The invention relates to a marker device and a tracking system for tracking the marker device, wherein the marker device comprises a rotationally oscillatable magnetic object and wherein the rotational oscillation is excitable by an external magnetic field, i.e. a magnetic field which is generated by a magnetic field providing unit 20, 31 that is located outside of the marker device. The rotational oscillation of the magnetic object induces a current in coils, wherein based on these induced currents the position and optionally also the orientation of the marker device is determined. This wireless kind of tracking can be carried out with relatively small marker devices, which can be placed, for instance, in a guidewire, the marker devices can be read out over a relatively large distance and it is possible to use a single marker device for six degrees of freedom localization.

A MEMS multi-module assembly, manufacturing method, and electronics apparatus are disclosed herein. The MEMS multi-module assembly comprises: a first die having a first hole; and a second die stacked on the first die, having a second MEMS device, wherein the second MEMS device is connected outside via the first hole.

A microelectromechanical system (MEMS) ambient pressure and acoustic sensor including an enclosure having an enclosure wall that defines an interior chamber and an acoustic input opening to the interior chamber, a moving structure positioned within the interior chamber and being acoustically coupled to the acoustic input opening. The moving structure having an acoustic sensing portion that is movable in response to an acoustic pressure input and an ambient pressure sensing portion that is movable in response to an ambient pressure input. The sensor further including a circuit electrically coupled to the moving structure and that is operable to determine an acoustic output and an ambient pressure output based on a movement of the moving structure.

A measurement chamber that is essentially dome-shaped and has a base area with a membrane and has at least two connectionpoints fora fluid flow. The measurement chamber has two outer webs opposite each other, one of the webs engaging a clamping edge of a coupling element.

A pressure measurement device for determining a pressure of a fluid located inside a cylindrical casing includes: at least one sensor for determining a force acting thereon; and a clamp for peripheral attachment to the casing. The at least one sensor is arranged inside the clamp and is operatively connected thereto. The clamp includes a peripheral link chain having chain links that are pivotably coupled to one another at end joints, and a closure device that interacts with a first chain link and a final chain link.

A method of determining fluid pressure inside a conduit. The method includes positioning a conduit in a surgical system. The conduit having an external surface, and the surgical system having a pair of sensors. The conduit is positioned in the surgical system such that the external surface of the conduit applies a force on the pair of sensors when the conduit expands. The method includes a step of generating one or more electrical signals with the pair of sensors. The one or more electrical signals corresponding to the force on the pair of sensors. The method includes a step of determining the fluid pressure inside the conduit by converting the one or more electrical signals into a fluid pressure value through a controller.

A microfabricated pressure transducer is formed in a multilayer substrate by etching a plurality of shallow and deep wells into the layers, and then joining these wells with voids formed by anisotropic etching. The voids define a flexible membrane over the substrate which deforms when a force is applied.

A pressure sensing unit comprises a membrane and two permanent magnets inside the cavity. One magnet is coupled to the membrane, and at least one magnet is free to oscillate with a rotational movement. At least one magnet is free to oscillate with a rotational movement. The oscillation takes place at a resonance frequency, which is a function of the sensed pressure, which pressure influences the spacing between the two permanent magnets. This oscillation frequency can be sensed remotely by measuring a magnetic field altered by the oscillation. The pressure sensing unit may be provided on a catheter or guidewire.

A method of determining fluid pressure inside a conduit. The method includes positioning a conduit in a surgical system. The conduit having an external surface, and the surgical system having a pair of sensors. The conduit is positioned in the surgical system such that the external surface of the conduit applies a force on the pair of sensors when the conduit expands. The method includes a step of generating one or more electrical signals with the pair of sensors. The one or more electrical signals corresponding to the force on the pair of sensors. The method includes a step of determining the fluid pressure inside the conduit by converting the one or more electrical signals into a fluid pressure value through a controller.

Self-calibrating sensor assemblies for excess body fluid drainage systems are disclosed herein. Self-calibrating sensor assemblies can include a sensor assembly engaged with a flexible interface member of a drainage catheter. The assembly includes a sensor having a body and a shaft extending from the body. A contact member is slidably mated with the shaft and coupled to the flexible interface member. A resilient member is coupled to the sensor shaft and disposed between the contact member and the body. An actuator moves the sensor between a first position and a second position with respect to the drainage catheter. In the first position the sensor is positioned to measure the pressure and/or force at the flexible interface member, and in the second position the resilient member exerts a known force on the sensor.