Global ETD Search

21	Algorithms Designs and Implementations for Page Allocation in SSD Firmware and SSD Caching in Storage Systems Liang, Shuang January 2010 (has links) No description available. Computer Science flash memory disk cache cache algorithms page allocation algorithm firmware
22	On Performance Optimization and System Design of Flash Memory based Solid State Drives in the Storage Hierarchy Chen, Feng 28 September 2010 (has links) No description available. Computer Science solid state drive flash memory hard disk drive hybrid storage system
23	Towards a Flexible High-efficiency Storage System for Containerized Applications Zhao, Nannan 08 October 2020 (has links) Due to their tight isolation, low overhead, and efficient packaging of the execution environment, Docker containers have become a prominent solution for deploying modern applications. Consequently, a large amount of Docker images are created and this massive image dataset presents challenges to the registry and container storage infrastructure and so far has remained a largely unexplored area. Hence, there is a need of docker image characterization that can help optimize and improve the storage systems for containerized applications. Moreover, existing deduplication techniques significantly degrade the performance of registries, which will slow down the container startup time. Therefore, there is growing demand for high storage efficiency and high-performance registry storage systems. Last but not least, different storage systems can be integrated with containers as backend storage systems and provide persistent storage for containerized applications. So, it is important to analyze the performance of different backend storage systems and storage drivers and draw out the implications for container storage system design. These above observations and challenges motivate my dissertation. In this dissertation, we aim to improve the flexibility, performance, and efficiency of the storage systems for containerized applications. To this end, we focus on the following three important aspects: Docker images, Docker registry storage system, and Docker container storage drivers with their backend storage systems. Specifically, this dissertation adopts three steps: (1) analyzing the Docker image dataset; (2) deriving the design implications; (3) designing a new storage framework for Docker registries and propose different optimizations for container storage systems. In the first part of this dissertation (Chapter 3), we analyze over 167TB of uncompressed Docker Hub images, characterize them using multiple metrics and evaluate the potential of le level deduplication in Docker Hub. In the second part of this dissertation (Chapter 4), we conduct a comprehensive performance analysis of container storage systems based on the key insights from our image characterizations, and derive several design implications. In the third part of this dissertation (Chapter 5), we propose DupHunter, a new Docker registry architecture, which not only natively deduplicates layers for space savings but also reduces layer restore overhead. DupHunter supports several configurable deduplication modes, which provide different levels of storage efficiency, durability, and performance, to support a range of uses. In the fourth part of this dissertation (Chapter 6), we explore an innovative holistic approach, Chameleon, that employs data redundancy techniques such as replication and erasure-coding, coupled with endurance-aware write offloading, to mitigate wear level imbalance in distributed SSD-based storage systems. This high-performance fash cluster can be used for registries to speedup performance. / Doctor of Philosophy / The amount of Docker images stored in Docker registries is increasing rapidly and present challenges for the underlying storage infrastructures. Before we do any optimizations for the storage system, we should first analyze this big Docker image dataset. To this end, in this dissertation we perform the first large-scale characterization and redundancy analysis of the images and layers stored in the Docker Hub registry. Based on the findings, this dissertation presents a series of practical and efficient techniques, algorithms, optimizations to achieve high performance and flexibility, and space-efficient storage system for containerized applications. The experimental evaluation demonstrates the effectiveness of our optimizations and techniques to make storage systems flexible and space-efficacy. Containers Distributed storage systems Deduplication Wear Balancing Flash memory Docker registry Docker images
24	An Application Framework for a Power-Aware Processor Architecture Mandlekar, Anup Shrikant 31 August 2012 (has links) The instruction-set based general purpose processors are not energy-efficient for event-driven applications. The E-textiles group at Virginia Tech proposed a novel data-flow processor architecture design to bridge the gap between event-driven applications and the target architecture. The architecture, although promising in terms of performance and energy-efficiency, was explored for limited number of applications. This thesis presents a model-driven approach for the design of an application framework, facilitating rapid development of software applications to test the architecture performance. The application framework is integrated with the prior automation framework bringing software applications at the right level of abstraction. The processor architecture design is made flexible and scalable, making it suitable for a wide range of applications. Additionally, an embedded flash memory based architecture design for reduction in the static power consumption is proposed. This thesis estimates significant reduction in overall power consumption with the incorporation of flash memory. / Master of Science Low Power Flash Memory Cells Model Driven Engineering Simulink Dataflow Architecture
