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Advanced Mathematics 2

Euler’s formula

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Mada za sehemu hiiComplex NumbersMada 4

Euler's formula

The polar form of a complex number z=r(cosθ+isinθ)z = r(\cos\theta + i\sin\theta) can be expressed in exponential form using the Maclaurin series for cosθ\cos\theta, sinθ\sin\theta, and eiθe^{i\theta}.

cosθ=1θ22!+θ44!θ66!+(6.7)\cos\theta = 1 - \frac{\theta^2}{2!} + \frac{\theta^4}{4!} - \frac{\theta^6}{6!} + \dots \quad (6.7)

sinθ=θθ33!+θ55!θ77!+(6.8)\sin\theta = \theta - \frac{\theta^3}{3!} + \frac{\theta^5}{5!} - \frac{\theta^7}{7!} + \dots \quad (6.8)

The Maclaurin series for exe^x is:

ex=1+x1!+x22!+x33!+x44!+x55!+(6.9)e^x = 1 + \frac{x}{1!} + \frac{x^2}{2!} + \frac{x^3}{3!} + \frac{x^4}{4!} + \frac{x^5}{5!} + \dots \quad (6.9)

Let x=iθx = i\theta. Substituting x=iθx = i\theta into equation (6.9):

eiθ=1+iθ1!+(iθ)22!+(iθ)33!+(iθ)44!+(iθ)55!+e^{i\theta} = 1 + \frac{i\theta}{1!} + \frac{(i\theta)^2}{2!} + \frac{(i\theta)^3}{3!} + \frac{(i\theta)^4}{4!} + \frac{(i\theta)^5}{5!} + \dots

=1+iθθ22!iθ33!+θ44!+iθ55!+= 1 + i\theta - \frac{\theta^2}{2!} - i\frac{\theta^3}{3!} + \frac{\theta^4}{4!} + i\frac{\theta^5}{5!} + \dots

=(1θ22!+θ44!)+i(θθ33!+θ55!)(6.10)= \left(1 - \frac{\theta^2}{2!} + \frac{\theta^4}{4!} - \dots\right) + i\left(\theta - \frac{\theta^3}{3!} + \frac{\theta^5}{5!} - \dots\right) \quad (6.10)

Substituting equations (6.7) and (6.8) into equation (6.10):

eiθ=cosθ+isinθ(6.11)e^{i\theta} = \cos\theta + i\sin\theta \quad (6.11)

Multiplying both sides of equation (6.11) by rr:

reiθ=r(cosθ+isinθ)re^{i\theta} = r(\cos\theta + i\sin\theta)

Since z=r(cosθ+isinθ)z = r(\cos\theta + i\sin\theta):

z=reiθ(6.12)z = re^{i\theta} \quad (6.12)

Equation (6.12) is Euler's formula, which represents the complex number zz in exponential form. The complex conjugate of zz can be expressed as z=reiθz^* = re^{-i\theta} (6.13)

If z1=r1eiθ1z_1 = r_1e^{i\theta_1} and z2=r2eiθ2z_2 = r_2e^{i\theta_2}, then:

  1. z1z2=r1r2ei(θ1+θ2)z_1z_2 = r_1r_2e^{i(\theta_1 + \theta_2)}
  2. z1z2=r1r2ei(θ1θ2)\frac{z_1}{z_2} = \frac{r_1}{r_2}e^{i(\theta_1 - \theta_2)}
  3. arg(z1z2)=arg(z1)+arg(z2)\arg(z_1z_2) = \arg(z_1) + \arg(z_2)
  4. arg(z1z2)=arg(z1)arg(z2)\arg\left(\frac{z_1}{z_2}\right) = \arg(z_1) - \arg(z_2)

Relationship between trigonometric and hyperbolic functions

Euler's formula enables us to determine the relationship between trigonometric and hyperbolic functions.

Considering the equations:

eiθ=cosθ+isinθe^{i\theta} = \cos\theta + i\sin\theta

eiθ=cosθisinθe^{-i\theta} = \cos\theta - i\sin\theta

1. Adding the two equations:

eiθ+eiθ=2cosθe^{i\theta} + e^{-i\theta} = 2\cos\theta

cosθ=eiθ+eiθ2\cos\theta = \frac{e^{i\theta} + e^{-i\theta}}{2}

Thus, cosθ=cosh(iθ)\cos\theta = \cosh(i\theta).

2. Subtracting the second equation from the first:

eiθeiθ=2isinθe^{i\theta} - e^{-i\theta} = 2i\sin\theta

sinθ=eiθeiθ2i\sin\theta = \frac{e^{i\theta} - e^{-i\theta}}{2i}

Thus, sinθ=isinh(iθ)\sin\theta = -i\sinh(i\theta).

3. From the identities in parts 1 and 2:

tanθ=sinθcosθ=isinh(iθ)cosh(iθ)=itanh(iθ)\tan\theta = \frac{\sin\theta}{\cos\theta} = \frac{-i\sinh(i\theta)}{\cosh(i\theta)} = -i\tanh(i\theta)

Thus, tanθ=itanh(iθ)\tan\theta = -i\tanh(i\theta).

Example 1

Express 13+i\frac{1}{\sqrt{3}} + i in exponential form.

Solution:

Let z=13+iz = \frac{1}{\sqrt{3}} + i.

r=(13)2+12=13+1=43=23=233r = \sqrt{\left(\frac{1}{\sqrt{3}}\right)^2 + 1^2} = \sqrt{\frac{1}{3} + 1} = \sqrt{\frac{4}{3}} = \frac{2}{\sqrt{3}} = \frac{2\sqrt{3}}{3}

θ=arctan(113)=arctan(3)=π3\theta = \arctan\left(\frac{1}{\frac{1}{\sqrt{3}}}\right) = \arctan(\sqrt{3}) = \frac{\pi}{3}

Thus, z=reiθ=233eiπ3z = re^{i\theta} = \frac{2\sqrt{3}}{3}e^{i\frac{\pi}{3}}.

