Computers, Materials & Continua
DOI:10.32604/cmc.2021.016738
Tech Science Press
Article
Toward Optimal Cost-Energy Management Green
Framework for Sustainable Future Wireless Networks
Mohammed H. Alsharif 1 , Abu Jahid2 , Mahmoud A. Albreem3 , Peerapong Uthansakul4, *
Jamel Nebhen5 and Khalid Yahya6
1
Department of Electrical Engineering, College of Electronics and Information Engineering,
Sejong University, Seoul, 05006, Korea
2
Department of Electrical and Computer Engineering, University of Ottawa, Ottawa, K1N 6N5, ON, Canada
3
Department of Electronics and Communications Engineering, A’Sharqiyah University, Ibra, 400, Oman
4
School of Telecommunication Engineering, Suranaree University of Technology, Nakhon Ratchasima, Thailand
5
College of Computer Engineering and Sciences, Prince Sattam bin Abdulaziz University, Alkharj, 11942, Saudi Arabia
6
Department of Mechatronics, Faculty of Engineering and Architecture, Istanbul Gelisim University, Istanbul, 34310, Turkey
*
Corresponding Author: Peerapong Uthansakul. Email: uthansakul@sut.ac.th
Received: 07 January 2021; Accepted: 10 February 2021
Abstract: The design of green cellular networking according to the traffic
arrivals has the capability to reduce the overall energy consumption to a
cluster in a cost-effective way. The cell zooming approach has appealed much
attention that adaptively offloads the BS load demands adjusting the transmit
power based on the traffic intensity and green energy availability. Besides,
the researchers are focused on implementing renewable energy resources,
which are considered the most attractive practices in designing energy-efficient
wireless networks over the long term in a cost-efficient way in the existing
infrastructure. The utilization of available solar can be adapted to acquire
cost-effective and reliable power supply to the BSs, especially that sunlight
is free, available everywhere, and a good alternative energy option for the
remote areas. Nevertheless, planning a photovoltaic scheme necessitates viability assessment to avoid poor power supply, particularly for BSs. Therefore,
cellular operators need to consider both technical and economic factors before
the implementation of solar-powered BSs. This paper proposed the usercentric cell zooming policy of solar-powered cellular base stations taking into
account the optimal technical criteria obtained by the HOMER software tool.
The results have shown that the proposed system can provide operational
expenditure (OPEX) savings of up to 47%. In addition, the efficient allocation
of resource blocks (RBs) under the cell zooming technique attain remarkable
energy-saving performance yielding up to 27%.
Keywords: Wireless networks; beyond 5G;
sustainability; OPEX; communication systems
green
communications
This work is licensed under a Creative Commons Attribution 4.0 International License,
which permits unrestricted use, distribution, and reproduction in any medium, provided
the original work is properly cited.
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1 Introduction
1.1 Background and Motivation
The energy consumption rate of information and communication technology (ICT) has
increased rapidly over the last few decades owing to the excessive demand for multimedia services. Wireless networks are considered one of the main sources of energy consumption in the
ICT arena [1]. Among the wireless network components, base stations (BSs) are considered a
paramount source of energy consumption, accounting for 57% of the total energy used [2].
In the last decade, wireless network operators are focused on providing a high data transfer
rate with large radio coverage to satisfy the demand of subscribers. Therefore, wireless network
operators have largely increased the BS numbers to deliver a high data rate to enormous wireless
devices and access point nodes. Consequently, both the energy consumption and operational
expenditure (OPEX) have notably increased i.e., linearly scaled with the augmentation of intensive
user requirements [3]. Recently, the massive connectivity of IoT devices incorporated with wireless
access networks led to tremendous energy consumption; it is expected to increases enormously
in the future due to the diverse type of IoT applications [4]. Thus, the primary focuses of
wireless network operators are became provisioning a high data rate with attention to energyefficient issue simultaneously. Moreover, the increasing concerns of the wireless network operators
about energy consumption not only to increase savings in OPEX but also due to the growing
awareness of global warming issues and ecological concerns [5]. Therefore, the researchers and
experts are endeavoring to determine the optimum approaches to diminish the energy consumption
rate notably for the wireless networks while persisting with desired data services.
