Glossary

1.5 Exponential form of complex numbers

5 min readaugust 13, 2024

The exponential form of complex numbers bridges algebra and geometry, offering a powerful tool for manipulating these mathematical objects. By expressing complex numbers as reiθre^{i\theta}, we can easily multiply, divide, and find powers and roots. This representation simplifies calculations and provides insight into the geometric properties of complex numbers.

, eix=cos(x)+isin(x)e^{ix} = \cos(x) + i\sin(x), is the foundation of the exponential form. It connects exponential and trigonometric functions, allowing us to switch between rectangular and polar forms effortlessly. This versatility makes the exponential form invaluable for solving complex equations and understanding their geometric interpretations.

Complex numbers in exponential form

Euler's formula and the exponential form

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  • Euler's formula states that for any real number x, eix=cos(x)+isin(x)e^{ix} = \cos(x) + i\sin(x)
    • This formula connects the exponential function with trigonometric functions
  • The exponential form of a complex number zz is z=reiθz = re^{i\theta}, where rr is the modulus () and θ\theta is the (angle) in radians
    • In the complex plane, the modulus rr represents the distance from the origin to the point representing the complex number
    • The argument θ\theta is the angle formed with the positive real axis
  • The real part of zz is rcos(θ)r\cos(\theta) and the imaginary part is rsin(θ)r\sin(\theta)
  • The exponential form allows for easier manipulation of complex numbers when multiplying, dividing, or finding powers and roots

Applications and advantages of the exponential form

  • The exponential form simplifies calculations involving powers and roots of complex numbers by utilizing the properties of exponents and trigonometric functions
  • When multiplying complex numbers in exponential form, the moduli are multiplied and the arguments are added: z1z2=r1r2ei(θ1+θ2)z_1z_2 = r_1r_2e^{i(\theta_1+\theta_2)}
  • When dividing complex numbers in exponential form, the moduli are divided and the arguments are subtracted: z1z2=r1r2ei(θ1θ2)\frac{z_1}{z_2} = \frac{r_1}{r_2}e^{i(\theta_1-\theta_2)}
  • To raise a complex number z=reiθz = re^{i\theta} to a power nn, use the formula: zn=(reiθ)n=rneinθz^n = (re^{i\theta})^n = r^n e^{in\theta}
  • When finding the nnth roots of a complex number zz, consider the formula: z1n=r1nei(θ+2kπn)z^{\frac{1}{n}} = r^{\frac{1}{n}} e^{i(\frac{\theta + 2k\pi}{n})}, where k=0,1,,n1k = 0, 1, \ldots, n-1

Exponential, polar, and rectangular forms

Converting between different forms of complex numbers

  • The polar form of a complex number is z=rcis(θ)z = r\text{cis}(\theta), where cis(θ)=cos(θ)+isin(θ)\text{cis}(\theta) = \cos(\theta) + i\sin(\theta)
    • This is equivalent to the exponential form z=reiθz = re^{i\theta}
  • To convert from rectangular form (a+bi)(a + bi) to polar or exponential form:
    • Calculate the modulus using r=a2+b2r = \sqrt{a^2 + b^2}
    • Calculate the argument using θ=atan2(b,a)\theta = \text{atan2}(b, a), where atan2\text{atan2} is the two-argument arctangent function
  • To convert from polar or exponential form to rectangular form, use the formulas:
    • Real part: a=rcos(θ)a = r\cos(\theta)
    • Imaginary part: b=rsin(θ)b = r\sin(\theta)
  • Example: Convert 2+2i2 + 2i to polar form
    • r=22+22=22r = \sqrt{2^2 + 2^2} = 2\sqrt{2}
    • θ=atan2(2,2)=π4\theta = \text{atan2}(2, 2) = \frac{\pi}{4}
    • Polar form: z=22cis(π4)z = 2\sqrt{2}\text{cis}(\frac{\pi}{4}) or z=22eiπ4z = 2\sqrt{2}e^{i\frac{\pi}{4}}

