University of Hertfordshire

By the same authors

Informational parasites in code evolution

Research output: Contribution to conferencePaperpeer-review

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Informational parasites in code evolution. / Burgos, Andres C.; Polani, D.

2015. Paper presented at 13th European Conf on Artificial Life (ECAL 2015), York, United Kingdom.

Research output: Contribution to conferencePaperpeer-review

Harvard

Burgos, AC & Polani, D 2015, 'Informational parasites in code evolution', Paper presented at 13th European Conf on Artificial Life (ECAL 2015), York, United Kingdom, 20/07/15 - 24/07/15.

APA

Burgos, A. C., & Polani, D. (2015). Informational parasites in code evolution. Paper presented at 13th European Conf on Artificial Life (ECAL 2015), York, United Kingdom.

Vancouver

Burgos AC, Polani D. Informational parasites in code evolution. 2015. Paper presented at 13th European Conf on Artificial Life (ECAL 2015), York, United Kingdom.

Author

Burgos, Andres C. ; Polani, D. / Informational parasites in code evolution. Paper presented at 13th European Conf on Artificial Life (ECAL 2015), York, United Kingdom.8 p.

Bibtex

@conference{00543dbf1dad434e8e5abdfa9e847c94,
title = "Informational parasites in code evolution",
abstract = "In a previous study, we considered an information-theoretic model of code evolution. In it, agents obtain information about their (common) environment by the perception of messages of other agents, which is determined by an interaction probability (the structure of the population). For an agent to understand another agent's messages, the former must either know the identity of the latter, or the code producing the messages must be universally interpretable. A universal code, however, introduces a vulnerability: a parasitic entity can take advantage of it. Here, we investigate this problem. In our specific setting, we consider a parasite to be an agent that tries to inflict as much damage as possible in the mutual understanding of the population (i.e. the parasite acts as a disinformation agent). We show that, after introducing a parasite in the population, the former adopts a code such that it captures the information about the environment that is missing in the population. Such agent would be of great value, but only if the rest of the population could understand its messages. However, it is of little use here, since the parasite utilises the most common messages in the population to express different concepts. Now we let the population respond by updating their codes such that, in this arms race, they again maximise their mutual understanding. As a result, there is a code drift in the population where the utilisation of the messages of the parasite is avoided. A consequence of this is that the information that the parasite possesses but the agents lack becomes understandable and readily available.",
keywords = "cs.MA",
author = "Burgos, {Andres C.} and D. Polani",
note = "Andres C. Burgos, Daniel Polani, {\textquoteleft}Informational parasites in code evolution{\textquoteright}, paper presented at the 13th European Conference on Artificial Life (ECAL 2015), York, UK, 20-24 July, 2015. ; 13th European Conf on Artificial Life (ECAL 2015) ; Conference date: 20-07-2015 Through 24-07-2015",
year = "2015",
month = may,
day = "1",
language = "English",

}

RIS

TY - CONF

T1 - Informational parasites in code evolution

AU - Burgos, Andres C.

AU - Polani, D.

N1 - Andres C. Burgos, Daniel Polani, ‘Informational parasites in code evolution’, paper presented at the 13th European Conference on Artificial Life (ECAL 2015), York, UK, 20-24 July, 2015.

PY - 2015/5/1

Y1 - 2015/5/1

N2 - In a previous study, we considered an information-theoretic model of code evolution. In it, agents obtain information about their (common) environment by the perception of messages of other agents, which is determined by an interaction probability (the structure of the population). For an agent to understand another agent's messages, the former must either know the identity of the latter, or the code producing the messages must be universally interpretable. A universal code, however, introduces a vulnerability: a parasitic entity can take advantage of it. Here, we investigate this problem. In our specific setting, we consider a parasite to be an agent that tries to inflict as much damage as possible in the mutual understanding of the population (i.e. the parasite acts as a disinformation agent). We show that, after introducing a parasite in the population, the former adopts a code such that it captures the information about the environment that is missing in the population. Such agent would be of great value, but only if the rest of the population could understand its messages. However, it is of little use here, since the parasite utilises the most common messages in the population to express different concepts. Now we let the population respond by updating their codes such that, in this arms race, they again maximise their mutual understanding. As a result, there is a code drift in the population where the utilisation of the messages of the parasite is avoided. A consequence of this is that the information that the parasite possesses but the agents lack becomes understandable and readily available.

AB - In a previous study, we considered an information-theoretic model of code evolution. In it, agents obtain information about their (common) environment by the perception of messages of other agents, which is determined by an interaction probability (the structure of the population). For an agent to understand another agent's messages, the former must either know the identity of the latter, or the code producing the messages must be universally interpretable. A universal code, however, introduces a vulnerability: a parasitic entity can take advantage of it. Here, we investigate this problem. In our specific setting, we consider a parasite to be an agent that tries to inflict as much damage as possible in the mutual understanding of the population (i.e. the parasite acts as a disinformation agent). We show that, after introducing a parasite in the population, the former adopts a code such that it captures the information about the environment that is missing in the population. Such agent would be of great value, but only if the rest of the population could understand its messages. However, it is of little use here, since the parasite utilises the most common messages in the population to express different concepts. Now we let the population respond by updating their codes such that, in this arms race, they again maximise their mutual understanding. As a result, there is a code drift in the population where the utilisation of the messages of the parasite is avoided. A consequence of this is that the information that the parasite possesses but the agents lack becomes understandable and readily available.

KW - cs.MA

M3 - Paper

T2 - 13th European Conf on Artificial Life (ECAL 2015)

Y2 - 20 July 2015 through 24 July 2015

ER -