Researchers are focused on numerous distinctive approaches to reduce the energy consumption into wireless networks such as energy-efficient hardware components, selective operation
of components, efficient use of radio transmission process, deploying heterogeneous cells, and
implementing renewable energy resources (RESs) [6]. RESs are considered the most attractive
practices in designing energy-efficient wireless networks over the long term in a cost-efficient way
in the existing infrastructure [7]. Nonetheless, the commissioning of RES-powered BSs is based
on the availability of wind profile/solar irradiation that hinges on the latitude, seasonal disparities,
and ecological circumstances. Besides, cannot ignore the amount of energy that is wasted due to
the lack of efficient utilization of resources. Whereas, the infrastructures of the BSs have been
designed to support daytime traffic i.e., (peak time). However, the traffic loads during the daytime
differ from those during the night [8]. Therefore, the BSs must effectively deal with the resources
to achieve efficient energy utilization and better saving.
1.2 Contributions
Considering all these inferences, researchers have insufficient descriptions for the total OPEX
savings including optimum extent efficient solution of RESs. Therefore, this study examines as
a major contribution achieve a balance between network performance and energy efficiency via
examines the feasibility of incorporating solar-powered BSs technique with a dynamic cell zooming strategy according to the traffic load conditions in Korea to determine the net OPEX savings.
The contributions of this work are summarized as follows:
• To propose and determine the technical feasibility of an adaptive standalone solar power
solution incorporating a dynamic cell zooming strategy based on resource susceptibility to
obtain a long-tenure energy balance.
• To investigate the optimal solution of harvested green energy for the considered cellular
architecture endeavoring to minimum net present cost as well as OPEX savings.
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• To examine the technical viability in terms of energy yield, cost-effectiveness in accordance
with optimum system design. Thereafter, the suggested framework is compared to other
techniques for further validation.
1.3 Paper Organization
The rest of this work is organized as follows; Section 2 presents the cell zooming concept
and performance metrics. Section 3 block diagram of BS hardware elements and mathematical
modeling. Section 4 shows the proposed solar power system and mathematical formulations. The
cost optimization formula is given in Section 5. Section 6 presents the simulation configurations.
Then, results and discussion are described in Section 7; and the economic feasibility of the
proposed solar system is discussed. Lastly, Section 8 concludes the work by highlighting the
attained results.
2 Cell Zooming and Performance Metrics
2.1 Cell Zooming Concept
The principle cell zooming strategy depends on the capability of allowing for the adjustment
of the size of the cell according to the traffic load. When congestion occurs in a cell due to
an increase in the number of users, the congested cell could “zoom-in,” while neighboring cells
with a smaller amount of traffic could “zoom-out” to provide coverage for the users that cannot
be served by the congested cell [9]. The incoming traffic arrival intensity depends on the tempospatial domains as it changes over time and space owing to the user mobility. For example, the
commercial area experiences high traffic demand whereas, lower in the residential area particularly
in the day time. The scenarios are getting reverse during the evening period. Cell zooming is
an effective method for improving energy efficiency by adjusting traffic load. The centralized
control server coordinates traffic demand and make zooming out decision accordingly. If the
traffic intensity of the considered BS is higher than the threshold value, the control server sends
information to zoom in the cell size. On the other hand, the BS under test moves to sleep mode if
UEs are shifted to neighboring BSs or when the traffic intensity becomes much lower. Under this
case, the surrounding BSs zooms out to serve new incoming users via a control server through
cooperation. Thereby, the sleep mode provision governed by the cell zooming technique enables to
reduce of additional energy consumption. Fig. 1 summarises the proposed cell zooming strategy.
The infrastructures of the cellular networks have been designed to support daytime traffic i.e.,
(peak time). However, the traffic loads during the daytime differ from those during the night, as
shown in Fig. 2. Thus, the BSs must effectively deal with the traffic load to achieve efficient energy
utilization and better saving.
