Abstract: An off chip driver structure includes a plurality of pull-up transistors, a plurality of pull-down transistors, a plurality of first regions of a first type, a plurality of second regions of a second type and a plurality of resistor components. The first regions and the second regions are staggered to form an electrostatic discharge (ESD) component. One of the resistor components is coupled to one of the pull-up transistors or one of the pull-down transistors, the resistor components are arranged between the first regions and the second regions.

Abstract: A semiconductor integrated circuit for a regulator includes an output controlling transistor, a controller circuit, a breeder resister and a current limiting resistor. The output controlling transistor is connected between an output terminal and a voltage input terminal. The breeder resister is connected between the output terminal and a constant potential point and generates the feedback voltage. The current limiting resistor is connected with the breeder resistor between the output terminal and the constant potential point.

Abstract: A semiconductor component includes a semiconductor substrate, and a doped well having a well terminal and a transistor structure having at least one potential terminal formed in the semiconductor substrate. The transistor structure has a parasitic thyristor, and is at least partly arranged in the doped well. The potential terminal and the well terminal are connected via a resistor.

Abstract: A circuit internal to a programmable integrated circuit for preventing laser interrogation of the programmable integrated circuit includes a sense resistor connected between a deep n-well and a source of bias voltage for the deep n-well. A voltage-sensing circuit is coupled across the sense resistor to measure voltage across the sense resistor. A tamper trigger circuit responsive to the voltage sensing circuit generates a tamper signal in response to a voltage sensed in the voltage sensing circuit having a magnitude greater than a threshold value.

Abstract: An ESD protection device, which is arranged to be active at a triggering voltage (Vt1) for providing ESD protection, comprises a first region of the first conductivity type formed in a semiconductor layer of the first conductivity type, the first region extending from a surface of the semiconductor layer and being coupled to a first current electrode (C) of the semiconductor device, a well region of a second conductivity type formed in the semiconductor layer extending from the surface of the semiconductor layer, and a second region of the second conductivity type formed in the well region, the second region being coupled to a second current electrode (B). The ESD protection device further comprises a floating region of the second conductivity type formed in the semiconductor layer between the first current electrode (C) and the well region and extending from the surface of the semiconductor layer a predetermined depth.

Abstract: Protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a first base region of semiconductor material having a first conductivity type, a second base region of semiconductor material having the first conductivity type and a dopant concentration that is less than the first base region, a third base region of semiconductor material having the first conductivity type and a dopant concentration that is greater than the second base region, an emitter region of semiconductor material having a second conductivity type opposite the first conductivity type within the first base region, and a collector region of semiconductor material having the second conductivity type. At least a portion of the second base region resides between the third base region and the first base region and at least a portion of the first base region resides between the emitter region and the collector region.

Abstract: A semiconductor component includes a semiconductor substrate, and a doped well having a well terminal and a transistor structure having at least one potential terminal formed in the semiconductor substrate. The transistor structure has a parasitic thyristor, and is at least partly arranged in the doped well. The potential terminal and the well terminal are connected via a resistor.

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: 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 transient voltage suppressor without leakage current is disclosed, which comprises a P-substrate. There is an N-type epitaxial layer formed on the P-substrate, and a first N-heavily doped area, a first P-heavily doped area, an electrostatic discharge (ESD) device and at least one deep isolation trench are formed in the N-epitaxial layer. A first N-buried area is formed in the bottom of the N-epitaxial layer to neighbor the P-substrate and located below the first N-heavily doped area and the first P-heavily doped area. The ESD device is coupled to the first N-heavily doped area. The deep isolation trench is not only adjacent to the first N-heavily doped area, but has a depth greater than a depth of the first N-buried area, thereby separating the first N-buried area and the ESD device.

Abstract: According to one embodiment, a semiconductor device that has a rectification element includes a semiconductor substrate, a first well region of a first conductivity type formed on the semiconductor substrate, a second well region of a second conductivity type formed on the semiconductor substrate, and a plurality of fins arranged over the first well region and the second well region at a first pitch in the same direction. In the semiconductor device, the rectification element includes a cathode region, an anode region, a well contact region, and a trigger region that are configured using fins. These regions are connected to each wiring portion to form a PNP-type bipolar transistor and an NPN-type bipolar transistor.

