Abstract: A method includes providing supply voltages to a supply voltage switching circuit that controls routing of the supply voltages to power consuming circuitry associated with the supply voltage switching circuit. The method includes comparing the supply voltages, including using at least one relatively lower precision comparator to compare the supply voltages for a relatively large difference between the supply voltages; and using at least one relatively higher precision comparator to compare the supply voltages for a relatively smaller difference between the supply voltages. The method further includes, based on a result of comparing the supply voltages, selectively coupling the supply voltages to at least one of an isolation well and a power supply rail of the supply voltage switching circuit.

Abstract: An electronic device includes circuitry configured to determine an antenna operation mode for one or more antenna arrays. The circuitry is further configured to control the one or more antenna arrays to operate in a combined antenna mode via a Wilkinson combiner. The circuitry is also configured to control the one or more antenna arrays to operate in an isolated antenna mode via a single-pole, multi-throw switch.

Abstract: A large-power insulated gate switching device (e.g., MOSFET) is used for driving relatively large surges of pulsed power through a load. The switching device has a relatively large gate capacitance which is difficult to quickly discharge. A gate charging and discharging circuit is provided having a bipolar junction transistor (BJT) configured to apply a charging voltage to charge the gate of the switching device where the BJT is configured to also discontinue the application of the charging voltage. An inductive circuit having an inductor is also provided.

Abstract: A radio frequency (RF) switch which comprises an RF domain section having a plurality of RF switching elements. A DC domain section is provided having circuitry configured for controlling the RF switching elements in response to one or more control signals. A resistive load is provided between the RF domain section and the DC domain section. A bypass circuit is configured for selectively bypassing at least a portion of the resistive load.

Abstract: An electronic device includes a transmission interface and a control circuit. The transmission interface includes a signal reference contact and a signal transmission contact. The control circuit is electrically coupled between the signal reference contact and a ground layer, in which the control circuit is configured to selectively conduct the signal reference contact and the ground layer, and when the signal reference contact and the ground layer are conducted, the signal transmission contact is configured to transmit a first signal, and when the signal reference contact the ground layer are not conducted, the signal reference contact is configured to transmit a second signal. A transmission frequency of the second signal is less than a transmission frequency of the first signal.

Abstract: An inverter comprises a first switch coupled to an input of an output filter and a positive dc bus, a second switch coupled to the input of the output filter and a negative dc bus, a first freewheeling apparatus coupled to the first switch, the second switch and ground, a first soft switching network coupled to the first freewheeling apparatus and the first switch, wherein the first soft switching network is configured such that the first switch is of a first zero voltage transition during a turn-on process of the first switch and a second soft switching network coupled to the first freewheeling apparatus and the second switch, wherein the second soft switching network is configured such that the second switch is of a second zero voltage transition during a turn-on process of the second switch.

Abstract: A semiconductor device, according to one possible configuration, includes switching circuits, each switching circuit comprising IGBT chips connected in series and clamping diodes. The semiconductor device also includes a first and a second wiring line and auxiliary emitter lines. The first wiring line and a first auxiliary emitter line connect the emitter terminals of IGBT chips of the first and second switching circuits. The second wiring line and another auxiliary emitter line connect the emitter terminals of the third IGBT chips of the first and second switching circuits. The wiring lines have a large current carrying capacity and a lower resistance value than their respectively connected auxiliary emitter line.

Abstract: A control circuit for reducing a charging time and a method thereof are provided. The charging device includes an input unit configured to receive a control signal indicating that applied power is process power, and a switch configured to cut off a path between a terminal set and a battery while the process power is applied, when the applied power is the process power.

Abstract: An analog switch may be maintained reliably in an off state. The switch comprises: a P-type first transistor having a source, a drain and a gate, a N-type second transistor having a source, a drain and a gate, and a switch control circuit to drive the gates of the first and second transistors. The drain of the first transistor and the source of the second transistor are connected at a first node, and the source of the first transistor and the drain of the second transistor are connected at a second node. When the voltage at the first or second nodes falls outside of a supply voltage range of the switch control circuit, the switch control circuit is operable, in response to a signal to make the switch high impedance, by adjusting the gate voltages of the first transistor and the second transistor.

Abstract: A semiconductor switch includes a plurality of metal-oxide-semiconductor field effect transistors (MOSFETs) and a pad. The MOSFETs are connected in series between a first node and a second node. The pad is provided above one or more of MOSFETs in the plurality without being provided above other MOSFETs in the plurality. The pad is connected to the first node. A value of an off capacitance (as determined without inclusion of any parasitic capacitance between the pad and the MOSFET) for each the MOSFETs under the pad is smaller than a value of an off capacitance of each of MOSFETs not under than the pad.

