Alphamagic square

An alphamagic square is a magic square that remains magic when its numbers are replaced by the number of letters occurring in the name of each number. Hence 3 would be replaced by 5, the number of letters in "three". Since different languages will have a different number of letters for the spelling of the same number, alphamagic squares are language dependent.[1] Alphamagic squares were invented by Lee Sallows in 1986.[2]

Example

The example below is alphamagic. To find out if a magic square is also an alphamagic square, convert it into the array of corresponding number words. For example

5 22 18
28 15 2
12 8 25

converts to ...

five twenty-two eighteen
twenty-eight fifteen two
twelve eight twenty-five

Counting the letters in each number word generates the following square which turns out to also be magic:

4 9 8
11 7 3
6 5 10

If the generated array is also a magic square, the original square is alphamagic. In 2017 British computer scientist Chris Patuzzo discovered several doubly alphamagic squares in which the generated square is in turn an alphamagic square.[3]

The above example enjoys another special property: the nine numbers in the lower square are consecutive. This prompted Martin Gardner to describe it as "Surely the most fantastic magic square ever discovered."[4]

A geometric alphamagic square

Figure 1:   A geomagic square that is also alphamagic

Sallows has produced a still more magical versiona square which is both geomagic and alphamagic. In the square shown in Figure 1, any three shapes in a straight lineincluding the diagonalstile the cross; thus the square is geomagic. The number of letters in the number names printed on any three shapes in a straight line sum to forty five; thus the square is alphamagic.

Other languages

The Universal Book of Mathematics provides the following information about Alphamagic Squares:[5][6]

A surprisingly large number of 3 × 3 alphamagic squares exist—in English and in other languages. French allows just one 3 × 3 alphamagic square involving numbers up to 200, but a further 255 squares if the size of the entries is increased to 300. For entries less than 100, none occurs in Danish or in Latin, but there are 6 in Dutch, 13 in Finnish, and an incredible 221 in German. Yet to be determined is whether a 3 × 3 square exists from which a magic square can be derived that, in turn, yields a third magic square—a magic triplet. Also unknown is the number of 4 × 4 and 5 × 5 language-dependent alphamagic squares.

References

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