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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Library support for historical and persistent data structures in non-volatile memories

Chatzistergiou, Andreas January 2016 (has links)
In the context of emerging non-volatile memory (NVM) where data structures can persist in-memory and are accessed through CPU loads and stores, we study how to efficiently manage data evolution. This is an extensively applied problem in both the scientific and business domains and is rapidly becoming an important component for a wider range of applications. We argue that the best way to achieve a smoother transition to the new programming model is to design a solution that is non-intrusive and generic i.e. not bound to a specific data model. We propose a novel library-level approach where the user can manage historical data directly from programming language code. This is achieved with a combination of two software layers: REWIND and VARIANT. At the bottom, lies REWIND (REcovery Write-Ahead System for In- Memory Non-Volatile Data Structures) which handles the low level specifics of NVM by dealing with write-ordering problems that arise in such context and allows recoverability of arbitrary data structures. Then, VARIANT (Versioning ARbItrary dAta structures in Non-volatile memory for Time-travel) focuses on versioning and time travel (moving between versions). We adopt a logging approach and we tightly integrate both systems for best performance by utilizing a common physical log of memory operations. With REWIND, we propose a novel recoverable log structure that permits atomic and durable appends and removals of log records. This is the keystone for building recoverable systems on top of NVM. Because latencies in recent NVM technologies such as Phase-change memory (PCM) are asymmetric, we propose novel techniques for reducing the write pressure of the recoverable log as well as mitigating the effect of synchronization control primitives such as memory fences (enhanced for NVM), i.e. barriers that enforce ordering and persistence to preceding instructions. We also propose different implementations for trading logging performance for rollback performance when this is appropriate. Finally, we revisit state-of-the-art recovery algorithms for the new context given the different latencies and synchronization control. Our results clearly indicate that current approaches for recoverability are ill-fitted for persisting data structures in the new context and it is possible to achieve low-overhead logging with customized mechanisms. Next, we focus on data evolution. We expose a simple API that allows versioning and time travel with minimal intrusiveness. We propose mechanisms for efficient and transparent cloning of Versionable data structures. This allows high concurrency since past images are returned as copies of the original data structure which remains intact. Then, we propose novel indexing techniques that significantly improve time travel performance as well as cloning with lazy schemes. We achieve a low overhead architecture by employing a mix of volatile and non-volatile data structures as well as hybrid structures that reside in both volatile and non-volatile memories. We perform an extensive evaluation of the proposed techniques and conclude that, in our context, by carefully mitigating the drawbacks of physical logging it is possible to create efficient systems for managing data evolution that are both data structure agnostic and non-intrusive.
2