Abstract: A method, in some embodiments, comprises: receiving a feedback voltage signal generated by a switch-mode power supply; generating an error signal based on a difference between a switching frequency of the switch-mode power supply and a target frequency; and using the error signal to adjust a ripple amplitude of the feedback voltage signal to control said switching frequency in the switch-mode power supply.

Abstract: According to one embodiment, a semiconductor device includes: a voltage line to which a first voltage is applied; a first circuit configured to operate by using the first voltage; and a second circuit configured to control a connection between the voltage line and the first circuit. The second circuit includes: at least one first switch circuit configured to connect the first circuit and the voltage line based on a first control signal; and a second switch circuit including a plurality of switch sections configured to connect the first circuit and the voltage line based on a plurality of second control signals different from the first control signal.

Abstract: The present application is directed to drive arrangement for semiconductor switches and in particular to a method of driving the gate of a switch with pulses corresponding to turn-on and turn-off commands through separate turn-on and turn-off transformers. The application provides a fail safe reset feature, a more efficient turn-on circuit and an energy recovery circuit for recovering energy from the gate upon turn-off. The application also provides a novel arrangement for assembling multiple pulse transformers on a circuit board.

Abstract: First and second external terminals are connected to high-voltage and low-voltage terminals, respectively, of a direct-current voltage source circuit in which first and second direct-current voltage sources are connected in series. A third external terminal is connected to a connecting point between the first and second direct-current voltage sources. A first switching element is connected between the first and fourth external terminals. A second switching element is connected between the fourth and second external terminals. A first AC switch unit includes third and fourth switching elements connected in inverse series between the third and fourth external terminals. A second AC switch unit includes fifth and sixth switching elements connected in inverse series between the third and fourth external terminals. The first and second AC switch units are connected in parallel. The first and second switching elements and the first and second AC switch units are incorporated in one module.

Abstract: A voltage generating circuit includes: (1) a driving unit having an input terminal and an output terminal, wherein the input terminal is configured to receive an input signal, wherein when the input signal is at a first logic level, power is configured to be charged from a first voltage terminal to the output terminal, and when the input signal is at a second logic level, power is configured to be discharged from the output terminal to a second voltage terminal; (2) a first switch configured to couple the second voltage terminal to a capacitance-compensating terminal based on the input signal; (3) a compensating capacitor configured to be coupled between the capacitance-compensating terminal and a third voltage terminal; and (4) a second switch configured to couple the capacitance-compensating terminal to a fourth voltage terminal based on the input signal.

Abstract: A circuit for protecting a voltage supply to a sensor from a transient event is provided. The circuit includes at least one buffer capacitor configured to provide output during the transient event, the output substantially equivalent to output of a regulated supply during normal operation of the sensor. A method of fabrication and a sensor are disclosed.

Abstract: A device for use with non-volatile memory, includes a first transistor of a first channel type coupled between first and second nodes, including a control gate supplied with a first control signal having a first phase, a second transistor of a second channel type different from the first channel type including a first terminal coupled to the first node, a second terminal coupled to a third node, a back gate coupled to the first terminal thereof, and a control gate supplied with a second control signal having a second phase substantially opposite to the first phase, a third transistor of the second channel type including a first terminal coupled to the second node, a second terminal coupled to the third node, a back gate coupled to the first terminal thereof, and a control gate supplied with the second control signal, and a protection circuit coupled between the first and second node.

Abstract: Gate drive faults are detected for an inverter which comprises a phase switch having an insulated gate, such as an IGBT. A complementary transistor pair is adapted to receive a supply voltage and a pulse-width modulated (PWM) signal to alternately charge and discharge the insulated gate. A comparator compares the voltage at the insulated gate with a reference voltage representing a gate drive fault to generate a first logic signal. A latch samples the first logic signal when the PWM signal has a value corresponding to charging the insulated gate. A logic circuit inhibits charging of the insulated gate when the latched logic signal indicates the gate drive fault. An insulated gate voltage less than the reference voltage is indicative of an under-voltage fault as well as other device failures of the IGBT or the complementary transistors.

