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  • Poster presentation
  • Open Access

Theoretical derivation of EMOTION-I model for emotional feel of sensation

BMC Neuroscience20089 (Suppl 1) :P79

  • Published:


  • Evolutionary Process
  • Sensory Information
  • Autonomous System
  • Associative Learning
  • External World

The first of a series of emotional models called "Emotional Model of The Theoretical Interpretation Of Neuroprocessing" (EMOTION-I) is derived theoretically to address the origin of emotions in evolutionary process. It is based on first principles without any a priori assumptions about what emotions are and what they are used for. The model is derived based on the necessary principles essential for the survival of an autonomous system (either an organism or an autonomous robot) when interacting with the real-world environment. The contextual abstraction of sensory information provides the basis for the evolution of the emotional context of sensation, i.e., the "feel" in sensation. The emergency of the contextual feel in sensation within the context of the survivability of an autonomous system is derived from the biological principles using reinforcement associative learning to acquire the contextual representation of the external world. The principles of the criteria for hardwiring in reflexes are also derived, which allows for consolidation of the acquired knowledge with respect to the appropriate interaction between the autonomous system and the external world. This theoretical mechanism provides the foundation for the formation of innate ability to recognize pleasant and unpleasant sensation in autonomous systems [1]. This EMOTION-I model forms the pre-processor for the EMOTION-II model for deriving the happy and unhappy emotions.

Authors’ Affiliations

Department of Biological Sciences, University of North Texas, Denton, TX 76203, USA


  1. Tam D: EMOTION-I Model: A Biologically-Based Theoretical Framework for Deriving Emotional Context of Sensation in Autonomous Control Systems. The Open Cybernetics & Systemics Journal. 2007, 1: 28-46. 10.2174/1874110X00701010028. [http://]View ArticleGoogle Scholar


© Tam; licensee BioMed Central Ltd. 2008

This article is published under license to BioMed Central Ltd.