A method of determining a set of calibration values for offset-compensation of an inductive angular sensor arrangement includes: a substrate with a transmitter coil and three receiver coils, and a rotatable target. The method involves the steps of: a) exciting the transmitter coil; b) positioning the target at or near predefined positions, c) measuring and processing the signals, including calculating sums of squares of difference signals. A sensor device, and an angular sensor system may be arranged or adapted in view of the method.

A detection system is used in a musical keyboard instrument that includes a key, the displacement of which changes in accordance with a playing operation. The detection system includes a detectable portion configured to be disposed on the movable member and including a first coil; a signal generator including a second coil configured to be disposed spaced from the first coil and configured to, in a state where the second coil receives a supply of current: generate a magnetic field; and generate a detection signal with a level depending on a distance between the detectable portion and the second coil; and a magnetic body disposed on at least one of the movable member or the signal generator.

An inductive position sensor may be configured to detect relative position between a first member and a second member. The inductive position sensor may include a transmit aerial configured to be disposed on the first member. The inductive position sensor may include a receive aerial configured to be disposed on the first member. The inductive position sensor may include processing circuitry configured to provide one or more signals indicative of the relative position between the first member and the second member based on a receive signal induced in the receive aerial resulting from a signal provided to the transmit aerial. One or more of the transmit aerial and the receive aerial may include one or more windings. A shape of the one or more windings can be a combination of a sinusoidal waveform and one or more scaled harmonics of the sinusoidal waveform.

An apparatus for determining a relative position of a wireless power transmitter from a wireless power receiver is provided. The apparatus comprises a plurality of sense coils, each configured to generate a respective signal under influence of an alternating magnetic field comprising a plurality of wave pulses, each wave pulse occurring in a respective time slot of a plurality of time slots. The apparatus further comprises a processor configured to determine the relative position of the wireless power transmitter from the wireless power receiver based on the respective signal from each of the plurality of sense coils.

A method and apparatus for obtaining a valid peak from an output signal of a resolver sensor are provided. The method includes inputting an excitation signal to a resolver sensor, receiving a resolver signal from the resolver sensor, receiving a high peak and a low peak from the received resolver signal, determining whether the high peak or the low peak falls within an effective range, and defining the high peak or the low peak as a valid peak when the high peak or the low peak falls within the effective range.

A position sensor includes a plurality of E-shaped ferromagnetic cores arranged to define a circular opening therethrough to receive a shaft. Each E-shaped ferromagnetic core has a plurality of teeth, wherein adjacent E-shaped ferromagnetic cores of the arranged plurality of E-shaped ferromagnetic cores have an overlapping tooth. The position sensor further includes a frame surrounding the arranged plurality of E-shaped ferromagnetic cores, with the E-shaped ferromagnetic cores coupled to the frame.

A vehicle includes an electric machine having a number of pole pairs, N, a position sensor having a number of pole pairs, M, that generates output indicative of a rotational position of the electric machine, and one or more controllers. The one or more controllers generate a remapped rotational position according to a product of the rotational position and L/N, generate a scaled position according to a product of the remapped rotational position and N/M, and command the electric machine to produce a specified torque or speed based on the scaled position. M is not equal to and not a factor of N, and L is a minimum common multiplier of N and M.

A resolver signal processing apparatus processes a resolver signal output from a resolver by applying an excitation signal generated by an excitation signal generating unit. In particular, the resolver signal processing apparatus includes: a resolver signal processing unit, in which the resolver signal processing unit includes a resolver signal acquiring unit receiving the resolver signal and extracting pole information of the resolver signal, a resolver phase compensating unit compensating a pole acquisition time of extracting the pole information of the resolver signal acquiring unit, and a resolver-digital converter outputting a digital signal by using the pole information extracted from the resolver signal acquiring unit, and a resolver signal processing method using the same.

A scale includes a plurality of conductors that are arrayed in a given interval along a measurement axis, wherein each of the plurality of conductors has projection portions, each of which projects toward each side of the measurement axis, and wherein at least a part of each of the projection portions has a curve projecting in the measurement axis.

A resolver converter includes a tracking loop circuit that calculates an angle θ from a resolver output signal, a control and diagnosis circuit that controls the tracking loop circuit and diagnoses based on the resolver output signal, wherein the control and diagnosis circuit, by operating the tracking loop circuit as a direct digital synthesizer (DDS), synchronously detects a noise signal superimposed on the resolver output signal.