Μοντελοποίηση και εξομοίωση των χαρακτηριστικών γήρανσης NV μνημών

Προδρομάκης, Αντώνιος 12 June 2015 (has links)
Τις τελευταίες δεκαετίες, η ανάπτυξη των non-volatile μνημών (NVMs) κατέστησε ικανή την αντικατάσταση volatile μνημών, όπως των DRAMs και των μαγνητικών σκληρών δίσκων (HDDs), σε caching και storage εφαρμογές, αντίστοιχα. Οι δίσκοι στερεάς κατάστασης (SSDs) που βασίζονται σε NAND Flash μνήμες έχουν ήδη αναδειχθεί ως ένα χαμηλού κόστους, υψηλής απόδοσης και αξιόπιστο μέσο στα σύγχρονα συστήματα αποθήκευσης. Επιπλέον, οι ιδιότητες των υλικών αλλαγής φάσης και η πρόσφατη κλιμάκωση της Phase-Change μνήμης (PCM), την καθιστά ένα τέλειο υποψήφιο για την ανάπτυξη μνημών τυχαίας προσπέλασης αλλαγής φάσης (PCRAMs). Η ραγδαία κλιμάκωση των NVMs, με διαδικασίες ολοκλήρωσης κάτω από 19nm, και η χρήση της multi-level cell (MLC) τεχνολογίας συνέβαλλαν στην αύξηση της πυκνότητας αποθήκευσης πληροφορίας και συνεπώς μείωσαν το κόστος αποθήκευσης δραματικά. Ωστόσο, η διάρκεια ζωής των NV μνημών δεν παρέμεινε ανεπηρέαστη. Διαφορετικές παρεμβολές και πηγές θορύβου σε συνδυασμό με την επίδραση της γήρανσης έχουν ένα μεγάλο αντίκτυπο στην αξιοπιστία και την αντοχή αυτών των τεχνολογιών μνήμης, και ως εκ τούτου, των συστημάτων αποθήκευσης στα οποία χρησιμοποιούνται (SSDs, PCRAMs). Πολλές μέθοδοι και τεχνικές, όπως η μέθοδος wear-leveling, εξειδικευμένοι κώδικες ανίχνευσης και διόρθωσης λαθών (ECC) και τεχνικές pre-coding έχουν χρησιμοποιηθεί για να αντισταθμίσουν αυτές τις επιπτώσεις, ενώ άλλες, πιο περίπλοκες μεν, αλλά και πιο αποτελεσματικές, όπως η δυναμική προσαρμογή των κατωφλίων ανάγνωσης, βρίσκονται σε πειραματικό στάδιο. Η ανάπτυξη αυτών των τεχνικών βασίζεται στον πειραματικό χαρακτηρισμό των NV μνημών, τόσο σε επίπεδο κελιού όσο και σε επίπεδο ολοκληρωμένου κυκλώματος. Ο χαρακτηρισμός αυτός σχετίζεται με την μέτρηση του λόγου του αριθμού των bit σφαλμάτων προς τον αριθμό των συνολικών bits (BER) και το χρόνο απόκρισης (ανάγνωσης και εγγραφής) καθ' όλη τη διάρκεια ζωής της μνήμης, για διάφορες μορφές δεδομένων και σενάρια χρονισμών. Η διαδικασία αυτή, μέχρι τώρα, γίνεται με τη χρήση της πραγματικής NV μνήμης, συνήθως με ολοκληρωμένα κυκλώματα που βρίσκονται στο στάδιο της προ-παραγωγής, ενώ πιο ενδελεχής έλεγχος γίνεται στο τελικό στάδιο της παραγωγής. Αυτή η προσέγγιση έχει δύο σημαντικά μειονεκτήματα. Από τη μία πλευρά, είναι μια πολύ χρονοβόρα διαδικασία, δεδομένου ότι η γήρανση μίας NVM μπορεί να απαιτεί ένα μεγάλο αριθμό από program / erase (P/E) κύκλους που πρέπει να εκτελεστούν για κάθε πείραμα. Ο αριθμός αυτός κυμαίνεται από κάποιες δεκάδες χιλιάδες (NAND Flash) έως και κάποια εκατομμύρια κύκλους (PCM). Από την άλλη πλευρά, τα χαρακτηριστικά γήρανσης μίας NVM είναι αναλόγως εξαρτώμενα από τον αριθμό των Ρ/Ε κύκλων που εκτελούνται, καθιστώντας έτσι αδύνατη την διεξαγωγή διαφορετικών ή διαδοχικών πειραμάτων στην ίδια κατάσταση γήρανσης της μνήμης. Σε αυτή την εργασία παρουσιάζουμε ένα μοντέλο που αντιπροσωπεύει με ακρίβεια τη διαδικασία γήρανσης NV μνημών, αντιμετωπίζοντας τες ως ένα χρονικά μεταβαλλόμενο κανάλι επικοινωνίας βασισμένο σε ένα μη συμμετρικό n-PAM μοντέλο. Με βάση τη μοντελοποίηση των χαρακτηριστικών γήρανσης, υλοποιούμε ένα σύστημα εξομοίωσης σε πραγματικό χρόνο και με μεγάλη ακρίβεια της συμπεριφοράς NV-μνημών, κάτω από ορισμένες από το χρήστη συνθήκες γήρανσης, σε τεχνολογία FPGA. Η πλατφόρμα που παρουσιάζεται στην παρούσα εργασία βασίζεται σε μια αναπροσαρμόσιμη αρχιτεκτονική υλικού και λογισμικού που επιτρέπει την ακριβή εξομοίωση των νέων και αναδυόμενων τεχνολογιών και μοντέλων των NVMs. Η πλατφόρμα που αναπτύχθηκε μπορεί να αποτελέσει ένα πολύτιμο εργαλείο για την ανάπτυξη και αξιολόγηση αλγορίθμων και τεχνικών κωδικοποίησης. / Over the last few years, non-volatle memory (NVM) has shown a great potential in replacing volatile memory, like DRAM in caching applications, and magnetic HDDs in storage applications. NAND Flash-based solid state drives (SSDs) have already emerged as a low-cost, high-performance and reliable storage medium for both commercial and enterprise storage systems. Additionally, the properties of phase-change materials and the recent scaling of Phase-Change Memory (PCM) has made it a perfect candidate for developing phase-change random access memories (PCRAMs). The rapid scaling of NVMs, with process nodes below 19nm, and the use of multi-level cell (MLC) technologies has increased their storage density and reduced the storage cost per bit. However, their lifetime capacity has not remained unaffected. Different interferences and noise sources along with aging effects have now a great impact on the reliability and endurance of these memory technologies, and hence, on the storage systems where these memories are used (SSDs, PCRAMs). Numerous techniques, such as wear-leveling, specialized error correcting codes (ECC) and precoding techniques have been employed to compensate these effects, while others, more complex but also more efficient, like dynamic adaptation of read reference thresholds, are at an experimental level. The development of these techniques is based on experimental characterization of NVM cells and chips. Characterization is related with measuring bit error ratio (BER) and response time (read and write time) during the whole lifetime of a device, for various loading data patterns and timing scenarios. This process is performed using real NVM integrated chips, usually the engineering, pre-production parts, while more thorough testing at the system level is performed when production parts are available. This approach has two major drawbacks. On one hand it is a very time-consuming process, since the aging of an NVM may require a large number of program/erase (P/E) cycles to be performed for each experiment, ranging from tens of thousands (NAND Flash) to millions (PCM) program cycles. On the other hand, the aging characteristics of an NVM are proportionally dependent on the number of the performed P/E cycles, thus making it impossible to conduct different or successive experiments at the same aging state of a memory chip. In this work, we present a model that accurately represents the aging process of an NVM cell, by treating it as a time-variant communications channel, based on an asymmetric n-PAM model. We present the architecture of a flexible FPGA-based platform, designed for accurate emulations of NVM technologies, focusing mainly on MLC NAND Flash technologies. Accuracy is measured in reference to experimentally specified bit error probabilities for various aging conditions (ie. the number of P/E cycles applied to a NAND Flash chip), usually for random data patterns. The hardware platform presented in this work is based on a reconfigurable hardware-software architecture, which enables the accurate emulation of new and emerging models and technologies of NVMs. The developed platform can be a valuable tool for the evaluation of memory-related algorithms, signal processing and coding techniques.
3

