Abstract: An electrostatic discharge (ESD) protection circuit (FIG. 3C) is disclosed. The circuit includes a bipolar transistor (304) having a base, collector, and emitter. Each of a plurality of diodes (308-316) has a first terminal coupled to the base and a second terminal coupled to the collector. The collector is connected to a first terminal (V+). The emitter is connected to a first power supply terminal (V?).

Abstract: An integrated circuit includes a bidirectional ESD device which has a plurality of parallel switch legs. Each switch leg includes a first current switch and a second current switch in a back-to-back configuration. A first current supply node of each first current switch is coupled to a first terminal of the ESD device. A second current supply node of each second current switch is coupled to a second terminal of the ESD device. A first current collection node of each first current switch is coupled to a second current collection node of the corresponding second current switch. The first current collection nodes in each first current switch is not coupled to any other first current collection node, and similarly, the second current collection node in each instance second current switch is not coupled to any other second current collection node.

Abstract: A first silicon controlled rectifier has a breakdown voltage in a first direction and a breakdown voltage in a second direction. A second silicon controlled rectifier has a breakdown voltage with a higher magnitude than the first silicon controlled rectifier in the first direction, and a breakdown voltage with a lower magnitude than the first silicon controlled rectifier in the second direction. A bidirectional electrostatic discharge (ESD) structure utilizes both the first silicon controlled rectifier and the second silicon controlled rectifier to provide bidirectional protection.

Abstract: An ESD cell includes an n+ buried layer (NBL) within a p-epi layer on a substrate. An outer deep trench isolation ring (outer DT ring) includes dielectric sidewalls having a deep n-type diffusion (DEEPN diffusion) ring (DEEPN ring) contacting the dielectric sidewall extending downward to the NBL. The DEEPN ring defines an enclosed p-epi region. A plurality of inner DT structures are within the enclosed p-epi region having dielectric sidewalls and DEEPN diffusions contacting the dielectric sidewalls extending downward from the topside surface to the NBL. The inner DT structures have a sufficiently small spacing with one another so that adjacent DEEPN diffusion regions overlap to form continuous wall of n-type material extending from a first side to a second side of the outer DT ring dividing the enclosed p-epi region into a first and second p-epi region. The first and second p-epi region are connected by the NBL.

Abstract: A surrounded emitter bipolar device includes a substrate having a p-epitaxial (p-epi) layer thereon, and a p-base in the p-epi layer. A two dimensional (2D) grid of p-base contacts (base units) include the p-base, wherein each base unit includes an outer dielectric structure surrounding an inner dielectric isolation ring. The inner dielectric isolation ring surrounds an n region (n+ moat). A first portion of the n+ moats are collector (C) units, and a second portion of the n+ moats are emitter (E) units. The E units are all fully surrounded by C units.

Abstract: A semiconductor controlled rectifier (FIG. 4A) for an integrated circuit is disclosed. The semiconductor controlled rectifier comprises a first lightly doped region (100) having a first conductivity type (N) and a first heavily doped region (108) having a second conductivity type (P) formed within the first lightly doped region. A second lightly doped region (104) having the second conductivity type is formed proximate the first lightly doped region. A second heavily doped region (114) having the first conductivity type is formed within the second lightly doped region. A buried layer (101) having the first conductivity type is formed below the second lightly doped region and electrically connected to the first lightly doped region. A third lightly doped region (102) having the second conductivity type is formed between the second lightly doped region and the third heavily doped region.

Abstract: A segmented bipolar transistor includes a p-base in a semiconductor surface including at least one p-base finger having a base metal/silicide stack including a base metal line that contacts a silicide layer on the semiconductor surface of the p-base finger. An n+ buried layer is under the p-base. A collector includes an n+ sinker extending from the semiconductor surface to the n+ buried layer including a collector finger having a collector metal/silicide stack including a collector metal line that contacts a silicide layer on the semiconductor surface of the collector finger. An n+ emitter has at least one emitter finger including an emitter metal/silicide stack that contacts the silicide layer on the semiconductor surface of the emitter finger. The emitter metal/silicide stack and/or collector metal/silicide stack include segmentation with a gap which cuts a metal line and/or the silicide layer of the stack.

Abstract: An electrostatic discharge (ESD) protection circuit (FIG. 5A) for an integrated circuit is disclosed. The integrated circuit includes a first ESD cell having a current path coupled between a first terminal and a second terminal. A second ESD cell has a current path coupled between the second terminal and a power supply terminal. A passive circuit is connected in parallel with one of the first and second ESD cells.

Abstract: A segmented bipolar transistor includes a p-base in a semiconductor surface including at least one p-base finger having a base metal/silicide stack including a base metal line that contacts a silicide layer on the semiconductor surface of the p-base finger. An n+ buried layer is under the p-base. A collector includes an n+ sinker extending from the semiconductor surface to the n+ buried layer including a collector finger having a collector metal/silicide stack including a collector metal line that contacts a silicide layer on the semiconductor surface of the collector finger. An n+ emitter has at least one emitter finger including an emitter metal/silicide stack that contacts the silicide layer on the semiconductor surface of the emitter finger. The emitter metal/silicide stack and/or collector metal/silicide stack include segmentation with a gap which cuts a metal line and/or the silicide layer of the stack.

