A method is provided for testing switch signals of an inverter of an electric machine of a drive system of a motor vehicle. The electric machine is controlled via a pulse-width modulation generated by a control unit using a target duty cycle and a triangular-waveform voltage sequence. An actual duty cycle of a current pulse-width modulation is continuously ascertained from the switch signals and compared with the target duty cycle of the control unit.

The present disclosure provides a method for analyzing a signal, the method comprising receiving an incoming square-wave-like signal that comprises a predetermined frequency and a variable duty cycle, continuously forming the first derivative of the incoming square-wave-like signal, and determining at least one of the frequency, and the duty cycle of the received signal based on the first derivative. Further, the present disclosure provides a measurement application device.

Embodiments herein relate to an apparatus comprising: a first circuit with a plurality of stages; and a second circuit communicatively coupled with the first circuit, wherein the second circuit includes: a plurality of tap lines, wherein respective tap lines of the plurality of tap lines are coupled between two stages of the plurality of stages; and the logic, wherein the logic is to identify, based on an average voltage measurement of at least one tap line, a status of a duty-cycle of a signal propagating through a stage of the first circuit. Other embodiments may be described and claimed.

Techniques are provided for non-linear filtering of a signal for improved pulse detection and pulse width discrimination. A system implementing the techniques according to an embodiment includes a first linear filter configured to filter an in-phase component of a received signal to a downsample bandwidth and a second linear filter configured to filter a quadrature phase component of the received signal to the downsample bandwidth. The system also includes a magnitude calculation circuit coupled to outputs of the first linear filter and the second linear filter and configured to generate a magnitude signal based on the filtered in-phase component and the filtered quadrature phase component of the received signal. The system further includes a median filter processor coupled to an output of the magnitude calculation circuit and configured to apply a median filter to the magnitude signal to generate a filtered signal having reduced noise while maintaining sharp edge transitions.

Techniques are provided for non-linear filtering of a signal for improved pulse detection and pulse width discrimination. A system implementing the techniques according to an embodiment includes a first linear filter configured to filter an in-phase component of a received signal to a downsample bandwidth and a second linear filter configured to filter a quadrature phase component of the received signal to the downsample bandwidth. The system also includes a magnitude calculation circuit coupled to outputs of the first linear filter and the second linear filter and configured to generate a magnitude signal based on the filtered in-phase component and the filtered quadrature phase component of the received signal. The system further includes a median filter processor coupled to an output of the magnitude calculation circuit and configured to apply a median filter to the magnitude signal to generate a filtered signal having reduced noise while maintaining sharp edge transitions.

A high-frequency QRS waveform curve analysis method comprises: acquiring a high-frequency QRS waveform curve; selecting the high-frequency QRS waveform curve in a preset time period as a reference waveform curve; selecting a point with the minimum root-mean-square voltage on the reference waveform curve as a first reference point; selecting a second reference point meeting a first selection condition and a third reference point meeting a second selection condition, wherein the time of the first reference point is later than that of the second reference point and earlier than the third reference point; based on the first reference point and the second reference point, determining an amplitude falling relative value; based on the first reference point and the third reference point, determining an amplitude rising relative value. If the amplitude falling rising relative values meet a preset condition, determining reference information according to the high-frequency QRS waveform curve.

One embodiment is a method of deconvolving overlapping first and second pulses in a photon-counting CT scanning system, the method comprising detecting a first pulse event having a first detected level; detecting a second pulse event having a second detected level; determining an amount of time that elapses between the detected first pulse event and the detected second pulse event; and reconstructing the first pulse and the second pulse using the first and second detected levels, the duration of time between the first and second pulse events, and a known pulse shape.

Secure circuitry of an integrated circuit detects a duration of a clock cycle of a crystal oscillator external to the integrated circuit, using a digital ring oscillator internal to the integrated circuit and having a higher frequency than the crystal oscillator. The secure circuitry calculates a variation in the duration of the clock cycle. In response to the duration being greater than a maximum duration limit, the duration being less than a minimum duration limit, and/or the variation being greater than a maximum variation limit, the secure circuitry performs an action.