Abstract
Because of the parallels found with human language production and acquisition, birdsong is an ideal animal model to study general mechanisms underlying complex, learned motor behavior. The rich and diverse vocalizations of songbirds emerge as a result of the interaction between a pattern generator in the brain and a highly nontrivial nonlinear periphery. Much of the complexity of this vocal behavior has been understood by studying the physics of the avian vocal organ, particularly the syrinx. A mathematical model describing the complex periphery as a nonlinear dynamical system leads to the conclusion that nontrivial behavior emerges even when the organ is commanded by simple motor instructions: smooth paths in a low dimensional parameter space. An analysis of the model provides insight into which parameters are responsible for generating a rich variety of diverse vocalizations, and what the physiological meaning of these parameters is. By recording the physiological motor instructions elicited by a spontaneously singing muted bird and computing the model on a Digital Signal Processor in real-time, we produce realistic synthetic vocalizations that replace the bird's own auditory feedback. In this way, we build a bio-prosthetic avian vocal organ driven by a freely behaving bird via its physiologically coded motor commands. Since it is based on a low-dimensional nonlinear mathematical model of the peripheral effector, the emulation of the motor behavior requires light computation, in such a way that our bio-prosthetic device can be implemented on a portable platform.
Highlights
The complex motor behavior originating the rich vocalizations of adult oscine birds results from the interaction between a central pattern generator and a nonlinear biomechanical periphery [1,2]
In the Methods section we describe the Zebra finch vocal organ and the mathematical model that accounts for its dynamics
In order to produce realistic synthetic vocalizations, we introduce a model of the vocal tract as a dynamical system, which includes a tube approximating the trachea and a Helmholtz resonator to represent the oropharyngealesophageal cavity (OEC)
Summary
The complex motor behavior originating the rich vocalizations of adult oscine birds results from the interaction between a central pattern generator (the brain) and a nonlinear biomechanical periphery (the bird’s vocal organ) [1,2]. The complexity of its dynamics leaves traces in the sounds that can be produced in it In this way, several acoustic features found in vocalizations can be related to nonlinear phenomena occurring in the syrinx [4,5] or introduced by acoustic interactions between the syrinx and the tract [6,7,8,9]. The complexity of the behavior does not require a complex motor pattern to drive the vocal organ, but rather simple, smooth gestures
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