System Level Exploration of RRAM for SRAM Replacement

Dogan, Rabia January 2013 (has links)
Recently an effective usage of the chip area plays an essential role for System-on-Chip (SOC) designs. Nowadays on-chip memories take up more than 50%of the total die-area and are responsible for more than 40% of the total energy consumption. Cache memory alone occupies 30% of the on-chip area in the latest microprocessors. This thesis project “System Level Exploration of RRAM for SRAM Replacement” describes a Resistive Random Access Memory (RRAM) based memory organizationfor the Coarse Grained Reconfigurable Array (CGRA) processors. Thebenefit of the RRAM based memory organization, compared to the conventional Static-Random Access Memory (SRAM) based memory organization, is higher interms of energy and area requirement. Due to the ever-growing problems faced by conventional memories with Dynamic Voltage Scaling (DVS), emerging memory technologies gained more importance. RRAM is typically seen as a possible candidate to replace Non-volatilememory (NVM) as Flash approaches its scaling limits. The replacement of SRAMin the lowest layers of the memory hierarchies in embedded systems with RRAMis very attractive research topic; RRAM technology offers reduced energy and arearequirements, but it has limitations with regards to endurance and write latency. By reason of the technological limitations and restrictions to solve RRAM write related issues, it becomes beneficial to explore memory access schemes that tolerate the longer write times. Therefore, since RRAM write time cannot be reduced realistically speaking we have to derive instruction memory and data memory access schemes that tolerate the longer write times. We present an instruction memory access scheme to compromise with these problems. In addition to modified instruction memory architecture, we investigate the effect of the longer write times to the data memory. Experimental results provided show that the proposed architectural modifications can reduce read energy consumption by a significant frame without any performance penalty.
4

