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The maintenance issue of batteries and the limited power level of energy harvesting is addressed by the presented integrated micropower supply. Connected to the 120/230-VRMS mains, it provides a 3.3-V ac output voltage, suitable for applications such as the Internet-of Things and smart homes. The micropower supply consists of a fully integrated ac–dc and dc–dc converter with one external low-voltage surface mount device buffer capacitor, resulting in an extremely compact size. Fabricated in a low-cost 0.35-μm 700-V complimentary metal-oxide-semiconductor technology, it covers a die size of 7.7 mm². The ac–dc converter is a direct coupled, full-wave rectifier with a subsequent series regulator. The dc–dc stage is a fully integrated capacitive 4:1 converter with up to 17-V input and 47.4% peak efficiency. The power supply comprises several high-voltage control circuits including level shifters and various types of charge pumps (CPs). A source supplied CP is utilized that supports a varying switching node potential. The overall losses are discussed and optimized, including flying capacitor bottom-plate losses. The power supply achieves an output power of 3 mW, resulting in a power density of 390 μW/mm². This exceeds prior art by a factor of 11.
Erfindungsgemäß wird ein Verfahren zur Optimierung des Betriebs eines in einem Regelkreis für einen Aufwärtswandler vorgesehenen digitalen Reglers (30) zur Verfügung gestellt. Das Verfahren umfasst die folgenden Verfahrensschritte: Auswerten (S1) mindestens einer Ausgangsgröße des digitalen Reglers im Betrieb des Aufwärtswandlers. Schätzen (S2) des instantanen Lastwiderstandswertes (RL) in der Strecke des Regelkreises anhand der mindestens einen ausgewerteten Ausgangsgröße. Einstellen (S3) mindestens eines Reglerkoeffizienten des digitalen Reglers anhand des geschätzten instantanen Lastwiderstandswertes (RL) im Betrieb des Aufwärtswandlers. Erfindungsgemäß bedingt eine Veränderung in der Einstellung des mindestens einen Reglerkoeffizienten eine Veränderung der Transitfrequenz im Regelkreis. Ferner wird ein Regelkreis für einen Aufwärtswandler mit einem digitalen Regler zur Verfügung gestellt, welcher eingerichtet ist, um die Schritte des erfindungsgemäßen Verfahrens durchzuführen. Des Weiteren wird ein Computerprogrammprodukt mit computerausführbarem Programmcode zur Durchführung des erfindungsgemäßen Verfahrens zur Verfügung gestellt.
This work presents a fully integrated GaN gate driver in a 180nm HV BCD technology that utilizes high-voltage energy storing (HVES) in an on-chip resonant LC tank, without the need of any external capacitor. It delivers up to 11nC gate charge at a 5V GaN gate, which exceeds prior art by a factor of 45-83, supporting a broad range of GaN transistor types. The stacked LC tank covers an area of only 1.44mm², which corresponds to a superior value of 7.6nC/mm².
In recent years, significant progress was made on switched-capacitor DCDC converters as they enable fully integrated on chip power management. New converter topologies overcame the fixed input-to-output voltage limitation and achieved high efficiency at high power densities. SC converters are attractive to not only mobile handheld devices with small input and output voltages, but also for power conversion in IoTs, industrial and automotive applications, etc. Such applications need to be capable of handling high input voltages of more than 10V. This talk highlights the challenges of the required supporting circuits and high voltage techniques, which arise for high Vin SC converters. It includes level shifters, charge pumps and back-to-back switches. High Vin conversion is demonstrated in a 4:1 SC DCDC converter with an input voltage as high as 17V with a peak efficiency of 45 %, and a buckboost SC converter with an input voltage range starting from 2 up to 13V, which utilizes a total of 17 ratios and achieves a peak efficiency of 81.5 %. Furthermore a highly integrated micro power supply approach is introduced, which is connected directly to the 120/230 Vrms mains, with an output power of 3mW, resulting in a power density >390μW/mm², which exceeds prior art by a factor of 11.
Multilevel-cell (MLC) flash is commonly deployed in today’s high density NAND memories, but low latency and high reliability requirements make it barely used in automotive embedded flash applications. This paper presents a time domain voltage sensing scheme that applies a dynamic voltage ramp at the cells’ control gate (CG) in order to achieve fast and reliable sensing suitable for automotive applications.
Die Erfindung betrifft eine Vorrichtung (100) und ein Verfahren zum elektrischen Verbinden und Trennen zweier elektrischer Potentiale (1, 2). Des Weiteren betrifft die Erfindung eine Verwendung der Vorrichtung (100). Dabei umfasst die Vorrichtung (100): – ein erstes Modul, welches einen ersten und einen zweiten Transistor (10a, 10b) umfasst, wobei der erste Transistor (10a) antiseriell zu dem zweiten Transistor (10b) geschaltet ist; und – ein zweites Modul, welches einen dritten und einen vierten Transistor (10c, 10d) umfasst, wobei der dritte Transistor (10c) antiseriell zu dem vierten Transistor (10d) geschaltet ist; wobei das erste Modul und das zweite Modul parallel geschaltet sind.
A device including a first and second monitoring unit, the first monitoring unit detecting a first voltage potential and the second monitoring unit detecting a second voltage potential, the monitoring units comparing the first voltage potential and the second voltage potential to the value of the supply voltage and activate a control unit as a function of the comparisons, the control unit determining a switching point in time of a second power transistor, and an arrangement being present which generates current when the second power transistor is being switched on, the current changing the first voltage potential, and the control unit activates a first power transistor when the first voltage potential has the same value as the supply voltage, so that the first power transistor is de-energized.
The presented wide-Vin step-down converter introduces a parallel-resonant converter (PRC), comprising an integrated 5-bit capacitor array and a 300 nH resonant coil, placed in parallel to a conventional buck converter. Unlike conventional resonant concepts, the implemented soft-switching control eliminates input voltage dependent losses over a wide operating range. This ensures high efficiency across a wide range of Vin= 12-48V, 100-500mA load and 5V output at up to 15MHz switching frequency. The peak efficiency of the converter is 76.3 %. Thanks to the low output current ripple, the output capacitor can be as small as 50 nF, while the inductor tolerates a larger ESR, resulting in small component size. The proposed PRC architecture is also suitable for future power electronics applications using fast-switching GaN devices.
More and more power electronics applications utilize GaN transistors as they enable higher switching frequencies in comparison to conventional Si devices. Faster switching shrinks down the size of passives and enables compact solutions in applications like renewable energy, electrical cars and home appliances. GaN transistors benefit from ~10× smaller gate charge QG and gate drive voltages in the range of typically 5V vs. ~15V for Si.