Knight's tour

Last updated July 06, 2024

An animation of an open knight's tour on a 5 x 5 board Knights-Tour-Animation.gif — An animation of an open knight's tour on a 5 × 5 board

A knight's tour is a sequence of moves of a knight on a chessboard such that the knight visits every square exactly once. If the knight ends on a square that is one knight's move from the beginning square (so that it could tour the board again immediately, following the same path), the tour is closed (or re-entrant); otherwise, it is open.^[1]^[2]

The knight's tour problem is the mathematical problem of finding a knight's tour. Creating a program to find a knight's tour is a common problem given to computer science students.^[3] Variations of the knight's tour problem involve chessboards of different sizes than the usual 8 × 8, as well as irregular (non-rectangular) boards.

Theory

The knight's tour problem is an instance of the more general Hamiltonian path problem in graph theory. The problem of finding a closed knight's tour is similarly an instance of the Hamiltonian cycle problem. Unlike the general Hamiltonian path problem, the knight's tour problem can be solved in linear time.^[4]

History

The knight's tour as solved by the Turk, a chess-playing machine hoax. This particular solution is closed (circular), and can thus be completed from any point on the board. Turk-knights-tour.svg — The knight's tour as solved by the Turk, a chess-playing machine hoax. This particular solution is closed (circular), and can thus be completed from any point on the board.

The earliest known reference to the knight's tour problem dates back to the 9th century AD. In Rudrata's Kavyalankara^[5] (5.15), a Sanskrit work on Poetics, the pattern of a knight's tour on a half-board has been presented as an elaborate poetic figure (citra-alaṅkāra) called the turagapadabandha or 'arrangement in the steps of a horse'. The same verse in four lines of eight syllables each can be read from left to right or by following the path of the knight on tour. Since the Indic writing systems used for Sanskrit are syllabic, each syllable can be thought of as representing a square on a chessboard. Rudrata's example is as follows:

से	ना	ली	ली	ली	ना	ना	ली
ली	ना	ना	ना	ना	ली	ली	ली
न	ली	ना	ली	ले	ना	ली	ना
ली	ली	ली	ना	ना	ना	ना	ली

transliterated:

se	nā	lī	lī	lī	nā	nā	lī
lī	nā	nā	nā	nā	lī	lī	lī
na	lī	nā	lī	le	nā	lī	nā
lī	lī	lī	nā	nā	nā	nā	lī

For example, the first line can be read from left to right or by moving from the first square to the second line, third syllable (2.3) and then to 1.5 to 2.7 to 4.8 to 3.6 to 4.4 to 3.2.

The Sri Vaishnava poet and philosopher Vedanta Desika, during the 14th century, in his 1,008-verse magnum opus praising the deity Ranganatha's divine sandals of Srirangam, Paduka Sahasram (in chapter 30: Chitra Paddhati) has composed two consecutive Sanskrit verses containing 32 letters each (in Anushtubh meter) where the second verse can be derived from the first verse by performing a Knight's tour on a 4 × 8 board, starting from the top-left corner.^[6] The transliterated 19th verse is as follows:

sThi (1)	rA (30)	ga (9)	sAm (20)	sa (3)	dhA (24)	rA (11)	dhyA (26)
vi (16)	ha (19)	thA (2)	ka (29)	tha (10)	thA (27)	ma (4)	thA (23)
sa (31)	thpA (8)	dhu (17)	kE (14)	sa (21)	rA (6)	sA (25)	mA (12)
ran (18)	ga (15)	rA (32)	ja (7)	pa (28)	dha (13)	nna (22)	ya (5)

The 20th verse that can be obtained by performing Knight's tour on the above verse is as follows:

sThi thA sa ma ya rA ja thpA

ga tha rA mA dha kE ga vi |

dhu ran ha sAm sa nna thA dhA

sA dhyA thA pa ka rA sa rA ||

It is believed that Desika composed all 1,008 verses (including the special Chaturanga Turanga Padabandham mentioned above) in a single night as a challenge.^[7]

A tour reported in the fifth book of Bhagavantabaskaraby by Bhat Nilakantha, a cyclopedic work in Sanskrit on ritual, law and politics, written either about 1600 or about 1700 describes three knight's tours. The tours are not only reentrant but also symmetrical, and the verses are based on the same tour, starting from different squares.^[8] Nilakantha's work is an extraordinary achievement being a fully symmetric closed tour, predating the work of Euler (1759) by at least 60 years.

