Abstract: A power supply system includes a first circuit board mounting a power source circuit and an electronic fuse and a second circuit board mounting a power consumption circuit and a switch. When the electronic fuse detects an overcurrent due to a failure occurring in the power consumption circuit, the power supply system immediately cuts out an overcurrent flowing through the power consumption circuit while changing the switch from an open state to a short-circuited state according to a fault signal output from the electronic fuse. Accordingly, it is possible to safely separate the first circuit board and the second circuit board, and therefore it is possible to replace the second circuit board with another circuit board mounting a normal power consumption circuit.

Abstract: For a single input/output circuit, changing an input/output form is enabled by a simple configuration. In the input/output circuit, a circuit section includes power supply terminals and ground terminals. A switching section is switchable between a first state in which a power supply line and a ground line are coupled to one of the power supply terminals and one of the ground terminals and a second state in which the power supply line and the ground line are coupled to the other one of the power supply terminals and the other one of the ground terminals. The circuit section operates as a circuit corresponding to one of an open collector output and an open emitter output in the first state and operates as a circuit corresponding to the other one of the open collector output and the open emitter output in the second state.

Abstract: According to an embodiment, a diagnostic circuit is configured to be coupled to an output terminal of a switching circuit and to a sense terminal of a sense circuit coupled in parallel with the switching circuit. The diagnostic circuit includes a configurable feedback circuit configured to be coupled to the output terminal and the sense terminal. The configurable feedback circuit is configured to receive a select signal, switch a configuration of the configurable feedback circuit between a first mode and a second mode based on the select signal, sink a current from the sense circuit in the first mode, source a current to the sense circuit in the second mode, and balance a voltage difference between the output terminal and the sense terminal in the first mode and in the second mode.

Abstract: In a driver, a dissipating unit dissipates, upon a potential difference between input and output terminals of a switching element being lower than a predetermined potential, electrical charge for overcurrent detection between the input and output terminals. The dissipating unit includes a rectifier having a pair of first and second conductive terminals. The first conductive terminal is connected to the input terminal of the switching element. An overcurrent determiner determines that an overcurrent flows between the input and output terminals of the switching element upon determination that electrical charge has not been dissipated by the dissipating unit despite the change of the switching element from the off state to the on state. A failure determiner determines whether there is a failure in the dissipating unit as a function of a potential at a point on the first electrical path from the failure determiner to the second conductive terminal.

Abstract: A method and circuit are described for detecting an overvoltage condition and using the detection of the overvoltage condition to protect a circuit or component from the overvoltage condition. In one embodiment, an overvoltage protection circuit is used to detect an overvoltage condition on pin driver electronics, the detection of which is powered by the overvoltage condition itself, thus eliminating the need to provide overvoltage protection circuitry that requires power supplies with voltages greater than the pin electronics the overvoltage protection circuit is meant to protect.

Abstract: A safety mechanism for a solar cell group, the safety mechanism constituted of: a signal receiver arranged to assert a permissive signal indicative of reception by the signal receiver of a predetermined signal; an electronically controlled switch arranged to provide in a closed state an effective short circuit across the output of the solar cell group responsive to the absence of the asserted permissive signal of the signal receiver; and a power harvester in communication with the solar cell group and arranged to provide electric power to the signal receiver when the electronically controlled switch is the closed state.

Abstract: A regulating system for an insulated gate bipolar transistor (IGBT) includes a clamping circuit coupled to the IGBT. The IGBT is coupled to a gate driver circuit. The regulating system also includes a feedback channel coupled to the clamping circuit. The feedback channel is configured to transmit signals representative of a conduction state of said clamping circuit. The regulating system further includes at least one gate driver controller coupled to the feedback channel and the gate driver circuit. The gate drive controller is configured to regulate temporal periodicities of the IGBT in an on-condition and an off-condition.

Abstract: A control signal interface circuit includes a line voltage protection circuit coupled to first and second input terminals. The protection circuit provides an input DC voltage across the input terminals within a predetermined range (i.e., 0-10 Vdc) and prevents the application of an input line voltage (i.e., 347 Vac) across the input terminals. A first current source circuit is coupled to the protection circuit, an isolation circuit is coupled to the first current source circuit and a second current source circuit is coupled to the isolation circuit. The first and second current source circuits collectively provide a linear output DC voltage with respect to the input DC voltage. At least one of the first and second current source circuits include circuitry wherein the linear conversion of the input DC voltage to the output DC voltage is independent of the temperature.

Abstract: System and methods are provided for monitoring a state of a switch element connecting a DC power supply to a load. A system includes a transformer having first and second windings, where a first end of the second winding electrically coupled to a first switch node of the switch element. The system also includes a transmit circuit configured for providing a waveform at the first winding and a sensor element having galvanically isolated input and output nodes for inducing a monitor signal at the output nodes in response to a signal at the input nodes. The system further includes a receive circuit coupled to the output nodes and configured for generating one or more output signals in response to the monitor signal. The system also includes capacitor elements for providing DC isolation for the second winding with respect to the first switch node and the sensor element.

