Modelling and design of power transistor inverter circuits

Pong, M. H.

January 1986

No description available.

621.3192

Power transistor circuits

Large Signal Physical Simulations of Si LD-MOS transistor for RF application

Syed, Asad Abbas

January 2004

<p>The development of computer aided design tools for devices and circuits has increased the interest for accurate transistor modeling in microwave applications. In the increasingly expanding wireless communication market, there is a huge demand for high performance RF power devices. The silicon LD- MOSFET transistor is dueto its high power performance is today widely used in systems such as mobile base stations, private branch exchanges (PBX), and local area networks (LAN) utilizing the bands between 0.9 to 2.5 GHz. </p><p>In this research we simulated LD-MOSFET transistor characteristics of the structure provided by Infineon technology at Kista, Stockholm. The maximum drain current obtained in the simulation was 400 mA at a gate voltage of 8 V. This value is somewhat higher than the measured one. This difference can be attributed to the parasitic effects since no parasitic effects were included in the simulations in the beginning. The only parasitic effect studied was by placing the source contact at the bottom of the substrate according to real commercial device. The matching between simulated and measured results were improved and maximum drain current was reduced to 300 mA/mm which was 30% higher than the measured drain current </p><p>The large signal RF simulations were performed in time-domain in our novel technique developed at LiU. This technique utilizes a very simple amplifier circuit without any passive components. Only DC bias and RF signals are applied to the gate and drain terminals, with the same fundamental frequency but with 180o phase difference. The RF signal at the drain acting as a short at higher harmonics. These signals thus also acted as an active match to the transistor. Large signal RF simulations were performed at 1, 2 and 3 GHz respectively. The maximum of drain current signal was observed at the maximum of drain voltage signal indicating the normal behavior of the transistor. At 1 GHz the output power was 1.25 W/mm with 63% of drain efficiency and 23.7 dB of gain. The out pout power was decreased to 1.15 W/mm and 1.1 W/mm at 2 and 3 GHz respectively at the same time the efficiency and gain was also decreased to 57% and 19 dB at 2 GHz and 51% and 15 dB at 3GHz respectively.</p>

Physics

Si-LDMOS

TCAD-Simulation

Large Signal

RF power transistor

Fysik

Physics

Fysik

Large Signal Physical Simulations of Si LD-MOS transistor for RF application

Syed, Asad Abbas

January 2004

The development of computer aided design tools for devices and circuits has increased the interest for accurate transistor modeling in microwave applications. In the increasingly expanding wireless communication market, there is a huge demand for high performance RF power devices. The silicon LD- MOSFET transistor is dueto its high power performance is today widely used in systems such as mobile base stations, private branch exchanges (PBX), and local area networks (LAN) utilizing the bands between 0.9 to 2.5 GHz. In this research we simulated LD-MOSFET transistor characteristics of the structure provided by Infineon technology at Kista, Stockholm. The maximum drain current obtained in the simulation was 400 mA at a gate voltage of 8 V. This value is somewhat higher than the measured one. This difference can be attributed to the parasitic effects since no parasitic effects were included in the simulations in the beginning. The only parasitic effect studied was by placing the source contact at the bottom of the substrate according to real commercial device. The matching between simulated and measured results were improved and maximum drain current was reduced to 300 mA/mm which was 30% higher than the measured drain current The large signal RF simulations were performed in time-domain in our novel technique developed at LiU. This technique utilizes a very simple amplifier circuit without any passive components. Only DC bias and RF signals are applied to the gate and drain terminals, with the same fundamental frequency but with 180o phase difference. The RF signal at the drain acting as a short at higher harmonics. These signals thus also acted as an active match to the transistor. Large signal RF simulations were performed at 1, 2 and 3 GHz respectively. The maximum of drain current signal was observed at the maximum of drain voltage signal indicating the normal behavior of the transistor. At 1 GHz the output power was 1.25 W/mm with 63% of drain efficiency and 23.7 dB of gain. The out pout power was decreased to 1.15 W/mm and 1.1 W/mm at 2 and 3 GHz respectively at the same time the efficiency and gain was also decreased to 57% and 19 dB at 2 GHz and 51% and 15 dB at 3GHz respectively.

Physics

Si-LDMOS

TCAD-Simulation

Large Signal

RF power transistor

Fysik

Physics

Fysik

Développement de nouvelles hétérostructures HEMTs à base de nitrure de gallium pour des applications de puissance en gamme d'ondes millimétriques / Development of new gallium nitride based HEMT heterostructures for microwave power applications

