Abstract: A magnetic sensor, may sense a first magnetic field component corresponding to a first axis of a magnetic field produced by a magnet. The magnetic sensor may sense a second magnetic field component corresponding to a second axis of the magnetic field. The magnetic sensor may determine information that defines potential positions of a movable object associated with the magnet. Each potential position, of the potential positions, may be defined by a first magnetic field range for the first magnetic field component and a second magnetic field range for the second magnetic field component. The magnetic sensor may identify a position of the movable object based on the first magnetic field component, the second magnetic field component, and the information that defines the potential positions. The magnetic sensor may provide an output based on identifying the position of the movable object.

Abstract: A system may include a digital sensor system including a sensor element and a digital interface. The digital interface may provide a wake-up signal based on a sensing action being performed by the sensor element after a predefined event is detected by the digital sensor system. The system may include a microcontroller to receive the wake-up signal provided by the digital interface, and wake from a sleep mode based on receiving the wake-up signal provided by the digital interface.

Abstract: A receiver may receive a pulse width encoded signal. The receiver may determine a position of a transition of a pulse of the pulse width encoded signal by oversampling the pulse width encoded signal with respect to a quantization function. The receiver may determine that the position of the transition deviates from an expected position according to the quantization function by more than a predetermined range. The receiver may generate a signal, indicating an unexpected event, based on determining that the position of the transition deviates from the expected position. The receiver may detect an error in a message corresponding to the pulse width encoded signal based on a check value identified from the pulse width encoded signal. The receiver may adjust, based on the signal indicating the unexpected event, a value, corresponding to the position of the transition, to cause the error in the message to be corrected.

Abstract: A sensor comprises a transmitter to transmit signals over a communication path, the sensor further capable to receive signals from the communication path, wherein the sensor is configured to communicate sensor data having a nibble data signal format at the transmitter in response to a trigger signal received at the sensor.

Abstract: Embodiments relate to integrated circuit (IC) sensors and more particularly to IC sensor diagnostics using multiple (e.g., redundant) communication signal paths, wherein one or more of the communication signal paths can be diverse (e.g., in hardware, software or processing, an operating principle, or in some other way) from at least one other of the multiple communication signal paths. Embodiments can relate to a variety of sensor types, implementations and applications, including 3D magnetic field and other sensors.

Abstract: Embodiments relate to apparatus (200) and methods for distinguishing data of a plurality of multidimensional magnetic field sensors (120). A first sensor arrangement (100-1) comprises a first magnetic field source (110-1) and a first multidimensional magnetic field sensor (120-1), wherein the first magnetic field source and the first magnetic field sensor are arranged relative to one another in a first manner characteristic for the first sensor arrangement. At least one second sensor arrangement (100-2) comprises a second magnetic field source (110-2) and a second multidimensional magnetic field sensor (120-2), wherein the second magnetic field source and the second magnetic field sensor are arranged relative to one another in a second manner characteristic for the second sensor arrangement.

Abstract: A circuit arrangement includes a controller and an integrated driver arrangement coupled to the controller. The integrated driver circuit includes a driver unit having at least one operation parameter, and a diagnostic unit coupled to the driver unit. The diagnostic unit is adapted to retrieve the at least one operation parameter from the driver unit, and is coupled to the controller.

Abstract: A sensor comprises a transmitter to transmit signals over a communication path, the sensor further capable to receive signals from the communication path, wherein the sensor is configured to communicate sensor data having a nibble data signal format at the transmitter in response to a trigger signal received at the sensor.

Abstract: Embodiments relate to integrated circuit (IC) sensors and more particularly to IC sensor diagnostics using multiple (e.g., redundant) communication signal paths, wherein one or more of the communication signal paths can be diverse (e.g., in hardware, software or processing, an operating principle, or in some other way) from at least one other of the multiple communication signal paths. Embodiments can relate to a variety of sensor types, implementations and applications, including 3D magnetic field and other sensors.

Abstract: A receiver may receive a pulse width encoded signal. The receiver may determine a position of a transition of a pulse of the pulse width encoded signal by oversampling the pulse width encoded signal with respect to a quantization function. The receiver may determine that the position of the transition deviates from an expected position according to the quantization function by more than a predetermined range. The receiver may generate a signal, indicating an unexpected event, based on determining that the position of the transition deviates from the expected position. The receiver may detect an error in a message corresponding to the pulse width encoded signal based on a check value identified from the pulse width encoded signal. The receiver may adjust, based on the signal indicating the unexpected event, a value, corresponding to the position of the transition, to cause the error in the message to be corrected.

