Abstract:For decoding information contained in the cochlea neural networks responses to speech signals, it is interesting to address which parts of input stimuli are more efficient. In this paper, the stimulus-specific information associated with a particular stimulus will be adopted to study the decrease of average uncertainties, and its calculation method is developed. We use a leaky integrate-and-fire model to capture the responses of cochlea neurons to the input speech signal, and calculate the stimulus-specific information caused by each speech signal part. It is shown that the weighted average of stimulus-specific information over the stimulus ensembles yields the mutual information, and the stimulus-specific information is also useful in clearly indentifying the stimuli that are significantly efficient to the cochlea neural network. Moreover, the stimulus-specific information can not only determine which signal component mainly contributes to the mutual information, but also confirms the availability of internal noise in the neural networks. There is a non-monotonic relationship between the noise intensity and the maximum stimulus-specific information. These results indicate that the applicability of the integrate-and-fire neuron model for current cochlear implant decoding technology deserves to be further investigated.
王风娇, 任昱昊, 赵进, 段法兵. 耳蜗神经网络中语音信号传输的刺激条件信息研究[J]. 复杂系统与复杂性科学, 2015, 12(4): 104-108.
WANG Fengjiao, REN Yuhao, ZHAO Jin, DUAN Fabing. Study of Specific-Stimulus Information for Transmission of Speech Signals in Cochlea Neural Networks[J]. Complex Systems and Complexity Science, 2015, 12(4): 104-108.
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