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The Twelve Days of Christmas: Music meets math in a
popular Christmas song
Lake Forest, Illinois (December 17, 2002) - Every year
during the holiday season, economic pundits tally up
the rising costs of a "true love's" generosity
in that ode to very conspicuous consumption: "The
Twelve Days of Christmas."
But as the lords leap, the maids milk, and the recipient
tries to figure out what to do with the outlandish haul,
mathematicians find greater delight in a more timeless
question: How many items - French hens, golden rings,
and the like-accumulate by the end of the 12th day in
the song? The answer, it turns out, paints holiday patterns
in math that resemble triangles, Christmas trees, stockings
and even the Star of David.
The gifts add up
The popular Christmas carol starts innocuously enough.
On day one, the character in the song gets a single
present (a partridge in a pear tree). But on day two,
the beneficiary receives a new present (a pair of turtle
doves) plus another partridge in a pear tree.
Day three brings a second helping of day two's gifts,
plus more new items (three French hens). By the twelfth
day, the narrator is an undeniable pack rat - and maybe
in violation of local zoning - after receiving 12 drummers
drumming, and new copies of all the previous day's gifts.
By the twelfth verse of the song, there are a lot of
gifts. How do you count it all up? Pure arithmetic provides
the easiest, though longest, way to do it:
| Day of song |
|
Number of gifts |
| One |
|
1 + |
| Two |
|
(1 + 2) + |
| Three |
|
(1 + 2 + 3) + |
| Four |
|
(1 + 2 + 3 + 4) + |
| Five |
|
(1 + 2 + 3 + 4 + 5) + |
| Six |
|
(1 + 2 + 3 + 4 + 5 + 6) + |
| Seven |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7) + |
| Eight |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7 + 8) + |
| Nine |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9) + |
| Ten |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10)
+ |
| Eleven |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10
+ 11) + |
| Twelve |
|
(1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10
+ 11 + 12)= |
| Total |
|
364 |
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The total, 364 gifts, means that our true love gets
a present for almost every day of the year!
Greeks bearing gifts - triangular
numbers
Here's where some neat mathematical patterns come in,
according to Bill Butterworth, professor of mathematics
at Barat College of DePaul University in Illinois. The
individual sums on each row-(1+2), (1+2+3) and so on-are
what the ancient Greeks called "triangular numbers"
because they make a triangle if you replace the numbers
with X's.
The triangular numbers form a sequence: 1, 3, 6, 10,
and so on.
Instead of doing drawn-out arithmetic, you can simply
use the triangular numbers to find out the number of
gifts bestowed on any day of the song. For example,
the 12th triangular number, 78, corresponds to the number
of gifts granted in day 12. How many gifts were furnished
on day 10? You just look up the 10th triangular number:
55.
Adding up the first 12 triangular numbers gives you
the total number of gifts mentioned in the song: 364.
Pascal's Triangle
The daily and 12-day totals for the gifts show up in
another, more remarkable math pattern, discovered over
a millennium ago and shaped coincidentally like a Christmas
tree. It's called Pascal's Triangle, named after the
Renaissance French mathematician Blaise Pascal, who
developed it after its discovery by Arab, Chinese, and
Persian mathematicians.
Today, Pascal's Triangle has a wide range of uses in
probability theory, fractals, calculus, and many other
areas of math. "I've found Pascal's Triangle to
be one of the richest and most accessible mathematical
'objects' over the years," says Butterworth. Indeed,
Pascal's triangle contains an astounding bag of mathematical
tricks that includes more than one holiday connection.
The first fourteen rows of Pascal's Triangle look like
this:
To identify any number on the triangle, mathematicians
specify its horizontal "row" and its diagonal
"column," with both column and row numbers
starting at 0. For example, the third row is 1, 2, 1,
and the first column (in either direction) is 1, 2,
3, 4, and so on.
How are the numbers chosen? In the triangle, every
number, such as 10 (in row 6, column 3), is the sum
of the two numbers in the previous row diagonally above
it - 4 and 6:
This simple rule yields many powerful numerical patterns-including
one that we've seen before.
"The triangular numbers - 1, 3, 6, 10, and so
on - appear in the second column of Pascal's triangle,"
Butterworth points out. That's the first ingredient
for "The Twelve Days of Christmas" connection.
Twelve days in the triangle
The second ingredient is a math result known - coincidentally
once again - as the Christmas Stocking Theorem.
The Christmas Stocking Theorem says this: Go to the
top of any column, and select a diagonal string of as
many numbers as you'd like down that column. To find
the sum of those numbers, you don't have to add them
up. You can find the sum nearby in the triangle. Just
put your finger on the last number in the string; move
your finger to the next number in the column; then slide
your finger over to the next column. That number provides
the sum of the string.
To apply this to the "Twelve Days," let's
choose column 2, the one with the triangular numbers.
Then, choose the first 12 numbers.
According to the Christmas stocking theorem, you can
find the sum of those numbers by putting your finger
on the last number of the twelve-78-then going to the
next number in the column - 91 - and then sliding over
to the next column. What number do you find there? 364!
This same pattern works for any column of the triangle.
As you may have noticed, there is actually a connection
to Christmas stockings: When highlighted, the string
of numbers down the column resembles the shank of a
Christmas stocking hanging from the tree, while the
sum appears in the toe! Because of this shape, the Christmas
Stocking Theorem is also known as the "Hockey Stick
Theorem," another popular winter pastime.
Star of David
There's also an intriguing "Star of David"
theorem in Pascal's Triangle, Butterworth points out.
First, here's how to make a Star of David pattern in
the triangle:
- Select any number in the interior of the triangle:
let's pick 84 (in row 10, column 4).
- Identify the six numbers surrounding that number:
120, 36, 28, 56, 126, 210.
- Split the six numbers into two groups of three:
120, 126, 28; and 56, 36, and 210.
- Connect the three numbers in each group, so that
each group forms one of the small triangles in the
Star of David:
Here's what the Star of David theorem says: No matter
which center entry is selected, the product of the numbers
in one of the small triangles is equal to the product
of the other: 28 x 120 x 126 = 36 x 56 x 210 = 423,360
"This product has no connection that we know of
with the center number," says Butterworth.
So a simple song like "The Twelve Days of Christmas"
can open the doors into the rich patterns of mathematics
during the holiday season.
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Links
The
Twelve Days of Christmas and Pascal's Triangle
Pascal's
Triangle (includes printable versions)
Pascal's Triangle
and Its Patterns
Pascal's
Triangle (includes history)
Expert
Bill Butterworth
Associate Professor and Director of the Mathematics
Program
Barat College of DePaul University
847.574.6351
Contacts
Ben Stein
American Institute of Physics
301-209-3091
Craig Smith
American Institute of Physics
301-209-3088
Mike Breen
American Mathematical Society
401-455-4109
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