# Plot the multiplication of complex roots of fractional polynomials

I'm thinking that @GGrothendieck's answer to the request for solutions to fractional roots of negative numbers deserves a graphical addendum:

Can someone plot the roots in a unit complex circle. as well as add the "graphical sum" of some of the roots, i.e. the sequential products of the same 5 roots of -8, vectors multiplied in sequence?

``````x <- as.complex(-8)  # or x <- -8 + 0i
# find all three cube roots
xroot5 <- (x^(1/5) * exp(2*c(0:4)*1i*pi/5))
plot(xroot5, xlim=c(-8, 2),  ylim=c(-5,5))
abline(h=0,v=0,lty=3)
``````

Originally I was thinking this would be some sort of head to tail illustration but complex multiplication is a series of expansions and rotations around the origin.

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I hadn't seen your comment when I posted my efforts. Multiplying each root also extends the modulus of the result by 8^(1/3). It might have improved the heuristic value, if I had drawn the unit circle since each of the roots fall outside it. I'd be happy to check your answer if you post it. – 42- Mar 24 '14 at 3:39

The circle is centered at 0, 0. The roots all have the same radius and picking any one of them, the radius is

``````r <- Mod(xroot[1])
``````

The following gives a plot which looks similar to the plot in the question except we have imposed an aspect ratio of 1 in order to properly draw it and there is a circle drawn through the 5 points:

``````plot(Re(xroot5), Im(xroot5), asp = 1)

library(plotrix)
draw.circle(0, 0, r)
``````

Multiplying any root by

``````e <- exp(2*pi*1i/5)
``````

will rotate it into the next root. For example, this plots `xroot5[1]` in red:

``````i <- 0
points(Re(xroot5[1] * e^i), Im(xroot5[1] * e^i), pch = 20, col = "red")
``````

and then repeat the last line for i = 1, 2, 3, 4 to see the others successively turn red.

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I do like the idea of drawing expanding "modulus circles". Each of the n-th powers of the roots will lie on such circles. – 42- Mar 24 '14 at 4:37

The `Reduce` function with `accumulate=TRUE` will deliver the sequence of intermediate powers of each of the roots of `x^5 = -8` up to the fith power:

``````x <- as.complex(-8)  # or x <- -8 + 0i
# find all five roots
xroot5 <- (x^(1/5) * exp(2*c(0:4)*1i*pi/5))
xroot5
#[1]  1.226240+0.890916i -0.468382+1.441532i -1.515717+0.000000i -0.468382-1.441532i
#[5] 1.226240-0.890916i
(Reduce("*", rep( xroot5[4], 5),acc=TRUE) )
#[1] -0.468382-1.441532i -1.858633+1.350376i  2.817161+2.046787i  1.631001-5.019706i
#[5] -8.000000+0.000000i
# Using the fourth root:
beg <- (Reduce("*", rep( xroot5[4], 5),acc=TRUE) )[-5]
ends <- (Reduce("*", rep( xroot5[4], 5),acc=TRUE) )[-1]
# Need more space
plot(xroot5, xlim=c(-8, 2),  ylim=c(-6,6))
abline(h=0,v=0,lty=3)
arrows(Re(beg),Im(beg), Re(ends), Im(ends), col="red")

# Plot sequence of powers of first root:
beg <- Reduce("*", rep( xroot5[1], 5),acc=TRUE)[-5]
ends <- Reduce("*", rep( xroot5[1], 5),acc=TRUE)[-1]
arrows(Re(beg),Im(beg), Re(ends), Im(ends), col="blue")
``````

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