AUTHOR=Schoppe Oliver , Harper Nicol S. , Willmore Ben D. B. , King Andrew J. , Schnupp Jan W. H. 

TITLE=Measuring the Performance of Neural Models

JOURNAL=Frontiers in Computational Neuroscience

VOLUME=10

YEAR=2016

URL=https://www.frontiersin.org/journals/computational-neuroscience/articles/10.3389/fncom.2016.00010

DOI=10.3389/fncom.2016.00010

ISSN=1662-5188

ABSTRACT=<p>Good metrics of the performance of a statistical or computational model are essential for model comparison and selection. Here, we address the design of performance metrics for models that aim to predict neural responses to sensory inputs. This is particularly difficult because the responses of sensory neurons are inherently variable, even in response to repeated presentations of identical stimuli. In this situation, standard metrics (such as the correlation coefficient) fail because they do not distinguish between explainable variance (the part of the neural response that is systematically dependent on the stimulus) and response variability (the part of the neural response that is not systematically dependent on the stimulus, and cannot be explained by modeling the stimulus-response relationship). As a result, models which perfectly describe the systematic stimulus-response relationship may appear to perform poorly. Two metrics have previously been proposed which account for this inherent variability: Signal Power Explained (<italic>SPE</italic>, Sahani and Linden, <xref ref-type="bibr" rid="B23">2003</xref>), and the normalized correlation coefficient (<italic>CC</italic><sub><italic>norm</italic></sub>, Hsu et al., <xref ref-type="bibr" rid="B12">2004</xref>). Here, we analyze these metrics, and show that they are intimately related. However, <italic>SPE</italic> has no lower bound, and we show that, even for good models, <italic>SPE</italic> can yield negative values that are difficult to interpret. <italic>CC</italic><sub><italic>norm</italic></sub> is better behaved in that it is effectively bounded between −1 and 1, and values below zero are very rare in practice and easy to interpret. However, it was hitherto not possible to calculate <italic>CC</italic><sub><italic>norm</italic></sub> directly; instead, it was estimated using imprecise and laborious resampling techniques. Here, we identify a new approach that can calculate <italic>CC</italic><sub><italic>norm</italic></sub> quickly and accurately. As a result, we argue that it is now a better choice of metric than <italic>SPE</italic> to accurately evaluate the performance of neural models.</p>