Here I've taken one of Sprott's simple three-dimensional chaotic flows with a quadratic nonlinearity (the system SQF, from table 3.1 reference [1]),
and replaced the quadratic nonlinearity with the tetration operator x
x to give the system:
.
The 2nd order tetration is realised on the analogue computer by multiplying the logarithm of |x| with |x| and then taking the exponential, this is all patched up as shown below:
Initial conditions were (0,-0.5,0). The following pictures show the results from the analogue computer: pen plots on the left (600 seconds' worth), oscilloscope traces on the right (with computer in FAST mode):
 |
| XZ-plane (left is pen plot (0.5 V/cm), right from oscilloscope (1 V/div)) |
 |
| XY-plane |
 |
| YZ-plane (plotter) |
 |
| YZ-plane (oscilloscope) |
And here are some MATHCAD results:
 |
| MATHCAD results (∆t = 0.00025) |
In passing, it's noted that the system has two equilibrium points, namely (-0.3463233..., -0.6926467..., 0.6926467...) and (-2, -4, 4), and the divergence of the system is equal to -1/2 and the system is dissipative.
It is apparent (and presumably not surprising) that many of the other chaotic systems remain chaotic when (for example) quadratic terms are replaced with |x|
|x|, e.g. Nosé–Hoover.
Reference
[1] J.C. Sprott, Elegant Chaos - Algebraically Simple Chaotic Flows, World Scientific, 2010, p. 70.
and replaced the quadratic nonlinearity with the tetration operator xx to give the system:
.
