Renewable Energy Sharing Among Base Stations as a Min-Cost-Max-Flow Optimization Problem

Benda, Doris; Chu, Xiaoli; Sun, Sumei; Quek, Tony Q. S.; Buckley, Alastair

doi:10.1109/tgcn.2018.2876005

Cited by 15 publications

(7 citation statements)

References 17 publications

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“…is algorithm is well-known and widely used in cloud resource allocation [38], energy sharing management [39], resource management [40,41], and network traffic management [42,43].…”

Section: Relocation Optimizationmentioning

confidence: 99%

Recurrent Neural-Based Vehicle Demand Forecasting and Relocation Optimization for Car-Sharing System: A Real Use Case in Thailand

Vateekul

Sri-iesaranusorn

Aiemvaravutigul

et al. 2021

Journal of Advanced Transportation

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A car-sharing system has been playing an important role as an alternative transport mode in order to avoid traffic congestion and pollution due to a quick growth of usage of private cars. In this paper, we propose a novel vehicle relocation system with a major improvement in threefolds: (i) data preprocessing, (ii) demand forecasting, and (iii) relocation optimization. The data preprocessing is presented in order to automatically remove fake demands caused by search failures and application errors. Then, the real demand is forecasted using a deep learning approach, Bidirectional Gated Recurrent Unit. Finally, the Minimum Cost Maximum Flow algorithm is deployed to maximize forecasted demands, while minimizing the amount of relocations. Furthermore, the system is deployed in the real use case, entitled “CU Toyota Ha:mo,” which is a car-sharing system in Chulalongkorn University. It is based on a web application along with rule-based notification via Line. The experiment was conducted based on the real vehicle usage data in 2019. By comparing in real environment in November of 2019, the results show that our model even outperforms the manual relocation by experienced staff. It achieved a 3% opportunity loss reduction and 3% less relocation trips, reducing human effort by 17 man-hours/week.

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“…is algorithm is well-known and widely used in cloud resource allocation [38], energy sharing management [39], resource management [40,41], and network traffic management [42,43].…”

Section: Relocation Optimizationmentioning

confidence: 99%

Recurrent Neural-Based Vehicle Demand Forecasting and Relocation Optimization for Car-Sharing System: A Real Use Case in Thailand

Vateekul

Sri-iesaranusorn

Aiemvaravutigul

et al. 2021

Journal of Advanced Transportation

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“…For each work in more detail, D. Niyato et al [123] investigated the performance of a solar-powered wireless sensor/mesh network in terms of packet blocking and dropping probabilities with the presented queuing model. Given the fact that as the period of BS's off state increases, the packet blocking probability also increases while the packet dropping [95], [113], [114] [82], [100], [102] [103], [115] [84], [95], [100], [103] [107], [114] [38], [79]- [81] [84], [88], [89] [107] [116], [117] Minimizing the total energy (on-grid and RE) cost [118] Minimizing the net energy cost in smart grid [21] Maximizing the network utility [55], [99], [101] [76], [99] [76] Minimizing the network latency [39], [85] [57], [58] Maximizing the weighted sum of on-grid consumption and user QoS metric [40] [40], [41] [42]- [44] [86], [87], [108] [41], [108] Maximizing the utilization of RE [104] [82], [104] Maximizing the energy efficiency [96], [105] [47], [105] Minimizing the cost of using conventional energy source [106] [83], [93] [36], [37], [91] [6...…”

Section: Design and Optimization Issuesmentioning

confidence: 99%

“…The regarding works determine the amount of wired energy transaction among the BSs or between BS and smart grid or both. With the optimal amount, grid power consumption can be minimized [89], [107], [116], [117]. In the case of energy sharing through physical power line between two BSs, it was shown that 80% of grid power consumption can be saved [89].…”

