Abstract: The invention relates to apparatus (40) comprising: an inductor; a rectifier coupled to the inductor; a voltage converter coupled to the rectifier; a battery coupled to the voltage converter; a load coupled to the voltage converter; and a control unit coupled to the voltage converter and arranged to cause either the battery to be charged by the rectifier, or the load to be powered by the rectifier, or the load to be powered by the battery, as a function of the state of a switch for controlling powering of the load and as a function of the output voltage of the rectifier.

Abstract: A wireless power transmitter device that includes a transmitter circuit, a transmitter coil, a transmitter communication unit and a transmitter control unit is provided. The transmitter circuit generates a transmitting current. The transmitter coil receives the transmitting current to generate an electromagnetic field to induce a receiving current in a wireless power receiver device. The transmitter communication unit is configured to receive a report of a received power of the wireless power receiver device therefrom. The transmitter control unit receives the report of the received power and determines whether a frequency splitting phenomena occurs according to the received power. When the frequency splitting phenomena occurs, the transmitter control unit adjusts at least one of a configuration of the transmitter coil and a configuration of the transmitter circuit or adjusts a transmitting frequency of the transmitting current.

Abstract: Disclosed is a direct current (DC) circuit breaker including a first line in which a first high-speed switch and a power semiconductor switch are connected in series; a second line in which a plurality of second high-speed switches, a plurality of pairs of a first non-linear resistor and a power fuse connected in parallel, and a resistor are connected in series; and a third line including a second non-linear resistor. The first line, the second line, and the third line are connected in parallel.

Abstract: An apparatus includes at least one external source terminal configured to be connected to at least one secondary terminal of a distribution transformer and at least one external load terminal configured to be connected to a load. The apparatus further includes a converter circuit coupled to the at least one external source terminal and to the at least one external load terminal and configured to provide shunt current regulation and series voltage regulation.

Abstract: An electronic module for protecting power semiconductor devices of an HVDC converter against high current surges and damaging electrical discharges includes a capacitor, a short circuit device, a movable portion, a short circuit portion and a spring element. The short circuit device is connected in parallel with the capacitor and has first and second busbars. The movable portion is connected to the first busbar and the short circuit portion is connected to the second busbar. The spring element is arranged between the movable portion and the short circuit portion. When a short circuit current flows through the first busbar, an electromagnetic force between the busbars causes the first busbar to repel the second busbar and move towards the short circuit portion. The latter provides a short circuit path connecting the first busbar to the second busbar short circuiting the capacitor and bypassing the power semiconductor devices of the HVDC converter.

Abstract: According to one embodiment, there is provided a semiconductor integrated circuit including an output transistor, an error amplifier, and a control circuit. The output transistor is connected between a first node on an input terminal side and a second node on an output terminal side. The error amplifier has a non-inverting input terminal, an inverting input terminal, and an output terminal. The non-inverting input terminal is connected to a third node between the second node and a standard potential. The inverting input terminal is connected to a reference voltage. The output terminal is connected to the gate of the output transistor. The control circuit makes responsiveness of the error amplifier at startup slower than responsiveness of the error amplifier at steady operation.

Abstract: A first substrate includes a substrate main body including a first principal surface and a second principal surface opposing each other in a first direction, first and second connection electrodes disposed on the first principal surface, and third and fourth connection electrodes disposed on the second principal surface. A first metal terminal includes a first connection portion electrically connected with the first connection electrode, and a first leg portion extending from the first connection portion. A second metal terminal includes a second connection portion electrically connected with the fourth connection electrode, and a second leg portion extending from the second connection portion. A multilayer capacitor is disposed on the first principal surface side of the first substrate, and an overcurrent protection device is disposed on the second principal surface side of the first substrate. The second connection electrode and the third connection electrode are electrically connected to each other.

Abstract: A wireless power transmission system according to the present disclosure includes: a pair of antennas, between which power is transmissible wirelessly by resonant magnetic coupling at a frequency f0, one of which is a series resonant circuit, and the other of which is a parallel resonant circuit; and a control section, which controls a transmission frequency according to the magnitude of the power being transmitted between the antennas. If the power transmitted between the antennas is greater than a reference value P1, the control section sets the transmission frequency to be a value that falls within a first level range that is higher than the frequency f0. But if the power is smaller than the reference value P1, then the control section sets the transmission frequency to be a value that falls within a second level range that is lower than the first level range.

Abstract: An electrical protective arrangement for an electrical installation has a fault current protection apparatus with a detection device for sensing a fault current and an evaluation device for comparing the sensed fault current with a threshold value. A tripping signal is output by the evaluation device if the sensed fault current exceeds the threshold value. A communication module is configured to send fault current data with information pertaining to the sensed fault current and to receive operating data for setting an operating state for the evaluation device.

