$ z^{s_i}+c$
s_i = 0.5, 2.5, … (two step repeating)
Center: 0.0+0.0i; Zoom = 0.1

Much more could be said about the rational functions in the previous posts. Rational Functions deserve their own topic, so I will not go there now. Let's switch to non-integer exponents, starting with half steps (square roots).

If you are familiar with complex numbers you know that the square root function has a discontinuity along the negative real axis. At every iteration step, for those orbits that are close to the negative real axis we put them into two groups. If you are above (or on) the axis you go here, if you are below then you go there. Of the points near -4, half will be sent close to 2i and the other half close to -2i. This creates discontinuities (tears) in our pictures.

Choosing the negative axis is a convention. The cut could be made along any line from 0 to ∞. (For that matter it could be any simple curve from 0 to ∞.) There is no way to avoid the discontinuity. It is always there, and always starts at 0. This is true of all non-integer exponents.

Today's picture is only here to demonstrate the cracks and tears that will be present for the rest of the pictures in this series.

$ z^{s_i}+c$
s_i = 2,-2, … (two step repeating)
Center:-1.23909+0.87230i; Zoom = 4096

Combining two steps of this sequence fractal give the rational function $ \frac{cx^4+2c^2x^2+c^3+1}{x^4+2cx^2+c^2}$. As with polynomial sequence fractals with a two-step sequence this is actually a picture of a degree 4 rational function.

These take a long time to render. Every point runs to the full iteration limit. My code is very inefficient, each step uses complex exponentiation. At higher iteration levels, most of the artifacts will disappear and the image will look like a sea of colored sand, containing a few smooth islands. (I was going to optimize the code and create such an image, but I ran out of time.)

$ z^{s_i}+c$
s_i = 2,-2, … (two step repeating)
Center:-1.059+0.792i; Zoom = 4

As mentioned yesterday, (non-polynomial) rational functions do not have points that "escape to infinity". That forces some changes when making pictures of the capture set. You cannot set a large radius and say when the orbit leaves that radius that it has escaped. In fact, the orbit is almost guaranteed to return. Perhaps another way to look at it is that since infinity, ∞, is just another point, nothing ever escapes.

To be sure rational functions still have critical points, and fixed and periodic points which may be attracting, repelling or indifferent. All the rich dynamics of polynomials are still present.

These images are generated without an "escape test", and also without an "inside color". There is of course an iteration limit. All orbits are run up to the full iteration limit. It does not make sense to color by iteration count, or to paint all the points that reach the iteration limit the same color. The coloring is based on a scheme I described in the series Smooth Colors in 2019. This scheme works well even when the concept of escape and capture are absent.

There are still attracting fixed points and cycles. With this coloring, they show up as smooth areas with gradually changing color.

$ z^{s_i}+c$
s_i = 2,-2, … (two step repeating)
Center:-0.40+-0.07i; Zoom = 0.5

Now the sequence alternates positive and negative exponents.

Up until now with the sequence fractals, each step of the iteration is a polynomial function. Different polynomials to be sure, but always a polynomial. Now with the addition of negative (integer) exponents we enter the realm of rational functions.

I have worked with rational functions in the past. That was prior to the most recent full site reboot, and I have not restored those older images yet. In general, the dynamics of rational functions are well-studied. Rational functions are studied on the Reimann sphere which is the complex numbers with the addition point, ∞, infinity. This makes "division by zero" possible. Also "escape to infinity" is just convergence to a point (∞). Lines are circles, and other cool stuff.

On a Reimann sphere, ∞ is an attracting fixed point when iterating a polynomial. But for a non-polynomial rational function, ∞ is just another point. An orbit can easily land on ∞ and then move on to other points. As an example, consider that the negative exponent (a power of the reciprocal) of a very large number is a very small number.

$ z^{s_i}+c$
s_i = 1,2,2,2,2,2,2,2,2,2 … (ten step repeating)
Center:-0.6984+0,0299i; Zoom = 4096

Same set up as yesterday, Sequence Fractals Part V #3. Different location and deeper zoom.

There is a lot of potential here. This satisfies my original goal to find formulas that generate "Mandelbrot set plus a little more" for when you cannot find anything new in z²+c. But I am going to set aside further exploration of positive integer exponents for another day.

$ z^{s_i}+c$
s_i = 1,2,2,2,2,2,2,2,2,2 … (ten step repeating)
Center:-0.76+0i; Zoom = 20

This is in the same vicinity of yesterday's picture, Sequence Fractals Part V #2. This time one z+c followed by nine steps of z²+c.

There is another way to look at this pattern. If you combine the ninth step, z²+c. and the tenth step, z+c, you get z²+2c. So the pattern could be described as throwing in an extra +c on every ninth step.

$ z^s_i+c$
s_i = 1,2,2,2, … (four step repeating)
Center:-0.769+0i; Zoom = 8

The usual z²+c, but replacing every fourth step with z+c

$ z^{s_i}+c$
s_i = 2, 3, … (two step repeating)
Center:0+0i; Zoom = 0.4

Sequence Fractals Part V will feature formulas where the exponent of z contains the sequence variable. As before, we will start gently, then go crazy.

Here is the simplest such formula, the sequence variable replaced the exponent 2 in the normal quadratic formula. Ironically, this form did not occur to me until I tried several others, and then started to prepare posts for the blog. So the blog will not be following the same path as my personal journey through the exponents.

