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Publications

Recent advances in understanding the auditory cortex.

King AJ. et al, (2018), F1000Res, 7

Network Receptive Field Modeling Reveals Extensive Integration and Multi-feature Selectivity in Auditory Cortical Neurons.

Harper NS. et al, (2016), PLoS Comput Biol, 12

Incorporating Midbrain Adaptation to Mean Sound Level Improves Models of Auditory Cortical Processing.

Willmore BDB. et al, (2016), J Neurosci, 36, 280 - 289

Measuring the Performance of Neural Models.

Schoppe O. et al, (2016), Front Comput Neurosci, 10

Hearing in noisy environments: noise invariance and contrast gain control.

Willmore BDB. et al, (2014), J Physiol, 592, 3371 - 3381

Constructing noise-invariant representations of sound in the auditory pathway.

Rabinowitz NC. et al, (2013), PLoS Biol, 11

Temporal predictability as a grouping cue in the perception of auditory streams.

Rajendran VG. et al, (2013), J Acoust Soc Am, 134, EL98 - E104

Spectrotemporal contrast kernels for neurons in primary auditory cortex.

Rabinowitz NC. et al, (2012), J Neurosci, 32, 11271 - 11284

Contrast normalization contributes to a biologically-plausible model of receptive-field development in primary visual cortex (V1).

Willmore BDB. et al, (2012), Vision Res, 54, 49 - 60

Contrast gain control in auditory cortex.

Rabinowitz NC. et al, (2011), Neuron, 70, 1178 - 1191

Sparse coding in striate and extrastriate visual cortex.

Willmore BDB. et al, (2011), J Neurophysiol, 105, 2907 - 2919

Object vision: a matter of principle.

Willmore BDB., (2011), Curr Biol, 21, R153 - R155

Neural representation of natural images in visual area V2.

Willmore BDB. et al, (2010), J Neurosci, 30, 2102 - 2114

Auditory cortex: representation through sparsification?

Willmore BDB. and King AJ., (2009), Curr Biol, 19, R1123 - R1125

The berkeley wavelet transform: a biologically inspired orthogonal wavelet transform.

Willmore B. et al, (2008), Neural Comput, 20, 1537 - 1564

Computation in neural systems. Editorial.

Goodhill G., (2008), Network, 19, 1 - 2

CMOS Monolithic Active Pixel Sensors (MAPS): New 'eyes' for science

Turchetta R. et al, (2006), NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 560, 139 - 142

Independent components of color natural scenes resemble V1 neurons in their spatial and color tuning.

Caywood MS. et al, (2004), J Neurophysiol, 91, 2859 - 2873

Methods for first-order kernel estimation: simple-cell receptive fields from responses to natural scenes.

Willmore B. and Smyth D., (2003), Network, 14, 553 - 577

The receptive-field organization of simple cells in primary visual cortex of ferrets under natural scene stimulation.

Smyth D. et al, (2003), J Neurosci, 23, 4746 - 4759

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