Abstract: A method for manufacturing a MuGFET ESD protection device having a given layout by means of a given manufacturing process, the method comprising selecting multiple interdependent layout and process parameters of which a first set are fixed by said manufacturing process and a second set are variable, selecting multiple combinations of possible layout and process parameter values which meet predetermined ESD constraints; determining an optimum value for at least one other parameter in view of a predetermined design target apart from the predetermined ESD constraints; determining values for fin width (Wfin), gate length (LG) and number of fins (N) on the basis of the optimum value; and manufacturing said MuGFET ESD protection device using the given manufacturing and process values.

Abstract: The present disclosure relates to a method for calibrating transient behaviour of an electrostatic discharge (ESD) test system. The system includes an ESD pulse generator and probe needles for applying a predetermined pulse on a device under test. The probe needles are connected to the ESD pulse generator via conductors. The test system includes measurement equipment for detecting transient behaviour of the device under test by simultaneously capturing voltage and current waveforms the device as a result of the pulse. The method includes the steps of: (a) applying the ESD test system on a first known system with a first known impedance, (b) applying the ESD test system on a second known system with a known second impedance, and (c) determining calibration data for the transient behaviour the ESD test system on the basis of captured voltage and current waveforms, taking into account said known first and second impedances.

Abstract: The disclosed method and device relates to a bidirectional ESD power clamp, comprising a semiconductor structure (BigNFET; BigPFET) having a conductive path connected between first and second nodes and having a triggering node via which the conductive path can be triggered. An ESD transient detection circuit is connected between the first and second nodes and to the triggering node and comprises a first part for detecting an occurrence of a first ESD transient on the first node. The semiconductor structure is provided on an insulator substrate, such that a parasitic conductive path between said first and second nodes via the substrate is avoided. The ESD transient detection circuit further comprises a second part for detecting an occurrence of a second ESD transient on the second node.

Abstract: A method for manufacturing a MuGFET ESD protection device having a given layout by means of a given manufacturing process, the method comprising selecting multiple interdependent layout and process parameters of which a first set are fixed by said manufacturing process and a second set are variable, selecting multiple combinations of possible layout and process parameter values which meet predetermined ESD constraints; determining an optimum value for at least one other parameter in view of a predetermined design target apart from the predetermined ESD constraints; determining values for fin width (Wfin), gate length (LG) and number of fins (N) on the basis of the optimum value; and manufacturing said MuGFET ESD protection device using the given manufacturing and process values.

Abstract: A method of quickly measuring a characteristic impedance of an ESD protecting circuit by applying a discharge voltage to the ESD protecting circuit, includes the steps of measuring a variation in discharge voltage applied to and a variation in discharge current caused to flow through the ESD protecting circuit with time; simultaneously detecting a state when both the discharge voltage and discharge current corresponding to each other are attenuated, after both the discharge voltage and discharge current sequentially rise to arrive individually to respective peak values based on an input to or an output from a computer; and taking a ratio of the variation of discharge voltage to the variation of discharge current during the attenuation as an impedance value when the ratio is nearly constant as well as an apparatus for realizing the same.

Abstract: A method and apparatus for designing an ESD protection circuit comprising a main ESD device and a triggering device connected to a triggering node of the main ESD device by means of which the main ESD device can be triggered for conducting ESD current at a reduced voltage. The triggering device is located in an initial current path for the ESD current. In this initial current path, there is at least one triggering component which can be triggered from an off-state to an on-state. The triggering speed of this component is considered and its design is optimised in view of increasing its triggering speed. Further shown is an ESD protection circuit in which at least one triggering component is selected to be of a predetermined type for achieving a fast triggering speed, preferably of the gated diode type.

Abstract: The present disclosure relates to a method for calibrating transient behaviour of an electrostatic discharge (ESD) test system. The system includes an ESD pulse generator and probe needles for applying a predetermined pulse on a device under test. The probe needles are connected to the ESD pulse generator via conductors. The test system includes measurement equipment for detecting transient behaviour of the device under test by simultaneously capturing voltage and current waveforms the device as a result of the pulse. The method comprises the steps of: (a) applying the ESD test system on a first known system with a first known impedance, (b) applying the ESD test system on a second known system with a known second impedance, and (c) determining calibration data for the transient behaviour the ESD test system on the basis of captured voltage and current waveforms, taking into account said known first and second impedances.

Abstract: A method of quickly measuring a characteristic impedance of an ESD protecting circuit by applying a discharge voltage to the ESD protecting circuit, includes the steps of measuring a variation in discharge voltage applied to and a variation in discharge current caused to flow through the ESD protecting circuit with time, grasping a state until both the discharge voltage and discharge current corresponding to each other whenever a predetermined common time elapses comes to an attenuation process after both the discharge voltage and discharge current sequentially rise to come individually to respective peak values based on an input to or an output from a computer; and taking a ratio of the variation of discharge voltage to the variation of discharge current in the attenuation process as an impedance value when the ratio is nearly constant as well as an apparatus for realizing the same.