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Abstract

We propose sublinear algorithms for probabilistic testing of the discrete and continuous Fr\'echet distance - a standard similarity measure for curves. We assume the algorithm is given access to the input curves via a query oracle: a query returns the set of vertices of the curve that lie within a radius $\delta$ of a specified vertex of the other curve. The goal is to use a small number of queries to determine with constant probability whether the two curves are similar (i.e., their discrete Fr\'echet distance is at most $\delta$) or they are ''$\varepsilon$-far'' (for $0 < \varepsilon < 2$) from being similar, i.e., more than an $\varepsilon$-fraction of the two curves must be ignored for them to become similar. We present two algorithms which are sublinear assuming that the curves are $t$-approximate shortest paths in the ambient metric space, for some $t\ll n$. The first algorithm uses $O(\frac{t}{\varepsilon}\log\frac{t}{\varepsilon})$ queries and is given the value of $t$ in advance. The second algorithm does not have explicit knowledge of the value of $t$ and therefore needs to gain implicit knowledge of the straightness of the input curves through its queries. We show that the discrete Fr\'echet distance can still be tested using roughly $O(\frac{t^3+t^2\log n}{\varepsilon})$ queries ignoring logarithmic factors in $t$. Our algorithms work in a matrix representation of the input and may be of independent interest to matrix testing. Our algorithms use a mild uniform sampling condition that constrains the edge lengths of the curves, similar to a polynomially bounded aspect ratio. Applied to testing the continuous Fr\'echet distance of $t$-straight curves, our algorithms can be used for $(1+\varepsilon')$-approximate testing using essentially the same bounds as stated above with an additional factor of poly$(\frac{1}{\varepsilon'})$.