Graeme Clark Collection
Permanent URI for this collection
Search Results
1 - 10 of 15
-
ItemManikin and cochlear implant patient test results with a portable adaptive beamforming processor to suppress the effects of noise( 1995)A simple adaptive beamformer (ABF) was implemented in a real-time portable speech processor and tested with four cochlear implant patients. The ABF algorithm used signals from only two microphones - one behind each ear - to attenuate sounds not arriving from the direction directly in front of the patient, and was compared with a strategy in which the two microphone signals were simply added together (two-microphone broadside strategy). Tests with the four patients were conducted in quiet and in noise. Results at a 0 dB signal-to-noise ratio showed large improvements in speech intelligibility for all patients, when compared to the two-microphone broadside strategy. Physical measurement of the directional characteristics of the ABF processor were made with a Kemar manikin. The effects of reverberation were explored by placing the manikin in different acoustic environments and observing the attenuation of the noise alone at various angles. A near-anechoic environment allowed the noise to be attenuated by as much as 21 dB, whereas in a highly reverberant concrete stairwell, the ABF processor was unable to provide any directional gain beyond about 3 dB.
-
ItemArchitecture of the Spectra 22 speech processor( 1995)The Spectra 22 is a logical extension in the development of the speech processing for the Cochlear Mini 22 system. It can implement the new coding strategy (Speak) that has provided significant improvement in patient benefit.
-
ItemEvaluation of a portable two-microphone adaptive beamforming speech processor with cochlear implant patients( 1995)Abstract not available due to copyright.
-
ItemA review of the biological, psychophysical, and speech processing principles used to design the tickle talker( 1992)The Tickle Talker is a wearable electrotactile speech processor, designed to be used by profoundly hearing-impaired children and adults in conjunction with lipreading and residual hearing. The effectiveness of such a device is affected by an interaction between biological, human engineering, psychophysical, and speech processing considerations. The requirements, the design principles, and the performance of the Tickle Talker in each of these areas will be discussed. Electrical stimulation of the nerve bundles lying along the sides of the fingers was chosen to provide safe, comfortable, energy-efficient stimulation of a well-organised and sensitive part of the tactile sensory system. This is achieved at a small cost to the appearance and mobility of one hand when using the Tickle Talker. The biphasic pulse waveform used to stimulate the nerve bundles has been chosen to ensure a biologically safe stimulus. The electrical parameters (pulse duration, pulse rate, and electrode position) that are used to encode speech information are varied within ranges that are matched to the characteristics of the tactile sense. The usable ranges and information-carrying potential of each of these parameters have been assessed in psychophysical experiments. A comparison of these results with similar experimental data for cochlear implant and hearing aid users is instructive in assessing the possible limitations of tactile and auditory speech processors. The results discussed will include the discrimination and identification of stimuli differing in intensity, duration and pulse rate; the identification of different spatial patterns of stimulation, and the detection of gaps in stimuli. In most respects, the tactile results are similar to the corresponding auditory measures. The resolution of temporal differences such as pulse rate discrimination or gap detection are generally not as good as in the auditory case, but may be as good or better than the corresponding results for some profoundly hearing-impaired individuals. The speech processor used in the Tickle Talker is a "feature extraction" device that explicitly estimates the second formant frequency, amplitude envelope, and fundamental frequency of the voice and encodes them in terms of electrode position, pulse width and pulse rate of the electrical stimulation pattern. Consideration of the psychophysical results and the speech information available from these parameters allows optimization of the Tickle Talker's operation and a broad estimation of its potential performance in speech discrimination. The perception of duration and place of articulation (front/back) of vowels, and the manner and voicing of consonants are expected to be improved by the Tickle Talker. Prosodic variations conveyed by pulse rate are expected to be perceived by some users, but not all. High frequency consonants such as: /s/,/z/./?/, and /t?/ are encoded in a particularly salient manner by the Tickle Talker.
-
ItemDesign fundamentals for a tactile speech processor: i) encoding of speech information, and ii) biomedical safety considerations [Abstract]( 1992)Approaches to providing speech information through the tactual modality have varied in: number and spatial location of transducers; method of interfacing with the skin's sensory apparatus; and content of speech information presented. Use of a multiple speech feature encoding approach to design of a tactile device was implemented in the wearable multichannel electrotactile speech processor or Tickle Talker developed at the University of Melbourne. Psychophysical studies established that subjects could discriminate salient electrical parameters in the tactual display, and that this information could be used to discriminate acoustic speech feature contrasts. Results with normally-hearing and hearing-impaired adults and children using an FOF2 encoding strategy showed improved discrimination scores for closed-set speech feature discrimination batteries, closed-set vowel and consonant identification tasks, as well as for open-set word and sentence comprehension. Based on analyses of tactual encoding of speech features, alternative speech processing strategies designed to increase the quality of speech information available were evaluated. Results for two hearing-impaired adults showed improved feature discrimination with the addition of a voicing signal to the FOF2 strategy. Biomedical safety investigations conducted concurrently have established that the electrical parameters of the stimulus waveform, electrode handset design, and electrical circuitry of the device are free from potential risks. Longer-term physiological assessments included measures of possible effects of electrical stimulation on tactual sensitivity, finger temperature, finger and hand blood flow, electrical thresholds and maximum comfortable levels, and on central nervous system, function as measured by EEG. Results of the kinesthetic, vascular and neurological assessments showed no significant contraindications which might limit application or long-term use of the device.
