Global ETD Search

201	Scalable Register File Architecture for CGRA Accelerators January 2016 (has links) abstract: Coarse-grained Reconfigurable Arrays (CGRAs) are promising accelerators capable of accelerating even non-parallel loops and loops with low trip-counts. One challenge in compiling for CGRAs is to manage both recurring and nonrecurring variables in the register file (RF) of the CGRA. Although prior works have managed recurring variables via rotating RF, they access the nonrecurring variables through either a global RF or from a constant memory. The former does not scale well, and the latter degrades the mapping quality. This work proposes a hardware-software codesign approach in order to manage all the variables in a local nonrotating RF. Hardware provides modulo addition based indexing mechanism to enable correct addressing of recurring variables in a nonrotating RF. The compiler determines the number of registers required for each recurring variable and configures the boundary between the registers used for recurring and nonrecurring variables. The compiler also pre-loads the read-only variables and constants into the local registers in the prologue of the schedule. Synthesis and place-and-route results of the previous and the proposed RF design show that proposed solution achieves 17% better cycle time. Experiments of mapping several important and performance-critical loops collected from MiBench show proposed approach improves performance (through better mapping) by 18%, compared to using constant memory. / Dissertation/Thesis / Masters Thesis Computer Science 2016 Computer engineering Computer science Electrical engineering Accelerators Coarse Grained Reconfigurable Array Compiler Hardware-Software Co-design Register File Scalability
202	Arquitetura de co-projeto hardware/software para implementação de um codificador de vídeo escalável padrão H.264/SVC Husemann, Ronaldo January 2011 (has links) Visando atuação flexível em redes heterogêneas, modernos sistemas multimídia podem adotar o conceito da codificação escalável, onde o fluxo de vídeo é composto por múltiplas camadas, cada qual complementando e aprimorando gradualmente as características de exibição, de forma adaptativa às capacidades de cada receptor. Atualmente, a especificação H.264/SVC representa o estado da arte da área, por sua eficiência de codificação aprimorada, porém demanda recursos computacionais extremamente elevados. Neste contexto, o presente trabalho apresenta uma arquitetura de projeto colaborativo de hardware e software, que explora as características dos diversos algoritmos internos do codificador H.264/SVC, buscando um adequado balanceamento entre as duas tecnologias (hardware e software) para a implementação prática de um codificador escalável de até 16 camadas em formato de 1920x1080 pixels. A partir de um modelo do código de referência H.264/SVC, refinado para reduzir tempos de codificação, foram definidas estratégias de particionamento de módulos e integração entre entidades de software e hardware, avaliando-se questões como dependência de dados e potencial de paralelismo dos algoritmos, assim como restrições práticas das interfaces de comunicação e acessos à memória. Em hardware foram implementados módulos de transformadas, quantização, filtro anti-blocagem e predição entre camadas, permanecendo em software funções de gerência do sistema, entropia, controle de taxa e interface com usuário. A solução completa obtida, integrando módulos em hardware, sintetizados em uma placa de desenvolvimento, com o software de referência refinado, comprova a validade da proposta, pelos significativos ganhos de desempenho registrados, mostrando-se como uma solução adequada para aplicações que exijam codificação escalável tempo real. / In order to support heterogeneous networks and distinct devices simultaneously, modern multimedia systems can adopt the scalability concept, when the video stream is composed by multiple layers, each one being responsible for gradually enhance the video exhibition quality, according to specific receiver capabilities. Currently the H.264/SVC specification can be considered the state-of-art in this area, by improving the coding efficiency, but, in the other hand, impacting in extremely high computational demands. Based on that, this work presents a hardware/software co-design architecture, which explores the characteristics of H.264/SVC internal algorithms, aiming the right balancing between both technologies (hardware and software) in order to generate a practical scalable encoder implementation, able to process up to 16 layers in 1920x1080 pixels format. Based in an H.264/SVC reference code model, which was refined in order to reduce global encoding time, the approaches for module partitioning and data integration between hardware and software were defined. The proposed methodology took into account characteristics like data dependency and inherent possibility of parallelism, as well practical restrictions like influence of communication interfaces and memory accesses. Particularly, the modules of transforms, quantization, deblocking and inter-layer prediction were implemented in hardware, while the functions of system management, entropy, rate control and user interface were kept in software. The whole solution, which was obtained integrating hardware modules, synthesized in a development board, with the refined H.264/SVC reference code, validates the proposal, by the significant performance gains registered, indicating it as an adequate solution for applications which require real-time video scalable coding. Vídeo digital Algoritmos Hardware Software Scalable video coding H.264/SVC standard Hardware/software co-design Programmable logics
