A High-Throughput Screening Approach to Discovering Good Forms of Biologically Inspired Visual Representation
Author(s)
Cox, David D.; Pinto, Nicolas; Doukhan, David; DiCarlo, James
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While many models of biological object recognition share a common set of ‘‘broad-stroke’’ properties, the performance of
any one model depends strongly on the choice of parameters in a particular instantiation of that model—e.g., the number
of units per layer, the size of pooling kernels, exponents in normalization operations, etc. Since the number of such
parameters (explicit or implicit) is typically large and the computational cost of evaluating one particular parameter set is
high, the space of possible model instantiations goes largely unexplored. Thus, when a model fails to approach the abilities
of biological visual systems, we are left uncertain whether this failure is because we are missing a fundamental idea or
because the correct ‘‘parts’’ have not been tuned correctly, assembled at sufficient scale, or provided with enough training.
Here, we present a high-throughput approach to the exploration of such parameter sets, leveraging recent advances in
stream processing hardware (high-end NVIDIA graphic cards and the PlayStation 3’s IBM Cell Processor). In analogy to highthroughput
screening approaches in molecular biology and genetics, we explored thousands of potential network
architectures and parameter instantiations, screening those that show promising object recognition performance for further
analysis. We show that this approach can yield significant, reproducible gains in performance across an array of basic object
recognition tasks, consistently outperforming a variety of state-of-the-art purpose-built vision systems from the literature.
As the scale of available computational power continues to expand, we argue that this approach has the potential to greatly
accelerate progress in both artificial vision and our understanding of the computational underpinning of biological vision.
Date issued
2009-11Department
Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences; McGovern Institute for Brain Research at MITJournal
PLoS Computational Biology
Publisher
Public Library of Science
Citation
Pinto, Nicolas et al. “A High-Throughput Screening Approach to Discovering Good Forms of Biologically Inspired Visual Representation.” PLoS Comput Biol 5.11 (2009): e1000579. © 2009 Pinto et al.
Version: Final published version
ISSN
1553-7358
553-734X