Example 2

Express the complex number z=e13π6iz = e^{\frac{13\pi}{6}i} in the form z=a+ibz = a + ib, where a,bRa, b \in \mathbb{R}.

Solution:

z=e13π6i=cos13π6+isin13π6z = e^{\frac{13\pi}{6}i} = \cos\frac{13\pi}{6} + i\sin\frac{13\pi}{6}

Since 13π6=2π+π6\frac{13\pi}{6} = 2\pi + \frac{\pi}{6},

z=cosπ6+isinπ6z = \cos\frac{\pi}{6} + i\sin\frac{\pi}{6}

z=32+12iz = \frac{\sqrt{3}}{2} + \frac{1}{2}i

Example 3

Using Euler's formula, show that sin3θ=3sinθsin3θ4\sin^3\theta = \frac{3\sin\theta - \sin 3\theta}{4}.

Solution:

Using the identity sinθ=eiθeiθ2i\sin\theta = \frac{e^{i\theta} - e^{-i\theta}}{2i}:

sin3θ=(eiθeiθ2i)3\sin^3\theta = \left(\frac{e^{i\theta} - e^{-i\theta}}{2i}\right)^3

=e3iθ3e2iθeiθ+3eiθe2iθe3iθ8i= \frac{e^{3i\theta} - 3e^{2i\theta}e^{-i\theta} + 3e^{i\theta}e^{-2i\theta} - e^{-3i\theta}}{-8i}

=e3iθ3eiθ+3eiθe3iθ8i= \frac{e^{3i\theta} - 3e^{i\theta} + 3e^{-i\theta} - e^{-3i\theta}}{-8i}

sin3θ=(e3iθe3iθ)3(eiθeiθ)8i\sin^3\theta = \frac{(e^{3i\theta} - e^{-3i\theta}) - 3(e^{i\theta} - e^{-i\theta})}{-8i}

sin3θ=2isin3θ6isinθ8i\sin^3\theta = \frac{2i\sin3\theta - 6i\sin\theta}{-8i}

sin3θ=sin3θ3sinθ4\sin^3\theta = \frac{\sin 3\theta - 3\sin\theta}{-4}

sin3θ=3sinθsin3θ4\sin^3\theta = \frac{3\sin\theta - \sin 3\theta}{4}

Example 4

Solve the equation z5+33+3i=0z^5 + 3\sqrt{3} + 3i = 0, expressing the roots in exponential form. Use the argument interval π<θπ-\pi < \theta \le \pi and the interval 2k2-2 \le k \le 2 for the required roots.

Solution:

z5=333iz^5 = -3\sqrt{3} - 3i

Let w=333iw = -3\sqrt{3} - 3i.

r=(33)2+(3)2=27+9=36=6r = \sqrt{(-3\sqrt{3})^2 + (-3)^2} = \sqrt{27 + 9} = \sqrt{36} = 6

θ=arctan(333)=arctan(13)\theta = \arctan\left(\frac{-3}{-3\sqrt{3}}\right) = \arctan\left(\frac{1}{\sqrt{3}}\right). Since both real and imaginary parts are negative, θ\theta is in the third quadrant. Thus, θ=5π6\theta = -\frac{5\pi}{6}.

w=6ei5π6w = 6e^{-i\frac{5\pi}{6}}

z=w15=615ei(5π6+2πk5)z = w^{\frac{1}{5}} = 6^{\frac{1}{5}}e^{i\left(\frac{-\frac{5\pi}{6} + 2\pi k}{5}\right)}

zk=65ei(5π+12πk30)z_k = \sqrt[5]{6}e^{i\left(\frac{-5\pi + 12\pi k}{30}\right)}

For k=2,1,0,1,2k = -2, -1, 0, 1, 2:

z2=65ei29π30z_{-2} = \sqrt[5]{6}e^{-i\frac{29\pi}{30}}

z1=65ei17π30z_{-1} = \sqrt[5]{6}e^{-i\frac{17\pi}{30}}

z0=65ei5π30=65eiπ6z_{0} = \sqrt[5]{6}e^{-i\frac{5\pi}{30}} = \sqrt[5]{6}e^{-i\frac{\pi}{6}}

z1=65ei7π30z_{1} = \sqrt[5]{6}e^{i\frac{7\pi}{30}}

z2=65ei19π30z_{2} = \sqrt[5]{6}e^{i\frac{19\pi}{30}}

Example 5

Solve for zz given that cosz=4\cos z = 4.

Solution:

Using Euler's formula, cosz=eiz+eiz2\cos z = \frac{e^{iz} + e^{-iz}}{2}.

eiz+eiz2=4\frac{e^{iz} + e^{-iz}}{2} = 4

eiz+eiz=8e^{iz} + e^{-iz} = 8

Multiply both sides by eize^{iz}:

(eiz)28eiz+1=0(e^{iz})^2 - 8e^{iz} + 1 = 0

Let u=eizu = e^{iz}. Then u28u+1=0u^2 - 8u + 1 = 0.

Using the quadratic formula:

u=8±6442=8±602=4±15u = \frac{8 \pm \sqrt{64 - 4}}{2} = \frac{8 \pm \sqrt{60}}{2} = 4 \pm \sqrt{15}

eiz=4±15e^{iz} = 4 \pm \sqrt{15}

iz=ln(4±15)iz = \ln(4 \pm \sqrt{15})

z=iln(4±15)z = -i\ln(4 \pm \sqrt{15})

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