This paper offers an overview of the XPP, a coarse-grained reconfigurable architecture, and presents a solution for its integration into a Simulink design flow for rapid prototyping. This includes a system-level co-simulation followed by the automated code generation for an embedded target platform. In order to realize this functionality, a custom Simulink module has been developed. During the co-simulation phase, it acts as a wrapper for an external simulator, whereas when code is generated, it is responsible for generating the appropriate function calls for communicating with the XPP device. Of these two aspects, only the co-simulation is considered here.
%0 Book Section
%1 Petrov04
%A Petrov, M.
%A Murgan, T.
%A May, F.
%A Vorbach, M.
%A Zipf, P.
%A Glesner, M.
%B Lecture Notes in Computer Science
%C Berlin
%D 2004
%I Springer
%J Proceedings of the International Conference on Field Programmable Logic
%K architecture reconfigurable simulation stateOfArt
%P 761--770
%T The XPP Architecture and Its Co-Simulation Within the Simulink Environment
%U http://www.springerlink.com/content/v64tj2lq3amad0cn
%V 3203
%X This paper offers an overview of the XPP, a coarse-grained reconfigurable architecture, and presents a solution for its integration into a Simulink design flow for rapid prototyping. This includes a system-level co-simulation followed by the automated code generation for an embedded target platform. In order to realize this functionality, a custom Simulink module has been developed. During the co-simulation phase, it acts as a wrapper for an external simulator, whereas when code is generated, it is responsible for generating the appropriate function calls for communicating with the XPP device. Of these two aspects, only the co-simulation is considered here.
@inbook{Petrov04,
abstract = {This paper offers an overview of the XPP, a coarse-grained reconfigurable architecture, and presents a solution for its integration into a Simulink design flow for rapid prototyping. This includes a system-level co-simulation followed by the automated code generation for an embedded target platform. In order to realize this functionality, a custom Simulink module has been developed. During the co-simulation phase, it acts as a wrapper for an external simulator, whereas when code is generated, it is responsible for generating the appropriate function calls for communicating with the XPP device. Of these two aspects, only the co-simulation is considered here.},
added-at = {2007-07-18T08:52:32.000+0200},
address = {Berlin},
author = {Petrov, M. and Murgan, T. and May, F. and Vorbach, M. and Zipf, P. and Glesner, M.},
biburl = {https://www.bibsonomy.org/bibtex/225c34e019e117c09d62203c74bf745e1/oliveira},
booktitle = {Lecture Notes in Computer Science},
description = {Referenced by Amano},
interhash = {ad5987dc913ebd723dfb58c9635ea36f},
intrahash = {25c34e019e117c09d62203c74bf745e1},
journal = {Proceedings of the International Conference on Field Programmable Logic},
keywords = {architecture reconfigurable simulation stateOfArt},
pages = {761--770},
publisher = {Springer},
timestamp = {2007-07-18T08:52:32.000+0200},
title = {The {XPP} Architecture and Its Co-Simulation Within the Simulink Environment},
url = {http://www.springerlink.com/content/v64tj2lq3amad0cn},
volume = 3203,
year = 2004
}