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Effects of Dicranopteris dichotoma on soil dissolved organic carbon in severely eroded red soil
We consider switched queueing networks with a mix of heavy-tailed (i.e., arrival processes with infinite variance) and exponential-type traffic and study the delay performance of the max-weight policy, known for its throughput optimality and asymptotic delay optimality properties. Our focus is on th...
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| Published in: | Mathematics of operations research 2018-05, Vol.43 (2), p.460 |
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| creator | Ren, Yinbang Li, Maokui Jiang, Jun Xie, Jinsheng |
| description | We consider switched queueing networks with a mix of heavy-tailed (i.e., arrival processes with infinite variance) and exponential-type traffic and study the delay performance of the max-weight policy, known for its throughput optimality and asymptotic delay optimality properties. Our focus is on the impact of heavy-tailed traffic on exponential-type queues/flows, which may manifest itself in the form of subtle rate-dependent phenomena. We introduce a novel class of Lyapunov functions (piecewise linear and nonincreasing in the length of heavy-tailed queues), whose drift analysis provides exponentially decaying upper bounds to queue-length tail asymptotics despite the presence of heavy tails. To facilitate a drift analysis, we employ fluid approximations, proving that if a continuous and piecewise linear function is also a “Lyapunov function” for the fluid model, then the same function is a “Lyapunov function” for the original stochastic system. Furthermore, we use fluid approximations and renewal theory in order to prove delay instability results, i.e., infinite expected delays in steady state. We illustrate the benefits of the proposed approach in two ways: (i) analytically, by studying the delay stability regions of single-hop switched queueing networks with disjoint schedules, providing a precise characterization of these regions for certain queues and inner and outer bounds for the rest. As a side result, we prove monotonicity properties for the service rates of different schedules that, in turn, allow us to identify “critical configurations” toward which the state of the system is driven, and that determine to a large extent delay stability; (ii) computationally, through a bottleneck identification algorithm, which identifies (some) delay unstable queues/flows in complex switched queueing networks by solving the fluid model from certain initial conditions. |
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Our focus is on the impact of heavy-tailed traffic on exponential-type queues/flows, which may manifest itself in the form of subtle rate-dependent phenomena. We introduce a novel class of Lyapunov functions (piecewise linear and nonincreasing in the length of heavy-tailed queues), whose drift analysis provides exponentially decaying upper bounds to queue-length tail asymptotics despite the presence of heavy tails. To facilitate a drift analysis, we employ fluid approximations, proving that if a continuous and piecewise linear function is also a “Lyapunov function” for the fluid model, then the same function is a “Lyapunov function” for the original stochastic system. Furthermore, we use fluid approximations and renewal theory in order to prove delay instability results, i.e., infinite expected delays in steady state. We illustrate the benefits of the proposed approach in two ways: (i) analytically, by studying the delay stability regions of single-hop switched queueing networks with disjoint schedules, providing a precise characterization of these regions for certain queues and inner and outer bounds for the rest. As a side result, we prove monotonicity properties for the service rates of different schedules that, in turn, allow us to identify “critical configurations” toward which the state of the system is driven, and that determine to a large extent delay stability; (ii) computationally, through a bottleneck identification algorithm, which identifies (some) delay unstable queues/flows in complex switched queueing networks by solving the fluid model from certain initial conditions.</description><identifier>ISSN: 0364-765X</identifier><identifier>EISSN: 1526-5471</identifier><language>eng</language><publisher>Linthicum: Institute for Operations Research and the Management Sciences</publisher><subject>Approximation ; Asymptotic methods ; Asymptotic properties ; Continuity (mathematics) ; Delay ; Dissolved organic carbon ; Drift ; Initial conditions ; Liapunov functions ; Linear functions ; Operations research ; Queues ; Schedules ; Soil erosion ; Stability ; Stability analysis ; Studies ; Switching theory ; Traffic ; Traffic congestion ; Traffic delay ; Upper bounds ; Weight</subject><ispartof>Mathematics of operations research, 2018-05, Vol.43 (2), p.460</ispartof><rights>Copyright Institute for Operations Research and the Management Sciences May 2018</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784</link.rule.ids></links><search><creatorcontrib>Ren, Yinbang</creatorcontrib><creatorcontrib>Li, Maokui</creatorcontrib><creatorcontrib>Jiang, Jun</creatorcontrib><creatorcontrib>Xie, Jinsheng</creatorcontrib><title>Effects of Dicranopteris dichotoma on soil dissolved organic carbon in severely eroded red soil</title><title>Mathematics of operations research</title><description>We consider switched queueing networks with a mix of heavy-tailed (i.e., arrival processes with infinite variance) and exponential-type traffic and study the delay performance of the max-weight policy, known for its throughput optimality and asymptotic delay optimality properties. Our focus is on the impact of heavy-tailed traffic on exponential-type queues/flows, which may manifest itself in the form of subtle rate-dependent phenomena. We introduce a novel class of Lyapunov functions (piecewise linear and nonincreasing in the length of heavy-tailed queues), whose drift analysis provides exponentially decaying upper bounds to queue-length tail asymptotics despite the presence of heavy tails. To facilitate a drift analysis, we employ fluid approximations, proving that if a continuous and piecewise linear function is also a “Lyapunov function” for the fluid model, then the same function is a “Lyapunov function” for the original stochastic system. Furthermore, we use fluid approximations and renewal theory in order to prove delay instability results, i.e., infinite expected delays in steady state. 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| ispartof | Mathematics of operations research, 2018-05, Vol.43 (2), p.460 |
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| language | eng |
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| source | Business Source Ultimate; JSTOR Archival Journals and Primary Sources Collection |
| subjects | Approximation Asymptotic methods Asymptotic properties Continuity (mathematics) Delay Dissolved organic carbon Drift Initial conditions Liapunov functions Linear functions Operations research Queues Schedules Soil erosion Stability Stability analysis Studies Switching theory Traffic Traffic congestion Traffic delay Upper bounds Weight |
| title | Effects of Dicranopteris dichotoma on soil dissolved organic carbon in severely eroded red soil |
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