Abstract: A high electron mobility transistor includes a buffer region and a barrier region adjoining and extending along the buffer region, the buffer and barrier regions are formed from semiconductor materials having different band-gaps and form an electrically conductive channel from a two-dimensional charge carrier gas. A gate structure is configured to control a conduction state of the channel and includes an electrically conductive gate electrode, a first doped semiconductor region, a second doped semiconductor region, and a resistor. The first doped semiconductor region is in direct electrical contact with a first section of the gate electrode. The second doped semiconductor region is in direct electrical contact with a second section of the gate electrode. The first and second doped semiconductor regions form a p-n junction with one another. The first and second sections of the gate electrode are electrically coupled to one another by the resistor.

Abstract: In one embodiment, method of generating a control signal for an isolated power supply, can include: (i) generating a first ground noise component with a first predetermined proportionality to a ground noise signal; (ii) generating a first peak signal based on a first control signal having the ground noise signal, where the first peak signal comprises a second ground noise component with a second predetermined proportionality to the ground noise signal; (iii) generating a second control signal based on a difference between the first peak signal and the first ground noise component; and (iv) controlling, by the second control signal, a switch of the isolated power supply.

Abstract: A system includes an inverter element to gate forward current flow from a first signal source, and a reverse current inhibition element to block reverse current flow towards the first signal source from a second signal source.

Abstract: The present invention provides a semiconductor device of a bi-directional analog switch having a high linearity and a low electric power loss. An ultrasonic diagnostic apparatus having a high degree of detection accuracy, comprising the semiconductor device, is also provided. A semiconductor device of a bi-directional analog switch, comprising a switch circuit capable of switching ON or OFF bi-directionally, and built-in driving circuits for the switch circuit, wherein the driving circuit is connected to first and second power supplies, and a first power supply voltage is higher than a maximum voltage of a signal applied to an input/output terminal of the switch circuit, a second power supply voltage is lower than a minimum voltage of a signal applied to an input/output terminal of the switch circuit, and the driving circuit comprises a Zener diode and a p-type MOSFET connected in series between the first power supply and the switch circuit.

Abstract: A bidirectional switch circuit includes two switching elements connected to conduct a current in both directions. The two switching elements are connected in series to each other. Of the two switching elements, the switching element to which a reverse voltage is applied, a voltage of a source of one of the switching elements being higher than a voltage of a drain of the one, is configured to conduct a current from the source to the drain even when an on-drive signal is not being input to a gate terminal of the one.

Abstract: A wake up circuit includes a bias signal control block configured to receive a sleep signal and to generate a plurality of bias control signals. The wake up circuit further includes a bias supply block configured to receive each bias control signal of the plurality of bias control signals and to generate a header bias signal. The bias supply block includes a first bias stage configured to receive a first bias control signal of the plurality of bias control signals, and to control the header bias signal to be equal to a first voltage. The bias supply block further includes a second bias stage configured to receive a second bias control signal of the plurality of bias control signals, and to control the header bias signal to be equal to a second voltage different from the first voltage. The wake up circuit further includes a header configured to receive the header bias signal, and to selectively connect a supply voltage to a load based on the header bias signal.

Abstract: A description is given of a method for the pulsed control of a transistor which has a control terminal and a load path. The load path of the transistor is connected in series with a load. A control circuit is provided for a transistor. In the method, the transistor is controlled with a control pulse of a first type, which has a first control level at least for a first time duration, before a control pulse of a second type, which has a second control level, which is higher in comparison with the first control level. A voltage across the load path of the transistor is evaluated and the pulsed control is terminated if the voltage across the load path exceeds a predefined threshold value.

Abstract: In an embodiment, a switching circuit includes input drain, source and gate nodes, a high voltage depletion mode transistor including a current path coupled in series with a current path of a low voltage enhancement mode transistor, and a current sense circuit for sensing the current flowing through a current sense path.

Abstract: Methods and systems to adjust a resistance between a supply grid and a power-gated grid during an active state of a power-gated circuitry in response to load changes in the circuitry to maintain a relatively consistent IR droop. Subsets of power gates (PGs) may be selectively enabled and disabled based on changes in a load factor, such as a voltage, which may be monitored at a gated power distribution grid and/or proximate to a transistor gate within the power-gated circuitry. The adjusting may be performed to minimize a difference between the monitored voltage and a reference, such as with successive approximation or CMS software. PG subsets may be distributed within one or more layers of an integrated circuit (IC) die and may be selectively enabled/disabled based on location. PGs may be embedded within lower layers of an integrated circuit (IC) die, such as within metal layers of the IC die.

Abstract: An electronic apparatus includes a switching element which has a control terminal and is driven by controlling voltage of the control terminal, a driving power supply circuit which supplies voltage required for driving the switching element, an on-driving circuit which is connected to the driving power supply circuit and the control terminal of the switching element and is supplied with voltage from the driving power supply circuit, and which applies a constant current to the control terminal of the switching element to charge the control terminal, thereby turning on the switching element, and at least one diode which is connected between the on-driving circuit and the control terminal of the switching element. The on-driving circuit applies a constant current to the control terminal of the switching element through the diode.

