An electromagnetic boat speedometer includes a boundary layer velocity compensating arrangement comprising a primary coil for producing a primary electromagnetic field within a relatively large first volume of water, a secondary coil for producing a secondary electromagnetic field within a relatively small portion of the first volume of water immediately adjacent the hull of the boat, and a set of first electrodes removably mounted in one or more openings in the hull of the boat, such that the tips of the first electrodes extending into the relatively small water portion. In one embodiment, the coils are simultaneously energized in opposition, so that the primary and secondary electromagnetic fields are in opposition. In a second embodiment, the coils are energized alternately, and the signals produced by the electrodes are modified to achieve the desired boundary layer compensation. A second set of second electrodes may be included in the second embodiment.

Systems and methods for enabling charged (ionized) air mass measurement for reliable air data computation onboard an aircraft. Ionic charge sensing may be used to derive air data having improved reliability. The systems and methods for ionic charge sensing employ an emitter electrode and two or more collector electrodes, which electrodes are disposed in proximity to the exterior skin of the aircraft and exposed to ambient air. The emitter electrode is positioned forward of the collector electrodes. The system further includes a solid-state ionic air data module that converts currents from the collector electrodes into air data parameter values. More specifically, the ionic air data module is configured to sense currents induced in the collector electrodes in response to corona discharge produced by the high-voltage emitter electrode.

Systems and methods for enabling charged (ionized) air mass measurement for reliable air data computation onboard an aircraft. Ionic charge sensing may be used to derive air data having improved reliability. The systems and methods for ionic charge sensing employ an emitter electrode and two or more collector electrodes, which electrodes are disposed in proximity to the exterior skin of the aircraft and exposed to ambient air. The emitter electrode is positioned forward of the collector electrodes. The system further includes a solid-state ionic air data module that converts currents from the collector electrodes into air data parameter values. More specifically, the ionic air data module is configured to sense currents induced in the collector electrodes in response to corona discharge produced by the high-voltage emitter electrode.

A measuring device with a measuring tube is disclosed. The measuring device includes a sensor unit for capturing a parameter of a medium, a control and evaluation unit, and a deflectable measuring sensor with a cavity and a base unit. The sensor unit is at least partially integrated in the wall of the measuring tube. The measuring sensor is connected to the base unit via a spring element. The base unit is arranged outside of the measuring tube. A side of the measuring sensor is in contact with the medium during operation. The cavity is arranged on the side of the measuring sensor facing the medium. The measuring sensor is integrated into the measuring tube wall in such a way that it can be deflected at least in the plane of the measuring tube wall. The sensor unit has a means for capturing the deflection of the measuring sensor.

Described is 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 with 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, and with an evaluation unit, which, 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 transmitter and the sound detection surface of the at least one receiver to cover the distance of this measuring section, determines at least one component of a wind velocity vector and/or the velocity of sound.

The technical solution described is characterized by at least one measuring section between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver being arranged approximately vertical to the earth's surface and the first sound emission surface and/or the first sound detection surface being inclined compared to the horizontal.

Described is 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 with 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, and with an evaluation unit, which, 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 transmitter and the sound detection surface of the at least one receiver to cover the distance of this measuring section, determines at least one component of a wind velocity vector and/or the velocity of sound.

The technical solution described is characterized by at least one measuring section between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver being arranged approximately vertical to the earth's surface and the first sound emission surface and/or the first sound detection surface being inclined compared to the horizontal.

A MEMS chip for wind speed measurements is provided. The chip integrates one or multiple embedded channels and a pressure sensor. The pressure sensor consists of a sensing membrane with a cavity beneath it. Each channel has one end connects to the cavity while the other end opens on the edge of the chip. To measure the wind speed, the membrane faces the wind and the air stagnates onto it while the channel connects the cavity to the static pressure. And the membrane deforms according to the wind pressure. The wind speed is then derived from the measured wind pressure.

A MEMS chip for wind speed measurements is provided. The chip integrates one or multiple embedded channels and a pressure sensor. The pressure sensor consists of a sensing membrane with a cavity beneath it. Each channel has one end connects to the cavity while the other end opens on the edge of the chip. To measure the wind speed, the membrane faces the wind and the air stagnates onto it while the channel connects the cavity to the static pressure. And the membrane deforms according to the wind pressure. The wind speed is then derived from the measured wind pressure.

The invention discloses a flexible conductive diaphragm comprising at least one conductive film, and the conductive film comprises a flexible support layer (1), a flexible sensitive layer (2) overlapped on the flexible support layer (1), a flexible conductive layer (3) overlapped on the flexible sensitive layer (2), and an electrode (4) electrically connected with the flexible conductive layer (3). The invention further discloses a method for preparing the flexible conductive diaphragm, and a flexible vibration sensor based on the flexible conductive diaphragm. With the combination of the techniques such as the flexible material, the nano-material and the arrayed micro-structure, the flexible vibration sensor of the present invention has the characteristics of high sensitivity, low preparation cost, light weight, small thickness, small size, and being foldable and flexible, and can be applied in wearable or adherable electronic devices.

The invention discloses a flexible conductive diaphragm comprising at least one conductive film, and the conductive film comprises a flexible support layer (1), a flexible sensitive layer (2) overlapped on the flexible support layer (1), a flexible conductive layer (3) overlapped on the flexible sensitive layer (2), and an electrode (4) electrically connected with the flexible conductive layer (3). The invention further discloses a method for preparing the flexible conductive diaphragm, and a flexible vibration sensor based on the flexible conductive diaphragm. With the combination of the techniques such as the flexible material, the nano-material and the arrayed micro-structure, the flexible vibration sensor of the present invention has the characteristics of high sensitivity, low preparation cost, light weight, small thickness, small size, and being foldable and flexible, and can be applied in wearable or adherable electronic devices.