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 $D(f)$ denote the deterministic communication complexity of a function, and let $\operatorname {rank} (f)$ denote the rank of its input matrix $M_{f}$ (over the reals). Since every protocol using up to $c$ bits partitions $M_{f}$ into at most $2^{c}$ monochromatic rectangles, and each of these has rank at most 1,

D(f)\geq \log _{2}\operatorname {rank} (f).

The log-rank conjecture states that $D(f)$ is also upper-bounded by a polynomial in the log-rank: for some constant $C$ ,

D(f)=O((\log \operatorname {rank} (f))^{C}).

Lovett ^[3] proved the upper bound

D(f)=O\left({\sqrt {\operatorname {rank} (f)}}\log \operatorname {rank} (f)\right).

This was improved by Sudakov and Tomon,^[4] who removed the logarithmic factor, showing that

D(f)=O\left({\sqrt {\operatorname {rank} (f)}}\right).

This is the best currently known upper bound.

The best known lower bound, due to Göös, Pitassi and Watson,^[5] states that $C\geq 2$ . In other words, there exists a sequence of functions $f_{n}$ , whose log-rank goes to infinity, such that

D(f_{n})={\tilde {\Omega }}((\log \operatorname {rank} (f_{n}))^{2}).

In 2019, an approximate version of the conjecture has been disproved.^[6]

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{{citation}}: 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{{citation}}: CS1 maint: location missing publisher (link)

[1] 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{{citation}}: CS1 maint: location missing publisher (link)

[2] Lovett, Shachar (February 2014), "Recent advances on the log-rank conjecture in communication complexity", Bulletin of the EATCS, 112, arXiv:1403.8106

[3] 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

[4] Sudakov, Benny; Tomon, Istvan (30 Nov 2023). "Matrix discrepancy and the log-rank conjecture". arXiv:2311.18524 [math].

[5] Göös, Mika; Pitassi, Toniann; Watson, Thomas (2018), "Deterministic Communication vs. Partition Number", SIAM Journal on Computing, 47 (6): 2435–2450, doi:10.1137/16M1059369

[6] 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{{citation}}: CS1 maint: location missing publisher (link)

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