Effect of passive whole-body rotation on sound localization accuracy of listener subjective straight ahead

Akio Honda; Yoji Masumi; Yôiti Suzuki; Shuichi Sakamoto

doi:10.1250/ast.41.249

Effects of listener’s whole-body rotation and sound duration on sound localization accuracy

The Journal of the Acoustical Society of America ◽

10.1121/1.5014754 ◽

2017 ◽

Vol 142 (4) ◽

pp. 2676-2676

Author(s):

Akio Honda ◽

Sayaka Tsunokake ◽

Yôiti Suzuki ◽

Shuichi Sakamoto

Keyword(s):

Sound Localization ◽

Whole Body ◽

Body Rotation ◽

Localization Accuracy ◽

Sound Duration

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Effects of listener's whole-body rotation and sound duration on horizontal sound localization accuracy

Acoustical Science and Technology ◽

10.1250/ast.39.305 ◽

2018 ◽

Vol 39 (4) ◽

pp. 305-307 ◽

Cited By ~ 2

Author(s):

Akio Honda ◽

Sayaka Tsunokake ◽

Yôiti Suzuki ◽

Shuichi Sakamoto

Keyword(s):

Sound Localization ◽

Whole Body ◽

Body Rotation ◽

Localization Accuracy ◽

Sound Duration

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Auditory Subjective-Straight-Ahead Blurs during Significantly Slow Passive Body Rotation

i-Perception ◽

10.1177/20416695211070616 ◽

2022 ◽

Vol 13 (1) ◽

pp. 204166952110706

Author(s):

Akio Honda ◽

Sayaka Tsunokake ◽

Yôiti Suzuki ◽

Shuichi Sakamoto

Keyword(s):

Sound Localization ◽

Rotation Speed ◽

Body Rotation ◽

Body Movements ◽

Localization Accuracy ◽

Passive Rotation ◽

Straight Ahead

This paper reports on the deterioration in sound-localization accuracy during listeners’ head and body movements. We investigated the sound-localization accuracy during passive body rotations at speeds in the range of 0.625–5 °/s. Participants were asked to determine whether a 30-ms noise stimuli emerged relative to their subjective-straight-ahead reference. Results indicated that the sound-localization resolution degraded with passive rotation, irrespective of the rotation speed, even at speeds of 0.625 °/s.

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Therapy-Resistant Atypical Downbeat Nystagmus with Vertigo Confined to Specific Head-Hanging Positions: Mapping to the Gravity Vector on a Multi-Axis Turntable

Case Reports in Neurology ◽

10.1159/000517840 ◽

2021 ◽

pp. 464-469

Author(s):

Dominik Péus ◽

Dominik Straumann ◽

Alexander Huber ◽

Christopher J. Bockisch ◽

Vincent Wettstein

Keyword(s):

Hair Cells ◽

Whole Body ◽

Downbeat Nystagmus ◽

Two Dimensional ◽

Body Rotation ◽

Therapeutic Approaches ◽

Atypical Case ◽

Anterior Semicircular Canal ◽

Head Positions ◽

Peripheral Origin

Downbeat nystagmus (DBN) observed in head-hanging positions, may be of central or peripheral origin. Central DBN in head-hanging positions is mostly due to a disorder of the vestibulo-cerebellum, whereas peripheral DBN is usually attributed to canalolithiasis of an anterior semicircular canal. Here, we describe an atypical case of a patient who, after head trauma, experienced severe and stereotypic vertigo attacks after being placed in various head-hanging positions. Vertigo lasted 10–15 s and was always associated with a robust DBN. The provocation of transient vertigo and DBN, which both showed no decrease upon repetition of maneuvers, depended on the yaw orientation relative to the trunk and the angle of backward pitch. On a motorized, multi-axis turntable, we identified the two-dimensional Helmholtz coordinates of head positions at which vertigo and DBN occurred (y-axis: horizontal, space-fixed; z-axis: vertical, and head-fixed; x-axis: torsional, head-fixed, and unchanged). This two-dimensional area of DBN-associated head positions did not change when whole-body rotations took different paths (e.g., by forwarding pitch) or were executed with different velocities. Moreover, the intensity of DBN was also independent of whole-body rotation paths and velocities. So far, therapeutic approaches with repeated liberation maneuvers and cranial vibrations were not successful. We speculate that vertigo and DBN in this patient are due to macular damage, possibly an unstable otolithic membrane that, in specific orientations relative to gravity, slips into a position causing paroxysmal stimulation or inhibition of macular hair cells.

