Abstract
We bridge the gap between two issues in infant development: vocal development and intrinsic motivation. We propose and experimentally test the hypothesis that general mechanisms of intrinsically motivated spontaneous exploration, also called curiosity-driven learning, can self-organize developmental stages during early vocal learning. We introduce a computational model of intrinsically motivated vocal exploration, which allows the learner to autonomously structure its own vocal experiments, and thus its own learning schedule, through a drive to maximize competence progress. This model relies on a physical model of the vocal tract, the auditory system and the agent's motor control as well as vocalizations of social peers. We present computational experiments that show how such a mechanism can explain the adaptive transition from vocal self-exploration with little influence from the speech environment, to a later stage where vocal exploration becomes influenced by vocalizations of peers. Within the initial self-exploration phase, we show that a sequence of vocal production stages self-organizes, and shares properties with data from infant developmental psychology: the vocal learner first discovers how to control phonation, then focuses on vocal variations of unarticulated sounds, and finally automatically discovers and focuses on babbling with articulated proto-syllables. As the vocal learner becomes more proficient at producing complex sounds, imitating vocalizations of peers starts to provide high learning progress explaining an automatic shift from self-exploration to vocal imitation.
Highlights
We show how a cognitive architecture for intrinsically motivated autonomous exploration (SAGG-RIAC; Baranes and Oudeyer, 2013; Moulin-Frier and Oudeyer, 2013a), applied to learning to control an articulatory synthesizer, can self-organize coherent vocal developmental sequences
We describe the learning of the internal model of the sensorimotor mapping, and the intrinsic motivation mechanism which allows the learner to decide adaptively which vocalization to experiment at given moments during its development, and whether to do so through self-exploration or through imitation of external sounds
Our main contribution with respect to previous computational models of speech acquisition is that we do not presuppose the existence of successive developmental stages, but rather they can emerge from an intrinsic drive to maximize the competence progress
Summary
] the child seemed to take pleasure in making sounds.” (Sigismund, 1971) “[He] first made the sound mm spontaneously by blowing noisily with closed lips. This amused [him] and was a discovery for [him].”1 (Taine, 1971). A key idea of recent approaches to intrinsic motivation is that learning progress in sensorimotor activities can generate intrinsic rewards in and for itself, and drive such spontaneous exploration (Gottlieb et al, 2013). Learning progress refers to the infant’s improvement of his predictions or control over activity they practice, which can be described as reduction of uncertainty (Friston et al, 2012)
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