Dynamic Dynamic Time Warping

Karl Bringmann; Nick Fischer; Ivor van der Hoog; Evangelos Kipouridis; Tomasz Kociumaka; Eva Rotenberg

doi:10.1137/1.9781611977912.10

Dynamic Dynamic Time Warping

Karl Bringmann, Nick Fischer, Ivor van der Hoog, Evangelos Kipouridis, Tomasz Kociumaka, Eva Rotenberg

Research output: Chapter in Book/Report/Conference proceeding › Article in proceedings › Research › peer-review

Abstract

The Dynamic Time Warping (DTW) distance is a popular similarity measure for polygonal curves (i.e., sequences of points). It finds many theoretical and practical applications, especially for temporal data, and is known to be a robust, outlier-insensitive alternative to the Fréchet distance. For static curves of at most n points, the DTW distance can be computed in O(n²) time in constant dimension. This tightly matches a SETH-based lower bound, even for curves in R¹.
In this work, we study dynamic algorithms for the DTW distance. Here, the goal is to design a data structure that can be efficiently updated to accommodate local changes to one or both curves, such as inserting or deleting vertices and, after each operation, reports the updated DTW distance. We give such a data structure with update and query time O(n^1.5 log n), where n is the maximum length of the curves.
As our main result, we prove that our data structure is conditionally optimal, up to subpolynomial factors. More precisely, we prove that, already for curves in R¹, there is no dynamic algorithm to maintain the DTW distance with update and query time O(n^1.5−δ) for any constant δ > 0, unless the Negative-k-Clique Hypothesis fails. In fact, we give matching upper and lower bounds for various trade-offs between update and query time, even in cases where the lengths of the curves differ.

Original language	English
Title of host publication	Proceedings of the 2024 Annual ACM-SIAM Symposium on Discrete Algorithms (SODA)
Publisher	Society for Industrial and Applied Mathematics
Publication date	2024
Pages	208-242
ISBN (Electronic)	978-1-61197-791-2
DOIs	https://doi.org/10.1137/1.9781611977912.10
Publication status	Published - 2024

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title = "Dynamic Dynamic Time Warping",

abstract = "The Dynamic Time Warping (DTW) distance is a popular similarity measure for polygonal curves (i.e., sequences of points). It finds many theoretical and practical applications, especially for temporal data, and is known to be a robust, outlier-insensitive alternative to the Fr{\'e}chet distance. For static curves of at most n points, the DTW distance can be computed in O(n2) time in constant dimension. This tightly matches a SETH-based lower bound, even for curves in R1. In this work, we study dynamic algorithms for the DTW distance. Here, the goal is to design a data structure that can be efficiently updated to accommodate local changes to one or both curves, such as inserting or deleting vertices and, after each operation, reports the updated DTW distance. We give such a data structure with update and query time O(n1.5 log n), where n is the maximum length of the curves. As our main result, we prove that our data structure is conditionally optimal, up to subpolynomial factors. More precisely, we prove that, already for curves in R1, there is no dynamic algorithm to maintain the DTW distance with update and query time O(n1.5−δ) for any constant δ > 0, unless the Negative-k-Clique Hypothesis fails. In fact, we give matching upper and lower bounds for various trade-offs between update and query time, even in cases where the lengths of the curves differ.",

author = "Karl Bringmann and Nick Fischer and {van der Hoog}, Ivor and Evangelos Kipouridis and Tomasz Kociumaka and Eva Rotenberg",

year = "2024",

doi = "10.1137/1.9781611977912.10",

language = "English",

pages = "208--242",

booktitle = "Proceedings of the 2024 Annual ACM-SIAM Symposium on Discrete Algorithms (SODA)",

publisher = "Society for Industrial and Applied Mathematics",

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T1 - Dynamic Dynamic Time Warping

AU - Bringmann, Karl

AU - Fischer, Nick

AU - van der Hoog, Ivor

AU - Kipouridis, Evangelos

AU - Kociumaka, Tomasz

AU - Rotenberg, Eva

PY - 2024

Y1 - 2024

N2 - The Dynamic Time Warping (DTW) distance is a popular similarity measure for polygonal curves (i.e., sequences of points). It finds many theoretical and practical applications, especially for temporal data, and is known to be a robust, outlier-insensitive alternative to the Fréchet distance. For static curves of at most n points, the DTW distance can be computed in O(n2) time in constant dimension. This tightly matches a SETH-based lower bound, even for curves in R1. In this work, we study dynamic algorithms for the DTW distance. Here, the goal is to design a data structure that can be efficiently updated to accommodate local changes to one or both curves, such as inserting or deleting vertices and, after each operation, reports the updated DTW distance. We give such a data structure with update and query time O(n1.5 log n), where n is the maximum length of the curves. As our main result, we prove that our data structure is conditionally optimal, up to subpolynomial factors. More precisely, we prove that, already for curves in R1, there is no dynamic algorithm to maintain the DTW distance with update and query time O(n1.5−δ) for any constant δ > 0, unless the Negative-k-Clique Hypothesis fails. In fact, we give matching upper and lower bounds for various trade-offs between update and query time, even in cases where the lengths of the curves differ.

AB - The Dynamic Time Warping (DTW) distance is a popular similarity measure for polygonal curves (i.e., sequences of points). It finds many theoretical and practical applications, especially for temporal data, and is known to be a robust, outlier-insensitive alternative to the Fréchet distance. For static curves of at most n points, the DTW distance can be computed in O(n2) time in constant dimension. This tightly matches a SETH-based lower bound, even for curves in R1. In this work, we study dynamic algorithms for the DTW distance. Here, the goal is to design a data structure that can be efficiently updated to accommodate local changes to one or both curves, such as inserting or deleting vertices and, after each operation, reports the updated DTW distance. We give such a data structure with update and query time O(n1.5 log n), where n is the maximum length of the curves. As our main result, we prove that our data structure is conditionally optimal, up to subpolynomial factors. More precisely, we prove that, already for curves in R1, there is no dynamic algorithm to maintain the DTW distance with update and query time O(n1.5−δ) for any constant δ > 0, unless the Negative-k-Clique Hypothesis fails. In fact, we give matching upper and lower bounds for various trade-offs between update and query time, even in cases where the lengths of the curves differ.

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EP - 242

BT - Proceedings of the 2024 Annual ACM-SIAM Symposium on Discrete Algorithms (SODA)

PB - Society for Industrial and Applied Mathematics

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Dynamic Dynamic Time Warping

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