Abstract: A sensor system utilizing adaptively selected carrier frequencies is disclosed. The system includes a system bus, a bus master, and a sensor. The system bus is configured to transfer power and data. The bus master is coupled to the system bus and is configured to provide power to the bus and receive data from the bus. The sensor is coupled to the system bus and is configured to transfer data on the bus using an adaptively selected carrier frequency.

Abstract: A magnetic sensor, may sense a first magnetic field component corresponding to a first axis of a magnetic field produced by a magnet. The magnetic sensor may sense a second magnetic field component corresponding to a second axis of the magnetic field. The magnetic sensor may determine information that defines potential positions of a movable object associated with the magnet. Each potential position, of the potential positions, may be defined by a first magnetic field range for the first magnetic field component and a second magnetic field range for the second magnetic field component. The magnetic sensor may identify a position of the movable object based on the first magnetic field component, the second magnetic field component, and the information that defines the potential positions. The magnetic sensor may provide an output based on identifying the position of the movable object.

Abstract: A digital sensor system includes a sensor element, an analog-to-digital converter coupled to the sensor element, and a wake-up circuit configured to activate the sensor element and the analog-to-digital converter in response to a predefined event.

Abstract: A data transmission system comprising an Automotive Sensor Network System (ASNS) connected to a plurality of source locations via a common bus, wherein the ASNS is configured to ascertain the source from which the data-frames and first package checksum are received and based on the ascertainment of the source, appropriate decoding methods are used to calculate the ASNS location data-frame checksums and the ASNS location package checksums. A higher order redundancy check is done over a series of data-frames to detect errors in the reception caused by temporary high interference that may exist in the transmission path.

Abstract: A sensor interface system includes a system bus, a bus master and a sensor. The bus master is coupled to the system bus. The bus master is configured to provide voltage regulation at a first band and perform data transmission within or at a second band. The sensor is also coupled to the system bus. The sensor is configured to receive or utilize the voltage regulation and to perform data transmission within or at the second band.

Abstract: Various devices, systems and methods are disclosed where a noise signal component of a sensor signal is used to obtain information about a sensor device. A device may include an evaluation circuit that is configured to receive a sensor signal having a noise signal component, and the evaluation circuit is further configured to evaluate the noise signal component to obtain information about a sensor device generating the sensor signal.

Abstract: A sensor system utilizing adaptively selected carrier frequencies is disclosed. The system includes a system bus, a bus master, and a sensor. The system bus is configured to transfer power and data. The bus master is coupled to the system bus and is configured to provide power to the bus and receive data from the bus. The sensor is coupled to the system bus and is configured to transfer data on the bus using an adaptively selected carrier frequency.

Abstract: A data transmission system comprising an Automotive Sensor Network System (ASNS) connected to a plurality of source locations via a common bus, wherein the ASNS is configured to ascertain the source from which the data-frames and first package checksum are received and based on the ascertainment of the source, appropriate decoding methods are used to calculate the ASNS location data-frame checksums and the ASNS location package checksums. A higher order redundancy check is done over a series of data-frames to detect errors in the reception caused by temporary high interference that may exist in the transmission path.

Abstract: Methods and devices are provided wherein feedback is included in a checksum. An example method includes communicating between a first device and a second device. The method further includes including feedback information used by the first device as input to a checksum calculation, wherein the feedback information is not communicated concurrently with the checksum from the first device to the second device.

Abstract: An electrical circuit includes a first circuit part and a second circuit part. A first electrical potential is applicable to the first circuit part, wherein a second electrical potential is applicable to the second circuit part. The two circuit parts are galvanically isolated from each other by an insulator, wherein the insulator includes a conducting portion. This conducting portion can be safely sensed by an additional circuitry, to detect if a full or partial contact to the first electrical potential or the second electrical potential has occurred due to a voltage shift or a current flow on the conducting portion, which is itself insulated. This sensing circuitry can incorporate protection elements to clamp voltages and limit currents to prevent destruction of connected circuitries in case of a fail of the insulation.