MEMS-enabled silicon photonic integrated devices and circuits

Photonic integrated circuits have seen a dramatic increase in complexity over the past decades. This development has been spurred by recent applications in datacenter communications and enabled by the availability of standardized mature technology platforms. Mechanical movement of wave-guiding structures at the micro- and nanoscale provides unique opportunities to further enhance functionality and to reduce power consumption in photonic integrated circuits. We here demonstrate integration of MEMS-enabled components in a simplified silicon photonics process based on IMEC's Standard iSiPP50G Silicon Photonics Platform and a custom release process

DESTINY: A Comprehensive Tool with 3D and Multi-Level Cell Memory Modeling Capability

To enable the design of large capacity memory structures, novel memory technologies such as non-volatile memory (NVM) and novel fabrication approaches, e.g., 3D stacking and multi-level cell (MLC) design have been explored. The existing modeling tools, however, cover only a few memory technologies, technology nodes and fabrication approaches. We present DESTINY, a tool for modeling 2D/3D memories designed using SRAM, resistive RAM (ReRAM), spin transfer torque RAM (STT-RAM), phase change RAM (PCM) and embedded DRAM (eDRAM) and 2D memories designed using spin orbit torque RAM (SOT-RAM), domain wall memory (DWM) and Flash memory. In addition to single-level cell (SLC) designs for all of these memories, DESTINY also supports modeling MLC designs for NVMs. We have extensively validated DESTINY against commercial and research prototypes of these memories. DESTINY is very useful for performing design-space exploration across several dimensions, such as optimizing for a target (e.g., latency, area or energy-delay product) for a given memory technology, choosing the suitable memory technology or fabrication method (i.e., 2D v/s 3D) for a given optimization target, etc. We believe that DESTINY will boost studies of next-generation memory architectures used in systems ranging from mobile devices to extreme-scale supercomputers. The latest source-code of DESTINY is available from the following git repository: https://bitbucket.org/sparsh_mittal/destiny_v2

A Holistic Solution for Reliability of 3D Parallel Systems

As device scaling slows down, emerging technologies such as 3D integration and carbon nanotube field-effect transistors are among the most promising solutions to increase device density and performance. These emerging technologies offer shorter interconnects, higher performance, and lower power. However, higher levels of operating temperatures and current densities project significantly higher failure rates. Moreover, due to the infancy of the manufacturing process, high variation, and defect densities, chip designers are not encouraged to consider these emerging technologies as a stand-alone replacement for Silicon-based transistors. The goal of this dissertation is to introduce new architectural and circuit techniques that can work around high-fault rates in the emerging 3D technologies, improving performance and reliability comparable to Silicon. We propose a new holistic approach to the reliability problem that addresses the necessary aspects of an effective solution such as detection, diagnosis, repair, and prevention synergically for a practical solution. By leveraging 3D fabric layouts, it proposes the underlying architecture to efficiently repair the system in the presence of faults. This thesis presents a fault detection scheme by re-executing instructions on idle identical units that distinguishes between transient and permanent faults while localizing it to the granularity of a pipeline stage. Furthermore, with the use of a dynamic and adaptive reconfiguration policy based on activity factors and temperature variation, we propose a framework that delivers a significant improvement in lifetime management to prevent faults due to aging. Finally, a design framework that can be used for large-scale chip production while mitigating yield and variation failures to bring up Carbon Nano Tube-based technology is presented. The proposed framework is capable of efficiently supporting high-variation technologies by providing protection against manufacturing defects at different granularities: module and pipeline-stage levels.PHDComputer Science & EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/168118/1/javadb_1.pd

Construction of the spatial development model of a city based on vertical planning concepts

Formation of an urbanistic approach to the study of the urban environment is based on the understanding of how the systems of support and spatial planning can be implemented. The relevance of the study is determined by the fact that urban planning in a traditional way when using horizontal space, may not always affect areas that will ensure expansion and improve the quality of life in cities. The novelty of the study is determined by the fact that vertical planning does not always allow using the general forms and structures of urban planning concepts. The authors have determined that particular importance in planning should be given to the design of the visual environment for the urban area. The paper presents a model for designing a vertical environment and defines the principles of modelling high-rise design concept. It is shown that modelling should be carried out online using real-time technologies. The practical significance of the study is determined by the fact that the construction of the developed model is possible only with the use of spatial modelling technologies on high-resource systems. Obtaining three-dimensional models is assumed in the structure of stereo modelling not only of buildings, but also of accompanying objects that can act as infrastructural assets

Méthodologies de conception ASIC pour des systèmes sur puce 3D hétérogènes à base de réseaux sur puce 3D

