3,010 research outputs found
Design of multimedia processor based on metric computation
Media-processing applications, such as signal processing, 2D and 3D graphics
rendering, and image compression, are the dominant workloads in many embedded
systems today. The real-time constraints of those media applications have
taxing demands on today's processor performances with low cost, low power and
reduced design delay. To satisfy those challenges, a fast and efficient
strategy consists in upgrading a low cost general purpose processor core. This
approach is based on the personalization of a general RISC processor core
according the target multimedia application requirements. Thus, if the extra
cost is justified, the general purpose processor GPP core can be enforced with
instruction level coprocessors, coarse grain dedicated hardware, ad hoc
memories or new GPP cores. In this way the final design solution is tailored to
the application requirements. The proposed approach is based on three main
steps: the first one is the analysis of the targeted application using
efficient metrics. The second step is the selection of the appropriate
architecture template according to the first step results and recommendations.
The third step is the architecture generation. This approach is experimented
using various image and video algorithms showing its feasibility
Coarse-grained reconfigurable array architectures
Coarse-Grained Reconfigurable Array (CGRA) architectures accelerate the same inner loops that benefit from the high ILP support in VLIW architectures. By executing non-loop code on other cores, however, CGRAs can focus on such loops to execute them more efficiently. This chapter discusses the basic principles of CGRAs, and the wide range of design options available to a CGRA designer, covering a large number of existing CGRA designs. The impact of different options on flexibility, performance, and power-efficiency is discussed, as well as the need for compiler support. The ADRES CGRA design template is studied in more detail as a use case to illustrate the need for design space exploration, for compiler support and for the manual fine-tuning of source code
Low-Power Reconfigurable Architectures for High-Performance Mobile Nodes
Modern embedded systems have an emerging demand on high
performance and low power circuits. Traditionally special functional units for
each application are developed separately. These are plugged to a general
purpose processors to extend its instruction set making it an application specific
instruction set processor. As this strategy reaches its boundaries in area and
complexity reconfigurable architectures propose to be more flexible. Thus
combining both approaches to a reconfigurable application specific processor is
going to be the upcoming solution for future embedded systems
Video Processing Acceleration using Reconfigurable Logic and Graphics Processors
A vexing question is `which architecture will prevail as the core feature of the next state of
the art video processing system?' This thesis examines the substitutive and collaborative
use of the two alternatives of the reconfigurable logic and graphics processor architectures.
A structured approach to executing architecture comparison is presented - this includes a
proposed `Three Axes of Algorithm Characterisation' scheme and a formulation of perfor-
mance drivers. The approach is an appealing platform for clearly defining the problem,
assumptions and results of a comparison. In this work it is used to resolve the advanta-
geous factors of the graphics processor and reconfigurable logic for video processing, and
the conditions determining which one is superior. The comparison results prompt the
exploration of the customisable options for the graphics processor architecture. To clearly
define the architectural design space, the graphics processor is first identifed as part of
a wider scope of homogeneous multi-processing element (HoMPE) architectures. A novel
exploration tool is described which is suited to the investigation of the customisable op-
tions of HoMPE architectures. The tool adopts a systematic exploration approach and a
high-level parameterisable system model, and is used to explore pre- and post-fabrication
customisable options for the graphics processor. A positive result of the exploration is the
proposal of a reconfigurable engine for data access (REDA) to optimise graphics processor
performance for video processing-specific memory access patterns. REDA demonstrates
the viability of the use of reconfigurable logic as collaborative `glue logic' in the graphics
processor architecture
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