Figure 1: Cell zooming concept in cellular networks; (a) Original size; (b) Central cell zooms in
when the load increases; (c) Central cell zooms out when the load decreases
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Figure 2: The daily traffic load pattern of a BS
If the traffic density in a particular BS is below the threshold value, then the particular BS
shifts its loads to the neighboring BSs according to their current traffic status and the BS goes
into sleep mode to reduce energy consumption. In such a case, the accepting BSs can zoom out
to serve the new arrivals in a cooperative manner. Note that the provision of sleep mode is
appropriate for low traffic density under off-peak duration. However, the neighboring BSs can only
serve the incoming BSs based on their unoccupied resource blocks and green energy availability
without sacrificing its own performance. In other words, the acceptor BSs adjust their transmit
power to extend the coverage distances allowing the low-density BSs to enter dormant conditions.
On the other hand, the BSs experiencing high traffic demand exceeding their capacity will share
the load to surrounded low densified BSs according to the proposed heuristic algorithm. The two
different heuristic cell zooming algorithms are described in the following.
• Distance-traffic aware: sort the BSs in a cluster in ascending order based on the traffic
arrivals (χ ). Set the boundary limit χth. If χi,j < χth , reallocate the UEs to the surrounded
acceptor BSs. In addition, sort the BSs based on the link distance between users and BS in
least to greatest manner. Set the threshold value dth. Decrease the transmission power when
d < dth and reallocate UEs. Calculate the new arrivals association capacity, then update
acceptor BSs transmit power and set a new load-serving. Finally, compute total energy
consumption and average energy saving. For clear understanding, the Pseudo code for cell
zooming algorithm is presented in Fig. 3. Similarly, the other algorithm can be expressed
in the same way.
Set of m users k = {UE1 , UE2 , . . . , UEm }; number of resource blocks NRB . Binary variable
χ i,j signifies the traffic demand at ith BS (BSi ) of jth user, as in the following,
1, if UEj is served by BSi
Xi,j =
(1)
0, otherwise; ∀i ∈ N, ∀j ∈ U
In the cell zooming algorithm, Si,j = S1 , S2 , . . ., SZi = set of BSs in operating mode whose traffic
is to be shared under shortest path between UE-BS and availability of green energy; neighboring
a (i.e., handle new arrivals from S );
BS is Ci,j = {Ci,1 , Ci,2 . . . Ci,Mi }; acceptor candidate BS set Ci,j
Zi
s = βi goes to sleep
traffic distribution it owns set of operating BSs Zi,j. On the other hand, Ci,j
a ) in S , χ = χ , χ . . . χ ,
mode when it can redistribute its all traffic among surrounded BSs (Ci,j
i,j
i,j
1 2
k
a
s
Fi,j = βi searches the best combination BSs (Fij) in receiving shifted load, Ci,j or Ci,j . However,
the notations used in the algorithm section is presented in Tab. 1.
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• Green energy-aware: likewise, user traffic variations, the generation of green energy is
heavily dependent on the time and space domain owing to the different factors. Therefore,
renewable energy production is highly variable over the geographical location. Arrange the
BSs in accordance with the green energy availability in a descending manner in a certain
period. According to the algorithm, the highest energy available BSs zooms out through
extending the transmit power to cover surrounding new demand arrivals from the donor
BSs. It is worthy to mention that the surplus electricity during peak RE generation is stored
in the battery bank and can be used in the night-time. It is obvious that the green energy
aware scheme exhibit inferior performance in the counterpart as it cannot have guaranteed
the continuous power supply over a day or during unavailability of RE generation.
2.2 Performance Metrics
Energy Consumption Gain (ECG): ECG metrics accounts the energy required for sending
requested data transmission over a particular duration. ECG in green communications can be
defined as the ratio of the ECR metrics of the proposed system to the reference schemes under
the specified network settings. For instance, the network architecture without cell zooming is
considered as a reference baseline and cell zooming enabled green-powered cellular system is the
proposed scheme recognized as a more energy-efficient architecture.
Figure 3: UE_BS distance-based traffic relocation cell zooming algorithm
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Table 1: Summary of research investigations on renewable energy powered cellular BSs
Symbol Definition
NRB = Number of resource blocks
k = UE1 , UE2 , . . . , UEm = set of m users that have to be served
χ i, j signifies the traffic demand at ith BS (BSi ) of jth user
U = Total number of UEs
Si,j = S1 , S2 , . . . , SZi = set of BSs in active mode whose traffic is shared
Ci, j = Neighboring BSs
a = Acceptor BS set
Ci,j
Zi,j = Traffic distribution it owns set of operating BSs
s = Neighboring sleep mode BS
Ci,j
Fi,j = BSi searches the beat combination of Neighboring BSs
i,j
PTx = transmit power by ith BS to jth user
N = Total number of base station in a cluster
Xth = Threshold limit of traffic arrivals
T = Time duration
di, j = Distance between ith BS to jth UE
dth = Threshold distance
A system with lower ECG identified as more energy efficient as it consumes low power to
transmit the same amount of data transmission.
