X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/kahina_paper1.git/blobdiff_plain/a601f08e009efccb69bc30f54a76342afca25273..e11b41ec23ed79334b53484f47df2731f407c8fe:/elsarticle-template.out?ds=inline

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-\BOOKMARK [1][-]{section.1}{Root finding problem}{}% 1
-\BOOKMARK [1][-]{section.2}{Aberth method}{}% 2
-\BOOKMARK [2][-]{subsection.2.1}{Polynomials Initialization}{section.2}% 3
-\BOOKMARK [2][-]{subsection.2.2}{Vector Z\(0\) Initialization}{section.2}% 4
-\BOOKMARK [2][-]{subsection.2.3}{Iterative Function Hi}{section.2}% 5
-\BOOKMARK [2][-]{subsection.2.4}{Convergence condition}{section.2}% 6
-\BOOKMARK [1][-]{section.3}{Amelioration of Aberth method }{}% 7
-\BOOKMARK [1][-]{section.4}{The implementation of simultaneous methods in a parallel computer}{}% 8
-\BOOKMARK [1][-]{section.5}{A parallel implementation of Aberth method}{}% 9
-\BOOKMARK [2][-]{subsection.5.1}{Background on the GPU architecture}{section.5}% 10
-\BOOKMARK [2][-]{subsection.5.2}{Background on the CUDA Programming Model}{section.5}% 11
-\BOOKMARK [2][-]{subsection.5.3}{ The implementation of Aberth method on GPU}{section.5}% 12
-\BOOKMARK [3][-]{subsubsection.5.3.1}{A sequential Aberth algorithm}{subsection.5.3}% 13
-\BOOKMARK [3][-]{subsubsection.5.3.2}{Parallelize the steps on GPU }{subsection.5.3}% 14
-\BOOKMARK [2][-]{subsection.5.4}{Experimental study}{section.5}% 15
-\BOOKMARK [3][-]{subsubsection.5.4.1}{Definition of the polynomial used}{subsection.5.4}% 16
-\BOOKMARK [3][-]{subsubsection.5.4.2}{The study condition}{subsection.5.4}% 17
-\BOOKMARK [3][-]{subsubsection.5.4.3}{Comparative study}{subsection.5.4}% 18
+\BOOKMARK [1][-]{section.1}{Root finding problem}{}% 1
+\BOOKMARK [1][-]{section.2}{Aberth method}{}% 2
+\BOOKMARK [2][-]{subsection.2.1}{Polynomials Initialization}{section.2}% 3
+\BOOKMARK [2][-]{subsection.2.2}{Vector Z\(0\) Initialization}{section.2}% 4
+\BOOKMARK [2][-]{subsection.2.3}{Iterative Function Hi}{section.2}% 5
+\BOOKMARK [2][-]{subsection.2.4}{Convergence condition}{section.2}% 6
+\BOOKMARK [1][-]{section.3}{Amelioration of Aberth method }{}% 7
+\BOOKMARK [1][-]{section.4}{The implementation of simultaneous methods in a parallel computer}{}% 8
+\BOOKMARK [1][-]{section.5}{A parallel implementation of Aberth method}{}% 9
+\BOOKMARK [2][-]{subsection.5.1}{Background on the GPU architecture}{section.5}% 10
+\BOOKMARK [2][-]{subsection.5.2}{Background on the CUDA Programming Model}{section.5}% 11
+\BOOKMARK [2][-]{subsection.5.3}{ The implementation of Aberth method on GPU}{section.5}% 12
+\BOOKMARK [3][-]{subsubsection.5.3.1}{A sequential Aberth algorithm}{subsection.5.3}% 13
+\BOOKMARK [3][-]{subsubsection.5.3.2}{Parallelize the steps on GPU }{subsection.5.3}% 14
+\BOOKMARK [2][-]{subsection.5.4}{Experimental study}{section.5}% 15
+\BOOKMARK [3][-]{subsubsection.5.4.1}{Definition of the polynomial used}{subsection.5.4}% 16
+\BOOKMARK [3][-]{subsubsection.5.4.2}{The study condition}{subsection.5.4}% 17
+\BOOKMARK [3][-]{subsubsection.5.4.3}{Comparative study}{subsection.5.4}% 18