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On the Power of Border Width-2 ABPs over Fields of Characteristic 2

Authors Pranjal Dutta, Christian Ikenmeyer, Balagopal Komarath, Harshil Mittal, Saraswati Girish Nanoti, Dhara Thakkar

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Author Details

Pranjal Dutta
  • National University of Singapore, Singapore
Christian Ikenmeyer
  • University of Warwick, UK
Balagopal Komarath
  • Indian Institute of Technology Gandhinagar, India
Harshil Mittal
  • Indian Institute of Technology Gandhinagar, India
Saraswati Girish Nanoti
  • Indian Institute of Technology Gandhinagar, India
Dhara Thakkar
  • Indian Institute of Technology Gandhinagar, India

Funding

  • Dutta, Pranjal: Supported by the project "Foundation of Lattice-based Cryptography", funded by NUS-NCS Joint Laboratory for Cyber Security, Singapore.
  • Ikenmeyer, Christian: Supported by EPSRC grant EP/W014882/1.
  • Nanoti, Saraswati Girish: Funded by CSIR NET JRF Fellowship.
  • Thakkar, Dhara: Funded by CSIR-UGC NET JRF Fellowship.

Cite As Get BibTex

Pranjal Dutta, Christian Ikenmeyer, Balagopal Komarath, Harshil Mittal, Saraswati Girish Nanoti, and Dhara Thakkar. On the Power of Border Width-2 ABPs over Fields of Characteristic 2. In 41st International Symposium on Theoretical Aspects of Computer Science (STACS 2024). Leibniz International Proceedings in Informatics (LIPIcs), Volume 289, pp. 31:1-31:16, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2024) https://doi.org/10.4230/LIPIcs.STACS.2024.31

Abstract

The celebrated result by Ben-Or and Cleve [SICOMP92] showed that algebraic formulas are polynomially equivalent to width-3 algebraic branching programs (ABP) for computing polynomials. i.e., VF = VBP₃. Further, there are simple polynomials, such as ∑_{i = 1}⁸ x_i y_i, that cannot be computed by width-2 ABPs [Allender and Wang, CC16]. Bringmann, Ikenmeyer and Zuiddam, [JACM18], on the other hand, studied these questions in the setting of approximate (i.e., border complexity) computation, and showed the universality of border width-2 ABPs, over fields of characteristic ≠ 2. In particular, they showed that polynomials that can be approximated by formulas can also be approximated (with only a polynomial blowup in size) by width-2 ABPs, i.e., VF ̅ = VBP₂ ̅. The power of border width-2 algebraic branching programs when the characteristic of the field is 2 was left open.
In this paper, we show that width-2 ABPs can approximate every polynomial irrespective of the field characteristic. We show that any polynomial f with 𝓁 monomials and with at most t odd-power indeterminates per monomial can be approximated by 𝒪(𝓁⋅ (deg(f)+2^t))-size width-2 ABPs. Since 𝓁 and t are finite, this proves universality of border width-2 ABPs. For univariate polynomials, we improve this upper-bound from O(deg(f)²) to O(deg(f)).
Moreover, we show that, if a polynomial f can be approximated by small formulas, then the polynomial f^d, for some small power d, can be approximated by small width-2 ABPs. Therefore, even over fields of characteristic two, border width-2 ABPs are a reasonably powerful computational model. Our construction works over any field.

Subject Classification

ACM Subject Classification
  • Theory of computation → Algebraic complexity theory
Keywords
  • Algebraic branching programs
  • border complexity
  • characteristic 2

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References

  1. Eric Allender and Fengming Wang. On the power of algebraic branching programs of width two. computational complexity, 25(1):217-253, 2016. Google Scholar
  2. Michael Ben-Or and Richard Cleve. Computing algebraic formulas using a constant number of registers. SIAM Journal on Computing, 21(1):54-58, 1992. Google Scholar
  3. Stuart J Berkowitz. On computing the determinant in small parallel time using a small number of processors. Information processing letters, 18(3):147-150, 1984. Google Scholar
  4. Karl Bringmann, Christian Ikenmeyer, and Jeroen Zuiddam. On algebraic branching programs of small width. Journal of the ACM (JACM), 65(5):1-29, 2018. Google Scholar
  5. Peter Bürgisser. The complexity of factors of multivariate polynomials. Found. Comput. Math., 4(4):369-396, 2004. URL: https://doi.org/10.1007/s10208-002-0059-5.
  6. Pranjal Dutta. Discovering the roots: Unifying and extending results on multivariate polynomial factoring in algebraic complexity. Master’s thesis, 2018. Google Scholar
  7. Pranjal Dutta. A tale of hardness, de-randomization and de-bordering in complexity theory. PhD Thesis, 2022. Google Scholar
  8. Pranjal Dutta, Fulvio Gesmundo, Christian Ikenmeyer, Gorav Jindal, and Vladimir Lysikov. Border complexity via elementary symmetric polynomials. arXiv preprint arXiv:2211.07055, 2022. Google Scholar
  9. Michael A Forbes and Amir Shpilka. A pspace construction of a hitting set for the closure of small algebraic circuits. In Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing, pages 1180-1192, 2018. Google Scholar
  10. Bruno Grenet. An upper bound for the permanent versus determinant problem. Theory of Computing, 2011. Google Scholar
  11. Christian Ikenmeyer and Abhiroop Sanyal. A note on VNP-completeness and border complexity. Information Processing Letters, 176:106243, 2022. Google Scholar
  12. Mrinal Kumar. On the power of border of depth-3 arithmetic circuits. ACM Trans. Comput. Theory, 12(1):5:1-5:8, 2020. URL: https://doi.org/10.1145/3371506.
  13. M. Mahajan. Algebraic complexity classes. Perspectives in Comp. Compl.: The Somenath Biswas Ann. Vol., pages 51-75, 2014. Google Scholar
  14. Meena Mahajan and V. Vinay. Determinant: Combinatorics, algorithms, and complexity. Chicago Journal of Theoretical Computer Science, 1997(5), 1997. Google Scholar
  15. Thierry Mignon and Nicolas Ressayre. A quadratic bound for the determinant and permanent problem. International Mathematics Research Notices, 2004(79):4241-4253, 2004. Google Scholar
  16. Ketan Mulmuley. Geometric complexity theory v: Efficient algorithms for noether normalization. Journal of the American Mathematical Society, 30(1):225-309, 2017. Google Scholar
  17. Ketan Mulmuley and Milind A. Sohoni. Geometric complexity theory I: an approach to the P vs. NP and related problems. SIAM J. Comput., 31(2):496-526, 2001. URL: https://doi.org/10.1137/S009753970038715X.
  18. Ketan D Mulmuley and Milind Sohoni. Geometric complexity theory II: towards explicit obstructions for embeddings among class varieties. SIAM Journal on Computing, 38(3):1175-1206, 2008. Google Scholar
  19. Amit Sinhababu and Thomas Thierauf. Factorization of polynomials given by arithmetic branching programs. computational complexity, 30:1-47, 2021. Google Scholar
  20. Volker Strassen. Vermeidung von Divisionen. Journal für die reine und angewandte Mathematik, 264:184-202, 1973. URL: http://eudml.org/doc/151394.
  21. Seinosuke Toda. Classes of arithmetic circuits capturing the complexity of computing the determinant. IEICE Transactions on Information and Systems, 75(1):116-124, 1992. Google Scholar
  22. Leslie G Valiant. Completeness classes in algebra. In Proceedings of the eleventh annual ACM symposium on Theory of computing, pages 249-261, 1979. Google Scholar
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