25	Optimisation des performance des logiciels de traitement de données sur les périphériques de stockage SSD / Performance optimization for data processing software on SSD storage devices Laga, Arezki 20 December 2018 (has links) Nous assistons aujourd’hui à une croissance vertigineuse des volumes de données. Cela exerce une pression sur les infrastructures de stockage et les logiciels de traitement de données comme les Systèmes de Gestion de Base de Données (SGBD). De nouvelles technologies ont vu le jour et permettent de réduire la pression exercée par les grandes masses de données. Nous nous intéressons particulièrement aux nouvelles technologies de mémoires secondaires comme les supports de stockage SSD (Solid State Drive) à base de mémoire Flash. Les supports de stockage SSD offrent des performances jusqu’à 10 fois plus élevées que les supports de stockage magnétiques. Cependant, ces nouveaux supports de stockage offrent un nouveau modèle de performance. Cela implique l’optimisation des coûts d’E/S pour les algorithmes de traitement et de gestion des données. Dans cette thèse, nous proposons un modèle des coûts d’E/S sur SSD pour les algorithmes de traitement de données. Ce modèle considère principalement le volume des données, l’espace mémoire alloué et la distribution des données. Nous proposons également un nouvel algorithme de tri en mémoire secondaire : MONTRES. Ce dernier est optimisé pour réduire le coût des E/S lorsque le volume de données à trier fait plusieurs fois la taille de la mémoire principale. Nous proposons enfin un mécanisme de pré-chargement de données : Lynx. Ce dernier utilise un mécanisme d’apprentissage pour prédire et anticiper les prochaines lectures en mémoire secondaire. / The growing volume of data poses a real challenge to data processing software like DBMS (DataBase Management Systems) and data storage infrastructure. New technologies have emerged in order to face the data volume challenges. We considered in this thesis the emerging new external memories like flash memory-based storage devices named SSD (Solid State Drive).SSD storage devices offer a performance gain compared to the traditional magnetic devices.However, SSD devices offer a new performance model that involves 10 cost optimization for data processing and management algorithms.We proposed in this thesis an 10 cost model to evaluate the data processing algorithms. This model considers mainly the SSD 10 performance and the data distribution.We also proposed a new external sorting algorithm: MONTRES. This algorithm includes optimizations to reduce the 10 cost when the volume of data is greater than the allocated memory space by an order of magnitude. We proposed finally a data prefetching mechanism: Lynx. This one makes use of a machine learning technique to predict and to anticipate future access to the external memory. Base de données Tri Pré-chargement de données Hiérarchie mémoire Mémoire flash SSD Database Sorting Prefetching Memory hierarchy Flash memory SSD 004.568
26	Structural And Electrical Properties Of Flash Memory Cells With Hfo2 Tunnel Oxide And With/without Nanocrystals Sahin, Dondu 01 July 2009 (has links) (PDF) In this study, flash memory cells with high-k dielectric HfO2 as tunnel oxide and group IV (Si, Ge) nanocrystals were fabricated and tested. The device structure was grown by magnetron sputtering deposition method and analyzed by various diagnostic techniques such as X-ray Photoelectron Spectroscopy (XPS) and Raman spectroscopy. The use of HfO2 tunnel oxide dielectric with high permittivity constant was one of the main purposes of this study. The ultimate aim was to investigate the use of Si and Ge nanocrystals together with HfO2 tunnel oxide in the memory elements. Interface structure of the fabricated devices was studied by XPS spectroscopy. A depth profile analysis was performed with XPS. Nanocrystal formations were verified using Raman spectroscopy technique. The final part of the study includes electrical characterization of memory devices fabricated using Si and Ge floating gate. C-V (Capacitance Voltage) and G-V (Conductance-Voltage) measurements and charge storage behaviour based on C-V measurements were performed. For comparison, structure of Si and Ge layers either in thin film or in the nanocrystal form were studied. A comparison of the C-V characteristics of these two structures revealed that the memory device with thin films do not confine charge carriers under the gate electrode as should be expected for a continuous film. On the other hand, the device with nanocrystals exhibited better memory behavior as a result of better confinement in the isolated nanocrystals. Trace amount of oxygen was found to be enough to oxidize Ge nanocrystals as confirmed by the Raman measurements. The charge storage capability is weakened in these samples as a result of Ge oxidation. In general, this work has demonstrated that high-k dielectric HfO2 and group IV nanocrystals can be used in the new generation MOS based memory elements. The operation of the memory elements are highly dependent on the material and device structures, which are determined by the process conditions. QC Physics 1-999
27	The differences between SSD and HDD technology regarding forensic investigations Geier, Florian January 2015 (has links) In the past years solid state disks have developed drastically and are now gaining increased popularity compared to conventional hard drives. While hard disk drives work predictable, transparent SSD routines work in the background without the user’s knowledge. This work describes the changes to the everyday life for forensic specialists; a forensic investigation includes data recovery and the gathering of a digital image of each acquired memory that provides proof of integrity through a checksum. Due to the internal routines, which cannot be stopped, checksums are falsified. Therefore the images cannot prove integrity of evidence anymore. The report proves the inconsistence of checksums of SSD and shows the differences in data recovery through high recovery rates on hard disk drives while SSD drives scored no recovery or very poor rates. SSD HHD Data Recovery Forensics Flash Memory Solid State Disk Hard Disk Drive TRIM Garbage collection Wear leveling NAND SandForce
28	USB zavaděč pro 8/32 bitové mikrokontroléry / USB bootloader for 8/32 bit microcontrollers Křenek, Pavel January 2009 (has links) This work deals with issues of in circuit programming with using a bootloader. The general aim is to create functional bootloader’s for the two different types of Freescale microcontrollers Freescale.