Choosing the appropriate form for a given problem

  • When working with complex numbers in different forms, it's essential to consider the context and choose the most appropriate representation for the given problem
  • Rectangular form (a+bi)(a + bi) is often used when performing addition, subtraction, or when the real and imaginary parts are of interest
  • Polar form rcis(θ)r\text{cis}(\theta) and exponential form reiθre^{i\theta} are useful when multiplying, dividing, or finding powers and roots of complex numbers
  • Example: Solve the equation z4=16iz^4 = 16i
    • Converting to exponential form: z=2eiπ2z = 2e^{i\frac{\pi}{2}}
    • Using De Moivre's formula: z4=(2eiπ2)4=16ei2π=16z^4 = (2e^{i\frac{\pi}{2}})^4 = 16e^{i2\pi} = 16
    • The exponential form simplifies the calculation of the fourth power

Powers and roots of complex numbers

Applying the exponential form to solve problems

  • To raise a complex number z=reiθz = re^{i\theta} to a power nn, use the formula: zn=(reiθ)n=rneinθz^n = (re^{i\theta})^n = r^n e^{in\theta}
  • When finding the nnth roots of a complex number zz, consider the formula: z1n=r1nei(θ+2kπn)z^{\frac{1}{n}} = r^{\frac{1}{n}} e^{i(\frac{\theta + 2k\pi}{n})}, where k=0,1,,n1k = 0, 1, \ldots, n-1
  • The nnth roots of unity are complex numbers that satisfy the equation zn=1z^n = 1
    • They are evenly spaced points on the in the complex plane and can be expressed as ei2kπne^{i\frac{2k\pi}{n}}, where k=0,1,,n1k = 0, 1, \ldots, n-1
  • Example: Find the cube roots of 8-8
    • In exponential form: 8=8eiπ-8 = 8e^{i\pi}
    • Using the formula: z13=2ei(π+2kπ3)z^{\frac{1}{3}} = 2e^{i(\frac{\pi + 2k\pi}{3})}, where k=0,1,2k = 0, 1, 2
    • The three cube roots are: 2eiπ3,2eiπ,2ei5π32e^{i\frac{\pi}{3}}, 2e^{i\pi}, 2e^{i\frac{5\pi}{3}}

Solving equations and simplifying expressions

  • The exponential form simplifies calculations involving powers and roots of complex numbers by utilizing the properties of exponents and trigonometric functions
  • When solving equations or simplifying expressions involving complex numbers, converting to exponential form can often lead to more straightforward solutions
  • Example: Simplify (1+i)6(1 + i)^6
    • Converting to exponential form: 1+i=2eiπ41 + i = \sqrt{2}e^{i\frac{\pi}{4}}
    • Using De Moivre's formula: (1+i)6=(2eiπ4)6=8ei3π2=8i(1 + i)^6 = (\sqrt{2}e^{i\frac{\pi}{4}})^6 = 8e^{i\frac{3\pi}{2}} = -8i
    • The exponential form allows for the application of De Moivre's formula, simplifying the calculation

De Moivre's formula for complex numbers

Derivation and application of De Moivre's formula

  • De Moivre's formula is a generalization of Euler's formula for integer powers of complex numbers
    • It states that for any complex number zz and any integer nn: (cos(θ)+isin(θ))n=cos(nθ)+isin(nθ)(\cos(\theta) + i\sin(\theta))^n = \cos(n\theta) + i\sin(n\theta)
  • To derive De Moivre's formula, start with Euler's formula and apply the binomial theorem to expand (eiθ)n(e^{i\theta})^n
  • De Moivre's formula is particularly useful for finding powers and roots of complex numbers expressed in polar or exponential form
  • When using De Moivre's formula to find the nnth roots of a complex number zz, the solutions are given by: z1n=r1n(cos(θ+2kπn)+isin(θ+2kπn))z^{\frac{1}{n}} = r^{\frac{1}{n}} (\cos(\frac{\theta + 2k\pi}{n}) + i\sin(\frac{\theta + 2k\pi}{n})), where k=0,1,,n1k = 0, 1, \ldots, n-1
  • Example: Find the fourth roots of 16(cos(π3)+isin(π3))16(\cos(\frac{\pi}{3}) + i\sin(\frac{\pi}{3}))
    • Using De Moivre's formula: z14=2(cos(π3+2kπ4)+isin(π3+2kπ4))z^{\frac{1}{4}} = 2(\cos(\frac{\frac{\pi}{3} + 2k\pi}{4}) + i\sin(\frac{\frac{\pi}{3} + 2k\pi}{4})), where k=0,1,2,3k = 0, 1, 2, 3
    • The four roots are: 2(cos(π12)+isin(π12)),2(cos(7π12)+isin(7π12)),2(cos(13π12)+isin(13π12)),2(cos(19π12)+isin(19π12))2(\cos(\frac{\pi}{12}) + i\sin(\frac{\pi}{12})), 2(\cos(\frac{7\pi}{12}) + i\sin(\frac{7\pi}{12})), 2(\cos(\frac{13\pi}{12}) + i\sin(\frac{13\pi}{12})), 2(\cos(\frac{19\pi}{12}) + i\sin(\frac{19\pi}{12}))

