Abstract: A power conversion device according to one or more embodiments may include: a microcomputer; and an output circuit controlled by the microcomputer, including an output unit that converts an input power into a predetermined power and outputs the predetermined power, an internal power source that supplies a power source to the microcomputer, a driver that drives the output unit by a signal from the microcomputer, and a microcomputer stop transition unit that, when an operation of the power conversion device is stopped, outputs a microcomputer stop signal to the microcomputer and causes an operation of the microcomputer to transition to a stop state. In one or more embodiments, after the microcomputer stop transition unit causes the operation of the microcomputer to transition to a stop state, the microcomputer or the output circuit may stop an output of the internal power source.

Abstract: A non-contact power supply apparatus is disclosed. A power supply DC converter receives electric power and outputs a direct current. An inverter electrically connected to the power supply DC converter generates an alternating current. A coil electrically connected to the inverter allows the alternating current to flow therethrough. The power supply DC converter autonomously controls output power to decrease an output voltage when the direct current increases.

Abstract: A processor is disclosed that performs pipelining which processes a plurality of threads and executes instructions in concurrent processing, the instructions corresponding to thread numbers of the threads and including a branch instruction. The processor may include a pipeline processor, which includes a fetch part that fetches the instruction of the thread having an execution right, and a computation execution part that executes the instruction fetched by the fetch part. The processor may include a branch controller that determines whether to drop an instruction subsequent to the branch instruction within the pipeline processor based on the thread number of the thread where the branch instruction is executed and on the thread number of the subsequent instruction.

Abstract: A semiconductor device substrate including: a substrate; a buffer layer which is provided on the substrate and made of a nitride semiconductor; and a device active layer which is formed of a nitride semiconductor layer provided on the buffer layer, the semiconductor device substrate in that the buffer layer includes: a first region which contains carbon and iron; a second region which is provided on the first region and has average concentration of iron lower than that in the first region and average concentration of carbon higher than that in the first region, and the average concentration of the carbon in the second region is lower than the average concentration of the iron in the first region. The semiconductor device substrate which can suppress a transverse leak current in a high-temperature operation of a device while suppressing a longitudinal leak current and can inhibit a current collapse phenomenon is provided.

Abstract: A current collapse characteristic is sufficiently suppressed. After forming a large opening (first opening) passing through both a TEOS oxide layer 42 and an oxide layer 41, a thin oxide layer (third insulating layer) 43 is formed entirely covering the layers 41 and 42 and the first opening. In the thin oxide layer 43 inside the first opening, a second opening for exposing a group-III nitride semiconductor layer 10 is provided. A gate electrode 50 is formed at a slanted portion of the first opening including the second opening. A taper angle of the first opening is smaller in the TEOS oxide layer 42 than in the oxide layer 41.

Abstract: An alternating-current voltage detection circuit for detecting an alternating-current voltage from an alternating-current power source according to one or more embodiments may include: a rectification circuit that performs full-wave rectification on an alternating-current voltage from the alternating-current power source and supplies a rectified output to a load; a series circuit comprising a first capacitor and a second capacitor electrically connected in series between one end of the alternating-current power source and the ground terminal of the rectification element; a discharge circuit that causes the second capacitor to discharge such that an absolute value of dv/dt voltage does not reach a predetermined voltage, wherein the second capacitor is electrically connected to the ground terminal side of the rectification element; and a predetermined period generator that outputs a signal after an elapse of a predetermined period of time from stoppage of a discharge operation of the discharge circuit.

Abstract: A semiconductor device is disclosed that includes a substrate; a first semiconductor region arranged in the cell region on a first surface side of the substrate; a second semiconductor region arranged in a cell region; a channel stopper electrode arranged in a termination region; a first electrode arranged on the first surface and electrically connected to the second semiconductor region; an insulation film arranged between the channel stopper electrode and the first electrode; first conductors arranged inside the insulation film; second conductors arranged on the insulation film; and a second electrode arranged on a second surface side of the substrate. A width of an overlapping portion in a height direction of the first conductor and the second conductor on the first electrode side is larger than a width of an overlapping portion in the height direction of the first and second conductors on the channel stopper electrode side.

Abstract: An ignition coil includes a first winding, a second winding, and a third winding. A first switch is electrically connected to the first winding. A battery is electrically connected to the first winding. A booster is electrically connected to the battery. A second switch is electrically connected to the third winding. A drive device drives the first switch and the second switch. The drive device turns the first switch from on-state to off-state to allow a secondary current to flow through the second winding, turns the second switch from off-state to on-state to supply an output of the booster to the third winding, and superimpose a second current to the second winding. When a third winding current becomes equal to or greater than a predetermined value, the booster controls such that power generated by the third winding current and an output voltage of the booster is restricted to constant power.

Abstract: A light emitting device includes: a substrate (40); blue light emitting elements (10) arranged on the main surface of the substrate (40); and a phosphor sheet (30) containing a phosphor that is excited by emission light from the blue light emitting elements and emits excitation light, the phosphor sheet (30) being disposed above the blue light emitting elements (30), wherein the blue light emitting elements (10) includes first blue light emitting elements (11) which emit first emission light having a first wavelength taken as a peak wavelength of a light emission spectrum, and second blue light emitting elements (12) which emit second emission light having a second wavelength taken as a peak wavelength of a light emission spectrum, and the second wavelength being a longer wavelength than the first wavelength by a wavelength difference of at least 10 nm.

