e (Euler's Number)
The number e is a famous irrational number, and is one of the most important numbers in mathematics.
The first few digits are:
2.7182818284590452353602874713527 (and more ...)
It is often called Euler's number after Leonhard Euler (pronounced "Oiler").
e is the base of the Natural Logarithms (invented by John Napier).
e is found in many interesting areas, so it is worth learning about.
There are many ways of calculating the value of e, but none of them ever give a totally exact answer, because e is irrational (not the ratio of two integers).
But it is known to over 1 trillion digits of accuracy!
For example, the value of (1 + 1/n)n approaches e as n gets bigger and bigger:
|n||(1 + 1/n)n|
Try it! Put "(1 + 1/100000)^100000" into the calculator:
(1 + 1/100000)100000
What do you get?
The value of e is also equal to 10! + 11! + 12! + 13! + 14! + 15! + 16! + 17! + ... (etc)
(Note: "!" means factorial)
The first few terms add up to: 1 + 1 + 12 + 16 + 124 + 1120 = 2.718055556
In fact Euler himself used this method to calculate e to 18 decimal places.
You can try it yourself at the Sigma Calculator.
To remember the value of e (to 10 places) just remember this saying (count the letters!):
Or you can remember the curious pattern that after the "2.7" the number "1828" appears TWICE:
2.7 1828 1828
And following THAT are the digits of the angles 45°, 90°, 45° in a Right-Angled Isosceles Triangle (no real reason, just how it is):
2.7 1828 1828 45 90 45
(An instant way to seem really smart!)
e is used in the "Natural" Exponential Function:
Graph of f(x) = ex
It has this wonderful property: "its slope is its value"
At any point the slope of ex equals the value of ex :
when x=0, the value ex = 1, and the slope = 1
when x=1, the value ex = e, and the slope = e
This is true anywhere for ex, and makes some things in Calculus (where we need to find slopes) a whole lot easier.
The area up to any x-value is also equal to ex :
An Interesting Property
Just for fun, try "Cut Up Then Multiply"
Let us say that we cut a number into equal parts and then multiply those parts together.
Example: Cut 10 into 2 pieces and multiply them:
Each "piece" is 10/2 = 5 in size
5×5 = 25
Now, ... how could we get the answer to be as big as possible, what size should each piece be?
The answer: make the parts as close as possible to "e" in size.
The winner is the number closest to "e", in this case 2.5.
Try it with another number yourself, say 100, ... what do you get?
100 Decimal Digits
Here is e to 100 decimal digits:
Advanced: Use of e in Compound Interest
Often the number e appears in unexpected places. Such as in finance.
Imagine a wonderful bank that pays 100% interest.
In one year you could turn $1000 into $2000.
Now imagine the bank pays twice a year, that is 50% and 50%
Half-way through the year you have $1500,
you reinvest for the rest of the year and your $1500 grows to $2250
You got more money, because you reinvested half way through.
That is called compound interest.
Could we get even more if we broke the year up into months?
We can use this formula:
r = annual interest rate (as a decimal, so 1 not 100%)
n = number of periods within the year
Our half yearly example is:
(1+1/2)2 = 2.25
Lets try it monthly:
(1+1/12)12 = 2.613...
Lets try it 10,000 times a year:
(1+1/10,000)10,000 = 2.718...
Yes, it is heading towards e (and is how Jacob Bernoulli first discovered it).
Why does that happen?
The answer lies in the similarity between:
|Compounding Formula:||(1 + r/n)n|
|e (as n approaches infinity):||(1 + 1/n)n|
The Compounding Formula is very like the formula for e (as n approaches infinity), just with an extra r (the interest rate).
When we chose an interest rate of 100% (= 1 as a decimal), the formulas became the same.
Read Continuous Compounding for more.
e is also a transcendental number.