Solving trigonometric identities and equations

  • Applying De Moivre's formula can simplify complex number calculations and help solve problems involving trigonometric identities and equations
  • By expressing trigonometric functions in terms of complex exponentials using Euler's formula, De Moivre's formula can be applied to simplify expressions and solve equations
  • Example: Prove the identity cos(5θ)=16cos5(θ)20cos3(θ)+5cos(θ)\cos(5\theta) = 16\cos^5(\theta) - 20\cos^3(\theta) + 5\cos(\theta)
    • Using Euler's formula: cos(θ)=eiθ+eiθ2\cos(\theta) = \frac{e^{i\theta} + e^{-i\theta}}{2}
    • Applying De Moivre's formula: (eiθ+eiθ2)5=ei5θ+ei5θ2=cos(5θ)(\frac{e^{i\theta} + e^{-i\theta}}{2})^5 = \frac{e^{i5\theta} + e^{-i5\theta}}{2} = \cos(5\theta)
    • Expanding the left side using the binomial theorem and simplifying leads to the desired identity
  • Mastering the use of De Moivre's formula is crucial for solving advanced problems involving complex numbers and trigonometric functions

Key Terms to Review (18)

Analytic continuation: Analytic continuation is a technique in complex analysis that extends the domain of a given analytic function beyond its original radius of convergence. This method allows for the function to be expressed in terms of another analytic function, effectively 'continuing' it in a larger region. It connects deeply with concepts like singularities, branch points, and the behavior of functions across different domains.
Angle θ: The angle θ represents the argument or phase of a complex number in the context of its exponential form, typically expressed as $re^{iθ}$, where r is the modulus. This angle indicates the direction of the complex number in the complex plane and is crucial for understanding its geometric interpretation. The value of θ is measured in radians and defines how far around the origin the complex number is located.
Argument: In complex analysis, the argument of a complex number is the angle formed between the positive real axis and the line representing the complex number in the complex plane. This angle provides insight into the direction of the complex number, which is essential for understanding its geometric representation, conversion to polar form, and expression in exponential form. The argument is typically measured in radians and can vary by integer multiples of $2\pi$, reflecting the periodic nature of angles.
Augustin-Louis Cauchy: Augustin-Louis Cauchy was a French mathematician whose pioneering work laid the foundation for modern analysis, particularly in complex analysis. His contributions, including the formulation of essential theorems and equations, have influenced various fields of mathematics and physics, establishing principles that remain vital today.
Cauchy-Riemann Equations: The Cauchy-Riemann equations are a set of two partial differential equations that provide necessary and sufficient conditions for a complex function to be differentiable at a point in the complex plane. These equations establish a relationship between the real and imaginary parts of a complex function, connecting them to the concept of analyticity and ensuring that the function behaves nicely under differentiation, which is crucial in various areas such as complex exponentials, conformal mappings, and transformations.
Cosine: Cosine is a trigonometric function that relates the angle of a right triangle to the ratio of the length of the adjacent side to the hypotenuse. In the context of complex numbers, cosine plays a crucial role in expressing complex exponentials using Euler's formula, which states that for any real number $x$, $$e^{ix} = ext{cos}(x) + i ext{sin}(x)$$. This connection highlights how cosine and sine can represent complex numbers in exponential form, offering deep insights into their geometric and algebraic properties.
De Moivre's Theorem: De Moivre's Theorem states that for any complex number in polar form, represented as $$r \text{cis} \theta$$ (where $$\text{cis} \theta = \cos \theta + i \sin \theta$$), the nth power of this complex number can be expressed as $$r^n \text{cis}(n\theta)$$. This theorem beautifully connects the algebraic manipulation of complex numbers with their geometric representation and is essential in converting between exponential and trigonometric forms.
Division in polar form: Division in polar form refers to the method of dividing complex numbers that are expressed in polar coordinates. This involves taking two complex numbers, each represented by their modulus and argument, and using these values to find the quotient in polar form, which simplifies calculations significantly. The process relies on the rules of dividing magnitudes and subtracting angles, making it easier to manage complex divisions compared to rectangular coordinates.
