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A 26x26 Magic Square

Scroll down to see a magic square
in which all rows, columns, and both diagonals
add up to the same magic sum (8801)

A Magic Square is a square of numbers in which every row, every column, and both diagonals add up to the same number. This number is often called the magic sum. The 26 by 26 magic square shown below has a magic sum equal to 8801.

Though magic squares can be made with non-consecutive and non-regular sequences, they are usually seen made up of consecutive numbers, possibly because it is harder to be consecutive.

The method described below can be used to create all 4N+2 even-size squares that are at least 10x10 in size, where the size is equal to double any odd number. This is just one method for creating magic squares, there are many other methods, just as there are millions and millions and millions (many millions if not billions or trillions) of these squares to be found.

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How to Create a 26x26 Magic Square
with a Magic Sum of 8801

The method described on this page can be used to create 14x14, 18x18 and larger 4N+2 magic squares

Steps:

  1. Create an overlay 26x26 Magic Square grid consisting only of the numbers 0, 1, 2 and 3
  2. Create a 13x13 Magic Square (half the size of our final 26x26 square) that starts with the number 1
  3. Double the size of that 13x13 Magic Square, quadrupling every number, to create a 26x26 magic square that has each number in it four times.
  4. Subtract the numbers in the overlay grid from the quadrupled numbers in the doubled square to make your new square.
    Alternate directions: You may create a 13x13 Magic Square that starts with zero in step 2 if you add the two squares together in step 4.

Step One: Create a 26x26 Magic Square overlay grid

Since we are going to create a magic square that contains each number four times, we need to also create a magic square consisting only of the numbers 0, 1, 2 and 3, and we need to make sure that each 2x2 part of this overlay grid contains all four numbers.

When I created my 6x6 Magic Square page, I knew that one method of creating these squares was to simply double the size of the 3x3 magic square, quadrupling its values, then use brute-force to find an overlay pattern that satisfied my requirements (every number from 0 to 3 overlaying each identical number in the quadrupled square, in such a way that every row, column and diagonal added up to 9). Imagine my surprise when I found over a million different overlay squares. You can see information about how I brute-forced that solution at www.mazes.com/magic-squares/magic-06.html.

Obviously, I do not want to brute-force a 10x10 or larger 4N+2 magic square (there must be billions and billions of answers), so I decided to seek out a method of creating an overlay grid that will work with all 4N+2 squares larger than 6x6. I decided to use binary numbers as part of my search for a universal method. Binary (or base two) numbers, as many math students know, use the digits 0 and 1 to represent any number. The binary equivalents for the decimal (or base 10) numbers 0, 1, 2 and 3 are 00, 01, 10, and 11. Since half of each binary number represents whether or not the 1 is present, and half of each number represents whether or not the two is present, I decided to create two temporary overlay grids, one for the value 1, and one for the value 2, so that each square was independently magic.

Also, I wanted to make it easy for you, my visitor, to use the same method with pencil and paper, so I wanted to use basically the same grid twice, just doubling the "one" grid to get the "two" grid, with a simple rotation to make sure that the sum of the values will be different.

Create a 26x26 Magic Square of all 1's and 0's

Here are the steps to create the first grid (based on the pattern '11100000000000001111111111'):
  • Draw a 26x26 grid on your paper.
  • Put the number 1 into the first column of the first 3 rows of your grid
  • Put the number 0 into the first column of the next 13 rows of your grid
  • Put the number 1 into the remaining spaces of the first column.
  • Double-check your work. You should now have 13 1's and 13 0's in the first column, which I have bolded so you can see it clearly. As a further double-check, you have used the digits in the pattern '11100000000000001111111111')
  • For the second column, put the opposite number ... if there is a 1 in the first column, put 0 in the second column, and vice-versa.
  • Double-check. The first column and the second column number should add up to 1.
  • Copy the first column to the third column, and copy the second column to the fourth column.
  • Turn the first two columns upside-down and copy them into the fifth and sixth columns.
  • Copy the fifth and sixth columns to the rest of the square.
  • Double-check. Each row, each column and both diagonals should have exactly 13 1's in it.

