Your search keyword '"Jesper Tegnér"' showing total 6 results

1. The Thermodynamics of Network Coding, and an Algorithmic Refinement of the Principle of Maximum Entropy

Author

Hector Zenil, Narsis A. Kiani, and Jesper Tegnér

Subjects

second law of thermodynamics, reprogrammability, algorithmic complexity, generative mechanisms, deterministic systems, algorithmic randomness, principle of maximum entropy, Maxent, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The principle of maximum entropy (Maxent) is often used to obtain prior probability distributions as a method to obtain a Gibbs measure under some restriction giving the probability that a system will be in a certain state compared to the rest of the elements in the distribution. Because classical entropy-based Maxent collapses cases confounding all distinct degrees of randomness and pseudo-randomness, here we take into consideration the generative mechanism of the systems considered in the ensemble to separate objects that may comply with the principle under some restriction and whose entropy is maximal but may be generated recursively from those that are actually algorithmically random offering a refinement to classical Maxent. We take advantage of a causal algorithmic calculus to derive a thermodynamic-like result based on how difficult it is to reprogram a computer code. Using the distinction between computable and algorithmic randomness, we quantify the cost in information loss associated with reprogramming. To illustrate this, we apply the algorithmic refinement to Maxent on graphs and introduce a Maximal Algorithmic Randomness Preferential Attachment (MARPA) Algorithm, a generalisation over previous approaches. We discuss practical implications of evaluation of network randomness. Our analysis provides insight in that the reprogrammability asymmetry appears to originate from a non-monotonic relationship to algorithmic probability. Our analysis motivates further analysis of the origin and consequences of the aforementioned asymmetries, reprogrammability, and computation.

Published

2019

2. A Decomposition Method for Global Evaluation of Shannon Entropy and Local Estimations of Algorithmic Complexity

Author

Hector Zenil, Santiago Hernández-Orozco, Narsis A. Kiani, Fernando Soler-Toscano, Antonio Rueda-Toicen, and Jesper Tegnér

Subjects

algorithmic randomness, algorithmic probability, Kolmogorov–Chaitin complexity, information theory, Shannon entropy, information content, Thue–Morse sequence, π, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We investigate the properties of a Block Decomposition Method (BDM), which extends the power of a Coding Theorem Method (CTM) that approximates local estimations of algorithmic complexity based on Solomonoff–Levin’s theory of algorithmic probability providing a closer connection to algorithmic complexity than previous attempts based on statistical regularities such as popular lossless compression schemes. The strategy behind BDM is to find small computer programs that produce the components of a larger, decomposed object. The set of short computer programs can then be artfully arranged in sequence so as to produce the original object. We show that the method provides efficient estimations of algorithmic complexity but that it performs like Shannon entropy when it loses accuracy. We estimate errors and study the behaviour of BDM for different boundary conditions, all of which are compared and assessed in detail. The measure may be adapted for use with more multi-dimensional objects than strings, objects such as arrays and tensors. To test the measure we demonstrate the power of CTM on low algorithmic-randomness objects that are assigned maximal entropy (e.g., π ) but whose numerical approximations are closer to the theoretical low algorithmic-randomness expectation. We also test the measure on larger objects including dual, isomorphic and cospectral graphs for which we know that algorithmic randomness is low. We also release implementations of the methods in most major programming languages—Wolfram Language (Mathematica), Matlab, R, Perl, Python, Pascal, C++, and Haskell—and an online algorithmic complexity calculator.

Published

2018

3. Symmetry and Correspondence of Algorithmic Complexity over Geometric, Spatial and Topological Representations

Author

Hector Zenil, Narsis A. Kiani, and Jesper Tegnér

Subjects

Kolmogorov–Chaitin complexity, algorithmic probability, algorithmic coding theorem, Turing machines, polyominoes, polyhedral networks, molecular complexity, polytopes, information content, Shannon entropy, symmetry breaking, recursive transformation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We introduce a definition of algorithmic symmetry in the context of geometric and spatial complexity able to capture mathematical aspects of different objects using as a case study polyominoes and polyhedral graphs. We review, study and apply a method for approximating the algorithmic complexity (also known as Kolmogorov–Chaitin complexity) of graphs and networks based on the concept of Algorithmic Probability (AP). AP is a concept (and method) capable of recursively enumerate all properties of computable (causal) nature beyond statistical regularities. We explore the connections of algorithmic complexity—both theoretical and numerical—with geometric properties mainly symmetry and topology from an (algorithmic) information-theoretic perspective. We show that approximations to algorithmic complexity by lossless compression and an Algorithmic Probability-based method can characterize spatial, geometric, symmetric and topological properties of mathematical objects and graphs.

