Online Metric Tracking and Smoothing

We consider the online smoothing problem , in which a tracker is required to maintain distance no more than Δ≥0 from a time-varying signal f while minimizing its own movement. The problem is determined by a metric space ( X , d ) with an associated cost function c :ℝ→ℝ. Given a signal f 1 , f 2 ,…∈...

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Vydané v:Algorithmica Ročník 68; číslo 1; s. 133 - 151
Hlavní autori: Chen, Sixia, Russell, Alexander
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Boston Springer US 01.01.2014
Springer
Predmet:
Algorithm Analysis and Problem Complexity
Algorithmics. Computability. Computer arithmetics
Algorithms
Applied sciences
Computer Science
Computer science; control theory; systems
Computer Systems Organization and Communication Networks
Data Structures and Information Theory
Exact sciences and technology
Mathematics of Computing
Theoretical computing
Theory of Computation
Online algorithms
Randomized algorithms
On line
Tracking
Proximity
Metric space
Fixed cost
Competitiveness
Algorithmics
Online algorithm
Randomized algorithm
Time varying system
Smoothing
Metric
Deterministic algorithms
ISSN:0178-4617, 1432-0541
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Popis
Shrnutí:We consider the online smoothing problem , in which a tracker is required to maintain distance no more than Δ≥0 from a time-varying signal f while minimizing its own movement. The problem is determined by a metric space ( X , d ) with an associated cost function c :ℝ→ℝ. Given a signal f 1 , f 2 ,…∈ X the tracker is responsible for producing a sequence a 1 , a 2 ,… of elements of X that meet the proximity constraint: d ( f i , a i )≤Δ. To complicate matters, the tracker is on-line—the value a i may only depend on f 1 ,…, f i —and wishes to minimize the cost of his travels, ∑ c ( d ( a i , a i +1 )). We evaluate such tracking algorithms competitively, comparing this with the cost achieved by an optimal adversary apprised of the entire signal in advance. The problem was originally proposed by Yi and Zhang (In: Proceedings of the 20th annual ACM-SIAM symposium on discrete algorithms (SODA), pp. 1098–1107. ACM Press, New York, 2009 ), who considered the natural circumstance where the metric spaces are taken to be ℤ k with the ℓ 2 metric and the cost function is equal to 1 unless the distance is zero (thus the tracker pays a fixed cost for any nonzero motion). We begin by studying arbitrary metric spaces with the “pay if you move” metric of Yi and Zhang (In: Proceedings of the 20th annual ACM-SIAM symposium on discrete algorithms (SODA), pp. 1098–1107. ACM Press, New York, [ 2009 ]) described above and describe a natural randomized algorithm that achieves a O (log b Δ )-competitive ratio, where b Δ =max x ∈ X | B Δ ( x )| is the maximum number of points appearing in any ball of radius Δ. We show that this bound is tight. We then focus on the metric space ℤ with natural families of monotone cost functions c ( x )= x p for some p ≥0. We consider both the expansive case ( p ≥1) and the contractive case ( p <1), and show that the natural lazy algorithm performs well in the expansive case. In the contractive case, we introduce and analyze a novel deterministic algorithm that achieves a constant competitive ratio depending only on p . Finally, we observe that by slightly relaxing the guarantee provided by the tracker, one can obtain natural analogues of these algorithms that work in continuous metric spaces.
ISSN:0178-4617
1432-0541
DOI:10.1007/s00453-012-9669-8