29	Disk na bázi paměti FLASH / Disk Drive Based on FLASH Memory Dvořák, Miroslav January 2012 (has links) The work deals with flash technology, the history of its development, current application of this technology and discusses the advantages and disadvantages of flash memories. It describes the integration of flash technology into mass storage devices and commonly used mechanisms that suppress the flash shortcomings for such application. The next part of the work focuses on analysis of commonly used buses for flash storage devices. Based on these theoretical foundations, text presents way to develop own flash based disk. The work focuses mainly on finding the most accessible platform for connecting the disk to personal computers - USB, on PCB design for storage module in Eagle CAD and implementation of necessary firmware for MCU and VHDL design for FPGA, that provide the disk functionality. At the end the work summarizes the results and outlines the way of further development.
30	A novel low-temperature growth method of silicon structures and application in flash memory Mih, Thomas Attia January 2011 (has links) Flash memories are solid-state non-volatile memories. They play a vital role especially in information storage in a wide range of consumer electronic devices and applications including smart phones, digital cameras, laptop computers, and satellite navigators. The demand for high density flash has surged as a result of the proliferation of these consumer electronic portable gadgets and the more features they offer – wireless internet, touch screen, video capabilities. The increase in the density of flash memory devices over the years has come as a result of continuous memory cell-size reduction. This size scaling is however approaching a dead end and it is widely agreed that further reduction beyond the 20 nm technological node is going to be very difficult, as it would result to challenges such as cross-talk or cell-to-cell interference, a high statistical variation in the number of stored electrons in the floating gate and high leakage currents due to thinner tunnel oxides. Because of these challenges a wide range of solutions in form of materials and device architectures are being investigated. Among them is three-dimensional (3-D) flash, which is widely acclaimed as the ideal solution, as they promise the integration of long-time retention and ultra-high density cells without compromising device reliability. However, current high temperature (>600 °C) growth techniques of the Polycrystalline silicon floating gate material are incompatible with 3-D flash memory; with vertically stacked memory layers, which require process temperatures to be ≤ 400 °C. There already exist some low temperature techniques for producing polycrystalline silicon such as laser annealing, solid-phase crystallization of amorphous silicon and metal-induced crystallization. However, these have some short-comings which make them not suitable for use in 3-D flash memory, e.g. the high furnace annealing temperatures (700 °C) in solid-phase crystallization of amorphous silicon which could potentially damage underlying memory layers in 3-D flash, and the metal contaminants in metal-induced crystallization which is a potential source of high leakage currents. There is therefore a need for alternative low temperature techniques that would be most suitable for flash memory purposes. With reference to the above, the main objective of this research was to develop a novel low temperature method for growing silicon structures at ≤ 400 °C. This thesis thus describes the development of a low-temperature method for polycrystalline silicon growth and the application of the technique in a capacitor-like flash memory device. It has been demonstrated that silicon structures with polycrystalline silicon-like properties can be grown at ≤ 400 °C in a 13.56 MHz radio frequency (RF) plasma-enhanced chemical vapour deposition (PECVD) reactor with the aid of Nickel Formate Dihydrate (NFD). It is also shown that the NFD coated on the substrates, thermally decomposes in-situ during the deposition process forming Ni particles that act as nucleation and growth sites of polycrystalline silicon. Silicon films grown by this technique and without annealing, have exhibited optical band gaps of ~ 1.2 eV compared to 1.78 eV for films grown under identical conditions but without the substrate being coated. These values were determined from UV-Vis spectroscopy and Tauc plots. These optical band gaps correspond to polycrystalline silicon and amorphous silicon respectively, meaning that the films grown on NFD-coated substrates are polycrystalline silicon while those grown on uncoated substrates remain amorphous. Moreover, this novel technique has been used to fabricate a capacitor-like flash memory that has exhibited hysteresis width corresponding to charge storage density in the order of 1012 cm-2 with a retention time well above 20 days for a device with silicon films grown at 300 °C. Films grown on uncoated films have not exhibit any significant hysteresis, and thus no flash memory-like behaviour. Given that all process temperatures throughout the fabrication of the devices are less than 400 °C and that no annealing of any sort was done on the material and devices, this growth method is thermal budget efficient and meets the crucial process temperature requirements of 3-D flash memory. Furthermore, the technique is glass compatible, which could prove a major step towards the acquisition of flash memory-integrated systems on glass, as well as other applications requiring low temperature polycrystalline silicon. 537.622

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