Combinatorial subspace: Difference between revisions
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For example, the following strings form a 2-dimensional combinatorial subspace of the strong kind (the wildcard sets are indicated above by a and b) | For example, the following strings form a 2-dimensional combinatorial subspace of the strong kind (the wildcard sets are indicated above by a and b) | ||
a a a b b a a a b b a a a b b | |||
3312131122121 3312131122222 3312131122323 | |||
3322231222121 3322231222222 3322231222323 | |||
3332331322121 3332331322222 3332331322323 | |||
and the following strings form a 2-dimensional combinatorial subspace of the weaker kind | and the following strings form a 2-dimensional combinatorial subspace of the weaker kind | ||
a b a b a b a b a b a b | |||
113113121311321 113213122311321 113313123311321 | 113113121311321 113213122311321 113313123311321 | ||
113113221312321 113213222312321 113313223312321 | 113113221312321 113213222312321 113313223312321 | ||
113113221313321 113213322313321 113313323313321 | 113113221313321 113213322313321 113313323313321 | ||
There is also a natural notion of a ''combinatorial embedding'' of <math>[3]^m</math> into <math>[3]^n.</math> Given a string <math>x\in[3]^n</math> and m disjoint subsets <math>W_1,\dots,W_m</math> of <math>[n],</math> send <math>y\in[3]^m</math> to <math>x+\sum_iy_iW_i,</math> where this denotes the sequence that takes the value <math>y_i</math> everywhere in the set <math>W_i</math> and is equal to x everywhere that does not belong to any <math>W_i</math>. An m-dimensional combinatorial subspace is the image of a combinatorial embedding. | There is also a natural notion of a ''combinatorial embedding'' of <math>[3]^m</math> into <math>[3]^n.</math> Given a string <math>x\in[3]^n</math> and m disjoint subsets <math>W_1,\dots,W_m</math> of <math>[n],</math> send <math>y\in[3]^m</math> to <math>x+\sum_iy_iW_i,</math> where this denotes the sequence that takes the value <math>y_i</math> everywhere in the set <math>W_i</math> and is equal to x everywhere that does not belong to any <math>W_i</math>. An m-dimensional combinatorial subspace is the image of a combinatorial embedding. | ||
Revision as of 15:07, 16 February 2009
An m-dimensional combinatorial subspace is obtained by taking m disjoint subsets [math]\displaystyle{ W_1,\dots,W_m }[/math] of [math]\displaystyle{ [n], }[/math] fixing the values of all coordinates outside these subsets, and taking all points that equal the fixed values outside the [math]\displaystyle{ W_i }[/math] and are constant on each [math]\displaystyle{ W_i. }[/math] Sometimes one adds the restriction that the maximum of each [math]\displaystyle{ W_i }[/math] is less than the minimum of [math]\displaystyle{ W_{i+1} }[/math]. (In particular, the Hales-Jewett theorem can be straightforwardly generalized to yield a monochromatic subspace of this more stronger kind.) In other words, where a combinatorial line has one set of wildcards, an m-dimensional combinatorial subspace has m sets of wildcards
For example, the following strings form a 2-dimensional combinatorial subspace of the strong kind (the wildcard sets are indicated above by a and b)
a a a b b a a a b b a a a b b 3312131122121 3312131122222 3312131122323 3322231222121 3322231222222 3322231222323 3332331322121 3332331322222 3332331322323
and the following strings form a 2-dimensional combinatorial subspace of the weaker kind
a b a b a b a b a b a b 113113121311321 113213122311321 113313123311321 113113221312321 113213222312321 113313223312321 113113221313321 113213322313321 113313323313321
There is also a natural notion of a combinatorial embedding of [math]\displaystyle{ [3]^m }[/math] into [math]\displaystyle{ [3]^n. }[/math] Given a string [math]\displaystyle{ x\in[3]^n }[/math] and m disjoint subsets [math]\displaystyle{ W_1,\dots,W_m }[/math] of [math]\displaystyle{ [n], }[/math] send [math]\displaystyle{ y\in[3]^m }[/math] to [math]\displaystyle{ x+\sum_iy_iW_i, }[/math] where this denotes the sequence that takes the value [math]\displaystyle{ y_i }[/math] everywhere in the set [math]\displaystyle{ W_i }[/math] and is equal to x everywhere that does not belong to any [math]\displaystyle{ W_i }[/math]. An m-dimensional combinatorial subspace is the image of a combinatorial embedding.
