Voltage scaling interfaces for multi-voltage digital systems / Interfaces de escalonamento de tensão para sistemas digitais de multiplas tensões

Llanos, Roger Vicente Caputo

January 2015

Os Sistemas Digitais de Múltiplas Tensões exploram o conceito de dimensionamento da tensão de alimentação através da aplicação de diferentes fontes para regiões específicas do chip. Cada uma destas regiões pertence a um domínio de energia e pode ter duas ou mais configurações de voltagens. Independentemente dos distintos níveis de energia em diferentes domínios de tensão, os blocos devem processar sinais com níveis lógicos coerentes. Nestes sistemas, os Conversores de Nível (LS do inglês Level Shifters) são componentes essenciais que atuam como interfaces de escalonamento da tensão entre domínios de energia, garantindo a correta transmissão dos sinais. Com a apropriada interface de escalonamento de tensão e sua correta implementação, pode-se evitar o consumo excessivo de potência dinâmica e estática. Portanto, a concepção e implementação de conversores de nível deve ser um processo consciente que garanta o menor sobrecusto no tamanho, consumo de energia, e tempo de atraso. Neste trabalho estudam-se as principais características das interfaces de escalonamento de tensão e se introduce um conversor de tensão com eficiência energética e área reduzida, adequado para a conversão de baixo a alto nível. Apresentam-se os conversores de nível com o melhor desempenho encontrados na literatura, os quais são categorizados em dois principais grupos: Dois trilhos (Dual-rail) e Único trilho (Single-rail), de acordo ao número de linhas de alimentação necessárias. O circuito proposto foi comparado com a topologia tradicional de cada grupo, o Differential Cascode Voltage Switch (DCVS) e o conversor de Puri respectivamente. Simulações na tecnologia CMOS 130nm da IBMTM mostram que a topologia proposta requer até 93,79% menos energia em determinadas condições. Esta apresentou 88,03% menor atraso e uma redução de 39,6% no Produto Potência-Atraso (PDP), quando comparada com a topologia DCVS. Em contraste com o conversor Puri, obteve-se uma redução de 32,08% no consumo de energia, 13,26% diminuição no atraso e 15,37% inferior PDP. Além disso, o conversor de nível proposto foi o único capaz de trabalhar a 35% da tensão nominal de alimentação. / Multiple Voltage Digital Systems exploit the concept of voltage scaling by applying different supplies to particular regions of the chip. Each of those regions belongs to a power domain and may have two or more supply voltage configurations. Regardless of distinct energy levels on different power domains, the blocks shall process signals with coherent logic levels. In these systems, the Level Shifters (LS) are essential components that act as voltage scaling interfaces between power domains, guaranteeing the correct signal transmission. With the appropriate voltage scaling interface and its proper implementation, we can avoid excessive static and dynamic power consumption. Therefore, the design and implementation of level shifters should be a conscientious process and must guarantee the lowest overhead in size, energy consumption, and delay time. In this work, we study the main characteristics of voltage scaling interfaces and introduce an energy-efficient level shifter with reduced area, and suitable for low-to-high level conversion. We present the level shifters with the best performance that we found in the literature and categorize them into two main groups: Dual-rail and Single-rail, according to the number of power rails required. The proposed circuit was compared to the traditional topology of each group, Differential Cascode Voltage Switch (DCVS) and Puri’s level shifter respectively. Simulations on an IBMTM 130nm CMOS technology show that the proposed topology requires up to 93.79% less energy under certain conditions. It presented 88.03% smaller delay and 39.6% less Power-Delay Product (PDP) when compared to the DCVS topology. In contrast with the Puri’s level shifter, we obtained a reduction of 32.08% in power consumption, 13.26% smaller delay and 15.37% lower PDP. Besides, our level shifter was the only one capable of working at 35% of the nominal supply voltage.