ECR =
ECRproposed
× 100%
ECGbaseline
(2)
However, ECR is an equipment level standard that evaluates the achievable throughput of the
entire radio access network per given power expenditure. On the other hand, ERG metrics are
sometimes preferable for energy efficiency analysis in the area of green cellular networking. The
ERG can be expressed as
1
ERG = 1 −
× 100%
(3)
ECG
Energy Saving Index (ESI): ESI metric measures the energy-saving gain introducing the cell
zooming concept under different zoom out range. It can define as
ESI =
E α − Eµ
× 100%
Eα
(4)
where Eα indicates the power consumption without incorporating cell zooming technique and
Eµ denote the power requirement with cell zoom out for the entire cellular
architecture respectively.
Load factor (δ): δ represents the ratio of the number of resource blocks occupied (RBO ) to
the available resource block (RBT ) in a given system bandwidth. Without loss of generality, we
presume one RB is occupied by a single active user and the occupancy of RB allocation linearly
scaled with incoming traffic profile. As the number of demand request increases led to occupied
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more number of resource blocks in order to satisfy the QoS. Under the proposed framework,
when the total available RBs are occupied in a particular BSs, the next available users can be
associated to the neighboring BSs without call service drop. However, δ can be expressed as
δ=
RBo
RBT
(5)
A RB is the least unit of physical resource allocation assigned to every user. Resource block
allocation decide the number of simultaneous users connected to the LTE base stations. In LTE,
one physical RB occupied 10 kHz bandwidth, having 12 subcarriers (each 15 kHz) and 14 symbols
over 1 msec duration. Typically, 10% RBs are kept reserved in LTE system in order to avoid
overlapping issue.
3 Cellular Base Station
The cellular BS consists of various equipment that can be used to communicate with
mobile/cellular units. The backhaul network has the following sub-units: (i) multiple transceivers
(TRXs), (ii) power amplifier (PA), (iii) radio-frequency (RF), (iv) baseband (BB), (v) DC–DC
Power supply, and (vi) cooling systems. The TRXs comprise PA which amplifies the signal power
coming from the BB unit. Besides, the BB is adapted for internal processing and coding, as shown
in Fig. 4. A detailed discussion of the BS components can be seen in [2].
The net power consumption by the BS is derived through the following equation [10];
DC + PDC + PDC
NTRX PPA
RF
BB
PBS =
(1 − σDC ) (1 − σcool )
(6)
where NTRX denotes the number of transmitting/receiving antennas for individual sites, i.e.,
DC , PDC , and PDC denote the power amplifier, radiofrequency, and baseband power,
transceivers; PPA
RF
BB
respectively. The power loss factors are approximate as σDC = 6% and σcool = 10% for converters
and air conditioners, respectively.
Figure 4: Block diagram of BS hardware elements
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Tab. 2 presents the power consumption scale of different parts of the macro BS system with
a 2 × 2 multi-input and multi-output (MIMO) antenna arrangement with three sectors.
Table 2: The power consumption scale of different hardware elements at BW 10 MHz [10]
Elements
Parameters
Unit
BS
PA
DC
PPA
Watts
RF
DC
PRF
DC
PBB
BB
Loss factor (σDC)
Loss factor (σcool )
PDC +PDC +PDC
RF
BB
PA
Total power/TRX = (1−σ
DC )(1−σcool )
No. of transceivers NTRX = NSect × NAnt × NCarr
Total power of the BS PBS = NTRX × Total power/TRX
51.5
Cell
zoomingout
102.6
Cell
zoomingin
16.3
Watts
10.9
10.9
5.4
Watts
%
%
14.8
6.0
10.0
14.8
6.0
10.0
13.6
6.0
0.0
Watts
91.25
6
547.52
151.65
6
909.93
37.55
6
225.32
Watts
4 Solar Power System
The proposed system comprises three segments such as sources, converters, and loads. PV
panels which are arranged in series and parallel connection based on the voltage and current
ratings. A battery bank or battery energy storage system (BESS) stores the energy from PV panels
and ensures the reliability and power quality of the generated power. Furthermore, a DC/AC
converter is used to convert the power to AC which supplies the power to the AC load (Air
conditioner). Moreover, excess energy is stored in the BESS as a backup which can be utilized
during non-sunny periods notably at night. The following subsections thoroughly demonstrate the
architecture of a solar system.