Section: Bs Cooperation 1) Coordinated Multipoint (Comp)mentioning

confidence: 99%

“…Nevertheless, the work did not consider the distance between two BSs which affects power losses. Considering the topology of the cellular network, D. Benda et al proposed two algorithms and compared their results [116]. First one was aware of the distance-dependent power loss in the transmission line and the other one was not.…”

Section: Bs Cooperation 1) Coordinated Multipoint (Comp)mentioning

confidence: 99%

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Renewable Energy-Enabled Cellular Networks

Ko¹,

Jung²,

Park³

et al. 2021

Preprint

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<div> <div> <div> <p>Renewable energy (RE)-powered base stations (BSs) have been considered as an attractive solution to address the exponential increasing energy demand in cellular networks while decreasing carbon dioxide (CO2) emissions. For the regions where reliable power grids are insufficient and infeasible to deploy, such as aerial platforms and harsh environments, RE has been an alternative power source for BSs. In this survey paper, we provide an overview of RE-enabled cellular networks, detailing their analysis, classification, and related works. First, we introduce the key components of RE-powered BSs along with their frequently adopted models. Second, we analyze the proposed strategies and design issues for RE-powered BSs that can be incorporated into cellular networks and categorize them into several groups to provide a good grasp. Third, we introduce feasibility studies on RE-powered BSs based on the recent literature. Fourth, we investigate RE-powered network components other than terrestrial BSs to address potential issues regarding RE-enabled networks. Finally, we suggest future research directions and conclusions. </p><p><br></p> </div> </div> </div>

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“…The amount of solar power generation is may be higher or lower in accordance with tempo-spatial traffic diversity and solar radiation intensity which often causes a mismatch with the BS load consumption. The concept of sharing surplus electricity among neighboring BSs via smart grid or external physical transmission lines has been recognized as an emerging solution in some literature [26]- [28]. An efficient energy cooperation framework among collocated BSs via smart grid based on the level of a priori knowledge about RE generation has been proposed in [28].…”

Section: Introductionmentioning

confidence: 99%

Toward Energy Efficiency Aware Renewable Energy Management in Green Cellular Networks With Joint Coordination

Jahid¹,

Islam

Hossain³

et al. 2019

IEEE Access

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In this paper, we focus on an essential energy management approach for enhancing energy efficiency (EE) as well as reducing fuel consumption of off-grid cellular networks whose base stations (BSs) are supplied with hybrid power sources including solar PV array and diesel generator (DG). To take the full advantage of PV technology, this paper examines the reliability performance and carbon footprint implications in addition to EE. This paper also investigates the benefits of unevenly harvested green energy sharing mechanism under zero fuel consumption scheme via physically installed resistive power lines taking into account of dynamic nature of renewable energy (RE) generation and traffic arrival density. Furthermore, joint transmission coordinated multipoint (JT-CoMP) user association technique is integrated for achieving higher throughput and EE performance providing the best SINR quality to a connected user equipment (UE). A comprehensive Monte-Carlo based simulation study has been carried out for evaluating EE, EE index (EEI), and energy saving performances in downlink LTE-advanced networks under a wide range of network settings. The results reveal that the proposed system can attain up to 26% energy savings via cooperation mechanism and 48.7% more energy efficient in terms of EEI under peak load over the conventional hybrid paradigm. INDEX TERMS Renewable energy management, Green cellular network, Energy efficiency, Joint coordination, LTE-A.

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Renewable Energy Sharing Among Base Stations as a Min-Cost-Max-Flow Optimization Problem

Cited by 15 publications

References 17 publications

Recurrent Neural-Based Vehicle Demand Forecasting and Relocation Optimization for Car-Sharing System: A Real Use Case in Thailand

Recurrent Neural-Based Vehicle Demand Forecasting and Relocation Optimization for Car-Sharing System: A Real Use Case in Thailand

Renewable Energy-Enabled Cellular Networks

Toward Energy Efficiency Aware Renewable Energy Management in Green Cellular Networks With Joint Coordination

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