Study of Resistance Switching Physical Mechanism in Hafnium Oxide Thin Film for Resistive Random Access Memory

Lou, Jyun-Hao 14 July 2012 (has links)
This study is focuses on the resistance switching physical mechanism in hafnium oxide (HfO2) of resistive random access memory (RRAM). HfO2 was taken as the resistance switching layer because HfO2 is extremely compatible with the prevalent complementary metal oxide semiconductor (CMOS) process. The detail physical mechanism is studied by the stable RRAM device (Ti/HfO2/TiN), which is offered from Industrial Technology Research Institute (ITRI). In this study, the resistance switching property of two different forming conductions are compared, including DC sweeping forming and AC pulse forming. In general, forming is a pivotal process in resistance random access memory (RRAM) to activate the resistance switching behavior. However, over forming would lead to device damage. The overshoot current has been considered as a degradation reason during the forming process. The circuit design is used to obtain the overshoot effect of DC sweeping forming by oscilloscope and semiconductor parameter analyzer system. The quantity of charge through the switching layer has been proven as the key element in the formation of the conduction path. Ultra-fast pulse forming can form a discontinuous conduction path to reduce the operation power.
5

Exploring atomicity on memory mapped files based on non-volatile memory file systems

Puglia, Gianlucca Oliveira 21 March 2017 (has links)
Submitted by PPG Ci?ncia da Computa??o (ppgcc@pucrs.br) on 2017-12-11T16:00:35Z No. of bitstreams: 1 Gianlucca_Oliveira_Puglia_dis.pdf: 2043630 bytes, checksum: f7fc70f33d1d15b56eded8458fbed2fa (MD5) / Approved for entry into archive by Tatiana Lopes (tatiana.lopes@pucrs.br) on 2017-12-18T11:25:26Z (GMT) No. of bitstreams: 1 Gianlucca_Oliveira_Puglia_dis.pdf: 2043630 bytes, checksum: f7fc70f33d1d15b56eded8458fbed2fa (MD5) / Made available in DSpace on 2017-12-18T11:49:55Z (GMT). No. of bitstreams: 1 Gianlucca_Oliveira_Puglia_dis.pdf: 2043630 bytes, checksum: f7fc70f33d1d15b56eded8458fbed2fa (MD5) Previous issue date: 2017-03-21 / As tecnologias de mem?rias n?o-vol?teis s?o uma grande promessa na ?rea de arquitetura de computadores e ? esperado que sejam poderosas ferramentas para solucionar os problemas referentes a manipula??o eficiente de dados dos dias de hoje. Estas tecnologias prov?m alta performance e acesso em granularidade de bytes com a distinta vantagem de serem persistentes. Por?m, afim de explorar estas tecnologias em todo seu potencial, os sistemas e arquiteturas de hoje precisam buscar meios de se adaptar a esta nova forma de acessar dados e de superar os desafios que v?m com ela.Trabalhos existentes na ?rea j? prop?em m?todos para adaptar as arquiteturas existentes para o uso de NVM bem como formas inovadoras de empregar estas mem?rias em futuras aplica??es. No entanto, o suporte dos sistemas operacionais a estas solu??es, ainda que existente, ainda ? muito limitado. Neste trabalho, n?s apresentamos duas varia??es da chamada de sistema msync, modeladas para explorar as caracter?sticas das tecnologias de NVM e garantir consist?ncia para os dados dos usu?rios. Ambas s?o solu??es simples que permitem aos usu?rios definirem checkpoints de seus arquivos usando a sintaxe comum de sistemas de arquivos. N?s implementamos e testamos estes m?todos sobre o sistema operacional Linux utilizando como base um sistema de arquivo nativamente voltado a NVM. Nossos resultados mostram que estes mecanismos s?o capazes de garantir a integridade dos arquivos mesmo na presen?a de falhas no sistema enquanto mant?m uma performance razo?vel. / Upcoming non-volatile memory technologies are a big promise in computer architecture and are expected to be powerful tools to address today?s issues regarding efficient data manipulation. They provide high performance and byte granularity while also having the distinct advantage of being persistent. However in order to explore these technologies to their full potential, existing systems and architecture must adapt to this new way of working with data and workaround the challenges that come with it. Existing work in the area already proposes methods to adapt existing architecture to NVM as well as innovative ways to employ these memories in future applications. However operating system support to such NVM-enabled solutions, although existent, still very limited. In this work, we present two variations of the existing mmap system call, designed to both explore NVM characteristics and provide user data consistency. Both are very simple solutions that allow users to control the persistence and define checkpoints to their files while using the common mapped file syntax. We have implemented and tested these methods over Linux using a NVM file system as our base. Our results show that these mechanisms can ensure file integrity in the presence of system failures while also providing a reasonable performance.
6

