To find the fifth roots of the complex number represented by 32cos(3π) + isin(3π), we first need to express this number in polar form.
The given complex number can be written as:
z = r(cos(θ) + isin(θ))Here, r is the modulus (magnitude) of the complex number and θ is the argument (angle).
1. **Calculate the modulus (r):**
The modulus r of the complex number is given by:
r = |z| = sqrt(x² + y²)In our case, 32cos(3π) + isin(3π) translates to:
r = 322. **Determine the argument (θ):**
The angle or argument is given by:
θ = 3πNow substituting the values, we get:
z = 32(cos(3π) + isin(3π))3. **Calculate the fifth roots:**
To find the fifth roots, we can use the formula for the n-th roots of a complex number:
w_k = r^(1/n) * (cos((θ + 2kπ)/n) + isin((θ + 2kπ)/n))where k takes integer values from 0 to n-1. In our case, n = 5:
w_k = 32^(1/5) * (cos((3π + 2kπ)/5) + isin((3π + 2kπ)/5))The value of 32^(1/5) is 2, since 25 = 32.
4. **Calculate roots for k = 0, 1, 2, 3, 4:**
- For k = 0:
w_0 = 2(cos(3π/5) + isin(3π/5))w_1 = 2(cos((3π + 2π)/5) + isin((3π + 2π)/5)) = 2(cos(5π/5) + isin(5π/5))w_2 = 2(cos((3π + 4π)/5) + isin((3π + 4π)/5)) = 2(cos(7π/5) + isin(7π/5))w_3 = 2(cos((3π + 6π)/5) + isin((3π + 6π)/5)) = 2(cos(9π/5) + isin(9π/5))w_4 = 2(cos((3π + 8π)/5) + isin((3π + 8π)/5)) = 2(cos(11π/5) + isin(11π/5))Thus, the fifth roots of the complex number 32cos(3π) + isin(3π) are:
- 2(cos(3π/5) + isin(3π/5))
- 2(cos(π) + isin(π))
- 2(cos(7π/5) + isin(7π/5))
- 2(cos(9π/5) + isin(9π/5))
- 2(cos(11π/5) + isin(11π/5))
This gives us a complete set of the fifth roots of the given complex number.