Abstract: In a first embodiment, an ultra-fast breakover diode has a turn on time TON that is less than 0.3 microseconds, where the forward breakover voltage is greater than +400 volts and varies less than one percent per ten degrees Celsius change. In a second embodiment, a breakover diode has a reverse breakdown voltage that is greater, in absolute magnitude, than the forward breakover voltage, where the forward breakover voltage is greater than +400 volts. In a third embodiment, a string of series-connected breakover diode dice is provided, along with a resistor string, in a packaged circuit. The packaged circuit acts like a single breakover diode having a large forward breakover voltage and a comparably large reverse breakdown voltage, even though the packaged circuit includes no discrete high voltage reverse breakdown diode. The packaged circuit is usable to supply a triggering current to a thyristor in a voltage protection circuit.

Abstract: A protection clamp is provided between a first terminal and a second terminal, and includes a multi-gate high electron mobility transistor (HEMT), a current limiting circuit, and a forward trigger control circuit. The multi-gate HEMT includes a drain/source, a source/drain, a first depletion-mode (D-mode) gate, a second D-mode gate, and an enhancement-mode (E-mode) gate disposed between the first and second D-mode gates. The drain/source and the first D-mode gate are connected to the first terminal and the source/drain and the second D-mode gate are connected to the second terminal. The forward trigger control and the current limiting circuits are coupled between the E-mode gate and the first and second terminals, respectively. The forward trigger control circuit provides an activation voltage to the E-mode gate when a voltage of the first terminal exceeds a voltage of the second terminal by a forward trigger voltage.

Abstract: An integrated circuit comprising electro-static discharge (ESD) protection circuitry arranged to provide ESD protection to an external terminal of the integrated circuit. The ESD protection circuitry comprises: a thyristor circuit comprising a first bipolar switching device operably coupled to the external terminal and a second bipolar switching device operably coupled to another external terminal, a collector of the first bipolar switching device being coupled to a base of the second bipolar switching device and a base of the first bipolar switching device being coupled to a collector of the second bipolar switching device. A third bipolar switching device is also provided and operably coupled to the thyristor circuit and has a threshold voltage for triggering the thyristor circuit, the threshold voltage being independently configurable of the thyristor circuit.

Abstract: An electrostatic discharge protection clamp adapted to limit a voltage appearing across protected terminals of an integrated circuit to which the electrostatic discharge protection clamp is coupled is presented. The electrostatic discharge protection clamp includes a substrate, and a first electrostatic discharge protection device formed over the substrate.

Abstract: A bi-directional triode thyristor (TRIAC) device for high voltage electrostatic discharge (ESD) protection may include a substrate, an N+ doped buried layer, an N-type well region and two P-type well regions. The N+ doped buried layer may be disposed proximate to the substrate. The N-type well region may encompass the two P-type well regions such that a portion of the N-type well region is interposed between the two P-type well regions. The P-type well regions may be disposed proximate to the N+ doped buried layer and comprise one or more N+ doped plates and one or more P+ doped plates. The portion of the N-type well region that is interposed between the two P-type well regions may comprise one or more P-type portions, such as a P+ doped plate or a P-type implant.

Abstract: An electrostatic discharge (ESD) protection circuit, methods of fabricating an ESD protection circuit, methods of providing ESD protection, and design structures for an ESD protection circuit. An NFET may be formed in a p-well and a PFET may be formed in an n-well. A butted p-n junction formed between the p-well and n-well results in an NPNP structure that forms an SCR integrated with the NFET and PFET. The NFET, PFET and SCR are configured to collectively protect a pad, such as a power pad, from ESD events. During normal operation, the NFET, PFET, and SCR are biased by an RC-trigger circuit so that the ESD protection circuit is in a high impedance state. During an ESD event while the chip is unpowered, the RC-trigger circuit outputs trigger signals that cause the SCR, NFET, and PFET to enter into conductive states and cooperatively to shunt ESD currents away from the protected pad.

Abstract: The present invention improves the performance of a semiconductor device formed with a triac. A thyristor is formed between a back surface electrode and an electrode by p-type semiconductor regions, an n-type substrate region, p-type semiconductor regions and an n-type semiconductor region. A thyristor is formed therebetween by the p-type semiconductor regions, the n-type substrate region, the p-type semiconductor regions and an n-type semiconductor region. The two thyristors are opposite in the direction of currents flowing between the back surface electrode and the electrode. The p-type semiconductor region of a high impurity concentration is formed so as to be internally included in the p-type semiconductor region of a low impurity concentration. The p-type semiconductor region of a low impurity concentration is interposed between the p-type semiconductor region of a high impurity concentration and the n-type substrate region.

Abstract: An apparatus and method for high voltage transient electrical overstress protection are disclosed. In one embodiment, the apparatus includes an internal circuit electrically connected between a first node and a second node; and a protection circuit electrically connected between the first node and the second node. The protection circuit is configured to protect the internal circuit from transient electrical overstress events while maintaining a relatively high holding voltage upon activation.