4.1 Photovoltaics
The total annual energy extraction from the PV arrangement (EPV ) is derived as [11],
EPV = PCPV × PSH × DFPV × 365 day/year,
(7)
where PCPV states a peak capacity of the PV array (kW); PSH denotes peak solar hour and is
calculated based on the equivalent average daily solar irradiation. DFPV states a derating factor
of PV array, considering the impact of dust, losses, temperature variations, and other potential
factors that can distress the output power of the panel.
4.2 Battery Bank
The BESS capacity of the BS merely depends on the depth of discharge (DOD) and must be
evaluated before commissioning. It can be expressed as [11],
DOD = 1 −
SOCmin
100
(8)
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where SOCmin denotes the minimum state of charge (SOC). The computation of days of autonomy (Abatt ) is essential to determine the performance of the fully charged batteries, i.e., the
number of days fully charged batteries can supply the power to the load. It is derived as [6],
min
Nbatt × Vnom × Qnom 1 − SOC
(24h/d)
100
(9)
Abatt =
Lprim−avg (1000Wh/kWh)
where the terms Nbatt and V nom are the total number of battery units in the BESS and a nominal
voltage of a single battery unit (V), respectively. The terms Qnom and Lprim,ave are the nominal
capacity of a single battery (Ah) and average daily BS load (kWh), respectively.
The lifetime of the battery plays a crucial role. The lifetime of a battery can be predicted
based on the operating conditions. More specifically, the DOD during each diurnal chargedischarge cycle displays a foremost role in the battery lifetime. It can be computed as [11],
Nbatt × Qlifetime
Rbatt = min
, Rbatt,f
Qthrpt
(10)
where the term Qlifetime represents the lifetime throughput of a single battery in kWh, Qthrpt
denotes the annual battery throughput in kWh per year, and the term Rbattf states a battery float
life in years.
4.3 Inverter
The total capacity of the inverter (Cinv ) is calculated as [11],
LAC
Cinv =
× σsf
ηinv
(11)
where the term LAC represents the available maximum AC load; ηinv and σsf is the inverter
efficiency and safety factor, respectively.
5 Cost Optimization Formula
The HOMER Micro-power optimization tool aids, to obtain an optimal solar system with low
net present cost (NPC). The term NPC contains all incurred expenses and incomes throughout
the project lifetime. The total annualized cost (CTAC ) exemplifies the annual price of the complete
cap
rep
scheme in the $/year that contains the initial capital (IC) costs (CTAC ), replacement costs (CTAC ),
o&m ). The complete description of the cost can be expressed mathematically
and O&M costs (CTAC
as [6],
cap
rep
o&m
CTAC = CTAC + CTAC + CTAC
(12)
The net present cost (CNPC ) can also be described for annualized value and can be derived as
CTAC = CNPC × CRF (i, N)
(13)
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The term CRF denotes the recovery factor which converts a CNPC into a flow of equal annual
costs over a definite period. It can be calculated based on the annual interest rate (i) and number
of years (N), and it is computed using the following equation,
CRF (i, N) =
i (1 + i)N
(1 + i)N − 1
(14)
The CNPC symbolizes all the prices incurred within the project lifespan, but with impending
cash flows cut-rate to the current discount ratio. The term NPC comprises the IC, replacement,
O&M, and salvage costs. However, the total NPC value is notably reduced due to the salvage
value at the end of the project lifespan. The computation of salvage value (S) can be carried out
using the following equation;
S = Crep
Rrem
Rcomp
(15)
wherein where Rcomp defines the lifespan of the component in years, Rrem denotes the remaining
lifespan of the component in years, and the term Crep is the replacement rate of the component
in $.
