# The Emergence of Canalization and Evolvability in an Open-Ended,   Interactive Evolutionary System

**Authors:** Joost Huizinga, Kenneth O. Stanley, and Jeff Clune

arXiv: 1704.05143 · 2019-02-15

## TL;DR

This paper demonstrates that open-ended, interactive evolutionary systems can naturally develop developmental canalization and increased evolvability, unlike traditional simulations, highlighting the importance of divergent evolution for complex trait emergence.

## Contribution

It shows that open-ended evolution can lead to canalization and modularity, providing insights into the evolution of evolvability in computational models.

## Key findings

- Genomes evolved to entrench certain variation dimensions.
- Genomes became highly modular and hierarchical.
- Evolvability correlated with increased fitness.

## Abstract

Natural evolution has produced a tremendous diversity of functional organisms. Many believe an essential component of this process was the evolution of evolvability, whereby evolution speeds up its ability to innovate by generating a more adaptive pool of offspring. One hypothesized mechanism for evolvability is developmental canalization, wherein certain dimensions of variation become more likely to be traversed and others are prevented from being explored (e.g. offspring tend to have similarly sized legs, and mutations affect the length of both legs, not each leg individually). While ubiquitous in nature, canalization almost never evolves in computational simulations of evolution. Not only does that deprive us of in silico models in which to study the evolution of evolvability, but it also raises the question of which conditions give rise to this form of evolvability. Answering this question would shed light on why such evolvability emerged naturally and could accelerate engineering efforts to harness evolution to solve important engineering challenges. In this paper we reveal a unique system in which canalization did emerge in computational evolution. We document that genomes entrench certain dimensions of variation that were frequently explored during their evolutionary history. The genetic representation of these organisms also evolved to be highly modular and hierarchical, and we show that these organizational properties correlate with increased fitness. Interestingly, the type of computational evolutionary experiment that produced this evolvability was very different from traditional digital evolution in that there was no objective, suggesting that open-ended, divergent evolutionary processes may be necessary for the evolution of evolvability.

## Full text

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## Figures

61 figures with captions in the complete paper: https://tomesphere.com/paper/1704.05143/full.md

## References

135 references — full list in the complete paper: https://tomesphere.com/paper/1704.05143/full.md

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Source: https://tomesphere.com/paper/1704.05143