Camel Graph
المؤلف:
Ball, W. W. R. and Coxeter, H. S. M
المصدر:
Mathematical Recreations and Essays, 13th ed. New York: Dover, 1987. Dawson, T. R. "CaissaÕs Playthings." Cheltenham Examiner. 1913.
الجزء والصفحة:
...
24-2-2022
2920
Camel Graph
A camel graph is a graph formed by all possible moves of a hypothetical chess piece called a "camel" which moves analogously to a knight except that it is restricted to moves that change by one square along one axis of the board and three squares along the other. To form the graph, each chessboard square is considered a vertex, and vertices connected by allowable camel moves are considered edges. It is therefore a 
-leaper graph. The term is used by Jelliss (2019), who notes, "The first purely camel tour I know of is that by T. R. Dawson in 'Caissa's Playthings' in Cheltenham Examiner 1913, where he used the name."
Ball and Coxeter (1987, p. 186) state, "Euler's method [to construct a Hamiltonian cycle] can be applied to find routes of this kind: for instance, he applied it to find a re-entrant route by which a piece that moved two cells forward like a castle [rook] and then one cell like a bishop would occupy in succession all the black cells on the board." Such a series of moves corresponds to a camel tour (Jelliss 2019).
Like bishop graphs, camel graph are disconnected (except for the trivial singleton graph on a 
board which is trivially connected), with each component being restricted to either black or white squares. Again, as with the bishop graph, the black and white components of an 
camel graph are isomorphic iff 
and 
are not both odd.
The 
camel graph consists of a connected white component and a disconnected black component which, as in the case of the 
knight graph, includes a central (unreachable from all of the other squares) isolated vertex.
Camel graphs are bicolorable, bipartite, class 1, perfect, triangle-free, and weakly perfect.
Precomputed properties of camel graphs will be implemented in a future version of the Wolfram Language as GraphData[![<span style=]()
{" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline8.svg" style="height:21px; width:6px" />"Camel", ![<span style=]()
{" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline9.svg" style="height:21px; width:6px" />m, n![<span style=]()
}" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline10.svg" style="height:21px; width:6px" />![<span style=]()
}" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline11.svg" style="height:21px; width:6px" />].
REFERENCES
Ball, W. W. R. and Coxeter, H. S. M. Mathematical Recreations and Essays, 13th ed. New York: Dover, 1987.
Dawson, T. R. "CaissaÕs Playthings." Cheltenham Examiner. 1913.
Dawson, T. R. L'Echiquier. 1928.Hansson, F. Problem 715 in Problemist Fairy Chess Supplement. April and June 1933.
Jelliss, G. "The Big Beasts: Camel ![<span style=]()
{" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline12.svg" style="height:21px; width:6px" />1, 3![<span style=]()
}" src="https://mathworld.wolfram.com/images/equations/CamelGraph/Inline13.svg" style="height:21px; width:6px" />Shaped Boards." §10.27 in Knight's Tour Notes. 2019. http://www.mayhematics.com/p/KTN10_Leapers.pdfKraitchik, M. Le Problème du Cavalier. 1927.
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