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Understanding Security Threats of Emerging Computing Architectures and Mitigating Performance Bottlenecks of On-Chip Interconnects in Manycore NTC SystemRajamanikkam, Chidhambaranathan 01 May 2019 (has links)
Emerging computing architectures such as, neuromorphic computing and third party intellectual property (3PIP) cores, have attracted significant attention in the recent past. Neuromorphic Computing introduces an unorthodox non-von neumann architecture that mimics the abstract behavior of neuron activity of the human brain. They can execute more complex applications, such as image processing, object recognition, more efficiently in terms of performance and energy than the traditional microprocessors. However, focus on the hardware security aspects of the neuromorphic computing at its nascent stage. 3PIP core, on the other hand, have covertly inserted malicious functional behavior that can inflict range of harms at the system/application levels. This dissertation examines the impact of various threat models that emerges from neuromorphic architectures and 3PIP cores.
Near-Threshold Computing (NTC) serves as an energy-efficient paradigm by aggressively operating all computing resources with a supply voltage closer to its threshold voltage at the cost of performance. Therefore, STC system is scaled to many-core NTC system to reclaim the lost performance. However, the interconnect performance in many-core NTC system pose significant bottleneck that hinders the performance of many-core NTC system. This dissertation analyzes the interconnect performance, and further, propose a novel technique to boost the interconnect performance of many-core NTC system.
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Error handling and energy estimation for error resilient near-threshold computing / Gestion des erreurs et estimations énergétiques pour les architectures tolérantes aux fautes et proches du seuilRagavan, Rengarajan 22 September 2017 (has links)
Les techniques de gestion dynamique de la tension (DVS) sont principalement utilisés dans la conception de circuits numériques pour en améliorer l'efficacité énergétique. Cependant, la réduction de la tension d'alimentation augmente l'impact de la variabilité et des erreurs temporelles dans les technologies nano-métriques. L'objectif principal de cette thèse est de gérer les erreurs temporelles et de formuler un cadre pour estimer la consommation d'énergie d'applications résistantes aux erreurs dans le contexte du régime proche du seuil (NTR) des transistors. Dans cette thèse, la détection et la correction d'erreurs basées sur la spéculation dynamique sont explorées dans le contexte de l'adaptation de la tension et de la fréquence d‘horloge. Outre la détection et la correction des erreurs, certaines erreurs peuvent être également tolérées et les circuits peuvent calculer au-delà de leurs limites avec une précision réduite pour obtenir une plus grande efficacité énergétique. La méthode de détection et de correction d'erreur proposée atteint 71% d'overclocking avec seulement 2% de surcoût matériel. Ce travail implique une étude approfondie au niveau des portes logiques pour comprendre le comportement des portes sous l'effet de modification de la tension d'alimentation, de la tension de polarisation et de la fréquence d'horloge. Une approche ascendante est prise en étudiant les tendances de l'énergie par rapport a l'erreur des opérateurs arithmétiques au niveau du transistor. En se basant sur le profilage des opérateurs, un flot d'outils est formulé pour estimer les paramètres d'énergie et d'erreur pour différentes configurations. Nous atteignons une efficacité énergétique maximale de 89% pour les opérateurs arithmétiques comme les additionneurs 8 bits et 16 bits au prix de 20% de bits défectueux en opérant en NTR. Un modèle statistique est développé pour que les opérateurs arithmétiques représentent le comportement des opérateurs pour différents impacts de variabilité. Ce modèle est utilisé pour le calcul approximatif dans les applications qui peuvent tolérer une marge d'erreur acceptable. Cette méthode est ensuite explorée pour unité d'exécution d'un processeur VLIW. L'environnement proposé fournit une estimation rapide des indicateurs d'énergie et d'erreurs d'un programme de référence par compilation simple d'un programme C. Dans cette méthode d'estimation de l'énergie, la caractérisation des opérateurs se fait au niveau du transistor, et l'estimation de l'énergie se fait au niveau fonctionnel. Cette approche hybride rend l'estimation de l'énergie plus rapide et plus précise pour différentes configurations. Les résultats d'estimation pour différents programmes de référence montrent une précision de 98% par rapport à la simulation SPICE. / Dynamic voltage scaling (DVS) technique is primarily used in digital design to enhance the energy efficiency by reducing the supply voltage of the design. However reduction in Vdd augments the impact of variability and timing errors in sub-nanometer designs. The main objective of this work is to handle timing errors, and to formulate a framework to estimate energy consumption of error resilient applications in the context of near-threshold regime (NTR). In this thesis, Dynamic Speculation based error detection and correction is explored in the context of adaptive voltage and clock overscaling. Apart from error detection and correction, some errors can also be tolerated or, in other words, circuits can be pushed beyond their limits to compute incorrectly to achieve higher energy efficiency. The proposed error detection and correction method achieves 71% overclocking with 2% additional hardware cost. This work involves extensive study of design at gate level to understand the behaviour of gates under overscaling of supply voltage, bias voltage and clock frequency (collectively called as operating triads). A bottom-up approach is taken: by studying trends of energy vs. error of basic arithmetic operators at transistor level. Based on the profiling of arithmetic operators, a tool flow is formulated to estimate energy and error metrics for different operating triads. We achieve maximum energy efficiency of 89% for arithmetic operators like 8-bit and 16-bit adders at the cost of 20% faulty bits by operating in NTR. A statistical model is developed for the arithmetic operators to represent the behaviour of the operators for different variability impacts. This model is used for approximate computing of error resilient applications that can tolerate acceptable margin of errors. This method is further explored for execution unit of a VLIW processor. The proposed framework provides quick estimation of energy and error metrics of a benchmark programs by simple compilation in a C compiler. In the proposed energy estimation framework, characterization of arithmetic operators is done at transistor level, and the energy estimation is done at functional level. This hybrid approach makes energy estimation faster and accurate for different operating triads. The proposed framework estimates energy for different benchmark programs with 98% accuracy compared to SPICE simulation.