-
ItemClinical experience with the University of Melbourne multichannel electrotactile speech processor (Tickle Talker)( 1992)The Tickle Talker is a multiple channel electrotactile speech processor, developed for use by profoundly hearing-impaired adults and children. The device is intended to be used in combination with lipreading and aided residual hearing, to assist the greatest potential range of users. Sound detection and speech reception threshold levels for a group of 14 congenitally hearing-impaired children were shown to be lower when using the Tickle Talker than for hearing aids across the speech frequency range. Tactile-alone feature contrast testing with adults demonstrated that both segmental and suprasegmental speech feature information was available from the tactual display presented by the Tickle Talker. Clinical results from an ongoing program involving fourteen hearing-impaired children demonstrate benefits in speech perception achieved through use of the Tickle Talker. The children have a range of degree of hearing impairment and educational setting. Results show improvements in discrimination scores for vowel and consonant speech features, and increased scores for recognition of closed-set words and for open-set words and sentences. In addition, anecdotal evidence indicates changes in speech production which may be attributed to perceptual input from the device (both from perception of other speakers, and from voice self-monitoring). Results from a group of 4 adult patients show that tactile input may be effectively combined with either aided residual hearing, or aided residual hearing and lipreading to improve speech discrimination across a similar range of closed and open-set word and sentence tests and on speech tracking. The results indicate that some specific tailoring of the speech information provided through the device for the needs of users with differing degrees of hearing-impairment may be required to optimize potential benefits to speech discrimination.
-
ItemCombined electrical and acoustical stimulation using a bimodal prosthesis( 1993)A new device incorporating a cochlear implant speech processor and a speech-processing hearing aid for the un-implanted ear has been designed and tested with four severely hearing-impaired patients. The aim of the device is to provide a more acceptable and effective combination of electrical and acoustic signals to the two ears. When used monaurally, and binaurally in conjunction with the cochlear implant, the speech-processing hearing aid mean scores for open-set sentences, words, and consonants were as good as or better than the mean scores for the patients' own conventional hearing aids. Some patients improved much more than did others. Although not conclusive, these results are encouraging, especially as they were achieved with a laboratory prototype that did not allow the patients to become accustomed to the processor in everyday situations.
-
ItemThe development of the nucleus multiple-channel cochlear implant( 1993)Physiology, biology, psychophysics and speech research studies led to the development of the inaugural cue-extraction speech processing strategy used in the Nucleus multiple-channel cochlear implant. This resulted in postlinguistically deaf adults obtaining open-set word scores for electrical stimulation alone, as well as significant improvements in understanding running speech when electrical stimulation was combined with lip-reading. Further speech processing research has resulted in progressive improvements in speech perception for postlinguistically deaf adults. The improvements have principally involved presenting more spectral information on a place coding basis, but additional temporal information has also improved its performance. The cue-extraction or speech-feature strategies used with the multiple-channel implant have also been shown to provide postlinguistically and prelinguistically deaf children (two to 17 years of age) with significant help in communication. In the children, open-set speech scores are most frequently obtained in the youngest age groups, and with longer periods of auditory training.
-
ItemImplantation of the new CI-24M Cochlear Limited receiver-stimulator and its electrode array(Monduzzi Editore, 1997)Cochlear Limited has released the new CI-24M model Nucleus 24 electrode cochlear implant system encompassing a series of new features. It offers the potential for improvements in hearing and cosmesis, as well as telemetry.
-
ItemEffects of rate and pulse manipulations of the spectral maxima speech processor upon speech production( 1993)Postlingually deafened adults experience many changes in their speech as a consequence of late-onset deafness. Previous studies have indicated changes in fundamental frequency, duration, intensity, and vowel formant frequencies in postlingually deafened adults. Postlingually deafened adults who receive multichannel cochlear implants demonstrate improved control of fundamental frequency and intensity. Shifts in formant frequencies to values similar to normal hearing. speakers also appears in some adult implant users. In order to examine how adult implant users adjust their vowel production in response to map changes, we examined vowel production following manipulations to the processing strategy of the Spectral Maxima Speech Processor. This processor uses a speech processing scheme in which six spectral maxima from the outputss of 16 bandpass filters stimulate the cochlea on a place basis at a constant rate. The rate of sampling of the filterbank output is 250 Hz, so six biphasic pulses are presented every 4 msec and there is no attempt to extract fundamental frequency or to find the formant peaks in the speech signal. Two manipulations to the scheme were examined. In the first condition, the rate of sampling remained at 250Hz but eight biphasic pulses were presented rather than six. In the second condition, six biphasic pulses were presented but the rate of sampling of the filterbank output was increased to 400 Hz. Speech samples also were acquired using the standard spectral maxima processor .and with no auditory feedback when the processor was turned off. Speech samples from three �subjects were acquired immediately after receiving the manipulated speech processors and after two weeks experience with the various processors. Preliminary data indicate one subject experienced increased fundamental frequencies while using the 400 Hz high rate strategy. No significant changes were observed in fundamental frequency between the normal SMSP processor and the eight pulse variation. Elimination of feedback resulted in significantly lower fundamental frequencies. The high rate and eight pulse variations resulted in significantly higher first formant frequencies. Second formant frequencies also appear to be influenced by the processing strategies. Comparisons of values produced immediately after receiving a new strategy versus those produced after two weeks use show shifts in primarily first formant values. Data will be presented for all three subjects and discussed in regard to sensitivity to variations in speech processing schemes and the influence of experience with manipulated schemes. (Work supported by the N1H-NIDCD).