Abstract: Power modules with reduced parasitic inductances are provided. A power module includes a first substrate including a first electrically-conductive layer and a second substrate including a second electrically-conductive layer. These substrates may be stacked on each other. A scalable network of power switches may be arranged on the substrates. Power bars may be connectable to the electrically-conductive layers through electromechanical interfaces at selectable interface locations. The locations and/or type of interface may be selectable based on the arrangement of the switches. The first and second electrically-conductive layers may be disposed on mutually opposed surfaces of a dielectric layer having a thickness chosen to effect a level of coupling between respective source and return current paths provided by the electrically-conductive layers.

Abstract: A control circuit includes: a first switching element having a source, a gate, and a drain; a battery configured to supply a voltage to the gate through a second switching element; a PWM signal generator circuit configured to supply a PWM signal to the gate through a third switching element; and a gate control circuit configured to, under a power-off condition, turn on the second switching element to supply the voltage of the battery to the gate and turns off the third switching element, and configured to under a power-on condition, turn on the third switching element to supply the PWM signal voltage to the gate and turns off the second switching element.

Abstract: A driver circuit has a detector circuit including a high side detection transistor, a resistor, and a low side detection transistor connected to a high side output transistor and a low side output transistor. A clamping circuit converts a high voltage amplitude change signal generated at a connection point of the high side detection transistor and resistor to a signal clamped to a voltage range applied on the low side. An OR circuit outputs a signal taking the logical sum of an inverted control signal and an output of a low side first stage drive circuit. A level shifter circuit outputs a level-shifted signal of the OR circuit to a high side first stage drive circuit. A second OR circuit outputs a signal wherein the logical sum of an output signal of the clamping circuit and the control signal is inverted to the low side first stage drive circuit.

Abstract: A power circuit. One embodiment provides a circuit for driving a power transistor having a control electrode and a load path. The circuit includes a driver circuit configured to change the power transistor to a completely on or off state with the aid of a control signal supplied to the control electrode. A series circuit includes a semiconductor switching element and a capacitor. The series circuit is connected in parallel with the load path and the capacitor provides a supply voltage for the driver circuit.

Abstract: A load driver includes a switching element connected to a load, a constant current generator that generates a constant current, and a driver circuit that turns on the switching element for an on-period, which depends on a value of the constant current and is shortened with an increase in the value of the constant current. The constant current generator supplies a first constant current having a first current value to the driver circuit during the on-period, and supplies a second constant current having a second current value smaller than the first current value after the on-period has elapsed and the switching element reaches an on state.

Abstract: A switch circuit device includes a switch circuitry and a driver circuitry. The switch circuitry switches an electrical connection between first and second terminals between the on-state and the off-state in response to a set of control signals. The driver circuitry is configured to generate the control signals and includes an N-latch circuit and a leakage current suppression circuitry. The N-latch circuit selectively outputs lower one of two input voltages fed thereto as one of the control signals. The leakage current suppression circuitry suppresses the leakage current through the N-latch circuit.

Abstract: A gate drive circuit which drives a gate terminal of a semiconductor switching device includes: a first wireless signal transmitter which transmits an input first AC signal wirelessly; a second wireless signal transmitter which transmits an input second AC signal wirelessly; a first rectifier circuit which includes a first diode that rectifies an output signal from the first wireless signal transmitter; and a second rectifier circuit which includes a second diode that rectifies an output signal from the second wireless signal transmitter. A threshold voltage of the second diode is larger than a threshold voltage of the first diode.

Abstract: A fast bias circuit including a bias unit, a resistor, a first switch, and a detecting circuit is provided. The resistor has a first terminal coupled to the bias unit to receive a bias voltage, and a second terminal coupled to a bias terminal of a target circuit, wherein the bias terminal is coupled to an input signal. The first switch has a first terminal coupled to the first terminal of the resistor, a second terminal coupled to the second terminal of the resistor, and a control terminal coupled to the detecting circuit. During an initialisation period, the detecting circuit compares the bias voltage with a voltage at the bias terminal of the target circuit to obtain a comparison result, and controls the first switch according to the comparison result. Furthermore, a fast bias method and a bias and load circuit are also provided.