Rennesson, Stéphanie

13 December 2013

Les matériaux III-N sont présents dans la vie quotidienne pour des applications optoélectroniques (diodes électroluminescentes, lasers). Les propriétés remarquables du GaN (grand gap, grand champ de claquage, champ de polarisation élevé, vitesse de saturation des électrons importante…) en font un candidat de choix pour des applications en électronique de puissance à basse fréquence, mais aussi à haute fréquence, par exemple en gamme d'ondes millimétriques. L’enjeu de ce travail de thèse consiste à augmenter la fréquence de travail des transistors tout en maintenant une puissance élevée. Pour cela, des hétérostructures HEMTs (High Electron Mobility Transistors) sont développées et les épaisseurs de cap et de barrière doivent être réduites, bien que ceci soit au détriment de la puissance délivrée. Une étude sera donc menée sur l’influence des épaisseurs de cap et de barrière ainsi que le type de barrière (AlGaN, AlN et InAlN) de manière à isoler les hétérostructures offrant le meilleur compromis en termes de fréquence et de puissance. De plus, les moyens mis en œuvre pour augmenter la fréquence de travail entrainent une dégradation du confinement des électrons du canal. De manière à limiter cet effet, une back-barrière est insérée sous le canal. Ceci fera l’objet d’une deuxième étude. Enfin, une étude de la passivation de surface des transistors sera menée. La combinaison des ces trois études permettra d’identifier la structure optimale pour délivrer le plus de puissance à haute fréquence (ici à 40 GHz). / Nitride based materials are present in everyday life for optoelectronic applications (light emitting diodes, lasers). GaN remarkable properties (like large energy band gap, high breakdown electric field, high polarization field, high electronic saturation velocity…) make it a promising candidate for low frequency power electronic applications, but also for high frequency like microwaves range for example. The aim of this work is to increase the transistors working frequency by keeping a high power. To do this, high electron mobility transistor heterostructures are developed, and cap and barrier thicknesses have to be reduced, although it is detrimental for a high power. A first study deals with the influence of cap and barrier thicknesses as well as the type of barrier (AlGaN, AlN and InAlN), in order to isolate heterostructures offering the best compromise in terms of power and frequency. Moreover, the means implemented to increase the working frequency lead to electron channel confinement degradation. In order limit this effect, a back-barrier is added underneath the channel. It will be the subject of the second study. Finally, a transistor surface passivation study will be led. The combination of those three parts will allow identifying the optimum structure to deliver the highest power at high frequency (here at 40 GHz).

Nitrure de gallium

III-N

Épitaxie

Transistor de puissance

RF

Ondes millimétriques

High electron mobility transistor

Gallium nitride

III-N

Epitaxy

Power transistor

RF

Microwaves

Electro-thermal and Radiation Reliability of Power Transistors: Silicon to Wide Bandgap Semiconductors

Bikram Kishore Mahajan (11794316)

19 December 2021

<p>We are in the midst of a technological revolution (popularly known as Industrie 4.0 or 4th Industrial Revolution) where our cars are being equipped with hundreds of sensors that make them safer, homes are becoming smarter, industry yields are at an all-time high, and internet-of-things is a reality. This was largely possible due to the developments in communication, electronics, motor controls, robotics, cyber security, software, efficient power distribution, etc. One of the major propellants of the 4th Industrial revolution is the ever-expanding applications of power electronics devices. All electrical energy will be provided, handled, and consumed through power electronics devices in the near future. Therefore, the reliability of power electronics devices will be instrumental in driving future technological advances. </p> <p> </p> <p><br></p><p>A myriad of devices is categorized as power electronics devices, and in the heart of those devices are the transistors. Although Silicon-based transistors still dominate the power electronics market, a paradigm shift towards wide bandgap semiconductors, such as silicon carbide (SiC), gallium nitride (GaN), beta-gallium oxide etc., is underway. However, realizing the full potential of these devices demands unconventional design, layout, and reliability. </p> <p> </p> <p>In this thesis, we try to establish a generalized model of reliability for power and logic transistors. We start by defining a comprehensive, substrate-, self-heating-, and reliability-aware safe operating area (SOA) that analytically establishes the optimum and self-consistent trade-off among breakdown voltage, power consumption, operating frequency, heat dissipation, and reliability before actual device fabrication. Then we take a deeper look into the reliability of individual transistors (a beta-gallium oxide transistor and a Silicon-based LDMOS), to test the predictions by the safe operating area, using both experiments and simulations. In the beta-gallium oxide transistor, we studied its implementation in a DC-DC voltage converter and concluded that the self-heating is a performance bottleneck and suggested approaches to alleviate it. For the LDMOS transistor, we investigated the hot carrier degradation (HCD) using experiments and simulations. We established that the HCD degradation kinetics is universal, and physics is the same as a classical transistor, despite a complicated geometry. Finally, we studied the correlation between HCD and radiation in LDMOS used in space shuttles, airplanes, etc., to determine its lifetime. </p><p><br></p> <p> </p> <p>We have holistically analyzed the reliability of power transistors by extending the theories of logic transistors in this thesis. Therefore, this thesis takes us a step closer to a generalized reliability model for power transistors by developing a comprehensive and predictive model for the safe operating area, encompassing all sources of stresses (e.g., electrical, thermal, and radiation) it experiences during operation.</p>

