The paper analyzes participant opinions from a Physics of Life Reviews discussion on the simplicity revolution in high-dimensional neuroscience and its implications for machine learning.
Estimating the effective dimension of large biological datasets using Fisher separability analysis
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abstract
Modern large-scale datasets are frequently said to be high-dimensional. However, their data point clouds frequently possess structures, significantly decreasing their intrinsic dimensionality (ID) due to the presence of clusters, points being located close to low-dimensional varieties or fine-grained lumping. We test a recently introduced dimensionality estimator, based on analysing the separability properties of data points, on several benchmarks and real biological datasets. We show that the introduced measure of ID has performance competitive with state-of-the-art measures, being efficient across a wide range of dimensions and performing better in the case of noisy samples. Moreover, it allows estimating the intrinsic dimension in situations where the intrinsic manifold assumption is not valid.
fields
q-bio.NC 1years
2019 1verdicts
UNVERDICTED 1representative citing papers
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Symphony of high-dimensional brain
The paper analyzes participant opinions from a Physics of Life Reviews discussion on the simplicity revolution in high-dimensional neuroscience and its implications for machine learning.