Cellular Automata. John von Neumann 1903 – 1957 “a Hungarian-American mathematician and polymath...
-
Upload
stuart-davis -
Category
Documents
-
view
214 -
download
0
Transcript of Cellular Automata. John von Neumann 1903 – 1957 “a Hungarian-American mathematician and polymath...
Cellular Automata
John von Neumann 1903 – 1957
“a Hungarian-American mathematician and
polymath who made major contributions to a vast
number of fields,[1] including mathematics (set
theory, functional analysis, ergodic theory, geo
metry, numerical analysis, and many other
mathematical fields), physics (quantum mechanics,
hydrodynamics, and fluid dynamics), economics
(game theory), computer science (linear progra
mming, computer architecture, self-replicating ma
chines, stochastic computing), and statistics. He
is generally regarded as one of the greatest
mathematicians in modern history.[2]”
From wikipedia:
Published report on the EDVAC “a computer architecture in which the data and the program are both
stored in the computer's memory in the same address space”
3
Self reproducing machines
4
Self reproducing machines
“Quines”
5
Self reproducing machines
Quotes
“Truth is much too complicated to allow anything but approximations.”
“You should call it entropy, for two reasons. In the first place your uncertainty function has been used in statistical mechanics ....In the second place, and more important, no one really knows what entropy really is, so in a debate you will always have the advantage.”■Suggesting to Claude Shannon a name for his new uncertainty function, as quoted in Scientific AmericanVol. 225 No. 3, (1971), p. 180
“If people do not believe that mathematics is simple, it is only
because they do not realize how complicated life is.”
“ I am thinking about something much more important than
bombs. I am thinking about computers”.-John von Neumann,
1946
What is a cellular automaton?
• light bulbs pictures
• relation to Turing machines– “non-von-Neumann-style architecture”
• invented by von Neumann
• CAs and universal computation
What is a cellular automaton?
Circular (“toroidal”) boundary conditions
time = 1 time = 2
Conway talks about creating Life:http://www.youtube.com/watch?v=FdMzngWchDk
Example: Game of Life
(John Conway, 1970s)
• Neighborhood: 2 dimensional 3x3 neighborhood:
• Rules: – A dead cell with exactly three live neighbors
becomes a live cell (birth). – A live cell with two or three live neighbors
stays alive (survival). – In all other cases, a cell dies or remains dead
(overcrowding or loneliness).
Demo: http://golly.sourceforge.net
A “glider”
Netlogo models library: Computer science –> Cellular Automata –> Life
Go through code
See http://www.bitstorm.org/gameoflife/
Seehttp://en.wikipedia.org/wiki/Conway%27s_Game_of_Life
• Is there a general way (a “definite procedure”) to predict the behavior of Life from a given initial configuration?
• Is there a general way (a “definite procedure”) to predict the behavior of Life from a given initial configuration?
• Relation to the Halting Problem.
• Is there a general way (a “definite procedure”) to predict the behavior of Life from a given initial configuration?
• Relation to the Halting Problem.
• Answer: No.
• Is there a general way (a “definite procedure”) to predict the behavior of Life from a given initial configuration?
• Relation to the Halting Problem.
• Answer: No.
• Reason “Life is Universal.” http://rendell-attic.org/gol/tm.htm
Elementary cellular automata
One-dimensional, two states (black and white)
Elementary cellular automata
One-dimensional, two states (black and white)
Rule:
Rule:
Elementary cellular automata
One-dimensional, two states (black and white)
Rule:
Elementary cellular automata
One-dimensional, two states (black and white)
Elementary cellular automata
One-dimensional, two states (black and white)
Rule:
Elementary cellular automata
One-dimensional, two states (black and white)
Rule:
Elementary cellular automata
One-dimensional, two states (black and white)
Rule:
http://mathworld.wolfram.com/ElementaryCellularAutomaton.html
See Netlogo models library –> Computer Science –> Cellular Automata –> CA 1D Elementary
http://www.youtube.com/watch?v=60P7717-XOQ
Wolfram’s Four Classes of CA Behavior
• Class 1: Almost all initial configurations relax after a transient period to the same fixed configuration (e.g., all black).
• Class 2: Almost all initial configurations relax after a transient period to some fixed point or some temporally periodic cycle of configurations, but which one depends on the initial configuration
• Class 3: Almost all initial configurations relax after a transient period to chaotic behavior. (The term ``chaotic'‘ here refers to apparently unpredictable space-time behavior.)
• Class 4: Some initial configurations result in complex localized structures, sometimes long-lived.
Rule:
ECA 110 is a universal computer(Matthew Cook, 2002)
Wolfram’s numbering of ECA:
0 1 1 0 1 1 1 0 = 110 in binary
– Transfer of information: moving particles
From http://www.stephenwolfram.com/publications/articles/ca/86-caappendix/16/text.html
– Transfer of information: moving particles
From http://www.stephenwolfram.com/publications/articles/ca/86-caappendix/16/text.html
– Transfer of information: moving particles
– Integration of information from different spatial locations: particle collisions
From http://www.stephenwolfram.com/publications/articles/ca/86-caappendix/16/text.html
– Transfer of information: moving particles
– Integration of information from different spatial locations: particle collisions
From http://www.stephenwolfram.com/publications/articles/ca/86-caappendix/16/text.html
Outline of proof
1. Define “cyclic tag systems” and prove they are universal (they can emulate Turing machines).
2. Show ECA 110 can emulate a cyclic tag system.
Wolfram’s hypothesis:
All class 4 CAs can support universal computation
Outline of Wolfram’s A New Kind of Science
(from MM review, Science, 2002)• Simple programs can produce complex, and
random-looking behavior– Complex and random-looking behavior in nature
comes from simple programs.
• Natural systems can be modeled using cellular-automata-like architectures
• Cellular automata are a framework for understanding nature
• Principle of computational equivalence
Principle of Computational Equivalence
1. The ability to support universal computation is very common in nature.
2. Universal computation is an upper limit on the sophistication of computations in nature.
3. Computing processes in nature are almost always equivalent in sophistication.