This is rather a research problem - you have to run statistical tests on the Cellular Automata (CA) Rule you find to show that it is random. If you would like to do a research projects like this check out **The Wolfram Science Summer School**.

For now let see what information and tools can get you started.

First of all I would read **Chapter 6: Starting from Randomness - Section 5: Randomness in Class 3 Systems** in the "New Kind of Science" (NKS) book and surounding chapters for better understanding of the subject.

I would also look at **many free apps exploring 3-color rules** at The Wolfram Demonstrations Project.

Next you can start from good candidates found on **page 64**. Follow that link and read the image captions about 3-color CAs with seamingly random behavior. The online book is free (you may need to register once). I would recommend also reading pages 62 - 70 exaplaining those images.

Also take a look at **"Random Sequence Generation by Cellular Automata" by Stephen Wolfram**.

If you do no thave Mathematica, then Wolfram|Alpha can provide tons of valuable information. Here are the queries for the CAs from NKS book: **rule 177**, **rule 912**, and **rule 2040**. Not how Wolfram|Alpha gives you, for example, **difference pattern** images - higly divergent (spread fast) means chaos and randomness:

If you have **Mathematica** - it is easy to evolve CAs (and further test their random properties say with **Chi-squared test**). This is how you set up a 3 color range 1 totalistic CAs from pictures in NKS book (you can dig further with **Hypothesis Testing**):

```
ArrayPlot[CellularAutomaton[{#, {3, 1}}, {{1}, 0}, 50], Mesh -> True,
PixelConstrained -> 7, ColorRules -> {0 -> White, 1 -> Red},
Epilog -> Text[Style["Rule " <> ToString@#, Red, Bold, 25], {50, 340}]] & /@
{177, 912, 2040} // Column
```