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Split Latency Allocator: Process Variation-Aware Register Access Latency Boost in a Near-Threshold Graphics Processing UnitPal, Asmita 01 August 2018 (has links)
Over the last decade, Graphics Processing Units (GPUs) have been used extensively in gaming consoles, mobile phones, workstations and data centers, as they have exhibited immense performance improvement over CPUs, in graphics intensive applications. Due to their highly parallel architecture, general purpose GPUs (GPGPUs) have gained the foreground in applications where large data blocks can be processed in parallel. However, the performance improvement is constrained by a large power consumption. Likewise, Near Threshold Computing (NTC) has emerged as an energy-efficient design paradigm. Hence, operating GPUs at NTC seems like a plausible solution to counteract the high energy consumption. This work investigates the challenges associated with NTC operation of GPUs and proposes a low-power GPU design, Split Latency Allocator, to sustain the performance of GPGPU applications.
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Exploiting Application Behaviors for Resilient Static Random Access Memory Arrays in the Near-Threshold Computing RegimeMugisha, Dieudonne Manzi 01 May 2015 (has links)
Near-Threshold Computing embodies an intriguing choice for mobile processors due to the promise of superior energy efficiency, extending the battery life of these devices while reducing the peak power draw. However, process, voltage, and temperature variations cause a significantly high failure rate of Level One cache cells in the near-threshold regime a stark contrast to designs in the super-threshold regime, where fault sites are rare.
This thesis work shows that faulty cells in the near-threshold regime are highly clustered in certain regions of the cache. In addition, popular mobile benchmarks are studied to investigate the impact of run-time workloads on timing faults manifestation. A technique to mitigate the run-time faults is proposed. This scheme maps frequently used data to healthy cache regions by exploiting the application cache behaviors. The results show up to 78% gain in performance over two other state-of-the-art techniques.
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Toward Reliable, Secure, and Energy-Efficient Multi-Core System DesignBasu, Prabal 01 August 2019 (has links)
Computer hardware researchers have perennially focussed on improving the performance of computers while stipulating the energy consumption under a strict budget. While several innovations over the years have led to high performance and energy efficient computers, more challenges have also emerged as a fallout. For example, smaller transistor devices in modern multi-core systems are afflicted with several reliability and security concerns, which were inconceivable even a decade ago. Tackling these bottlenecks happens to negatively impact the power and performance of the computers. This dissertation explores novel techniques to gracefully solve some of the pressing challenges of the modern computer design. Specifically, the proposed techniques improve the reliability of on-chip communication fabric under a high power supply noise, increase the energy-efficiency of low-power graphics processing units, and demonstrate an unprecedented security loophole of the low-power computing paradigm through rigorous hardware-based experiments.
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Predicting Critical Warps in Near-Threshold GPGPU Applications Using a Dynamic Choke Point AnalysisSanyal, Sourav 01 August 2019 (has links)
General purpose graphics processing units (GP-GPU), owing to their enormous thread-level parallelism, can significantly improve the power consumption at the near-threshold (NTC) operating region, while offering close to a super-threshold performance. However, process variation (PV) can drastically reduce the GPU performance at NTC. In this work, choke points—a unique device-level characteristic of PV at NTC—that can exacerbate the warp criticality problem in GPUs have been explored. It is shown that the modern warp schedulers cannot tackle the choke point induced critical warps in an NTC GPU. Additionally, Choke Point Aware Warp Speculator, a circuit-architectural solution is proposed to dynamically predict the critical warps in GPUs, and accelerate them in their respective execution units. The best scheme achieves an average improvement of ∼39% in performance, and ∼31% in energy-efficiency, over one state-of-the-art warp scheduler, across 15 GPGPU applications, while incurring marginal hardware overheads.
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Switched-Capacitor DC-DC Converters for Near-Threshold DesignAbdelfattah, Moataz January 2017 (has links)
No description available.
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Designing Future Low-Power and Secure Processors with Non-Volatile MemoryPan, Xiang 07 September 2017 (has links)
No description available.
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