1.5 De Moivre's Theorem

Cards (99)

De Moivre's Theorem is faster than multiplying out Cartesian forms for larger powers of complex numbers.
Compare the efficiency of De Moivre's Theorem with Cartesian multiplication for finding powers of complex numbers.
1️⃣ De Moivre's Theorem uses the formula $z^{n} =$ $r^{n}(\cos n\theta + i \sin n\theta)$ .
2️⃣ Cartesian multiplication involves expanding $(a + bi) \times (c + di)$ .
3️⃣ De Moivre's Theorem is faster for larger powers.
4️⃣ Cartesian multiplication is cumbersome and prone to errors.
De Moivre's Theorem enhances both speed and simplicity in complex number calculations.
What is the polar form of a complex number?
$z =$ $r(\cos \theta + i \sin \theta)$
In polar form, $r$ represents the modulus
The argument in polar form is the angle from the positive real axis.
What is the modulus of the complex number $3 +$ $4i$ ? 
5
The argument of $3 +$ $4i$ is approximately 0.927
Match the components of polar form with their meaning:
r (Modulus) ↔️ Distance from the origin
θ (Argument) ↔️ Angle from the real axis
Polar form uses distance and direction to represent complex numbers.
What is the complex exponential function defined as for $z =$ $x +$ $iy$ ? 
e^{z} = e^{x}(\cos y + i \sin y)</latex>
Euler's formula states that $e^{i \theta} =$ $\cos \theta +$ $i \sin \theta$ , connecting complex exponentials to trigonometric functions
What is the exponential form of 2(\cos \frac{\pi}{4} + i \sin \frac{\pi}{4})</latex>?
$2e^{i \frac{\pi}{4}}$
Match the complex forms with their representations:
Cartesian ↔️ $x +$ $iy$
Polar ↔️ $r(\cos \theta + i \sin \theta)$
Exponential ↔️ $re^{i \theta}$
Euler's formula states that $e^{i \theta} =$ $\cos \theta +$ $i \sin \theta$ .
What does De Moivre's Theorem state for $z^{n}$ ? 
z^{n} = r^{n}(\cos n\theta + i \sin n\theta)</latex>
In De Moivre's Theorem, $n$ represents the power
If z = 2(\cos \frac{\pi}{4} + i \sin \frac{\pi}{4})</latex> and $n =$ $3$ , then $z^{3} =$ $- 4\sqrt{2} +$ $4i\sqrt{2}$ .
What is the exponential form of a complex number $r(\cos \theta + i \sin \theta)$ ? 
$re^{i \theta}$
De Moivre's Theorem applies to all integers $n$ .
De Moivre's Theorem states that for $z =$ $r(\cos \theta + i \sin \theta)$ , then $z^{n} =$ $r^{n}(\cos n\theta + i \sin n\theta)$ is the result
What is the general form of a complex number in De Moivre's Theorem?
z = r(\cos \theta + i \sin \theta)</latex>
De Moivre's Theorem is used for finding roots of unity
What is the purpose of De Moivre's Theorem?
Simplifying complex number powers
De Moivre's Theorem contrasts with Euler's formula because it raises complex numbers to powers.
De Moivre's Theorem can be visualized geometrically on the Argand diagram.
What geometrical transformation does the argument $\theta$ undergo when raising a complex number to the power $n$ ? 
Rotation around the origin
The modulus $r$ in De Moivre's Theorem scales the distance from the origin on the Argand diagram.
What does the argument $\theta$ represent in polar form? 
Angle from positive real axis
The modulus $r$ in polar form represents the distance from the origin.
The argument $\theta$ measures the angle from the positive real axis to the complex number.
What is the complex exponential function defined for z = x + iy</latex>?
$e^{z} =$ $e^{x}(\cos y + i \sin y)$
Euler's formula states that $e^{i \theta} =$ $\cos \theta +$ $i \sin \theta$ , linking complex exponentials to trigonometric functions.
The exponential form of a complex number is $re^{i \theta}$ .
What is the $n$ -th power of a complex number $z =$ $r(\cos \theta + i \sin \theta)$ according to De Moivre's Theorem? 
$z^{n} =$ $r^{n}(\cos n\theta + i \sin n\theta)$
What happens to the modulus when raising a complex number to the power $n$ on the Argand diagram? 
It scales by $r^{n}$
The argument $\theta$ rotates the point around the origin by $n\theta$ radians when $z$ is raised to the power $n$ .
De Moivre's Theorem simplifies finding powers of complex numbers in polar form.
What is the result of (\cos \frac{\pi}{6} + i \sin \frac{\pi}{6})^{4}</latex> using De Moivre's Theorem?
$- \frac{1}{2} +$ $i \frac{\sqrt{3}}{2}$
The geometric interpretation of complex number powers simplifies calculations by visually representing transformations on the Argand