SciTech-Math-Complex Analysis复分析: Complex复数 + De Moivre's Formula:帝魔服公式 + Euler's Formula:欧拉公式

https://www.desmos.com/calculator/v1nugr08y5
https://mathvault.ca/euler-formula/
https://www.britannica.com/science/Eulers-formula
复数域的:

一切代数恒等式 仍像实数域的成立;
不等式 是不能定义像实数域比较大小的不等式.
事实上, 如果复数域可以比较大小,那么必然推导出$-1 > 0$:
$\begin{array}{ccl} hypothesis\ i > 0 &\ \Rightarrow\ & (i)^2 > 0 &\Rightarrow \ (+i)^2=-1 > 0 &\ \Rightarrow \ contradiction \\ hypothesis\ i < 0 &\ \Rightarrow\ & -i > 0 &\Rightarrow \ (-i)^2=-1 > 0 &\ \Rightarrow \ contradiction \\ \end{array}$
so$\ ONLY$ real number field $R$ has it's $inequalities$.

De Moivre's Formula

$Abraham\ de\ Moivre,\ French\ mathematician$

$\large (r_{1}\ cis\ \theta_{1})^n =r^{n}\ cis\ n*\theta$
OR $\large [\ r(\cos{\theta}+i*{\sin{\theta}})\ ]^{n} = r^{n}[\ \cos{(n*\theta)} + i*\sin{(n*\theta)}\ ]$
It lets us multiply a complex number by itself (as many times as we want) in one go!
Let's learn about it, and also discover a much neater way to write it.
Thanks to Abraham de Moivre so we have this useful formula.

Euler's Formula

https://mathvault.ca/euler-formula/, $Leonhard\ Euler,\ Swiss\ mathematician$

We can also create de Moivre's Formula with some help from Leonhard Euler!

Euler's Formula for complex numbers says:
$\large f(\theta) = e^{i\theta} = 1\ cis\ \theta = \cos{\theta} + i \cdot \sin{\theta}$
$\large f'(\theta)=\frac{d(e^{i\theta})}{d(\theta)} = i * e^{i\theta}$
$\large f'(\theta)= i * f(\theta)$, compares $\large f'(\theta)$ to $\large f(\theta)$ at arbitrary polar form point $\large (1,\theta)$:
- only the $\large angle$ in radians rotated $\large \frac{\pi}{2}$ counterclockwise from $\large \theta$, and become $\large (\theta + \frac{\pi}{2})$
- and the $\large magnitude$ remains.
$\large \begin{array}{ccl} & \because & f(\theta) &=& e^{i\theta} &=& \cos{\theta} + i \cdot \sin{\theta} \\ & & f'(\theta) &=& i * f(\theta) &=& i*e^{i\theta}\end{array}$

$\large \begin{array}{ccl} & \therefore & & & & & & & & & \\ & & f(\theta) &=& e^{i*\theta} & & & & & && \\ & & f(1) &=& e^{i*1} &=& e^i \ ,&\ f'(1) &=& i * e^{i} &=& i * e^{i} \\ & & f(0) &=& e^{i*0} &=& 1 \ ,&\ f'(0) &=& i * 1 &=& i \\ & & f(\frac{\pi}{2}) &=& e^{i*\frac{\pi}{2}} &=& i \ ,&\ f'(\frac{\pi}{2}) &=& i * i &=& -1 \\ & & f(\pi) &=& e^{i*\pi} &=& -1 \ ,&\ \ f'({\pi}) &=& i * -1 &=& -i \\ & & f(\frac{3\pi}{2}) &=& e^{i*\frac{3\pi}{2}} &=& -i \ ,&\ f'(\frac{3\pi}{2}) &=& i * -i &=& 1 \end{array}$
Euler’s Identity
Euler’s identity is the most beautiful equation in mathematics. It is written as:
$\large e^{i\pi} + 1 = 0$

where it showcases five of the most important constants in mathematics. These are:
- The $0$: additive identity
- The $1$: unity
- The $\large \pi$: Pi constant (ratio of a circle’s circumference to its diameter)
- The $\large e$: base of natural logarithm
- The $\large i$: imaginary unit
Among these:
- three types of numbers are represented: $\{integers\}$, $\{irrational\ numbers\}$ and $\{imaginary\ numbers\}$.
- Three of the basic mathematical operations are also represented: $\large addition$, $\large multiplication$ and $\large exponentiation$.
We obtain Euler’s identity:
- by starting with Euler’s formula $\large e^{i\theta} = \cos{\theta} + i\cdot\sin{\theta}$
- and by setting $\large \theta = \pi$ and sending the subsequent $-1$ to the left-hand side.
- The intermediate form $\large e^{i \pi} = -1$ is common in the context of trigonometric unit circle in the complex plane:
  it corresponds to the point on the unit circle whose angle with respect to the positive real axis is $\pi$.

