High-Performance Hardware of the Sliding-Window Method for Parallel Computation of Modular Exponentiations

Modular exponentiation is a basic operation in various applications, such as cryptography. Generally, the performance of this operation has a tremendous impact on the efficiency of the whole application. Therefore, many researchers have devoted special interest to providing smart methods and efficient implementations for modular exponentiation. One of these methods is the sliding-window method, which pre- processes the exponent into zero and non-zero partitions. Zero partitions allow for a reduction of the number of modular multiplications required in the exponentiation process. In this paper, we devise a novel hardware for computing modular exponentiation using the sliding-window method. The partitioning strategy used allows variable-length non-zero partitions, which increases the average number of zero partitions and so decreases that of non-zero partitions. It performs the partitioning process in parallel with the pre-computation step of the exponent so no overhead is introduced. The implementation is efficient when compared against related existing hardware implementations.

[1]  P. L. Montgomery Modular multiplication without trial division , 1985 .

[2]  Zainalabedin Navabi,et al.  VHDL: Analysis and Modeling of Digital Systems , 1992 .

[3]  Nadia Nedjah,et al.  Three hardware architectures for the binary modular exponentiation: sequential, parallel, and systolic , 2006, IEEE Transactions on Circuits and Systems I: Regular Papers.

[4]  Adi Shamir,et al.  A method for obtaining digital signatures and public-key cryptosystems , 1978, CACM.

[5]  Noboru Kunihiro,et al.  New Methods for Generating Short Addition Chains , 2000 .

[6]  Nadia Nedjah,et al.  Fast hardware for modular exponentiation with efficient exponent pre-processing , 2007, J. Syst. Archit..

[7]  Nadia Nedjah,et al.  Efficient Hardware for Modular Exponentiation Using the Sliding-Window Method , 2007, ITNG.

[8]  Nadia Nedjah,et al.  Parallel computation of modular exponentiation for fast cryptography , 2007, Int. J. High Perform. Syst. Archit..

[9]  Adi Shamir,et al.  A method for obtaining digital signatures and public-key cryptosystems , 1978, CACM.

[10]  Alfred Menezes,et al.  Handbook of Applied Cryptography , 2018 .

[11]  Nadia Nedjah,et al.  Efficient and secure cryptographic systems based on addition chains: Hardware design vs. software/hardware co-design , 2007, Integr..

[12]  N. Nedjah,et al.  Hardware architecture for booth-Barrett's modular multiplication , 2006 .

[13]  Nadia Nedjah,et al.  Co-design for System Acceleration: A Quantitative Approach , 2007 .

[14]  Nadia Nedjah,et al.  Four Hardware Implementations for the M-ary Modular Exponentiation , 2006, Third International Conference on Information Technology: New Generations (ITNG'06).

[15]  Donald Ervin Knuth,et al.  The Art of Computer Programming , 1968 .