Euler's Formula: Euler's Formula states that for any real number $$x$$, the equation $$e^{ix} = ext{cos}(x) + i ext{sin}(x)$$ holds true, connecting exponential functions with trigonometric functions. This powerful relationship allows us to represent complex numbers in exponential form, offering deep insights into their behavior and properties. The formula serves as a bridge between algebraic and geometric interpretations of complex numbers, making it crucial in various mathematical contexts.
Laplace Transform: The Laplace Transform is a powerful integral transform that converts a function of time (usually denoted as $f(t)$) into a function of a complex variable (denoted as $F(s)$). This transformation is particularly useful in solving ordinary differential equations, as it simplifies the process by changing the domain from time to frequency, allowing for easier analysis and manipulation of linear time-invariant systems. By utilizing the exponential form of complex numbers, the Laplace Transform can effectively handle various applications in physics and engineering, especially in system dynamics and control theory.
Leonhard Euler: Leonhard Euler was an influential Swiss mathematician and physicist who made pioneering contributions across various areas of mathematics, including complex analysis. His work on the exponential form of complex numbers and the development of important functions like the gamma and zeta functions has significantly shaped modern mathematical thought.
Magnitude: Magnitude refers to the distance of a complex number from the origin in the complex plane, representing its size or length. It is calculated using the formula $$|z| = ext{sqrt}(a^2 + b^2)$$ for a complex number $$z = a + bi$$, where $$a$$ is the real part and $$b$$ is the imaginary part. Understanding magnitude helps visualize complex numbers geometrically and facilitates their representation in exponential form.
Multiplication in polar form: Multiplication in polar form is a method used to multiply complex numbers represented in polar coordinates, where each number is expressed as a product of a modulus (magnitude) and an exponential of an angle. This approach simplifies the multiplication process by allowing us to combine the magnitudes and add the angles directly, resulting in a new complex number that is also represented in polar form. Understanding this method highlights the elegance of complex number operations and their geometric interpretations.
Polar Coordinates: Polar coordinates are a two-dimensional coordinate system that defines a point in the plane using a distance from a reference point and an angle from a reference direction. This system is particularly useful in complex analysis, as it allows for the representation of complex numbers in a way that highlights their magnitude and direction, connecting closely with the exponential form of complex numbers where a complex number can be expressed as a product of its magnitude and a rotational factor derived from its angle.
R = |z|: In the context of complex numbers, the term $$r = |z|$$ defines the magnitude or absolute value of a complex number $$z$$. This magnitude is represented as the distance from the origin to the point representing the complex number in the complex plane, which can be expressed in polar and exponential forms. Understanding this concept is crucial for translating between different representations of complex numbers and connecting geometric interpretations with algebraic calculations.
Sine: Sine is a fundamental trigonometric function that relates the angle of a right triangle to the ratio of the length of the opposite side to the length of the hypotenuse. In the context of complex numbers, sine plays a key role in expressing complex exponential functions using Euler's formula, connecting angles and rotations in the complex plane with real-valued functions.
Unit Circle: The unit circle is a circle in the Cartesian coordinate system with a radius of one, centered at the origin (0,0). It is essential in understanding the exponential form of complex numbers because it provides a geometric representation of complex numbers as points on this circle, linking trigonometric functions to complex exponentials through Euler's formula.
Z = re^(iθ): The expression $z = re^{i\theta}$ represents the exponential form of a complex number, where 'r' is the modulus (or absolute value) of the complex number and 'θ' is the argument (or angle) measured in radians. This form connects the polar coordinates to the complex plane, allowing for easier multiplication, division, and exponentiation of complex numbers through Euler's formula, which states that $e^{i\theta} = \cos(\theta) + i\sin(\theta)$.
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