An apparatus for calibrating a pressure sensing device having a pressure sensor and a temperature compensation device includes: a chamber for applying a variable temperature and a variable pressure to the pressure sensing device; a temperature regulation device for regulating the temperature in the chamber designed such that the temperature in the chamber respectively increases in a strictly monotonous manner or falls in a strictly monotonous manner during one or more time intervals; a pressure regulation device for regulating the pressure in the chamber designed such that the pressure in the chamber respectively monotonously increases or respectively monotonously falls in at least one of the time intervals during a plurality of sub-intervals of the one-time interval; a reference pressure sensor for sensing the pressure in the chamber during the time interval(s); and a data record generation device for generating corresponding data records.

A method for diagnosing a differential pressure line of a differential pressure measurement arrangement includes capturing a first set number of differential pressure values, which represent a difference between a first media pressure and a second media pressure within a process, and checking whether the differential pressure measurement arrangement and/or the process are in a state that allows a diagnosis of the differential pressure line. Where it is determined that the differential pressure measurement arrangement and/or the process are not in a state that allows a diagnosis of the differential pressure line, the differential pressure values are captured anew such that the previously captured differential pressure values are deleted or overwritten. Otherwise, a diagnostic function to determine whether a differential pressure line is blocked is carried out.

A curved recess in a stopper includes a groove-pattern region and a groove-free region. When a sensor diaphragm reaches a bottom of the curved recess in the stopper, a groove-free region is divided into a ring-shaped first region with which a sensor diaphragm is in close contact and a ring-shaped second region disposed between an inner wall surface of a ring-shaped wall and the ring-shaped first region. The first region serves as a sealing region and the second region serves as a confinement region so that a pressure transmitting medium that remains in a space adjacent to the inner wall surface of the ring-shaped wall is confined in the confinement region, and abnormal deformation of the sensor diaphragm is prevented.

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.

Determining when to calibrate a pressure sensor of a mobile device. Particular systems and methods determine values of a plurality of metrics, determine weights for the metric values, determine weighted metric values by applying the weights to the metric values, use the weighted metric values to determine if a pressure sensor of the mobile device should be calibrated using information associated with the first location, and calibrate the pressure sensor of the mobile device using the information associated with the first location if a determination is made that the pressure sensor of the mobile device should be calibrated using information associated with the first location.

A milling machine includes a cutting rotor, a foldable conveyor, a sensor, and a controller. The cutting rotor is configured to mill material beneath the milling machine. The foldable conveyor is configured to receive and dispose the milled material and includes a first section and a second section foldable with respect to the first section at a fold structure. The sensor is positioned on the milling machine and configured to sense a value indicative of a force acting on the second section. The controller is configured to determine an amount of the milled material within the second section of the foldable conveyor using the value indicative of the force.

A method determines a total velocity average cross-section parameter σ.sub.totν in a relationship of the form Γ.sub.loss(U)=n.sub.bσ.sub.totν.Math.ƒ(U, U.sub.d), where: Γ.sub.loss(U) is a rate of exponential loss of sensor atoms from a cold atom sensor trap of trap depth potential energy U in a vacuum environment due to collisions with residual particles in the vacuum environment; n.sub.b is a number density of residual particles in the vacuum environment; U.sub.d is a parameter given by $U_d=\sqrt{2k_{B}T/m_{\mathrm{bg}}}\frac{4\pi {\hslash }^2}{m_t.Math.{\sigma }_{\mathrm{tot}}v.Math.}$
which relates the masses of the sensor atoms m.sub.t and residual particles m.sub.bg to the total velocity average cross-section parameter

Systems, methods, and computer readable medium are provided for automatically resetting a zero-offset calibration coefficient for a pressure transducer. Ambient pressure measurements from a first pressure sensor and a second pressure sensor can be received by a computing device and compared. Based on determining a difference in the received ambient pressure measurements, an updated zero-offset calibration coefficient can be generated. The updated zero-offset calibration coefficient can be transmitted to the first pressure sensor, which once received, causes the first pressure sensor to update a previously determined zero-offset calibration coefficient with the updated zero-offset calibration coefficient.

Systems, methods, and computer readable medium are provided for automatically resetting a zero-offset calibration coefficient for a pressure transducer. Ambient pressure measurements from a first pressure sensor and a second pressure sensor can be received by a computing device and compared. Based on determining a difference in the received ambient pressure measurements, an updated zero-offset calibration coefficient can be generated. The updated zero-offset calibration coefficient can be transmitted to the first pressure sensor, which once received, causes the first pressure sensor to update a previously determined zero-offset calibration coefficient with the updated zero-offset calibration coefficient.

A pressure measuring device configured as a multi-function device operable as a differential pressure switch (DPS); a differential pressure transducer (DPT); a pressure switch (PS); a pressure transducer (PT) providing readings of high and low pressure zones; a data recording logger; and a backwashing controller. The pressure measuring device may use at least two piezoelectric sensors operable to measure pressure attributes. The associated electronic hardware, processing unit, cables and pressure tubing are retrofittable and packaged in a molded case, with no moving parts with the electronic hardware fully coated to make the device reliable and resistant to extreme environmental conditions. The device is configured for remote access, enabling remote device configuration, maintenance and servicing. The device is further operable to communicate with various external devices: a tablet, a smartphone and the like as a user interface and further provides wired interface with a programmable logic controller (PLC) via RS-485 interface.