Abstract: 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.

Abstract: Techniques for operating a static fluid meter are described herein. In an example, a sampling interval is identified. The sampling interval is a period of time within which an electromagnetic or acoustic device measures or samples a rate of the fluid flow. The sampling interval may be approximately 1 second long; however, the interval may be longer or shorter depending on the design requirements of a particular system. A random number is generated and/or received. A sampling time within the sampling interval may be determined based at least in part on the random number. By sampling at a different and randomly determined location within each of a series of sampling intervals a more accurate fluid measurement may be obtained.

Abstract: Techniques for operating a static fluid meter are described herein. In an example, a sampling interval is identified. The sampling interval is a period of time within which an electromagnetic or acoustic device measures or samples a rate of the fluid flow. The sampling interval may be approximately 1 second long; however, the interval may be longer or shorter depending on the design requirements of a particular system. A random number is generated and/or received. A sampling time within the sampling interval may be determined based at least in part on the random number. By sampling at a different and randomly determined location within each of a series of sampling intervals a more accurate fluid measurement may be obtained.

Abstract: A device for sensing the rotation of a member rotating about an axis XX? comprises m proximity sensors situated in a plane perpendicular to the axis XX? and in m radial directions, m being an integer greater than or equal to 2. A mark fastened to the rotary member and eccentric to the axis XX? modifies the amplitude response of the proximity sensors when the rotary member rotates. An excitation circuit excites the proximity sensors, each sensor supplying an excitation response when it is excited. The amplitude of the excitation response of each of the sensors is compared with a comparison threshold value during a time period referred to as an observation window to supply a logic level 1 or 0 according to whether the response amplitude is greater than or less than the comparison threshold value. The movement of the mark past one of the sensors is identified as a function of the value 0 or 1 of said logic level.

Abstract: A device for sensing the rotation of a member rotating about an axis XX? comprises m proximity sensors situated in a plane perpendicular to the axis XX? and in m radial directions, m being an integer greater than or equal to 2. A mark fastened to the rotary member and eccentric to the axis XX? modifies the amplitude response of the proximity sensors when the rotary member rotates. An excitation circuit excites the proximity sensors, each sensor supplying an excitation response when it is excited. The amplitude of the excitation response of each of the sensors is compared with a comparison threshold value during a time period referred to as an observation window to supply a logic level 1 or 0 according to whether the response amplitude is greater than or less than the comparison threshold value. The movement of the mark past one of the sensors is identified as a function of the value 0 or 1 of said logic level.

Abstract: A method for detecting malfunctions in a flowmeter includes the measuring of the receive signal VIN output by a transducer. A characteristic of the receive signal is compared to a predetermined reference characteristic VREF and the peak voltage VPK of the receive signal is stored. An alarm signal VAL is generated when a trigger characteristic VDEC of the receive signal is less than the predetermined reference characteristic. A threshold voltage VTH is defined, proportional to the peak amplitude VPK of the receive signal in such a manner that VTH=K×VPK where K is a factor depending on the transducer. The receive signal is compared with the threshold voltage and a conditioned output signal VOUT is generated in a first state when the receive signal is greater than the threshold voltage, and in a second state when the receive signal is less than the threshold voltage.