After Nilakantha, one of the first mathematicians to investigate the knight's tour was Leonhard Euler. The first procedure for completing the knight's tour was Warnsdorf's rule, first described in 1823 by H. C. von Warnsdorf.

In the 20th century, the Oulipo group of writers used it, among many others. The most notable example is the 10 × 10 knight's tour which sets the order of the chapters in Georges Perec's novel Life a User's Manual .

The sixth game of the World Chess Championship 2010 between Viswanathan Anand and Veselin Topalov saw Anand making 13 consecutive knight moves (albeit using both knights); online commentators jested that Anand was trying to solve the knight's tour problem during the game.

Existence

Schwenk^[10] proved that for any m × n board with m ≤ n, a closed knight's tour is always possible unless one or more of these three conditions are met:

m and n are both odd
m = 1, 2, or 4
m = 3 and n = 4, 6, or 8.

Cull et al. and Conrad et al. proved that on any rectangular board whose smaller dimension is at least 5, there is a (possibly open) knight's tour.^[4]^[11] For any m × n board with m ≤ n, a knight's tour is always possible unless one or more of these three conditions are met:

m = 1 or 2
m = 3 and n = 3, 5, or 6^[12]
m = 4 and n = 4.^[13]

Number of tours

On an 8 × 8 board, there are exactly 26,534,728,821,064 directed closed tours (i.e. two tours along the same path that travel in opposite directions are counted separately, as are rotations and reflections).^[14]^[15]^[16] The number of undirected closed tours is half this number, since every tour can be traced in reverse. There are 9,862 undirected closed tours on a 6 × 6 board.^[17]

n	Number of directed tours (open and closed) on an n × n board (sequence A165134 in the OEIS )
1	1
2	0
3	0
4	0
5	1,728
6	6,637,920
7	165,575,218,320
8	19,591,828,170,979,904

Finding tours with computers

There are several ways to find a knight's tour on a given board with a computer. Some of these methods are algorithms, while others are heuristics.

Brute-force algorithms

A brute-force search for a knight's tour is impractical on all but the smallest boards.^[18] On an 8 × 8 board, for instance, there are 13267364410532 knight's tours,^[14] and a much greater number of sequences of knight moves of the same length. It is well beyond the capacity of modern computers (or networks of computers) to perform operations on such a large set. However, the size of this number is not indicative of the difficulty of the problem, which can be solved "by using human insight and ingenuity ... without much difficulty."^[18]

Divide-and-conquer algorithms

By dividing the board into smaller pieces, constructing tours on each piece, and patching the pieces together, one can construct tours on most rectangular boards in linear time – that is, in a time proportional to the number of squares on the board.^[11]^[19]

Warnsdorf's rule

	a	b	c	d	e	f	g	h
8									8
7									7
6									6
5									5
4									4
3									3
2									2
1									1
	a	b	c	d	e	f	g	h

A graphical representation of Warnsdorf's Rule. Each square contains an integer giving the number of moves that the knight could make from that square. In this case, the rule tells us to move to the square with the smallest integer in it, namely 2.

Warnsdorf's rule is a heuristic for finding a single knight's tour. The knight is moved so that it always proceeds to the square from which the knight will have the fewest onward moves. When calculating the number of onward moves for each candidate square, we do not count moves that revisit any square already visited. It is possible to have two or more choices for which the number of onward moves is equal; there are various methods for breaking such ties, including one devised by Pohl^[20] and another by Squirrel and Cull.^[21]

This rule may also more generally be applied to any graph. In graph-theoretic terms, each move is made to the adjacent vertex with the least degree.^[22] Although the Hamiltonian path problem is NP-hard in general, on many graphs that occur in practice this heuristic is able to successfully locate a solution in linear time.^[20] The knight's tour is such a special case.^[23]

The heuristic was first described in "Des Rösselsprungs einfachste und allgemeinste Lösung" by H. C. von Warnsdorf in 1823.^[23]

A computer program that finds a knight's tour for any starting position using Warnsdorf's rule was written by Gordon Horsington and published in 1984 in the book Century/Acorn User Book of Computer Puzzles.^[24]

Neural network solutions

The knight's tour problem also lends itself to being solved by a neural network implementation.^[25] The network is set up such that every legal knight's move is represented by a neuron, and each neuron is initialized randomly to be either "active" or "inactive" (output of 1 or 0), with 1 implying that the neuron is part of the solution. Each neuron also has a state function (described below) which is initialized to 0.

