Exploring the Power of Complex Numbers: (1 + i)^2020
This article delves into the fascinating world of complex numbers, specifically exploring the value of (1 + i)^2020. We'll uncover the beauty of De Moivre's Theorem and its application in solving this complex power.
Understanding Complex Numbers
Before we embark on the calculation, let's first understand the basics of complex numbers. Complex numbers are expressed in the form a + bi, where a and b are real numbers, and i is the imaginary unit, defined as the square root of -1.
De Moivre's Theorem: A Powerful Tool
De Moivre's Theorem offers a convenient way to calculate powers of complex numbers. It states that for any complex number z = r(cos θ + i sin θ) and any integer n, the following holds:
z^n = r^n(cos nθ + i sin nθ)
Calculating (1 + i)^2020
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Polar Form: We begin by converting 1 + i into its polar form. The magnitude, r, is calculated as √(1^2 + 1^2) = √2. The angle, θ, is found using arctan(1/1) = π/4 radians. Therefore, 1 + i = √2(cos π/4 + i sin π/4).
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Applying De Moivre's Theorem: Now, let's apply De Moivre's Theorem to calculate (1 + i)^2020:
(1 + i)^2020 = (√2)^2020 (cos (2020 * π/4) + i sin (2020 * π/4))
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Simplifying: Since (√2)^2020 = 2^1010, and 2020 * π/4 simplifies to 505π, we get:
(1 + i)^2020 = 2^1010 (cos 505π + i sin 505π)
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Final Result: Knowing that cos 505π = -1 and sin 505π = 0, we arrive at the final answer:
(1 + i)^2020 = -2^1010
Conclusion
The calculation of (1 + i)^2020 serves as a beautiful illustration of the power of De Moivre's Theorem in simplifying complex expressions. Through this exploration, we gain a deeper understanding of complex numbers and their applications in mathematics and various scientific fields.