Comparison of the lattice-Boltzmann model with the finite-difference time-domain method for electrodynamics.

A three-dimensional lattice-Boltzmann model (LBM) for the simulation of the Maxwell equations is presented. The inclusion of media follows an extension of a special limit described in the literature which is applicable to this LBM and does not harm the stability of simulations. The focus of the present study lies on the properties of numerical accuracy and stability of the LBM in comparison to the standard finite-difference time-domain (FDTD) method based on Yee's method. Typical examples, often investigated in the context of numerical simulations, are considered. These include the propagation of electrodynamic (EM) fields in one- and three-dimensional systems. Results of this simulations are compared to the ones of their theoretical predictions. Further on, long-time simulations are done in systems with periodic boundary conditions to check if the total energy is conserved. To investigate the effect of the numeric impedance, the propagation of an EM pulse is monitored spatially and temporarily in a two-dimensional system. The simulation results indicate, in contrast to the one obtained from the FDTD method, that the presented LBM does fulfill the expected energy conservation and is not effected by the numerical impedance. This LBM therefore represents a valuable alternative for the simulation of EM problems like long-time simulations by avoiding intrinsic properties the FDTD method suffers from.

[Determination of hearing thresholds in children using auditory brainstem responses : Influence of sedation and anaesthesia on quality and measurement time]. / Hörschwellenbestimmungen bei Kindern mittels früher akustisch evozierter Potenziale : Einfluss von Sedierung und Narkose auf Qualität und Messzeit.

BACKGROUND: A fundamental prerequisite for successful application of auditory brainstem responses (ABR) in paedaudiological diagnostics is to ensure a high quality of the measurement. This is commonly quantified by means of the residual noise. Key factors are the averaging number and the magnitude of spontaneous electroencephalogram (EEG). This is the first study to quantify the influence of different forms of sedation (anaesthesia, sedation with chloral hydrate or melatonin, natural sleep) on the individual EEG magnitude in children. MATERIALS AND METHODS: ABR measurements of 80 children aged between 1 month and 6 years were analysed retrospectively. Individual mean EEG amplitude was calculated from the averaging number and the residual noise. The results were analysed statistically with the type of sedation as a factor. From the mean EEG amplitudes, a theoretical recording time for a residual noise level of 35 nV was estimated. RESULTS: The spontaneous EEG activity is, on average, 2.5-times larger in awake children than in naturally sleeping children and more than 4­times larger than in sedated children. Although the EEG amplitude in intubation anaesthesia was smaller than with the other three types of sedation, this difference was not significant. The theoretical measurement time for 35 nV of residual noise was 10-times larger in awake than in sedated children. CONCLUSION: The large difference in spontaneous EEG activity between awake and sedated children indicates that sedation should be used for estimation of hearing thresholds on the basis of ABR. Only in rare cases is a reliable estimate of hearing thresholds likely to be obtained from ABR in awake children. Since different types of sedation do not influence the measurement time significantly, selection can be made solely on the basis of age and medical indication.

[Speaker discrimination in cochlear implant users]. / Sprecherunterscheidung mit Cochleaimplantaten.

BACKGROUND: Although the word and sentence recognition skills of cochlear implant (CI) users have been studied extensively, little is known about their ability to distinguish between individuals on the basis of voice, an important skill for social communication. METHODS: Speech material from the Oldenburg Logatome Corpus (OLLO) was used to build a set of 120 logatome pairs spoken by 15 male and 15 female speakers, with no overlap of the fundamental frequencies of the two groups of speakers. Each pair contained two different logatomes. For half of the pairs, the two logatomes were spoken by the same speaker, for the other half they were spoken by different speakers. Using a same-different paradigm, 13 adult normal-hearing listeners and 13 adult post-lingually deafened CI users were asked whether the pair of different logatomes were spoken by the same or by different speakers. RESULTS: Mean speaker discrimination score for the CI users was 74.6 % correct and for the normal-hearing listeners 89.6 % correct. A significant influence of voice gender on speaker discrimination score was found in CI users and in normal hearing listeners. CONCLUSION: The results of the CI users were significantly above the level of chance and no ceiling effect was observed for the normal-hearing listeners, i. e., the presented set of logatome pairs from the OLLO seems to be very well suited to speaker discrimination experiments in CI users and quantitative comparison to normal-hearing listeners. CI users are able to discriminate between speakers but their performance is slightly worse than that of normal-hearing listeners.