This study scrutinizes to minimize the total cost of the NPC for an optimal scheme of a
stand-alone solar system based on various constraints. To attain system optimization, the objective
function of the NPC can be derived using Eq. (15) and formulated as
min
EPV , EBattery , ELosses , EBS
CTAC
CRF (i, N)
(16)
The above-derived objective function is subjected to the following constraints;
EBattery + EPV > 0
(16.1)
EBattery + EPV = EBS + ELosses
(16.2)
To warrant a power balance between actual demand and energy production, the power
production of the available sources (EPV and EBattery ) must meet the demand of BS (EBS ), also
with losses (ELosses ) as defined in Eq. (16.2).
6 Simulation Configurations
The monthly average solar irradiation values, as shown in Fig. 5. In addition, the economic
value, system value, project lifespan, and interest rate (annual), as provided in Tab. 3.
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Figure 5: Solar irradiance for Korea (Monthly average) [11]
Table 3: Simulation configuration
Components
Parameters
Range
Control factors
Interest rate-Annual Korea (December, 2020)
Project lifespan
Dispatch scheme
Apply set point SOC
Percentage of load and hourly load
Sizes considered
Operational lifetime
Efficiency
Principal rate
Replacement rate
O&M price/year
Sizes considered
Efficiency
Operational lifespan
Principal cost
Replacement rate
O&M price/year
Number of batteries
Round trip efficacy
Minimum operational lifespan
Principal cost
Replacement rate
O&M price/year
0.5%
10 years
cyclic charging
80%
10%
2, 2.5, 3, 4, 4.5, 5 kW
25 years
85%
$1/Watt
$1/Watt
$0.01/Watt
0.1, 0.2, 0.3, 0.4 kW
95%
15 years
$0.4/Watt
$0.4/Watt
$0.01/Watt
24, 32, 40, 64, 72
85%
5 years
$300
$300
$10
PV
Inverter
Trojan L16P Battery
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7 Results and Discussion
Most economically, the total NPC cost of solar-powered BS is $26,887 that comprises 2.5 kW
rated PV panels and 64 numbers batteries which are connected in eight parallel strings along with
a 0.1 kW inverter. Detailed discussions of the optimal size measures, energy harvest, and economic
investigation of the proposed solar-powered BS are given in the following subsections.
7.1 Energy Yield Analysis
The optimal capacity of the PV array, as determined by the HOMER, is 2.5 kW. The designed
PV array has 10 Sharp modules, and each proposed module is rated at 250 W with a nominal
voltage of 29.80 V, nominal current of 8.40 A, open-circuit voltage of 38.3 V, and short circuit
current of 8.9 A. The yearly energy output of the PV is calculated using Eq. (7): the total energy
output of the PV is calculated as 3180 kWh (2.5 kW × 4.1 h × 0.85 × 365 days/year). In addition,
the generating energy increase up to 34.01%, i.e., 4262 kWh more annually using a dual-axis
tracking system. This energy yield also notably meets the losses incurred in the system battery
and inverter loss of approximately 453 and 12 kWh, respectively, and supplies the power to BS
load (3582 kWh), and results in annual excess energy up to 680 kWh, i.e., 15.95% of the total
energy generation. in August.
The ratios of annual energy output and input of the BESS, i.e., 2625 and 3077 kWh,
respectively. Roughly, the BESS supplies the power to the load about 237 h, specifically during
the malfunction of the PV array. The seasonal statistics that the maximum energy contribution of
the BESS is in August, while the minimum energy contribution in April. Besides, the frequency
histogram of the state of charge (SOC) shown that the state of charge stretched to 42%. The
average hourly energy generation of the PV, BESS, unmet load, and excess electricity is presented
in Fig. 6. It is observed that the lower rate of energy contribution from PV array is in August;
therefore, the higher rate of energy contribution from the BESS is in the same period.
Figure 6: The average hourly energy generation of
excess electricity
the PV, BESS, unmet load, and
The net capacity of the inverter unit is 0.1 kW, and its efficiency is computed between the
input (236 kWh) and output energy (224 kWh) annually and observed as 95%. The total operating
hours are 8,759 h/year (24 h × 365 days/year).
