Toward scalable source level accuracy analysis for floating-point to fixed-point conversion

Author

Deest, Gael ; Yuki, Tomofumi ; Sentieys, Olivier ; Derrien, Steven

fYear

2014

fDate

2-6 Nov. 2014

Firstpage

726

Lastpage

733

Abstract

In embedded systems, many numerical algorithms are implemented with fixed-point arithmetic to meet area cost and power constraints. Fixed-point encoding decisions can significantly affect cost and performance. To evaluate their impact on accuracy, designers resort to simulations. Their high running-time prevents thorough exploration of the design-space. To address this issue, analytical modeling techniques have been proposed, but their applicability is limited by scalability issues. In this paper, we extend these techniques to a larger class of programs. We use polyhedral methods to extract a more compact, graph-based representation of the program. We validate our approach with a several image and signal processing algorithms.

Keywords

embedded systems; fixed point arithmetic; floating point arithmetic; graph theory; signal processing; analytical modeling techniques; area cost constraints; embedded systems; fixed-point arithmetic; fixed-point conversion; fixed-point encoding decisions; floating-point conversion; graph-based representation; image processing algorithms; polyhedral methods; power constraints; scalability issues; scalable source level accuracy analysis; signal processing algorithms; Accuracy; Arrays; Convolution; Convolutional codes; Equations; Kernel; Mathematical model;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer-Aided Design (ICCAD), 2014 IEEE/ACM International Conference on

Conference_Location

San Jose, CA

Type

conf

DOI

10.1109/ICCAD.2014.7001432

Filename

7001432