A SiC Schottky-barrier diode and a SiPiN diode are connected in parallel. Due to a difference in their thermal properties, a relatively large current flows in the SiPiN diode at a high temperature in which electro migration progresses easily in a solder layer, and the progression of the electro migration is suppressed. At a low temperature in which the electro migration does not progress so much, only a relatively small current flows in the SiPiN diode, and a loss suppression by the SiC Schottky-barrier diode is achieved.

A SiC Schottky-barrier diode and a SiPiN diode are connected in parallel. Due to a difference in their thermal properties, a relatively large current flows in the SiPiN diode at a high temperature in which electro migration progresses easily in a solder layer, and the progression of the electro migration is suppressed. At a low temperature in which the electro migration does not progress so much, only a relatively small current flows in the SiPiN diode, and a loss suppression by the SiC Schottky-barrier diode is achieved.

A five-level converting device includes an AC terminal, a bus capacitor module having a positive terminal, a negative terminal and a neutral terminal, a first switch module and a second switch module. The first switch module includes a bidirectional switching circuit, and the bidirectional switching circuit includes two first switching units reversely connected in series. The second switch module includes two second switching units, two third switching units, two fourth switching units, and two fifth switching units. The two second switching units are cascaded and connected to the two fourth switching units in parallel. The third, the fourth and the fifth switching units are cascaded and are connected to the bus capacitor module in parallel. Two different connection points of the first switch module are connected to the third switching units and fifth switching units through two flying capacitor modules respectively.

A five-level converting device includes an AC terminal, a bus capacitor module having a positive terminal, a negative terminal and a neutral terminal, a first switch module and a second switch module. The first switch module includes a bidirectional switching circuit, and the bidirectional switching circuit includes two first switching units reversely connected in series. The second switch module includes two second switching units, two third switching units, two fourth switching units, and two fifth switching units. The two second switching units are cascaded and connected to the two fourth switching units in parallel. The third, the fourth and the fifth switching units are cascaded and are connected to the bus capacitor module in parallel. Two different connection points of the first switch module are connected to the third switching units and fifth switching units through two flying capacitor modules respectively.

A failure in the activation, of a motor, caused by external noise superimposed on an induced voltage is reduced. A detection circuit is connected to a connection node provided between an upper-arm switching element and a lower-arm switching element, and detects the induced voltage of a fan motor before activation. The switching controller activates the fan motor in accordance with a result of detection by the detection circuit. While the detection circuit detects the induced voltage, the switching controller performs switching control which involves alternately turning ON and OFF of the lower-arm switching element.

A failure in the activation, of a motor, caused by external noise superimposed on an induced voltage is reduced. A detection circuit is connected to a connection node provided between an upper-arm switching element and a lower-arm switching element, and detects the induced voltage of a fan motor before activation. The switching controller activates the fan motor in accordance with a result of detection by the detection circuit. While the detection circuit detects the induced voltage, the switching controller performs switching control which involves alternately turning ON and OFF of the lower-arm switching element.

An image forming apparatus includes a fixing unit that includes a roller and an electric heating wire heater, a current applying circuit that applies electrical current to the electric heater wire heater, a measuring unit electrically connected to the current applying circuit and that measures a value of electrical current that flows through the electric heating wire heater, and a controller that controls the electrical current that flows through the electric heating wire heater by controlling the current applying circuit based on the electrical current value measured by the measuring unit. The controller controls the electrical current to be less than or equal to an electrical current limit value. A magnitude of the electrical current limit value is linked to a magnitude of stable state electrical current.

An image forming apparatus includes a fixing unit that includes a roller and an electric heating wire heater, a current applying circuit that applies electrical current to the electric heater wire heater, a measuring unit electrically connected to the current applying circuit and that measures a value of electrical current that flows through the electric heating wire heater, and a controller that controls the electrical current that flows through the electric heating wire heater by controlling the current applying circuit based on the electrical current value measured by the measuring unit. The controller controls the electrical current to be less than or equal to an electrical current limit value. A magnitude of the electrical current limit value is linked to a magnitude of stable state electrical current.

Systems and methods for electrical power conversion include the provision of a full-bridge tunnel diode inverter topology which provides a balanced push-pull drive voltage and current across the entire transformer primary. Moreover, the full-bridge tunnel diode inverter may avoid operating its tunnel diodes in a high-current/high-voltage state at light loads, unlike a single-diode inverter. The disclosed principles also allow a full-bridge tunnel diode inverter topology that may avoid RF chirps in the tunnel diodes during rising or falling device ramp currents since the primary current passes through two tunnel diodes in series.

A wireless power system including a power supply device configured to generate AC power; a transmitter configured to transmit the AC power generated by the power supply device; and a receiver configured to receive the AC power. The receiver includes a receiving unit to receive AC power through a resonance frequency band from the transmitter; a rectifying unit to rectify the received AC power to DC power; a DC-DC converter to convert the rectified DC power into a specific DC power required by a load; a voltage restricting unit disposed before the load; and a controller to detect a first rectified DC power, which is rectified from the received AC power, that is less than a predetermined threshold to prevent an instant overvoltage from being transferred to the load, to transmit, via a modulation unit through out-of-band communication at a specific frequency band other than the resonant frequency band, a signal to increase the AC power to be received from the transmitter and control the voltage restricting unit to allow the detected first rectified DC power to be transferred to the load in response to the detected first rectified DC power also being less than a charge quantity of the load, to detect a second rectified DC power, which is rectified from the received AC power, that is equal to or greater than the predetermined threshold to prevent the instant overvoltage from being transferred to the load, and to transmit, via the modulation unit, a signal to decrease the AC power to be received from the transmitter and control the voltage restricting unit to prevent the detected second rectified DC power from being transferred to the load in response to the detected second rectified DC power being equal to or greater than the predetermined threshold. Further, the predetermined threshold is different than the charge quantity of the load, and the transmitter includes a transmission resonant coil configured to transmit the AC power through the resonance frequency band to the receiver; and an out-of-band communication module configured to receive the signal from the receiver through the out-of-band communication.