An example power supply for supplying electrical power to an electronic device includes an AC to DC converter, power factor correction (PFC) circuitry, and a controller. The AC to DC converter is configured to convert an input AC power signal into a DC power signal. The PFC circuitry is configured to correct a power factor of the DC power signal. The controller is configured to monitor an amount of correction () being applied to the DC power signal by the PFC circuitry and to shut down supply of power to the electronic device in response to being within a first threshold of zero degrees for a second threshold amount of time.

A method for estimating the current flowing through a winding of an electric motor of the type having one winding controllable by a switching device, including the following steps: measuring a voltage at the input of the winding, correcting the measured voltage to produce a corrected voltage determining a resistance of the switching device, estimating the current flowing through the winding by dividing the difference between a control voltage used to control the switching device and the corrected voltage by the resistance. The use of such an estimating method for providing a diagnosis for a current sensor, and an estimating method for controlling an electric motor in fail-soft mode are also disclosed.

Data transmission method for a two-wire data bus from a transmitter having ports to a receiver having ports. The method comprises the steps of: detecting a first common-mode voltage swing on the ports and forming a first common-mode signal. Detecting a second common-mode voltage swing on the ports and forming a second common-mode signal. The transmitter sending data via the two-wire data bus. The receiver receiving the data. The voltage difference on the ports being compared with a lower and an upper reception threshold, wherein an output of an apparatus element assumes a first or second level on the basis of this comparison. Raising the differential send level if the absolute value of the first common-mode signal is greater than a first threshold value. Raising the upper reception threshold and/or lowering the lower reception threshold if the absolute value of the second common-mode signal is greater than a second threshold value. The method allows the transmission of a datum from the transmitter to the receiver. On the basis of the result of the comparison of the absolute value of the detected first common-mode signal with a first threshold value, the upper reception threshold is raised and/or the lower reception threshold is lowered whenever this absolute value of the first common-mode signal is greater than this first threshold value.

An apparatus is provided for monitoring a high-voltage on-board power supply system of an electrically operated vehicle for the occurrence of overloading, wherein the high-voltage on-board power supply system includes as components one or more energy sources and/or one or more energy sinks which are each connected via a conductor line arrangement to a first supply potential line and to a second supply potential line. Each of the components is assigned a current sensor which is designed to detect a current flowing through the respective component and to transmit information representing the level of the current to an evaluation unit for evaluation. The evaluation unit is designed to compare the current with a first current threshold and a second current threshold and to output a switch-off signal at least for the component assigned to the current sensor if, as a first criterion, the level of the current and the duration of the level of the current are between the first and second current thresholds.

A system for an aircraft includes an aircraft component that includes a heater routed through the aircraft component, the heater including a resistive heating element and insulation surrounding the resistive heating element. A first current flows into the resistive heating element to provide heating for the aircraft component and a second current flows out of the resistive heating element. The system further includes a first sensor configured to produce a first sensor signal representing the first current, a second sensor configured to produce a second sensor signal representing the second current, a leakage sensor configured to produce a leakage sensor signal representing a leakage current, and a signal processor configured to sample and measure the first current, the second current, and a leakage current using a high frequency sampling rate to identify the presence of electric arcing. The detection of electric arcing is used to predict future heater failure and estimate heater remaining useful life.

A detection apparatus has an alternating-current voltage input unit and a generation circuit. The generation circuit generates a superimposition signal in which information indicating a timing of a zero cross in an alternating-current voltage inputted into the input unit and information indicating a voltage level of the alternating-current voltage are superimposed.

The present invention provides a solar photovoltaic installation capable of storing power while supplying power during daytime when solar radiation conditions are excellent. The solar photovoltaic installation of the invention includes at least a first solar module string 11 and a second solar module string 12 as solar module strings 10, the solar photovoltaic installation further includes at least a first storage battery array 21 and a second storage battery array 22 as storage battery arrays 20, and while power storage capacity detection means 60 detects that the second storage battery array 22 is less than a predetermined capacity and voltage detection means 50 detects voltage of more than predetermined voltage, the control means 40 connects the first solar module string 11 to a power conditioner 30, and connects the second solar module string 12 to the second storage battery array 22.

The embodiments described herein provide systems and methods for determining the health status of a sensed switch. In general, the embodiments described herein determine a measure of a health status of the sensed switch by comparing a voltage on the sensed switch, ascertaining a first comparator state under one test condition and ascertaining a second comparator state under a second test condition. The first comparator state and the second comparator state are and then compared to determine the measure of the health status of the sensed switch.

Data transmission method (d) for a two-wire data bus (Z) from a transmitter (S) having ports (A1, A2) to a receiver (E) having ports (A3, A4). The method comprises the steps of: detecting a first common-mode voltage swing on the ports (A1, A2) and forming a first common-mode signal (k1). Detecting a second common-mode voltage swing on the ports (A3, A4) and forming a second common-mode signal (k2). The transmitter (S) sending data via the two-wire data bus (Z). The receiver (E) receiving the data. The voltage difference on the ports (A3, A4) being compared with a lower and an upper reception threshold (SW4, SW5), wherein an output (0) of an apparatus element (CMP2) assumes a first or second level on the basis of this comparison. Raising the differential send level if the absolute value of the first common-mode signal (k1) is greater than a first threshold value (SW1). Raising the upper reception threshold (SW5) and/or lowering the lower reception threshold (SW4) if the absolute value of the second common-mode signal (k2) is greater than a second threshold value (SW2). The method allows the transmission of a datum from the transmitter (S) to the receiver (E). On the basis of the result of the comparison of the absolute value of the detected first common-mode signal (k1) with a first threshold value (SW1), the upper reception threshold (SW5) is raised and/or the lower reception threshold (SW4) is lowered whenever this absolute value of the first common-mode signal (k1) is greater than this first threshold value (SW1).

An example power supply for supplying electrical power to an electronic device includes an AC to DC converter, power factor correction (PFC) circuitry, and a controller. The AC to DC converter is configured to convert an input AC power signal into a DC power signal. The PFC circuitry is configured to correct a power factor of the DC power signal. The controller is configured to monitor an amount of correction () being applied to the DC power signal by the PFC circuitry and to shut down supply of power to the electronic device in response to being within a first threshold of zero degrees for a second threshold amount of time.