| P50 | author | Tobias Goehring | Q87740063 |
| | Sean R Mills | Q89475062 |
| | Mark D Fletcher | Q98725940 |
| P2860 | cites work | Electro-Tactile Stimulation Enhances Cochlear Implant Speech Recognition in Noise. | Q30355974 |
| | Speech enhancement based on neural networks improves speech intelligibility in noise for cochlear implant users | Q30364458 |
| | Cochlear implants: system design, integration, and evaluation. | Q30382987 |
| | Speech perception in tones and noise via cochlear implants reveals influence of spectral resolution on temporal processing | Q30425385 |
| | Cochlear implantation with hearing preservation yields significant benefit for speech recognition in complex listening environments | Q30435627 |
| | Fundamental frequency is critical to speech perception in noise in combined acoustic and electric hearing. | Q30462957 |
| | Spatial tuning curves from apical, middle, and basal electrodes in cochlear implant users | Q30467075 |
| | Low-frequency speech cues and simulated electric-acoustic hearing | Q30482931 |
| | Derivation of auditory filter shapes from notched-noise data | Q34144446 |
| | Speechreading supplemented with frequency-selective sound-pressure information | Q38582910 |
| | Tactile presentation of voice fundamental frequency as an aid to the perception of speech pattern contrasts | Q38595290 |
| | Combined Electric and Acoustic Stimulation With Hearing Preservation: Effect of Cochlear Implant Low-Frequency Cutoff on Speech Understanding and Perceived Listening Difficulty | Q38903310 |
| | An evaluation of hearing preservation outcomes in routine cochlear implant care: Implications for candidacy | Q39835362 |
| | Microphone directionality, pre-emphasis filter, and wind noise in cochlear implants | Q40013221 |
| | Tactile localization of the direction and distance of sounds | Q41703966 |
| | Evaluation of two multichannel tactile aids for the hearing impaired | Q42160196 |
| | Speech perception and talker segregation: effects of level, pitch, and tactile support with multiple simultaneous talkers | Q44054696 |
| | Unintelligible low-frequency sound enhances simulated cochlear-implant speech recognition in noise | Q44972329 |
| | Improved speech recognition in noise in simulated binaurally combined acoustic and electric stimulation | Q48145279 |
| | Speech pattern hearing aids for the profoundly hearing impaired: speech perception and auditory abilities | Q49162269 |
| | Clinical evaluation of signal-to-noise ratio-based noise reduction in Nucleus® cochlear implant recipients | Q50435423 |
| | Effects of introducing unprocessed low-frequency information on the reception of envelope-vocoder processed speech | Q50465304 |
| | Speech recognition in background noise of cochlear implant patients. | Q50488181 |
| | Speech recognition in noise for cochlear implantees with a two-microphone monaural adaptive noise reduction system. | Q50489976 |
| | The recognition of sentences in noise by normal-hearing listeners using simulations of cochlear-implant signal processors with 6-20 channels. | Q50502952 |
| | Speechreading enhancement: a comparison of spatial-tactile display of voice fundamental frequency (F0) with auditory F0. | Q50514313 |
| | Speech recognition with primarily temporal cues. | Q50517986 |
| | Comparison of two multichannel tactile devices as supplements to speechreading in a postlingually deafened adult. | Q50520080 |
| | Effect of temporal envelope smearing on speech reception. | Q50526009 |
| | Evaluation of the Siemens Minifonator vibrotactile aid. | Q50558917 |
| | Development and preliminary evaluation of an earmold sound-to-tactile aid for the hearing-impaired. | Q50576351 |
| | Sensitivity to amplitude-modulated vibrotactile signals. | Q50577312 |
| | Continuing evaluation of the Queen's University tactile vocoder II: Identification of open set sentences and tracking narrative. | Q50580765 |
| | Continuing evaluation of the Queen's University tactile vocoder. I: Identification of open set words. | Q50580770 |
| | Speech understanding in background noise with the two-microphone adaptive beamformer BEAM in the Nucleus Freedom Cochlear Implant System. | Q51088636 |
| | Multidimensional tactile displays: identification of vibratory intensity, frequency, and contactor area. | Q52254964 |
| | Vibrotactile frequency for encoding a speech parameter | Q67686199 |
| | Transformed up-down methods in psychoacoustics | Q71753046 |
| | Effects of simulated cochlear-implant processing on speech reception in fluctuating maskers | Q73706186 |
| | Information from time-varying vibrotactile stimuli | Q73961403 |
| | Tactile information transfer: a comparison of two stimulation sites | Q81433076 |
| | Cochlear implant simulator with independent representation of the full spiral ganglion | Q89456577 |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | cochlear implant | Q724965 |
| P304 | page(s) | 2331216518797838 | |
| P577 | publication date | 2018-01-01 | |
| P1433 | published in | Trends in hearing | Q27725724 |
| P1476 | title | Vibro-Tactile Enhancement of Speech Intelligibility in Multi-talker Noise for Simulated Cochlear Implant Listening | |
| P478 | volume | 22 | |