When the network is allowed to run, each neuron can change its state and output based on the states and outputs of its neighbors (those exactly one knight's move away) according to the following transition rules:

U_{t+1}(N_{i,j})=U_{t}(N_{i,j})+2-\sum _{N\in G(N_{i,j})}V_{t}(N)

V_{t+1}(N_{i,j})=\left\{{\begin{array}{ll}1&{\mbox{if}}\,\,U_{t+1}(N_{i,j})>3\\0&{\mbox{if}}\,\,U_{t+1}(N_{i,j})<0\\V_{t}(N_{i,j})&{\mbox{otherwise}},\end{array}}\right.

where $t$ represents discrete intervals of time, $U(N_{i,j})$ is the state of the neuron connecting square $i$ to square $j$ , $V(N_{i,j})$ is the output of the neuron from $i$ to $j$ , and $G(N_{i,j})$ is the set of neighbors of the neuron.

Although divergent cases are possible, the network should eventually converge, which occurs when no neuron changes its state from time $t$ to $t+1$ . When the network converges, either the network encodes a knight's tour or a series of two or more independent circuits within the same board.

Notes

↑ Brown, Alfred James (2017). Knight's Tours and Zeta Functions (MS thesis). San José State University. p. 3. doi: 10.31979/etd.e7ra-46ny .
↑ Hooper, David; Whyld, Kenneth (1996) [First pub. 1992]. "knight's tour". The Oxford Companion to Chess (2nd ed.). Oxford University Press. p. 204. ISBN 0-19-280049-3.
↑ Deitel, H. M.; Deitel, P. J. (2003). Java How To Program Fifth Edition (5th ed.). Prentice Hall. pp. 326–328. ISBN 978-0131016217.
1 2 Conrad, A.; Hindrichs, T.; Morsy, H. & Wegener, I. (1994). "Solution of the Knight's Hamiltonian Path Problem on Chessboards". Discrete Applied Mathematics. 50 (2): 125–134. doi: 10.1016/0166-218X(92)00170-Q .
↑ Satyadev, Chaudhary. Kavyalankara of Rudrata (Sanskrit text, with Hindi translation);. Delhitraversal: Parimal Sanskrit Series No. 30.
↑ "Indian Institute of Information Technology, Bangalore". www.iiitb.ac.in. Retrieved 2019-10-11.
↑ Bridge-india (2011-08-05). "Bridge-India: Paduka Sahasram by Vedanta Desika". Bridge-India. Retrieved 2019-10-16.
↑ A History of Chess by Murray
↑ "MathWorld News: There Are No Magic Knight's Tours on the Chessboard".
↑ Allen J. Schwenk (1991). "Which Rectangular Chessboards Have a Knight's Tour?" (PDF). Mathematics Magazine. 64 (5): 325–332. doi:10.1080/0025570X.1991.11977627. S2CID 28726833. Archived from the original (PDF) on 2019-05-26.
1 2 Cull, P.; De Curtins, J. (1978). "Knight's Tour Revisited" (PDF). Fibonacci Quarterly. 16: 276–285. Archived (PDF) from the original on 2022-10-09.
↑ "Knight's Tours on 3 by N Boards".
↑ "Knight's Tours on 4 by N Boards".
1 2 Löbbing, Martin; Wegener, Ingo (1996). "The number of knight's tours equals 33,439,123,484,294—counting with binary decision diagrams". Electronic Journal of Combinatorics. 3 (1). Research Paper 5. doi:10.37236/1229. MR 1368332. See attached comment by Brendan McKay, Feb 18, 1997, for the corrected count.
↑ Brendan McKay (1997). "Knight's Tours on an 8 × 8 Chessboard". Technical Report TR-CS-97-03. Department of Computer Science, Australian National University. Archived from the original on 2013-09-28. Retrieved 2013-09-22.
↑ Wegener, I. (2000). Branching Programs and Binary Decision Diagrams. Society for Industrial & Applied Mathematics. ISBN 978-0-89871-458-6.
↑ Weisstein, Eric W. "Knight Graph". MathWorld .
