User Association Strategy for Energy Efficiency and Interference Mitigation of Heterogeneous Networks

Achki, Samira; Aziz, Layla; Gharnati, Fatima; Ait Ouahman, Abdellah

doi:https://doi.org/10.1155/2020/7018727

Advances in Materials Science and Engineering

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Abstract Introduction Related Works Authors’ Contributions Conclusion Data Availability Conflicts of Interest References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 7018727 | https://doi.org/10.1155/2020/7018727

User Association Strategy for Energy Efficiency and Interference Mitigation of Heterogeneous Networks

Samira Achki,¹Layla Aziz,¹Fatima Gharnati,²and Abdellah Ait Ouahman²

Academic Editor: Michelina Catauro

Received08 Feb 2020

Accepted09 Apr 2020

Published22 May 2020

Abstract

The necessity of the use of several mobile services increases every day. This requires the consumption of energy rates. Hence, minimizing the energy and interferences of mobile users are major concerns of Heterogeneous Networks (HetNet). This paper aims to improve the energy of mobile users by minimizing a weighted function. To consider significant weights values, we have exploited the multicriteria AHP method. The cost function represents the cost of users toward available BS. It includes the essential criteria influencing energy consumption. Moreover, we introduce an optimal user association based on their minimal cost values. Simulation results prove that the optimal method has saved more energy and reduced network interferences.

1. Introduction

HetNets are considered to offer added capacity and more spectral efficiency. HetNet is a grouping the different cell kinds: Macro, Picos and femtoscell, and divided access technology. Picocells and femtocells named small cells are densely populated and distributed in the geographic area of the macro cell. These small cells [1] use less power as they present end users are nearer to network access points. That way, one of the key objects for HetNet is to improve energy-efficient and reduce the mitigation interference of small cells. The mobile wireless communication, which necessitates high energy efficiency (EE), great system capacity, less interference and strong signal coverage, and, have contracted rapidly and experienced explosive data evolution over the last period, [2]. Because by this trend, satisfying the improved EE, mitigation interference and improved quality of service (QoS), the HetNet nowadays has to transport divers data information to the users with higher energy-efficiency. So, the architecture of the multi-tier heterogeneous network (HetNet), based on small cells, has been propounded as a promising technology to grow and increase the network capacity and avert coverage holes [3]. Also, due to the swiftly increase energy consumption in wireless systems, the research study of EE has concerned broad attention all over the world [4, 5]. It is known that HetNet with small cells can resolve the physical poverty of radiofrequency and growth the system capacity to some level, but at the purse of the extent and deploying more hardware infrastructures, that mains to higher energy consumption accordingly [6]. Therefore, owing to the compromise between the profit and cost, the EE and management of the intereference of HetNet is enough interesting and dignified of research, that is primarily discussed in this paper. In HetNet, the greater density deployed user mobile and small cells are frequently lightly charged because of their base transmit power associated with macro base stations (BSs). Orderly to take full benefit and supervised the signal transmission between user’s mobile MUEs and macro, smallcells. In this paper, we explore a new algorithm based on a cost function for user association in HetNet. We have exploited the AHP method for attributing a significant values of weights in the cost function. We have taken into account three important factors: SINR, distance, and the power consumed by the user. Motivated by the importance of enhancing energy efficiency and making an optimal association of users, we have formulated our problem as a minimization problem. Moreover, we have exploited the AHP process for attributing the weights’ preferences in the proposed cost function, where three essential criteria are considered. This paper is organized as follows: Section 2 reviews the most popular and recent approaches used for improving the energy efficiency in HetNets. Section 3 presents the main contributions of this work. Section 4 details the problem formulation and the numerical illustration. Section 5 presents the results of the studied scenarios. Section 6 concludes the present study.

