Status and trends of power semiconductor device models for circuit simulation

Kraus, R.; Mattausch, Hans Jürgen

doi:10.1109/63.668107

Cited by 110 publications

(47 citation statements)

References 95 publications

(46 reference statements)

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“…Gate oxide thickness and doping concentration of the channel can be used to control the V. Typically, 2~4V is designed for gate drive of 10-15V. With the scaling down of the CMOS technology [9][10][11], the gate drive of the power trench MOSFET drops to 2.5-4.5V. Therefore, lower threshold voltages of 2-5V are needed for these applications.…”

Section: Threshold Voltagementioning

confidence: 99%

Modeling and Simulation of Power MOSFET Using Orcad-Pspice

Lotfi¹,

Dibi²

2016

IJUNESST

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Section: Threshold Voltagementioning

confidence: 99%

Modeling and Simulation of Power MOSFET Using Orcad-Pspice

Lotfi¹,

Dibi²

2016

IJUNESST

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“…Their basic electrical model, obtained from the manufacturer, is based on the work of Kraus et al [3]. It employs a mixed functional and physical description [4], representing a trade-off between a high accuracy of description and the ability to perform rather complex simulations, that is with multi-chip structures and including parasitic elements and temperature dependence. By contrast, to be representative of the behavior of the transistor during short-circuit conditions, the original model had to be modified in order to include shortchannel effects (i.e.…”

Section: Device Compact Model: Electrical Componentmentioning

confidence: 99%

Failure-relevant abnormal events in power inverters considering measured IGBT module temperature inhomogeneities

Perpiñà

Castellazzi²,

Piton

et al. 2007

Microelectronics Reliability

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“…A complete and thorough review of power semiconductor device models has been proposed in [6] from which lumped models emerged as one of the most promising modelling concepts for power semiconductor devices. Indeed, they allow high flexibility and good trade-offs between accuracy and simulation time to be achieved.…”

Section: Introductionmentioning

confidence: 99%

Effect of layout parasitics on the current distribution of power MOSFETs operated at high switching frequency

et al. 2006

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The internal electrical characteristics of an 800-V 9-A 0.7-silicon power MOSFET are investigated using a distributed modelling approach. A cad tool has been developed to automatically extract layout parasitics and create an equivalent spice-like netlist of the device under investigation. The distributed model is employed to investigate the performance of the device during a turn-off switching at different values of the gate fall time. Simulations show that reducing the gate fall time contributes to increase the internal current imbalance leading to current density overshoots, referred to as hot spots. Moreover, faster switching operation forces current density to crowd towards the slowest parts of the device which in turn degrades the overall device ruggedness. These results demonstrate that the proposed modelling approach allows accurate simulation of the internal current distribution identifying the regions where hot spots are more likely to occur.

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Status and trends of power semiconductor device models for circuit simulation

Cited by 110 publications

References 95 publications

Modeling and Simulation of Power MOSFET Using Orcad-Pspice

Modeling and Simulation of Power MOSFET Using Orcad-Pspice

Failure-relevant abnormal events in power inverters considering measured IGBT module temperature inhomogeneities

Effect of layout parasitics on the current distribution of power MOSFETs operated at high switching frequency

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