A method and corresponding device are provided for determining a flow speed in a fluid conduit. The fluid conduit is provided with first, second and third ultrasonic transducers, wherein respective connection lines between transducers extend outside of a symmetry axis of the fluid conduit. First and second measuring signals are applied to the first ultrasonic transducer and received at the second and the third ultrasonic transducer, respectively. The measuring signals comprise a respective reversed signal portion with respect to time of a response signal. Respective first and second response signals are measured and the flow speed is derived from at least one of the first and second response signals.

A method of measuring the speed of a fluid comprising the following steps: generating a plurality of pseudorandom frequencies (fus_n); for each pseudorandom frequency (fus_n), emitting ultrasound signals into the fluid to travel along a path of defined length; receiving the ultrasound signals; for each received ultrasound signal, producing a travel time measurement, so as to generate for each pseudorandom frequency (fus_n) a predefined number of travel time measurements; for each pseudorandom frequency (fus_n), evaluating the accuracy of the measurements; for evaluating the speed of the fluid, making use of the measurements produced for the pseudorandom frequency that presents the greatest accuracy.

A method for measuring a speed of a fluid, comprising measurement phases and detection phases each carried out between two measurement phases, each detection phase comprising the steps of; measuring a spurious ultrasonic signal level; comparing the spurious ultrasonic signal level with a detection threshold capable of assuming a plurality of predefined values; if the measured spurious ultrasonic signal level is less than the detection threshold, reducing the detection threshold, and repeating the measurement step and the comparison step; when the measured spurious ultrasonic signal level becomes greater than or equal to the detection threshold, detecting a disturbance and, depending on the value of the detection threshold, determining if the disturbance originates from an anomaly or from attempted fraudulent activity.

A measuring device, in particular a flow meter, has a measurement tube for receiving or conveying a fluid, first and second oscillation transducers on a side wall of the measurement tube, and a control device. An operating method has the control device drive the first oscillation transducer chronologically in succession for respective mode-selective excitation of a first and a second oscillation mode of a wave conducted in the side wall of the measurement tube. The second oscillation transducer is driven similarly for a second measurement direction. The excited waves are conducted directly in the side wall or indirectly through the fluid and recorded in the other oscillation transducer, resulting in measurement data for each measurement direction and oscillation mode. Result information relates to a property of the fluid or a state of the measuring device determined from the measurement data for both measurement directions and both respective oscillation modes.

A method for determining a flow speed of a liquid in a fluid conduit is provided. During a signal-generating phase, an impulse signal is applied to a first ultrasonic transducer. A response signal is then received at a second ultrasonic transducer. A measuring signal is later derived from the response signal, wherein the derivation comprises reversing a signal portion with respect to time. During a measurement phase, a liquid moves with respect to the fluid conduit. The measuring signal is then applied to one of the two transducers and a response signal of the measuring signal is measured at the other transducer. A flow speed is derived from the response signal of the measuring signal.

A method for measuring a speed of a fluid, comprising the steps of: transmitting an ultrasonic measurement signal (Se); acquiring and digitising a measurement portion (25, 26) of an ultrasonic measurement signal received (Sr, Sr1, Sr2) after the ultrasonic measurement signal (Se) has travelled a path of defined length (L) to obtain measurement samples; estimate, from the measurement samples, an amplitude of the measurement portion; access reference samples from a reference table pre-filled and stored in a memory, the reference samples forming a reference curve which is an interpolation of the measurement samples; produce adjusted measurement samples by multiplying the measurement samples by ratio between an amplitude of the reference curve and the amplitude of the measurement portion; for each adjusted measurement sample, determine a unit time delay between the adjusted measurement sample and the reference curve; for each adjusted measurement sample, estimate a zero-crossing time of the measurement portion from the unit time delay and from the reference samples, estimate, from an average of the zero-crossing times, the time it takes the ultrasonic measurement signal to travel the path of defined length; estimate the speed of the fluid from the travel time measurement.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for determining atmospheric conditions. In one aspect, a method includes receiving data relating to atmospheric conditions collected at a particular altitude located within the stratosphere, providing the data to a machine-learned model that has been trained using a training data set collected in a controlled environment, determining, by the machine-learned model, atmospheric conditions data for the particular altitude based on the data collected for the particular altitude and storing the atmospheric conditions data for the particular altitude.

An ultrasonic anemometer (7) as well as a method for determination of at least one component of a wind velocity vector and/or a velocity of sound includes at least one sound transducer at least temporarily working as a transmitter (1, 2, 3, 4, 5, 6, 15, 16) with a sound emission surface for emitting sound waves and at least one sound transducer at least temporarily working as a receiver (1, 2, 3, 4, 5, 6, 15, 16) with a sound detection surface for at least partially receiving the emitted sound waves. An evaluation unit, determines at least one component of a wind velocity vector and/or the velocity of sound, based on a recorded transit time, which the sound waves require on a measuring section located between the sound emission surface of the at least one transmittor and the sound detection surface of the at least one receiver to cover the distance of this measuring section. At least one measuring section is provided between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver arranged approximately vertical to the earth's surface and the first sound emission surface and/or the first sound detection surface is inclined compared to the horizontal.

An aircraft freestream data system can include a first ultrasonic air data system (UADS) configured to sense local acoustic properties at a first location on an aircraft, a first local air data module operatively connected to the first UADS and configured to determine first local air data of the first location and to output first local air data, and a freestream data module operatively connected to the first local air data module. The freestream data module can be configured to receive the first local air data from the local air data module, determine one or more freestream air data parameters based on at least the first local air data, and output the one or more freestream air data parameters to one or more aircraft consuming systems.

A method of measuring temperature and velocity of a fluid flow passing through a device of a plant includes the step of positioning at least two sensors in the device. For each sensor, a traveling path for an acoustic signal received from another sensor is determined. Each sensor emits an acoustic signal at a frequency that differs from a frequency of an acoustic signal to be emitted by the other sensor(s) in the fluid flow. A velocity profile and temperature profile for the fluid flow based on the acoustic signals received by the sensors is determined. A measurement system can include sensors and a computer device that can determine a velocity profile and temperature profile for a fluid flow passing through a device based on the acoustic signals received by the sensors. A plant can be configured to implement the method or include an embodiment of the measurement system.