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Postural Preparation to Making a Step: Is There a “Motor Program” for Postural Preparation?

Journal of Applied Biomechanics ◽

10.1123/jab.23.4.261 ◽

2007 ◽

Vol 23 (4) ◽

pp. 261-274 ◽

Cited By ~ 7

Author(s):

Adriana M. Degani ◽

Alessander Danna-Dos-Santos ◽

Mark L. Latash

Keyword(s):

Reaction Time ◽

Simple Reaction Time ◽

Center Of Pressure ◽

Motor Program ◽

Whole Body ◽

Single Motor ◽

Simple Reaction ◽

Specific Manner ◽

Young Subjects ◽

Straight Ahead

We tested the hypothesis that a sequence of mechanical events occurs preceding a step that scales in time and magnitude as a whole in a task-specific manner, and is a reflection of a “motor program.” Young subjects made a step under three speed instructions and four tasks: stepping straight ahead, down a stair, up a stair, and over an obstacle. Larger center-of-pressure (COP) and force adjustments in the anteriorposterior direction and smaller COP and force adjustments in the mediolateral direction were seen during stepping forward and down a stair, as compared with the tasks of stepping up a stair and over an obstacle. These differences were accentuated during stepping under the simple reaction time instruction. These results speak against the hypothesis of a single motor program that would underlie postural preparation to stepping. They are more compatible with the reference configuration hypothesis of whole-body actions.

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Tuning of a Basic Coordination Pattern Constructs Straight-Ahead and Curved Walking in Humans

Journal of Neurophysiology ◽

10.1152/jn.00817.2003 ◽

2004 ◽

Vol 91 (4) ◽

pp. 1524-1535 ◽

Cited By ~ 96

Author(s):

Grégoire Courtine ◽

Marco Schieppati

Keyword(s):

Principal Components ◽

Lower Limb ◽

Time Course ◽

Body Movement ◽

The Body ◽

Whole Body ◽

Coordination Pattern ◽

Data Set ◽

Coordination Patterns ◽

Straight Ahead

We tested the hypothesis that common principles govern the production of the locomotor patterns for both straight-ahead and curved walking. Whole body movement recordings showed that continuous curved walking implies substantial, limb-specific changes in numerous gait descriptors. Principal component analysis (PCA) was used to uncover the spatiotemporal structure of coordination among lower limb segments. PCA revealed that the same kinematic law accounted for the coordination among lower limb segments during both straight-ahead and curved walking, in both the frontal and sagittal planes: turn-related changes in the complex behavior of the inner and outer limbs were captured in limb-specific adaptive tuning of coordination patterns. PCA was also performed on a data set including all elevation angles of limb segments and trunk, thus encompassing 13 degrees of freedom. The results showed that both straight-ahead and curved walking were low dimensional, given that 3 principal components accounted for more than 90% of data variance. Furthermore, the time course of the principal components was unchanged by curved walking, thereby indicating invariant coordination patterns among all body segments during straight-ahead and curved walking. Nevertheless, limb- and turn-dependent tuning of the coordination patterns encoded the adaptations of the limb kinematics to the actual direction of the walking body. Absence of vision had no significant effect on the intersegmental coordination during either straight-ahead or curved walking. Our findings indicate that kinematic laws, probably emerging from the interaction of spinal neural networks and mechanical oscillators, subserve the production of both straight-ahead and curved walking. During locomotion, the descending command tunes basic spinal networks so as to produce the changes in amplitude and phase relationships of the spinal output, sufficient to achieve the body turn.

