The polar form of a complex number z=r(cosθ+isinθ) can be expressed in exponential form using the Maclaurin series for cosθ, sinθ, and eiθ.
cosθ=1−2!θ2+4!θ4−6!θ6+…(6.7)
sinθ=θ−3!θ3+5!θ5−7!θ7+…(6.8)
The Maclaurin series for ex is:
ex=1+1!x+2!x2+3!x3+4!x4+5!x5+…(6.9)
Let x=iθ. Substituting x=iθ into equation (6.9):
eiθ=1+1!iθ+2!(iθ)2+3!(iθ)3+4!(iθ)4+5!(iθ)5+…
=1+iθ−2!θ2−i3!θ3+4!θ4+i5!θ5+…
=(1−2!θ2+4!θ4−…)+i(θ−3!θ3+5!θ5−…)(6.10)
Substituting equations (6.7) and (6.8) into equation (6.10):
eiθ=cosθ+isinθ(6.11)
Multiplying both sides of equation (6.11) by r:
reiθ=r(cosθ+isinθ)
Since z=r(cosθ+isinθ):
z=reiθ(6.12)
Equation (6.12) is Euler's formula, which represents the complex number z in exponential form. The complex conjugate of z can be expressed as z∗=re−iθ (6.13)
If z1=r1eiθ1 and z2=r2eiθ2, then:
z1z2=r1r2ei(θ1+θ2)
z2z1=r2r1ei(θ1−θ2)
arg(z1z2)=arg(z1)+arg(z2)
arg(z2z1)=arg(z1)−arg(z2)
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+isinθ
e−iθ=cosθ−isinθ
1. Adding the two equations:
eiθ+e−iθ=2cosθ
cosθ=2eiθ+e−iθ
Thus, cosθ=cosh(iθ).
2. Subtracting the second equation from the first:
eiθ−e−iθ=2isinθ
sinθ=2ieiθ−e−iθ
Thus, sinθ=−isinh(iθ).
3. From the identities in parts 1 and 2:
tanθ=cosθsinθ=cosh(iθ)−isinh(iθ)=−itanh(iθ)
Thus, tanθ=−itanh(iθ).
Example 1
Express 31+i in exponential form.
Solution:
Let z=31+i.
r=(31)2+12=31+1=34=32=323
θ=arctan(311)=arctan(3)=3π
Thus, z=reiθ=323ei3π.
Example 2
Express the complex number z=e613πi in the form z=a+ib, where a,b∈R.
Solution:
z=e613πi=cos613π+isin613π
Since 613π=2π+6π,
z=cos6π+isin6π
z=23+21i
Example 3
Using Euler's formula, show that sin3θ=43sinθ−sin3θ.
Solution:
Using the identity sinθ=2ieiθ−e−iθ:
sin3θ=(2ieiθ−e−iθ)3
=−8ie3iθ−3e2iθe−iθ+3eiθe−2iθ−e−3iθ
=−8ie3iθ−3eiθ+3e−iθ−e−3iθ
sin3θ=−8i(e3iθ−e−3iθ)−3(eiθ−e−iθ)
sin3θ=−8i2isin3θ−6isinθ
sin3θ=−4sin3θ−3sinθ
sin3θ=43sinθ−sin3θ
Example 4
Solve the equation z5+33+3i=0, expressing the roots in exponential form. Use the argument interval −π<θ≤π and the interval −2≤k≤2 for the required roots.
Solution:
z5=−33−3i
Let w=−33−3i.
r=(−33)2+(−3)2=27+9=36=6
θ=arctan(−33−3)=arctan(31). Since both real and imaginary parts are negative, θ is in the third quadrant. Thus, θ=−65π.