Stochastic Colored Petri Net Models for Rainbow Optical Networks

Giuliana Annamaria FRANCESCHINIS; FUMAGALLI A.; SILINGUELLI A.

doi:10.1007/BFb0097780

Stochastic Colored Petri Net Models for Rainbow Optical Networks

Giuliana Annamaria FRANCESCHINIS, FUMAGALLI A., SILINGUELLI A.

Dipartimento di Scienze e Innovazione Tecnologica

Risultato della ricerca: Capitolo in libro/report/atti di convegno › Contributo in volume (Capitolo o Saggio) › peer review

Abstract

In this paper, Stochastic Well-formed Nets (SWN) are used to model an optical multi-receiver system and study its performance. A novel approach to resolving packet contention (loss), occurring in optical multi-receiver nodes when the number of packets concurrently reaching the node exceeds the number of available receivers, is presented: it is based on the combined use of fiber delay lines and photonic switches, to temporarily store (delay) optical packets prior to reception. In order to effectively delay the contending packets and improve the multi-receiver throughput three novel control strategies are presented and their performance analyzed using SWN models. Techniques specific to this formalism are applied to cope with the state space explosion problem. A further optimization is achieved by altering the models in such a way that exact performance results can be obtained with reduced computational complexity.

Lingua originale	Inglese
Titolo della pubblicazione ospite	Application of Petri Nets to Communication Networks - Advances in Petri Nets
Editore	SPRINGER
Pagine	273-303
Numero di pagine	31
Volume	1605
ISBN (stampa)	9783540658702
DOI	https://doi.org/10.1007/BFb0097780
Stato di pubblicazione	Pubblicato - 1 gen 1999

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title = "Stochastic Colored Petri Net Models for Rainbow Optical Networks",

abstract = "In this paper, Stochastic Well-formed Nets (SWN) are used to model an optical multi-receiver system and study its performance. A novel approach to resolving packet contention (loss), occurring in optical multi-receiver nodes when the number of packets concurrently reaching the node exceeds the number of available receivers, is presented: it is based on the combined use of fiber delay lines and photonic switches, to temporarily store (delay) optical packets prior to reception. In order to effectively delay the contending packets and improve the multi-receiver throughput three novel control strategies are presented and their performance analyzed using SWN models. Techniques specific to this formalism are applied to cope with the state space explosion problem. A further optimization is achieved by altering the models in such a way that exact performance results can be obtained with reduced computational complexity.",

author = "FRANCESCHINIS, \{Giuliana Annamaria\} and FUMAGALLI A. and SILINGUELLI A.",

year = "1999",

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publisher = "SPRINGER",

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Stochastic Colored Petri Net Models for Rainbow Optical Networks. / FRANCESCHINIS, Giuliana Annamaria; A., FUMAGALLI; A., SILINGUELLI.
Application of Petri Nets to Communication Networks - Advances in Petri Nets. Vol. 1605 SPRINGER, 1999. pag. 273-303.

Risultato della ricerca: Capitolo in libro/report/atti di convegno › Contributo in volume (Capitolo o Saggio) › peer review

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N2 - In this paper, Stochastic Well-formed Nets (SWN) are used to model an optical multi-receiver system and study its performance. A novel approach to resolving packet contention (loss), occurring in optical multi-receiver nodes when the number of packets concurrently reaching the node exceeds the number of available receivers, is presented: it is based on the combined use of fiber delay lines and photonic switches, to temporarily store (delay) optical packets prior to reception. In order to effectively delay the contending packets and improve the multi-receiver throughput three novel control strategies are presented and their performance analyzed using SWN models. Techniques specific to this formalism are applied to cope with the state space explosion problem. A further optimization is achieved by altering the models in such a way that exact performance results can be obtained with reduced computational complexity.

AB - In this paper, Stochastic Well-formed Nets (SWN) are used to model an optical multi-receiver system and study its performance. A novel approach to resolving packet contention (loss), occurring in optical multi-receiver nodes when the number of packets concurrently reaching the node exceeds the number of available receivers, is presented: it is based on the combined use of fiber delay lines and photonic switches, to temporarily store (delay) optical packets prior to reception. In order to effectively delay the contending packets and improve the multi-receiver throughput three novel control strategies are presented and their performance analyzed using SWN models. Techniques specific to this formalism are applied to cope with the state space explosion problem. A further optimization is achieved by altering the models in such a way that exact performance results can be obtained with reduced computational complexity.

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BT - Application of Petri Nets to Communication Networks - Advances in Petri Nets

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Stochastic Colored Petri Net Models for Rainbow Optical Networks

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