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Antihysteresis of perceived longitudinal body axis during continuous quasi-static whole-body rotation in the earth-vertical roll plane

Experimental Brain Research ◽

10.1007/s00221-011-2572-8 ◽

2011 ◽

Vol 209 (3) ◽

pp. 443-454

Author(s):

M. Tatalias ◽

C. J. Bockisch ◽

G. Bertolini ◽

D. Straumann ◽

A. Palla

Keyword(s):

Body Axis ◽

Whole Body ◽

Body Rotation ◽

Longitudinal Body Axis ◽

Vertical Roll ◽

The Earth

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Contribution of bone-reverberated waves to sound localization of dolphins: A numerical model

Acta Acustica ◽

10.1051/aacus/2020030 ◽

2020 ◽

Vol 5 ◽

pp. 3

Author(s):

Aida Hejazi Nooghabi ◽

Quentin Grimal ◽

Anthony Herrel ◽

Michael Reinwald ◽

Lapo Boschi

Keyword(s):

Wave Propagation ◽

Numerical Model ◽

Sound Localization ◽

Three Dimensional ◽

Vertical Plane ◽

Dimensional Structure ◽

Bone Modeling ◽

Sound Sources ◽

Localization Accuracy ◽

Future Work

We implement a new algorithm to model acoustic wave propagation through and around a dolphin skull, using the k-Wave software package [1]. The equation of motion is integrated numerically in a complex three-dimensional structure via a pseudospectral scheme which, importantly, accounts for lateral heterogeneities in the mechanical properties of bone. Modeling wave propagation in the skull of dolphins contributes to our understanding of how their sound localization and echolocation mechanisms work. Dolphins are known to be highly effective at localizing sound sources; in particular, they have been shown to be equally sensitive to changes in the elevation and azimuth of the sound source, while other studied species, e.g. humans, are much more sensitive to the latter than to the former. A laboratory experiment conducted by our team on a dry skull [2] has shown that sound reverberated in bones could possibly play an important role in enhancing localization accuracy, and it has been speculated that the dolphin sound localization system could somehow rely on the analysis of this information. We employ our new numerical model to simulate the response of the same skull used by [2] to sound sources at a wide and dense set of locations on the vertical plane. This work is the first step towards the implementation of a new tool for modeling source (echo)location in dolphins; in future work, this will allow us to effectively explore a wide variety of emitted signals and anatomical features.

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Role of the Cerebellar Flocculus Region in the Coordination of Eye and Head Movements During Gaze Pursuit

Journal of Neurophysiology ◽

10.1152/jn.2000.84.3.1614 ◽

2000 ◽

Vol 84 (3) ◽

pp. 1614-1626 ◽

Cited By ~ 32

Author(s):

Timothy Belton ◽

Robert A. McCrea

Keyword(s):

Eye Movements ◽

Smooth Pursuit ◽

Head Movements ◽

Whole Body ◽

Head Tracking ◽

Smooth Pursuit Eye Movements ◽

Body Rotation ◽

Pursuit Eye Movements ◽

Smooth Tracking ◽

Eye Velocity

The contribution of the flocculus region of the cerebellum to horizontal gaze pursuit was studied in squirrel monkeys. When the head was free to move, the monkeys pursued targets with a combination of smooth eye and head movements; with the majority of the gaze velocity produced by smooth tracking head movements. In the accompanying study we reported that the flocculus region was necessary for cancellation of the vestibuloocular reflex (VOR) evoked by passive whole body rotation. The question addressed in this study was whether the flocculus region of the cerebellum also plays a role in canceling the VOR produced by active head movements during gaze pursuit. The firing behavior of 121 Purkinje (Pk) cells that were sensitive to horizontal smooth pursuit eye movements was studied. The sample included 66 eye velocity Pk cells and 55 gaze velocity Pk cells. All of the cells remained sensitive to smooth pursuit eye movements during combined eye and head tracking. Eye velocity Pk cells were insensitive to smooth pursuit head movements. Gaze velocity Pk cells were nearly as sensitive to active smooth pursuit head movements as they were passive whole body rotation; but they were less than half as sensitive (≈43%) to smooth pursuit head movements as they were to smooth pursuit eye movements. Considered as a whole, the Pk cells in the flocculus region of the cerebellar cortex were <20% as sensitive to smooth pursuit head movements as they were to smooth pursuit eye movements, which suggests that this region does not produce signals sufficient to cancel the VOR during smooth head tracking. The comparative effect of injections of muscimol into the flocculus region on smooth pursuit eye and head movements was studied in two monkeys. Muscimol inactivation of the flocculus region profoundly affected smooth pursuit eye movements but had little effect on smooth pursuit head movements or on smooth tracking of visual targets when the head was free to move. We conclude that the signals produced by flocculus region Pk cells are neither necessary nor sufficient to cancel the VOR during gaze pursuit.

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