Pascal's triangle: Difference between revisions

The Pascal's triangle is a convenient tabular presentation for the binomial coefficients. Already known in the 11th century^[1], it was adopted in Western world under this name after Blaise Pascal published his Traité du triangle arithmétique ("Treatise on the Arithmetical Triangle") in 1654.

For instance, we can use Pascal's triangle to compute the binomial expansion of

${\displaystyle (x+y)^{4}=1\times a^{4}+4\times a^{3}b+6\times a^{2}b^{2}+4\times ab^{3}+1\times b^{4}~}$

The coefficients 1, 4, 6, 4, 1 appear directly in the triangle.

Each coefficient in the triangle is the sum of the two coefficients over it^[2]. For instance, ${\displaystyle 6=3+3}$. The binomial coefficients relate to this construction by Pascal's rule, which states that if

${\displaystyle {n \choose k}={\frac {n!}{k!(n-k)!}}}$

is the kth binomial coefficient in the binomial expansion of (x+y)ⁿ, then

${\displaystyle {n \choose k}={n-1 \choose k-1}+{n-1 \choose k}}$

for any nonnegative integer n and any integer k between 0 and n.^[3]

Those coefficients have applications in algebra and in probabilities. From the triangle, we can equally compute the Fibonacci numbers and create the Sierpinski triangle. After studying it, Isaac Newton expanded it and found new methods to extract the square root and to calculate the natural logarithm of a number.

Properties

In order to ease the understanding of some properties, the triangle should be presented differently :

Each coefficient is the sum of the coefficient exactly over it and the other to its left. For instance, ${\displaystyle 3+3=6}$.

Let's call this rule the "addition rule"^[2].

Using this format, it is easy to apply an index to each row :

${\displaystyle {\begin{array}{lcccccccc}0:&1&&&&&&&\\1:&1&1&&&&&&\\2:&1&2&1&&&&&\\3:&1&3&3&1&&&&\\4:&1&4&6&4&1&&&\\5:&1&5&10&10&5&1&&\\6:&1&6&15&20&15&6&1&\\7:&1&7&21&35&35&21&7&1\\...&...&...&...&...&...&...&...&...\\\end{array}}}$

Starting the indices at zero facilitates many calculations.

The sum of any row is ${\displaystyle 2^{r}~}$, with ${\displaystyle r~}$ being the row index : ${\displaystyle 0,1,2,\ldots ~}$ For instance, the sum of row 4 is ${\displaystyle 1+4+6+4+1=16=2^{4}~}$.

Since there is a formula for summing a row, then maybe there is one for a column ? It is the case. Again, we index the triangle, but this time it will be the columns :

${\displaystyle {\begin{array}{lcccccccc}&0&1&2&3&4&5&6&7\\0:&1&&&&&&&\\1:&1&1&&&&&&\\2:&1&2&1&&&&&\\3:&1&3&3&1&&&&\\4:&1&4&6&4&1&&&\\5:&1&5&10&10&5&1&&\\6:&1&6&15&20&15&6&1&\\7:&1&7&21&35&35&21&7&1\\...&...&...&...&...&...&...&...&...\\\end{array}}}$

Anyone familiar with the factorial function can easily find the general formula. The sum of a column ${\displaystyle c~}$ ending at row ${\displaystyle r~}$ is

${\displaystyle {\frac {(r+1)\times r\,\times \cdots \times (r-c+1)}{(c+1)!}}{\text{ with }}r,c\in \mathbb {N} ^{*}}$.

There is another method to compute this sum, see ^[4].

Up until now, we added along the rows and the columns. We can add along the diagonals. Adding from left to right gives :

${\displaystyle {\begin{array}{ccccccccccr}1&&&&&&&&&=&1\\1&&&&&&&&&=&1\\1&+&1&&&&&&&=&2\\1&+&2&&&&&&&=&3\\1&+&3&+&1&&&&&=&5\\1&+&4&+&3&&&&&=&8\\1&+&5&+&6&+&1&&&=&13\\1&+&6&+&10&+&4&+&1&=&21\\...&&&&&&&&&=&...\\\end{array}}}$

The numbers on the rigth are the Fibonacci numbers.

References