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A service system with packing constraint...
Stolyar, Alexander...

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A service system with packing constraints: Greedy randomized algorithm achieving sublinear in scale optimality gap by Stolyar, Alexander ( Author )
Lemonjar Open Access
Australian National University
29-08-2023
A service system with multiple types of arriving customers is considered. There is an infinite number of homogeneous servers. Multiple customers can be placed for simultaneous service into one server, subject to general packing constraints. Each new arriving customer is placed for service immediately, either into an occupied server, as long as packing constraints are not violated, or into an empty server. After service completion, each customer leaves its server and the system. The basic objective is to minimize the number of occupied servers in steady state. We study a Greedy-Random (GRAND) placement (packing) algorithm, introduced in [23]. This is a simple online algorithm, which places each arriving customer uniformly at random into either one of the already occupied servers that can still fit the customer, or one of the so-called zero-servers, which are empty servers designated to be available to new arrivals. In [23], a version of the algorithm, labeled GRAND($aZ$), was considered, where the number of zero servers is $aZ$, with $Z$ being the current total number of customers in the system, and $a>0$ being an algorithm parameter. GRAND($aZ$) was shown in [23] to be asymptotically optimal in the following sense: (a) the steady-state optimality gap grows linearly in the system scale $r$ (the mean total number of customers in service), i.e. as $c(a) r$ for some $c(a)> 0$; and (b) $c(a) \to 0$ as $a\to 0$. In this paper, we consider the GRAND($Z^p$) algorithm, in which the number of zero-servers is $Z^p$, where $p \in (1-1/(8\kappa),1)$ is an algorithm parameter, and $(\kappa-1)$ is the maximum possible number of customers that a server can fit. We prove the asymptotic optimality of GRAND($Z^p$) in the sense that the steady-state optimality gap is $o(r)$, sublinear in the system scale. This is a stronger form of asymptotic optimality than that of GRAND($aZ$).
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English
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MYR 0.01
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http://arxiv.org/abs/1511.03241
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