Abstract: A transistor being one of an IGBT and a MOSFET and arranged near a gate control circuit applies a gate control signal from the gate control circuit to the gate of a transistor arranged far from the gate control circuit. A gate control signal is applied via a resistive element to the transistor arranged near the gate control circuit.

Abstract: A gate drive circuit is disclosed that charges the gate of a switching transistor to a voltage that is high enough to turn the switching transistor fully on and then prevent the charge from flowing back into the gate drive circuit. The gate drive circuit works with a ground rectifier switch by providing a fully differential connection of the switching transistor and its capacitor and resistor in parallel with the antenna.

Abstract: A circuit arrangement including a first transistor, a second transistor and a third transistor. The first transistor and the second transistor are configured so that the current flowing through the first transistor is proportional to the current flowing through the second transistor and the third transistor. The first transistor, the second transistor and the third transistor are configured to operate in an ohmic mode. The second transistor and the third transistor are coupled in series to each other. The first transistor, the second transistor and the third transistor match each other in at least one characteristic.

Abstract: A method and apparatus for current drain switching with a replica loop. The method comprises the steps of: matching a voltage across a current sense resistor with a voltage created by a reference current across a matched reference resistor; replicating an operating point of an output transistor using a scaled matched replica of the output transistor and the current sense resistor. The method then shifts a feedback voltage from the output sense resistor to the matched replica sensor and shifts the output of a gate from an output transistor to the replica transistor. A first switch is then actuated in order to preserve the gate charge of the output transistor. A second switch is actuated to sample and hold a drain voltage in the buffer in order to bias the drain of the replica transistor. A third switch is then activated to stop the output current.

Abstract: A gate driving circuit may include: a bias unit receiving an input signal having preset high and low signal levels, including a first N-MOSFET turned on in the case in which the input signal has the high level and a first P-MOSFET turned on in the case in which the input signal has the low level, and supplying bias powers by the turning-on of the first N-MOSFET and the first P-MOSFET; and an amplifying unit including a second N-MOSFET turned on by receiving the bias power supplied from the first N-MOSFET in the case in which the input signal has the high level and a second P-MOSFET turned on by receiving the bias power supplied from the first P-MOSFET turned on in the case in which the input signal has the low level and providing a gate signal depending on the turning-on of the second N-MOSFET and the second P-MOSFET.

Abstract: In an embodiment, a switching circuit includes input drain, source and gate nodes, a high voltage depletion mode transistor including a current path coupled in series with a current path of a low voltage enhancement mode transistor, and a current sense circuit for sensing the current flowing through a current sense path.

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 output driver circuit includes first, second, third, and fourth transistors having a common current path, wherein a gate of the first transistor receives a first switching signal, a gate of the second transistor receives a first reference voltage, a gate of the third transistor receives a second reference voltage, and a gate of the fourth transistor receives a second switching signal, and wherein a first capacitor is coupled between the gate of the first transistor and the gate of the third transistor, a second capacitor is coupled between the gate of the second transistor and the gate of the fourth transistor, and an output signal is provided at a node coupling the second and third transistors.

Abstract: Various embodiments of circuits configured to improve second order harmonic distortion of Metal Oxide Semiconductor (MOS) transistors operating in linear region are provided. In one embodiment, a circuit includes an averaging circuit configured to average signals at a drain and a source of a MOS transistor and provide the averaged signal to a gate of the MOS transistor, and one or more current sources coupled with the gate; the circuit is configured to vary voltage at the gate so as to vary a resistance of the MOS transistor. The averaging circuit comprises a first MOS circuit coupled between the drain and the gate, a first capacitor coupled in parallel to the first MOS circuit between the drain and the gate, a second MOS circuit coupled between the source and the gate, and a second capacitor coupled in parallel to the second MOS circuit between the source and the gate.

Abstract: According to an embodiment, a solid-state switching device includes a high-voltage switching transistor including a source, a drain and a gate, and being adapted for switching a high voltage on the basis of a switching signal, and a switching driver circuit operationally connected to the high-voltage switching transistor, the switching driver circuit including a low-voltage driver transistor including a source, a drain and a gate, connected in series to the high-voltage switching transistor and being adapted for transferring the switching signal to the high-voltage switching transistor, wherein the high-voltage switching transistor is arranged source-down on top of the drain of the low-voltage driver transistor.