Dans cette thèse, nous étudions les architectures 3D NoC grâce à des implémentations de conception physiques en utilisant la technologie 3D réel mis en oeuvre dans l'industrie. Sur la base des listes d'interconnexions en déroute, nous procédons à l'analyse des performances d'évaluer le bénéfice de l'architecture 3D par rapport à sa mise en oeuvre 2D. Sur la base du flot de conception 3D proposé en se concentrant sur la vérification temporelle tirant parti de l'avantage du retard négligeable de la structure de microbilles pour les connexions verticales, nous avons mené techniques de partitionnement de NoC 3D basé sur l'architecture MPSoC y compris empilement homogène et hétérogène en utilisant Tezzaron 3D IC technlogy. Conception et mise en oeuvre de compromis dans les deux méthodes de partitionnement est étudiée pour avoir un meilleur aperçu sur l'architecture 3D de sorte qu'il peut être exploitée pour des performances optimales. En utilisant l'approche 3D homogène empilage, NoC topologies est explorée afin d'identifier la meilleure topologie entre la topologie 2D et 3D pour la mise en œuvre MPSoC 3D sous l'hypothèse que les chemins critiques est fondée sur les liens inter-routeur. Les explorations architecturales ont également examiné les différentes technologies de traitement. mettant en évidence l'effet de la technologie des procédés à la performance d'architecture 3D en particulier pour l'interconnexion dominant du design. En outre, nous avons effectué hétérogène 3D d'empilage pour la mise en oeuvre MPSoC avec l'approche GALS de style et présenté plusieurs analyses de conception physiques connexes concernant la conception 3D et la mise en œuvre MPSoC utilisant des outils de CAO 2D. Une analyse plus approfondie de l'effet microbilles pas à la performance de l'architecture 3D à l'aide face-à-face d'empilement est également signalé l'identification des problèmes et des limitations à prendre en considération pendant le processus de conception.In this thesis, we study the exploration 3D NoC architectures through physical design implementations using real 3D technology used in the industry. Based on the proposed 3D design flow focusing on timing verification by leveraging the benefit of negligible delay of microbumps structure for vertical connections, we have conducted partitioning techniques for 3D NoC-based MPSoC architecture including homogeneous and heterogeneous stacking using Tezzaron 3D IC technlogy. Design and implementation trade-off in both partitioning methods is investigated to have better insight about 3D architecture so that it can be exploited for optimal performance. Using homogeneous 3D stacking approach, NoC architectures are explored to identify the best topology between 2D and 3D topology for 3D MPSoC implementation. The architectural explorations have also considered different process technologies highlighting the wire delay effect to the 3D architecture performance especially for interconnect-dominated design. Additionally, we performed heterogeneous 3D stacking of NoC-based MPSoC implementation with GALS style approach and presented several physical designs related analyses regarding 3D MPSoC design and implementation using 2D EDA tools. Finally we conducted an exploration of 2D EDA tool on different 3D architecture to evaluate the impact of 2D EDA tools on the 3D architecture performance. Since there is no commercialize 3D design tool until now, the experiment is important on the basis that designing 3D architecture using 2D EDA tools does not have a strong and direct impact to the 3D architecture performance mainly because the tools is dedicated for 2D architecture design.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

Fractal capacitors

A linear capacitor structure using fractal geometries is described. This capacitor exploits both lateral and vertical electric fields to increase the capacitance per unit area. Compared to standard parallel-plate capacitors, the parasitic bottom-plate capacitance is reduced. Unlike conventional metal-to-metal capacitors, the capacitance density increases with technology scaling. A classic fractal structure is implemented with 0.6-μm metal spacing, and a factor of 2.3 increase in the capacitance per unit area is observed. It is shown that capacitance boost factors in excess of ten may be possible as technology continues to scale. A computer-aided-design tool to automatically generate and analyze custom fractal layouts has been developed

Towards Cache-Coherent Chiplet-Based Architectures with Wireless Interconnects

Cache-coherent chiplet-based architectures have gained significant attention due to their potential for scalability and improved performance in modern computing systems. However, the interconnects in such architectures often pose challenges in maintaining cache coherence across chiplets, leading to increased latency and energy consumption. This thesis focuses on exploring the feasibility and advantages of integrating wireless interconnects into cache-coherent chiplet-based architectures. Through extensive simulations of 16 and 64 core systems segmented in 4 and 8 chiplet systems with multiple inter-chiplet latencies we debug and obtain traffic data. By studying the inter-chiplet traffic for different chiplet-based configurations and analyzing it in terms of spatial, temporal and time variance we derive that chiplet scaling degrades performance. Further we formulate the impact of hybrid wired and wireless interconnects and assess the potential performance benefits they offer. The findings from this research will contribute to the design and optimization of cache-coherent chiplet-based architectures, shedding light on the practicality and advantages of utilizing wireless interconnects in future computing systems