1 2 Simon, Dan (2013), Evolutionary Optimization Algorithms, John Wiley & Sons, pp. 449–450, ISBN 9781118659502, The knight's tour problem is a classic combinatorial optimization problem. ... The cardinality N_x of x (the size of the search space) is over 3.3×10¹³ (Löbbing and Wegener, 1995). We would not want to try to solve this problem using brute force, but by using human insight and ingenuity we can solve the knight's tour without much difficulty. We see that the cardinality of a combinatorial optimization problem is not necessarily indicative of its difficulty.
↑ Parberry, Ian (1997). "An Efficient Algorithm for the Knight's Tour Problem" (PDF). Discrete Applied Mathematics. 73 (3): 251–260. doi: 10.1016/S0166-218X(96)00010-8 . Archived (PDF) from the original on 2022-10-09.
1 2 Pohl, Ira (July 1967). "A method for finding Hamilton paths and Knight's tours". Communications of the ACM. 10 (7): 446–449. CiteSeerX 10.1.1.412.8410 . doi:10.1145/363427.363463. S2CID 14100648.
↑ Squirrel, Douglas; Cull, P. (1996). "A Warnsdorff-Rule Algorithm for Knight's Tours on Square Boards" (PDF). GitHub . Retrieved 2011-08-21.
↑ Van Horn, Gijs; Olij, Richard; Sleegers, Joeri; Van den Berg, Daan (2018). A Predictive Data Analytic for the Hardness of Hamiltonian Cycle Problem Instances (PDF). DATA ANALYTICS 2018: The Seventh International Conference on Data Analytics. Athens, greece: XPS. pp. 91–96. ISBN 978-1-61208-681-1 . Retrieved 2018-11-27.
1 2 Alwan, Karla; Waters, K. (1992). Finding Re-entrant Knight's Tours on N-by-M Boards. ACM Southeast Regional Conference. New York, New York: ACM. pp. 377–382. doi:10.1145/503720.503806.
↑ Dally, Simon, ed. (1984). Century/Acorn User Book of Computer Puzzles. Century Communications. ISBN 978-0712605410.
↑ Y. Takefuji, K. C. Lee. "Neural network computing for knight's tour problems." Neurocomputing, 4(5):249–254, 1992.

External links

Media related to Knight's Tours at Wikimedia Commons
OEIS sequenceA001230(Number of undirected closed knight's tours on a 2n X 2n chessboard)
H. C. von Warnsdorf 1823 in Google Books
Introduction to Knight's tours by George Jelliss
Knight's tours complete notes by George Jelliss
Philip, Anish (2013). "A Generalized Pseudo-Knight?s Tour Algorithm for Encryption of an Image". IEEE Potentials. 32 (6): 10–16. doi:10.1109/MPOT.2012.2219651. S2CID 39213422.

Related Research Articles

The eight queens puzzle is the problem of placing eight chess queens on an 8×8 chessboard so that no two queens threaten each other; thus, a solution requires that no two queens share the same row, column, or diagonal. There are 92 solutions. The problem was first posed in the mid-19th century. In the modern era, it is often used as an example problem for various computer programming techniques.

The travelling salesman problem, also known as the travelling salesperson problem (TSP), asks the following question: "Given a list of cities and the distances between each pair of cities, what is the shortest possible route that visits each city exactly once and returns to the origin city?" It is an NP-hard problem in combinatorial optimization, important in theoretical computer science and operations research.

The Hamiltonian path problem is a topic discussed in the fields of complexity theory and graph theory. It decides if a directed or undirected graph, G, contains a Hamiltonian path, a path that visits every vertex in the graph exactly once. The problem may specify the start and end of the path, in which case the starting vertex s and ending vertex t must be identified.

