TIME-MULTIPLEXED INTERCONNECTION NETWORK FOR FIELD-PROGRAMMABLE GATE ARRAYS

Ph.DDOCTOR OF PHILOSOPH

A framework to explore low-power architecture and variability-aware timing estimation of FPGAs

Master'sMASTER OF ENGINEERIN

Architecture FPGA améliorée et flot de conception pour une reconfiguration matérielle en ligne efficace

The self-reconfiguration capabilities of modern FPGA architectures pave the way for dynamic applications able to adapt to transient events. The CAD flows of modern architectures are nowadays mature but limited by the constraints induced by the complexity of FPGA circuits. In this thesis, multiple contributions are developed to propose an FPGA architecture supporting the dynamic placement of hardware tasks. First, an intermediate representation of these tasks configuration data, independent from their final position, is presented. This representation allows to compress the task data up to 11x with regard to its conventional raw counterpart. An accompanying CAD flow, based on state-of-the-art tools, is proposed to generate relocatable tasks from a high-level description. Then, the online behavior of this mechanism is studied. Two algorithms allowing to decode and create in real-time the conventional bit-stream are described. In addition, an enhancement of the FPGA interconnection network is proposedto increase the placement flexibility of heterogeneous tasks, at the cost of a 10% increase in average of the critical path delay. Eventually, a configurable substitute to the configuration memory found in FPGAs is studied to ease their partial reconfiguration.Les capacités d'auto-reconfiguration des architectures FPGA modernes ouvrent la voie à des applications dynamiques capables d'adapter leur fonctionnement pour répondre à des évènements ponctuels. Les flots de reconfiguration des architectures commerciales sont aujourd'hui aboutis mais limités par des contraintes inhérentes à la complexité de ces circuits. Dans cette thèse, plusieurs contributions sont avancées afin de proposer une architecture FPGA reconfigurable permettant le placement dynamique de tâches matérielles. Dans un premier temps, une représentation intermédiaire des données de configuration de ces tâches, indépendante de leur positionnement final, est présentée. Cette représentation permet notamment d'atteindre des taux de compression allant jusqu'à 11x par rapport à la représentation brute d'une tâche. Un flot de conception basé sur des outils de l'état de l'art accompagne cette représentation et génère des tâches relogeables à partir d'une description haut-niveau. Ensuite, le comportement en ligne de ce mécanisme est étudié. Deux algorithmes permettant le décodage de ces tâches et la génération en temps-réel des données de configuration propres à l'architectures son décrits. Par ailleurs, une amélioration du réseau d'interconnexion d'une architecture FPGA est proposée pour accroître la flexibilité du placement de tâches hétérogènes, avec une augmentation de 10% en moyenne du délai du chemin critique. Enfin, une alternative programmable aux mémoires de configuration de ces circuits est étudiée pour faciliter leur reconfiguration partielle

A novel asynchronous FPGA architecture design and its performance evaluation

ABSTRACT This paper proposes GAPLA: a Globally Asynchronous Locally Synchronous Programmable Logic Array architecture. The whole FPGA area is divided into locally synchronous blocks wrapped with asynchronous I/O interfaces. Data communications between synchronous blocks are controlled by 2-phase handshaking signals under bundled-data delay assumption. The size and shape of each locally synchronous block are programmable so that different modules in a design can be effectively implemented. By dividing the FPGA area into smaller blocks, the delays of long interconnect wires, which could easily dominate other delays in conventional FPGAs, only come into picture when there are communications between blocks. Therefore, each block could run at higher speed. The area overhead of adopting the GALS style in GAPLA architecture is estimated to be very small (about 7%). Experimental results show an up to 55% performance improvement compared to the conventional FPGAs

Choose-Your-Own Adventure: A Lightweight, High-Performance Approach To Defect And Variation Mitigation In Reconfigurable Logic

For field-programmable gate arrays (FPGAs), fine-grained pre-computed alternative configurations, combined with simple test-based selection, produce limited per-chip specialization to counter yield loss, increased delay, and increased energy costs that come from fabrication defects and variation. This lightweight approach achieves much of the benefit of knowledge-based full specialization while reducing to practical, palatable levels the computational, testing, and load-time costs that obstruct the application of the knowledge-based approach. In practice this may more than double the power-limited computational capabilities of dies fabricated with 22nm technologies. Contributions of this work: • Choose-Your-own-Adventure (CYA), a novel, lightweight, scalable methodology to achieve defect and variation mitigation • Implementation of CYA, including preparatory components (generation of diverse alternative paths) and FPGA load-time components • Detailed performance characterization of CYA – Comparison to conventional loading and dynamic frequency and voltage scaling (DFVS) – Limit studies to characterize the quality of the CYA implementation and identify potential areas for further optimizatio

The IPS fidelity scale as a guideline to implement Supported Employment

info:eu-repo/semantics/publishe

Evaluation of advanced techniques for structural FPGA self-test

This thesis presents a comprehensive test generation framework for FPGA logic elements and interconnects. It is based on and extends the current state-of-the-art. The purpose of FPGA testing in this work is to achieve reliable reconfiguration for a FPGA-based runtime reconfigurable system. A pre-configuration test is performed on a portion of the FPGA before it is reconfigured as part of the system to ensure that the FPGA fabric is fault-free. The implementation platform is the Xilinx Virtex-5 FPGA family. Existing literature in FPGA testing is evaluated and reviewed thoroughly. The various approaches are compared against one another qualitatively and the approach most suitable to the target platform is chosen. The array testing method is employed in testing the FPGA logic for its low hardware overhead and optimal test time. All tests are additionally pipelined to reduce test application time and use a high test clock frequency. A hybrid fault model including both structural and functional faults is assumed. An algorithm for the optimization of the number of required FPGA test configurations is developed and implemented in Java using a pseudo-random set-covering heuristic. Optimal solutions are obtained for Virtex-5 logic slices. The algorithm effort is parameterizable with the number of loop iterations each of which take approximately one second for a Virtex-5 sliceL circuit. A flexible test architecture for interconnects is developed. Arbitrary wire types can be tested in the same test configuration with no hardware overhead. Furthermore, a routing algorithm is integrated with the test template generation to select the wires under test and route them appropriately. Nine test configurations are required to achieve full test coverage for the FPGA logic. For interconnect testing, a local router-based on depth-first graph traversal is implemented in Java as the basis for creating systematic interconnect test templates. Pent wire testing is additionally implemented as a proof of concept. The test clock frequency for all tests exceeds 170 MHz and the hardware overhead is always lower than seven CLBs. All implemented tests are parameterizable such that they can be applied to any portion of the FPGA regardless of size or position