中文

Microsecond-precision sound localization emerges from slow equilibrium dynamics

神经元与认知 2026-07-04 v1

摘要

Precise sound localization relies on microsecond sensitivity to interaural time differences (ITDs), yet binaural perception exhibits sluggish tracking of dynamic acoustic cues. How these properties coexist remains unresolved. Here, ITD is represented as a stable equilibrium of neural population dynamics rather than by the classical place-coding framework originally proposed by Jeffress in 1948. In this framework, excitatory and inhibitory interactions across frequency channels generate a population signal that drives a dynamical system toward an equilibrium corresponding to the estimated ITD. Despite relying on relatively slow temporal dynamics, the model achieves microsecond-level precision and reproduces key physiological observations, including frequency-dependent best-delay distributions, without requiring explicit delay lines or precisely timed inhibition. These findings provide a potential explanation for how precise ITD sensitivity can arise from slow neural dynamics.

引用

@article{arxiv.2607.03890,
  title  = {Microsecond-precision sound localization emerges from slow equilibrium dynamics},
  author = {Toshio Irino},
  journal= {arXiv preprint arXiv:2607.03890},
  year   = {2026}
}

备注

This manuscript was submitted to Science on July 4, 2026