Abstract: An electrostatic discharge (ESD) protection circuit (FIG. 3C) is disclosed. The circuit includes a bipolar transistor (304) having a base, collector, and emitter. Each of a plurality of diodes (308-316) has a first terminal coupled to the base and a second terminal coupled to the collector. The collector is connected to a first terminal (V+). The emitter is connected to a first power supply terminal (V?).

Abstract: An electrostatic discharge (ESD) protection circuit (FIG. 2A) for an integrated circuit is disclosed. The circuit is formed on a substrate (P-EPI) having a first conductivity type. A buried layer (NBL 240) having a second conductivity type is formed below a face of the substrate. A first terminal (206) and a second terminal (204) are formed at a face of the substrate. A first ESD protection device (232) has a first current path between the first terminal and the buried layer. A second ESD protection device (216) has a second current path in series with the first current path and between the second terminal and the buried layer.

Abstract: A semiconductor controlled rectifier comprises a first lightly doped region (100) having a first conductivity type (N) and a first heavily doped region (108) having a second conductivity type (P) formed within the first lightly doped region. A second lightly doped region (104) having the second conductivity type is formed proximate the first lightly doped region. A second heavily doped region (114) having the first conductivity type is formed within the second lightly doped region. A buried layer (101) having the first conductivity type is formed below the second lightly doped region and electrically connected to the first lightly doped region. A third lightly doped region (102) having the second conductivity type is formed between the second lightly doped region and the buried layer. A fourth lightly doped region (400) having the second conductivity type is formed between the second lightly doped region and the buried layer.

Abstract: An integrated circuit and method with a bidirectional ESD transistor. A base diffusion separates an emitter diffusion and a collector diffusion. Silicide is blocked from the base diffusion, the emitter-base junction, the collector-base junction, and from equal portions of the emitter diffusion and the collector diffusions.

Abstract: A semiconductor device includes a body and a transistor fabricated into the body. Isolation material at least partially encases the body. Biasing is coupled to the isolation material, wherein the biasing is for changing the electric potential of the isolation material in response to an electrostatic discharge event.

Abstract: A drain extended metal oxide semiconductor (MOS) includes a substrate having a semiconductor. A gate is located on the semiconductor, a source is located on the semiconductor and on one side of the gate, and a drain is located on the semiconductor and on another side of said gate. The MOS includes least one first finger having a first finger drain component located adjacent the drain, the first finger drain component has a silicide layer. At least one second finger has a second finger drain component located adjacent the drain, the second finger drain component has less silicide than the first finger drain component.

Abstract: A bipolar transistor includes a substrate having a semiconductor surface, a first trench enclosure and a second trench enclosure outside the first trench enclosure both at least lined with a dielectric extending downward from the semiconductor surface to a trench depth, where the first trench enclosure defines an inner enclosed area. A base and an emitter formed in the base are within the inner enclosed area. A buried layer is below the trench depth including under the base. A sinker diffusion includes a first portion between the first and second trench enclosures extending from a topside of the semiconductor surface to the buried layer and a second portion within the inner enclosed area, wherein the second portion does not extend to the topside of the semiconductor surface.

Abstract: A bipolar transistor includes a substrate having a semiconductor surface, a first trench enclosure and a second trench enclosure outside the first trench enclosure both at least lined with a dielectric extending downward from the semiconductor surface to a trench depth, where the first trench enclosure defines an inner enclosed area. A base and an emitter formed in the base are within the inner enclosed area. A buried layer is below the trench depth including under the base. A sinker diffusion includes a first portion between the first and second trench enclosures extending from a topside of the semiconductor surface to the buried layer and a second portion within the inner enclosed area, wherein the second portion does not extend to the topside of the semiconductor surface.

Abstract: An integrated circuit contains a voltage protection structure having a diode isolated DENMOS transistor with a guard element proximate to the diode and the DENMOS transistor. The guard element includes an active area coupled to ground. The diode anode is connected to an I/O pad. The diode cathode is connected to the DENMOS drain. The DENMOS source is grounded. A process of forming the integrated circuit is also disclosed.

Abstract: An integrated circuit containing a field controlled diode which includes a p-type channel region between an upper gate and a lower n-type depletion gate, a p-type anode in a p-type anode well abutting the channel region, and an n-type cathode in a p-type anode well abutting the channel region opposite from the anode well. An n-type lower gate link connects the lower gate to the surface of the substrate. A surface control element is located at the surface of the channel region between the cathode and the upper gate. A process of forming the integrated circuit containing the field controlled diode is described.

Abstract: A semiconductor controlled rectifier (FIG. 4A) for an integrated circuit is disclosed. The semiconductor controlled rectifier comprises a first lightly doped region (100) having a first conductivity type (N) and a first heavily doped region (108) having a second conductivity type (P) formed within the first lightly doped region. A second lightly doped region (104) having the second conductivity type is formed proximate the first lightly doped region. A second heavily doped region (114) having the first conductivity type is formed within the second lightly doped region. A buried layer (101) having the first conductivity type is formed below the second lightly doped region and electrically connected to the first lightly doped region. A third lightly doped region (102) having the second conductivity type is formed between the second lightly doped region and the third heavily doped region.