203	Arquitetura de co-projeto hardware/software para implementação de um codificador de vídeo escalável padrão H.264/SVC Husemann, Ronaldo January 2011 (has links) Visando atuação flexível em redes heterogêneas, modernos sistemas multimídia podem adotar o conceito da codificação escalável, onde o fluxo de vídeo é composto por múltiplas camadas, cada qual complementando e aprimorando gradualmente as características de exibição, de forma adaptativa às capacidades de cada receptor. Atualmente, a especificação H.264/SVC representa o estado da arte da área, por sua eficiência de codificação aprimorada, porém demanda recursos computacionais extremamente elevados. Neste contexto, o presente trabalho apresenta uma arquitetura de projeto colaborativo de hardware e software, que explora as características dos diversos algoritmos internos do codificador H.264/SVC, buscando um adequado balanceamento entre as duas tecnologias (hardware e software) para a implementação prática de um codificador escalável de até 16 camadas em formato de 1920x1080 pixels. A partir de um modelo do código de referência H.264/SVC, refinado para reduzir tempos de codificação, foram definidas estratégias de particionamento de módulos e integração entre entidades de software e hardware, avaliando-se questões como dependência de dados e potencial de paralelismo dos algoritmos, assim como restrições práticas das interfaces de comunicação e acessos à memória. Em hardware foram implementados módulos de transformadas, quantização, filtro anti-blocagem e predição entre camadas, permanecendo em software funções de gerência do sistema, entropia, controle de taxa e interface com usuário. A solução completa obtida, integrando módulos em hardware, sintetizados em uma placa de desenvolvimento, com o software de referência refinado, comprova a validade da proposta, pelos significativos ganhos de desempenho registrados, mostrando-se como uma solução adequada para aplicações que exijam codificação escalável tempo real. / In order to support heterogeneous networks and distinct devices simultaneously, modern multimedia systems can adopt the scalability concept, when the video stream is composed by multiple layers, each one being responsible for gradually enhance the video exhibition quality, according to specific receiver capabilities. Currently the H.264/SVC specification can be considered the state-of-art in this area, by improving the coding efficiency, but, in the other hand, impacting in extremely high computational demands. Based on that, this work presents a hardware/software co-design architecture, which explores the characteristics of H.264/SVC internal algorithms, aiming the right balancing between both technologies (hardware and software) in order to generate a practical scalable encoder implementation, able to process up to 16 layers in 1920x1080 pixels format. Based in an H.264/SVC reference code model, which was refined in order to reduce global encoding time, the approaches for module partitioning and data integration between hardware and software were defined. The proposed methodology took into account characteristics like data dependency and inherent possibility of parallelism, as well practical restrictions like influence of communication interfaces and memory accesses. Particularly, the modules of transforms, quantization, deblocking and inter-layer prediction were implemented in hardware, while the functions of system management, entropy, rate control and user interface were kept in software. The whole solution, which was obtained integrating hardware modules, synthesized in a development board, with the refined H.264/SVC reference code, validates the proposal, by the significant performance gains registered, indicating it as an adequate solution for applications which require real-time video scalable coding. Vídeo digital Algoritmos Hardware Software Scalable video coding H.264/SVC standard Hardware/software co-design Programmable logics
