Difference between revisions of "Prototile"
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| − | {{tiling/def}} | + | {{:tiling/def}} |
In the theory of [[tiling]]s a '''set of prototiles''', also called a '''protoset''', | In the theory of [[tiling]]s a '''set of prototiles''', also called a '''protoset''', | ||
is a (finite or infinite) set of tiles that represent (by congruence) all the tiles of a tiling, or of a class of tilings. | is a (finite or infinite) set of tiles that represent (by congruence) all the tiles of a tiling, or of a class of tilings. | ||
| − | A protoset $ \P = \{P_k\} $ ''admits'' a tiling if there is a tiling $\T$ such | + | A protoset $ \P = \{P_k\} $ ''admits'' a tiling if there is a tiling $ \T = \{T_i\} $ such |
that all its tiles $T_i$ are congruent to some $P_k$. | that all its tiles $T_i$ are congruent to some $P_k$. | ||
Revision as of 16:58, 11 February 2012
$ \def\T{\mathcal T} % tiling \def\P{\mathcal P} % protoset $
In the theory of tilings a set of prototiles, also called a protoset, is a (finite or infinite) set of tiles that represent (by congruence) all the tiles of a tiling, or of a class of tilings.
A protoset $ \P = \{P_k\} $ admits a tiling if there is a tiling $ \T = \{T_i\} $ such that all its tiles $T_i$ are congruent to some $P_k$.
Tiling problem
The tiling problem, i.e., the problem to determine whether a protoset admits a tiling is (algorithmically) undecidable, both in general and for many special cases. Normally, a protoset will (if at all) admit either a single tiling or uncountably many tilings, but intermediate numbers are also possible. If a protoset admits (up to congruence) only a single tiling then it is called monomorphic, if it admits precisely two distinct tilings it called dimorphic, trimorphic for three tilings, etc., $n$-morphic for $n$ tilings, and $\sigma$-morphic if there are countably many distinct tilings.
Prototile. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Prototile&oldid=20982