Abstract: A method an apparatus for a power switch acceleration scheme during wakeup is disclosed. In one embodiment, an integrated circuit includes at least one power gated circuit block. The power gated circuit block includes a virtual voltage node from which a voltage is provided to the circuitry of the block when active. Power switches are coupled between the virtual voltage node and a corresponding global voltage node. When the power gated circuit block is powered on, power switches are activated sequentially. The rate at which power switches are activated is increased as the voltage on the virtual voltage node increases. Sequentially activating the power switches may prevent an excess of current inrush into the power gated circuit block. The increase in the rate at which power switches are activated when the voltage on the virtual voltage node is at least at a certain level may allow for a faster wakeup.

Abstract: A gate drive circuit includes a turn-on circuit having an upper limiter for receiving a gate drive signal. The upper limiter has an output terminal. The turn-on circuit also has a transistor having a base connected to the output terminal of the upper limiter. In addition, the terminal has a terminal connected to a gate of a power switching device. The upper limiter limits a voltage input to the base of the transistor to not exceed a first predetermined value.

Abstract: A high frequency switch circuit including: a first rectifier circuit including at least one rectifier element having one end connected between the gate terminal of a first MOSFET circuit and a first control terminal and the other end connected to ground, and a second rectifier circuit including at least one rectifier element having one end connected between the gate terminal of a second MOSFET circuit and a second control terminal and the other end connected to ground. The circuit further includes a connecting section connecting the forward-current input terminal side of at least one of the rectifier elements of the first rectifier circuit and one of the main terminal sides of the first MOSFET circuit, and connecting the forward-current input terminal side of at least one of the rectifier elements of the second rectifier circuit and one of the main terminal sides of the second MOSFET circuit.

Abstract: Apparatus and methods are disclosed related to using one or more field effect transistors as a resistor. One such apparatus can include a field effect transistor (FET), averaging resistors and a bidirectional current source. The averaging resistors can apply an average of a voltage at the source of the FET and a voltage at the drain of the FET to the gate of the field effect transistor. The bidirectional current source can turn the FET on and off. The FET can operate in the ohmic region when on. Such an apparatus can improve the linearity of the FET as a resistor, for example, at lower frequencies near or at direct current (DC). In some implementations, the apparatus can include one or more current sources to remove an offset introduced by the bidirectional current source at the source and/or the drain of the FET.

Abstract: The described FET switch topology greatly reduces the off state loading experienced by the gate biasing resistors in a stacked FET structure. The FET switch topology evenly distributes the voltage across the FET switch topology which reduces the voltage across the gate biasing resistors when the stacked FET structure is in an off state. Because the off state loading is reduced, there is a corresponding reduction of the current through bias resistors, which permits a reduction in the size of the bias resistors. This permits a substantial reduction in the area attributed to the bias resistors in an integrated solution.

Abstract: A switching device for switching a high operating voltage is described. The switching device-includes a first switching arrangement with a first self-conducting switching element), which has a control connector and a first and second main connector for forming a switching section. The switching device may include a second switching arrangement having a first and a second connector for forming a switching section, which is wired serially in respect to the switching section of the first switching arrangement. The second switching arrangement includes an optically triggerable switching element for switching the switching section of the second switching arrangement so it becomes conductive. The second connector of the second switching arrangement is connected with the control connector of the first self-conducting switching element.

Abstract: A drive circuit is provided with a charge pump including a capacitor. The capacitor of the charge pump is configured to be charged in the first stage and to be connected with the gate terminal of the switching device in the second stage. The charge pump is configured to be able to adjust a charging voltage charged in the capacitor according to an order signal.

Abstract: A serial-parallel conversion circuit for converting a high-speed serial signal to a parallel signal is provided. Further, a display device with high image quality and fewer external connection terminals is provided. Furthermore, a method for driving a serial-parallel conversion circuit for converting a high-speed serial signal to a parallel signal is provided. A serial-parallel conversion circuit includes a plurality of units in each of which a sampling switch and an amplifier are connected to each other. In the serial-parallel conversion circuit, each sampling switch is configured to output part of a serial signal to its respective amplifier only through one transistor.