Published

2018

4. A Review of Graph and Network Complexity from an Algorithmic Information Perspective

Author

Hector Zenil, Narsis A. Kiani, and Jesper Tegnér

Subjects

algorithmic information theory, complex networks, Kolmogorov-Chaitin complexity, algorithmic randomness, algorithmic probability, biological networks, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Information-theoretic-based measures have been useful in quantifying network complexity. Here we briefly survey and contrast (algorithmic) information-theoretic methods which have been used to characterize graphs and networks. We illustrate the strengths and limitations of Shannon’s entropy, lossless compressibility and algorithmic complexity when used to identify aspects and properties of complex networks. We review the fragility of computable measures on the one hand and the invariant properties of algorithmic measures on the other demonstrating how current approaches to algorithmic complexity are misguided and suffer of similar limitations than traditional statistical approaches such as Shannon entropy. Finally, we review some current definitions of algorithmic complexity which are used in analyzing labelled and unlabelled graphs. This analysis opens up several new opportunities to advance beyond traditional measures.

Published

2018

5. A Decomposition Method for Global Evaluation of Shannon Entropy and Local Estimations of Algorithmic Complexity

Author

Fernando Soler-Toscano, Narsis A. Kiani, Hector Zenil, Jesper Tegnér, Santiago Hernández-Orozco, Antonio Rueda-Toicen, Universidad de Sevilla. Departamento de Filosofía y Lógica y Filosofía de la Ciencia, and Swedish Research Council

Subjects

Information theory, Computer science, Thue–Morse sequence, General Physics and Astronomy, lcsh:Astrophysics, 02 engineering and technology, information content, Article, law.invention, algorithmic randomness, law, lcsh:QB460-466, 0202 electrical engineering, electronic engineering, information engineering, π, Kolmogorov–Chaitin complexity, MATLAB, lcsh:Science, computer.programming_language, information theory, Lossless compression, Shannon entropy, 020206 networking & telecommunications, Pascal (programming language), Python (programming language), algorithmic probability, lcsh:QC1-999, Algorithmic randomness, Calculator, Algorithmic probability, 020201 artificial intelligence & image processing, lcsh:Q, Information content, Perl, computer, Algorithm, lcsh:Physics

Abstract

We investigate the properties of a Block Decomposition Method (BDM), which extends the power of a Coding Theorem Method (CTM) that approximates local estimations of algorithmic complexity based on Solomonoff–Levin’s theory of algorithmic probability providing a closer connection to algorithmic complexity than previous attempts based on statistical regularities such as popular lossless compression schemes. The strategy behind BDM is to find small computer programs that produce the components of a larger, decomposed object. The set of short computer programs can then be artfully arranged in sequence so as to produce the original object. We show that the method provides efficient estimations of algorithmic complexity but that it performs like Shannon entropy when it loses accuracy. We estimate errors and study the behaviour of BDM for different boundary conditions, all of which are compared and assessed in detail. The measure may be adapted for use with more multi-dimensional objects than strings, objects such as arrays and tensors. To test the measure we demonstrate the power of CTM on low algorithmic-randomness objects that are assigned maximal entropy (e.g., π) but whose numerical approximations are closer to the theoretical low algorithmic-randomness expectation. We also test the measure on larger objects including dual, isomorphic and cospectral graphs for which we know that algorithmic randomness is low. We also release implementations of the methods in most major programming languages—Wolfram Language (Mathematica), Matlab, R, Perl, Python, Pascal, C++, and Haskell—and an online algorithmic complexity calculator. Swedish Research Council (Vetenskapsrådet)

Published

2018

6. A Review of Graph and Network Complexity from an Algorithmic Information Perspective

Author

Narsis A. Kiani, Jesper Tegnér, and Hector Zenil

Subjects

Network complexity, Theoretical computer science, Computer science, General Physics and Astronomy, lcsh:Astrophysics, Review, Kolmogorov-Chaitin complexity, 01 natural sciences, 010305 fluids & plasmas, algorithmic randomness, 0103 physical sciences, lcsh:QB460-466, Entropy (information theory), Invariant (mathematics), 010306 general physics, lcsh:Science, algorithmic information theory, Lossless compression, Algorithmic information theory, complex networks, Complex network, algorithmic probability, lcsh:QC1-999, biological networks, lcsh:Q, Algorithmic probability, Biological network, lcsh:Physics

Abstract

Information-theoretic-based measures have been useful in quantifying network complexity. Here we briefly survey and contrast (algorithmic) information-theoretic methods which have been used to characterize graphs and networks. We illustrate the strengths and limitations of Shannon’s entropy, lossless compressibility and algorithmic complexity when used to identify aspects and properties of complex networks. We review the fragility of computable measures on the one hand and the invariant properties of algorithmic measures on the other demonstrating how current approaches to algorithmic complexity are misguided and suffer of similar limitations than traditional statistical approaches such as Shannon entropy. Finally, we review some current definitions of algorithmic complexity which are used in analyzing labelled and unlabelled graphs. This analysis opens up several new opportunities to advance beyond traditional measures.

Published

2018