Größenkontrollierte Herstellung von Ge-Nanokristallen in Hoch-Epsilon-Dielektrika auf Basis von ZrO2

Lehninger, David 08 December 2018 (has links)
Nanokristalle werden beispielsweise für eine Anwendung in Solarzellen, Lichtemittern und nichtflüchtigen Datenspeichern diskutiert. Damit diese Anwendungen funktionieren können, ist eine genaue Kontrolle der Kristallitgröße sowie der Flächendichte und Lage der Kristallite in der Matrix wichtig. Zudem sollte die Matrix amorph sein, da amorphe Matrixmaterialien die Nanokristall-Oberfläche besser passivieren und beständiger gegen Leckströme sind. In dieser Arbeit werden Ge-Nanokristalle in die Hoch-Epsilon-Dielektrika ZrO2 und TaZrOx eingebettet. Im System Ge/ZrO2 kristallisieren die Ge-Cluster und die ZrO2-Matrix bei der gleichen Temperatur. Aufgrund der kristallinen Matrix weicht die Form der Ge-Nanokristalle von einer Kugel ab, worunter unter anderem die Größenkontrolle leidet. Die Beimischung von Ta2O5 stabilisiert die amorphe Phase des ZrO2 und verhindert dadurch die gemeinsame Kristallisation. Dadurch wird es im System Ge/TaZrOx möglich, kugelförmige Ge-Nanokristalle im Größenbereich von 3 nm bis 6 nm positionskontrolliert in eine amorphe Matrix einzubetten. Für die Untersuchung einer möglichen Anwendung des Materialsystems wurden Speicherzellen eines nichtflüchtigen Datenspeichers auf Basis von Ge-Nanokristallen hergestellt. Dabei zeigte sich, dass das System Ge/TaZrOx überdurchschnittlich viele Ladungen speichert und daher für diese Anwendung vielversprechend ist. Zudem stabilisiert die Beimischung von Ta2O5 eine extrem seltene orthorhombische Modifikation des ZrO2. Für ferroelektrische Datenspeicher könnte diese Phase eine aussichtsreiche Alternative zum HfO2 sein.
7

Nanoscale resistive switching memory devices: a review

Slesazeck, Stefan, Mikolajick, Thomas 10 November 2022 (has links)
In this review the different concepts of nanoscale resistive switching memory devices are described and classified according to their I–V behaviour and the underlying physical switching mechanisms. By means of the most important representative devices, the current state of electrical performance characteristics is illuminated in-depth. Moreover, the ability of resistive switching devices to be integrated into state-of-the-art CMOS circuits under the additional consideration with a suitable selector device for memory array operation is assessed. From this analysis, and by factoring in the maturity of the different concepts, a ranking methodology for application of the nanoscale resistive switching memory devices in the memory landscape is derived. Finally, the suitability of the different device concepts for beyond pure memory applications, such as brain inspired and neuromorphic computational or logic in memory applications that strive to overcome the vanNeumann bottleneck, is discussed.

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