I recently began coding in R and stumbled upon this code, which draws a Mandelbrot fractal:

```
library(caTools) # external package providing write.gif function
jet.colors <- colorRampPalette(c("#00007F", "blue", "#007FFF", "cyan", "#7FFF7F",
"yellow", "#FF7F00", "red", "#7F0000"))
m <- 1200 # define size
C <- complex( real=rep(seq(-1.8,0.6, length.out=m), each=m ),
imag=rep(seq(-1.2,1.2, length.out=m), m ) )
C <- matrix(C,m,m) # reshape as square matrix of complex numbers
Z <- 0 # initialize Z to zero
X <- array(0, c(m,m,20)) # initialize output 3D array
for (k in 1:20) { # loop with 20 iterations
Z <- Z^2+C # the central difference equation
X[,,k] <- exp(-abs(Z)) # capture results
}
write.gif(X, "Mandelbrot.gif", col=jet.colors, delay=100)
```

I made a few tests and looked at the result. I found out the images had a too low resolution, so I tried this code to improve the resolution: essentially, it calculates the function twice the times (i.e. `f(1)`

, `f(1.5)`

, `f(2)`

, `f(2.5)`

instead of `f(1)`

, `f(2)`

), I think.

```
library(caTools) # external package providing write.gif function
jet.colors <- colorRampPalette(c("#00007F", "blue", "#007FFF", "cyan", "#7FFF7F",
"yellow", "#FF7F00", "red", "#7F0000"))
m <- 1200 # define size
C <- complex( real=rep(seq(-1.8,0.6, length.out=m), each=m ),
imag=rep(seq(-1.2,1.2, length.out=m), m ) )
C <- matrix(C,m,m) # reshape as square matrix of complex numbers
Z <- 0 # initialize Z to zero
X <- array(0, c(m,m,20*2)) # initialize output 3D array
for (n in 1:20) { # loop with 20 iterations
for (m in 1:2) { # Loop twice
k <- n+m/2 # Does the trick of adding .5
Z <- Z^2+C # the central difference equation
X[,,k] <- exp(-abs(Z)) # capture results
}
}
write.gif(X, "Mandelbrot.gif", col=jet.colors, delay=100)
```

Although it calculates twice the amount of numbers, the resolution of `Mandelbrot.gif`

seems to be the same, as well as the dimensions (1200x1200).