204	Co-design d’un bloc PA-antenne en technologie silicium pour application radar 80GHz / Co-design of a PA-Antenna block in silicon technology for 80GHz radar application Demirel, Nejdat 10 December 2010 (has links) Ce travail porte sur la conception d'un amplificateur de puissance à 79 GHz et la co-intégration de l'amplificateur de puissance et l'antenne en technologie silicium SiGe. L'objectif de la thèse est de développer un module radiofréquence à l'émission pour des applications radar à 79 GHz. Ce module sera composé d'un amplificateur de puissance, d'une antenne et du circuit d'adaptation PA/Antenne. L'inter-étage entre le PA et l'antenne est une source supplémentaire d'atténuation du signal, d‟autant plus rédhibitoire en technologie intégrée pour des fréquences aussi élevées. En réalisant une conception commune, ou co-design, de l'antenne et de l'amplificateur de puissance (PA), nous pouvons, à terme, nous affranchir du traditionnel inter-étage d'adaptation d'impédance entre ces deux blocs. Plus précisément, il convient de dimensionner l'antenne afin qu'elle présente a la sortie du PA l'impédance optimale que requiert son rendement en puissance maximum. / This work focuses on the design of a power amplifier (PA) at 79 GHz and the co-integration of the PA and the antenna on SiGe technology. The objective of this thesis is to develop a RF front-end block for radar applications at 79 GHz. This block is compound of a power amplifier, antenna and PA/Antenna inter-stage matching. The inter-stage between the PA and the antenna adds supplementary losses in the global performances, especially prohibitive in integrated technology for high frequencies. The co-design of the antenna and the PA allows to suppress the traditional inter-stage impedance matching between these two blocks. More specifically, it is suitable to design the antenna with the appropriate output impedance of the PA which gives optimal performances for maximum power and efficiency. Amplificateur de puissance, Co-intégration Fréquences millimétriques Application radar BiCMOS SiGe Power amplifier Co-design Millimeter frequencies Radar application SiGe BiCMOS
205	Co-design of Security Aware Power System Distribution Architecture as Cyber Physical System Youssef, Tarek 06 April 2017 (has links) The modern smart grid would involve deep integration between measurement nodes, communication systems, artificial intelligence, power electronics and distributed resources. On one hand, this type of integration can dramatically improve the grid performance and efficiency, but on the other, it can also introduce new types of vulnerabilities to the grid. To obtain the best performance, while minimizing the risk of vulnerabilities, the physical power system must be designed as a security aware system. In this dissertation, an interoperability and communication framework for microgrid control and Cyber Physical system enhancements is designed and implemented taking into account cyber and physical security aspects. The proposed data-centric interoperability layer provides a common data bus and a resilient control network for seamless integration of distributed energy resources. In addition, a synchronized measurement network and advanced metering infrastructure were developed to provide real-time monitoring for active distribution networks. A hybrid hardware/software testbed environment was developed to represent the smart grid as a cyber-physical system through hardware and software in the loop simulation methods. In addition it provides a flexible interface for remote integration and experimentation of attack scenarios. The work in this dissertation utilizes communication technologies to enhance the performance of the DC microgrids and distribution networks by extending the application of the GPS synchronization to the DC Networks. GPS synchronization allows the operation of distributed DC-DC converters as an interleaved converters system. Along with the GPS synchronization, carrier extraction synchronization technique was developed to improve the system’s security and reliability in the case of GPS signal spoofing or jamming. To improve the integration of the microgrid with the utility system, new synchronization and islanding detection algorithms were developed. The developed algorithms overcome the problem of SCADA and PMU based islanding detection methods such as communication failure and frequency stability. In addition, a real-time energy management system with online optimization was developed to manage the energy resources within the microgrid. The security and privacy were also addressed in both the cyber and physical levels. For the physical design, two techniques were developed to address the physical privacy issues by changing the current and electromagnetic signature. For the cyber level, a security mechanism for IEC 61850 GOOSE messages was developed to address the security shortcomings in the standard. Smart Grid Cyber-physical system Co-design Controls and Control Theory Digital Communications and Networking Power and Energy Systems and Communications
206	Ladicí nástroj generických simulátorů mikroprocesorů / Debugger for Generic Microprocessor Simulators Wilczák, Milan January 2010 (has links) Application specific instruction set processors become part of every day life although it's not always visible at first sight. During their development it's needed to somehow describe their architecture, instruction set and behavior. To make their developement worth, it's necessary to be able to create applications for these processors and during application development errors are always made. Debuggers serve to discover and help fixing them. This paper summarises some basic information to debugger development and describes implementation for processors created using the Lissom project.
