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Research PaperResearchia:202607.17024

Data Driven Block Replacement Scheduling

Aniruddhan Ganesaraman

Abstract

We develop data-driven algorithms for maintaining $N$ independent identical machines under a \textit{block replacement policy}, in which each machine is replaced upon failure and all machines are jointly replaced at regular intervals of length $k$. The goal is to learn the cost-minimizing interval $k^$ from operational data when the lifetime distribution is unknown. At each decision epoch, the operator selects $k \in \{1, 2, \ldots, K\}$, observes the resulting failure history (a mixture of comp...

Submitted: July 17, 2026Subjects: Mathematics; Mathematics

Description / Details

We develop data-driven algorithms for maintaining NN independent identical machines under a \textit{block replacement policy}, in which each machine is replaced upon failure and all machines are jointly replaced at regular intervals of length kk. The goal is to learn the cost-minimizing interval kβˆ—k^* from operational data when the lifetime distribution is unknown. At each decision epoch, the operator selects k∈{1,2,…,K}k \in \{1, 2, \ldots, K\}, observes the resulting failure history (a mixture of complete and right-censored lifetimes) and incurs a per-unit-time cost governed by the renewal function. We formulate this as a stochastic multi-armed bandit and propose Hoeffding- and Bernstein-based lower-confidence-bound algorithms achieving O(Klog⁑T)O(K \log T) regret, matching the Lai--Robbins lower bound. Exploiting a nested observation property unique to block replacement, correlated variants attain O((Kβˆ’kβˆ—)log⁑T)O((K-k^*)\log T) regret and require only O(1)O(1) direct pulls of suboptimal arms k<kβˆ—k < k^*. A complementary Kaplan--Meier renewal algorithm estimates the lifetime distribution nonparametrically from censored data, achieving almost-sure policy consistency and empirically near-zero incremental regret at long horizons. We additionally analyze two average-cost MDPs: a time-elapsed formulation establishing that block replacement is optimal within its policy class for any lifetime distribution, and an age-vector formulation proving a monotone threshold structure under increasing failure rate distributions and providing a gold-standard cost benchmark. Numerical experiments confirm the theoretical ordering and reveal structural cost gaps between optimal block and age-dependent replacement.


Source: arXiv:2607.15229v1 - http://arxiv.org/abs/2607.15229v1 PDF: https://arxiv.org/pdf/2607.15229v1 Original Link: http://arxiv.org/abs/2607.15229v1

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Date:
Jul 17, 2026
Topic:
Mathematics
Area:
Mathematics
Comments:
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