sleeve is disposed about the polymeric tube. The first sidewall thickness is less than the second sidewall thickness and a first sensing element is disposed at the first location and a second sensing element is disposed at the second location. In another example, the first and second sidewall thicknesses are the same and a fluid restriction is disposed within the polymeric tube between the first and second sensing locations.

A capacitance diaphragm gauge (CDG) assembly includes a CDG sensor positioned within a vacuum enclosure, which is maintained at a vacuum. The CDG sensor generates sensor signals responsive to a pressure of an applied gas. The vacuum enclosure provides thermal insulation around the CDG sensor. The CDG sensor is maintained at a selected operating temperature using an internal heater positioned on the CDG sensor. The internal heater is responsive to external heater control signals. The temperature of the CDG sensor is monitored using an internal temperature sensor mounted on the CDG sensor. The temperature sensor generates a temperature signal. The vacuum enclosure includes an end cap that seals the vacuum enclosure. Connectors positioned through the end cap communicate the sensor signals, the heater control signals and the temperature signals through the end cap. The connectors are hermetically sealed to the end cap to maintain the vacuum within the vacuum enclosure.

The present invention makes it possible to, even when a stainless steel is adopted in a diaphragm: prevent the diaphragm and a strain sensor from exfoliating from each other; be hardly susceptible to the influence of temperature in an operating environment; not allow the sensitivity of a pressure sensor to be dominated only by the mechanical characteristic of a material constituting the diaphragm; and increase the degree of freedom in design of members constituting the pressure sensor. A pressure sensor according to the present invention is, in order to solve the above problems, characterized in that: the pressure sensor has a diaphragm deforming by the pressure of a fluid, an elastic body covering the whole surface of the diaphragm and joining to the diaphragm on one side, and a strain sensor being arranged by joining on the other side of the elastic body and on an end side apart from a position corresponding to the center of the diaphragm and detecting the deformation of the elastic body working together with the deformation of the diaphragm as a strain; and the elastic body is formed of a material having a linear expansion coefficient close to the linear expansion coefficient of a material constituting the strain sensor.

Arrangement with capacitive pressure-measuring cell has a diaphragm for measuring vacuum pressure and a printed circuit board acting as a temperature sensor and another electronic component designed as a microchip that contains a digital signal processor with a temperature-to-digital converter and a capacitance-to-digital converter using a time measuring method. The converters determine temperature and capacitance of the cell in comparison to a reference resistor for temperature arranged on the printed circuit board and reference capacitor for capacitance for the pressure to be measured dependent on deformation of the diaphragm. A temperature-corrected pressure signal derived from the two measured signals uses correlation, the measured signals having been determined in advance from a calibration process, and the temperature-corrected pressure signal is provided as a pressure signal at the signal output for further processing. In this manner there is quick pressure measurement with high measuring accuracy.

Certain implementations of the disclosed technology may include systems, methods, and apparatus for a sealed transducer with an adjustment port. The sealed transducer may include one or more terminals. A first terminal may include electrical connections for connecting to an input voltage source, a ground, and for providing a transducer output signal. A second terminal, for example, may include an electrical port for connecting to an external and separately sealed adjustment network. In one example implementation, the adjustment network can include one or more components configured to couple with internal circuitry of the transducer to alter a response of the transducer.

In an embodiment a system includes a sensor including a base having a base electrode and a first membrane suspended above the base, wherein the first membrane has a first membrane electrode, wherein the first membrane is configured to deflect with respect to the base electrode in response to an environmental condition, and wherein the sensor is configured to measure a capacitance between the base electrode and the first membrane electrode. The system further includes a first device of the system configured to generate electrical interference signals, a first electrically conductive shield layer positioned between the sensor and the first device of the system, wherein the first electrically conductive shield layer defines a plurality of first apertures extending through the first electrically conductive shield layer and a dielectric material disposed in the plurality of first apertures.

A capacitive pressure transducer includes a shielded spacer positioned between the capacitor electrodes and driven with a separate voltage source.