Today's sequence consists of two repeating integers. The result is similar to the previous Sequence Fractal sets. As long as we stick with positive integers in the sequence, each iteration is a polynomial function.

$ z^2+s_i*z+c$
s₀=0.5, s_i+1=-2.0*s_i²+0.7007
Center:-0.891+0i; Zoom = 256

The sequence adder is increased by 0.0001 compared to yesterday's image, Sequence Fractals Part IV #35. The capture set is gone. Gone at least in this area, and as far as I can tell, everywhere else.

The high density in both of these images is probably a result of choosing a sequence so close to the capture/no capture boundary.

$ z^2+s_i*z+c$
s₀=0.5, s_i+1=-2.0*s_i²+0.7006
Center:-0.891+0i; Zoom = 256

Another sequence fractal formula variation. A z term is added and it is multiplied by the sequence value. The constant sequence 0 would give rise to the usual quadratic / Mandelbrot situation.

I tried several different sequences, and a few zooms on each. I found nothing that stood out as distinctly different from the other formula variations presented so far.

This is the first of two zooms along the negative real axis. Here, the sequence slowly converges to a 32 cycle. Tomorrow's image, Sequence Fractals Part IV #36 is the same location with a small increase in the adder.

$ s_i*z^2+c$
s₀=0.1i, s_i+1=-3.0*s_i²+0.1
Center:-15.61563-0.37619i; Zoom = 13107

Here is a deep zoom on the left side of yesterday's picture, Sequence Fractals Part IV #33. Just a little above the center line, the real axis.

$ s_i*z^2+c$
s₀=0.1i, s_i+1=-3.0*s_i²+0.1
Center:-2+0i; Zoom = 0.04

This one uses the a*s_i²+b sequence generator with a = -3, b = 0.1. The sequence converges quickly to a small value. The result is a large fractal. Large in the sense that the capture area extends well beyond the |c|<=2.0 that is typical with quadratic polynomials. The horizontal range of this image is (-25,+25).

$ s_i*z^2+c$
s₀=0.1i, s_i+1=(0.5+0.1i)*s_i+(0.5-0.1i)
Center:2.7243-0.0262i; Zoom = 3276

Another zoom, same setup as yesterday. Sequence Fractals Part IV #31

$ s_i*z^2+c$
s₀=0.1i, s_i+1=(0.5+0.1i)*s_i+(0.5-0.1i)
Center:-1.312+0.069i; Zoom = 256

This sequence starts at 0.1i and converges to a value close to 1.0. The convergence is quick, but not a straight line.

Again, since the sequence converges quickly, the image looks almost like a regular fractal.

$ s_i*z^2+c$
s₀=1.5, s_i+1=0.9*s_i+0.1
Center:-0.7348+0.180i; Zoom = 128

The sequence multiplies z² again. The sequence starts at 1.5 and converges to 1.0 along the real axis.

Since the sequence converges quickly to the multiplicative identity, 1.0, the resulting images look like Mandelbrot set zooms.

$ s_i*z^2+c$
s_i=1.0, 0.001 repeating
Center:-12.2+0.0i; Zoom = 3

Introducing a new variation on the sequence fractal formula. The z² part is mulplied by the sequence value s_i.

To get my footing with the new formula I started out with a simple two step repeating sequence. The "do-nothing" value of one alternates with the a very small value, 0.001. If an orbit tries to escape, every other step pulls it back. The result is that a large area around the origin is captured. Today's view is far out to the left (-12 units) on the negative real axis.

$ z^2+c*s_i$
s₀=0.3, s_i+1=(-0.5+0.25i)*s_i²+(1.2+0.5i)
Center:-0.8244795+0.27693854i; Zoom = 102400

Here is a zoom into the top of the mountain peak in the lower center of Sequence Fractals Part IV #27.

I feel compelled to try to describe this when I should just let the image speak for itself. This has some characteristic of the jigsaw puzzle fractals. See Sequence Fractals Part III #27 and Sequence Fractals Part IV #16 for a description of "jigsaw puzzle fractals". The areas that I image as the puzzle pieces have a fractal spirals along the edges. The "drop cloth" fractals, see Sequence Fractals Part IV #22 and Sequence Fractals Part IV #23 also have fractal shapes on the edges of puzzle pieces. This one however seems much more organized than the splashed paint appearance of the others.

$ z^2+c*s_i$
s₀=0.3, s_i+1=(-0.5+0.25i)*s_i²+(1.2+0.5i)
Center:-0.82443+0.27707i; Zoom = 5120

Here is a zoom into the left side of the comb in the upper left of the previous image, Sequence Fractals Part IV #26

Are those puzzle pieces on the left?

$ z^2+c*s_i$
s₀=0.3, s_i+1=(-0.5+0.25i)*s_i²+(1.2+0.5i)
Center:0+0i; Zoom = 0.5

Some more playing around with complex parameters in the a*s_i²+b sequence generator.

I have not investigated the long term behavior of this sequence. Given the large capture set and Mandlebrot-like right side, I suspect it the sequence converges to very short cycle, most likely a single point.

A couple of zooms to follow.

$ z^2+c*s_i$
s₀=0.4, s_i+1=(-0.7-0.6i)*s_i²+(0.5+0.1i)
Center:-1.971+0.325; Zoom = 256

Complex numbers are used in the sequence generating formula for the sequence.