Abstract: The present disclosure relates to a switching device, comprising an input for a sensor signal, the sensor signal having a sensor signal amplitude; and processing circuitry to determine a switching threshold based on the sensor signal amplitude and a weighting factor depending on said sensor signal amplitude and to generate a switching signal when a level of the sensor signal crosses the switching threshold.

Abstract: A power supply system comprises a first battery, a second battery, an output electric circuit, a first switching element, a second switching element, and a third switching element. The output electric circuit includes a first electric circuit and a second electric circuit. The second electric circuit has a potential lower than a potential of the first electric circuit. The first, second and third switching elements are provided in series with each other from the first electric circuit toward the second electric circuit. The first battery is provided in parallel with the second switching element. The second battery is provided in parallel with a series connection between the second switching element and the third switching element.

Abstract: A system-in-a-package (SIP) has a semiconductor chip embedded in a dielectric substrate. An inductor is on a top surface of a substrate and is connected to the semiconductor chip. A thin film capacitor may be placed between the inductor and the dielectric substrate. A second thin film capacitor may be placed on the top surface of the semiconductor chip, or be embedded in the dielectric substrate with a thermal pad on a bottom surface of the substrate which is connected to the second thin film capacitor to facilitate heat dissipation.

Abstract: Technology for concurrently powering equipment from multiple power sources, and the control thereof is disclosed. One example implementation of the technology includes a first power supply that powers equipment from a first power source and a second power supply that also powers the equipment from a second power source while the equipment is being powered by the first power supply. A target direct current (DC) output voltage of at least one of the power supplies is changed, thereby changing a ratio of the power being drawn from the first power supply to the power being drawn from the second power supply.

Abstract: A wireless power transfer system may include a transmitter transducer assembly, a signal generator and one or more power receivers. The transmitter transducer assembly may include at least one transmitter transducer. The signal generator may be operationally configured to generate an alternating current transmission signal. The one or more power receivers may be electrically connected to one or more respective loads. Each of the one or more power receivers may include a receiver transducer assembly. The receiver transducer assembly may include at least one receiver transducer. Each receiver transducer of the at least one receiver transducer may receive a time varying electromagnetic flux of the electromagnetic field transmitted from the transmitter transducer assembly and produce a second power signal. The power processor may convert the second power signal to a third power signal appropriate for the respective one or more loads.

Abstract: An electronic apparatus comprises several series-connected loads powered by a high voltage power source. To provide voltage regulation for each load, a ladder circuit is described. To automatically balance the voltage at output, one or more voltage-control-oscillators are included.

Abstract: Provided is a DC current breaker having a high-speed breaking function appropriate to a voltage-type converter and a DC current breaking method. In addition, provided is a DC current breaker and a DC current breaking method capable of reducing cost of the breaker and securing economical competiveness by using a relatively simple configuration.

Abstract: Exemplary apparatuses and methods are provided which provide a safety system that automatically controls charge and discharge of high voltage (HV) capacitors upon application or removal of HV power to a HV system (e.g., a surveillance radar) that includes different timing and sequencing for turn-on/turn operations. In one embodiment, an apparatus and method automatically discharges high voltage (HV) capacitors when HV power is deactivated. Another aspect of an embodiment of the invention automatically deactivates a HV capacitor shunt when the HV system's main HV power is applied or activated. Additionally, an exemplary apparatus requires no human interaction when shunting the HV capacitors, increasing electrical system safety.

Abstract: A control unit supplies power and data through a rotary transformer to a sensor assembly disposed on a wheel. The data sent by the control unit to the sensor assembly is produced by modulation of the power signal using frequency shift key or amplitude shift key modulation. The sensor assembly converts the received power signal that power to operate the circuitry and sensor assembly, converts the FSK or ASK data signal, and sends sensor data back to the control unit through the rotary transformer by load modulation. The control unit demodulates the load modulated sensor data.

Abstract: A boat is disclosed. The boat includes an electrical storage having a storage element electrically connected to a positive and a negative pole. The boat also includes a water sensor configured to determine whether one of the poles is in contact with water, and a disconnection device operatively connected to the water sensor and configured to interrupt the electrical connection between at least one of the poles and the storage element when the water sensor determines that one of the poles is in contact with water.

Abstract: The present disclosure relates to detection of faults in an electric power system. In one embodiment, an incremental quantities subsystem is configured to determine a forward torque, an operating torque, and a reverse torque based on the plurality of time-domain representations of electrical conditions. Each of the forward torque, the operating torque, and the reverse torque may be integrated over an interval. A fault detection subsystem may determine an occurrence of the fault based on a comparison of the operating torque to the forward torque and the reverse torque. Further, a direction of the fault may be determined based on the comparison of the forward torque, the operating torque, and the reverse torque. A fault may be declared based on the comparison and the direction. A protective action subsystem may implement a protective action based on the declaration of the fault.