We extend previously proposed measures of complexity, emergence, and self-organization to continuous distributions using differential entropy. Given that the measures were based on Shannon’s information, the novel continuous complexity measures describe how a system’s predictability changes in terms of the probability distribution parameters. This allows us to calculate the complexity of phenomena for which distributions are known. We find that a broad range of common parameters found in Gaussian and scale-free distributions present high complexity values. We also explore the relationship between our measure of complexity and information adaptation
We study how statistical complexity depends on the system size and how the complexity of the whole s...
The aim of the thesis is to define, develop, and consider applications of different measures of dyna...
We review several statistical complexity measures proposed over the last decade and a half as genera...
Since the second half of the last century, the concept of complexity has been studied to find and co...
This is the first release of our functions to measure complexity of discrete and continuous probabil...
This paper is part of a series addressing the empirical/statistical distribution of the diversity of...
We construct a complexity measure from first principles, as an average over the ‘‘obstruction agains...
Many complexity measures are defined as the size of a minimal representation in a specific model cla...
A generalized Statistical Complexity Measure (SCM) is a functional that characterizes the probabilit...
Measuring the complexity of dynamical systems is important in order to classify them and better unde...
One of the most popular methods of estimating the complexity of networks is to measure the entropy o...
The initial ideas regarding measuring complexity appeared in computer science, with the concept of c...
There is no single universally accepted definition of `Complexity'. There are several perspectives o...
Measures of entropy have been widely used to characterize complexity, particularly in physiological ...
Time series from chaotic and stochastic systems shape properties which can make it hard to distingui...
We study how statistical complexity depends on the system size and how the complexity of the whole s...
The aim of the thesis is to define, develop, and consider applications of different measures of dyna...
We review several statistical complexity measures proposed over the last decade and a half as genera...
Since the second half of the last century, the concept of complexity has been studied to find and co...
This is the first release of our functions to measure complexity of discrete and continuous probabil...
This paper is part of a series addressing the empirical/statistical distribution of the diversity of...
We construct a complexity measure from first principles, as an average over the ‘‘obstruction agains...
Many complexity measures are defined as the size of a minimal representation in a specific model cla...
A generalized Statistical Complexity Measure (SCM) is a functional that characterizes the probabilit...
Measuring the complexity of dynamical systems is important in order to classify them and better unde...
One of the most popular methods of estimating the complexity of networks is to measure the entropy o...
The initial ideas regarding measuring complexity appeared in computer science, with the concept of c...
There is no single universally accepted definition of `Complexity'. There are several perspectives o...
Measures of entropy have been widely used to characterize complexity, particularly in physiological ...
Time series from chaotic and stochastic systems shape properties which can make it hard to distingui...
We study how statistical complexity depends on the system size and how the complexity of the whole s...
The aim of the thesis is to define, develop, and consider applications of different measures of dyna...
We review several statistical complexity measures proposed over the last decade and a half as genera...