Biomedical Engineering Reference
In-Depth Information
[Reuter et al. 1999] Reuter R., Orglmeister R. and Herzel H. Simulations of vocal
fold vibrations with an analog circuit. International Journal of Bifurcations and
Chaos
9
, 1075-1088 (1999).
[Robb 1988] Robb J. B. and Saxman J. Acoustic observations in young children's
vocalizations. J. Acoust. Soc. Am.
83
, 1876-1882 (1988).
[Scharff and Nottebohm 1991] Scharff C. and Nottebohm F. A comparative study
of the behavioural deficits following lesions in various part of the zebra finch
song system: implications for vocal learning. J. Neurosci.
11
, 2896-2913 (1991).
[Schuster et al. 1990] Schuster H. G. and Wagner P. A model for neural oscillators
in the visual cortex: 1. Mean-field theory and derivation of phase equations.
Biol. Cybern.
64
, 77-82 (1990).
[Sigman and Mindlin 2000] Sigman M. and Mindlin B. G. Dynamics of three cou-
pled excitable cells with D
3
symmetry. Int. J. Bif. Chaos
10
, 1709-1728 (2000).
[Solari et al. 1996] Solari H. G., Natiello M. and Mindlin G. B.
Nonlinear Dynam-
ics: a Two Way Trip from Physics to Math
. IOP, London (1996).
[Spiro et al. 1999] Spiro J. E., Dalva M. B. and Mooney R. (1999) Long-range
inhibition within the zebra finch song nucleus RA can coordinate the firing of
multiple projection neurons. J. Neurophysiol.
81
, 3007-3020 (1999).
[Stark and Perkel 1999] Stark L. L. and Perkel D. J. Two stage, input specific
synaptic maturation in a nucleus essential for vocal production in the zebra
finch. J. Neurosci.
19
, 9107-9116 (1999).
[Steinecke and Herzel 1995] Steinecke I. and Herzel H. Bifurcations in an asymmet-
ric vocal fold-model. J. Acoust. Soc. Am.
97
1874-1884 (1995).
[Straneck 1990a] Straneck R.
Canto de las Aves Pampeanas I
, LOLA, Buenos Aires
(1990).
[Straneck 1990b] Straneck R.
Canto de las Aves Misioneras I
, LOLA, Buenos Aires
(1990).
[Straneck 1990c] Straneck R.,
Canto de las Aves Misioneras II
,LOLA,Buenos
Aires (1990).
[Sturdy et al. 2003] Sturdy C. B., Wild J. M. and Mooney R. Respiratory and
telencephalic modulation of vocal motor neurons in the zebra finch. J. Neurosci.
23
, 1072-1086 (2003).
[Suthers 1990] Suthers R. Contributions to birdsong from the left and right sides
of the intact syrinx. Nature
347
, 473-477 (1990).
[Suthers 1994] Suthers R. A. Variable asymmetry and resonance in the avian vo-
cal tract: a structural basis for individually distinct vocalizations. J. Comp.
Physiol. A
175
, 457-466 (1994).
[Suthers 2001] Suthers R. A. Peripheral vocal mechanisms in birds: are songbirds
special? Netherlands J. Zool.
51
, 217-242 (2001).
[Suthers 2004] Suthers R. A. The vocal apparatus. Ann. N.Y. Acad. Sci.
1016
109-129 (2004).
[Suthers and Margoliash 2002] Suthers R. A. and Margoliash D. Curr. Opin. Neu-
robiol.
12
, 684-690 (2002).
[Suthers and Zuo 1991] Suthers R. A. and Zuo M. X. A test of the aerodynamics
whistle hypothesis. Soc. Neurosci. Abstr.
17
, 1050 (1991).
[Suthers et al. 1999] Suthers R. A., Goller F. and Pytte C. The neuromuscular
control of birdsong. Phil. Trans. R. Soc. London B
354
, 927-939 (1999).
[Suthers et al. 2002] Suthers R. A., Goller F. and Wild M. J. Somatosensory feed-
back modulates respiratory motor program of crystallized birdsong. Proc. Natl.
Acad. Sci USA 99: 5680-5685 (2002).