Implementación hardware de un controlador de memoria cache de reconfiguraciones en VHDL

Este proyecto presenta una implementación hardware de un controlador que gestiona de manera eficiente las reconfiguraciones que se realizan en tiempo de ejecución en un sistema que aplica cacheo de reconfiguraciones. Esta técnica consiste en utilizar una memoria on-chip que sirve de cache entre la memoria de configuración del dispositivo reconfigurable y la memoria principal, donde se guardarán todas y cada una de las reconfiguraciones que se quieran cargar en el dispositivo. La eficiencia de la técnica se puede mejorar particionando las configuraciones en bloques, y mapeando las configuraciones en diferentes memorias cache, en vez de en una sola. De este modo, dada una asignación de reconfiguraciones de tareas en diferentes memorias on-chip, el controlador hardware presentado gestiona la reconfiguración de las tareas de manera adecuada y eficiente. Los resultados experimentales que se presentan muestran que nuestro controlador realiza las operaciones necesarias en unos pocos cientos ciclos de reloj, mientras que su coste de implementación en términos de recursos hardware es muy asequible

Dynamically reconfigurable management of energy, performance, and accuracy applied to digital signal, image, and video Processing Applications

There is strong interest in the development of dynamically reconfigurable systems that can meet real-time constraints in energy/power-performance-accuracy (EPA/PPA). In this dissertation, I introduce a framework for implementing dynamically reconfigurable digital signal, image, and video processing systems. The basic idea is to first generate a collection of Pareto-optimal realizations in the EPA/PPA space. Dynamic EPA/PPA management is then achieved by selecting the Pareto-optimal implementations that can meet the real-time constraints. The systems are then demonstrated using Dynamic Partial Reconfiguration (DPR) and dynamic frequency control on FPGAs. The framework is demonstrated on: i) a dynamic pixel processor, ii) a dynamically reconfigurable 1-D digital filtering architecture, and iii) a dynamically reconfigurable 2-D separable digital filtering system. Efficient implementations of the pixel processor are based on the use of look-up tables and local-multiplexes to minimize FPGA resources. For the pixel-processor, different realizations are generated based on the number of input bits, the number of cores, the number of output bits, and the frequency of operation. For each parameters combination, there is a different pixel-processor realization. Pareto-optimal realizations are selected based on measurements of energy per frame, PSNR accuracy, and performance in terms of frames per second. Dynamic EPA/PPA management is demonstrated for a sequential list of real-time constraints by selecting optimal realizations and implementing using DPR and dynamic frequency control. Efficient FPGA implementations for the 1-D and 2-D FIR filters are based on the use a distributed arithmetic technique. Different realizations are generated by varying the number of coefficients, coefficient bitwidth, and output bitwidth. Pareto-optimal realizations are selected in the EPA space. Dynamic EPA management is demonstrated on the application of real-time EPA constraints on a digital video. The results suggest that the general framework can be applied to a variety of digital signal, image, and video processing systems. It is based on the use of offline-processing that is used to determine the Pareto-optimal realizations. Real-time constraints are met by selecting Pareto-optimal realizations pre-loaded in memory that are then implemented efficiently using DPR and/or dynamic frequency control