Still life
A still life (or stable pattern) is a pattern that does not change from one generation to the next, and thus may be thought of as an oscillator with period 1. Still lifes are sometimes assumed to be finite and nonempty. The two main subgroups of still lifes are strict still lifes and pseudo still lifes. In some contexts, the term "still life" may refer to strict still lifes.
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Strict still lifes
A strict still life is a still life that is either connected (i.e., has no islands), or is such that removing one or more its islands destroys the stability of the pattern. For example, beehive with tail is a strict still life because it is connected, and table on table is a strict still life because neither of the tables are stable by themselves.
Pseudo still lifes
A pseudo still life consists of two or more islands which can be partitioned (either individually or as sets) into noninteracting subpatterns which are by themselves each still lifes. Furthermore, there must be at least one dead cell that has more than three alive neighbours in the overall pattern but has less than three alive neighbours in the subpatterns. This final restriction removes patterns such as bakery, blockade and fleet from consideration, as the islands are not "almost touching".
Note that a pattern may have multiple disconnected components and still be a strict (as opposed to pseudo) still life if the disconnected components are dependent on each other for stability (for example, table on table above). Some pseudo still lifes have also been found by Gabriel Nivasch that can be partitioned into a minimum of three and four stable subpatterns, respectively, as in the second and third images below.^{[1]} The stable subpatterns themselves may be either strict or pseudo still lifes. It is not possible to construct a pseudo still life that can be partitioned into a minimum of greater than four stable subpatterns because of the Four Color Theorem.^{[1]}
It has been shown that it is possible to determine whether a still life pattern is a strict still life or a pseudo still life in polynomial time by searching for cycles in an associated skewsymmetric graph.^{[2]}^{[3]}
Constellations
A constellation is not, strictly speaking, a still life; instead, the term is used for patterns composed of two or more noninteracting objects. This contrasts with pseudo still lifes, in which the objects in question must interact. Compare for instance the biblock and blockade:
Enumerating still lifes
The number of strict and pseudo still lifes that exist for a given number of cells has been enumerated up to 24. The values in the strict still life table below were originally computed by John Conway (47 cells), Robert Wainwright (810 cells), David Buckingham (1113 cells), Peter Raynham (14 cells), Mark Niemiec (1524 cells), Simon Ekström (2528 cells), Simon Ekström and "Apple Bottom" (2930 cells), and Nathaniel Johnston (3132 cells). The values in the pseudo still life table were enumerated by Mark Niemiec (124 cells), Simon Ekström (2528 cells), Simon Ekström and "Apple Bottom" (2930 cells), and Nathaniel Johnston (3132 cells). The values in the tables below are given by Sloane's A019473 and A056613, respectively.


See also
 List of common still lifes
 List of pseudo still lifes
 List of still lifes
 List of strict still lifes
References
 ↑ ^{1.0} ^{1.1} Nivasch, Gabriel (July, 2001). "Still lifes". Retrieved on March 23, 2016.
 ↑ Cook, Matthew (2003). "Still life theory". New Constructions in Cellular Automata: 93–118, Santa Fe Institute Studies in the Sciences of Complexity, Oxford University Press.
 ↑ Cook, Matthew. "Still Life". Mathematical Sciences Research Institute.
External links
 Life Object Counts at Mark D. Niemiec's Life Page