Abstract: A battery system is disclosed which includes: first and second battery blocks connected in parallel, each including a plurality of batteries connected in series; a battery state detector detecting voltages of the batteries in either of the second battery blocks. The number of the batteries in the second battery block is smaller than that of the first battery block. The battery state detector is installed integral with the second battery block.

Abstract: A method and circuit are described for detecting an overvoltage condition and using the detection of the overvoltage condition to protect a circuit or component from the overvoltage condition. In one embodiment, an overvoltage protection circuit is used to detect an overvoltage condition on pin driver electronics, the detection of which is powered by the overvoltage condition itself, thus eliminating the need to provide overvoltage protection circuitry that requires power supplies with voltages greater than the pin electronics the overvoltage protection circuit is meant to protect.

Abstract: A battery system is disclosed which includes: first and second battery blocks connected in parallel, each including a plurality of batteries connected in series; a battery state detector detecting voltages of the batteries in either of the second battery blocks. The number of the batteries in the second battery block is smaller than that of the first battery block. The battery state detector is installed integral with the second battery block.

Abstract: A protection circuit includes a diode chip, and a switching device integrated with the diode chip, the switching device being isolated, optically triggered, optically powered, and the diode chip connected between a high side terminal of the switching device and an input to a first inverting amplifier, the diode chip further supplying a current when an overvoltage occurs between a drain and a source of the switching device.

Abstract: A gas discharge lamp power supply having a base, a pair of opposed side walls extending from the base, and opposed first and second end walls extending from the base between the opposed side walls. The first end wall has a sloped wall extending angularly between the side walls, and two input terminals are mounted on the sloped wall. In another embodiment, the power supply has a control with a nonvolatile memory for storing an error code in response to a detected fault condition, thereby permitting the error code to be displayed upon power being removed from and then, subsequently reapplied.

Abstract: The present invention provides a method and apparatus for providing electro-static discharge (ESD) protection between a first and a second circuit node. One embodiment of the ESD protection circuit includes one or more steering diodes that generate electromagnetic radiation and couple the first circuit node to ground in response to a voltage applied to the first circuit node. The ESD protection circuit also includes a latch circuit that couples the first circuit node to ground in response to the electromagnetic radiation generated by the steering diode(s).

Abstract: A rechargeable lithium battery protection device uses an external circuit to control charging or discharging a rechargeable lithium battery for preventing an overcharge or an overdischarge of the battery. The rechargeable lithium battery protection device includes a diagnostic circuit, a light coupling circuit, a balance circuit, and an identifier circuit. The battery diagnostic circuit checks the voltage of the chargeable battery and outputs a detect signal, and then the balance circuit determines whether or not the detect signal is an overcharge signal and discharges the battery. Meanwhile, the light coupling circuit adjusts an impedance of the light coupling circuit according to the detect signal for disconnecting the battery from the external circuit and the identifier circuit provides the position of a battery that sends out the signal.

Abstract: A current balancing circuit includes a voltage detecting circuit having a detecting diode, and a control switch having an input part and an output part, the input part is coupled in series to the detecting diode and disposed opposite to the detecting diode for detecting abnormal and/or reverse voltages and for preventing electric circuits or facilities from being damaged by the abnormal and/or reverse voltages. The input part may be a photodiode having a positive or negative side coupled to the negative or positive side of the detecting diode. A resistor or a divider diode may be used to protect the voltage detecting circuit.

Abstract: A power switching device in an electrical power distribution system on board a helicopter. There is a power switching device that switches on or off the power flow from a main distributor to the consumer. This switching device comprises an overhead panel with a switching means. This device improves the functional safety of electrical and electronic devices in the helicopter by reducing the electromagnetic influence without increasing the weight of the shielding technology and without requiring additional space in the helicopter airframe. With this device there is at least one fuse panel that is in electrical communication with a main distributor. The main distributor has an electrically protective switch which is connected to a power supply connection and a consumer connection. The electronic protective switch is controllable by a control unit which is connected to a control switch on the overhead panel via a fiber optic cable.

Abstract: A power switching device in an electrical power distribution system on board a helicopter. There is a power switching device that switches on or off the power flow from a main distributor to the consumer. This switching device comprises an overhead panel with a switching means. This device improves the functional safety of electrical and electronic devices in the helicopter by reducing the electromagnetic influence without increasing the weight of the shielding technology and without requiring additional space in the helicopter airframe. With this device there is at least one fuse panel that is in electrical communication with a main distributor. The main distributor has an electrically protective switch which is connected to a power supply connection and a consumer connection. The electronic protective switch is controllable by a control unit which is connected to a control switch on the overhead panel via a fiber optic cable.

Abstract: The present invention is a fault tolerant apparatus for regulating the flow of electricity. The apparatus comprises a light radiating circuit which includes a first light source for radiating a first light signal, a second light source for radiating a second light signal and a first light sensor for receiving at least one of the first and second light signals and for generating a first light sensor output signal in response to the first and second light signals. The radiating circuit further includes a control circuit for actuating the first light source to radiate the first light signal when the control circuit receives a control input signal and for actuating the second light source to radiate the second light signal when the control circuit fails to receive the first light sensor output signal from the first light sensor within a predetermined time after the control circuit has received the control input signal.