<span class="mw-page-title-main">Hamiltonian path</span> Path in a graph that visits each vertex exactly once

In the mathematical field of graph theory, a Hamiltonian path is a path in an undirected or directed graph that visits each vertex exactly once. A Hamiltonian cycle is a cycle that visits each vertex exactly once. A Hamiltonian path that starts and ends at adjacent vertices can be completed by adding one more edge to form a Hamiltonian cycle, and removing any edge from a Hamiltonian cycle produces a Hamiltonian path. The computational problems of determining whether such paths and cycles exist in graphs are NP-complete; see Hamiltonian path problem for details.

In computer science, a topological sort or topological ordering of a directed graph is a linear ordering of its vertices such that for every directed edge (u,v) from vertex u to vertex v, u comes before v in the ordering. For instance, the vertices of the graph may represent tasks to be performed, and the edges may represent constraints that one task must be performed before another; in this application, a topological ordering is just a valid sequence for the tasks. Precisely, a topological sort is a graph traversal in which each node v is visited only after all its dependencies are visited. A topological ordering is possible if and only if the graph has no directed cycles, that is, if it is a directed acyclic graph (DAG). Any DAG has at least one topological ordering, and algorithms are known for constructing a topological ordering of any DAG in linear time. Topological sorting has many applications, especially in ranking problems such as feedback arc set. Topological sorting is possible even when the DAG has disconnected components.

In the mathematical field of graph theory, a cubic graph is a graph in which all vertices have degree three. In other words, a cubic graph is a 3-regular graph. Cubic graphs are also called trivalent graphs.

The longest uncrossedknight's path is a mathematical problem involving a knight on the standard 8×8 chessboard or, more generally, on a square n×n board. The problem is to find the longest path the knight can take on the given board, such that the path does not intersect itself. A further distinction can be made between a closed path, which ends on the same field as where it begins, and an open path, which ends on a different field from where it begins.

A zero-suppressed decision diagram is a particular kind of binary decision diagram (BDD) with fixed variable ordering. This data structure provides a canonically compact representation of sets, particularly suitable for certain combinatorial problems. Recall the Ordered Binary Decision Diagram (OBDD) reduction strategy, i.e. a node is replaced with one of its children if both out-edges point to the same node. In contrast, a node in a ZDD is replaced with its negative child if its positive edge points to the terminal node 0. This provides an alternative strong normal form, with improved compression of sparse sets. It is based on a reduction rule devised by Shin-ichi Minato in 1993.

In graph theory, a king's graph is a graph that represents all legal moves of the king chess piece on a chessboard where each vertex represents a square on a chessboard and each edge is a legal move. More specifically, an $king's graph is a king's graph of an chessboard. It is the map graph formed from the squares of a chessboard by making a vertex for each square and an edge for each two squares that share an edge or a corner. It can also be constructed as the strong product of two path graphs.$

In graph theory, a knight's graph, or a knight's tour graph, is a graph that represents all legal moves of the knight chess piece on a chessboard. Each vertex of this graph represents a square of the chessboard, and each edge connects two squares that are a knight's move apart from each other. More specifically, an $knight's graph is a knight's graph of an chessboard. Its vertices can be represented as the points of the Euclidean plane whose Cartesian coordinates are integers with and, and with two vertices connected by an edge when their Euclidean distance is .$

<span class="mw-page-title-main">Hypercube graph</span> Graphs formed by a hypercubes edges and vertices

In graph theory, the hypercube graph $Q n$ is the graph formed from the vertices and edges of an $n$ -dimensional hypercube. For instance, the cube graph $Q 3$ is the graph formed by the 8 vertices and 12 edges of a three-dimensional cube. $Q n$ has $2 n$ vertices, $2 n - 1 n$ edges, and is a regular graph with $n$ edges touching each vertex.

In graph theory, a rook's graph is an undirected graph that represents all legal moves of the rook chess piece on a chessboard. Each vertex of a rook's graph represents a square on a chessboard, and there is an edge between any two squares sharing a row (rank) or column (file), the squares that a rook can move between. These graphs can be constructed for chessboards of any rectangular shape. Although rook's graphs have only minor significance in chess lore, they are more important in the abstract mathematics of graphs through their alternative constructions: rook's graphs are the Cartesian product of two complete graphs, and are the line graphs of complete bipartite graphs. The square rook's graphs constitute the two-dimensional Hamming graphs.