Complex Numbers:

The "$unit\ imaginary\ number$ when squared equals −1:
$ i^2 = -1\ \ \Rightarrow\ \ i = \pm \sqrt{-1}$
Special case:
- $\large i = \cos{\frac{\pi}{2}} + i*\sin{\frac{\pi}{2}} $
- $ x = r\ cis\ \theta = r(\cos{\theta}+i*{\sin{\theta}}),\ \forall\ z \in C,\ r \in R,\ \theta \in [0,2\pi)$
- $ x * i = r\ cis \ (\theta +\frac{\pi}{2}) = i * r(\cos{\theta}+i*{\sin{\theta}}) = r * [ \cos{(\theta + \frac{\pi}{2})} + i \sin{(\theta + \frac{\pi}{2})} ] $
  ONLY the $\large angle\ in\ radians$ become $(\theta + \frac{\pi}{2})$, and the $\large magnitude$ remains.
- $\large \forall\ x \in R, \ f(x) = e^{kx}, we\ have\ f'(x)=\frac{d(e^{kx})}{d(x)} = k * e^{kx}, since\ (e^x)' = e^{x}$
- $\large \forall\ \theta \in C, \ f(\theta) = e^{i\theta}, we\ have\ f'(\theta)=\frac{d(e^{i\theta})}{d(\theta)} = i*e^{i\theta}$
What is a Complex number?
a Complex Number is a combination of a Real Number and Imaginary Number;
- $ x = a + b*i,\ Cartesian\ Form$, in Cartesian coordinates.
- $ x = r(\cos{\theta}+i*{\sin{\theta}}),\ Polar\ Form$, in Polar coordinates.
  In fact, a common way to write a complex number in $Polar form$ is
  $a + b*i = r(\cos\theta + i*\sin\theta)$
  And "$\cos{\theta} + i*\sin{\theta}$" is often shortened to "$cis\ θ$" OR "$\angle \theta$", so:
  $a + b*i = r\ cis\ \theta = r \angle \theta$
  where: $cis\ \theta$ OR $\angle \theta$ is just shorthand for $\cos\theta + i*\sin\theta$
- conversions:
  - From $Cartesian$ to $Polar$( use $3 + 4i$ as a example):
    $ r = \sqrt{a^{2} + b^{2}} = \sqrt{3^{2} + 4^{2}} = \sqrt{25} = 5$
    $ \theta = \arctan{(b/a)} = \arctan{(4/3)} = 0.9273 (to\ 4\ decimals)$
```
 import math as m
 a, b = 3, 4
 rho = m.sqrt(m.pow(a, 2) + m.pow(b, 2))
 theta = m.atan(b/a);
```
  - From $Polar$ to $Cartesian$:
    $ a = r * \cos\theta = 5.0 * \cos{(0.92729..)} = 3.0,\ (at\ perfect\ accuracy)$
    $ b = r * \sin\theta = 5.0 * \sin{(0.92729...)} = 4.0,\ (at\ perfect\ accuracy)$
```
 import math as m
 rho, theta = 5.0, 0.9272952180016122
 a = rho * m.cos(theta)
 b = rho * m.sin(theta)
```
- In other words the complex number $3 + 4i$ can also be shown as distance 5 and angle 0.927 radians.
  
  $Cartesian\ Form$ $Polar\ Form$
两个复数的乘积结果: 模相乘(模等于两者模相乘), 角相加(弧角等于两者弧角相加)
$极坐标$ 表示：
$\large \begin{array}{ccl} z_{1} &=& r_{1} \angle \theta_{1}\ , \\ z_{2} &=& r_{2} \angle \theta_{2} \\ z_{1}*z_{2} &=& r_{1}*r_{2} \angle (\theta_{1}+\theta_{2}) \\ OR \\ z_{1} &=& r_{1}(\cos{\theta_{1}}+i*{\sin{\theta_{1}}}) \\ z_{2} &=& r_2 (\cos{\theta_{2}}+i*\sin{\theta_{2}}) \\ z_{1}*z_{2} &=& r_{1} * r_2 [\cos{(\theta_{1}+\theta_{2})} + i*\sin{(\theta_{1}+\theta_{2})} ] \end{array}$

Complex Numbers in Exponential Form

Cartesian Form: At this point, we already know that a complex number $z$ can be expressed in Cartesian coordinates as $x + iy$, where $x$ and $y$ are respectively the $real\ part$ and the $imaginary\ part$ of $z$.
Polar Form: Indeed, the same complex number can also be expressed in Polar coordinates as $r(\cos \theta + i \sin \theta)$, where $r$ is the $magnitude$ of its distance to the origin, and $\theta$ is its $angle\ in\ radians$ with respect to the positive real axis.
Exponential Form: it does not end there: thanks to $Euler’s formula$, every complex number can now be expressed as a $complex\ exponential$ as follows:
$z = r(\cos \theta + i \sin \theta) = r e^{i \theta}$
where $r$ and $\theta$ are the same numbers as before.
To go from $(x, y)$ to $(r, \theta)$, we use the formulas $\begin{align*} r & = \sqrt{x^2 + y^2} \\[4px] \theta & = \operatorname{atan2}(y, x) \end{align*}$,
where $\operatorname{atan2}(y, x)$ is the two-argument arctangent function with $\operatorname{atan2}(y, x) = \arctan (\frac{y}{x})$ whenever $x>0$.
Conversely, to go from $(r, \theta)$ to $(x, y)$, we use the formulas: $\begin{align*} x & = r \cos \theta \\[4px] y & = r \sin \theta \end{align*}$
The $exponential\ form\ of\ complex\ numbers$ also makes multiplying complex numbers much easier — much like the same way rectangular coordinates make addition easier.
For example, given two complex numbers $z_1 = r_1 e^{i \theta_1}$ and $z_2 = r_2 e^{i \theta_2}$,
we can now multiply them together as follows:
$\begin{align*} z_1 z_2 & = r_1 e^{i \theta_1} \cdot r_2 e^{i \theta_2} \\ & = r_1 r_2 e^{i(\theta_1 + \theta_2)} \end{align*}$
In the same spirit, we can also divide the same two numbers as follows:
$\begin{align*} \frac{z1}{z2} & = \frac{r_1 e^{i \theta_1}}{r_2 e^{i \theta_2}} \\ & = \frac{r_1}{r_2} e^{i (\theta_{1}-\theta_2)} \end{align*}$