Create a 26x26 Magic Square of all 2's and 0's

Here are the steps to create the second grid:

  • Rotate the first grid 90 degrees counter-clockwise and
  • double all the numbers.
  • You can see how the bolded left column has become the bolded bottom row after rotation.

Add Magic Square 1 to Magic Square 2

And, of course, here are the steps to create the third grid, which is your overlay grid:

  • Add the two squares together
  • You should end up with every 2x2 block containing all four digits, 0, 1, 2 and 3.
  • (I have bolded alternating 2x2 blocks so that you can see this more easily.)
  • and, if you have done the work properly, each row, each column, and both diagonals add up to the same magic sum.
  • Lay this grid aside for a few minutes. You won't need it until after you've finished your quadrupled grid

Step Two: Create a 13x13 Magic Square

Next, you need to create a magic square that is half the size as your desired square. Since this half-sized square is odd (13x13), it is easy to create. Just follow the method you see described at the bottom of every odd square page at www.mazes.com/magic-squares. Here is one such square, in which I started with the number 1 in the middle of the top row, then moved one square up one and two squares to the right after each move, except when the next move would be blocked, in which case I dropped down one for the next number.

I deliberately used a different magic square than the one you learned in school, just because I enjoy being different.

Now that you have an odd square, we are ready for the next step

Step Three:  Double the size of the 13x13 magic square
and quadruple all the numbers

Draw a 26x26 grid, then, for each number in the 13x13 magic square:
  • Multiply the number times four (quadruple it), and
  • Write that number four times, into a 2x2 area of the new grid that corresponds to the position of the original number in the 13x13 square. (I have bolded alternating 2x2 blocks so you can see how the 13x13 square has expanded into a 26x26 square.)

Step Four: Put the Quadrupled and the Overlay grids together

This last part should be simple.
  • If the smallest number in the quadrupled grid is 4, use subtraction: Quadrupled minus Overlay = Magic Square
    The lowest number in the new Magic Square will be one, just like in the original 13x13 magic square.
     
  • If the smallest number in the quadrupled grid is 0, use addition: Quadrupled plus Overlay = Magic Square
    The lowest number in the new Magic Square will be zero, just like in the original.
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A 26-by-26 Magic Square

(Magic Sum = 8801)

553552245244613612305304673672367366763753746766435434127126495492185184
555554247246615614307306675674365364543733726564433432125124493494187186
60960830130066966836136053523713706362431430123122491490183182551548241240
61061130230367167036336255543693686160429428121120489488181180549550243242
66466535635749484174165756427426119118487486179178547546239238607604297296
66666735835951504194185958425424117116485484177176545544237236605606299298
4445412413105104421420113112483482175174543542235234603602295294663660353352
4647414415107106423422115114481480173172541540233232601600293292661662355354
1001014684691091084774761691685395382312305995982912906596583513504340409408
1021034704711111104794781711705375362292285975962892886576563493484142411410
15615747247316416553253322422559459528628765465534634738394064079897464465
15815947447516616753453522622759259328428565265334434536374044059699466467
16016152852922022158858928028165065134234334354024039495462463154153520521
16216353053122222359059128228364864934034132334004019293460461152155522523
21621758458527627764464533633730313983999091458459150151518519210209524525
21821958658727827964664733833928293963978889456457148149516517208211526527
27327264164033233324253923938687454455146147514515206207574575214213580581
27527464364233433526273943958485452453144145512513204205572573212215582583
32932821203883898081448449142143510511202203570571262263578579270269636637
33133023223903918283450451140141508509200201568569260261576577268271638639
38538477764444451361375045051981995665672582596266272662676346353263251617
38738679784464471381395065071961975645652562576246252642656326333243271819
44144013313450250319419556256325425562262331431562862932032112133803817273
44344213513250150019319256156025325262162031331263163032332215143833827574
497496189190559558251250619618311310679678319318983773766968437436129128
49949819118855755624924861761630930867767631731611103793787170439438131130
This Magic Square was created by John Knoderer, a webmaster and computer programmer who is available to telecommute to your location. (In other words, John would be delighted to create puzzles for your website or do other amazing work for you on a contract basis.)

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