Abstract: A pass gate circuit includes a first transistor coupled between an input node (receiving an input signal) and an output node (outputting an output signal). A second transistor is configured to generate a voltage difference in response to a bias current flowing therethrough, wherein that voltage difference is applied between a first gate of the first transistor and the output node. A differential amplifier functions to compare the voltage at the output node to a reference voltage and generate the bias current in response to that comparison.

Abstract: In a bidirectional switch using a metal-oxide-semiconductor field-effect transistor (MOSFET), the source terminal and the backgate terminal of the MOSFET are connected to each other via a transfer gate. A switch may be used between the connection point of the backgate terminal and the transfer gate of the MOSFET and the ground potential (where the MOSFET is an n-channel type) or supply potential (where the MOSFET is a p-channel type).

Abstract: A control voltage is generated at a control input of a semiconductor circuit breaker by an actuation circuit at switching flanks of a switching signal, said control voltage having a profile which is flattened in relation to the profile of the switching signal. With the disclosed method, the switching losses in a semiconductor circuit breaker are reduced. By defining a value for a switching parameter of a control device of the actuation circuit, the switching behavior of the actuation circuit can be influenced by the switching parameter. A specific parameter value of the switching parameter can be varied during operation of the actuation circuit.

Abstract: There are disclosed herein various implementations of nested composite switches. In one implementation, a nested composite switch includes a normally ON primary transistor coupled to a composite switch. The composite switch includes a low voltage (LV) transistor cascoded with an intermediate transistor having a breakdown voltage greater than the LV transistor and less than the normally ON primary transistor. In one implementation, the normally on primary transistor may be a group III-V transistor and the LV transistor may be an LV group IV transistor.

Abstract: Signal distribution circuitry for use in an integrated circuit, the signal distribution circuitry comprising: first and second output nodes, for connection to respective output signal lines; first and second supply nodes for connection to respective high and low voltage sources; and switching circuitry connected to the first and second output nodes and the first and second supply nodes and operable based on an input signal to conductively connect the first and second output nodes either to the first and second supply nodes, respectively, in a first state when the input signal has a first value, or to each other, in a second state when the input signal has a second value different from the first value, so as to transmit output signals dependent on the input signal via such output signal lines.

Abstract: A half bridge is described with at least one transistor having a channel that is capable in a first mode of operation of blocking a substantial voltage in at least one direction, in a second mode of operation of conducting substantial current in one direction through the channel and in a third mode of operation of conducting substantial current in an opposite direction through the channel. The half bridge can have two circuits with such a transistor.

Abstract: Embodiments provide a switching device including one or more field-effect transistors (FETs). In embodiments, a negative bias circuit is configured to generate a negative voltage signal based on a radio frequency (RF) signal applied to the circuit. When the FET is in an off state, the negative voltage signal is provided to a gate terminal of the FET.

Abstract: Radio-frequency (RF) switch circuits are disclosed providing improved switching performance. An RF switch system includes at least one field-effect transistor (FET) disposed between a first node and a second node, each having a respective source, drain, gate, and body. The system includes a coupling circuit including a first path and a second path, the first path being between the respective source or the respective drain and the respective gate of the at least one FET, the second path being between the respective source or the respective drain and the respective body of the at least one FET. The coupling circuit may be configured to allow discharge of interface charge from either or both of the coupled gate and body.

Abstract: A signal output circuit includes: an output buffer including a first terminal configured to output a first output signal; a first output terminal; a first switch inserted on a signal path from the first terminal to the first output terminal; and a second switch configured to transmit a predetermined voltage to the first output terminal when being turned on.

Abstract: There is provided a radio frequency switch circuit including a first switch circuit unit connected between a first node connected to a first signal port and a common node connected to a common port, and operated according to a first control signal, a second switch circuit unit connected between a second node connected to a second signal port and the common node and operated according to a second control signal having a phase opposite to that of the first control signal, a first shunt circuit unit connected between the second node and a common source node and operated according to the first control signal, a second shunt circuit unit connected between the first node and the common source node, and a source voltage generating unit generating a source voltage, wherein the source voltage is lower than a high level of the first control signal and higher than a ground potential.

Abstract: A power module includes an IGBT; a MOSFET connected in parallel with the IGBT; a lead frame having a first frame portion on which the IGBT is mounted and a second frame portion on which the MOSFET is mounted, and having a step by which the first frame portion is located at a first height and the second frame portion is located at a second height larger than the first height; and an insulation sheet for a heat sink which is disposed on an underside of only the first frame portion of the lead frame.

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.