Alife7- (Printable) Metabolism and Solid Cellular Automata

Artificial Life VII, August 2000

Creating a Physically-Based, Virtual-Metabolism with Solid Cellular Automata (SOCA)

Alan Dorin

http://www.cs.monash.edu.au/~aland
aland@cs.monash.edu.au

Centre for Electronic Media Art
School of Computer Science & Software Engineering
Monash University, Melbourne, Australia

Outline

Motivation
Previous work (by others)
Introducing Solid Cellular Automata
Previous work (by the author)

Simple chemical reactions
Models of catalysis
A model of life
Conclusions & future work

Motivation

To model an organism...

network of self-sustaining, self-bounding, auto/cross-catalytic chemical processes.
...in the spirit of Monod, Kauffman, Prigogine, Maturana & Varela.

Organism components act entirely within the limits imposed by...

their physical & chemical attributes
their local environment

Previous Work (by others)

Physical Simulation
(computer animation, weather forecasting, engineering)
Cellular Automata
(study complex dynamical systems, reproducing systems)
Self-Assembly
(nano-technology, cell & bacteriophage development)
Distributed A.I.
(agent simulations, distributed problem solving)
Molecular Dynamics / Supra-molecular Inorganic Chemistry
(chemical modelling, synthesis, visualization)

Introduction to Solid Cellular Automata (SOCA)

The Physical Model

Model of rigid, convex, polyhedra which are:

suspended in a fluid medium
subject to:
- Fluid drag
- Contact forces caused by collisions
- Internally-generated forces (attract/repel)
- Externally-generated forces (gravity)

The Cellular Automaton Model

Polyhedron's faces may be in one of a number of discrete states.
States are visualized by colour.
One state is designated the inert state.

A polyhedron's environmental conditions consist of the state and range of all non-inert faces on neighbouring polyhedra.
A polyhedron's transition table prescribes state changes for a face
(according to the face's current state and local environmental conditions)
A polyhedron's force table dictates forces generated by a face
(according to the face's current state and local environmental conditions)

Previous work (by the author)

Previous Work: Chaining SOCA elements

Forces	Grey	Blue	Green
Grey	-0.25	0	0
Blue	0	-1	+1
Green	0	+1	-1

short chains

long clumpy chains

long open chains

Previous Work: Size-limited and fracturing clusters of SOCA elements

Forces	Grey	Blue	Green	Red
Grey	-1	-1	-1	0
Blue	-1	-60	-30	-20
Green	-1	-30	+70	-2
Red	0	-20	-2	+70

Transitions	Grey	Blue	Green	Red
Grey	-	-	-	-
Blue	-	-	-	-
Green	-	-	8,Red,0	1,Red,0
Red	-	-	-	10,Green,0


single cluster	size-limited & fractured clusters

Modelling chemical reactions


Red	+ Blue		Magenta	+ Cyan

Forces:

Null (rely on kinetic energy of elements & random collisions)

Transitions	Grey	Red	Blue	Cyan	Magenta
Grey	-	-	-	-	-
Red	-	-	1,Magenta,0	-	-
Blue	-	1,Cyan,0	-	-	-
Cyan	-	-	-	-	-
Magenta	-	-	-	-	-


Illustration of (contained) reaction	Concentration vs. Time (plot)

Catalyzed reactions



Red	+ Blue	Green/Yellow catalyst	Magenta	+ Cyan

Transitions:

Blue -> Cyan
Red -> Magenta

(in the presence of Red)
(in the presence of Blue)

Forces	Grey	Green	Blue	Red	Cyan	Magenta	Yellow
Grey	0	0	0	0	0	0	0
Green	0	0	0	+500	0	-500	0
Blue	0	0	0	0	0	0	+500
Red	0	+500	0	0	0	0	0
Cyan	0	0	0	0	0	0	-500
Magenta	0	-500	0	0	0	0	0
Yellow	0	0	+500	0	-500	0	0

t=0

Red, Blue and a Green/Yellow catalyst

t=100

Red has been pulled towards Green
Blue has been pulled towards Yellow

t=120

Red and Blue have been pulled into proximity and react to form Magenta and Cyan which then frees the catalyst

Concentration vs. Time (plot)

Auto-catalysis


Green	Blue catalyst	Blue

Forces:

Green >attract< Blue

Blue <repel> Blue

Transitions:

Green -> Blue

(in the presence of Blue)

t=0

Lots of Green, one Blue (at the back)

t=300

Green turns towards expanding collection of Blue

t=900...

Blue collection continues to expand converting more and more Green to Blue

Cross-catalysis

Red	+ Blue	Green catalyst	Inert	+ Yellow


Magenta	+ Cyan	Yellow catalyst	Inert	+ Green

The reactions produce catalyst for each other

Forces:

Blue >attract< Green

Red >attract< Green

Magenta >attract< Yellow

Cyan >attract< Yellow

Transitions:

Red -> Inert

Blue -> Yellow

(in the presence of Blue)

(in the presence of Red)

Magenta -> Inert

Cyan -> Green

(in the presence of Cyan)

(in the presence of Magenta)

t=0

Lots of Blue/Red, Cyan/Magenta, a bit of Yellow & Green

t=900...

Blue/Red, Cyan/Magenta pulled towards their respective catalysts to manufacture more catalyst

A model of living systems

Q: Which SOCA topology might potentially be formed from a set of cross-catalytic reactions?

A: The cluster / star is:

easily assembled
robust
of recognizable form
an ideal candidate!

Q: How can a cluster / star be produced using virtual cross-catalytic reactions?

A: Yellow & Green catalyst elements produced by cross catalytic reactions (above) may be clustered together to produce a topology which is:

dynamic
maintained by the cross-catalytic reactions
robust
of recognizable form
a (virtual) metabolic system

Red	+ Blue/Grey	Green/Grey catalyst	Inert	+ Yellow/Grey


Magenta	+ Cyan/Grey	Yellow/Grey catalyst	Inert	+ Green/Grey

Forces:

Blue >attract< Green

Red >attract< Green

Magenta >attract< Yellow

Cyan >attract< Yellow

Grey >attract< Grey

Black >attract< Black*

Transitions:

Red -> Inert

Blue -> Yellow

(in the presence of Blue)

(in the presence of Red)

Magenta -> Inert

Cyan -> Green

(in the presence of Cyan)

(in the presence of Magenta)

Grey -> Inert

Grey -> Black*
Black -> Grey*

(in the presence of 3 Grey)

(in the presence of 3 Grey)
(in the presence of 5 Black)

* Optional forces & transitions for reproduction by fracture

These structures may even fracture (using process explained for fracturing, size-limited structures above) and therefore reproduce whilst maintaining the cross-catalytic reactions.

Dynamic, fracturing clusters formed by (virtual) cross-catalysis

Conclusions & future work

The following SOCA models have been presented:

chemical reactions essential to living things
an organism which:
- constructs its materials
- self-assembles
- cross-catalyzes
- regulates its size
- reproduces by fracture
In the future some motile structures which have been constructed using SOCA will be demonstrated.