A multi-channel transient voltage suppression device includes a semiconductor substrate, a semiconductor layer, at least two bidirectional transient voltage suppression structures, and at least one isolation trench. The semiconductor substrate, having a first conductivity type, is coupled to a grounding terminal. The semiconductor layer, having a second conductivity type opposite to the first conductivity type, is formed on the semiconductor substrate. The bidirectional transient voltage suppression structures are formed in the semiconductor layer. Each bidirectional transient voltage suppression structure is coupled to an input/output (I/O) pin and the grounding terminal. The isolation trench is formed in the semiconductor substrate and the semiconductor layer and formed between the bidirectional transient voltage suppression structures. The isolation trench has a height larger than the height of the semiconductor layer and surrounds the bidirectional transient voltage suppression structures.

An electronic device includes a first group III nitride transistor and an electrostatic discharge (ESD) protection circuit. The ESD protection circuit includes a diode and a second transistor. The diode has an anode electrically connected to a gate of the first group III nitride transistor. The second transistor has a drain electrically connected to the gate of the first group III nitride transistor, a gate electrically connected to a cathode of the diode and a source electrically connected to a source of the first group III nitride transistor.

An ESD protection circuit has a driver transistor with a drain that is coupled to an I/O pad of an IC device and a source that is coupled to a first rail of a power supply in the IC device, and a diode that couples the I/O pad to the first rail and that is configured to be reverse-biased when a rated voltage is applied to the I/O pad. The rated voltage lies within a nominal operating range for voltage levels defined for the input/output pad. The ESD protection circuit has a gate pull transistor that couples a gate of the driver transistor to the I/O pad or the first rail. The gate pull transistor may be configured to present a high impedance path between the gate of the driver transistor and the I/O pad or the first rail when the rated voltage is applied to the I/O pad. The gate pull transistor may be configured to provide a low impedance path between the gate of the driver transistor and the I/O pad or the first rail when an overvoltage signal applied to the I/O pad has a magnitude that exceeds the nominal operating range of voltage levels defined for the I/O pad.

An electrostatic protection circuit connected with an internal circuit is provided. The electrostatic protection circuit includes: a first circuit, a first diode connected in parallel with the first circuit, a second circuit, and a second diode connected in parallel with the second circuit. The first circuit is connected between a power supply pad and an internal circuit input terminal. The second circuit is connected between the internal circuit input terminal and a ground pad. The first circuit and the second circuit are diode-triggered silicon controlled rectifier circuits. The technical solution of the disclosure can improve electrostatic protection capability of a charged device model of a chip.

The present application discloses a semiconductor chip, an electronic device and an electrostatic discharge (ESD) protection method for an electronic device thereof. The semiconductor chip includes an operation electrical contact, a detection electrical contact, an ESD protection unit, and a logic circuit. The operation electrical contact receives an operation signal. The detection electrical contact receives a chip connection signal. The ESD protection unit is coupled to the operation electrical contact. The logic circuit is coupled to the detection electrical contact, and adjusts capacitance of the ESD protection unit according to a chip connection signal received by the detection electrical contact.

The present disclosure provides an electrostatic discharge (ESD) protection circuit and a chip. The ESD protection circuit is connected between a power supply VDD and a ground VSS, and includes a filter branch, a first inverter group, a switch transistor, a clamp transistor, a feedback transistor, and a second inverter group. The first inverter group has two terminals respectively connected to a first node and a second node. The switch transistor has a gate connected to the second node. The clamp transistor has a gate connected to a fourth node. The feedback transistor has a gate connected to the fourth node. The second inverter group has two terminals respectively connected to a third node and the fourth node.

A semiconductor device is provided that is useful for ESD protection purposes. The device includes a semiconductor die; diode unit cells integrated on the die and being electrically connected between the first and second terminal, each unit cell includes a first region of a first charge type in the die and a second region of a second charge type in the die; an isolation structure arranged in the die, the isolation structure being configured to electrically isolate the unit cells from one another in the semiconductor die; and contacts including first contacts that are electrically connected to the first terminal and second contacts that are electrically connected to the second terminal, and each contact among the first and second contacts is electrically connected to the first region of a respective unit cell among the unit cells and to the second region of another unit cell among the unit cells.

A bidirectional electrostatic discharge protection device includes a first transient voltage suppressor chip, a second transient voltage suppressor chip, a first conductive wire, and a second conductive wire. The first transient voltage suppressor chip includes a first diode and a first bipolar junction transistor. The first diode and the first bipolar junction transistor are electrically connected to a first pin. The second transient voltage suppressor chip includes a second diode and a second bipolar junction transistor. The second diode and the second bipolar junction transistor are electrically connected to a second pin. The first conductive wire is electrically connected between the first diode and the second bipolar junction transistor. The second conductive wire is electrically connected between the second diode and the first bipolar junction transistor.

Disclosed is an electrostatic protection circuit, an array substrate and a display device. The electrostatic protection circuit includes a first electrostatic discharge end, a second electrostatic discharge end and a signal line connecting end; a first discharge sub-circuit coupled between the first electrostatic discharge end and the signal line connecting end; and a second discharge sub-circuit coupled between the second electrostatic discharge end and the signal line connecting end. Each of the first discharge sub-circuit and the second discharge sub-circuit comprises at least one MOSFET, and gates of all MOSFETs comprised in the first discharge sub-circuit and the second discharge sub-circuit are not coupled with any one of the first electrostatic discharge end, the second electrostatic discharge end and the signal line connecting end.

An electro-static discharge (ESD) protection network for an input/output (I/O) pad includes a driver stack including an upper branch and a lower branch, the upper branch being electrically connected between a first node that has a first reference voltage and the I/O pad, and the lower branch being electrically connected between the I/O pad and a second node that has a second reference voltage; a first ESD device electrically connected between the I/O pad and a third node that has a third reference voltage; and a power clamp between the third node and the second node.