Abstract: A switch circuit is described, where a switch to be controlled is formed of two NMOS transistors having their source terminals connected together and their gate terminals connected together. Their drain terminals are the input and output terminals of the switch. A driver circuit controls a bootstrap circuit that is formed of a latching circuit and a capacitor. When the switch is in an off state, the driver circuit connects the capacitor to a charging voltage source for charging the capacitor to a bootstrap voltage, and applies a non-zero voltage across the latching circuit. When the driver circuit is controlled to turn on the switch, the driver circuit disconnects the capacitor from the charging voltage source, and the latching circuit becomes conductive and effectively connects the capacitor across the gate and source terminals of the switch to turn it on with the bootstrap voltage. The bootstrap voltage across the capacitor maintains the latching circuit in a latched conductive state.

Abstract: A constant current source circuit includes one end connected to a second node as sources of third and fourth transistors, and the other end connected to a second power supply node that supplies a second voltage different from a first voltage. The clamp circuit is configured to form a current path between the second node and the second power supply node. It adjusts the potential of the second node to a certain potential when a first external input signal is switched from a first state to a second state.

Abstract: An ignitor semiconductor apparatus can include an output stage IGBT that controls the ON and OFF of the primary current of ignition coil, a sensing IGBT and a sensing resistance for detecting the current flowing through output stage IGBT, gate resistance and a current control circuit that detects the voltage across sensing resistance and controls the current flowing through output stage IGBT. First and second gate control circuits separately control the gate voltages of IGBT's such that the gate voltage of the output stage IGBT is higher than the gate voltage of the sensing IGBT, when the current flowing through output stage IGBT is larger than a predetermined current value, and such that the gate voltage of output stage IGBT is lower than the gate voltage of sensing IGBT, when the current flowing through output stage IGBT is smaller than the predetermined current value.

Abstract: A semiconductor device arrangement and a method. One embodiment includes at least one power transistor and at least one gate resistor located between a gate of the power transistor and a connecting point in the drive circuit of the power transistor. The semiconductor device arrangement includes a switchable element between the connecting point and a source of the power transistor.

Abstract: Switch circuits are disclosed, for providing a single-ended and a differentially switched high-voltage output signals by switching a high supply voltage in response to at least one logic-level control signal. The switch that provides the single-ended switched high-voltage output signal includes a chain of at least three serially coupled field effect transistors (FETs). The chain receives the high supply voltage and switches it to output the high-voltage output signal. The switch that provides the differentially switched high-voltage output signal includes two differentially coupled chains, each having at least three serially coupled FETs. The chains receive the high supply voltage and switch it to output the differential high-voltage output signal. A control/bias circuit provides a control voltage to at least one of the FETs in the chains, responsive to the control signal.

Abstract: A cascoded input-output device is provided configured to receive at an input node a lower voltage input signal and to generate at an output node a higher voltage output signal. The input-output device is split into two voltage domains to enable output signals in a larger range to be generated, while the components of the input-output device individually operate in a smaller range. By applying a selected bias voltage to a protected node of the cascoded input-output device, first changing that selected bias voltage in response to a transition of the input signal and then switching that selected bias voltage back when the output signal reaches a predetermined level, that node is protected, either avoiding stress-inducing voltage swings or providing a switching speed increasing charge boost.

Abstract: A capacitive load drive circuit may comprise a high current drive amplifier configured to be coupled to a capacitive load during a high current ramp up of the voltage across the capacitive load to a cut off voltage; a low current drive amplifier configured to be connected to the capacitive load during a low current ramp up of the voltage across the capacitive load, from the cut off voltage to a maximum voltage across the capacitive load; and the high current drive amplifier configured to be connected to the capacitive load during a high current ramp down of the voltage across the capacitive load. The low current drive amplifier may be connected to the capacitive load during a period of steady state of the voltage across the capacitive load, intermediate the low current ramp up and the high current ramp down.

Abstract: A control circuit controls a driving transistor connected in series with an electrical load between a power supply voltage and a ground. The control circuit includes a pull-up resistor connected at one end to a power supply voltage side of the driving transistor, a current detection resistor for detecting an electric current flowing from the driving transistor to the ground, a current mirror circuit including a starting transistor connected between the pull-up transistor and the current detection resistor. The current mirror circuit supplies a mirror current of the electric current. The control circuit further includes a current source circuit for supplying a driving current to a control terminal of the driving transistor in accordance with the mirror current to turn ON the driving transistor in response to an external control signal.

