RT info:eu-repo/semantics/article
T1 PID controller based on a self-adaptive neural network to ensure qos bandwidth requirements in passive optical networks
A1 Merayo Álvarez, Noemí
A1 Juárez Estévez, David
A1 Aguado Manzano, Juan Carlos
A1 Miguel Jiménez, Ignacio de
A1 Durán Barroso, Ramón José
A1 Fernández Reguero, Patricia
A1 Lorenzo Toledo, Rubén Mateo
A1 Abril Domingo, Evaristo José
K1 Red neuronal (NN)
K1 Red óptica pasiva (PON)
K1 Neural  network  (NN)
K1 Passive  optical  network  (PON)
AB In this paper, a proportional-integral-derivative (PID) controller integrated with a neural network (NN) is proposed to ensure quality of service (QoS) bandwidth requirements in passive optical networks (PONs). To the best of our knowledge, this is the first time an approach that implements a NN to tune a PID to deal with QoS in PONs is used. In contrast to other tuning techniques such as Ziegler-Nichols or genetic algorithms (GA), our proposal allows a real-time adjustment of the tuning parameters according to the network conditions. Thus, the new algorithm provides an online control of the tuning process unlike the ZN and GA techniques, whose tuning parameters are calculated offline. The algorithm, called neural network service level PID (NNSPID), guarantees minimum bandwidth levels to users depending on their service level agreement, and it is compared with a tuning technique based on genetic algorithms (GASPID). The simulation study demonstrates that NN-SPID continuously adapts the tuning parameters, achieving lower fluctuations than GA-SPID in the allocation process. As a consequence, it provides a more stable response than GA-SPID since it needs to launch the GA to obtain new tuning values. Furthermore, NN-SPID guarantees the minimum bandwidth levels faster than GA-SPID. Finally, NN-SPID is more robust than GA-SPID under real-time changes of the guaranteed bandwidth levels, as GA-SPID shows high fluctuations in the allocated bandwidth, especially just after any change is made.
PB Institute of Electrical and Electronics Engineers (IEEE)
SN 1943-0639
YR 2017
FD 2017
LK http://uvadoc.uva.es/handle/10324/33487
UL http://uvadoc.uva.es/handle/10324/33487
LA eng
NO IEEE/OSA Journal of Optical Communications and Networking, 2017, Volume 9, Issue 5, pp.  433 - 445
NO Producción Científica
DS UVaDOC
RD 29-abr-2024