Abstract: Electrostatic discharge (ESD) protection is provided for discharging current between input and output nodes. In accordance with various embodiments, an ESD protection device includes an open-base transistor having an emitter connected to the input node and a collector connected to pass current to the output node via a resistor in response to a voltage at the input node exceeding a threshold that causes the transistor to break down. The resistor is coupled across emitter and collector regions of a second open-base transistor that is configured to turn on for passing current in response to the current across the resistor exceeding a threshold that applies a threshold breakdown voltage across the second transistor. In some implementations, an emitter and/or base of the second transistor are connected to, or are respectively the same region as, a base and a collector of the first transistor.

Abstract: An area-efficient, high voltage, single polarity ESD protection device (300) is provided which includes an p-type substrate (303); a first p-well (308-1) formed in the substrate and sized to contain n+ and p+ contact regions (310, 312) that are connected to a cathode terminal; a second, separate p-well (308-2) formed in the substrate and sized to contain only a p+ contact region (311) that is connected to an anode terminal; and an electrically floating n-type isolation structure (304, 306, 307-2) formed in the substrate to surround and separate the first and second semiconductor regions. When a positive voltage exceeding a triggering voltage level is applied to the cathode and anode terminals, the ESD protection device triggers an inherent thyristor into a snap-back mode to provide a low impedance path through the structure for discharging the ESD current.

Abstract: A light emitting device is provided. The light emitting device includes a light emitting structure including a first conductive semiconductor layer, an active layer, and a second conductive semiconductor layer, a first dielectric layer over a cavity where a part of the light emitting structure is removed, a second electrode layer over the first dielectric layer, a second dielectric layer over the light emitting structure above the cavity, and a first electrode over the second dielectric layer.

Abstract: A system and methods are provided for triggering an operating device. In one embodiment, a triggering device includes a receiving unit configured to receive one or more wireless control signals. The receiving unit may include a switch and a processor, wherein the processor is configured to control the switch for activation of an operating device coupled to a signaling line based, at least in part, on the one or more wireless control signals. According to another embodiment, the triggering device may include a connector configured to electrically couple the receiving unit to the signaling line, the connector having one or more contacts and a housing configured to clasp the signaling line and couple the one or more contacts to the signaling line. Additionally, the signaling line may relate to existing wiring of the operating device.

Abstract: High- and low-side surface voltage sustaining regions are produced utilizing optimum surface variation lateral doping. Schottky junctions are formed by depositing metal (M) on an n-type region having the lowest potential, taking M as the anode AL or AH of the Schottky diode, and ohmic contact is formed at the portion having the highest potential, taken as the cathode KL or KH of the Schottky diode. The potentials refer to a reverse bias applied to the Schottky diode. Each voltage-sustaining region is isolated and can be divided into several sections with isolation region inserted between them. A Schottky diode is formed in each section and connected to each other in series. A lateral Schottky diode and an n-MOST can be formed within a single voltage-sustaining region. The source region and drain region are connected directly to the anode and cathode of the Schottky junction, respectively.

Abstract: The present disclosure provides systems and methods for configuring and constructing a single photo detector or array of photo detectors with all fabrications circuitry on a single side of the device. Both the anode and the cathode contacts of the diode are placed on a single side, while a layer of laser treated semiconductor is placed on the opposite side for enhanced cost-effectiveness, photon detection, and fill factor.

Abstract: A solar device is provided, comprising a substrate structure having a surface region, a flexible and conformal material comprising a polymer material affixing the surface region, and one or more solar cells spatially provided by one or more films of materials characterized by a thickness dimension of 25 microns and less and mechanically coupled to the flexible and conformal material. The one or more solar cells have a flexible characteristic. The flexible characteristic maintains each of the solar cells substantially free from any damage or breakage thereto when the one or more films of materials is subjected to bending.

