- #1
limitkiller
- 80
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1- is there any complex number, x ,such that x^x=i?
2- (-1)^([itex]\sqrt{2}[/itex])=?
2- (-1)^([itex]\sqrt{2}[/itex])=?
Yes, but finding it is non-trivial, involving, I think, the Lambert W function.limitkiller said:1- is there any complex number, x ,such that x^x=i?
We can write -1 in "polar form" as [itex]e^{i\pi}[/itex] and then [itex](-1)^{\sqrt{2}}= (e^{i\pi})^{\sqrt{2}}= e^{i\pi\sqrt{2}}= cos(\pi\sqrt{2})+ i sin(\pi\sqrt{2})[/itex]2- (-1)^([itex]\sqrt{2}[/itex])=?
HallsofIvy said:Yes, but finding it is non-trivial, involving, I think, the Lambert W function.
We can write -1 in "polar form" as [itex]e^{i\pi}[/itex] and then [itex](-1)^{\sqrt{2}}= (e^{i\pi})^{\sqrt{2}}= e^{i\pi\sqrt{2}}= cos(\pi\sqrt{2})+ i sin(\pi\sqrt{2})[/itex]
or about .99+ .077i.
Writing z = reiθ, zz = i gives θ sec(θ) eθ tan(θ) = π/2 + 2πn and r = eθ tan(θ). For n = 0, θ has a solution in (π/6, π/4), and probably infinitely many for each n.limitkiller said:1- is there any complex number, x ,such that x^x=i?
Complex numbers are numbers that contain both a real part and an imaginary part. The imaginary part is represented by the letter "i", which stands for the square root of -1. Complex numbers are written in the form a + bi, where a is the real part and bi is the imaginary part.
The power of -1, when applied to complex numbers, is a way of rotating a complex number around the origin on the complex plane. When a complex number is raised to the power of -1, it essentially becomes its reciprocal or multiplicative inverse.
Complex numbers can be represented on a graph known as the complex plane. The real part of the complex number is plotted on the horizontal axis, while the imaginary part is plotted on the vertical axis. This allows for a visual representation of the complex number and its position on the complex plane.
Complex numbers have various applications in real life, especially in fields such as engineering, physics, and economics. They are used to solve problems that involve alternating currents, oscillations, and electromagnetic fields. In economics, complex numbers are used in game theory and optimization problems.
Some properties of powers of -1 include:
- Any power of -1 can be written as -1, 1, i, or -i.
- When raised to an even power, -1 becomes positive 1.
- When raised to an odd power, -1 remains negative 1.
- When raised to a multiple of 4, -1 becomes positive 1.
- When raised to a power greater than 1, -1 has a repeating pattern of 4 different values.
- When raised to a negative power, -1 becomes the reciprocal of its positive power.