Abstract: An ESD protection device comprising an SCR-type circuit including a PNP transistor and NPN transistor incorporates a Zener diode which permits the circuit to operate at comparatively low trigger voltage thresholds. Zener diode breakdown voltage is controlled by doping levels in a doped area of an N-type well. One or more diodes connected in series between the SCR circuit and the input/output terminal of the device advantageously raises the snapback voltage of the SCR circuit. The use of nitride spacers between doped regions instead of gate oxide technology significantly reduces unwanted leakage currents.

Abstract: A semiconductor device is provided which comprises an ESD protection device. The structure of the semiconductor device comprises a p-doped isolated region in which a structure is manufactured which operates as a Silicon Controlled Rectifier which is coupled between an I/O pad and a reference voltage or ground voltage. The semiconductor device also comprises a pnp transistor which is coupled parallel to the Silicon Controlled Rectifier. The base of the transistor is coupled to the gate of the Silicon Controlled Rectifier. In an optional embodiment, the base and gate are also coupled to the I/O pad.

Abstract: A semiconductor device is provided which comprises an ESD protection device. The structure of the semiconductor device comprises a p-doped isolated region in which a structure is manufactured which operates as a Silicon Controlled Rectifier which is coupled between an I/O pad and a reference voltage or ground voltage. The semiconductor device also comprises a pnp transistor which is coupled parallel to the Silicon Controlled Rectifier. The base of the transistor is coupled to the gate of the Silicon Controlled Rectifier. In an optional embodiment, the base and gate are also coupled to the I/O pad.

Abstract: An electrostatic protection includes a buried layer having an outer region and an inner region which are heavily doped regions of a first conductivity type. The inner region is surrounded by an undoped or lightly doped ring region. The ring region is surrounded by the outer region. The device further includes a semiconductor region over the buried layer, a first well of the first conductivity type in the semiconductor region, a first transistor in the semiconductor region, and a second transistor in the semiconductor region. The first well forms a collector of the first transistor and a collector of the second transistor.

Abstract: An electrostatic discharge (ESD) device is disclosed having two PNP transistors. During a high-voltage ESD event a parasitic NPN transistor couples to one of the two PNP transistors to provide ESD protection.

Abstract: Systems and methods are disclosed for pre-fetching assets from content providers to user equipment (UE). In one embodiment, the UE initiates a pre-fetch operation to download assets from content providers in advance of an end user requesting the assets. The UE accesses a resource profile for the pre-fetch operation that indicates the content providers that have assets for the UE to download in advance for local storage on the UE, and defines a percentage of UE resources allocated to each of the content providers for downloading the assets during the pre-fetch operation. The UE may then download the assets from the content providers based on the resource profile, and store the assets in a local memory.

Abstract: An ESD protection structure comprising a thyristor structure. The thyristor structure is formed from a first P-doped section comprising a first P-doped well formed within a first region of a P-doped epitaxial layer, a first N-doped section comprising a deep N-well structure, a second P-doped section comprising a second P-doped well formed within a second region of the epitaxial layer, and a second N-doped section comprising an N-doped contact region formed within a surface of the second P-doped well. The ESD protection structure further comprises a P-doped region formed on an upper surface of the deep N-well structure and forming a part of the second P-doped section of the thyristor structure.

Abstract: A semiconductor device is provided which comprises an ESD protection device. The ESD protection device is being formed by one or more pnp transistors which are present in the structure of the semiconductor device. The semiconductor device comprises two portions, of an isolated p-doped region which are separated by an N-doped region. Two p-doped regions are provided within the two portions. The p-dopant concentration of the two-doped region is higher than the p-dopant concentration of the isolated p-doped region. A first electrical contact is connected only via a highly doped p-contact region to the first p-doped region and a second electrical contact is connected only via another highly doped p-contact region to the second p-doped region.

Abstract: A semiconductor device includes an ESD protection device. In a N-well, two P+ doped regions form a collector and emitter of a parasitic transistor of the ESD protection device. The N-well area between the P+ doped regions, forms a base of the parasitic transistor. At some distance away from the P+ doped regions an N+ doped region is provided. The N-well in between the N+ doped region and base of the transistor forms a parasitic resistor of the ESD protection device. The N+ doped region and the emitter of the transistor are coupled to each other via an electrical connection. The ESD protection device has a limited snapback behaviour and has a well-tunable trigger voltage.

Abstract: An ESD protection circuit and device structure comprises five transistors, two PNP and three NPN. The five transistors are coupled together so that a first NPN and PNP pair constitute a first silicon controlled rectifier, SCR. The NPN transistor 102 of the first SCR and a third transistor of NPN type are coupled so that they constitute a Darlington pair. A further NPN and PNP pair are coupled together to form a second SCR with the collector of the PNP transistor of the first SCR being coupled with the emitter of the PNP transistor of the second SCR. The circuit is particularly suitable for high voltage triggering applications and two or more devices may be cascaded in series in order to further increase the triggering voltage.

Abstract: An electrostatic discharge (ESD) device is disclosed having two PNP transistors. During a high-voltage ESD event a parasitic NPN transistor couples to one of the two PNP transistors to provide ESD protection.

