Your search keyword '"Kaibao Nie"' showing total 3 results

1. An Experimental Vestibular Neural Prosthesis: Design and Preliminary Results With Rhesus Monkeys Stimulated With Modulated Pulses

Author

Kaibao Nie, Albert F. Fuchs, Jay T. Rubinstein, James O. Phillips, Steven M. Bierer, Leo Ling, Chris R. S. Kaneko, and Trey Oxford

Subjects

Eye Movements, medicine.medical_treatment, Biomedical Engineering, Nystagmus, Prosthesis Design, Implants, Experimental, Cochlear implant, otorhinolaryngologic diseases, medicine, Animals, Modulation pattern, Electrodes, Evoked Potentials, Vestibular system, Pulse (signal processing), business.industry, Neural Prosthesis, Eye movement, Signal Processing, Computer-Assisted, Vestibular nerve, Macaca mulatta, Electric Stimulation, Cochlear Implants, Vestibule, Labyrinth, sense organs, medicine.symptom, business, Biomedical engineering

Abstract

A vestibular neural prosthesis was designed on the basis of a cochlear implant for treatment of Meniere's disease and other vestibular disorders. Computer control software was developed to generate patterned pulse stimuli for exploring optimal parameters to activate the vestibular nerve. Two rhesus monkeys were implanted with the prototype vestibular prosthesis and they were behaviorally evaluated post implantation surgery. Horizontal and vertical eye movement responses to patterned electrical pulse stimulations were collected on both monkeys. Pulse amplitude modulated (PAM) and pulse rate modulated (PRM) trains were applied to the lateral canal of each implanted animal. Robust slow-phase nystagmus responses following the PAM or PRM modulation pattern were observed in both implanted monkeys in the direction consistent with the activation of the implanted canal. Both PAM and PRM pulse trains can elicit a significant amount of in-phase modulated eye velocity changes and they could potentially be used for efficiently coding head rotational signals in future vestibular neural prostheses.

Published

2013

2. Encoding Frequency Modulation to Improve Cochlear Implant Performance in Noise

Author

Fan-Gang Zeng, Ginger S. Stickney, and Kaibao Nie

Subjects

Sound Spectrography, Computer science, Speech recognition, medicine.medical_treatment, Acoustics, Speech coding, Biomedical Engineering, Information Storage and Retrieval, Prosthesis Design, Sensitivity and Specificity, Amplitude modulation, symbols.namesake, Cochlear implant, otorhinolaryngologic diseases, medicine, Humans, Active listening, Center frequency, Stochastic Processes, Signal processing, Analog transmission, Reproducibility of Results, Signal Processing, Computer-Assisted, Speech processing, Equipment Failure Analysis, Noise, Cochlear Implants, Amplitude, Fourier analysis, QUIET, Speech Perception, symbols, Frequency modulation, Algorithms

Abstract

Different from traditional Fourier analysis, a signal can be decomposed into amplitude and frequency modulation components. The speech processing strategy in most modern cochlear implants only extracts and encodes amplitude modulation in a limited number of frequency bands. While amplitude modulation encoding has allowed cochlear implant users to achieve good speech recognition in quiet, their performance in noise is severely compromised. Here, we propose a novel speech processing strategy that encodes both amplitude and frequency modulations in order to improve cochlear implant performance in noise. By removing the center frequency from the subband signals and additionally limiting the frequency modulation's range and rate, the present strategy transforms the fast-varying temporal fine structure into a slowly varying frequency modulation signal. As a first step, we evaluated the potential contribution of additional frequency modulation to speech recognition in noise via acoustic simulations of the cochlear implant. We found that while amplitude modulation from a limited number of spectral bands is sufficient to support speech recognition in quiet, frequency modulation is needed to support speech recognition in noise. In particular, improvement by as much as 71 percentage points was observed for sentence recognition in the presence of a competing voice. The present result strongly suggests that frequency modulation be extracted and encoded to improve cochlear implant performance in realistic listening situations. We have proposed several implementation methods to stimulate further investigation. Index Terms-Amplitude modulation, cochlear implant, fine structure, frequency modulation, signal processing, speech recognition, temporal envelope.

Published

2005

3. A Novel Speech-Processing Strategy Incorporating Tonal Information for Cochlear Implants

Author

Shangkai Gao, Ning Lan, Kaibao Nie, and Fan-Gang Zeng

Subjects

China, Speech perception, Computer science, medicine.medical_treatment, Speech recognition, Biomedical Engineering, Intelligibility (communication), Prosthesis Design, Signal, Pattern Recognition, Automated, Pitch Discrimination, Hearing, Cochlear implant, otorhinolaryngologic diseases, medicine, Humans, Language, Signal processing, Speech Intelligibility, Tonal language, Signal Processing, Computer-Assisted, Fundamental frequency, Speech processing, Equipment Failure Analysis, Cochlear Implants, Speech Perception, Neural Networks, Computer, Frequency modulation, Algorithms

Abstract

Good performance in cochlear implant users depends in large part on the ability of a speech processor to effectively decompose speech signals into multiple channels of narrow-band electrical pulses for stimulation of the auditory nerve. Speech processors that extract only envelopes of the narrow-band signals (e.g., the continuous interleaved sampling (CIS) processor) may not provide sufficient information to encode the tonal cues in languages such as Chinese. To improve the performance in cochlear implant users who speak tonal language, we proposed and developed a novel speech-processing strategy, which extracted both the envelopes of the narrow-band signals and the fundamental frequency (F/sub 0/) of the speech signal, and used them to modulate both the amplitude and the frequency of the electrical pulses delivered to stimulation electrodes. We developed an algorithm to extract the fundamental frequency and identified the general patterns of pitch variations of four typical tones in Chinese speech. The effectiveness of the extraction algorithm was verified with an artificial neural network that recognized the tonal patterns from the extracted F/sub 0/ information. We then compared the novel strategy with the envelope-extraction CIS strategy in human subjects with normal hearing. The novel strategy produced significant improvement in perception of Chinese tones, phrases, and sentences. This novel processor with dynamic modulation of both frequency and amplitude is encouraging for the design of a cochlear implant device for sensorineurally deaf patients who speak tonal languages.

Published

2004