Abstract: In one embodiment, a two terminal multi-channel ESD device is configured to include a zener diode and a plurality of P-N diodes. In another embodiment, the ESD devices has an asymmetrical characteristic.

Abstract: An electro-static discharge protection device includes a first conductive type well and a second conductive type well which are formed in a surface of the first conductive type layer or a first conductive type substrate. A first high concentration second conductive type region, a first high concentration first conductive type region, and a second high concentration second conductive type region are formed in a surface of the second conductive type well. A third high concentration second conductive type region is formed in a surface of the first conductive type well. The first high concentration second conductive type region and the first high concentration first conductive type region are connected with a first power supply of a potential. The third high concentration second conductive type region is connected with a second power supply having a potential different from the potential of the first power supply.

Abstract: A Break Over Diode (“BOD”) device is a gate-less two terminal high power semiconductor switch in which transitions from a blocking state to a conducting state are triggered by a dV/dt pulse to the anode. The BOD device can be thought of as two cross-coupled PNP and NPN transistors, and includes both anode and cathode shorts which reduce the gain of the NPN and PNP transistors by shunting some current away from their bases directly to their emitters, thereby improving blocking. Moreover, the anode and cathode shorts in conjunction with the device blocking junction form PN diodes which are distributed throughout the bulk of the material and function as anti-parallel diodes to the base-emitter junctions of the PNP and NPN transistors, which enables the BOD device to handle a larger current reversal for a longer period of time. The P base layer may be made thin to decrease the voltage fall time from full blocking to full conduction, and the cathode and anode shorts may be provided in a honeycomb pattern.

Abstract: In one embodiment, a two terminal multi-channel ESD device is configured to include a zener diode and a plurality of P-N diodes.

Abstract: High-side and low-side surface voltage sustaining regions is produced by utilizing optimum surface variation lateral doping. Schottky junctions are formed by depositing metal M on an n-type region having the lowest potential, taking M as the anode AL or AH of the Schottky diode, and ohmic contact is formed at the portion having the highest potential, which is taken as the cathode KL or KH of the Schottky diode. Where said potentials refer to a reverse bias is applied to the Schottky diode. A small isolation region is formed between two surface voltage sustaining regions. Each voltage sustaining region can be divided into several sections. Isolation region are inserted between neighbouring sections. A Schottky diode is formed in each section. Schottky diode of each section is connected to each other in series. A lateral Schottky diode and an n-MOST can be formed within a single voltage sustaining region.

Abstract: A silicon rectifier semiconductor device with selectable trigger and holding voltages includes a trigger element. A first well region of a first conductivity type formed within a semiconductor body. A first region of the first conductivity type is formed within the first well region. A second region of a second conductivity type is formed with the first well region. A second well region having the second conductivity type is formed within the semiconductor body adjacent the first well region. A third region of the first conductivity type is formed within the second well region. A fourth region of the second conductivity type is formed within the second well region. The trigger element is connected to the first region and alters a base trigger voltage and a base holding voltage into an altered trigger voltage and an altered holding voltage. A first terminal or pad is connected to the second region. A second terminal is connected to the third region, the fourth region, and the trigger element.

Abstract: An ESD protection device, which is arranged to be active at a triggering voltage (Vt1) for providing ESD protection, comprises a first region of the first conductivity type formed in a semiconductor layer of the first conductivity type, the first region extending from a surface of the semiconductor layer and being coupled to a first current electrode (C) of the semiconductor device, a well region of a second conductivity type formed in the semiconductor layer extending from the surface of the semiconductor layer, and a second region of the second conductivity type formed in the well region, the second region being coupled to a second current electrode (B). The ESD protection device further comprises a floating region of the second conductivity type formed in the semiconductor layer between the first current electrode (C) and the well region and extending from the surface of the semiconductor layer a predetermined depth.

