An implant includes a processor, RF communication circuitry, optical communication circuitry, a power source and a memory, all of which being hermetically sealed within a housing having a transparent window. Sensor readings are transmitted by RF using the RF communication circuitry to a remote reader after receiving interrogation signals from the reader. During calibration of the sensor, corrective coefficients are calculated by comparing actual sensor pressure readings with known pressure readings. The corrective coefficients are transmitted to the memory of the control circuitry using optical communication wherein modulated light is transmitted through the transparent window of the housing to the photo-detector.

An implantable intravascular pressure sensor comprising a first transducer arranged to provide a pressure dependent signal in response to alternating electrical signals of a first frequency band, a second transducer arranged to provide a reference signal in response to alternating electrical signals of a second frequency band different from the first frequency band and an antenna coupling for sending and receiving said signals.

A sensor module includes a container. The container has a closed wall extending between a first end of the container and a second end of the container. An exterior of the closed wall at least partly defines a seal-receiving channel. The seal-receiving channel extends around a circumference of the closed wall. The sensor module also includes a pedestal positioned between the first end and the second end and at least partly defining a first compartment and a second compartment surrounded by the closed wall. The sensor module further includes a sensor die positioned within the first compartment and mounted on the pedestal.

Provided is a method, system, and sensor device for identifying and detecting presence of a leak in a fluid conduit. The sensor device freely flows with a fluid within the fluid conduit. The sensor device includes an outer capsule that is free flowing within the fluid and provides fluid-tight containment to an interior compartment, at least one acoustic sensor mounted within the interior compartment, wherein the at least one acoustic sensor senses acoustic properties of the fluid to detect the presence of the leak, and a conductor for activating the at least one acoustic sensor to sense the acoustic properties of the fluid and the fluid conduit, wherein the conductor passes from the interior compartment and through to the outer capsule.

A protective housing for protecting an electronic device includes a plurality of walls defining a casing, a plurality of partitions, and at least one flow groove. One of the walls of the housing, referred to as the main wall, has an opening covered with a membrane for exposing a part of a measuring device to atmospheric pressure. The plurality of partitions are arranged on the outer surface of the main wall and separated from each other by passages. The plurality of partitions are arranged around the opening to completely surround the opening and protect the membrane. The at least one flow groove is arranged next to the opening, in order to allow liquid that may accumulate around the opening and/or against the partitions to be discharged. The present disclosure also concerns a pressure sensor, in particular, for a tank of a motor vehicle, using such a protective housing.

A system and method are presented for detecting and measuring pressure within a region of a body lumen or vessel. The pressure sensing system includes a light source for transmitting light through a pathway containing polarization-maintaining fiber optic wires. A distal portion of the polarization-maintaining fiber optic wire, which is engaged to and extends along a guidewire, includes pressure sensing station(s) made up of fiber Bragg gratings (FBG). The light transmitted to and reflected from the FBGs on the two polarization modes of the polarization-maintaining fiber optic wire can be analyzed to provide one or more pressure values.

An insulating tile may be attached to an interior or exterior surface adjacent to a chilled compartment of an aircraft galley structure to increase the overall thermal resistance of the galley structure (as well as the capacity of the galley air/liquid chiller system). The insulating tile includes an outer barrier encapsulating a thermally resistant core material within a vacuum, both the outer barrier and the core material resistant to flame propagation and thus suitable for commercial aircraft use. The insulating tile may further include getters within the core material to maintain the vacuum (and thus the thermal resistance of the tile) by absorbing moisture. Scannable passive pressure and/or moisture sensors may be placed within the core material for reporting at a glance the state of the vacuum, so that a particular tile may be serviced or replaced if necessary.

A flexible, passive pressure sensor includes three LC tank circuits. The first LC tank circuit is a pressure sensing LC tank circuit, having a capacitance that varies in response to changes in environmental pressure. The second and third LC tank circuits are reference LC tank circuits, having capacitances that are relatively constant over changes in environmental pressure. A measurement tool measures the resonant frequencies of the three LC tank circuits and then computes a pressure measurement that accounts for changes in resonant frequencies in the LC tank circuits due to environmental effects and deforming.

A protective housing for protecting an electronic device includes a housing having walls. One of the walls of the housing, referred to as the main wall, has an opening for exposing a part of a measuring device to atmospheric pressure. The housing comprises, arranged on the outer surface of the main wall, a plurality of partitions separated from each other by passages and arranged around the opening to completely surround it and at least one flow groove arranged next to the opening, in order to allow liquid that may be likely to accumulate around the opening and/or against the partitions to be discharged. The present disclosure also concerns a pressure sensor, in particular, for a tank of a motor vehicle, using such a protective housing.

The device includes a distal connector portion with a connector for electrical connection to an external electrical circuit, a proximal measuring portion including a detector of the physical parameter configured to be in fluid contact, the detector has a general shape of a wafer delimiting a first electrical contact face and a second opposite measuring face, a member for electrically joining the detector and the connector. The detector is configured in the device such that both faces of the detector are immersed and in direct fluid contact.