I'd just like to check my logic here...

I wrote code to solve the Knight's Tour and it works well for 8x8 boards starting the Knight at any square.

But... on a 5x5 board I show no solution possible when starting at square (0, 1).

What I tried for 5x5 starting the Knight at Row 0, Col 1:

  1. Warnsdorff's path
  2. Added Roth (tie breakers based on Euclidean distance from center).

Since those did not produce a solution I did code that is just basic recursion with backtracking to test every possible path -- also no solution found when starting a 5x5 on 1, 0.

I looked everywhere for a list of exhaustive solutions to the 5x5 board but found none.

Is it that there just is no solution for 5x5 when starting at square 0, 1?

Thank you!

                             1   2   3   4     5

                          1 304  0   56   0    304

                          2  0   56   0   56    0

                          3  56  0   64   0    56

                          4  0   56    0  56   0

                          5 304   0   56   0   304

This might help.If knights starts at (1,1) there will be 304 possible knights tour and if it starts at (1,2) then there will be NO knights tour.Similarly if knight starts at (3,3) then there are 64 possible knights tour.

  • 2
    How does "this" help? Do you have any source for that matrix?
    – Nico Haase
    Jun 19 '18 at 11:17
  • 2
    I just said that it might give clearance for the (question) that whichever method he uses he cannot find solution if knight starts at particular square and i dont know how to get that matrix but i got this from one of the link on wikipedia.oeis.org/A165134 Jun 20 '18 at 5:30

Correct, there is no solution when you start at any of the squares adjacent to a corner square.


By a simple coloring argument, you must start on a square the same color as a corner.

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