E: Difference between revisions

e is a [TODO]

Probabilistic interpretation

Bernoulli trials

Suppose that something has a 1 in ${\displaystyle n}$ chance of occurring. After ${\displaystyle n}$ times, what is the probability that the event has not happened once? Each time, the probability that the event doesn't happen is ${\displaystyle (1-1/n)}$, so the probability that the event doesn't happen ${\displaystyle n}$ times in a row is ${\displaystyle (1-1/n)^{n}}$.

It turns out that this sequence is Cauchy [TODO], and ${\displaystyle e}$ is the inverse of its limit

$${\displaystyle {\frac {1}{e}}:=\lim _{n\rightarrow \infty }\left(1-{\frac {1}{n}}\right)^{n}.}$$

Similarly, if something has a 1 in ${\displaystyle n}$ chance of occurring, then after ${\displaystyle nt}$ times, what is the probability that the event has not happened once? For large ${\displaystyle n}$ it approaches some fixed value

$${\displaystyle e^{-t}=\lim _{n\rightarrow \infty }\left(1-{\frac {1}{n}}\right)^{nt}.}$$

The[TODO terminology] numerical value of e is useful to know, because if you're ever in a situation where you have to calculate one of these probabilities, it could be a major pain to multiply ${\displaystyle (1-1/n)}$ with itself ${\displaystyle nt}$ times, if you had no access to a calculator. Instead, you could save yourself some work by looking up this number[TODO it's not a single number; it's a sequence of numbers] ${\displaystyle e}$ in a table that someone has already computed. [TODO I don't find this explanation very convincing.]

Central limit theorem [TODO]

Suppose you do ${\displaystyle N}$ experiments, where in each experiment you flip a coin 100 times and record the results. For ${\displaystyle 0\leq k\leq 100}$, what fraction of the experiments resulted in heads landing precisely ${\displaystyle k}$ times?

For ${\displaystyle N}$ large, the answer is proportional to

$${\displaystyle e^{-(k-50)^{2}/\sigma }}$$

${\displaystyle \sigma }$

Compounding interest interpretation [TODO yuck]

If you have your money in a bank account, where you make a rate of interest ${\displaystyle r}$, which compounds ${\displaystyle c}$ times yearly, then after a year your bank account will contain

$${\displaystyle (1+r)^{c}}$$

${\displaystyle c}$

${\displaystyle r}$

${\displaystyle r=1/c}$

${\displaystyle (1+1/c)^{c}}$

${\displaystyle c}$

$${\displaystyle e:=\lim _{c\rightarrow \infty }\left(1+{\frac {1}{c}}\right)^{c}}$$

This example, though it's how e is introduced, is rather disconnected from reality. No bank actually offers this as an option. And even if they did, why would they fix the rate to be ${\displaystyle r=1/c}$? Why not some other rate? [TODO the answer, I think, is that if ${\displaystyle r(c)}$ grows faster than ${\displaystyle 1/c}$ then the limit will diverge, and if it grows slower than ${\displaystyle 1/c}$ then the limit will be 1.]

Geometric interpretation

${\displaystyle \cosh(a)}$ and ${\displaystyle \sinh(a)}$ are the ${\displaystyle x}$ and ${\displaystyle y}$ coordinates on a unit hyperbola, at the place where the ray subtending an area of ${\displaystyle a/2}$ intersects the hyperbola. (This description is not very clear; see the figure.) In this situation, ${\displaystyle e^{a}}$ is the simply sum of ${\displaystyle x}$ and ${\displaystyle y}$ coordinates.