This paper interprets work on understanding the actions of Turing machines operating on an initially blank tape. While this is impossible for arbitrary machines, complete characterizations of behavior are possible if the number of states is sufficiently constrained. The approach combines normalization to drastically reduce the number of machines considered, human-generated classification schemes, and computer-generated proofs of behavior. This approach can be applied to other computational systems, giving complete characterizations in sufficiently small domains. This is of interest in the area of emergent systems since the properties of such systems are often difficult to determine. By using computers to eliminate multitudes of machines wit...
In this paper we present the problems previously encountered in the academic literature related to T...
AbstractThis paper studies the classification of recursive sets by the number of tape reversals requ...
The busy beaver problem is to find the maximum number of 1’s that can be printed by an n-state Turin...
We survey some work concerned with small universal Turing machines, cellular automata, tag systems, ...
Thesis: M. Eng., Massachusetts Institute of Technology, Department of Electrical Engineering and Com...
International audienceWe start by an introduction to the basic concepts of computability theory and ...
Sources that generate symbolic sequences with algorithmic nature may differ in statistical complexit...
AbstractLet TM(k,l) be the set of one-tape Turing machines with k states and l symbols. It is known ...
We survey some work concerned with small universal Turing machines, cellular automata, tag systems, ...
3rd International Workshop on Physics and Computation, Egypt, August 30-SEP 06, 2010International au...
This paper surveys some topics in the area of small universal Turing machines and tag systems. In p...
AbstractIt is a well-known fact that apparently simple systems can give rise to complex behavior. Bu...
Multitape Turing machines which can use their storage tapes only as counters or as pushdown stores a...
Turing machines have been well studided in the context of Computability theory, looking at computati...
Let ϕ be a fixed numerical function. If the k-state Turing machine M with input string ϕ(k) (that is...
In this paper we present the problems previously encountered in the academic literature related to T...
AbstractThis paper studies the classification of recursive sets by the number of tape reversals requ...
The busy beaver problem is to find the maximum number of 1’s that can be printed by an n-state Turin...
We survey some work concerned with small universal Turing machines, cellular automata, tag systems, ...
Thesis: M. Eng., Massachusetts Institute of Technology, Department of Electrical Engineering and Com...
International audienceWe start by an introduction to the basic concepts of computability theory and ...
Sources that generate symbolic sequences with algorithmic nature may differ in statistical complexit...
AbstractLet TM(k,l) be the set of one-tape Turing machines with k states and l symbols. It is known ...
We survey some work concerned with small universal Turing machines, cellular automata, tag systems, ...
3rd International Workshop on Physics and Computation, Egypt, August 30-SEP 06, 2010International au...
This paper surveys some topics in the area of small universal Turing machines and tag systems. In p...
AbstractIt is a well-known fact that apparently simple systems can give rise to complex behavior. Bu...
Multitape Turing machines which can use their storage tapes only as counters or as pushdown stores a...
Turing machines have been well studided in the context of Computability theory, looking at computati...
Let ϕ be a fixed numerical function. If the k-state Turing machine M with input string ϕ(k) (that is...
In this paper we present the problems previously encountered in the academic literature related to T...
AbstractThis paper studies the classification of recursive sets by the number of tape reversals requ...
The busy beaver problem is to find the maximum number of 1’s that can be printed by an n-state Turin...