Abstract: There is provided a current switching circuit that adds additional current in accordance with an intensity of output current to input current of a current mirror at a rising edge of the output current of the current mirror. The current switching circuit includes a MOS transistor outputting the additional current upon receiving ON potential at a gate terminal, and a slope of a leading edge waveform of a pulse signal providing the ON potential is controlled in accordance with the intensity of the output current.

Abstract: An Internet Protocol (IP) telephone has a constant impedance filter that is capable of being continuously attached to the physical layer of a computer chip in the IP telephone. The constant impedance filter is located outside the physical layer and is connected to a relay on the physical layer. The relay is configured using native FET devices, which are normally conductive without a supply voltage. Therefore, the relay is capable of operating during the discovery mode of IP telephone operation, where no power is applied to the substrate. Rectifier circuits rectify an incoming signal during discovery mode, and apply the rectified signal to the gate of the relay to improve conductivity of the relay. This allows for faster detection of the IP telephone during discovery mode. During normal operation mode, voltage is applied to the physical layer, and the relay is opened by grounding the native devices.

Abstract: A control circuit for controlling a switching device having a first terminal, a second terminal, and a control terminal is disclosed. The control circuit includes a first diode for coupling to the first terminal of the switching device, a second diode for coupling to the second terminal of the switching device, a first transistor for coupling to the control terminal of the switching device, and a second transistor coupled to the second diode. The first transistor is coupled to the first diode. The control circuit is configured to allow current flow in only one direction between the first and second terminals of the switching device.

Abstract: A DC-coupled two-stage gate driver circuit for driving a junction field effect transistor (JFET) is provided. The JFET can be a wide bandgap junction field effect transistor (JFET) such as a SiC JFET. The driver includes a first turn-on circuit, a second turn-on circuit and a pull-down circuit. The driver is configured to accept an input pulse-width modulation (PWM) control signal and generate an output driver signal for driving the gate of the JFET.

Abstract: An integrated circuit device includes a sense amplifier with an input to receive a present signal representing a present bit. The sense amplifier is to produce a decision regarding a logic level of the present bit. The integrated circuit device also includes a circuit to precharge the input of the sense amplifier by applying to the input of the sense amplifier a portion of a previous signal representing a previous bit. The integrated circuit device further includes a latch, coupled to the sense amplifier, to output the logic level.

Abstract: A semiconductor device with less power consumption and an electronic appliance using the same. The semiconductor device of the invention is supplied with a first potential from a high potential power source and a second potential from a low potential power source. Upon input of a first signal to an input node, an output node outputs a second signal. With the semiconductor device of the invention, a potential difference of the second signal can be controlled to be smaller than a potential difference between the first potential and the second potential, thereby power consumption required for charging/discharging wires can be reduced.

Abstract: An exemplary gate driving circuit is adapted for receiving an external gate power supply voltage and an external control signal, sequentially generating multiple internal shift data signal groups and thereby sequentially outputting multiple gate signals. Each of the internal shift data signal groups includes multiple sequentially-generated internal shift data signals. The gate driving circuit includes multiple gate signal generating modules. Each of the gate signal generating modules includes a voltage modulation circuit and a gate output buffer circuit. The voltage modulation circuit modulates the external gate power supply voltage according to a corresponding one of the internal shift data signal groups and the external control signal, and thereby a modulated voltage signal is obtained. The gate output buffer circuit includes a plurality of parallel-coupled output stages. The output stages output the modulated voltage signal as a part of the gate signals during the output stages being sequentially enabled.

Abstract: A control circuit controls a driving transistor connected in series with an electrical load between a power supply voltage and a ground. The control circuit includes a pull-up resistor connected at one end to a power supply voltage side of the driving transistor, a current detection resistor for detecting an electric current flowing from the driving transistor to the ground, a current mirror circuit including a starting transistor connected between the pull-up transistor and the current detection resistor. The current mirror circuit supplies a mirror current of the electric current. The control circuit further includes a current source circuit for supplying a driving current to a control terminal of the driving transistor in accordance with the mirror current to turn ON the driving transistor in response to an external control signal.

