A failure detection device for a steering angle sensor according to an embodiment comprises: a steering angle sensor including a main gear that rotates together with a steering wheel, a first sub-gear and a second sub-gear that are each engaged with the main gear and have a constant gear ratio with the main gear, a first Hall IC chip for detecting the angle of the first sub-gear, and a second Hall IC chip for detecting the angle of the second sub-gear; and a control unit that determines failure of the steering angle sensor on the basis of a first angle difference between the current angle and a previous angle of the first sub-gear as detected by the first Hall IC chip, and a second angle difference between the current angle and a previous angle of the second sub-gear as detected by the second Hall IC chip.

A handwheel actuator assembly includes a handwheel shaft configured to receive a handwheel; a feedback device operable to provide a variable level of resistance to rotation of the handwheel shaft; and a handwheel shaft position sensor operable to sense an angular position of the handwheel shaft. The handwheel shaft position sensor may be mounted on a circuit board. The circuit may comprise a controller that is configured to receive signals from the handwheel shaft position sensor.

A sensor unit for a steering system, in particular a steer-by-wire steering system, includes a component to be monitored and having a multifunctional position sensor, which has at least one spring element and at least one piezoelectric sensor, which is associated with the spring element and is provided at a first end of the spring element. The spring element is associated with the component to be monitored via a second end opposite to the first end. A steering wheel subassembly, a rack subassembly and a steering system are furthermore described.

A position identification assembly for a steering column is provided. The assembly may include a mount bracket, a steering column, a sensor, and a controller. The mount bracket may define an opening to the cavity. The steering column may be mounted to the mount bracket for translation at least partially in to and out of the cavity and the steering column may define one or more physical features therealong. The sensor may be secured to the mount bracket to detect the physical features. Each of the one or more physical features may be arranged upon the steering column such that the sensor detects the one or more physical features when the steering column translates between positions and may send a signal to the controller reflecting the same. The controller is programmed to identify a steering column position based on the received signal.

An angular position sensor may include a housing, and a rotor including a rotor assembly with a rotor latching device. The rotor and the housing are connected by the rotor latching device secured by a retaining ring. The retaining ring can be transferred into a secured position in an axial direction. The retaining ring is integral with the rotor assembly and features at least one retaining element with which the retaining ring secures the connection of rotor and housing. The retaining ring and the rotor latching device each feature corresponding latching elements. The rotor assembly features axial position-securing elements. The latching elements interact such that the retaining ring is secured in an axial direction along the rotary axis relative to the rotor. The axial position-securing elements interact so that the rotor is secured essentially free of play on the housing in an axial direction along the rotary axis.

A vehicle steering system for use in turning steerable vehicle wheels includes a steering column and a steering gear operably connected with the steering column. The steering gear turns the steerable vehicle wheels upon rotation of the steering column. A first control assembly is connected to the steering column. The first control assembly has a first motor operably connected to the steering column for applying a torque to the steering column. A second control assembly is connected to the steering column. The second control assembly has a second motor operably connected to the steering column for applying a torque to the steering column. he second control assembly directly communicates with the first control assembly. A vehicle controller is configured to communicate with the first and second control assemblies to autonomously steer the vehicle.

A steering system for a motor vehicle having a rotation sensor may include a magnetic element that is attached to a steering shaft and is rotatable with the latter about an axis, two stator elements that are arranged fixed coaxially relative to the steering shaft. The stator elements may be spaced apart axially from one another and may be operatively connected to at least one sensor element via two flux conductors. A flux conductor in each case has a collecting portion, a connecting portion, and a compensator portion. The collecting portion is connected to a stator element and is connected to the compensator portion via a connecting portion. The sensor element may be arranged between the two flux conductors. The compensator portion may have a compensator surface that is smaller than or equal to a collecting surface of the collecting portion.

A sensor device includes a first stator pair, consisting of a first and second ferromagnetic stators and a second stator pair, consisting of the second ferromagnetic stator and a third ferromagnetic stator. The sensor device includes a multipole magnet, rotatable relative to the two stator pairs. A magnetic field is induced as a result of the rotation. The sensor device includes first and second magnetic field sensors configured to output first and second sensor signals, respectively. The sensor device includes a magnetic flux concentrator configured to concentrate the induced magnetic field at the location of the first magnetic field sensor and at the location of the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged such that an influence of a rotation-independent magnetic stray field on the sensor signals is compensated for upon difference formation or summation applied to the sensor signals.

Disclosed is an electronic device for determining the angular position of a shaft of a motor vehicle, the device including a printed circuit board and a magnetic guide including at least two fastening tabs for fastening to the printed circuit board, the printed circuit board including a base substrate and at least two fastening areas for fastening the magnetic guide, each designed to receive a fastening tab of the magnetic guide, the fastening tab defining a fastening orifice. Each fastening area is defined on the base substrate of the printed circuit board and includes a pad fastened to the base substrate. Each fastening tab is joined to the pad of the corresponding fastening area by way of an adhesive that is applied in its fastening orifice.

An apparatus, methods and systems for data collection related to an oil and gas process and disclosed. A system may include a multi-sensor acquisition component including a plurality of inputs and a plurality of outputs, a sensor data storage profile circuit structured to determine a data storage profile including a data storage plan for the plurality of inputs, a sensor communication circuit structured to interpret a plurality of inputs, a sensor data storage implementation circuit structured to store at least a portion of the inputs in response to the data storage profile, a data analysis circuit structured to analyze the plurality of inputs and determine a data quality parameter, and a data response circuit structured to adjust at least one of the data storage profile and the data collection routine in response to the data quality parameter.