Abstract: A battery management system, BMS, integrated circuit, IC, (102) for a battery pack. The battery pack (101) comprises a sequence of battery cells connected in series; and a sequence of battery-cell-connection-nodes between adjacent battery cells. The BMS IC (102) comprises: a sequence of cell-measuring-pins (104) for connecting to corresponding battery-cell-connection-nodes; a plurality of bi-directional ESD protection elements (105), each one connected between a pair of adjacent cell-measuring-pins (104) in the sequence; a sequence of cell-balancing-pins (106) for connecting to corresponding battery-cell-connection-nodes; and a plurality of dual polarity switches (107), each one connected between a pair of adjacent cell-balancing-pins in the sequence.

Abstract: Methods of fabricating ESD protection devices include forming a single-stage voltage clamp device with high holding voltage characteristics (e.g., ˜40 V) includes two p-n-p structures coupled in series via an n-p-n structure. The device has a low-voltage terminal that may be coupled to the ground of a circuit and high voltage terminal that may be coupled to a voltage source of the circuit. A highly-doped floating (n+)/(p+) junction region within a heavily doped base of the low-voltage-side p-n-p structure allows for holding voltages of at least 40 V in the single-stage device without the need to employ two such devices in series to achieve the desired holding voltage.

Abstract: A single-stage voltage clamp device with high holding voltage characteristics (e.g., ˜40V) includes two p-n-p structures coupled in series via an n-p-n structure. The device has a low-voltage terminal that may be coupled to the ground of a circuit and high voltage terminal that may be coupled to a voltage source of the circuit. A highly doped floating (n+)/(p+) junction region within a heavily doped base of the low-voltage-side p-n-p structure allows for holding voltages of at least 40V in the single-stage device without the need to employ two such devices in series to achieve the desired holding voltage.

Abstract: An ESD protection device for protecting an integrated circuit against an ESD event includes a first terminal coupled to an input/output pad of the IC, a second terminal coupled to a reference or ground voltage, a silicon-controlled rectifier device having an anode connected to the first terminal and a cathode connected to the reference or ground voltage, and a pnp transistor coupled in parallel with the SCR device. The pnp transistor has an emitter coupled to the first terminal, a collector coupled to the second terminal, and a base coupled to a gate of the SCR. The pnp transistor includes a contact region formed at a first side of a substrate, the first contact region being surrounded by an STI layer formed at the first side of the substrate. An insulation structure is formed at an intersection of the first contact region and the STI layer.

Abstract: An electrostatic discharge (ESD) protection device includes a first bi-directional silicon controlled rectifier having a doped well of a first conductivity type, a buried doped layer having a second conductivity type opposite the first conductivity type, first and second highly doped regions of the second conductivity type in the doped well, and a third highly doped region of the first conductivity type in the doped well. The first, second and third highly doped regions are connected to a first node. A first transistor in the doped well includes an emitter coupled to the first highly doped region, a collector coupled to a conductive line in the buried doped layer, and a base coupled to the third highly doped region. A second transistor in the doped well includes an emitter coupled to the second highly doped region, a collector coupled to the conductive line in the buried doped layer, and a base coupled to the third highly doped region.

Abstract: An ESD protection device for protecting an integrated circuit (IC) against an ESD event includes a first terminal coupled to an input/output pad of the IC, a second terminal coupled to a reference or ground voltage, a silicon-controlled rectifier (SCR) device having an anode connected to the first terminal and a cathode connected to the reference or ground voltage, and a pnp transistor coupled in parallel with the SCR device. The pnp transistor has an emitter coupled to the first terminal, a collector coupled to the second terminal, and a base coupled to a gate of the SCR. The pnp transistor includes a contact region formed at a first side of a substrate, the first contact region being surrounded by an STI layer formed at the first side of the substrate. An insulation structure is formed at an intersection of the first contact region and the STI layer.

Abstract: Semiconductor device and methods for making the devices includes a buried layer of a first conductivity in a substrate in which a distance between two adjacent ends can be selected to achieve a desired breakdown voltage. A deep well having a first doping concentration of a second conductivity type is implanted in an epitaxial layer above the two adjacent ends of the buried layer. A patterned doped region is formed in the deep well and extending into the epitaxial layer above and separated a distance from the two adjacent ends of the buried lay. The patterned doped region has a second doping concentration of the second conductivity type that is greater than the first doping concentration.

Abstract: The present disclosure teaches a Field-Effect Transistor (FET) configured as a diode to provide ESD protection. The field-effect transistor has its gate, source, and body connected to a common power supply rail. A low-density doped drain region extends in a length direction beyond the gate sidewall spacers of the transistor to provide a lower leakage current than would otherwise be exhibited by the protection device.

