English

Fast matrix multiplication techniques based on the Adleman-Lipton model

Quantitative Methods 2012-02-10 v5 Data Structures and Algorithms Emerging Technologies

Abstract

On distributed memory electronic computers, the implementation and association of fast parallel matrix multiplication algorithms has yielded astounding results and insights. In this discourse, we use the tools of molecular biology to demonstrate the theoretical encoding of Strassen's fast matrix multiplication algorithm with DNA based on an nn-moduli set in the residue number system, thereby demonstrating the viability of computational mathematics with DNA. As a result, a general scalable implementation of this model in the DNA computing paradigm is presented and can be generalized to the application of \emph{all} fast matrix multiplication algorithms on a DNA computer. We also discuss the practical capabilities and issues of this scalable implementation. Fast methods of matrix computations with DNA are important because they also allow for the efficient implementation of other algorithms (i.e. inversion, computing determinants, and graph theory) with DNA.

Keywords

Cite

@article{arxiv.0912.0750,
  title  = {Fast matrix multiplication techniques based on the Adleman-Lipton model},
  author = {Aran Nayebi},
  journal= {arXiv preprint arXiv:0912.0750},
  year   = {2012}
}

Comments

To appear in the International Journal of Computer Engineering Research. Minor changes made to make the preprint as similar as possible to the published version

R2 v1 2026-06-21T14:19:26.559Z