Most-perfect magic square

੭	੧੨	੧	੧੪
੨	੧੩	੮	੧੧
੧੬	੩	੧०	੫
੯	੬	੧੫	੪

7	12	1	14
2	13	8	11
16	3	10	5
9	6	15	4

transcription of
the indian numerals

Most-perfect magic square from
the Parshvanath Jain temple in Khajuraho

A most-perfect magic square of doubly even order n = 4k is a pan-diagonal magic square containing the numbers 1 to n² with three additional properties:

Each 2×2 subsquare, including wrap-round, sums to s/k, where s = n(n² + 1)/2 is the magic sum.
All pairs of integers distant n/2 along any diagonal (major or broken) are complementary (i.e. they sum to n² + 1).

Examples

Specific examples of most-perfect magic squares that begin with the 2015 date demonstrate how theory and computer science are able to define this group of magic squares. ^[1]^[2] Only 16 of the 49 2x2 cell blocks that sum to 130 are accented by the different colored fonts in the 8x8 example.

The 12x12 square below was found by making all the 42 principal reversible squares with ReversibleSquares, running Transform1 2All on all 42, making 23040 of each, (of the 23040 x 23040 total each), then making the most-perfect squares from these with ReversibleMost-Perfect. These squares were then scanned for squares with 20,15 in the proper cells for any of the 8 rotations. The 2015 squares all originated with principal reversible square number #31. This square has values that sum to 35 on opposite sides of the vertical midline in the first two rows.^[2]

12 × 12 Most-Perfect Magic Square
20	15	60	49	24	51	132	123	92	89	128	87
119	136	79	102	115	100	7	28	47	62	11	64
25	10	65	44	29	46	137	118	97	84	133	82
126	129	86	95	122	93	14	21	54	55	18	57
31	4	71	38	35	40	143	112	103	78	139	76
113	142	73	108	109	106	1	34	41	68	5	70
13	22	53	56	17	58	125	130	85	96	121	94
138	117	98	83	134	81	26	9	66	43	30	45
8	27	48	61	12	63	120	135	80	101	116	99
131	124	91	90	127	88	19	16	59	50	23	52
2	33	42	67	6	69	114	141	74	107	110	105
144	111	104	77	140	75	32	3	72	37	36	39

12 x 12 reversible square #31 of 42
1	2	7	8	13	14	19	20	25	26	31	32
3	4	9	10	15	16	21	22	27	28	33	34
5	6	11	12	17	18	23	24	29	30	35	36
37	38	43	44	49	50	55	56	61	62	67	68
39	40	45	46	51	52	57	58	63	64	69	70
41	42	47	48	53	54	59	60	65	66	71	72
73	74	79	80	85	86	91	92	97	98	103	104
75	76	81	82	87	88	93	94	99	100	105	106
77	78	83	84	89	90	95	96	101	102	107	108
109	110	115	116	121	122	127	128	133	134	139	140
111	112	117	118	123	124	129	130	135	136	141	142
113	114	119	120	125	126	131	132	137	138	143	144

Physical Properties

The image below shows areas completely surrounded by larger numbers with a blue background. A water retention topographical model is one example of the physical properties of magic squares. ^[3]^[4]

Most-perfect magic square upgraded to a cube

There are 108 of these 2x2 subsquares that have the same sum for the 4x4x4 most-perfect cube.^[5]

Most-perfect magic square translated to the polyiamonds

Number shapes on a triangular grid divided into equal polyiamond areas containing equal sums give a polyiamond magic constant. ^[6]

Properties

All most-perfect magic squares are panmagic squares.

Apart from the trivial case of the first order square, most-perfect magic squares are all of order 4n. In their book, Kathleen Ollerenshaw and David S. Brée give a method of construction and enumeration of all most-perfect magic squares. They also show that there is a one-to-one correspondence between reversible squares and most-perfect magic squares.

All order four panmagic squares are most-perfect magic squares.

For n = 36, there are about 2.7 × 10⁴⁴ essentially different most-perfect magic squares.

The second property above implies that each pair of the integers with the same background colour in the 4×4 square below have the same sum, and hence any 2 such pairs sum to the magic constant.

7	12	1	14
2	13	8	11
16	3	10	5
9	6	15	4

Notes

↑ F1 Compiler http://www.f1compiler.com/samples/Most%20Perfect%20Magic%20Square%208x8.f1.html
1 2 Harry White, http://budshaw.ca/Most-perfect.html
↑ Knecht, Craig; Walter Trump; Daniel ben-Avraham; Robert M. Ziff (2012). "Retention capacity of random surfaces". Physical Review Letters. 108 (4): 045703. arXiv:1110.6166. Bibcode:2012PhRvL.108d5703K. doi:10.1103/PhysRevLett.108.045703.
↑ https://oeis.org/A201126 OEIS A201126
↑ https://oeis.org/A270205 OEIS A270205
↑ https://oeis.org/A303295 OEIS A303295

References

Kathleen Ollerenshaw, David S. Brée: Most-perfect Pandiagonal Magic Squares: Their Construction and Enumeration, Southend-on-Sea : Institute of Mathematics and its Applications, 1998, 186 pages, ISBN 0-905091-06-X
T.V.Padmakumar, Number Theory and Magic Squares, Sura books, India, 2008, 128 pages, ISBN 978-81-8449-321-4

External links

T. V. Padmakumar, Strongly magic squares
Harvey Heinz: Most-perfect Magic Squares
OEIS sequence A051235 (Number of essentially different most-perfect pandiagonal magic squares of order 4n)
OEIS sequence A270205 (Number of 2 X 2 planar subsets in an n X n X n cube)
OEIS sequence A275359 (Maximum incarceration of numbers in an n X n X n number cubes with full incarceration volumes) -- Incarcetration

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[F1-1] F1 Compiler http://www.f1compiler.com/samples/Most%20Perfect%20Magic%20Square%208x8.f1.html

[HarryWhite-2] 1 2 Harry White, http://budshaw.ca/Most-perfect.html

[Knecht11-3] Knecht, Craig; Walter Trump; Daniel ben-Avraham; Robert M. Ziff (2012). "Retention capacity of random surfaces". Physical Review Letters. 108 (4): 045703. arXiv:1110.6166. Bibcode:2012PhRvL.108d5703K. doi:10.1103/PhysRevLett.108.045703.

[OEISK-4] ttps://oeis.org/A201126 OEIS A201126

[OEIS-5] ttps://oeis.org/A270205 OEIS A270205

[MPOEIS-6] ttps://oeis.org/A303295 OEIS A303295