The mutilated chessboard problem is a tiling puzzle posed by Max Black in 1946 that asks:

Suppose a standard 8×8 chessboard has two diagonally opposite corners removed, leaving 62 squares. Is it possible to place 31 dominoes of size 2×1 so as to cover all of these squares?

Rudrata was a Kashmiri poet and literary theorist, who wrote a work called the Kavyalankara in the first quarter of the ninth century. Very little is known about Rudrata. From Namisadhu's commentary on the verses 12-14 of the fifth chapter of the Kavyalankara, it is inferred that he was also known as Shatananda and his father's name was Bhamuka.

Adiabatic quantum computation (AQC) is a form of quantum computing which relies on the adiabatic theorem to perform calculations and is closely related to quantum annealing.

A mathematical chess problem is a mathematical problem which is formulated using a chessboard and chess pieces. These problems belong to recreational mathematics. The most well-known problems of this kind are the eight queens puzzle and the knight's tour problem, which have connection to graph theory and combinatorics. Many famous mathematicians studied mathematical chess problems, such as, Thabit, Euler, Legendre and Gauss. Besides finding a solution to a particular problem, mathematicians are usually interested in counting the total number of possible solutions, finding solutions with certain properties, as well as generalization of the problems to N×N or M×N boards.

Quantum optimization algorithms are quantum algorithms that are used to solve optimization problems. Mathematical optimization deals with finding the best solution to a problem from a set of possible solutions. Mostly, the optimization problem is formulated as a minimization problem, where one tries to minimize an error which depends on the solution: the optimal solution has the minimal error. Different optimization techniques are applied in various fields such as mechanics, economics and engineering, and as the complexity and amount of data involved rise, more efficient ways of solving optimization problems are needed. Quantum computing may allow problems which are not practically feasible on classical computers to be solved, or suggest a considerable speed up with respect to the best known classical algorithm.

In mathematics, the Hamiltonian cycle polynomial of an n×n-matrix is a polynomial in its entries, defined as

In mathematics, a queen's graph is an undirected graph that represents all legal moves of the queen—a chess piece—on a chessboard. In the graph, each vertex represents a square on a chessboard, and each edge is a legal move the queen can make, that is, a horizontal, vertical or diagonal move by any number of squares. If the chessboard has dimensions $, then the induced graph is called the queen's graph.$

In mathematics, a bishop's graph is a graph that represents all legal moves of the chess piece the bishop on a chessboard. Each vertex represents a square on the chessboard and each edge represents a legal move of the bishop; that is, there is an edge between two vertices (squares) if they occupy a common diagonal. When the chessboard has dimensions $, then the induced graph is called the bishop's graph.$

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Brown, Alfred James (2017). Knight's Tours and Zeta Functions (MS thesis). San José State University. p. 3. doi: 10.31979/etd.e7ra-46ny .

[2] Hooper, David; Whyld, Kenneth (1996) [First pub. 1992]. "knight's tour". The Oxford Companion to Chess (2nd ed.). Oxford University Press. p. 204. ISBN 0-19-280049-3.

[3] Deitel, H. M.; Deitel, P. J. (2003). Java How To Program Fifth Edition (5th ed.). Prentice Hall. pp. 326–328. ISBN 978-0131016217.

[Conrad1994-4] 1 2 Conrad, A.; Hindrichs, T.; Morsy, H. & Wegener, I. (1994). "Solution of the Knight's Hamiltonian Path Problem on Chessboards". Discrete Applied Mathematics. 50 (2): 125–134. doi: 10.1016/0166-218X(92)00170-Q .

[5] Satyadev, Chaudhary. Kavyalankara of Rudrata (Sanskrit text, with Hindi translation);. Delhitraversal: Parimal Sanskrit Series No. 30.

[6] "Indian Institute of Information Technology, Bangalore". www.iiitb.ac.in. Retrieved 2019-10-11.