Hot Carrier Degradation

Safe Operating Area

Universal Scaling

Analytical Modeling

Power Electronics

Radiation

LDMOS

TCAD

HSPICE

Power Transistor

Trakční měniče velkých výkonů / High power traction converters

Žižka, Pavel

January 2008

This master thesis is based on realization of the previous university project, design of locomotive reconstruction and solving accompanying problems. In this thesis there are described all parts of a converter. The end of thesis involved theory about driver circuits of power transistors IGBT. Nowadays is still more often to think about reconstruction of the old technology rather than design a complete new construction. Investors take this decision from the financial reasons and because to the old technology designer can add only the converter. In this instant we talk about electrical locomotive, there should be kept a supply transformer and a driving unit (DC engine). The aim of this thesis is to design the converter between these two basic parts. The converter must taking the quasi-sinusoidal current which is in the phase with the input voltage, also must be able to control the engine and recuperate energy back to the network. For realization of these conditions, the converter must contain the active rectifier working in the DC-link and from which the step-down DC/DC converter is fed. Converter output is connected to the driving unit. The digital control of the power transistors is provided by processor MOTOROLA DSP56F. The control impulses, switching the power transistors, go through the driver circuits to transistors. All problems are described in the following text.

Technologie d’intégration monolithique des JFET latéraux / Technology of monolithic integration of Side JFET

Laariedh, Farah

13 May 2013

Le carbure de silicium (SiC) est un semi-conducteur à large bande d’énergie interdite, remarquable par ses propriétés physiques situées à mi-chemin entre le silicium et le diamant. Ceci suscite actuellement un fort intérêt industriel pour son utilisation dans la fabrication de composants susceptibles de fonctionner dans des conditions extrêmes : forte puissance et haute température. Les travaux de thèse se sont focalisés sur la levée de verrous technologiques pour réaliser des composants latéraux de type JFET (Junction Field Effect Transistor) et les intégrer monolithiquement dans des substrats SiC-4H. L’objectif est de réaliser un bras d’onduleur intégré en SiC avec deux étages commande et puissance. Dans un premier temps, nous avons entamé cette thèse par une caractérisation de deux lots de composants JFET latéraux à canaux N et P réalisés dans le cadre de deux projets ANR précédents cette thèse. De cette étude nous avons extrait plusieurs points positifs, comme celui qui concerne la tenue en tension des JFET de puissance et l’intégration monolithique des JFET basse tension. Mais, nous avons aussi mis en évidence, la nécessité d’optimiser la structure de composants et d’améliorer certaines étapes technologiques, principalement, la définition des canaux par implantation ionique, le contact ohmique et la gravure profonde. Des études approfondies pour réaliser le contact ohmique sur SiC type P et des procédés pour réaliser une gravure profonde dans le SiC ont été développés. Ces études ont permis d’obtenir une faible résistance de contact comparable à l’état de l’art mondial, d’avoir des calibres en courant plus élevés et par conséquent une meilleure modulation. Pour la gravure, un masque dur à base de silicium et nickel (NiSi), nous a permis de mettre en place un procédé original qui permet des gravures profondes du SiC et réaliser les structures intégrés des JFET. L’ensemble de ces améliorations technologiques nous a permis d’obtenir des nouveaux lots de composants JFET P et N intégrés sur la même puce, avec des meilleures performances par rapport aux précédentes réalisations, notamment avec une conduction dans les canaux 10 à 100 fois plus importante. Nous avons également obtenu une modulation du courant Ids en fonction de la tension Vgs sur un nombre très important de JFET en augmentant significativement le rendement par rapport aux lots précédents. / Silicon carbide (SiC) a semiconductor is as wide band gap, notable for its physical properties located between silicon and diamond. The inherent properties of silicon carbide (SiC) high thermal conductivity, and high breakdown voltage make it a very promising material for high power, high temperature and high-frequency device applications. The thesis focused on the removal of technological barriers to achieve lateral components JFET (Junction Field Effect Transistor) and monolithically integrated in SiC-4H substrates. The objective is to realize an arm of inverter integrated there SIC with two floors command and power. Initially, we started this thesis by a characterization of two lots of components JFET with channels N and P realized during two previous ANR this thesis. In this study, we extracted several positive points, such, the breakdown voltage of the JFET power and monolithic integration of low voltage JFET. But we have also highlighted the need to optimize the structure of components and improve some technological steps, mainly the definition channels by ion implantation, the ohmic contact and deep etching. Extensive to achieve ohmic contact on SiC P type and methods for performing deep etching in SiC studies have been developed. These studies have resulted in a low resistance comparable to the state of the art world contact, having sizes in higher current and therefore a better modulation. For etching, a hard mask to silicon and nickel (NiSi) has enabled us to develop a novel method that allows deep etching of SiC JFETs achieve integrated structures. All these technological improvements allowed us to get new batches of P and N JFET integrated on the same chip components with better performance compared to previous achievements, especially with conduction channels 10 to 100 times important. We also got a modulation current Ids as a function of the voltage Vgs on a large number of JFET significantly increasing the performance compared to previous batches.

Electronique de puissance

Carbure de silicium

Composant en Carbure de Silicium

JFET latéraux

Contact ohmique

Gravure plasma

Caractérisation électrique

Caractérisation de semiconducteurs

Power Electronics

Power Transistor

Silicon Carbide Component

Ohmic Contact

Deep etching

SemiConductor Characterisation

621.317 072