A computational theory for the classification of natural biosonar targets based on a spike code

A computational theory for the classification of natural biosonar targets is developed based on the properties of an example stimulus ensemble. An extensive set of echoes (84 800) from four different foliages was transcribed into a spike code using a parsimonious model (linear filtering, half-wave rectification, thresholding). The spike code is assumed to consist of time differences (interspike intervals) between threshold crossings. Among the elementary interspike intervals flanked by exceedances of adjacent thresholds, a few intervals triggered by disjoint half-cycles of the carrier oscillation stand out in terms of resolvability, visibility across resolution scales and a simple stochastic structure (uncorrelatedness). They are therefore argued to be a stochastic analogue to edges in vision. A three-dimensional feature vector representing these interspike intervals sustained a reliable target classification performance (0.06% classification error) in a sequential probability ratio test, which models sequential processing of echo trains by biological sonar systems. The dimensions of the representation are the first moments of duration and amplitude location of these interspike intervals as well as their number. All three quantities are readily reconciled with known principles of neural signal representation, since they correspond to the centre of gravity of excitation on a neural map and the total amount of excitation.

[1]  D. G. Watts,et al.  Spectral analysis and its applications , 1968 .

[2]  M. Vater Cochlear Physiology and Anatomy in Bats , 1988 .

[3]  D. Hartley,et al.  The sound emission pattern of the echolocating bat, Eptesicus fuscus , 1989 .

[4]  Roman Kuc,et al.  Building a Sonar Map in a Specular Environment Using a Single Mobile Sensor , 1991, IEEE Trans. Pattern Anal. Mach. Intell..

[5]  Tomaso Poggio,et al.  Computational vision and regularization theory , 1985, Nature.

[6]  N. Suga,et al.  Delay lines and amplitude selectivity are created in subthalamic auditory nuclei: the brachium of the inferior colliculus of the mustached bat. , 1993, Journal of neurophysiology.

[7]  Venugopal V. Veeravalli,et al.  A sequential procedure for multihypothesis testing , 1994, IEEE Trans. Inf. Theory.

[8]  Leslie S. Smith Onset-based Sound Segmentation , 1995, NIPS.

[9]  J. Simonoff Multivariate Density Estimation , 1996 .

[10]  T Dau,et al.  A quantitative model of the "effective" signal processing in the auditory system. I. Model structure. , 1996, The Journal of the Acoustical Society of America.

[11]  D. Irvine,et al.  First-spike timing of auditory-nerve fibers and comparison with auditory cortex. , 1997, Journal of neurophysiology.

[12]  Wulfram Gerstner,et al.  Reduction of the Hodgkin-Huxley Equations to a Single-Variable Threshold Model , 1997, Neural Computation.

[13]  斉藤勲 Long Delay Lines for Ranging Are Created by inhibition in the Inferior Colliculus of the Mustached Bat(ヒゲコウモリが標的との距離測定に必要とする、大脳皮質聴覚野上の遅延線に対する、下丘における抑制性介存神経の関与について) , 1997 .

[14]  Malcolm Slaney,et al.  An Efficient Implementation of the Patterson-Holdsworth Auditory Filter Bank , 1997 .

[15]  J Gautrais,et al.  Rate coding versus temporal order coding: a theoretical approach. , 1998, Bio Systems.

[16]  Pascal Bondon,et al.  Efficiency of high-order moment estimates , 1998, IEEE Trans. Signal Process..

[17]  B. Grothe The evolution of temporal processing in the medial superior olive, an auditory brainstem structure , 2000, Progress in Neurobiology.

[18]  R Müller,et al.  Acoustic flow perception in cf-bats: extraction of parameters. , 2000, The Journal of the Acoustical Society of America.

[19]  R. Kuc,et al.  Foliage echoes: a probe into the ecological acoustics of bat echolocation. , 2000, The Journal of the Acoustical Society of America.

[20]  Avinash C. Kak,et al.  Principles of computerized tomographic imaging , 2001, Classics in applied mathematics.

[21]  Phillip J. McKerrow,et al.  Plant acoustic density profile model of CTFM ultrasonic sensing , 2001 .

[22]  R Kuc,et al.  Transforming echoes into pseudo-action potentials for classifying plants. , 2001, The Journal of the Acoustical Society of America.

[23]  Lutz Wiegrebe,et al.  The effect of preceding sonar emission on temporal integration in the bat, Megaderma lyra , 2002, Journal of Comparative Physiology A.

[24]  P. Schlegel,et al.  Frequency sensitivity and directional hearing in the gleaning bat,Plecotus auritus (Linnaeus 1758) , 2004, Journal of Comparative Physiology A.

[25]  J. H. Casseday,et al.  Frequency tuning and response latencies at three levels in the brainstem of the echolocating bat, Eptesicus fuscus , 1994, Journal of Comparative Physiology A.