Hyper-optimistic conjecture: Difference between revisions
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[http://gowers.wordpress.com/2009/02/08/dhj-quasirandomness-and-obstructions-to-uniformity/#comment-2114 Gil Kalai] and [http://gowers.wordpress.com/2009/02/08/dhj-quasirandomness-and-obstructions-to-uniformity/#comment-2119 Tim Gowers] have proposed a “hyper-optimistic” conjecture. | [http://gowers.wordpress.com/2009/02/08/dhj-quasirandomness-and-obstructions-to-uniformity/#comment-2114 Gil Kalai] and [http://gowers.wordpress.com/2009/02/08/dhj-quasirandomness-and-obstructions-to-uniformity/#comment-2119 Tim Gowers] have proposed a “hyper-optimistic” conjecture. | ||
Let <math>c^\mu_n</math> be the [[equal-slices measure]] of a line-free set. For instance, <math>c^\mu_0 = 1</math>, <math>c^\mu_1 = 2</math>, and <math>c^\mu_2 = 4</math>. | Let <math>c^\mu_n</math> be the maximum [[equal-slices measure]] of a line-free set. For instance, <math>c^\mu_0 = 1</math>, <math>c^\mu_1 = 2</math>, and <math>c^\mu_2 = 4</math>. | ||
As in the unweighted case, every time we find a subset <math>B</math> of the grid <math>\Delta_n := \{ (a,b,c): a+b+c=n\}</math> without equilateral triangles, it gives a line-free set <math>\Gamma_B := \bigcup_{(a,b,c) \in B} \Gamma_{a,b,c}</math>. The [[equal-slices measure]] of this set is precisely the cardinality of B. Thus we have the lower bound <math>c^\mu_n \geq \overline{c}^\mu_n</math>, where <math>\overline{c}^\mu_n</math> is the largest size of equilateral triangles in <math>\Delta_n</math>. The computation of the <math>\overline{c}^\mu_n</math> is [[Fujimura's problem]]. | As in the unweighted case, every time we find a subset <math>B</math> of the grid <math>\Delta_n := \{ (a,b,c): a+b+c=n\}</math> without equilateral triangles, it gives a line-free set <math>\Gamma_B := \bigcup_{(a,b,c) \in B} \Gamma_{a,b,c}</math>. The [[equal-slices measure]] of this set is precisely the cardinality of B. Thus we have the lower bound <math>c^\mu_n \geq \overline{c}^\mu_n</math>, where <math>\overline{c}^\mu_n</math> is the largest size of equilateral triangles in <math>\Delta_n</math>. The computation of the <math>\overline{c}^\mu_n</math> is [[Fujimura's problem]]. | ||
Revision as of 00:17, 10 March 2009
Gil Kalai and Tim Gowers have proposed a “hyper-optimistic” conjecture.
Let [math]\displaystyle{ c^\mu_n }[/math] be the maximum equal-slices measure of a line-free set. For instance, [math]\displaystyle{ c^\mu_0 = 1 }[/math], [math]\displaystyle{ c^\mu_1 = 2 }[/math], and [math]\displaystyle{ c^\mu_2 = 4 }[/math].
As in the unweighted case, every time we find a subset [math]\displaystyle{ B }[/math] of the grid [math]\displaystyle{ \Delta_n := \{ (a,b,c): a+b+c=n\} }[/math] without equilateral triangles, it gives a line-free set [math]\displaystyle{ \Gamma_B := \bigcup_{(a,b,c) \in B} \Gamma_{a,b,c} }[/math]. The equal-slices measure of this set is precisely the cardinality of B. Thus we have the lower bound [math]\displaystyle{ c^\mu_n \geq \overline{c}^\mu_n }[/math], where [math]\displaystyle{ \overline{c}^\mu_n }[/math] is the largest size of equilateral triangles in [math]\displaystyle{ \Delta_n }[/math]. The computation of the [math]\displaystyle{ \overline{c}^\mu_n }[/math] is Fujimura's problem.
Hyper-optimistic conjecture: We in fact have [math]\displaystyle{ c^\mu_n = \overline{c}^\mu_n }[/math]. In other words, to get the optimal equal-slices measure for a line-free set, one should take a set which is a union of slices [math]\displaystyle{ \Gamma_{a,b,c} }[/math].
This conjecture, if true, will imply the DHJ theorem. Note also that all our best lower bounds for the unweighted problem to date have been unions of slices. Also, the k=2 analogue of the conjecture is true, and is known as the LYM inequality (in fact, for k=2 we have [math]\displaystyle{ c^\mu_n = \overline{c}^\mu_n = 1 }[/math] for all n).
Small values of [math]\displaystyle{ c^\mu_n }[/math]
I have now found the extremal solutions for the weighted problem in the hyper-optimistic conjecture, again using integer programming.
The first few values are
- [math]\displaystyle{ c^\mu_0=1 }[/math] (trivial)
- [math]\displaystyle{ c^\mu_1=2 }[/math] (trivial)
- [math]\displaystyle{ c^{\mu}_2=4 }[/math] with 3 solutions
- [math]\displaystyle{ c^{\mu}_3=6 }[/math] with 9 solutions
- [math]\displaystyle{ c^{\mu}_4=9 }[/math] with 1 solution
- [math]\displaystyle{ c^{\mu}_5=12 }[/math] with 1 solution
Comparing this with the known bounds for [math]\displaystyle{ \overline{c}^\mu_n }[/math] we see that the hyper-optimistic conjecture is true for [math]\displaystyle{ n \leq 5 }[/math].
