Speeding up the log-polar transform with inexpensive parallel hardware: graphics units and multi-core architectures
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Otros documentos de la autoría: Antonelli, Marco; Igual, Francisco D.; Ramos, Jose Francisco; Traver Roig, Vicente Javier
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http://dx.doi.org/10.1007/s11554-012-0281-6 |
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Título
Speeding up the log-polar transform with inexpensive parallel hardware: graphics units and multi-core architecturesFecha de publicación
2012Editor
Springer-VerlagISSN
1861-8200Tipo de documento
info:eu-repo/semantics/articleVersión de la editorial
http://link.springer.com/article/10.1007/s11554-012-0281-6#Versión
info:eu-repo/semantics/publishedVersionPalabras clave / Materias
Resumen
Log-polar imaging is a kind of foveal, biologically inspired visual representation with advantageous properties in practical applications in computer vision, robotics, and other fields. While the cheapest, most flexible, ... [+]
Log-polar imaging is a kind of foveal, biologically inspired visual representation with advantageous properties in practical applications in computer vision, robotics, and other fields. While the cheapest, most flexible, and most common approach to get log-polar images is to use software-based mappers, this solution entails a cost which prevents certain experiments or applications from being feasible. This may be the case in some real-time (robotic) applications and, in general, when the conversion cost is not affordable for the task at hand. To overcome this drawback and make log-polar imaging more generally available, parallel solutions with affordable modern multi-core architectures have been devised, implemented, and tested in this work. Experimental results reveal that speed-up factors as high as or higher than 10 or 20, depending on the configuration, are possible to get log-polar images from large gray-level or color cartesian images using commodity graphics processors. Remarkable speedups are also reported for current multi-core processors. This noteworthy performance allows visual tasks that would otherwise be unthinkable with sequential implementations to become feasible. Additionally, since three different approaches have been explored and compared in terms of several criteria, different cost-effective choices are advisable depending on different visual task requirements or hardware availability. [-]
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Journal of Real-Time Image Processing, september 2015, vol. 10, issue 3, p. 533-550Derechos de acceso
© Springer-Verlag Berlin Heidelberg 2012
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