Abstract: A gate drive apparatus including a constant-current-pulse gate drive circuit which creates a gate signal for a switching device as a constant-current output, a constant-voltage-pulse gate drive circuit which creates the gate signal as a constant-voltage output, and a decision/switch circuit which switches the operation of the constant-current-pulse gate drive circuit and the operation of the constant-voltage-pulse gate drive circuit. The variance of switching speeds attributed to the variances of threshold voltages and mirror voltages in a plurality of switching devices which are driven by the gate drive apparatus can be suppressed, and the variance of losses can be minimized.

Abstract: In the preferred embodiment, a current source is switchable between two precisely defined output currents. A terminal of a coupling capacitor is coupled to the gate of an output MOSFET. The other terminal of the capacitor is switched between two reference voltages to toggle the MOSFET to output the selected one of the two currents. A switchable bias voltage source is coupled to the gate only during the on state of the MOSFET to set the gate voltage of the MOSFET. The current output of the current source is quickly and accurately changed. A reference MOSFET is not directly coupled to the output MOSFET, so there are no slow settling components coupled to the gate of the output MOSFET.

Abstract: Switch circuits are disclosed, for providing a single-ended and a differentially switched high-voltage output signals by switching a high supply voltage in response to at least one logic-level control signal. The switch that provides the single-ended switched high-voltage output signal includes a chain of at least three serially coupled field effect transistors (FETs). The chain receives the high supply voltage and switches it to output the high-voltage output signal. The switch that provides the differentially switched high-voltage output signal includes two differentially coupled chains, each having at least three serially coupled FETs. The chains receive the high supply voltage and switch it to output the differential high-voltage output signal. A control/bias circuit provides a control voltage to at least one of the FETs in the chains, responsive to the control signal.

Abstract: An integrated regulated current drive circuit for driving a squib of an inflatable airbag has a current sense resistor connected in series with a load, and a reference resistor connected in series with a reference current source. Both resistors are matched to define a precise ratio of resistance values which determines the amount of current fed to the squib. Both resistors are implemented by combining a number of identical on-chip resistor elements.

Abstract: A circuit for processing an analog signal having a time sequence of discrete signal levels, each of which lies in a time interval and represents an information-bearing segment of the interval while the rest of the time interval is a non-information-bearing segment, comprises a transistor in emitter-follower or source-follower configuration, a high emitter or source resistance or, instead, a high-ohm constant current source, and a device for applying a voltage supply, as well as a switch which is connected between the emitter and a reference potential to prevent a current from flowing via the high-ohm resistance or the high-ohm voltage source for charge reversal of an output capacitance of the circuit in one direction, whereas for charge reversal in the other direction the dynamic current boosting effect of the transistor is exploited. This results in a fast emitter-follower or source-follower circuit which is particularly suitable as the output stage for image sensors.

Abstract: A system and method of controlling the primary switching FET turn-on and turn-off profiles in a switching power converter suppresses voltage and current spikes, reduces power consumption, and reduces system switching time. A combination of fast and slow shunt circuits is used to control current flow through the primary switching FET. The FET switching rate is slowed during the period of maximum current change to limit the magnitude of switching spikes and is allowed to proceed rapidly at other times to reduce switching time and power consumption.

Abstract: A method and circuit for providing a switched current source output has a precharge mode, in which a charge storage device is charged to a reference voltage, and the gate of an output transistor is discharged. In a discharge mode, the charge storage device is discharged to the gate of the output transistor to raise the gate voltage by an amount depending on the charge flow.

Abstract: A drive circuit for a power switch component.

Abstract: An enhanced transistor gate drive is disclosed in which a pair of Kelvin sense leads measure the voltage potential across at the gate and source of the transistor. The difference in the voltage potential of the Kelvin sense lead from the gate and the Kelvin sense lead of the source is provided to a voltage controlled current source, which compares the output of the voltage differentiator to an oscillating voltage input. Changes to the voltage difference between the Kelvin sense connectors will result in more or less voltage being applied at the gate of the transistor, thereby parasitic inductance in the transistor from causing the device to switch on and off.

Abstract: A switch includes a switching transistor, a switching resistor, connected between a control terminal of the switching transistor and a switching control terminal, and an accelerating element. The accelerating element includes a resistance smaller than a resistance of the switching resistor, the accelerating element being adapted to be connected in parallel to the switching resistor upon switching of the switching transistor until a voltage at the control terminal of the switching transistor has reached a predetermined value.