Abstract: A device and method for controlling a power converter. The device includes an activation terminal configured to obtain a first voltage based on the input voltage; a controlling terminal configured to obtain a second voltage based on the output voltage; and a digital controller configured to obtain a driving power based on the first voltage and/or the second voltage; the digital controller is configured to obtain the driving power at least based on the first voltage when the power converter is stopped. Therefore, a sufficient driving power can be provided for the digital controller even when the power converter is stopped.

Abstract: Circuits and devices are described that provide power to appliances and other devices via a power correction circuit and an LLC converter, which may for example include resonant series converters and flyback converters. The circuits and devices economize on board space, part size and power start up time by separately powering up the controller circuit portion prior to powering up the LLC converter.

Abstract: A power conversion device according to one or more embodiments may include: a microcomputer; and an output circuit controlled by the microcomputer, including an output unit that converts an input power into a predetermined power and outputs the predetermined power, an internal power source that supplies a power source to the microcomputer, a driver that drives the output unit by a signal from the microcomputer, and a microcomputer stop transition unit that, when an operation of the power conversion device is stopped, outputs a microcomputer stop signal to the microcomputer and causes an operation of the microcomputer to transition to a stop state. In one or more embodiments, after the microcomputer stop transition unit causes the operation of the microcomputer to transition to a stop state, the microcomputer or the output circuit may stop an output of the internal power source.

Abstract: A semiconductor device and a method for forming the semiconductor device. The semiconductor device includes: a unipolar component at least including an epitaxial layer; a transition layer connected to the epitaxial layer; and a bypass component connected to the transition layer; the unipolar component and the bypass component are connected in parallel and the transition layer is configured between the unipolar component and the bypass component.

Abstract: A semiconductor device is disclosed that includes a substrate; a first semiconductor region arranged in the cell region on a first surface side of the substrate; a second semiconductor region arranged in a cell region; a channel stopper electrode arranged in a termination region; a first electrode arranged on the first surface and electrically connected to the second semiconductor region; an insulation film arranged between the channel stopper electrode and the first electrode; first conductors arranged inside the insulation film; second conductors arranged on the insulation film; and a second electrode arranged on a second surface side of the substrate. A width of an overlapping portion in a height direction of the first conductor and the second conductor on the first electrode side is larger than a width of an overlapping portion in the height direction of the first and second conductors on the channel stopper electrode side.

Abstract: Circuits and devices are described that provide power to appliances and other devices via a power correction circuit and an LLC converter, which may for example include resonant series converters and flyback converters. The circuits and devices economize on board space, part size and power start up time by separately powering up the controller circuit portion prior to powering up the LLC converter.

Abstract: A trench semiconductor device includes a layer of semiconductor material, an exterior trench pattern formed in the layer of semiconductor material, and an interior trench pattern formed in the layer of semiconductor material, at least partially surrounded by the exterior trench pattern. The exterior trench pattern includes a plurality of exterior trench portions that are each lined with dielectric material and filled with conductive material, and the interior trench pattern includes a plurality of interior trench portions that are each lined with dielectric material and filled with conductive material.

Abstract: A semiconductor device, comprising a nitride semiconductor layer, a switching element, and a driving transistor; the switching element comprises: a first portion of a first electrode formed on the nitride semiconductor layer; a second electrode formed on the nitride semiconductor layer; and a first control electrode formed on the nitride semiconductor layer and located between the first portion of the first electrode and the second electrode; the driving transistor comprises: a second portion of the first electrode formed on the nitride semiconductor layer and connecting the first portions of the adjacent first electrodes to each other; a third electrode formed on the nitride semiconductor layer and transmitting a signal to the first control electrode; and a second control electrode formed on the nitride semiconductor layer and located between the second portion of the first electrode and the third electrode.

Abstract: A device and method for calculating switching time. The device includes: a digital calculator configured to calculate a next on time according to an output voltage signal and an inductor current signal detected during an on period of a switching element and calculate a next off time according to the next on time, an input voltage signal and the output voltage signal; and a signal generator configured to generate a pulse width modulation signal for controlling the switching element, according to the next on time and the next off time. Therefore, a digital controlling manner is provided, not only the number of components and the cost are decreased, but also detection accuracy is improved with a simple structure.

Abstract: A power conversion device may include: a microcomputer; and an output circuit controlled by the microcomputer, including an output unit that converts an input power into a predetermined power and outputs the predetermined power, an internal power source that supplies a power source to the microcomputer, a driver that drives the output unit by a signal from the microcomputer, and a microcomputer stop transition unit that, when an operation of the power conversion device is stopped, outputs a microcomputer stop signal to the microcomputer and causes an operation of the microcomputer to transition to a stop state. In one or more embodiments, after the microcomputer stop transition unit causes the operation of the microcomputer to transition to a stop state, the microcomputer or the output circuit may stop an output of the internal power source.

Abstract: Voltage-dividing resistors are arranged in parallel with a first DC power supply. A first switch is electrically connected to a first resistor and a second resistor and includes a first terminal, a second terminal, and a control terminal. A second switch switches supply of a power voltage from a second DC power supply. A voltage comparator includes a first and a second input terminals. A reference power supply is connected to the first input terminal of the voltage comparator and outputs a reference voltage. The first terminal of the first switch is electrically connected to the second input terminal of the voltage comparator. The control terminal of the first switch is electrically connected to a positive voltage side of the second DC power supply. When the power voltage is supplied to the control terminal, and allows a voltage to be applied to the first and the second resistors.