Online Supervisory Control and Resource Management for Energy Harvesting BS Sites Empowered with Computation Capabilities

Dlamini, Thembelihle; Gambı́n, Ángel Fernández; Munaretto, Daniele; Rossi, Michele

doi:10.1155/2019/8593808

Cited by 13 publications

(24 citation statements)

References 38 publications

(63 reference statements)

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“…In [35], the network impact is used to identify the BS to be switched off within a cluster, one at a time, with no significant network performance degradation. Moreover, the network impact has been used in [36] to identify a BS to be switched off within a BS cluster where each BS is empowered with computation capabilities. With the advent of EH, it is desirable to incorporate the green energy utilization as a performance metric in traffic load balancing strategies [37,38].…”

Section: Sleep-modes Strategies In Mnsmentioning

confidence: 99%

“…In [17], a dynamic resource provisioning framework for a virtualized computing environment is presented and it is experimentally validated on a small server cluster that provides online services. Along the lines of MEC [28,36], the long-term short memory (LSTM) neural network is used for forecasting the traffic load and harvested energy, and then the limited lookahead control (LLC) technique uses the forecasted traffic load and harvested energy to obtain the best control input that will drive the edge systems into the desired behavior.…”

Section: Energy Savings In Virtualized Platforms Using Soft-scalingmentioning

confidence: 99%

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Softwarization in Future Mobile Networks and Energy Efficient Networks

Dlamini¹

2020

Mobile Computing

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The data growth generated by pervasive mobile devices and the Internet of Things at the network edge (i.e., closer to mobile users), couple with the demand for ultra-low latency, requires high computation resources which are not available at the end-user device. This demands a new network design paradigm in order to handle user demands. As a remedy, a new MN network design paradigm has emerged, called Mobile Edge Computing (MEC), to enable low-latency and locationaware data processing at the network edge. MEC is based on network function virtualization (NFV) technology, where mobile network functions (NFs) that formerly existed in the evolved packet core (EPC) are moved to the access network [i.e., they are deployed on local cloud platforms in proximity to the base stations (BSs)]. In order to reap the full benefits of the virtualized infrastructure, the NFV technology shall be combined with intelligent mechanisms for handling network resources. Despite the potential benefits presented by MEC, energy consumption is a challenge due to the foreseen dense deployment of BSs empowered with computation capabilities. In the effort to build greener 5G mobile network (MN), we advocate the integration of energy harvesting (EH) into future edge systems.

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Section: Sleep-modes Strategies In Mnsmentioning

confidence: 99%

Section: Energy Savings In Virtualized Platforms Using Soft-scalingmentioning

confidence: 99%

Softwarization in Future Mobile Networks and Energy Efficient Networks

Dlamini¹

2020

Mobile Computing

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“…In [6], computing resources are provisioned depending on the expected server workloads via a reinforcement learning-based resource management algorithm, which learns the optimal policy for dynamic workload offloading and servers autoscaling. Our previous works in [7] and [17], focus on the provision of computing resources (VMs) based on a Limited Lookahead Control (LLC) policy and the network impact (the use of traffic load as a performance metric [18]), after forecasting the future workloads and harvested energy. A single Base Station (BS) optimization case is considered for an off-grid site in [7], and a multiple BS optimization case, each BS site powered by hybrid energy sources, is studied in [17] where the edge management procedures are enabled by an edge controller.…”

Section: B Related Workmentioning

confidence: 99%

“…Our previous works in [7] and [17], focus on the provision of computing resources (VMs) based on a Limited Lookahead Control (LLC) policy and the network impact (the use of traffic load as a performance metric [18]), after forecasting the future workloads and harvested energy. A single Base Station (BS) optimization case is considered for an off-grid site in [7], and a multiple BS optimization case, each BS site powered by hybrid energy sources, is studied in [17] where the edge management procedures are enabled by an edge controller. This work differs from our previous works as the MEC server is placed in proximity to a BS cluster, and not one co-located for each BS.…”

Section: B Related Workmentioning

confidence: 99%

Adaptive Resource Management for a Virtualized Computing Platform within Edge Computing

Dlamini¹,

Gambı́n

2019

2019 16th Annual IEEE International Conference on Sensing, Communication, and Networking (SECON)

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In virtualized computing platforms, energy consumption is related to the computing-plus-communication processes. However, most of the proposed energy consumption models and energy saving solutions found in literature consider only the active Virtual Machines (VMs), thus the overall operational energy expenditure is usually related to solely the computation process. To address this shortcoming, in this paper we consider a computing-plus-communication energy model, within the Multiaccess Edge Computing (MEC) paradigm, and then put forward a combination of a traffic engineering-and MEC Location Service-based online server management algorithm with Energy Harvesting (EH) capabilities, called Automated Resource Controller for Energy-aware Server (ARCES), for autoscaling and reconfiguring the computing-plus-communication resources. The main goal is to minimize the overall energy consumption, under hard per-task delay constraints (i.e., Quality of Service (QoS)). ARCES jointly performs (i) a short-term server demand and harvested solar energy forecasting, (ii) VM soft-scaling, workload and processing rate allocation and lastly, (iii) switching on/off of transmission drivers (i.e., fast tunable lasers) coupled with the location-aware traffic scheduling. Our numerical results reveal that ARCES achieves on average energy savings of 69%, and an energy consumption ranging from 31%-45%and from 21%-25% at different values of per-VM reconfiguration cost, with respect to the case where no energy management is applied.

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“…An example considers BSs equipped with EH capabilities and may reduce thus by the same occasion energy consumption. The authors in [109] suggest to optimize the BSs and virtual MEC resources use following traffic load and forecasted harvested energy parameters. The heuristic optimization employs sleep mode for BS and softscaling for Virtual machines.…”

Section: Rf-eh Enabled Mecmentioning

confidence: 99%

Overview on 5G Radio Frequency Energy Harvesting

Hassani¹,

Hassani²,

Boutammachte³

2019

Adv. sci. technol. eng. syst. j.

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The current industrial landscape is becoming increasingly aware of the need to optimize energy use and management for all domains, including telecommunications. Among others, RF Energy Harvesting is a promising technique for 5G systems as an alternative to traditional energy supply sources. This paper presents 5G landscape and ecosystem. It positions RF-Energy Harvesting in 5G context and reviews its techniques. It also considers constraints and research trends for different aspects needed to make RF energy harvesting ready for deployment along with 5G enabling technologies.

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Online Supervisory Control and Resource Management for Energy Harvesting BS Sites Empowered with Computation Capabilities

Cited by 13 publications

References 38 publications

Softwarization in Future Mobile Networks and Energy Efficient Networks

Softwarization in Future Mobile Networks and Energy Efficient Networks

Adaptive Resource Management for a Virtualized Computing Platform within Edge Computing

Overview on 5G Radio Frequency Energy Harvesting

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