Note

To be sure, these do presuppose properties of exponent such as $e^{z_1+z_2}=e^{z_1} e^{z_2}$ and $e^{-z_1} = \frac{1}{e^{z_1}}$, which for example can be established by expanding the power series of $e^{z_1}$, $e^{-z_1}$ and $e^{z_2}$.
Had we used the $rectangular\ notation$ $x + iy$ instead, the same division would have required multiplying by the complex conjugate in the $numerator$ and $denominator$.
With the $polar\ coordinates$, the situation would have been the same (save perhaps worse).
If anything, the $exponential form$ sure makes it easier to see that:
- multiplying two complex numbers is really the same as:
  multiplying magnitudes and adding angles,
- dividing two complex numbers is really the same as:
  dividing magnitudes and subtracting angles.

the most remarkable formula in mathematics

Indeed, whether it’s $Euler’s\ identity$ or $complex\ logarithm$,
$Euler’s\ formula$ seems to leave no stone unturned whenever expressions such $\sin$, $i$ and $e$ are involved.
It’s a powerful tool whose mastery can be tremendously rewarding,
and for that reason is a rightful candidate of “the most remarkable formula in mathematics”.

Description	Statement
Euler’s formula	$e^{ix} = \cos x + i \sin x$
Euler’s identity	$e^{i \pi} + 1 = 0$
Complex number (exponential form)	$z = r e^{i \theta}$
Complex exponential	$e^{x+iy} = e^x (\cos y + i \sin y)$
Sine (exponential form)	$\sin x = \dfrac{e^{ix}-e^{-ix}}{2i}$
Cosine (exponential form)	$\cos x = \dfrac{e^{ix} + e^{-ix}}{2}$
Tangent (exponential form)	$\tan x = \dfrac{e^{ix}-e^{-ix}}{i(e^{ix} + e^{-ix})}$
Hyperbolic sine (exponential form)	$\sinh z = \dfrac{\sin iz}{i}$
Hyperbolic cosine (exponential form)	$\cosh z = \cos iz$
Hyperbolic tangent (exponential form)	$\tanh z = \dfrac{\tan iz}{i}$
Complex logarithm	$\ln z = \ln \|z\| + i\phi$
General complex exponential	$a^z = e^{z \ln a}$
De Moivre’s theorem	$(\cos x + i \sin x)^n = \cos nx + i \sin nx$
Additive identity of sine	$\sin (x+y) = \sin x \cos y + \cos x \sin y$
Additive identity of cosine	$\cos (x+y) = \cos x \cos y-\sin x \sin y$

posted @ 2024-02-18 21:40 abaelhe 阅读(55) 评论(0) 收藏举报

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Description	Statement
Euler’s formula	\(e^{ix} = \cos x + i \sin x\)
Euler’s identity	\(e^{i \pi} + 1 = 0\)
Complex number (exponential form)	\(z = r e^{i \theta}\)
Complex exponential	\(e^{x+iy} = e^x (\cos y + i \sin y)\)
Sine (exponential form)	\(\sin x = \dfrac{e^{ix}-e^{-ix}}{2i}\)
Cosine (exponential form)	\(\cos x = \dfrac{e^{ix} + e^{-ix}}{2}\)
Tangent (exponential form)	\(\tan x = \dfrac{e^{ix}-e^{-ix}}{i(e^{ix} + e^{-ix})}\)
Hyperbolic sine (exponential form)	\(\sinh z = \dfrac{\sin iz}{i}\)
Hyperbolic cosine (exponential form)	\(\cosh z = \cos iz\)
Hyperbolic tangent (exponential form)	\(\tanh z = \dfrac{\tan iz}{i}\)
Complex logarithm	\(\ln z = \ln \|z\| + i\phi\)
General complex exponential	\(a^z = e^{z \ln a}\)
De Moivre’s theorem	\((\cos x + i \sin x)^n = \cos nx + i \sin nx\)
Additive identity of sine	\(\sin (x+y) = \sin x \cos y + \cos x \sin y\)
Additive identity of cosine	\(\cos (x+y) = \cos x \cos y-\sin x \sin y\)

abaelhe