Abstract: ESD protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a base well region having a first conductivity type and composed of first and second regions, the first base well region having a higher doped concentration and the second base well region situated between the first base well region and a collector region having a second conductivity type opposite the first conductivity type, an emitter region within the first base well region having the second conductivity type, first and second floating regions within the first base well region, the first floating region having the second conductivity type between the emitter region and the seocond floating region, the second floating region having the first conductivity type between the first floating region and the second base well region. The floating regions within the first base well region are abutting and electrically connected.

Abstract: An electrostatic discharge (ESD) protection device includes a first bi-directional silicon controlled rectifier having a doped well of a first conductivity type, a buried doped layer having a second conductivity type opposite the first conductivity type, first and second highly doped regions of the second conductivity type in the doped well, and a third highly doped region of the first conductivity type in the doped well. The first, second and third highly doped regions are connected to a first node. A first transistor in the doped well includes an emitter coupled to the first highly doped region, a collector coupled to a conductive line in the buried doped layer, and a base coupled to the third highly doped region. A second transistor in the doped well includes an emitter coupled to the second highly doped region, a collector coupled to the conductive line in the buried doped layer, and a base coupled to the third highly doped region.

Abstract: An electrostatic discharge protection device includes a buried layer having a plurality of heavily doped regions of a first conductivity type and a laterally diffused region between adjacent heavily doped regions, a semiconductor region over the buried layer, and a first well of the first conductivity type extending from a surface of the semiconductor region to a heavily doped region. The device includes a first transistor in the semiconductor region having an emitter coupled to the first terminal, and a second transistor in the semiconductor region having an emitter coupled to the second terminal. The first well forms a collector of the first transistor and a collector of the second transistor.

Abstract: An overcharge protection circuit comprises a first series of first terminals a second series of second terminals, a first overvoltage protection device connected between each consecutive pair of first terminals, a current balancing device connected between each consecutive pair of second terminals, and a second overvoltage protection device connected between a first terminal and a second terminal. The second overvoltage protection device is configured to pass a current if a voltage over the second overvoltage protection device exceeds a threshold. The second overvoltage protection device may comprise a bidirectional ESD diode, while both the first overvoltage protection device and the second overvoltage protection device may comprise a unidirectional ESD diode.

Abstract: Semiconductor device and methods for making the devices includes a buried layer of a first conductivity in a substrate in which a distance between two adjacent ends can be selected to achieve a desired breakdown voltage. A deep well having a first doping concentration of a second conductivity type is implanted in an epitaxial layer above the two adjacent ends of the buried layer. A patterned doped region is formed in the deep well and extending into the epitaxial layer above and separated a distance from the two adjacent ends of the buried lay. The patterned doped region has a second doping concentration of the second conductivity type that is greater than the first doping concentration.

Abstract: An integrated circuit die includes a stack of a substrate and multiple layers extending in parallel to the substrate. A number of integrated electronic components is formed in the stack, and connected to form an electronic circuit. The electronic circuit comprises a first electric contact, a second electric contact, and a coupling which couples the electric strips electrically to each other. The coupling includes a circuit via which extends through at least two of the layers. The die further includes an integrated current sensor having a coil arrangement for sensing a current flowing through a part of the electronic circuit. The coil arrangement is magnetically coupled to the circuit via over at least a part of a length of the circuit via to sensing a magnetic flux through the circuit via. A measurement unit can measure a parameter of the coil arrangement representative of a current flowing through the circuit via.

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 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 ESD protection structure formed within a semiconductor substrate of an integrated circuit device. The ESD protection structure comprises a thyristor structure being formed from a first P-doped section forming an anode of the thyristor structure, a first N-doped section forming a collector node of the thyristor structure, a second P-doped section, and a second N-doped section forming a cathode of the thyristor structure. A low-resistance coupling is provided between an upper surface region of the collector node of the thyristor structure and the anode of the thyristor structure.

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: A method of testing a semiconductor device against electrostatic discharge includes operating the semiconductor device, and, while operating the semiconductor device, monitoring a functional performance of the semiconductor device. The monitoring includes monitoring one or more signal waveforms of respective one or more signals on respective one or more pins of the semiconductor device to obtain one or more monitor waveforms, and monitoring one or more register values of one or more registers of the semiconductor device to obtain one or more monitor register values as function of time. The method includes applying an electrostatic discharge event to the semiconductor device while monitoring the functional performance of the semiconductor device. The method can further comprise determining a functional change from the one or more monitor waveforms and the one or more monitor register values as function of time.

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.