Abstract: A thyristor arrangement includes a main thyristor, at least one auxiliary thyristor, a resistance device which electrically connects the auxiliary thyristor and the main thyristor to one another, and an optical triggering device for breakover triggering of the main thyristor via the auxiliary thyristor and the resistance device. The resistance device defines a time-dependent ohmic resistance in such a way that the value thereof is relatively large during a switch-on phase of the main thyristor and relatively small during a current-carrying phase of the main thyristor.

Abstract: A system for protecting a high-speed input/output pad of an integrated circuit. The system includes a preferably parasitic silicon controlled rectifier (SCR) and a triggering mechanism that preferably includes an NMOS triggering FET. The SCR includes an anode connected to the input/output pad and a trigger input. The anode and the trigger input form a reverse-biased junction that, during normal operation of the integrated circuit, isolates the triggering mechanism from the input/output pad when power is applied to the integrated circuit.

Abstract: An electro-static discharge protection device includes a first conductive type well and a second conductive type well which are formed in a surface of the first conductive type layer or a first conductive type substrate. A first high concentration second conductive type region, a first high concentration first conductive type region, and a second high concentration second conductive type region are formed in a surface of the second conductive type well. A third high concentration second conductive type region is formed in a surface of the first conductive type well. The first high concentration second conductive type region and the first high concentration first conductive type region are connected with a first power supply of a potential. The third high concentration second conductive type region is connected with a second power supply having a potential different from the potential of the first power supply.

Abstract: An apparatus for switching microwave signals includes a plurality of input lines, a plurality of output lines; and a plurality of thyristor. Each thyristor has a lower conducting surface that is electrically connected to one of the input lines and an upper conducting surface that is electrically connected to one of the output lines. A selected thyristor transmits a microwave signal between a selected input line and a selected output line in an ON state and blocks the microwave signal between the selected input line and the selected output line in an OFF state.

Abstract: An ESD protection structure for protecting an integrated circuit from electrostatic discharge, having a bipolar protection element, whose emitter is formed by an emitter zone of the first conduction type, whose collector is formed by a buried layer of the first conduction type, and whose base is formed by a base zone of the second conduction type disposed in-between. The base zone is spaced apart from the buried layer by an intermediate layer. Highly and lightly doped regions alternatively are provided in a section of the buried layer. The highly doped regions are spaced apart from one another by the lightly doped regions. A region with a reduced breakdown voltage of the protection element is disposed in a part of the protection element spaced apart from the section of the buried layer. Also provided is an integrated circuit having such an ESD protection structure.

Abstract: A described embodiment of the present invention includes an integrated circuit having a plurality of I/O modules. The I/O modules include a bond pad formed on a substrate. The I/O modules also include an electrostatic discharge device formed in the substrate. The electrostatic discharge device is at least partially formed beneath the bond pad. The I/O module also includes an I/O buffer formed in the substrate. The I/O buffer is connected to the bond pad. The I/O buffer provides communication between the bond pad and circuitry formed in the substrate. The circuitry is positioned substantially adjacent to both the electrostatic discharge device and the I/O buffer.

Abstract: A bi-directional silicon controlled rectifier structure provides electrostatic discharge (ESD) protection against both positive and negative voltage spikes. The structure utilizes a pair of wells, n+ and p+ regions formed in both wells, a first ring formed around the junction between the first well and the semiconductor material, and a second ring formed around the junction between the second well and the semiconductor material.

Abstract: An ESD protection apparatus for dual-polarity input pad comprises a triple-well formed with a first, second and third regions to form an SCR structure. A first and second ground connection regions of opposite conductivity types are formed on the first region, a first and second input connection regions of opposite conductivity types are formed in the third region, and a bridge region is formed across the second region and extends to the first and third regions. Under normal operation, the first, second, and third regions form two back-to-back diodes. Under positive polarity ESD event, breakdown is occurred between the bridge and first regions to thereby trigger an SCR circuit for positive polarity ESD protection. Under negative polarity ESD event, breakdown is occurred between the bridge and third regions to thereby trigger an SCR circuit for negative polarity ESD protection.