Stable lattice Boltzmann model for Maxwell equations in media.

The present work shows a method for stable simulations via the lattice Boltzmann (LB) model for electromagnetic waves (EM) transiting homogeneous media. LB models for such media were already presented in the literature, but they suffer from numerical instability when the media transitions are sharp. We use one of these models in the limit of pure vacuum derived from Liu and Yan [Appl. Math. MODEL: 38, 1710 (2014)AMMODL0307-904X10.1016/j.apm.2013.09.009] and apply an extension that treats the effects of polarization and magnetization separately. We show simulations of simple examples in which EM waves travel into media to quantify error scaling, stability, accuracy, and time scaling. For conductive media, we use the Strang splitting and check the simulations accuracy at the example of the skin effect. Like pure EM propagation, the error for the static limits, which are constructed with a current density added in a first-order scheme, can be less than 1%. The presented method is an easily implemented alternative for the stabilization of simulation for EM waves propagating in spatially complex structured media properties and arbitrary transitions.

Loudness of subcritical sounds as a function of bandwidth, center frequency, and level.

Level differences at equal loudness between band-pass noise and pure tones with a frequency equal to the center frequency of the noise were measured in normal-hearing listeners using a loudness matching procedure. The center frequencies were 750, 1500, and 3000 Hz and noise bandwidths from 5 to 1620 Hz were used. The level of the reference pure tone was 30, 50, or 70 dB. For all center frequencies and reference levels, the level at equal loudness was close to 0 dB for the narrowest bandwidth, increased with bandwidth for bandwidths smaller than the critical bandwidth, and decreased for bandwidths larger than the critical bandwidth. For bandwidths considerably larger than the critical bandwidth, the level difference was negative. The maximum positive level difference was measured for a bandwidth close to the critical bandwidth. This maximum level difference decreased with increasing reference level. A similar effect was found when the level differences were derived from data of an additional categorical loudness scaling experiment. The results indicate that the decrease of loudness at equal level with increasing subcritical bandwidth is a common property of the auditory system which is not taken into account in current loudness models.

[On the effect of reverberation on speech intelligibility by cochlear implant listeners]. / Zur Wahrnehmung verhallter Sprache mit Cochleaimplantaten.

BACKGROUND: An important parameter for characterization of the acoustic quality of closed rooms is reverberation. There is a rising interest in evaluating the ability of cochlear implant (CI) users to understand speech in real-world environments. Whereas the influence of noise on speech perception has been widely investigated, much less is known about the detrimental effect of reverberation. The present study aimed to investigate the influence of reverberation time on the speech perception of CI users and subjects with normal hearing. METHOD: A reverberated version of the sentences of the Oldenburg sentence test (OLSA) which is a widely used German test to measure speech reception thresholds (SRT) in cochlear implant users was generated using professional audio processing software. The reverberation times used were 0.7, 1.0, 1.5 and 2.0 s. For these four reverberation times and for a non-reverberated control condition, the SRT was measured in eight adult CI users and in eight subjects with normal hearing. RESULTS: To characterize the detrimental effect of reverberation the SRT differences between the reverberated and non-reverberated conditions were calculated. These SRT differences revealed a significant effect of reverberation in CI users with, e.g. a mean SRT increase of 2.9 dB in CI users and 0.9 dB in subjects with normal hearing for a reverberation time of 0.7 s. A strong correlation was found between the SRT increase and the SRT in the non-reverberated condition, highlighting the problems of poor performers in reverberant environments. CONCLUSION: The results of the current investigation indicated that reverberation results in decreased speech understanding of CI users.

Loudness of sounds with a subcritical bandwidth: a challenge to current loudness models?

