According to an embodiment, the semiconductor device (100) comprises a semiconductor body (1) with a first side (10) and a second side (20) opposite to the first side. The semiconductor device further comprises a first thyristor structure (I) and a second thyristor structure (II). The second thyristor structure is arranged laterally beside the first thyristor structure. Each of the first and the second thyristor structure comprises a first base region (11a, 11b) at the first side and agate electrode (1a, 1b) on the first side adjoining the assigned first base region. The first base regions of the two thyristor structures are regions of the semiconductor body and are of the same conductivity type. The gate electrodes of the thyristor structures are individually and independently electrically contactable.

An electronic device can include a bidirectional HEMT. In an aspect, the electronic device can include a pair of switch gate and blocking gate electrodes, wherein the switch gate electrodes are not electrically connected to the blocking gate electrodes, and the first blocking, first switch, second blocking, and second switch gate electrodes are on the same die. In another aspect, the electronic device can include shielding structures having different numbers of laterally extending portions. In a further aspect, the electronic device can include a gate electrode and a shielding structure, wherein a portion of the shielding structure defines an opening overlying the gate electrode.

A half-bridge circuit can include a high-side HEMT, a high-side switch transistor, a low-side HEMT, and a low-side switch transistor. The die substrates of the HEMTs can be coupled to the sources of their corresponding switch transistors. In another aspect, a packaged electronic device for a half-bridge circuit can have a design that can use shorter connectors that help to reduce parasitic inductance and resistance. In a further aspect, a packaged electronic device for a half-bridge circuit can include more than one connection along the bottom of the package allows less lead connections along the periphery of the packaged electronic device and can allow for a smaller package.

The present application teaches, inter alia, methods and circuits for operating a B-TRAN (double-base bidirectional bipolar junction transistor). Exemplary base drive circuits provide high-impedance drive to the base contact region on the side of the device instantaneously operating as the collector. (The B TRAN is controlled by applied voltage rather than applied current.) Current signals operate preferred implementations of drive circuits to provide diode-mode turn-on and pre-turnoff operation, as well as a hard ON state with low voltage drop (the transistor-ON state). In some preferred embodiments, self-synchronizing rectifier circuits provide adjustable low voltage for gate drive circuits. In some preferred embodiments, the base drive voltage used to drive the c-base region (on the collector side) is varied while base current at that terminal is monitored, so no more base current than necessary is applied. This solves the difficult challenge of optimizing base drive in a B-TRAN.

A symmetrically-bidirectional bipolar transistor circuit where the two base contact regions are clamped, through a low-voltage diode and a resistive element, to avoid bringing either emitter junction to forward bias. This avoids bipolar gain in the off state, and thereby avoids reduction of the withstand voltage due to bipolar gain.

An apparatus can include a first circuit that is configured to provide electrostatic discharge (ESD) protection against an ESD pulse applied between a first node and a second node. The first circuit includes a series stack of bipolar transistors that are configured to shunt current between the first and second nodes in response to the ESD pulse; and a diode connected in series with the stack of bipolar transistors and configured to lower a snapback holding voltage of the first circuit when shunting current between the first and second nodes.

An electronic device can include a bidirectional HEMT. In an aspect, a packaged electronic device can include the bidirectional HEMT can be part of a die having a die substrate connection that is configured to be at a fixed voltage, electrically connected to drain/source or source/drain depending on current flow through the bidirectional HEMT, or electrically float. In another aspect, the electronic device can include Kelvin connections on both the drain/source and source/drain side of the circuit. In a further embodiment, a circuit can include the bidirectional HEMT, switch transistors, and diodes with breakdown voltages to limit voltage swings at the drain/source and source/drain of the switch transistors.

The present application teaches, inter alia, methods and circuits for operating B-TRANs (double-base bidirectional bipolar junction transistors). Base drive circuits provide high-impedance drive to the base contact region on whichever side of the device is (instantaneously) operating as the collector. (B-TRANs, unlike other bipolar junction transistors, are controlled by applied voltage, not applied current.) Control signals operate preferred drive circuits, providing diode-mode turn-on and pre-turnoff operation, and a hard ON state with a low voltage drop (the transistor-ON state). In some (not necessarily all) preferred embodiments, a self-synchronizing rectifier circuit provides an adjustable low voltage for the gate drive circuit. Also, in some preferred embodiments, the base drive voltage used to drive the c-base region (on the collector side) is varied while monitoring the base current at that terminal, so that no more base current than necessary is applied. This solves the difficult challenge of optimizing base drive in B-TRANs.

The present application teaches, among other innovations, methods and circuits for operating a B-TRAN (double-base bidirectional bipolar junction transistor). A base drive circuit is described which provides high-impedance drive to the base contact region on whichever side of the device is operating as the collector (at a given moment). (The B-TRAN, unlike other bipolar junction transistors, is controlled by applied voltage rather than applied current.) The preferred implementation of the drive circuit is operated by control signals to provide diode-mode turn-on and pre-turnoff operation, as well as a hard ON state with a low voltage drop (the transistor-ON state). In some but not necessarily all preferred embodiments, an adjustable low voltage for the gate drive circuit is provided by a self-synchronizing rectifier circuit. Also, in some but not necessarily all preferred embodiments, the base drive voltage used to drive the c-base region (on the collector side) is varied while the base current at that terminal is monitored, so that no more base current than necessary is applied. This solves the difficult challenge of optimizing base drive in a B-TRAN.

A symmetrically-bidirectional bipolar transistor circuit where the two base contact regions are clamped, through a low-voltage diode and a resistive element, to avoid bringing either emitter junction to forward bias. This avoids bipolar gain in the off state, and thereby avoids reduction of the withstand voltage due to bipolar gain.