Circuitos digitais

Microeletrônica

Tensão elétrica

Level shifter

Low power

Multiple supply voltage

Power-delay product

CMOS

Dynamic power

Static power

Voltage scaling interfaces for multi-voltage digital systems / Interfaces de escalonamento de tensão para sistemas digitais de multiplas tensões

Llanos, Roger Vicente Caputo

January 2015

Os Sistemas Digitais de Múltiplas Tensões exploram o conceito de dimensionamento da tensão de alimentação através da aplicação de diferentes fontes para regiões específicas do chip. Cada uma destas regiões pertence a um domínio de energia e pode ter duas ou mais configurações de voltagens. Independentemente dos distintos níveis de energia em diferentes domínios de tensão, os blocos devem processar sinais com níveis lógicos coerentes. Nestes sistemas, os Conversores de Nível (LS do inglês Level Shifters) são componentes essenciais que atuam como interfaces de escalonamento da tensão entre domínios de energia, garantindo a correta transmissão dos sinais. Com a apropriada interface de escalonamento de tensão e sua correta implementação, pode-se evitar o consumo excessivo de potência dinâmica e estática. Portanto, a concepção e implementação de conversores de nível deve ser um processo consciente que garanta o menor sobrecusto no tamanho, consumo de energia, e tempo de atraso. Neste trabalho estudam-se as principais características das interfaces de escalonamento de tensão e se introduce um conversor de tensão com eficiência energética e área reduzida, adequado para a conversão de baixo a alto nível. Apresentam-se os conversores de nível com o melhor desempenho encontrados na literatura, os quais são categorizados em dois principais grupos: Dois trilhos (Dual-rail) e Único trilho (Single-rail), de acordo ao número de linhas de alimentação necessárias. O circuito proposto foi comparado com a topologia tradicional de cada grupo, o Differential Cascode Voltage Switch (DCVS) e o conversor de Puri respectivamente. Simulações na tecnologia CMOS 130nm da IBMTM mostram que a topologia proposta requer até 93,79% menos energia em determinadas condições. Esta apresentou 88,03% menor atraso e uma redução de 39,6% no Produto Potência-Atraso (PDP), quando comparada com a topologia DCVS. Em contraste com o conversor Puri, obteve-se uma redução de 32,08% no consumo de energia, 13,26% diminuição no atraso e 15,37% inferior PDP. Além disso, o conversor de nível proposto foi o único capaz de trabalhar a 35% da tensão nominal de alimentação. / Multiple Voltage Digital Systems exploit the concept of voltage scaling by applying different supplies to particular regions of the chip. Each of those regions belongs to a power domain and may have two or more supply voltage configurations. Regardless of distinct energy levels on different power domains, the blocks shall process signals with coherent logic levels. In these systems, the Level Shifters (LS) are essential components that act as voltage scaling interfaces between power domains, guaranteeing the correct signal transmission. With the appropriate voltage scaling interface and its proper implementation, we can avoid excessive static and dynamic power consumption. Therefore, the design and implementation of level shifters should be a conscientious process and must guarantee the lowest overhead in size, energy consumption, and delay time. In this work, we study the main characteristics of voltage scaling interfaces and introduce an energy-efficient level shifter with reduced area, and suitable for low-to-high level conversion. We present the level shifters with the best performance that we found in the literature and categorize them into two main groups: Dual-rail and Single-rail, according to the number of power rails required. The proposed circuit was compared to the traditional topology of each group, Differential Cascode Voltage Switch (DCVS) and Puri’s level shifter respectively. Simulations on an IBMTM 130nm CMOS technology show that the proposed topology requires up to 93.79% less energy under certain conditions. It presented 88.03% smaller delay and 39.6% less Power-Delay Product (PDP) when compared to the DCVS topology. In contrast with the Puri’s level shifter, we obtained a reduction of 32.08% in power consumption, 13.26% smaller delay and 15.37% lower PDP. Besides, our level shifter was the only one capable of working at 35% of the nominal supply voltage.

Circuitos digitais

Microeletrônica

Tensão elétrica

Level shifter

Low power

Multiple supply voltage

Power-delay product

CMOS

Dynamic power

Static power

Předzesilovače pro zpracování biologických signálů / Preamplifier for biological signals processing

Derishev, Anton

January 2014

The work deals with the design and optimization of amplifiers in CMOS technology with low supply voltage and low power consumption. The main aim is to design an amplifier to amplify the biological signal. The first part is a brief introduction to the theory of biological signals. The work also contains a brief description of the biological signal processing methods and their properties. The important part is the description of the methods to reduce the supply voltage of the amplifier. The practical part of this thesis focuses on the design amplifiers with low supply voltage and low power consumption. All active elements and application examples have been verified by PSpice simulator using the 0.18 µm TSMC CMOS parameters. Simulated plots are included in this thesis to illustrate behavior of structures.

