- #1
ZeroSum
- 11
- 0
Homework Statement
Consider a branch of \log{z} analytic in the domain created with the branch cut x=−y, x≥0. If, for this branch, \log{1}=-2\pi i, find the following.
\log{(\sqrt{3}+i)}
Homework Equations
\log{z} = \ln{r} + i(\theta + 2k\pi)
The Attempt at a Solution
This one is actually given in the textbook (odd numbered problem), but I'm having trouble understanding how the answer was arrived at.
The answer given: 0.693 - i\frac{11\pi}{6}
I can see easily that \log{\sqrt{(1)^2 + (\sqrt{3})^2}}=\ln{2} = 0.693... The real part here makes sense since it's the (real) log of the modulus of the given complex number \sqrt{3}+i.
I can also understand that the branch cut is made along x=-y. Where I'm getting confused is how the cut actually affects this log. So r = 2, \theta=\frac{\pi}{6}. Winding around counterclockwise from 0, we reach \frac{\pi}{6} easily, since it does not cross the branch cut at all.
Does the restriction \log{1}=-2\pi i actually restrict this to moving around the circle clockwise from -\frac{\pi}{4} such that -\frac{9\pi}{4} < \theta \le -\frac{\pi}{4}? When using this log with principal values and restricted to a domain of analyticity of -\pi < \theta \le \pi we traditionally wind around counterclockwise toward \pi and clockwise toward -\pi. This one, if I understand it correctly, winds around -2\pi from the cut so that it's restricted to one set of values for an otherwise multi-valued log.
Why do both of these ways of figuring a single-valued log (the traditional principal valued log cut on the negative x-axis and the one used in this problem) seem to involve winding around the axis different ways? What should I be understanding here that I'm not?