[7] Bridge-india (2011-08-05). "Bridge-India: Paduka Sahasram by Vedanta Desika". Bridge-India. Retrieved 2019-10-16.

[8] A History of Chess by Murray

[9] "MathWorld News: There Are No Magic Knight's Tours on the Chessboard".

[10] Allen J. Schwenk (1991). "Which Rectangular Chessboards Have a Knight's Tour?" (PDF). Mathematics Magazine. 64 (5): 325–332. doi:10.1080/0025570X.1991.11977627. S2CID 28726833. Archived from the original (PDF) on 2019-05-26.

[Cull1978-11] 1 2 Cull, P.; De Curtins, J. (1978). "Knight's Tour Revisited" (PDF). Fibonacci Quarterly. 16: 276–285. Archived (PDF) from the original on 2022-10-09.

[12] "Knight's Tours on 3 by N Boards".

[13] "Knight's Tours on 4 by N Boards".

[lw96-14] 1 2 Löbbing, Martin; Wegener, Ingo (1996). "The number of knight's tours equals 33,439,123,484,294—counting with binary decision diagrams". Electronic Journal of Combinatorics. 3 (1). Research Paper 5. doi:10.37236/1229. MR 1368332. See attached comment by Brendan McKay, Feb 18, 1997, for the corrected count.

[15] Brendan McKay (1997). "Knight's Tours on an 8 × 8 Chessboard". Technical Report TR-CS-97-03. Department of Computer Science, Australian National University. Archived from the original on 2013-09-28. Retrieved 2013-09-22.

[16] Wegener, I. (2000). Branching Programs and Binary Decision Diagrams. Society for Industrial & Applied Mathematics. ISBN 978-0-89871-458-6.

[17] Weisstein, Eric W. "Knight Graph". MathWorld .

[Simon01a-18] 1 2 Simon, Dan (2013), Evolutionary Optimization Algorithms, John Wiley & Sons, pp. 449–450, ISBN 9781118659502, The knight's tour problem is a classic combinatorial optimization problem. ... The cardinality N_x of x (the size of the search space) is over 3.3×10¹³ (Löbbing and Wegener, 1995). We would not want to try to solve this problem using brute force, but by using human insight and ingenuity we can solve the knight's tour without much difficulty. We see that the cardinality of a combinatorial optimization problem is not necessarily indicative of its difficulty.

[19] Parberry, Ian (1997). "An Efficient Algorithm for the Knight's Tour Problem" (PDF). Discrete Applied Mathematics. 73 (3): 251–260. doi: 10.1016/S0166-218X(96)00010-8 . Archived (PDF) from the original on 2022-10-09.

[pohl-20] 1 2 Pohl, Ira (July 1967). "A method for finding Hamilton paths and Knight's tours". Communications of the ACM. 10 (7): 446–449. CiteSeerX 10.1.1.412.8410 . doi:10.1145/363427.363463. S2CID 14100648.

[21] Squirrel, Douglas; Cull, P. (1996). "A Warnsdorff-Rule Algorithm for Knight's Tours on Square Boards" (PDF). GitHub . Retrieved 2011-08-21.

[Van_Horn_et._al-22] Van Horn, Gijs; Olij, Richard; Sleegers, Joeri; Van den Berg, Daan (2018). A Predictive Data Analytic for the Hardness of Hamiltonian Cycle Problem Instances (PDF). DATA ANALYTICS 2018: The Seventh International Conference on Data Analytics. Athens, greece: XPS. pp. 91–96. ISBN 978-1-61208-681-1 . Retrieved 2018-11-27.

[alwan-waters-23] 1 2 Alwan, Karla; Waters, K. (1992). Finding Re-entrant Knight's Tours on N-by-M Boards. ACM Southeast Regional Conference. New York, New York: ACM. pp. 377–382. doi:10.1145/503720.503806.

[24] Dally, Simon, ed. (1984). Century/Acorn User Book of Computer Puzzles. Century Communications. ISBN 978-0712605410.

[25] Y. Takefuji, K. C. Lee. "Neural network computing for knight's tour problems." Neurocomputing, 4(5):249–254, 1992.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]

[19]

[20]

[21]

[22]

[23]

[24]

[25]