Skyline Computation with Noisy Comparisons
Given a set of $n$ points in a $d$-dimensional space, we seek to compute the skyline, i.e., those points that are not strictly dominated by any other point, using few comparisons between elements. We adopt the noisy comparison model [FRPU94] where comparisons fail with constant probability and confi...
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| creator | Groz, Benoît Mallmann-Trenn, Frederik Mathieu, Claire Verdugo, Victor |
| description | Given a set of $n$ points in a $d$-dimensional space, we seek to compute the
skyline, i.e., those points that are not strictly dominated by any other point,
using few comparisons between elements. We adopt the noisy comparison model
[FRPU94] where comparisons fail with constant probability and confidence can be
increased through independent repetitions of a comparison. In this model
motivated by Crowdsourcing applications, Groz & Milo [GM15] show three bounds
on the query complexity for the skyline problem. We improve significantly on
that state of the art and provide two output-sensitive algorithms computing the
skyline with respective query complexity $O(nd\log (dk/\delta))$ and $O(ndk\log
(k/\delta))$ where $k$ is the size of the skyline and $\delta$ the expected
probability that our algorithm fails to return the correct answer. These
results are tight for low dimensions. |
| doi_str_mv | 10.48550/arxiv.1710.02058 |
| format | Article |
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skyline, i.e., those points that are not strictly dominated by any other point,
using few comparisons between elements. We adopt the noisy comparison model
[FRPU94] where comparisons fail with constant probability and confidence can be
increased through independent repetitions of a comparison. In this model
motivated by Crowdsourcing applications, Groz & Milo [GM15] show three bounds
on the query complexity for the skyline problem. We improve significantly on
that state of the art and provide two output-sensitive algorithms computing the
skyline with respective query complexity $O(nd\log (dk/\delta))$ and $O(ndk\log
(k/\delta))$ where $k$ is the size of the skyline and $\delta$ the expected
probability that our algorithm fails to return the correct answer. These
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skyline, i.e., those points that are not strictly dominated by any other point,
using few comparisons between elements. We adopt the noisy comparison model
[FRPU94] where comparisons fail with constant probability and confidence can be
increased through independent repetitions of a comparison. In this model
motivated by Crowdsourcing applications, Groz & Milo [GM15] show three bounds
on the query complexity for the skyline problem. We improve significantly on
that state of the art and provide two output-sensitive algorithms computing the
skyline with respective query complexity $O(nd\log (dk/\delta))$ and $O(ndk\log
(k/\delta))$ where $k$ is the size of the skyline and $\delta$ the expected
probability that our algorithm fails to return the correct answer. These
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skyline, i.e., those points that are not strictly dominated by any other point,
using few comparisons between elements. We adopt the noisy comparison model
[FRPU94] where comparisons fail with constant probability and confidence can be
increased through independent repetitions of a comparison. In this model
motivated by Crowdsourcing applications, Groz & Milo [GM15] show three bounds
on the query complexity for the skyline problem. We improve significantly on
that state of the art and provide two output-sensitive algorithms computing the
skyline with respective query complexity $O(nd\log (dk/\delta))$ and $O(ndk\log
(k/\delta))$ where $k$ is the size of the skyline and $\delta$ the expected
probability that our algorithm fails to return the correct answer. These
results are tight for low dimensions.</abstract><doi>10.48550/arxiv.1710.02058</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Data Structures and Algorithms |
| title | Skyline Computation with Noisy Comparisons |
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