43 research outputs found
Approximating Local Homology from Samples
Recently, multi-scale notions of local homology (a variant of persistent
homology) have been used to study the local structure of spaces around a given
point from a point cloud sample. Current reconstruction guarantees rely on
constructing embedded complexes which become difficult in high dimensions. We
show that the persistence diagrams used for estimating local homology, can be
approximated using families of Vietoris-Rips complexes, whose simple
constructions are robust in any dimension. To the best of our knowledge, our
results, for the first time, make applications based on local homology, such as
stratification learning, feasible in high dimensions.Comment: 23 pages, 14 figure
Wasserstein Stability for Persistence Diagrams
The stability of persistence diagrams is among the most important results in
applied and computational topology. Most results in the literature phrase
stability in terms of the bottleneck distance between diagrams and the
-norm of perturbations. This has two main implications: it makes the
space of persistence diagrams rather pathological and it is often provides very
pessimistic bounds with respect to outliers. In this paper, we provide new
stability results with respect to the -Wasserstein distance between
persistence diagrams. This includes an elementary proof for the setting of
functions on sufficiently finite spaces in terms of the -norm of the
perturbations, along with an algebraic framework for -Wasserstein distance
which extends the results to wider class of modules. We also provide apply the
results to a wide range of applications in topological data analysis (TDA)
including topological summaries, persistence transforms and the special but
important case of Vietoris-Rips complexes
Computing 1-Periodic Persistent Homology with Finite Windows
Let be a periodic cell complex endowed with a covering where
is a finite quotient space of equivalence classes under translations acting
on . We assume is embedded in a space whose homotopy type is a -torus
for some , which introduces "toroidal cycles" in which do not lift to
cycles in by . We study the behaviour of toroidal and non-toroidal
cycles for the case is 1-periodic, i.e. for some free
action of on . We show that toroidal cycles can be entirely
classified by endomorphisms on the homology of unit cells of , and moreover
that toroidal cycles have a sense of unimodality when studying the persistent
homology of .Comment: 1st revised version, only major change is in Section 3 to the theory
behind constructing the necessary endomorphism
2D vector field simplification based on robustness
pre-printVector field simplification aims to reduce the complexity of the flow by removing features in order of their relevance and importance, to reveal prominent behavior and obtain a compact representation for interpretation. Most existing simplification techniques based on the topological skeleton successively remove pairs of critical points connected by separatrices, using distance or area-based relevance measures. These methods rely on the stable extraction of the topological skeleton, which can be difficult due to instability in numerical integration, especially when processing highly rotational flows. These geometric metrics do not consider the flow magnitude, an important physical property of the flow. In this paper, we propose a novel simplification scheme derived from the recently introduced topological notion of robustness, which provides a complementary view on flow structure compared to the traditional topological-skeleton-based approaches. Robustness enables the pruning of sets of critical points according to a quantitative measure of their stability, that is, the minimum amount of vector field perturbation required to remove them. This leads to a hierarchical simplification scheme that encodes flow magnitude in its perturbation metric. Our novel simplification algorithm is based on degree theory, has fewer boundary restrictions, and so can handle more general cases. Finally, we provide an implementation under the piecewise-linear setting and apply it to both synthetic and real-world datasets
The U.S. Fishery Conservation and Management Act 1976 - a Plan for Diplomatic Action
We propose a new framework for the experimental study of periodic, quasi- periodic and recurrent dynamical systems. These behaviors express themselves as topological features which we detect using persistent cohomology. The result- ing 1-cocycles yield circle-valued coordinates associated to the recurrent behavior. We demonstrate how to use these coordinates to perform fundamental tasks like period recovery and parameter choice for delay embeddings. QC 20121221TOPOSY
A Comparison of Relaxations of Multiset Cannonical Correlation Analysis and Applications
Canonical correlation analysis is a statistical technique that is used to
find relations between two sets of variables. An important extension in pattern
analysis is to consider more than two sets of variables. This problem can be
expressed as a quadratically constrained quadratic program (QCQP), commonly
referred to Multi-set Canonical Correlation Analysis (MCCA). This is a
non-convex problem and so greedy algorithms converge to local optima without
any guarantees on global optimality. In this paper, we show that despite being
highly structured, finding the optimal solution is NP-Hard. This motivates our
relaxation of the QCQP to a semidefinite program (SDP). The SDP is convex, can
be solved reasonably efficiently and comes with both absolute and
output-sensitive approximation quality. In addition to theoretical guarantees,
we do an extensive comparison of the QCQP method and the SDP relaxation on a
variety of synthetic and real world data. Finally, we present two useful
extensions: we incorporate kernel methods and computing multiple sets of
canonical vectors