In a semiconductor device in the related art, it has been necessary to match the threshold voltage of a power element with the circuit operation of a gate driver; accordingly, it has been difficult to realize the operation of the gate driver most appropriate for the employed power element. According to one embodiment, when a power element is turned off, the semiconductor device monitors the collector voltage of the power element, and increases the number of NMOS transistors that draw out charges from the gate of the power element in a period until the collector voltage becomes lower than the pre-set determination threshold, rather than in the period after the collector voltage becomes lower than the determination threshold.

A switching element drive device that reduces a switching loss while suppressing noise with an inexpensive configuration, is provided. The switching element drive device includes a current sensor configured to measure a load current flowing through a load, a voltage sensor configured to measure an input voltage inputted from a power supply, and a control part configured to output a command value of a gate drive voltage to a gate drive voltage supply part, the gate drive voltage supply part being configured to supply the gate drive voltage for driving a switching element disposed between the power supply and the load, wherein the control part is further configured to determine the command value of the gate drive voltage based on the load current and the input voltage.

An apparatus includes a controller. The controller receives feedback associated with a device powered by a power source. Sampling of the feedback associated with the device is susceptible to noise caused by a power converter in a vicinity of the controller. To achieve more accurate sampling of the feedback, the controller adjusts operation of the power converter during a window of time in which the power source powers the device. The adjusted operation reduces noise caused by the power converter such that, during the window of time in which the operation of the power converter is adjusted, the controller derives one or more accurate sample values from the received feedback.

A switching power-supply device has an inductor, a switching element serially connected to the inductor, a control circuit, which controls on and off of the switching element and performs an output voltage control in any one of a plurality of modes including a continuous mode and a discontinuous mode, and a continuous mode detection circuit, which detects that the output voltage control is performed in the continuous mode when a current flowing through the switching element is equal to or greater than a threshold.

The present invention relates to the control of a DC-DC converter, wherein the gradient of a controlled variable is limited for the control of the DC-DC converter. A maximum current change in the DC-DC converter can be limited by limiting the gradient of the controlled variable in order to optionally prevent dangerous operating states of the DC-DC converter.

A power supply circuit includes an inductor, a power transistor configured to control an inductor current flowing through the inductor, and an integrated circuit driving the power transistor. The integrated circuit includes a first terminal that receives a power supply voltage for operating the integrated circuit, generated according to a variation in the inductor current, a second terminal to which a control electrode of the power transistor is coupled, a first drive circuit configured to drive the power transistor via the second terminal during a first time period to turn on the power transistor, and a second drive circuit configured to drive the power transistor via the second terminal during a second time period to turn on the power transistor, the second time period including at least a part of the first time period, driving capability of the second drive circuit being lower than that of the first drive circuit.

The present disclosure provides a power supply control device. The power supply control device includes an error amplifier, generating an error voltage according to a difference between a feedback voltage and a reference voltage; a slope voltage generation circuit, generating a slope voltage of a lamp waveform according to an inductor current; a reference voltage generation circuit, generating the reference voltage that depends on an output voltage; a first comparator, generating a reset signal by comparing the error voltage and the slope voltage; a second comparator, generating a skip signal by comparing the error voltage and the reference voltage; an oscillator, generating a set signal; and a controller, receiving an input of each of the signals (set, reset and skip) and performing a switching drive of an output stage in either a fixed on-time control operation or a fixed frequency current mode operation.

A control method of a switching circuit, a control circuit of the switching circuit and the switching circuit are provided. The control circuit includes a slope buffer and a first operational amplifier. The slope buffer receives a first voltage reference, and controls slopes of a rising edge and a falling edge to generate a second voltage reference. The first operational amplifier receives an output feedback voltage and a reference voltage, and performs an operational amplification to obtain a compensation voltage. When the first voltage reference has the falling edge, the reference voltage is coupled to the first voltage reference through a first switch, and the second voltage reference is coupled to an output voltage through a second switch. When the first voltage reference has the rising edge, the reference voltage is coupled to the second voltage reference through a third switch.

A power drive circuit includes a power conversion module, a plurality of gate drivers, a waveform processing unit, a control unit, a weighting unit, and a comparator. Each gate driver includes a drive resistance setting value. The waveform processing unit outputs a current absolute value waveform of an AC power. The weighting unit generates a trigger voltage. When the comparator determines that the current absolute value waveform is greater than the trigger voltage, the comparator outputs a slew rate control signal to each of the gate drivers. When the gate driver receives the slew rate control signal, each of the gate drivers decreases the drive resistance setting value of the gate driver.

A power module for operating a vehicle, in particular an electric vehicle and/or a hybrid vehicle, comprising numerous semiconductor components, which form at least one topological switch; an input contact for supplying an input current to the semiconductor components; a control electronics for controlling the semiconductor components, to generate an output current based on the input current; an output contact for outputting the output current; wherein the control electronics is configured to set a gate current for one of the semiconductor components based on one or more status parameters for the semiconductor component.