Abstract: A low-capacitance bidirectional device of protection against overvoltages, intended to be used at high frequencies, including first and second discrete one-way Shockley diodes, the cathode and the anode of the first diode being respectively connected to the anode and to the cathode of the second diode, the break-over voltages of each diode ranging between 50 and 125 V.

Abstract: In order to eliminate the difference in ESD resistance caused by polarities of excessive voltages applied to an external terminal and enhance ESD resistance of a semiconductor integrated circuit device to both the positive and negative overvoltages, a protection element having a thyristor structure, for protecting an internal circuit from the positive overvoltage and a protection element made up of a diode D1 for protecting the internal circuit from the negative overvoltage are provided between the external terminal and a ground potential.

Abstract: The present invention provides a novel ESD structure for protecting an integrated circuit (IC) from ESD damage and a method of fabricating the ESD structure on a semiconductor substrate. The ESD structure of the present invention has lower trigger voltage and lower capacitance, and takes smaller substrate area than prior art ESD structures. The low trigger voltage is provided by a small N+P diode or a P+N diode which has a PN junction with a much lower breakdown voltage than a PN junction between a N+ (or P+) source/drain region and a P-well (or N-well). All of the diffusion regions in the ESD device of the present invention can be formed using ordinary process steps for fabricating the MOS devices in the IC and does not require extra masking steps in addition to those required to fabricate the IC.

Abstract: A diode coupling-based arrangement back-biases each of the semiconductor substrates of a plurality of integrated circuits at the maximum (e.g., most negative) DC voltage applied to any individual circuit, irrespective of a potential variation in applied DC voltages. Each semiconductor chip/substrate includes an auxiliary terminal to which each DC voltage terminal for that chip is diode-coupled. The auxiliary voltage terminal is connected to the underside biasing and thermal dissipation pad of the substrate. When multiple packages are mounted and conductively joined to a shared metallic dissipation region of a support substrate, all auxiliary voltage terminals will be connected in common, so as to back-bias each semiconductor substrate to the most maximum (e.g., most negative) of all applied DC voltages.

Abstract: A preferably asymetrical thyristor (1) with at least one driver stage (20) for amplifying a control current (I) fed into the cathodal base (16) of the thyristor, in which, in the driver stage, the transistor gain factors &agr;npn and &agr;pnp are in each case greater than, preferably, in the thyristor and anode short circuits of the thyristor (174) have a smaller electrical conductivity in the driver stage than in the thyristor.

Abstract: The solar cell of the present invention includes a titanium dioxide semiconductor that is held between a pair of electrodes so that the titanium dioxide semiconductor and at least one of the electrodes form a rectification barrier.

Abstract: A semiconductor overvoltage protection device in the form of a four layer diode has first and third layers of a first conductivity semiconductor material, second and fourth layers of a second conductivity type semiconductor material and a first buried region of the first conductivity type in the third layer adjacent to the junction between the second and third layers. The buried region has a greater impurity concentration than the third layer. The first layer is penetrated by a plurality of dots of the second layer extending through the first layer and the first buried region lies wholly beneath the second layer and is laterally offset from the dots and the first layer.

Abstract: An electrostatic discharge (ESD) protection structure is disclosed. The ESD protection structure of the present invention uses a resistance capacitance (RC) circuit to distinguish an overshoot phenomenon caused by the instantaneous power-on from an ESD event, so as to prevent the ESD protection device, such as a P-type modified lateral silicon controlled rectifier (MLSCR), from being triggered unexpectedly by an overshoot phenomenon which results from the power-on under normal operation, and thereby the efficiency of the ESD protection device is promoted.

Abstract: A low-capacitance bidirectional device of protection against overvoltages, intended to be used at high frequencies, including first and second discrete one-way Shockley diodes, the cathode and the anode of the first diode being respectively connected to the anode and to the cathode of the second diode, the break-over voltages of each diode ranging between 50 and 125 V.

