Log-rank conjecture
In theoretical computer science, the log-rank conjecture states that the deterministic communication complexity of a two-party Boolean function is polynomially related to the logarithm of the rank of its input matrix.[1][2]
Let denote the deterministic communication complexity of a function, and let denote the rank of its input matrix (over the reals). Since every protocol using up to bits partitions into at most monochromatic rectangles, and each of these has rank at most 1,
The log-rank conjecture states that is also upper-bounded by a polynomial in the log-rank: for some constant ,
Lovett [3] proved the upper bound
This was improved by Sudakov and Tomon,[4] who removed the logarithmic factor, showing that
This is the best currently known upper bound.
The best known lower bound, due to Göös, Pitassi and Watson,[5] states that . In other words, there exists a sequence of functions , whose log-rank goes to infinity, such that
In 2019, an approximate version of the conjecture has been disproved.[6]
See also
[edit]References
[edit]- ^ Lovász, László; Saks, Michael (1988), Möbius Functions and Communication Complexity, Annual Symposium on Foundations of Computer Science, White Plains, New York, USA, pp. 81–90
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: CS1 maint: location missing publisher (link) - ^ Lovett, Shachar (February 2014), "Recent advances on the log-rank conjecture in communication complexity", Bulletin of the EATCS, 112, arXiv:1403.8106
- ^ Lovett, Shachar (March 2016), "Communication is Bounded by Root of Rank", Journal of the ACM, 63 (1): 1:1–1:9, arXiv:1306.1877, doi:10.1145/2724704, S2CID 47394799
- ^ Sudakov, Benny; Tomon, Istvan (30 Nov 2023). "Matrix discrepancy and the log-rank conjecture". arXiv:2311.18524 [math].
- ^ Göös, Mika; Pitassi, Toniann; Watson, Thomas (2018), "Deterministic Communication vs. Partition Number", SIAM Journal on Computing, 47 (6): 2435–2450, doi:10.1137/16M1059369
- ^ Chattopadhyay, Arkadev; Mande, Nikhil; Sherif, Suhail (2019), The Log-Approximate-Rank Conjecture is False, Annual ACM Symposium on the Theory of Computing, Phoenix, Arizona, USA
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