Univerzální napájecí zdroj s mikrokontrolérem / General-purpose power supply with microcontroller

Jorda, Ivo

January 2014

The aim of this thesis is design of adjustable switched mode power supply with symmetrical output of 25 V, and switched mode power supply with fixed output voltage of 5 V. Required maximum output current of each outputs is 3 A. At the beginning of the paper function of the basic SMPS topologies is described. Next all reqiured SMPSs are designed and chosen parts of the design are simulated. In the second half of the thesis assembly and testing of PCB are described as well as functions of programs. Last chapter contains results of meassurement of power supply paramters.

Lineární aktivní filtr napájecího napětí „Ripple Blocker“ / Linear active filter of supply voltage „Ripple Blocker“

Vlček, Pavel

January 2015

This work deals with a methods for increasing the PSRR of the linear active filters of supply voltage or if linear regulators and voltage range of supply, primarily his minimal value. In the work are used ideal parts of reference voltage source and reference current source. The work describes how to eliminate effect of feedback loop on the PSRR, how to decrrease minimal power supply voltage and how to set stability of total schematic.

Digitálně řízený zdroj generující proudové impulzy nastavitelného náběhu a trvání / Digitally controllable power-supply generating current pulses with adjustable rising slope and duration

Dujíček, Martin

January 2014

Master’s thesis is focused on design of digitally controllable power-supply for generating current pulses with nominal level (few amperes), adjustable rising slope and time of duration. Device uses voltage controlled current source. Control voltage is generated by digital to analog converter. Computer simulations are accomplished for designed electronic circuit and measurement of prototype is done as well.

New Mixed-Mode Chireix Outphasing Theory and Frequency-Agile Clockwise-Loaded Class-J Theory for High Efficiency Power Amplifiers

Chang, Hsiu-Chen

January 2020

No description available.

Electrical Engineering

Blindleistungsbereitstellung aus Flächenverteilnetzen - praktische Umsetzung in einem Feldtest

Kreutziger, Markus, Wende-von-Berg, Sebastian, Krahmer, Sebastian, Schegner, Peter

19 March 2024

Im Rahmen des Beitrags sollen das Potenzial der Blindleistungsbereitstellung und mögliche Regelungskonzepte im Kontext von Redispatch 2.0 dargestellt werden. Ein umfangreicher Feldtest zeigt das Zusammenspiel von Übertragungs und Verteilnetzbetreibern bezüglich einer spannungsebenenübergreifenden Blindleistungsregelung auf. Neben der Konzeption und Entwicklung aller Systemkomponenten wurden die Funktionalität einer aktiven Blindleistungsregelung und deren Wirkung auf den realen Netzbetrieb evaluiert.

info:eu-repo/classification/ddc/620

ddc:620

info:eu-repo/classification/ddc/004

ddc:004

Laboratorní zdroj s vysokou účinností / High efficiency laboratory power supply

Tejmlová, Lenka

January 2011

The project shows the problems of power supply in electrical engineering. It describes the general parameters of these types of supplies and presents their characteristics. Based on these findings, it is also focused on the selection of specific elements of the laboratory supply, to reach the given parameters. It contains the recalculations of the parameters of other additional components. The overall scheme of the supply is divided into several blocks, thematically corresponded to subchapters. According to the accomplished concept the laboratory supply is realized and its parameters had been tested. Projects results are assessed at the end.

Návrh a identifikace rozšířeného modelu MEMS gyroskopu / An Extended Model of a MEMS Gyroscope: Design and Identification

Vágner, Martin

January 2016

The thesis is aimed on measurement and modeling of MEMS gyroscopes based on input-output characteristics. The first part briefs the state of the art. The second part is dedicated to measurement methodology. Critical points and sources of uncertainty are discussed and evaluated using measurements or simulations. The last part shows key characteristics of MEMS gyroscopes based on the survey of a group of different sensor types. The results have revealed significant influence of supply voltage that causes bias drift of the gyroscope and bias drift of the internal temperature sensor. The error can be comparable to temperature drift; however, this effect is not addressed in the literature. The second observed effect is temperature dependency of angle random walk. In the last part, a general model of a MEMS gyroscope is rewritten to reflect observed effects. Moreover, the structure is selected to be easily extendable and the coefficients are expressed to allow a comparison of nominal parameters of different sensors.