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7.2 Economic Analysis
A cash flow summary for Seoul city is presented in Fig. 7 (project lifespan). A detail of the
breakdown of the cash flow summary is as follows.
• The size of the system is directly proportional to the IC cost invested during the commencement of the scheme. The total IC of the proposed scheme is $21,740 and its breakdown is
as follows:
(a) 11.50% for PV array (2.5 kW (size) × $1,000/kW (cost) = $2500).
(b) 88.32% for BESS (64 (units) × $300/unit (cost) = $19, 200).
(c) 0.19% for inverter (0.1 kW (size) × $400/kW (cost) = $40).
• The O&M cost of the system is considered to be $6660, and its breakdown is as
follows:
(a) For PV array (i.e., 2.5 kW (size) × $10/1 kW (cost) × 10 years (project lifetime) =
$250).
(b) For BESS (64 (units) × $10/unit (cost) × 10 years (project lifetime) = $6400).
(c) For inverter (0.1 kW (size) × $10/1 kW (cost) × 10 years (project lifetime) = $10).
• Due to the short operational lifespan of the project (10 years), and the lifespan of the
BESS, PV arrays, and inverter is 10, 25, 15 years respectively. There are no replacement
costs.
• The salvage value of each component at the end of the project lifespan has to be considered. With the help of Eq. (15), the salvage value of the PV array is computed and found
to be $1500, which is the highest value among other components. The salvage value of the
inverter is estimated at $13. The total salvage value at the end of the venture lifespan is
$1513.
The net NPC is calculated by adding up the aggregated cash flows for each year and found
to be $26,887 i.e., $21,740 (IC) + $6660 (O&M prices) − $1513 (salvage).
Figure 7: Summary of cash flow (project lifespan)
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7.3 Cell Zooming Assessment
A quantitative comparison of the ECG identifying the impact of two different cell zooming
techniques is clearly presented in Fig. 8. As expected, the performance of both schemes remains
unchanged under no cell zooming conditions. As the cell zooms out more, less energy consumed
by the entire RAN architecture. According to the definition, the distance-traffic based cell zooming
scheme consumes less amount of power for the given value of zoom out level. As a consequence,
the distance-traffic aware cell zooming method attains about 4.8% less energy consumption in
comparison to the green energy aware as evident from the Fig. 8. On the other hand, the energy
consumption is about 27% lower when the cell zooms out entirely than the 20% zooming level.
Figure 8: Percentage of ECG vs. percentage of cell zooming
Fig. 9 compares the ERG metric with the percentage of cell zooming under 10 MHz system
bandwidth. Note that ERG performance can be derived with the help of ECG in accordance with
the definition. ERG defines the reduction of total power consumption to transmit a single bit of
information. Distance-traffic aware based cell zooming scheme shows improved performance by
about 5% in comparison with green energy-based zooming technique.
Figure 9: Percentage of ERG vs. percentage of cell zooming
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A detailed comparison of two different BS zooming options such as distance-traffic aware and
green energy availability is demonstrated in Fig. 10. The distance-traffic aware scheme keeps its
optimistic nature in terms of average energy. Further, Fig. 10 depicts that distance traffic-aware cell
zooming mechanism achieve 6.5% more energy savings in their counterpart and exhibits superior
performance for the higher level of zooming.
Figure 10: ESI vs. percentage of cell zooming
Figs. 11–13 depicted the average energy-saving performance comparing between the distancetraffic and green energy availability aware schemes with the BS sleeping hours per day, level of
cell zooming, and percentage of shifted traffic to the collocated BSs respectively. As observed,
the distance-traffic aware technique keeps its optimistic nature in all these three figures by means
of a considerable amount of energy savings. Notably, the energy savings gap between the two
aforementioned schemes of cell zooming is more apparent for the higher values of the zoom-out
level, BS sleeping hours, and shifted load demand. On the other hand, the separation of energysaving performance curves follows a similar pattern for the lower values of variable parameters.
This is because, for the lower values of zooming level, shifted load, and sleep mode duration,
the improvement of energy savings keep remains identical between the two methods. In contrast,
the green energy aware technique shows inferior performance as the available energy at the onsite BS may not sufficient to guarantee all the traffic demand. Whereas, the distance-traffic aware
demonstrates comparatively reliable performance for a prolonged period since this scheme does
not depends solely on the green power supply. In a nutshell, owing to the random fluctuations of
RE energy production on-site BSs, a solar energy-based cell zooming scheme is not a preferable
choice for achieving a greater level of system performance.