Level differences at equal loudness were measured for bandpass noises centered at 1.5 kHz with bandwidths from 5 to 405 Hz and a 1.5-kHz pure tone. Irrespective of the reference (tone or 135-Hz wide noise), the data indicate a decrease in loudness with increasing bandwidth. This is at odds with the assumption of stationary loudness models that loudness for sounds with a subcritical bandwidth is determined by the intensity and center frequency only. It is also not in agreement with dynamic loudness models, which predict higher levels for a tone than for equally loud noises, i.e., the opposite effect.

Increased intensity discrimination thresholds in tinnitus subjects with a normal audiogram.

Recent auditory brain stem response measurements in tinnitus subjects with normal audiograms indicate the presence of hidden hearing loss that manifests as reduced neural output from the cochlea at high sound intensities, and results from mice suggest a link to deafferentation of auditory nerve fibers. As deafferentation would lead to deficits in hearing performance, the present study investigates whether tinnitus patients with normal hearing thresholds show impairment in intensity discrimination compared to an audiometrically matched control group. Intensity discrimination thresholds were significantly increased in the tinnitus frequency range, consistent with the hypothesis that auditory nerve fiber deafferentation is associated with tinnitus.

Rebound depolarization in single units of the ventral cochlear nucleus: a contribution to grouping by common onset?

Simultaneous grouping by common onset time is believed to be a powerful cue in auditory perception; components that start or stop roughly at the same time are judged as far more likely to have originated from the same source. Here we report a simple experiment designed to simulate a complex psychophysical paradigm first described by Darwin and Sutherland [(1984) Grouping frequency components of vowels. When is a harmonic not a harmonic? Quarterly J of Experimental Psychology: Hum Exp Psychol 36(A):193-208]. It is possible to change the perception of the vowel /I/ to /epsilon/ by manipulating the harmonics around the first formant (F1). Increasing the amplitude of one harmonic around F1 caused the perception of the vowel to change from /I/ to /epsilon/. Extending the increased component before the vowel could, however, greatly reduce this change. The role of neural adaptation in this effect was questioned by repeating the experiment but this time using a 'captor' tone which was switched on with the asynchronous harmonic and off when the vowel started. This time the vowel percept did change in a fashion analogous to the effect of an increase in the amplitude of the fourth harmonic (which is close to F1). This effect was explained by assuming that the captor had grouped with the leading portion of the asynchronous component enabling the remainder of the asynchronous component to be grouped with the remainder of the components. We propose a relatively low-level neuronal explanation for this grouping effect: the captor reduces the neural response to the leading segment of the asynchronous component by activating across-frequency suppression, either from the cochlea, or acting via a wideband inhibitor in the ventral cochlear nucleus. The reduction in neural response results in a release from adaptation with the offset of the captor terminating the inhibition, such that the response to the continuation of that component is now enhanced. Using a simplified paradigm we show that both primary-like and chopper units in the ventral cochlear nucleus of the anesthetized guinea pig may show a rebound in excitation when a captor is positioned so as to stimulate the suppressive sidebands in its receptive field. The strength of the rebound was positively correlated with the strength of the suppression. These and other results are consistent with the view that low-level mechanisms underlie the psychophysical captor effect.

Within-channel cues in comodulation masking release (CMR): experiments and model predictions using a modulation-filterbank model.

Experiments and model calculations were performed to study the influence of within-channel cues versus across-channel cues in comodulation masking release (CMR). A class of CMR experiments is considered that are characterized by a single (unmodulated or modulated) bandpass noise masker with variable bandwidth centered at the signal frequency. A modulation-filterbank model suggested by Dau et al. [J. Acoust. Soc. Am. 102, 2892-2905 (1997)] was employed to quantitatively predict the experimental data. Effects of varying masker bandwidth, center frequency, modulator bandwidth, modulator type, and signal duration on CMR were examined. In addition, the effect of band limiting the noise before or after modulation was shown to influence the CMR in the same way as a systematic variation of the modulation depth. It is demonstrated that a single-channel analysis, which analyzes only the information from one peripheral channel, quantitatively accounts for the CMR in most cases, indicating that an across-channel process is generally not necessary for simulating results from this class of CMR experiments. True across-channel processes may be found in another class of CMR experiments.