A bidirectional switch module includes a plurality of bidirectional switches and a mount board. Each of the plurality of bidirectional switches includes a first source electrode, a first gate electrode, a second gate electrode, and a second source electrode. On the mount board, the plurality of bidirectional switches are mounted. In the bidirectional switch module, the plurality of bidirectional switches are connected in parallel.

A switch circuit includes first and second transistor stacks coupled in parallel between first and second ports. The first transistor stack includes a first plurality of transistors coupled in series between the first and second ports to provide a first variably-conductive path between the first and second ports. Each transistor of the first plurality of transistors has a gate terminal coupled to a first control terminal. The second transistor stack includes a second plurality of transistors coupled in series between the first and second ports to provide a second variably-conductive path between the first and second ports. Each transistor of the second plurality of transistors has a gate terminal coupled to a second control terminal. When implemented in a transceiver, first and second drivers are configured to simultaneously configure the first and second variably-conductive paths in a low-impedance state.

A high voltage semiconductor device, particularly a device including a number of high breakdown voltage transistors having a common drain, first well, and insulating structure between the gate and the drain as well as method for using the same is provided in this disclosure. The high breakdown voltage transistors in the device together are in an elliptical shape. A second well region, gate structure, and a source region are partially overlapping discontinuous elliptical rings having at least two discontinuities or openings in a top view. The respective discontinuities or openings define each of the high breakdown voltage transistors.

A switch circuit includes first and second transistor stacks coupled in parallel between first and second ports. The first transistor stack includes a first plurality of transistors coupled in series between the first and second ports to provide a first variably-conductive path between the first and second ports. Each transistor of the first plurality of transistors has a gate terminal coupled to a first control terminal. The second transistor stack includes a second plurality of transistors coupled in series between the first and second ports to provide a second variably-conductive path between the first and second ports. Each transistor of the second plurality of transistors has a gate terminal coupled to a second control terminal. When implemented in a transceiver, first and second drivers are configured to simultaneously configure the first and second variably-conductive paths in a low-impedance state.

A semiconductor switching module includes an insulated gate bipolar transistor and a unipolar switching device. The insulated gate bipolar transistor includes a first transistor cell and a supplemental cell, wherein the first transistor cell includes a first gate and a first source and wherein the supplemental cell includes a second gate and a supplemental electrode. The unipolar switching device is based on a wide bandgap material and includes a third gate and a third source. The third gate and the second gate are electrically connected with each other and are disconnected from the first gate. The first source, the supplemental cell and the third source are electrically connected with each other.

A device includes a heterojunction device, a unipolar power transistor operatively connected in series with said hetero junction device; an external control terminal for driving said unipolar power transistor and said heterojunction device; and an interface unit having a plurality of interface terminals. A first interface terminal is operatively connected to an active gate region of the heterojunction device and a second interface terminal is operatively connected to said external control terminal. The heterojunction device includes a threshold voltage less than a threshold voltage of the unipolar power transistor, wherein the threshold voltage of the heterojunction device is less than a blocking voltage of the unipolar power transistor.

A switch system includes a bidirectional switch, a first gate driver circuit, a second gate driver circuit, a control unit, a first decision unit, and a second decision unit. The bidirectional switch includes a first source, a second source, a first gate, and a second gate. The first decision unit determines, based on a voltage at the first gate and a first threshold voltage, a state of the first gate in a first period in which a signal to turn OFF the first gate is output from the control unit to the first gate driver circuit. The second decision unit determines, based on a voltage at the second gate and a second threshold voltage, a state of the second gate in a second period in which a signal to turn OFF the second gate is output from the control unit to the second gate driver circuit.

A high-speed multiplexor comprises a set of differential input pairs to receive and mix a set of differential input signals at a differential output node pair. The high-speed multiplexer further comprises an active inductive load pair driven by the input stage using the mixed set of differential input signals. Each active inductive load comprises a p-channel field effect transistor (pFET) device connected to one of the differential output node pairs and a resistor connected between a gate node and a drain node of the pFET device. The multiplexer further comprises a first cross-coupling capacitor connected between the gate node of a first inductive load and a second output node of the differential output node pair and a second cross-coupling capacitor connected between the gate node of a second inductive load and a first output node of the differential output node pair.

Semiconductor device with multiple independent gates. A gate-controlled semiconductor device includes a first plurality of cells of the semiconductor device configured to be controlled by a primary gate, and a second plurality of cells of the semiconductor device configured to be controlled by an auxiliary gate. The primary gate is electrically isolated from the auxiliary gate, and sources and drains of the semiconductor device are electrically coupled in parallel. The first and second pluralities of cells may be substantially identical in structure.

Semiconductor device with multiple independent gates. A gate-controlled semiconductor device includes a first plurality of cells of the semiconductor device configured to be controlled by a primary gate, and a second plurality of cells of the semiconductor device configured to be controlled by an auxiliary gate. The primary gate is electrically isolated from the auxiliary gate, and sources and drains of the semiconductor device are electrically coupled in parallel. The first and second pluralities of cells may be substantially identical in structure.