Abstract: A method is described for generating electrode stimulation signals for an implanted electrode array. An acoustic audio signal is processed to generate band pass signals each representing an associated band of audio frequencies. Stimulation information is extracted from the band pass signals to generate stimulation event signals defining electrode stimulation signals. The stimulation event signals are mapped according to independent channel-specific loudness functions to produce a set of electrode stimulation signals within channel-specific minimum and maximum threshold levels. The electrode stimulation signals are developed into a set of output electrode pulses to the electrodes in the implanted electrode array.

Abstract: A method is described for generating electrode stimulation signals for an implanted electrode array. An acoustic audio signal is processed to generate band pass signals each representing an associated band of audio frequencies. Stimulation information is extracted from the band pass signals to generate stimulation event signals defining electrode stimulation signals. The stimulation event signals are weighted according to independent channel-specific loudness functions to produce a set of electrode stimulation signals within channel-specific minimum and maximum threshold levels. The electrode stimulation signals are developed into a set of output electrode pulses to the electrodes in the implanted electrode array.

Abstract: Generation of electrode stimulation signals for an implanted electrode array is described. An acoustic audio signal is processed to generate band pass signals which include a fine structure carrier signal and a modulator envelope signal. For each band pass signal, fine time structure information is extracted from the carrier signal to determine a sequence of stimulation event signals. For one or more low frequency band pass signals, the modulator envelope signal is sampled synchronously with the carrier signal to create envelope weighted stimulation event signals. For one or more higher frequency band pass signals, if and only if the modulator envelope signal exceeds a sampling threshold value, then the modulator envelope signal is sampled synchronously with the carrier signal to create envelope weighted stimulation event signals. The envelope weighted stimulation event signals are then processed to produce electrode stimulation signals for the implanted electrode array.

Abstract: A system and method for activating electrodes in an implanted electrode array with a stimulation signal is described. A stimulation definition stage, for each of a plurality of defined sound signal characteristics (C), assigns each electrode to one of a plurality of stimulation groups (G) each having an associated group stimulation amplitude function (A), where (G) varies with (C). An electrode stimulator activates each electrode as the stimulation signal varies based on spectral components of the stimulation signal.

Abstract: Generating electrode stimulation signals is described for stimulating cochlear tissue using an implanted electrode array. An acoustic audio signal is processed to generate band pass signals which represent an associated band of audio frequencies. Stimulation information is extracted from the band pass signals to generate stimulation event signals that define electrode stimulation signals. The stimulation event signals are then weighted according independent channel-specific loudness functions to produce electrode stimulation signals. The electrode stimulation signals are developed into output electrode pulses to the electrodes in the implanted electrode array for stimulating cochlear tissue.

Abstract: A system and method for activating stimulation electrodes in cochlear implant electrode is described. A preprocessor filter bank processes an input acoustic audio signal to generate band pass signals that each represent an associated band of audio frequencies. An information extractor extracts stimulation signal information from the band pass signals based on assigning the band pass signals to corresponding electrode stimulation groups that each contain one or more stimulation electrodes, and generates a set of stimulation event signals for each electrode stimulation group that define electrode stimulation timings and amplitudes. A pulse selector selects a set of electrode stimulation signals from the stimulation event signals based on a pulse weighting function that uses channel-specific weighting factors favoring lower frequencies for activating the stimulation electrodes to stimulate neighboring audio nerve tissue.

Abstract: A method of developing a weighting matrix for a cochlear implant patient is described. An electrode stimulus signal is derived from a first musical signal. A set of further stimulus signals is derived that have a defined musical relation to the first musical signal. A set of weighting values are selected for the stimulation electrodes for the electrode stimulus signal. Then the weighting values are set for the stimulation electrodes for each of the further stimulus signals. Each of the stimulus signals is consecutively presented to the patient and the weighting values individually adjusted for each of the further stimulus signals until the series of stimulus signals elicits an increasing pitch percept according to the defined musical relation. The adjusted weighting values are stored and assigned to a corresponding analysis channel.

Abstract: Generation of electrode stimulation signals for an implanted electrode array is described. An acoustic audio signal is processed to generate band pass signals which include a fine structure carrier signal and a modulator envelope signal. For each band pass signal, fine time structure information is extracted from the carrier signal to determine a sequence of stimulation event signals. For one or more low frequency band pass signals, the modulator envelope signal is sampled synchronously with the carrier signal to create envelope weighted stimulation event signals. For one or more higher frequency band pass signals, if and only if the modulator envelope signal exceeds a sampling threshold value, then the modulator envelope signal is sampled synchronously with the carrier signal to create envelope weighted stimulation event signals. The envelope weighted stimulation event signals are then processed to produce electrode stimulation signals for the implanted electrode array.

Abstract: A method is described for generating electrode stimulation signals for a plurality of stimulation electrodes in an implanted electrode array. An acoustic audio signal is processed with a bank of filters to generate a set of band pass signals where each band pass signal corresponds to a band of audio frequencies associated with one of the filters. A lateral suppression network is used to perform channel specific dynamic amplitude mapping of the band pass signals to generate a set of compressed band pass signals. Stimulation information is extracted from the compressed band pass signals to generate a set of stimulation timing signals, and the stimulation timing signals are developed into a set of electrode stimulation signals to the stimulation electrodes.

Abstract: Generating electrode stimulation signals for an implanted electrode array is described. An acoustic audio signal is processed to generate band pass signals which represent associated bands of audio frequencies. Macro bands are defined, each of which characterizes multiple band pass signals. The macro bands are processed in a sequence of sampling intervals. For each sampling interval, the processing includes: i. extracting timing and energy information from each band pass signal to form requested stimulation events, ii. decimating the requested stimulation events to select a maximum energy band pass signal within each macro band, and iii. decimating each selected band pass signal based on a pulse selection inhibition function and preserving temporal and spectral structures of the band pass signals so as to generate stimulation event signals.

Abstract: Electrode stimulation signals are generated for an implanted electrode array. An acoustic audio signal is processed with a bank of filters that are each associated with a band of audio frequencies, and a set of band pass signals is generated with each band pass signal corresponding to the band of frequencies associated with one of the filters. Stimulation information is extracted from the band pass signals to generate a set of stimulation event signals defining electrode stimulation signals. Then the stimulation event signals are weighted with a weighted matrix of stimulation amplitudes reflecting patient-specific perceptual characteristics to produce a set of electrode stimulation signals for electrodes in the implanted electrode array.

Abstract: An implantable device includes a multi-channel electrode array in which each channel is associated with an electrode in the array. An audio processing stage processes an input audio signal to produce output channel signals representing associated bands of audio frequencies. A timing and envelope detector processes the output channel signals in a sequence of sampling intervals, including, for each sampling interval, determining for each output channel signal: i. a set of requested pulse timings containing a plurality of pulse timing requests, and ii. a set of corresponding envelope signals representing pulse magnitude for pulse timing requests. A pulse selection amplitude definition stage determines for each set of requested pulse timings: i. a set of output pulses at specified times selected from the set of requested pulse timings based on a pulse selection inhibition function, and ii. a stimulation amplitude associated with each output pulse.

Abstract: A system and method for activating electrodes in an implanted electrode array with a stimulation signal is described. A stimulation definition stage, for each of a plurality of defined sound signal characteristics (C), assigns each electrode to one of a plurality of stimulation groups (G) each having an associated group stimulation amplitude function (A), where (G) varies with (C). An electrode stimulator activates each electrode as the stimulation signal varies based on spectral components of the stimulation signal.