Abstract: An ESD protection structure comprising a first semiconductor region of a first doping type, a second semiconductor region of the first doping type, a semiconductor structure of a second doping type opposite to the first doping type formed to provide lateral isolation between the first and second semiconductor regions of the first doping type, and a first contact region of the second doping type formed within a surface of the second semiconductor region. A thyristor structure is formed within the ESD protection structure comprising the first contact region of the second doping type, the second semiconductor region of the first doping type, the semiconductor structure of the second doping type, and the first semiconductor region of the first doping type. Wherein no contact region is formed within a surface of the semiconductor structure of the second doping type between the first and second semiconductor regions of the first doping type.

Abstract: An ESD protection device comprising an SCR -type circuit including a PNP transistor and NPN transistor incorporates a Zener diode which permits the circuit to operate at comparatively low trigger voltage thresholds. Zener diode breakdown voltage is controlled by doping levels in a doped area of an N-type well. One or more diodes connected in series between the SCR circuit and the input/output terminal of the device advantageously raises the snapback voltage of the SCR circuit. The use of nitride spacers between doped regions instead of gate oxide technology significantly reduces unwanted leakage currents.

Abstract: An ESD protection structure formed within an isolation trench and comprising a first peripheral semiconductor region of a first doping type, a second semiconductor region of the first doping type, and a semiconductor structure of a second doping type opposite to the first doping type formed to provide lateral isolation between the semiconductor regions of the first doping type and isolation between the further semiconductor region of the first doping type and the isolation trench. The semiconductor structure of the second doping type is formed such that no semiconductor region of the second doping type is formed between a peripheral side of the first semiconductor region of the first doping type and a wall of the isolation trench, and no semiconductor region of the first doping type is in contact with the isolation trench other than the first semiconductor region of the first doping type.

Abstract: An electrostatic discharge, ESD, protection circuit arrangement is connectable to a first pin and a second pin of an electronic circuit and arranged to at least partly absorb an ESD current entering the electronic circuit through at least one of the first pin or the second pin during an ESD stress event. The protection circuit arrangement comprises a first ESD protection circuit arranged to absorb a first portion of the ESD current during a first part of the ESD stress event during which first part a level of the ESD current exceeds a predetermined current threshold; and a second ESD protection circuit arranged to absorb a second portion of the ESD current, the second portion having a current level below the current threshold, at least during a second part of the ESD stress event. The second ESD protection circuit comprises a current limiting circuit arranged to limit a current through at least a portion of the second ESD protection circuit to the current threshold.

Abstract: An electrostatic discharge protection circuit comprises at least two electrostatic discharge protection units connected in series between respective pairs of at least three input terminals, one of the input terminals being a reference input terminal. Each of the units comprises a silicon controlled rectifier and a current mirror. The output of the silicon controlled rectifier constitutes a first output of the respective unit and is connected to an input terminal of the circuit. The output of the current mirror constitutes a second output of the respective unit and is connected with the reference input terminal of the circuit. Thus the units are connected in series but the output terminals of the current mirrors are all connected with the reference input terminal, which may be a ground terminal, so as to minimise the breakdown resistance of the circuit.

Abstract: A semiconductor device is provided which comprises an ESD protection device. The ESD protection device is being formed by one or more pnp transistors which are present in the structure of the semiconductor device. The semiconductor device comprises two portions, of an isolated p-doped region which are separated by an N-doped region. Two p-doped regions are provided within the two portions. The p-dopant concentration of the two-doped region is higher than the p-dopant concentration of the isolated p-doped region. A first electrical contact is connected only via a highly doped p-contact region to the first p-doped region and a second electrical contact is connected only via another highly doped p-contact region to the second p-doped region.

Abstract: A semiconductor device includes an ESD protection device. In a N-well, two P+ doped regions form a collector and emitter of a parasitic transistor of the ESD protection device. The N-well area between the P+ doped regions, forms a base of the parasitic transistor. At some distance away from the P+ doped regions an N+ doped region is provided. The N-well in between the N+ doped region and base of the transistor forms a parasitic resistor of the ESD protection device. The N+ doped region and the emitter of the transistor are coupled to each other via an electrical connection. The ESD protection device has a limited snapback behaviour and has a well-tunable trigger voltage.

Abstract: A semiconductor device is provided which comprises an ESD protection device. The structure of the semiconductor device comprises a p-doped isolated region in which a structure is manufactured which operates as a Silicon Controlled Rectifier which is coupled between an I/O pad and a reference voltage or ground voltage. The semiconductor device also comprises a pnp transistor which is coupled parallel to the Silicon Controlled Rectifier. The base of the transistor is coupled to the gate of the Silicon Controlled Rectifier. In an optional embodiment, the base and gate are also coupled to the I/O pad.

Abstract: An electrostatic discharge, ESD, protection circuit arrangement is connectable to a first pin and a second pin of an electronic circuit and arranged to at least partly absorb an ESD current entering the electronic circuit through at least one of the first pin or the second pin during an ESD stress event. The protection circuit arrangement comprises a first ESD protection circuit arranged to absorb a first portion of the ESD current during a first part of the ESD stress event during which first part a level of the ESD current exceeds a predetermined current threshold; and a second ESD protection circuit arranged to absorb a second portion of the ESD current, the second portion having a current level below the current threshold, at least during a second part of the ESD stress event. The second ESD protection circuit comprises a current limiting circuit arranged to limit a current through at least a portion of the second ESD protection circuit to the current threshold.