puzzles

Mrs. Sandy McAllister will have to save a tremendous sum out of her housekeeping allowance if she is to win that sixth present that her canny husband promised her. And the allowance must be a very liberal one if it is to admit of such savings. The problem required that we should find five numbers higher than 36 the units of which may be displayed so as to form a square, a triangle, two triangles, and three triangles, using the complete number in every one of the four cases.

Every triangular number is such that if we multiply it by 8 and add 1 the result is an odd square number. For example, multiply 1, 3, 6, 10, 15 respectively by 8 and add 1, and we get 9, 25, 49, 81, 121, which are the squares of the odd numbers 3, 5, 7, 9, 11. Therefore in every case where 8x² + 1 = a square number, x² is also a triangular. This point is dealt with in our puzzle, "The Battle of Hastings." I will now merely show again how, when the first solution is found, the others may be discovered without any difficulty. First of all, here are the figures:—

8	×	1²	+ 1 =	3²
8	×	6²	+ 1 =	17²
8	×	35²	+ 1 =	99²
8	×	204²	+ 1 =	577²
8	×	1189²	+ 1 =	3363²
8	×	6930²	+ 1 =	19601²
8	×	40391²	+ 1 =	114243²

(1 × 3) + (3 × 1)	=	6	(8 × 1) + (3 × 3)	=	17
(1 × 17) + (3 × 6)	=	35	(8 × 6) + (3 × 17)	=	99
(1 × 99) + (3 × 35)	=	204	(8 × 35) + (3 × 99)	=	577

and so on. Look for the numbers in the table above, and the method will explain itself.

Thus we find that the numbers 36, 1225, 41616, 1413721, 48024900, and 1631432881 will form squares with sides of 6, 35, 204, 1189, 6930, and 40391; and they will also form single triangles with sides of 8, 49, 288, 1681, 9800, and 57121. These numbers may be obtained from the last column in the first table above in this way: simply divide the numbers by 2 and reject the remainder. Thus the integral halves of 17, 99, and 577 are 8, 49, and 288.

All the numbers we have found will form either two or three triangles at will. The following little diagram will show you graphically at a glance that every square number must necessarily be the sum of two triangulars, and that the side of one triangle will be the same as the side of the corresponding square, while the other will be just 1 less.

Thus a square may always be divided easily into two triangles, and the sum of two consecutive triangulars will always make a square. In numbers it is equally clear, for if we examine the first triangulars—1, 3, 6, 10, 15, 21, 28—we find that by adding all the consecutive pairs in turn we get the series of square numbers—9, 16, 25, 36, 49, etc.

The method of forming three triangles from our numbers is equally direct, and not at all a matter of trial. But I must content myself with giving actual figures, and just stating that every triangular higher than 6 will form three triangulars. I give the sides of the triangles, and readers will know from my remarks when stating the puzzle how to find from these sides the number of counters or coins in each, and so check the results if they so wish.

Number	Side of Square.	Side of Triangle.	Sides of Two Triangles.	Sides of Three Triangles.
36	6	8	6 + 5	5 + 5 + 3
1225	35	49	36 + 34	33 + 32 + 16
41616	204	288	204 + 203	192 + 192 + 95
1413721	1189	1681	1189 + 1188	1121 + 1120 + 560
48024900	6930	9800	6930 + 6929	6533 + 6533 + 3267
1631432881	40391	57121	40391 + 40390	38081 + 38080 + 19040

I should perhaps explain that the arrangements given in the last two columns are not the only ways of forming two and three triangles. There are others, but one set of figures will fully serve our purpose. We thus see that before Mrs. McAllister can claim her sixth £5 present she must save the respectable sum of £1,631,432,881.