First Passage Percolation with Queried Hints

Kritkorn Karntikoon, Yiheng Shen, Sreenivas Gollapudi, Kostas Kollias, Aaron Schild, Ali K Sinop
Proceedings of The 27th International Conference on Artificial Intelligence and Statistics, PMLR 238:4231-4239, 2024.

Abstract

Solving optimization problems leads to elegant and practical solutions in a wide variety of real-world applications. In many of those real-world applications, some of the information required to specify the relevant optimization problem is noisy, uncertain, and expensive to obtain. In this work, we study how much of that information needs to be queried in order to obtain an approximately optimal solution to the relevant problem. In particular, we focus on the shortest path problem in graphs with dynamic edge costs. We adopt the {\em first passage percolation} model from probability theory wherein a graph $G’$ is derived from a weighted base graph $G$ by multiplying each edge weight by an independently chosen, random number in $[1, \rho]$. Mathematicians have studied this model extensively when $G$ is a $d$-dimensional grid graph, but the behavior of shortest paths in this model is still poorly understood in general graphs. We make progress in this direction for a class of graphs that resemble real-world road networks. Specifically, we prove that if $G$ has a constant continuous doubling dimension, then for a given $s-t$ pair, we only need to probe the weights on $((\rho \log n )/ \epsilon)^{O(1)}$ edges in $G’$ in order to obtain a $(1 + \epsilon)$-approximation to the $s-t$ distance in $G’$. We also generalize the result to a correlated setting and demonstrate experimentally that probing improves accuracy in estimating $s-t$ distances.

Cite this Paper


BibTeX
@InProceedings{pmlr-v238-karntikoon24a, title = {First Passage Percolation with Queried Hints}, author = {Karntikoon, Kritkorn and Shen, Yiheng and Gollapudi, Sreenivas and Kollias, Kostas and Schild, Aaron and K Sinop, Ali}, booktitle = {Proceedings of The 27th International Conference on Artificial Intelligence and Statistics}, pages = {4231--4239}, year = {2024}, editor = {Dasgupta, Sanjoy and Mandt, Stephan and Li, Yingzhen}, volume = {238}, series = {Proceedings of Machine Learning Research}, month = {02--04 May}, publisher = {PMLR}, pdf = {https://proceedings.mlr.press/v238/karntikoon24a/karntikoon24a.pdf}, url = {https://proceedings.mlr.press/v238/karntikoon24a.html}, abstract = {Solving optimization problems leads to elegant and practical solutions in a wide variety of real-world applications. In many of those real-world applications, some of the information required to specify the relevant optimization problem is noisy, uncertain, and expensive to obtain. In this work, we study how much of that information needs to be queried in order to obtain an approximately optimal solution to the relevant problem. In particular, we focus on the shortest path problem in graphs with dynamic edge costs. We adopt the {\em first passage percolation} model from probability theory wherein a graph $G’$ is derived from a weighted base graph $G$ by multiplying each edge weight by an independently chosen, random number in $[1, \rho]$. Mathematicians have studied this model extensively when $G$ is a $d$-dimensional grid graph, but the behavior of shortest paths in this model is still poorly understood in general graphs. We make progress in this direction for a class of graphs that resemble real-world road networks. Specifically, we prove that if $G$ has a constant continuous doubling dimension, then for a given $s-t$ pair, we only need to probe the weights on $((\rho \log n )/ \epsilon)^{O(1)}$ edges in $G’$ in order to obtain a $(1 + \epsilon)$-approximation to the $s-t$ distance in $G’$. We also generalize the result to a correlated setting and demonstrate experimentally that probing improves accuracy in estimating $s-t$ distances.} }
Endnote
%0 Conference Paper %T First Passage Percolation with Queried Hints %A Kritkorn Karntikoon %A Yiheng Shen %A Sreenivas Gollapudi %A Kostas Kollias %A Aaron Schild %A Ali K Sinop %B Proceedings of The 27th International Conference on Artificial Intelligence and Statistics %C Proceedings of Machine Learning Research %D 2024 %E Sanjoy Dasgupta %E Stephan Mandt %E Yingzhen Li %F pmlr-v238-karntikoon24a %I PMLR %P 4231--4239 %U https://proceedings.mlr.press/v238/karntikoon24a.html %V 238 %X Solving optimization problems leads to elegant and practical solutions in a wide variety of real-world applications. In many of those real-world applications, some of the information required to specify the relevant optimization problem is noisy, uncertain, and expensive to obtain. In this work, we study how much of that information needs to be queried in order to obtain an approximately optimal solution to the relevant problem. In particular, we focus on the shortest path problem in graphs with dynamic edge costs. We adopt the {\em first passage percolation} model from probability theory wherein a graph $G’$ is derived from a weighted base graph $G$ by multiplying each edge weight by an independently chosen, random number in $[1, \rho]$. Mathematicians have studied this model extensively when $G$ is a $d$-dimensional grid graph, but the behavior of shortest paths in this model is still poorly understood in general graphs. We make progress in this direction for a class of graphs that resemble real-world road networks. Specifically, we prove that if $G$ has a constant continuous doubling dimension, then for a given $s-t$ pair, we only need to probe the weights on $((\rho \log n )/ \epsilon)^{O(1)}$ edges in $G’$ in order to obtain a $(1 + \epsilon)$-approximation to the $s-t$ distance in $G’$. We also generalize the result to a correlated setting and demonstrate experimentally that probing improves accuracy in estimating $s-t$ distances.
APA
Karntikoon, K., Shen, Y., Gollapudi, S., Kollias, K., Schild, A. & K Sinop, A.. (2024). First Passage Percolation with Queried Hints. Proceedings of The 27th International Conference on Artificial Intelligence and Statistics, in Proceedings of Machine Learning Research 238:4231-4239 Available from https://proceedings.mlr.press/v238/karntikoon24a.html.

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