An active gate driver suitable for activating an electronic switch of an electric motor. The active gate driver comprises a pull up branch, a pull down branch and a current and voltage feedback from an output of the active gate driver to at least one input of the active gate driver, wherein the current and voltage feedback is common to both the pull up branch and the pull down branch.

According to one embodiment, an electronic circuit includes: a first circuit configured to generate a first current and output a first voltage, the first voltage being one of a voltage based on the first current and a first predetermined voltage; a second circuit configured to generate a first output current based on the first voltage; a first output terminal outputting the first output current to a first switching device; a first input terminal having a first input signal inputted, the first input signal relating to driving and non-driving of the first switching device; and a third circuit configured to generate a first control signal based on the first input signal, the first control signal switching the first voltage to the first predetermined voltage and stoping the first current.

Various examples are provided related to semiconductor topologies and devices that can be used for soft starting and active fault protection of power converters. In one example, an active switch device includes an active switch having a gating control input; and a thyristor having a gating control input. The thyristor is coupled in parallel with the active switch. The active switch can be an IGBT, MOSFET, or other appropriate device. In another example, a power converter can include the active switch devices and switching control circuitry coupled to gating control inputs of the active switch devices.

A switch including multiple current branches and slope circuitry. The slope circuitry activates or deactivates the current branches one at a time according to a corresponding one of multiple slope functions in response to a transition of the input signal. Each current branch develops a current so that the output node follows a predetermined voltage-current function. Each slope function is other than a step function and may be linear or non-linear. A slope function may be configured as a current-starved inverter charging or discharging a capacitor with a fixed current. Delay circuitry may be included to delay the inputs or the outputs of the slope circuitry configured as multiple slope control circuits. The slope control circuits may be daisy-chained from first to last to effectuate the delay. Each current branch may include an electronic switch and may further include a resistor to determine the current level.

A switching device includes a first leg having a plurality of transistors connected in series. The switching device also includes a second leg having a transistor, where the second leg is connected in parallel to plurality of transistors of the first leg. The switching device further includes a third leg having a diode, and the third leg has lower reverse recovery losses relative to the first leg and/or the second leg.

A gate driver circuit includes at least one driver configured to generate a first gate control signal for a first power disconnect switch and a second gate control signal for a second power disconnect switch in parallel with the first power disconnect switch, and logic configured to implement a delayed turn on time for the second gate control signal compared to the first gate control signal such that the first power disconnect switch turns on before the second power disconnect switch when powering up a load coupled to the first and the second power disconnect switches. The gate driver circuit logic may also be configured to implement a delayed turn off time such that the first power disconnect switch turns off before the second power disconnect switch when powering down the load. Corresponding power conversion circuits, electronic systems, and methods of power disconnect switch control are also described.

An aspect relates to an apparatus including a first and second power rails; a first set of power switch cells coupled to the first and second power rails, the first set of power switch cells being cascaded from an output to an input of a control circuit; and a second set of power switch cells coupled to the first and second power rails, the second set of power switch cells being coupled to one of a pair of cells of the first set, the first output, and the first input of the control circuit. Another aspect relates to a method including propagating a control signal via a first set of cascaded power switch cells to sequentially couple a first power rail to a second power rail; and propagating the control signal via a second set of power switch cells coupled between a pair of cells of the first set.

A filter circuit includes a first switch circuit that exclusively connects a first common terminal to either of a first selection terminal and a second selection terminal; a first signal terminal that is connected to the first selection terminal and that is for communicating a first communication signal belonging to a first frequency range, which is a frequency range of a first communication band; a second signal terminal that is connected to the second selection terminal and that is for communicating a second communication signal belonging to a second frequency range, which is the frequency range of a second communication band and which is at least partially overlapped with the first frequency range; and a first band pass filter one end of which is connected to the first common terminal and which uses both the first frequency range and the second frequency range as pass bands.

An off chip driving system includes a decision circuit, multiple first and second adjustable-enhancement circuits, and multiple first and second drivers. The decision circuit outputs a first and a second decision signal according to a clock and an input data. Each first adjustable-enhancement circuit generates one of first control signals in response to the first and the second decision signal and one of first optional signals. Each second adjustable-enhancement circuit generates one of second control signals in response to the first and the second decision signal and one of second optional signals. Each first driver is coupled to the corresponding first adjustable-enhancement circuit and configured to be enabled in response to the corresponding first control signal. Each second driver is coupled to the corresponding second adjustable-enhancement circuit and configured to be enabled in response to the corresponding second control signal.

A semiconductor integrated circuit includes: a first voltage line on which a specific one of a power-supply voltage and a reference voltage appears; a second voltage line; a plurality of circuit cells each receiving power generated as a difference between a voltage appearing on the second voltage line and the other one of the power-supply voltage and the reference voltage; a plurality of switch transistors connected in parallel between the first and second voltage lines to serve as switch transistors including switch transistors each having different conducting-state resistances; and a switch conduction control section for controlling a transition of each of the switch transistors from a non-conducting state to a conducting state by turning on the switch transistors at separate points of time.