Fig. 14 illustrates the percentage of energy-saving versus the resource blocks occupancy i.e.,
load factor. Both the curves follow the identical patterns to reach their least values with the increment of δ. The energy-saving curve for the proposed system outperforms the conventional one
as evident from the graph. Here, the conventional schemes signify the cellular system operating
without considering cell zooming options. The curves move toward the downward direction with
the highest occupancy of resource block numbers as explained in the performance metric section.
However, the green curve in the Fig. 14 is derived from the distance-traffic aware cell zooming
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scheme. Notably, the new traffic arrivals will be associated with the closest neighboring BSs once
the contemplated active BS has no empty resource block, and thereby, the quality of service
remains uninterrupted. From the aforementioned analysis, it can be concluded that incorporating
the cell zooming concept with the traditional cell networks can achieve a greater level of energy
savings performance satisfying the quality of experience.
Figure 11: Average energy savings vs. BS sleeping hours in a day under zoom out condition
Figure 12: Comparison of energy savings performance with cell zoom out level
7.4 Economic Feasibility of the Proposed System
The key priority of the mobile operators is to increase the profit with reduced OPEX in the
cellular network. The economic viability with the PV system over conventional energy resources
are as follows;
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Figure 13: Percentage of energy saving index vs. cell zooming level
Figure 14: Percentage of energy saving vs. load factor
In remote areas, i.e., an off-grid station, the Diesel generator (DG) is usually employed to
power the BS. The DG rating should be around 3.5 kW that can be figured between the ratio
of maximum BS and 30% DG efficiency × converter efficacy of 95%. The net NPC is computed
and recorded as $50,736. It is observed using the summation process of $2,310 (IC costs) +
$41,496 (O&M costs) + $6,930 (replacement costs). The detailed description of the above costs
are as follows;
• The IC costs are computed by multiplying the system size of 3.5 kW with its cost of about
$660/kW.
• The O&M cost (annual) of the DG is approximately $4,150 (excluding fuel transportation
cost). A breakdown of this cost is described as;
The net maintenance cost of DG is $438/year, estimated using the product of DG
maintenance cost ($0.05/h) with annual operational hours (8760 h).
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The total fuel cost is computed using the product of diesel price ($1.04/liter) with
total diesel consumption (3,569 liter/year) and found to be $3,712. It is calculated
based on specific fuel consumption (0.388 liter/kWh) × annual electricity generation
by the DG (9,198 kWh/year, i.e., the product of DG size (3.5 kW) with its efficiency
(0.3 × 24 h × 365 days per year)). Therefore, the net O&M cost for the complete
plan lifespan is estimated to be $41,496.
• Every three years, a cellular operator has to replace the DG, i.e., a minimum of three DG
replacements during the lifespan of the scheme. Therefore, the net replacement rate is equal
to $6,930, i.e., 3 × 3.5 kW × $660/kW.
The net NPC of the solar system is approximately $26,887. Applying the proposed solar
system, total OPEX savings $23,849 which is 47% compared with the conventional power sources.
8 Conclusion
In this work, the solar-powered BSs technique with a dynamic cell zooming strategy according
to the traffic load conditions is suggested for the green wireless networks. The simulation results
revealed that the proposed system can be achieved OPEX savings of up to 47%, and it can
potentially meet the total demand of BS without any outage. Moreover, two different heuristic
cell zooming algorithms are extensively compared to extract the best option by means of energy
savings under optimal technical conditions. Results reveal that distance-traffic aware cell zooming
scheme exhibits more energy-efficient yielding to 27%, 5%, 6.5% in terms of ECG, ERG, and ESI,
respectively compared to the availability of renewable energy-based method.
Funding Statement: This research was supported by SUT Research and Development Fund. Also,
this work was supported by the Deanship of Scientific Research at Prince Sattam bin Abdulaziz
University, Saudi Arabia.
Conflicts of Interest: The authors declare that they have no conflicts of interest to report regarding
the present study.
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