Birth of period-3 orbits

Tangent bifurcation on complex plane

For quadratic mapping f we have two fixed points z_* = f(z_*)  
    z_1,2 = 1/2 -+ (1/4 - c)^1/2,     l_1,2 = 2z_1,2 .
Since z₂ = 1/2 - z₁ the roots are situated symmetrically with respect to the point p = 1/2. The square root function maps the whole complex plane into a complex half-plane. We choose the Re(z) > 0 half-plane here, therefore the fixed point z₂ is always repelling (i.e. z₂ is repeller).

While parameter c belongs to the main cardioid on the scheme below, the fixed point z₁ lies into the blue circle and is attracting. Corresponding repeller z₂ lies into the yellow circle. z₁ becomes a repeller too when c lies outside the main cardioid.

For c = 0 we have z₁ = 0, l₁ = 0 that is z₁ lies in the center of the blue circle and is a superattracting point. z₂ lies in the center of the yellow circle. While c goes to 1/4,   z_{1, 2} move towards the p point. For c = 1/4 the two roots merge together in p and we get one parabolic fixed point with multiplier l = 1. For c > 1/4, as c leaves the main cardioid, we get two complex repelling fixed points
    z_1,2 = 1/2 -+ t i,   t = (c - 1/4)^1/2
where t is real. They go away the p point in the vertical direction.

On the pictures below colors inside filled J sets show how fast a point goes to attractor z₁. For c = 0 (the first image) attractor "A" lies in the center of circles. Repeller "R" always lies in J ! On the second picture you see infinite sequence of preimages of the attractor, repeller and critical point (the critical point "C" lies in the center of J)

Animations 350+350 and 350x450 pixels. You will see here the play of two repellers (and their preimages) near the point c = 1/4.

Comments (0)

Subscribe to this comment's feed

Name

Email

Website

Title

Comment

smaller | bigger

Subscribe via email (registered users only)

I have read and agree to the Terms of Usage.

Add Comment