Abstract: A switching apparatus and method for detecting an operating state is disclosed. One embodiment has a MOS transistor, a replica of the MOS transistor and an evaluation arrangement and detects the start of switching of the MOS transistor by comparing the gate-source voltages of the transistors.

Abstract: A multiphase receiver to compensate for intersymbol interference in the sampling of an input signal includes a first integrating receiver to integrate and sample data of the input signal on a first phase of a clock and a second integrating receiver to integrate and sample data of the input signal on a second phase of the clock. The multiphase receiver also includes an equalization circuit to adjust integration by the first integrating receiver dependent on a result of integration of data previously received by an integrating receiver distinct from the first integrating receiver, and to adjust integration by the second integrating receiver dependent on a result of integration of data previously received by an integrating receiver distinct from the second integrating receiver.

Abstract: A solid state switch that employs a controller driven input and MOSFET power switching devices is disclosed. The controller can test for a short-circuit on the load side of the MOSFET power switching devices before putting the switch in a sustained conductive state.

Abstract: An apparatus and a method switch a load through a power transistor. The apparatus includes: a first current generator for generating a current to charge a capacitance of a control terminal of the power transistor during power on of the power transistor; a second current generator for generating a current to discharge the capacitance during power off of the power transistor. The apparatus is equipped with control circuitry having a storage element for storing a voltage value representative of the potential difference between the control terminal and a conduction terminal of the power transistor when the power transistor operates in the saturation region and a discharge circuit for generating an additional current to discharge the capacitance during the power-off process. The additional current is a function of the potential difference of the control terminal and the stored voltage value from the conduction terminal.

Abstract: A circuit arrangement configured to drive a load is disclosed herein. The circuit arrangement comprises a first and a second supply potential terminal for application of a first supply potential and a second supply potential. A load terminal is provided between the first and second supply potential for connection of the load. The circuit arrangement further comprises a first transistor component of a first conduction type. The first transistor component includes a load path and a control terminal, with the load path connected between the first supply potential terminal and the load terminal. The circuit arrangement also comprises a freewheeling element. The freewheeling element is provided as a second transistor of a second conduction type connected up as a diode. The second transistor is connected between the load terminal and the second supply potential terminal. The first transistor component and the freewheeling element are integrated in a common semiconductor body.

Abstract: A gate drive circuit includes a turn-on side circuit for turning on a gate of a power switching device, the turn-on side circuit including a first turn-on side power supply circuit and a second turn-on side power supply circuit, the first turn-on side power supply circuit including: a first turn-on voltage source for supplying a first turn-on voltage; first turn-on wiring; and a first turn-on switch connected in the first turn-on wiring and controlled by a gate drive signal; and the second turn-on side power supply circuit including: a second turn-on voltage source for supplying a second turn-on voltage applied to the gate of the power switching device to set the power switching device in a steady (on) state; second turn-on wiring; a second turn-on switch connected in the second turn-on wiring; and a turn-on side delay circuit for delaying the gate drive signal and passing it to the second turn-on switch.

Abstract: This patent specification describes a backflow prevention circuit which includes a first switch configured to conduct or to shut down a current path from an input terminal to an output terminal, a logic circuit configured to binarize an input voltage at the input terminal based on an output voltage at the output terminal and to output a binary signal and a shutdown circuit configured to cause the first switch to shut down independently of a switching control signal in accordance with the binary signal output from the logic circuit. The switching control signal performs a switching control of the first switch. The logic circuit outputs a shutdown signal to shut down independently of the switching control signal when the input voltage becomes smaller than the output voltage.

Abstract: An output buffer circuit has a main driver including a first pMOS transistor and a first nMOS transistor for driving a load, and a second pMOS transistor and a second nMOS transistor for driving the load in coaction with the first pMOS transistor and the first nMOS transistor, and a predriver including a third pMOS transistor and a third nMOS transistor for driving the first pMOS transistor, a fourth pMOS transistor and a fourth nMOS transistor for driving the first nMOS transistor, a fifth nMOS transistor for driving the first pMOS transistor in coaction with the third nMOS transistor, and a fifth pMOS transistor for driving the first nMOS transistor in coaction with the fourth pMOS transistor.