Title :
A module-based partial reconfiguration design for solving sparse linear systems over GF(2)
Author :
Meintanis, D. ; Papaefstathiou, I.
Author_Institution :
Dept. of Electron. & Comput. Eng., Tech. Univ. of Crete, Chania, Greece
Abstract :
Factorization of large numbers, is of great importance in cryptanalysis, since many security algorithms are based on the fact that factoring of such numbers is an extremely difficult task. The fastest known algorithm for factoring large numbers is the Number Field Sieve (NFS). This algorithm has four main steps. Two of them, the sieving and the linear algebra steps are the more time consuming. In this paper, we introduce and implement a new matrix-by-vector multiplication scheme using a module based run time reconfiguration design, for the linear algebra step. Our implementation is based on Xilinx Virtex FPGA devices with serial 6.5 Gbps transceivers. We compare our system with other proposed architectures and we demonstrate that we can be 19,4 to 57,4 times faster, depending on the parameters of the block Wiedemann algorithm and on the FPGA device used.
Keywords :
cryptography; field programmable gate arrays; linear systems; matrix decomposition; matrix multiplication; reconfigurable architectures; sparse matrices; GF(2); Number Field Sieve algorithm; Xilinx Virtex FPGA devices; bit rate 6.5 Gbit/s; block Wiedemann algorithm; cryptanalysis; factorization; linear algebra; matrix-by-vector multiplication scheme; module-based partial reconfiguration design; run time reconfiguration design; security algorithms; serial 6.5 Gbps transceivers; sparse linear systems; Algorithm design and analysis; Computer architecture; Computer security; Design engineering; Field programmable gate arrays; Linear algebra; Linear systems; Optical design; Sparse matrices; Transceivers;
Conference_Titel :
Field-Programmable Technology, 2009. FPT 2009. International Conference on
Conference_Location :
Sydney, NSW
Print_ISBN :
978-1-4244-4375-8
DOI :
10.1109/FPT.2009.5377677