Abstract: In one embodiment, a transistor is formed to have a first current flow path to selectively conduct current in both directions through the transistor and to have a second current flow path to selectively conduct current in one direction.

Abstract: A Shockley diode including: a vertical stack of first to fourth layers of alternated conductivity types between first and second electrodes; a recess formed in the fourth layer and extending vertically to penetrate into the second layer; a first region of same conductivity type as the second layer but of greater doping level, extending at the bottom of the recess in the second layer; and a second region of same conductivity type as the third layer but of greater doping level, extending along the lateral walls of the recess and connecting the first region to the fourth layer.

Abstract: A power semiconductor structure with a field effect rectifier having a drain region, a body region, a source region, a gate channel, and a current channel is provided. The body region is substantially located above the drain region. The source region is located in the body region. The gate channel is located in the body region and adjacent to a gate structure. The current channel is located in the body region and is extended from the source region downward to the drain region. The current channel is adjacent to a conductive structure coupled to the source region.

Abstract: The present invention improves the performance of a semiconductor device formed with a triac. A thyristor is formed between a back surface electrode and an electrode by p-type semiconductor regions, an n-type substrate region, p-type semiconductor regions and an n-type semiconductor region. A thyristor is formed therebetween by the p-type semiconductor regions, the n-type substrate region, the p-type semiconductor regions and an n-type semiconductor region. The two thyristors are opposite in the direction of currents flowing between the back surface electrode and the electrode. The p-type semiconductor region of a high impurity concentration is formed so as to be internally included in the p-type semiconductor region of a low impurity concentration. The p-type semiconductor region of a low impurity concentration is interposed between the p-type semiconductor region of a high impurity concentration and the n-type substrate region.

Abstract: In one embodiment, a transistor is formed to have a first current flow path to selectively conduct current in both directions through the transistor and to have a second current flow path to selectively conduct current in one direction.

Abstract: A bidirectional transient voltage suppression device is disclosed. The bi-directional transient voltage suppression device comprises a semiconductor die. The semiconductor die has a multi-layer structure comprising a semiconductor substrate of a first conductivity type, a buried layer of a second conductivity type, an epitaxial layer, and five diffused regions. The buried layer and the semiconductor substrate form a first semiconductor junction. The first diffused region of the second conductivity type and the semiconductor substrate form a second semiconductor junction. The fourth diffused region of the first conductivity type and the third diffused region of the second conductivity type form a third semiconductor junction. The fifth diffused region of the first conductivity type and the second diffused region of the second conductivity type form a fourth semiconductor junction.

Abstract: An HF control bi-directional switch component of the type having its gate referenced to the rear surface formed in the front surface of a peripheral well of the component, including two independent gate regions intended to be respectively connected to terminals of a transformer having a midpoint connected to the rear surface terminal of the component.

Abstract: A thyristor-based semiconductor device includes a thyristor body that has at least one region in the substrate and a thyristor control port in a trenched region of the device substrate. According to an example embodiment of the present invention, the trench is at least partially filled with a dielectric material and a control port adapted to capacitively couple to the at least one thyristor body region in the substrate. In a more specific implementation, the dielectric material includes deposited dielectric material that is adapted to exhibit resistance to voltage-induced stress that thermally-grown dielectric materials generally exhibit. In another implementation, the dielectric material includes thermally-grown dielectric material, and when used in connection with highly-doped material in the trench, grows faster on the highly-doped material than on a sidewall of the trench that faces the at least on thyristor body region in the substrate.

Abstract: A thyristor-based semiconductor device exhibits a relatively increased base-emitter capacitance. According to an example embodiment of the present invention, a base region and an adjacent emitter region of a thyristor are doped such that the emitter region has a lightly-doped portion having a light dopant concentration, relative to the base region. In one embodiment, the thyristor is implemented in a memory circuit, wherein the emitter region is coupled to a reference voltage line and a control port is arranged for capacitively coupling to the thyristor for controlling current flow therein. In another implementation, the thyristor is formed on a buried insulator layer of a silicon-on-insulator (SOI) structure. With these approaches, current flow in the thyristor, e.g., for data storage therein, can be tightly controlled.

Abstract: A semiconductor device includes a thyristor designed to reduce or eliminate manufacturing and operational difficulties commonly experienced in the formation and operation of NDR devices. According to one example embodiment of the present invention, the semiconductor substrate is trenched adjacent a doped or dopable substrate region, which is formed to included at least two vertically-adjacent thyristor regions of different polarity. A capacitively-coupled control port for the thyristor is coupled to at least one of the thyristor regions. The trench also includes a dielectric material for electrically insulating the vertically-adjacent thyristor regions. The thyristor is electrically connected to other circuitry in the device, such as a transistor, and used to form a device, such as a memory cell.