Abstract: A method for determining a cryptographic key for a MEMS device includes identifying physical properties for the device. A feature vector having a plurality of values is determined. Each of the values correspond to different physical properties. The cryptographic key is determined from the feature vector. The cryptographic key can be determined using a fuzzy extractor. The cryptographic key can be determined using different feature vectors corresponding to different channels in a device or different MEMS structures in the device.

Abstract: A method for determining a cyrptographic key for a MEMS device includes identifying physical properties for the device. A feature vector having a plurality of values is determined. Each of the values correspond to different physical properties. The cryptographic key is determined from the feature vector. The cryptographic key can be determined using a fuzzy extractor. The cryptographic key can be determined using different feature vectors corresponding to different channels in a device or different MEMS structures in the device.

Abstract: A medication patch compliance control unit system and method is disclosed. The control unit can include an attachment sensor, a user interface and a controller that receives signals from the attachment sensor and sends signals to the user interface. The control unit can include an attachment sensor, a wireless transceiver and a controller that receives signals from the attachment sensor and sends signals through the transceiver. The attachment sensor can be a temperature sensor, and the controller can determine attachment based on whether the sensor is reading temperatures in the normal body temperature range. The user interface can include visual and/or audible indicators. The control unit can include an expiration timer, and provide an expiration signal when the patch is expired. The transceiver can transmit medication patch data to a healthcare provider. The controller can record when the medication patch is attached to and detached from the patient.

Abstract: A micromechanical sensor is described having a substrate with a structured layer on it, a seismic mass that is movable relative to the structured layer under the effect of a spring force, at least one measuring capacitor electrode array for registering a displacement of the seismic mass in a direction of measurement, and at least one drive capacitor electrode array for deflecting the seismic mass in a self-test direction, the direction of measurement being oriented perpendicular to the self-test direction. A corresponding optimization method is also described.

Abstract: A sensor element, in particular for determining an angle of rotation, has a detection medium whose position varies as a function of a change in a parameter to be measured, where the change in the position of the detection medium leads to a change in an analyzable signal of the sensor element which is influenced by the detection medium. The detection medium has at least one conductor loop carrying current which is exposed to an external magnetic field; the detection medium is rotationally movably mounted so that a rotational motion of the sensor element about an angle of rotation in the plane of the magnetic field is converted into a deflection of the detection medium perpendicular to the magnetic field.

Abstract: A micromechanical device, in particular an acceleration sensor, includes a seismic mass which is resiliently supported on a substrate via a first flexural spring device and which can be deflected in at least one direction by an acceleration, the deflection being able to be limited by a stop device. The stop device has at least one limit stop that is resiliently supported on the substrate via a second flexural spring device, the second flexural spring device having a greater flexural strength than the first flexural spring device.

Abstract: A micromechanical magnetic field sensor includes a printed circuit trace device, which is suspended above a substrate and is capable of being deflected elastically. Also included are a first capacitor plate device that is joined to the printed circuit trace device and is able to be deflected together with the printed circuit trace device, and a second, fixed capacitor plate device that is joined to the substrate and forms a capacitor device by interacting with the first capacitor plate device. A magnetic field sensing device conducts a predetermined current through the printed circuit trace device and measures the change in capacitance of the capacitor device arising in dependence on an applied magnetic field. The magnetic field sensing device can also be designed in such a way that it can be calibrated by calibration current loops.