A semiconductor die with high-voltage tolerant electrical overstress circuit architecture is disclosed. One embodiment of the semiconductor die includes a signal pad, a ground pad, a core circuit electrically connected to the signal pad, and a stacked thyristor protection device. The stacked thyristor includes a first thyristor and a resistive thyristor electrically connected in a stack between the signal pad and the ground pad, which enhances the holding voltage of the circuit relatively to an implementation with only the thyristor. Further, the resistive thyristor includes a PNP bipolar transistor and a NPN bipolar transistor that are cross-coupled, and an electrical connection between a collector of the PNP bipolar transistor and a collector of the NPN bipolar transistor. This allows the resistive thyristor to exhibit both thyristor characteristics and resistive characteristics based on a level of current flow.

A short-circuit semiconductor component comprises a semiconductor body, in which a rear-side base region of a first conduction type, an inner region of a second conduction type complementary to the first conduction type, and a front-side base region of the first conduction type are disposed. The rear-side base region is electrically connected to a rear-side electrode with a rear-side electrode width, and the front-side base region is electrically connected to a front-side electrode with a front-side electrode width. A turn-on structure with a turn-on structure width is embedded into the front-side and/or rear-side base region and is covered by the respective electrode. The turn-on structure is configured to be turned on depending on a supplied turn-on signal and to produce, on a one-off basis, an irreversible, low-resistance connection between the two electrodes. The ratio of the turn-on structure width to the respective electrode width is less than 1.

Electrical overstress protection for high speed interfaces are disclosed. In certain embodiments, a semiconductor die with bidirectional protection against electrical overstress is provided. The semiconductor die includes a first pad, a second pad, a forward protection silicon controlled rectifier (SCR) electrically connected between the first pad and the second pad and configured to activate in response to electrical overstress that increases a voltage of the first pad relative to a voltage of the second pad, and a reverse protection SCR electrically connected in parallel with the forward protection SCR between the first pad and the second pad and configured to activate in response to electrical overstress that decreases the voltage of the first pad relative to the voltage of the second pad.

A MOS controlled thyristor device according to the concept of the present invention includes a substrate comprising a first surface and a second surface, which face each other, gate patterns disposed on the first surface, a cathode electrode configured to cover the gate patterns, and an anode electrode disposed on the second surface, The substrate includes a lower emitter layer having a first conductive type, a lower base layer having a second conductive type on the lower emitter layer, an upper base region provided in an upper portion of the lower emitter layer and having a first conductive type, wherein the upper base region is configured to expose a portion of a top surface of the lower base layer, an upper emitter region having a second conductive type and provided in an upper portion of the upper base region, a first doped region having a first conductive type and a second doped region surrounded by the first doped region and having a second conductive type, wherein the first and second doped regions are provided in an upper portion of the upper emitter region, and a first doping pattern having a first conductive type, which is provided on one surface of the upper portion of the upper emitter region. The first doping pattern is interposed between the upper base region and the first doped region along a first direction parallel to the top surface of the substrate. The first doping pattern is configured to expose a top surface of the upper emitter region on the other surface of the upper portion of the upper emitter region. Each of the gate patterns is configured to cover portions of an exposed top surface of the lower base layer, an exposed top surface of the upper base layer, an exposed top surface of the upper emitter region, a top surface of the first doping pattern, and a top surface of the first doped region. The cathode electrode is configured to cover portions of top and side surfaces of the gate pattern, a top surface of the second doped region, and a top surface of the first doped region. The first conductive type and the second conductive type are different from each other.

A semiconductor device includes: a semiconductor layer of a first conductivity type; a first electrode located on the semiconductor layer; a second electrode located on the semiconductor layer; a third electrode located on the semiconductor layer between the first electrode and the second electrode, and separated from them; a first semiconductor region that is located in the semiconductor layer and is of a second conductivity type; a first cathode region of the first conductivity type; a first anode region of the second conductivity type; a second cathode region of the first conductivity type; a second anode region of the second conductivity type; a third anode region of the second conductivity type; a third cathode region of the first conductivity type; a second semiconductor region of the second conductivity type; a fourth anode region of the second conductivity type; and a fourth cathode region of the first conductivity type.

Disclosed is a power semiconductor device comprising a semiconductor wafer having a first main side and second main side. The semiconductor wafer comprises parallel thyristor cells, which each comprises (a) a cathode electrode and gate electrode on the first main side; (b) a cathode layer comprising a cathode region of a first conductivity type, forming an ohmic contact with the cathode electrode; (c) a first base layer of a second conductivity type, wherein the cathode region forms a p-n junction between the first base layer and cathode region; (d) a second base layer of the first conductivity type forming a second p-n junction with the first base layer; (e) an anode layer of the second conductivity type separated from the first base layer by the second base layer. The gate electrodes of the plurality of thyristor cells form a gate design comprising multiple polygons each comprising at least four struts.

An integrated gate-commutated thyristor (IGCT) includes a semiconductor wafer having a first main side and a second main side opposite to the first main side and a plurality of first type thyristor cells and second type thyristor cells. The cathode electrode of the first type thyristor cells forms an ohmic contact with the cathode region and the cathode electrode of the second type thyristor cells is insulated from the cathode region. A predefined percentage of second type thyristor cells of the overall amount of first type thyristor cells and second type thyristor cells in a segment ring is greater than 0% and less than or equal to 75%.

Thyristor semiconductor device comprising an anode region, a first base region and a second base region having opposite types of conductivity, and a cathode region, all superimposed along a vertical axis.

Electrical overstress protection for high speed interfaces are disclosed. In certain embodiments, a semiconductor die with bidirectional protection against electrical overstress is provided. The semiconductor die includes a first pad, a second pad, a forward protection silicon controlled rectifier (SCR) electrically connected between the first pad and the second pad and configured to activate in response to electrical overstress that increases a voltage of the first pad relative to a voltage of the second pad, and a reverse protection SCR electrically connected in parallel with the forward protection SCR between the first pad and the second pad and configured to activate in response to electrical overstress that decreases the voltage of the first pad relative to the voltage of the second pad.

An insulated gate turn-off (IGTO) device, formed as a die, has a layered structure including a p+ layer (e.g., a substrate), an n− epi layer, a p-well, trenched insulated gate regions formed in the p-well, and n+ regions between the gate regions, so that vertical NPN and PNP transistors are formed. The device may be formed of a matrix of cells or may be interdigitated. To turn the device on, a positive voltage is applied to the gate, referenced to the cathode. The cells further contain a vertical p-channel MOSFET, for rapidly turning the device off. The p-channel MOSFET may be made a depletion mode device by implanting boron ions at an angle into the trenches to create a p-channel. This allows the IGTO device to be turned off with a zero gate voltage while in a latch-up condition, when the device is acting like a thyristor.