Particle Lenia: Self Organising Particles (opens in new tab)

Idiot here.

I think this field of study has wild potential.

How do you get one of these to learn a function. And further: learn to combine functions from individuals to accomplish a task?

I wonder if such artificial life forms could be hooked up to a machine learning algorithm somehow, so that they learn from their experience in the environment. I imagine the organisms would need some kind of "senses" like touch and vision; maybe a concept of food, light, enemy/friend..

Oh, there's a link at the bottom of the paper to a project called Sensorimotor Lenia, which goes in that direction.

> These patterns can display certain properties of biological systems such as a spatially localized organization, directional or rotational movements, etc. In fact, CA [cellular automata] have a long relationship with biology and especially the origins of life/cognition as it is a self-organizing system that can serve as a computational testbed and toy model for such theories but also as a source of inspiration on what are the basic building block of “life”.

> However, while the notions of embodiment within an environment, individuality and self-maintenance are central in theoretical biology and in particular in the definition of agency, it remains unclear how such mechanisms and properties can emerge from a set of local update rules in a CA.

> In this blogpost, we propose an approach enabling to learn self-organizing agents capable of reacting to the perturbations induced by the environment, i.e. robust agents with sensorimotor capabilities.

> ..Searching for rules at the cell-level in order to give rise to higher-level cognitive processes at the level of the organism and at the level of the group of organisms opens many exciting opportunities to the development of embodied approaches in AI in general.

Learning Sensorimotor Agency in Cellular Automata - Finding robust self-organizing “agents” with gradient descent and curriculum learning: individuality, self-maintenance and sensori-motricity within a cellular automaton environment

https://developmentalsystems.org/sensorimotor-lenia/

A completely artificial computer simulation exhibiting properties of life is meaningless. Of course if you call SimulateLife() it will appear to simulate life. But if the things you’re building the supposed life from are made up and you can’t do it in nature then you’re basically just making a video game.

Paper: https://google-research.github.io/self-organising-systems/pa...

(via https://news.ycombinator.com/item?id=34108745, but we merged that thread hither)

I don't see the potential (yet?) except that it's fun.

fun to play with … with added ingredients, would it be possible to simulate larger and more complex phenomena?

Really exciting work! This reminds me a lot of Physarum (slime mold) simulations popularized by media artists like Sage Jensen[1]. The combination of explicitly defined particles along with fields that those particles can interact with is proving to be a fascinating technique!

[1]: https://cargocollective.com/sagejenson/physarum

Direct link to the web demo: https://znah.net/lenia/

I'm most interested in assessing these systems for their ability to learn us something about abiogenesis (the origin of life).Can you set up a system like this in a suitable environment where the interaction with the environment somehow has the potential to accumulate complexity (or ordered structure) without any further 'engineering' intervention?

When I read the title I immediately thought that this must be in the sphere of @zzznah.

This reminded me of a video of lipid bilayer formation:

https://www.youtube.com/watch?v=lm-dAvbl330

It seems like our "toy" models are getting closer to reality.

If an AI faced someone or something who could disconnect it, we would have a true intelligence, I think that only intelligence of natural origin could reach here.