In this paper, the problem of how to describe the thermal properties of the insulated-gate bipolar transistor (IGBT) module with the use of the compact thermal model is considered. This model makes it possible to calculate internal temperature of every semiconductor device included in this module with self-heating phenomena and mutual thermal couplings between these devices taken into account. A new method of measuring parameters of the thermal model of devices contained in the considered module is proposed, and the accuracy of this method is discussed. Some results of measurements of the considered parameters are presented, and uneven distribution of temperature in the investigated module in selected conditions of its power supply is evaluated. Differences between the measured waveforms of the internal temperature of components of the IGBT module and its casings are discussed.

Measurements of Parameters of the Thermal Model of the IGBT Module

The paper concerns modeling the nonisothermal characteristics of switch-mode voltage regulators (VRs) consisting of the boost converter with discrete semiconductor devices and a monolithic current-mode pulsewidth modulation controller. New electrothermal hybrid models of a p-n diode and a power metal oxide semiconductor transistor, as well as the electrothermal model of the monolithic UC3842 controller dedicated for SPICE analysis of switch-mode VRs are presented and described in detail. The results of simulations verified experimentally are given as well.

Modeling Nonisothermal Characteristics of Switch-Mode Voltage Regulators

In the article, a new method to improve the accuracy of the insulated-gate bipolar transistor (IGBT) junction temperature computations in the piecewise linear electrical circuit simulation (PLECS) software is proposed and described in detail. This method allows computing the IGBT junction temperature using a nonlinear compact thermal model of this device in PLECS. In the method, a nonlinear compact thermal model of the IGBT is used, which considers the dependence of thermal resistance on the junction temperature. The usefulness of the method is experimentally verified, and it is confirmed that it increases the accuracy of the computations and shortens their time. The differences between the measured and computed characteristics are discussed. The application of the developed method for computations resulted in a significant reduction of their error to only a few percent. The developed method can be applied in the system-level simulations of the power electronics converters.

Accurate Computation of IGBT Junction Temperature in PLECS

In this paper, a physics-based high-frequency (HF) model of switching power converters including the insulated gate bipolar transistor (IGBT) unit cells, heat sink, and connective printed circuit board (PCB) traces combined in a single electrical circuit is presented. The IGBT model includes the HF stray components superimposed on the well-known Hefner IGBT model. The HF components were calculated using a 3-D quasi-static finite element (3-D FE) analysis. The proposed complex model of the IGBT was verified both numerically and experimentally at different switching frequencies. The computed IGBT model was used in a low-high frequency model of a motor-drive system, and the common mode ground current was experimentally verified showing excellent results.

Physics-Based Modeling of Power Converters From Finite Element Electromagnetic Field Computations

Modelling the temperature influence on dc characteristics of the IGBT

While there are several analytical models dedicated to vertical insulated gate bipolar transistors (IGBTs) there is virtually no reliable model for lateral IGBTs (LIGBTs). LIGBTs are increasingly popular in smart power and power integrated circuits, especially in those applications where high voltage (e.g., 600 V) and high current capability (e.g., 30 A/cm2) are required. In this paper, we report for the first time a complete analytical model for the LIGBT based on semiconductor physics with very few fitting parameters. The model is implemented in the widely available circuit simulator PSpice. The model consistently describes the current and voltage waveforms for all loading conditions. The model is assessed against finite element device simulations and experimental results

An Analytical Model for the Lateral Insulated Gate Bipolar Transistor (LIGBT) on Thin SOI

Several vertical insulated gate bipolar transistor (IGBT) electrothermal models are currently available on circuit simulators. However, no reliable electrothermal models have been proposed for the lateral IGBT (LIGBT). In this paper, for the first time, an electrothermal model for an LIGBT structure based on a novel concept recently reported by Udrea (IEDM, p. 451, 2004), and here termed silicon-on-membrane, is presented. The model relies on a systematic study of both the isothermal and self-heating behaviors of the device. The model is further implemented in the SPICE circuit simulator language and validated against extensive Medici numerical simulations and experimental data

Electrothermal model for an SOI-based LIGBT

Several vertical IGBT electro-thermal models are currently available on circuit simulators. However, no reliable electro-thermal models have been proposed for the lateral insulated gate bipolar transistor (LGBT). In this paper, for the first time we present a fully coupled electrothermal model for a LIGBT structure based on a novel concept recently reported in (Napoli, et. al., 2005). The model relies on a systematic study of both isothermal and self heating behavior of the device. It is valid in both steady state and switching conditions. The model is further implemented in the Spice circuit simulator and validated against extensive numerical simulations and experimental data

Fully coupled dynamic self heating model for power SOI Lateral Insulated Gate Bipolar Transistors

Several vertical IGBT electro-thermal models are currently available on circuit simulators. However, no reliable electro-thermal models have been proposed for the lateral IGBT (LIGBT). In this paper we present a novel steady-state electro-thermal model for a LIGBT on thin Silicon-On-Insulator (SOI) technology. The model is fully-assessed against experimental results and numerical simulations

A compact steady-state self-heating model for a thin SOI LIGBT

The silicon on insulator (SOI) lateral insulated gate bipolar transistor (LIGBT) is a popular choice in smart integrated circuit (IC) applications. An isothermal model valid for both thin and thick SOI LIGBTs was recently reported by us. In this paper, the authors formulate the well known thin silicon thermal conductivity reduction to the device model and extend it to include the package thermal behaviour. In the process the thermally important layers of the packaging and their impact on the device, both on electrical and thermal behaviours are identified. The resulting compact, physics based, scalable, fully coupled self-heating model is verified through numerical simulations and experimental data

A fully Coupled Compact Self-Heating Model for a Thin SOI LIGBT with Packaging

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