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Tiling Square Rooms with Equal Stacks of Tiles or Solution Patterns of x 2 – ny = 1 by Donald E. Hooley . Some Problems. A box contains beetles and spiders. There are 46 legs in the box. How many belong to beetles?
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Tiling Square Rooms with Equal Stacks of Tilesor Solution Patterns of x2 – ny = 1by Donald E. Hooley
Some Problems • A box contains beetles and spiders. There are 46 legs in the box. How many belong to beetles? • 14 October 1066. The men of Harold stood well together and formed sixty and one squares. When Harold joined the Saxons were one mighty square of men. How many in Harold’s army?
Diophantine Equations 6x + 8y = 1 x2 = 61y2 + 1 or x2 - 61y2 = 1
Another Problem A mildly eccentric floor tile layer tiles only square rooms with square tiles which come in stacks of equal numbers of tiles. Unfortunately the number of tiles in each stack is unknown and the tile layer always leaves himself standing on one untiled square near the center of the room.
Simpler Quadratic Diophantine Equation x2 = ny + 1 or x2 - ny = 1 Use Excel to explore positive integer solutions.
x2 – 6y = 1 Solutions Diff x y Diff 5 4 2 7 8 4 4 11 20 12 2 13 28 8 4 17 48 20 2 19 60 12 4 23 88 28
x2 – 6y = 1 Taken modulo 6 we have x2 = 1 modulo 6 But the quadratic residues mod 6 are 1, 4, 3, 4, 1 so if x = 1 mod 6 or x = 5 mod 6 then x2 = 1 mod 6
x2 – 6y = 1 Thus x = 6t + 1 or x = 6t - 1 Since x2 – 6y = 1 gives y = (x2 - 1)/6
x2 – 6y = 1 If x = 6t + 1 then y = (x2 - 1)/6 = ((6t+1)2 - 1)/6 = (36t2+12t+1-1)/6 = 6t2 + 2t
x2 – 6y = 1 And if x = 6t - 1 then y = (x2 - 1)/6 = ((6t-1)2 - 1)/6 = (36t2-12t+1-1)/6 = 6t2 - 2t
x2 – 6y = 1 So we have solutions x = 6t –1, y = 6t2 – 2t and x = 6t +1, y = 6t2 + 2t for any positive integer t.
x2 – 8y = 1 Solutions Diff x y Diff 3 1 2 5 3 2 2 7 6 3 2 9 10 4 2 11 15 5 2 13 21 6 2 15 28 7
x2 – 8y = 1 Taken modulo 8 this gives x2 = 1 mod 8 But the quadratic residues mod 8 are 1, 4, 1, 0, 1, 4, 1 so if x = 1, 3, 5 or 7 mod 8 then x2 = 1 mod 8
x2 – 8y = 1 But x = 1, 3, 5 or 7 mod 8 is equivalent to x = 1 mod 2 or x = 2t + 1 t = 1, 2, 3, …
x2 – 8y = 1 Now solving for y if x = 2t + 1 then y = (x2 – 1)/8 = ((2t+1)2-1)/8 = (4t2+4t+1-1)/8 = (t2+t)/2 = T(t), t = 1, 2, 3, … the triangular numbers
x2 – ny = 1 In general (nt+1)2 = n2t2 + 2nt + 1 = 1 mod n and (nt-1)2 = n2t2 - 2nt + 1 = 1 mod n
x2 – ny = 1 So if x = nt + 1 solving for y gives y = (x2 – 1)/n = ((nt+1)2-1)/n = (n2t2+2nt+1-1)/n = nt2 + 2t
x2 – ny = 1 And if x = nt - 1 solving for y gives y = (x2 – 1)/n = ((nt-1)2-1)/n = (n2t2-2nt+1-1)/n = nt2 - 2t
x2 – ny = 1 So there exist an infinite number of solutions of the form x = nt –1, y = nt2 – 2t and x = nt +1, y = nt2 + 2t for t = 1, 2, 3, ... and there may also exist other solutions depending on quadratic residues mod n.
References Alpern, Dario. (2001) Quadratic Diophantine Equation Solver at www.alpertron.com.ar/quad.htm Beiler, Albert. (1964) Recreations in the Theory of Numbers – The Queen of Mathematics Entertains. Dover Publications, Inc., New York. Dudley, Underwood. (1969) Elementary Number Theory. W. H. Freeman Co., San Francisco.