207	Designing with and for People with Dementia: Wellbeing, Empowerment and Happiness Niedderer, Kristina, Ludden, Geke, Cain, Rebecca, Wölfel, Christian 13 November 2019 (has links) Designing with and for People with Dementia: Wellbeing, Empowerment and Happiness is the International Conference 2019 of the MinD Consortium, the DRS Special Interest Group on Behaviour Change and the DRS Special Interest Group on Wellbeing and Happiness, hosted by the Technische Universität Dresden, in Dresden, Germany. The conference proceedings provide trans-disciplinary contributions for researchers, practitioners, end-users and policy makers from the design and health care professions in terms of new findings, approaches and methods for using design to improve dementia care and to support people with dementia and their carers. The conference has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement No 691001, and from the DFG German Research Foundation. info:eu-repo/classification/ddc/620 ddc:620
208	Hierarchical Combined Plant and Control Design for Thermal Management Systems Austin L Nash (8063924) 03 December 2019 (has links) Over the last few decades, many factors, including increased electrification, have led to a critical need for fast and efficient transient cooling. Thermal management systems (TMSs) are typically designed using steady-state assumptions and to accommodate the most extreme operating conditions that could be encountered, such as maximum expected heat loads. Unfortunately, by designing systems in this manner, closed-loop transient performance is neglected and often constrained. If not constrained, conventional design approaches result in oversized systems that are less efficient under nominal operation. Therefore, it is imperative that \emph{transient} component modeling and subsystem interactions be considered at the design stage to avoid costly future redesigns. Simply put, as technological advances create the need for rapid transient cooling, a new design paradigm is needed to realize next generation systems to meet these demands. <br><br>In this thesis, I develop a new design approach for TMSs called hierarchical control co-design (HCCD). More specifically, I develop a HCCD algorithm aimed at optimizing high-fidelity design and control for a TMS across a system hierarchy. This is accomplished in part by integrating system level (SL) CCD with detailed component level (CL) design optimization. The lower-fidelity SL CCD algorithm incorporates feedback control into the design of a TMS to ensure controllability and robust transient response to exogenous disturbances, and the higher-fidelity CL design optimization algorithms provide a way of designing detailed components to achieve the desired performance needed at the SL. Key specifications are passed back and forth between levels of the hierarchy at each iteration to converge on an optimal design that is responsive to desired objectives at each level. The resulting HCCD algorithm permits the design and control of a TMS that is not only optimized for steady-state efficiency, but that can be designed for robustness to transient disturbances while achieving said disturbance rejection with minimal compromise to system efficiency. Several case studies are used to demonstrate the utility of the algorithm in designing systems with different objectives. Additionally, high-fidelity thermal modeling software is used to validate a solution to the proposed model-based design process. <br> Mechanical Engineering Control Systems, Robotics and Automation energy systems control co-design robust control nonlinear optimization
209	ComPron : Learning Pronunciation through Building Associations between Native Language and Second Language Speech Sounds Lessing, Sara January 2020 (has links) Current computer-assisted pronunciation training (CAPT) tools are too focused on what technologies can do, rather than focusing on learner needs and pedagogy. They also lack an embodied perspective on learning. This thesis presents a Research through Design project exploring what kind of interactive design features can support second language learners’ pronunciation learning of segmental speech sounds with embodiment in mind. ComPron was designed: an open simulated prototype that supports learners in learning perception and production of new segmental speech sounds in a second language, by comparing them to native language speech sounds. ComProm was evaluated through think-aloud user tests and semi-structured interviews (N=4). The findings indicate that ComPron supports awareness of speech sound-movement connections, association building between sounds, and production of sounds. The design features that enabled awareness, association building, and speech sound production support are discussed and what ComPron offers in comparison to other CAPT-tools. Research through Design (RtD) Co-design Embodied Learning Human Computer Interaction
210	Implementation of an FPGA based Emulator for High Speed Power Electronic Systems Adnan, Muhammad Wasif January 2014 (has links) During development of control systems for power electronic systems, it is desirable to test the controller in real-time, by interfacing it with an emulator device. In this context, this work comprises the development of an emulator that can model accurately the dynamics of high speed power electronic systems and provides interfaces that are compatible with the real hardware. The realtime state calculations, based on discrete models, were performed on custom logic, implemented on an FPGA. The realized system allows to emulate Linear Parameter Varying (LPV) systems, achieving sampling rates up to 12MHz using a low cost Xilinx FPGA. As a result, power electronic systems with very high switching frequencies can be modeled. In addition, the FPGA incorporates a soft-core processor that allows a designer to easily re-configure the system model through software. The emulator system has been validated for a multiphase DC-DC converter, by comparing its results with the real hardware setup. Hardware-in-Loop Simulations Control of Power Electronic Systems FPGA Hardware-Software Co-design Elektroteknik och elektronik

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