On Sunflowers and Matrix Multiplication

We present several variants of the sunflower conjecture of Erdos and Rado [ER60] and discuss the relations among them. We then show that two of these conjectures (if true) imply negative answers to questions of Coppersmith and Wino grad [CW90] and Cohn et al [CKSU05] regarding possible approaches for obtaining fast matrix multiplication algorithms. Specifically, we show that the Erdos-Rado sunflower conjecture (if true) implies a negative answer to the ``no three disjoint equivoluminous subsets'' question of Coppersmith and Wino grad [CW90]; we also formulate a ``multicolored'' sunflower conjecture in $\Z_3^n$ and show that (if true) it implies a negative answer to the ``strong USP'' conjecture of [CKSU05] (although it does not seem to impact a second conjecture in [CKSU05] or the viability of the general group-theoretic approach). A surprising consequence of our results is that the Coppersmith-Wino grad conjecture actually implies the Cohn et al. conjecture. The multicolored sunflower conjecture in $\Z_3^n$ is a strengthening of the well-known (ordinary) sunflower conjecture in $\Z_3^n$, and we show via our connection that a construction from [CKSU05] yields a lower bound of $(2.51\ldots)^n$ on the size of the largest {\em multicolored} 3-sunflower-free set, which beats the current best known lower bound of $(2.21\ldots)^n$ [Edel04] on the size of the largest 3-sunflower-free set in $\Z_3^n$.

[1]  Endre Szemerédi,et al.  Combinatorial Properties of Systems of Sets , 1978, J. Comb. Theory, Ser. A.

[2]  Michael Clausen,et al.  Algebraic complexity theory , 1997, Grundlehren der mathematischen Wissenschaften.

[3]  A. J. Stothers On the complexity of matrix multiplication , 2010 .

[4]  Michael Bateman,et al.  New Bounds on cap sets , 2011, 1101.5851.

[5]  J. Gathen Algebraic complexity theory , 1988 .

[6]  Don Coppersmith,et al.  Matrix multiplication via arithmetic progressions , 1987, STOC.

[7]  R. Salem,et al.  On Sets of Integers Which Contain No Three Terms in Arithmetical Progression. , 1942, Proceedings of the National Academy of Sciences of the United States of America.

[8]  Virginia Vassilevska Williams,et al.  Multiplying matrices faster than coppersmith-winograd , 2012, STOC '12.

[9]  V. Strassen Relative bilinear complexity and matrix multiplication. , 1987 .

[10]  Paul Erdös,et al.  On the combinatorial problems which I would most like to see solved , 1981, Comb..

[11]  Noga Alon,et al.  The monotone circuit complexity of boolean functions , 1987, Comb..

[12]  J. Spencer Intersection Theorems for Systems of Sets , 1977, Canadian Mathematical Bulletin.

[13]  P. Erdös,et al.  Intersection Theorems for Systems of Sets , 1960 .

[14]  P. Erdös,et al.  Intersection theorems for systems of sets (ii) , 1969 .

[15]  Yves Edel Extensions of Generalized Product Caps , 2004, Des. Codes Cryptogr..

[16]  Alexandr V. Kostochka,et al.  Intersection Statements for Systems of Sets , 1997, J. Comb. Theory, Ser. A.

[17]  Alexandr V. Kostochka A Bound of the Cardinality of Families Not Containing \(\Delta \) -Systems , 2013, The Mathematics of Paul Erdős II.

[18]  V. Strassen Gaussian elimination is not optimal , 1969 .

[19]  Roy Meshulam,et al.  On Subsets of Finite Abelian Groups with No 3-Term Arithmetic Progressions , 1995, J. Comb. Theory A.

[20]  N. Alon,et al.  Constructive lower bounds for off-diagonal Ramsey numbers , 2001 .

[21]  Christopher Umans,et al.  A group-theoretic approach to fast matrix multiplication , 2003, 44th Annual IEEE Symposium on Foundations of Computer Science, 2003. Proceedings..

[22]  Christopher Umans,et al.  Group-theoretic Algorithms for Matrix Multiplication , 2005, FOCS.

[23]  Z. Füredi Surveys in Combinatorics, 1991: “Turán Type Problems” , 1991 .