Refine
Document Type
- Conference proceeding (14)
- Journal article (1)
Has full text
- yes (15) (remove)
Is part of the Bibliography
- yes (15)
Institute
- Technik (12)
- ESB Business School (3)
Publisher
- VDE Verlag GmbH (15) (remove)
Class Phi2 amplifier using GaN HEMTs at 13.56MHz with tuned transformer for wireless power transfer
(2022)
This paper discusses a design procedure of a wireless power transfer system at a RF switching frequency of 13.56MHz. The wireless power transfer amplifier uses GaN HEMTs in aClass phi2 topology and is designed in order to achieve high efficiency and high power density. A design method for the load over a certain bandwidth is presented for a transformer with its tuning network.
Switched reluctance motors are particularly attractive due to their simple structure. The control of this machine type requires the instants, to switch the currents in the motor phases in an appropriate sequence. These switching instants are determined either based on a position sensor, or on signals generated by a sensorless method. A very simple sensorless method uses the switching frequency of the hysteresis controllers used for phase current control. This paper first presents an automatic commissioning method for this sensorless method and second a startup procedure, thus enhancing this approach towards an application in industry.
The current paper proposes a design method for an active damping approach for LC output filters in a power stage for motor control with continuous output voltage. The power stage uses GaN-HEMTs and operates at switching frequencies in a range between 500 kHz and 1MHz. The active damping of the output filter is achieved here by a feedback of the filter inductor current using a high-pass structure. The paper discusses the impact of this feedback on the system behavior and proposes a design method.
Electronic design automation approaches can roughly be divided into optimizers and procedures. While the former have enabled highly automated synthesis flows for digital integrated circuits, the latter play a vital (but mostly underestimated role) in the analog domain. This paper describes both automation strategies in comparison, identifying two fundamentally different automation paradigms that reflect the two basic design practices known as “top-down” and “bottom-up”. Then, with a focus on the latter, the history of procedural approaches is traced from their
early beginnings until today’s evolvements and future prospects to underline their practical importance and to accentuate their scientific value, both in itself and in the overall context of EDA.
This paper presents an improvement in usability and integrity of simulation-based analog circuit sizing. Instead of using geometrical sizing parameters (width, length), a transformed design-space, consisting exclusively of electrical parameters (branch currents, efficiencies and speed) is utilized. This design-space is explored more efficiently by optimizers. Moreover, this design-space can be reduced without affecting the quality of the result. The method is illustrated on two application examples, a symmetrical and a miller operational amplifier. Sizing the circuits using the transformed design-space showed significant reduction in required circuit simulations (up to 11x faster), better convergence, without loss in quality.
The integration of renewable energy sources in single family homes is challenging. Advance knowledge of the demand of electrical energy, heat, and domestic hot water (DHW) is useful to schedule projectable devices like heat pumps. In this work, we consider demand time series for heat and DHW from 2018 for a single family home in Germany. We compare different forecasting methods to predict such demands for the next day. While the 1-day-back forecast method led to the prediction of heat demand, the N-day-average performed best for DHW demand when Unbiased Exponentially Moving Average (UEMA) is used with a memory of 2.5 days. This is surprising as these forecasting methods are very simple and do not leverage additional information sources such as weather forecasts.
Industrielle Produktionseinrichtungen haben mit rund 40% einen signifikanten Anteil am Gesamtenergiebedarf in Deutschland. Daher wurden und werden sie sowohl technologisch als auch energetisch optimiert. Häufig geht die technologischwirtschaftliche Optimierung auch mit der Reduzierung des Energie und Materialverbrauchs einher. Zudem macht der Ausbau der regenerativen Energiequellen die Energieerzeugung zunehmend volatiler, sodass nicht nur die Senkung des absoluten Energieverbrauchs, sondern auch eine höhere Flexibilität (Steuerung der Leistung über der Zeit) zunehmend interessanter wird. Dadurch ändert sich oft die installierte Leistung sowie die Gestaltung der Verlustleistungsabfuhr, was die Dimensionierung von Anlagen, zum Beispiel von spanenden Werkzeugmaschinen, beeinflusst.
Mit der Überarbeitung der DIN EN 50173 (VDE 0800-173) Serie, wurden unter anderem die optischen Übertragungsstreckenklassen ersatzlos gestrichen. Um die so entstandene Lücke zu schließen, hat das deutsche Gremium DKE GUK 715.3 „Informationstechnische Verkabelung von Gebäudekomplexen“ neue Klassen erarbeitet, die in der DIN VDE 0800- 173-100 „Klassifizierung von Lichtwellenleiter-Übertragungsstrecken“ im Juni 2019 veröffentlicht wurden. Die Norm klassifiziert Lichtwellenleiter Übertragungsstrecken für anwendungsneutrale Kommunikationskabelanlagen nach DIN EN 50173-1.
Sie dient Benutzern, eine breite Palette von Anwendungen zu ermöglichen, die Auswahl des Verkabelungssystems zu erleichtern, eine zukunftssichere Klassifizierung von LWL-Verkabelungen zu generieren und dazu, Systemanforderungen zu beschreiben.
Die in der Norm definierten Klassen beschreiben die Anforderungen an die Übertragungsstrecken und basieren auf einer maximal zulässigen Einfügedämpfung in dB für maximale Übertragungsstreckenlängen, wobei zusätzlich das Bandbreitenlängenprodukt berücksichtigt wird.
Der Beitrag liefert einen Überblick über die Norm und zeigt Anwendungsbeispiele auf.
Power loss measurement of power electronic components and overall systems is sometimes difficult by use of electrical quantities and in few applications even not possible. The calorimetric power loss measurement is an established method to identify the overall system losses with a suitable accuracy. This paper presents a novel method with an open chamber calorimeter under accurate air mass flow, air pressure, humidity measurement and temperature control. The benefits are the approximately halved measurement time compared to established systems and the possibility to control the chamber temperature. So it is possible to measure the power losses at different ambient temperatures.
Usually battery chargers have two stages and DC charging current is considered to by necessary for a proper charging. To decrease the charger volume, a single stage LLC battery charger is investigated in this paper. PFC stage is eliminated, therefore no bulky capacitor is necessary any more, and battery is charged with a sinusoidal-like charging current. However, previous studies show that such a pulsating charging current has only minimal impact on battery life and efficiency. Design considerations of the resonant tank and optimal transformer design are presented. A 360W single stage LLC converter prototype for e-bike charger achieves a power factor of 0.98, efficiency of 0.93 and power density of 1,8kW/dm³.