This article focuses on communication systems following Zipf’s law, in a study of the rel-ationship between the properties of those communication systems and the exponent of the law. The properties of communication systems are described using quantitative measures of semantic vagueness and the cost of word use. The precision and the economy of a communication system is reduced to a function of the exponent of Zipf’s law and the size of the communication system. Taking the exponent of the frequency spectrum, it is demonstrated that semantic precision grows with the exponent, where-as the cost of word use reaches a global minimum between 1.5 and 2, if the size of the communication system remains constant. The exponent of Zipf’s law is shown t...
Here we study a communication model where signals associate to stimuli. The model assumes that signa...
Word frequencies in a text follow a curious pattern. A few of them appear extremely frequently, whil...
Zipf's law states that the frequency of a word is a power function of its rank. The exponent of the ...
This article focuses on communication systems following Zipf’s law, in a study of the rel-ationship ...
It is well-known that word frequencies arrange themselves according to Zipf's law. However, little i...
It is hard to imagine how the development of quantitative linguistics would have been after G.K. Zi...
Here we present a new model for Zipf's law in human word frequencies. The model defines the goal and...
Zipf’s Law is an empirical law according to which the frequency of occurrence of a word in a corpus ...
Copyright: © 2015 Salge et al. This is an open access article distributed under the terms of the Cre...
Zipf’s law is a mathematically relatively simple formula stating that the frequency of a word is inv...
H. Simon proposed a simple stochastic process for explaining Zipf’s law for word frequencies. Here w...
Zipf's law seems to be ubiquitous in human languages and appears to be a universal property of compl...
In his pioneering research, G.K. Zipf observed that more frequent words tend to have more meanings, ...
According to Zipf’s meaning-frequency law, words that are more frequent tend to have more meanings. ...
A family of information theoretic models of communication was introduced more than a decade ago to e...
Here we study a communication model where signals associate to stimuli. The model assumes that signa...
Word frequencies in a text follow a curious pattern. A few of them appear extremely frequently, whil...
Zipf's law states that the frequency of a word is a power function of its rank. The exponent of the ...
This article focuses on communication systems following Zipf’s law, in a study of the rel-ationship ...
It is well-known that word frequencies arrange themselves according to Zipf's law. However, little i...
It is hard to imagine how the development of quantitative linguistics would have been after G.K. Zi...
Here we present a new model for Zipf's law in human word frequencies. The model defines the goal and...
Zipf’s Law is an empirical law according to which the frequency of occurrence of a word in a corpus ...
Copyright: © 2015 Salge et al. This is an open access article distributed under the terms of the Cre...
Zipf’s law is a mathematically relatively simple formula stating that the frequency of a word is inv...
H. Simon proposed a simple stochastic process for explaining Zipf’s law for word frequencies. Here w...
Zipf's law seems to be ubiquitous in human languages and appears to be a universal property of compl...
In his pioneering research, G.K. Zipf observed that more frequent words tend to have more meanings, ...
According to Zipf’s meaning-frequency law, words that are more frequent tend to have more meanings. ...
A family of information theoretic models of communication was introduced more than a decade ago to e...
Here we study a communication model where signals associate to stimuli. The model assumes that signa...
Word frequencies in a text follow a curious pattern. A few of them appear extremely frequently, whil...
Zipf's law states that the frequency of a word is a power function of its rank. The exponent of the ...