Managing Algorithmic Skeleton Nesting Requirements in Realistic Image Processing Applications: The Case of the SKiPPER-II Parallel Programming Environment's Operating Model

• Published in: EURASIP journal on advances in signal processing Vol. 2005; no. 7; p. 218656
• Main Authors: Coudarcher, Rémi, Duculty, Florent, Serot, Jocelyn, Jurie, Frédéric, Derutin, Jean-Pierre, Dhome, Michel
• Format: Journal Article
• Language: English
• Published: BioMed Central Ltd 2005; SpringerOpen
• Subjects: 3D face tracking; algorithmic skeleton; Computer Science; image processing; nesting; parallel programming
• ISSN: 1687-6180; 1687-6172; 1687-6180
• DOI: 10.1186/1687-6180-2005-218656

: SKiPPER is a SKeleton-based Parallel Programming EnviRonment being developed since 1996 and running at LASMEA Laboratory, the Blaise-Pascal University, France. The main goal of the project was to demonstrate the applicability of skeleton-based parallel programming techniques to the fast prototyping of reactive vision applications. This paper deals with the special features embedded in the latest version of the project: algorithmic skeleton nesting capabilities and a fully dynamic operating model. Throughout the case study of a complete and realistic image processing application, in which we have pointed out the requirement for skeleton nesting, we are presenting the operating model of this feature. The work described here is one of the few reported experiments showing the application of skeleton nesting facilities for the parallelisation of a realistic application, especially in the area of image processing. The image processing application we have chosen is a 3D face-tracking algorithm from appearance.