Abstract: A cascaded diode acting as all ESD protection device with reduced substrate leakage current is disclosed. The cascaded diode is composed of a chain of coupled similar elemental diodes, each composed of an n-well in a p-substrate, the n-well having p regions and n regions, and a deep n-well disposed under and connected to the n-well. The first elemental diode has its p region electrically connected to a pin or pad that is the higher potential end of a portion of an integrated circuit to be protected, its n region electrically connected to the p region of an intermediate elemental diode. The p region of an intermediate diode is connected electrically to the n region of the preceding elemental diode and the n region of an intermediate elemental diode is connected electrically to the p region of the following elemental diode.

Abstract: An ESD protection circuit that will prevent internal circuits of an integrated circuit is formed on a semiconductor substrate to prevent damage during extreme voltage levels from an ESD voltage source and is connected to an input/output pad. A plurality of drains of multiple MOS FET's is formed within the surface of the semiconductor substrate and are each connected to the input/output pad. A plurality of sources of the multiple MOS FET's is formed within the surface of the semiconductor substrate and are placed at a distance from the plurality of drains and are connected to a ground reference potential. Pairs of the plurality of sources are adjacent to each other. A plurality of isolation regions placed between each source of the pairs of sources and are allowed to float. The multiple MOS FET's have a plurality of parasitic bipolar junction transistors.

Abstract: The thyristor is based on a semiconductor body with an anode-side base zone of the first conductivity type and one or more cathode-side base zones of the opposite, second conductivity type. Anode-side and cathode-side emitter zones are provided, and at least one region in the cathode-side base zone whose geometry gives it a reduced breakdown voltage as compared with the remaining regions in the cathode-side base zone and the edge of the semiconductor body. At the anode, below the region of reduced breakdown voltage, the thyristor has at least one recombination zone in which the free charge carriers have a reduced lifetime.

Abstract: A surface voltage sustaining structure for semiconductor device which includes at least one high-side high-voltage device, comprises at least two surface voltage sustaining regions, wherein a first surface voltage sustaining region is for sustaining a voltage drop from a high voltage terminal of the high-side high-voltage device to a floating voltage terminal of the high-side high-voltage device, and a second surface voltage sustaining region is for sustaining a voltage drop from said high voltage terminal or from said floating voltage terminal to the substrate. The potential of the floating-voltage terminal of the high-side high-voltage device can vary (float) from the potential of the substrate up to the potential of the high voltage terminal.

Abstract: The present invention relates to a circuit device for protection against electrostatic discharge, and being immune to the latch-up phenomenon. The circuit device is of the integrated type in a portion of a semiconductor integrated circuit. The device includes an active limiting element and a resistor connected in series between a terminal of the active element connected to an input/output pin of the integrated circuit, and a terminal of a circuit to be protected. The active element is a bipolar transistor having a base terminal and an emitter-acting collector terminal connected together. The distributed resistor is formed in an emitter-acting collector region of the transistor which is diffused and elongated at the surface inside a base pocket of the transistor.

Abstract: An ESD protection circuit is fabricated on a semiconductor block on an insulating layer overlying a supporting substrate. The ESD protection circuit comprises a first N-type doped region, a first P-type doped region, a second N-type doped region and a second P-type doped region sequentially formed in the semiconductor block, and a stacked structure overlying the first P-type doped region and the second N-type doped region, wherein the first N-type doped region is more heavily doped than the second N-type doped region and the first P-type doped region is more lightly doped than the second P-type doped region.

Abstract: A design for an overvoltage protection circuit can be used to fabricate several different circuits incorporating different protection techniques. The design is suitable for use in a single device, which can be easily and inexpensively packaged and protected from the environment. Three terminal protection circuits can have three terminals on an upper surface of a substrate, or one terminal on a lower surface of the substrate, using a single modular design. Additional circuitry can be included to sense for high current conditions which are caused by overvoltages too low to trigger the normal overvoltage protection circuits.

Abstract: The solar cell of the present invention includes a titanium dioxide semiconductor that is held between a pair of electrodes so that the titanium dioxide semiconductor and at least one of the electrodes form a rectification barrier.