In recent years, the research including improved EE and mitigation of interference based on SINR in HetNet has concerned more interests all to the world. On EE, significant results previously exist to save battery power as well as small and macro Base Station (BS) transmission power. In [7], the authors proposed an algorithm to resolve the nonlinear mixed-integer programming problem where is combined cell activation and selection scheme for energy efficiency and developed a three-layer iterative. In [8] exploited the weighted sum of rates in the long-term to stability the network weight and therefore realized developed load balancing benefit and energy efficiency. In [9] explored scheme-based BS association for heterogeneous networks and proposed a distributed charge update approach based on algorithm a coordinate descent. In [10] suggest a quality of service (QoS) determined distributed cell association algorithm in that users obtain a number of resource blocks which is only adequate to satisfy their QoS constraints while exploiting the sum purpose of rate. In [11] proposed algorithm that combined user scheduling and user association for load balancing and EE by maximizing a distributed technique the optimization named the alternating direction method of multipliers. In [12] proposed algorithm the utility that based on user association which practices an almost technical based on subframe interference coordination. In [13] proposed algorithm a distributed certainty propagation to determine user association problems in HetNet with several user significances. In [14] proposed many schemes of user association based on weighted average rate using stochastic geometry approach and on cover probability. In [15] proposed algorithm of power control with mobility prediction to evaluate far radio head switching processes in a heterogeneous cloud radio access network (H-CRAN) to enhance energy efficiency. In [16] presented a joint optimization approach that considers the BS sleep model for ameliorating the energy-efficiency of HetNet. In [17] elaborate algorithm a Small-BS on/off switching based on the optimum distance to decrease power consumption in the network. In [18] considered a small-cell sleep methodology based on the traffic load in that BSs are put off for a certain duration when their traffic load reductions under some threshold. In [19] proposed an energy-efficient growth problem based on coverage probability below also a random sleeping strategic sleeping policy and purpose static and dynamic user models in the sleeping policy strategic, that only take on considered BS on/off strategies but not take the user association. In [20] proposed a Markov theory for Mobility Model based on Velocity Organization (MM-VC) and studies the characteristics of the phase-type distribution of cell resident time. Also, the sleeping strategy between small cells was useful to decrease the energy consumption of the system. However, it only measured energy consumption and canceled the throughput of the network. Moreover, it did not consider the user association. In [21] proposed strategies that corporate optimization method considering User Association and Small-Cell Base Station On/Off Strategies for Energy Efficiency. The authors in [22] optimized the Resource Allocation (RA) problem in the Internet of things (IoT) based on the heuristic algorithm, this algorithm aims to achieve the goal of optimizing the RA and decreasing the total communication cost between resources and gateways. In [23], the authors proposed the Bat Algorithm (BA) for reducing the energy consumption in a wireless sensor network. This algorithm aims to select the best monitoring sensor node in the path to decreasing energy consumption. Moreover, its main objective is to cover the network lifetime through covering the lifetime of operating sensors as well as transferring collected data from great node to the sink. The authors in [24] proposed the method of machine learning paradigm applying Position-Based Services (PBSs) confidentiality via the mobile edge computing in the real-time industrial informatics, to assure the timely delivery of position-based services at the network edge. The profits of mobile edge service policy proposal position privacy and poor latency by a resource of networking and computing services at the locality of roaming users. In [25], authors proposed the energy-aware green model for Cyber-Physical Security (CPS) in a smart industrial system through achieving confidentiality, the main goal is to improve its energy consumption. So the proposed model that runs on real-time taking into account the regressive position-based query scheduling to decrease the communication and computation cost for each query. Hence, this eases the energy consumption optimization. Several studies have been focused on the integrated multi-criteria tools, where different multi-criteria methods have been combined for achieving a significant selection. Among these combined tools AHP-TOPSIS and Fuzzy-AHP tools are widely exploited. To maximize the network lifetime in WSN, authors in [26] proposed an integrated AHP-TOPSIS tool. The combined model aims to select the clusters’ leaders efficiently.

3. Authors’ Contributions

In this section, The authors present the main contributions of this work:(i)The above studies generally take attention to the combined optimization algorithms between BSs strategies and user association. Though, all of the aforementioned analyses did not focus necessarily on joint optimization algorithms of user association and Interference strategy.(ii)The majority of the previously achieved works determine the criteria importance using equal or random preferences of criteria. However, the present study focuses on a novel selection algorithm based on the AHP method to determine the significant importance of the essential criteria.(iii)From our knowledge, this work is the first one that combines the multi-criteria AHP method and an optimization algorithm for minimizing the cost of the users association and resolving the problem of network interferences.

4. Proposed Work

4.1. System Model and Problem Formulation

The system model illustrates in Figure 1 contains one Macro base station (Macro Cell) underlaid with two Small base station (Small Cell). The user mobile (MUEs) is randomly positioned in the coverage area of the Macro Cell, while the MUEs are randomly located in their associated Small Cells.

In our model, Users are characterized by various criteria where each one influences the user association. The main objective of this work is enhancing energy efficiency by reducing the wireless interferences and making an efficient user association considering several criteria. the SINR of MUE i, associated with its designated MBS k can be written as [27]:the EE of the nth UE which selects the mth BS can be written as [28]:where: represents the power coefficient and ,

In order to include the different criteria for making users association, we consider the following weighted function:where represents the weight associated with energy criteria (E). is the weight of the distance separating the user from the BS. is the weight of the SINR criteria.

Each user has three essential criteria (distance from BS, its power and the value of its SINR) where each one impacts its value. In this work, we assume that each user disposes of an association cost. So, the association of all users composes a cost matrix. The main objective of the user association problem is designing an optimal association technique. Therefore, our problem is minimizing the cost of the users association. We express our problem as follows:subject to:

4.2. AHP Method

AHP is a well known multicriteria method exploited for resolving decision problems. It has been applied in several research fields including marketing and engineering. AHP method is composed of five steps: [29]. Step 1: Determine the problem criteria. Step 2: generate the pair wise-comparison for all criteria using the values of Table 1. Step 3: determine the most appropriate eigenvectors to the maximal eigenvalue to define the criteria importance. Step 4: represent a validation step where judgments consistency is compared to Consistency Ratio (CR) and Consistency Index (CI) [30]:where represents the Eigenvalue that corresponds to the pair-wise comparisons matrix, and n represents the number of different elements considered for the comparison. CR is defined using equation:where RCI is a random consistency index chosen from Table 2 according to the number of criteria. The last step aims to validate the process using CR: pairwise comparisons are considered valid if CR is less or equal to 0.1.

4.3. Optimal User Association

4.3.1. Our Algorithm

The steps the optimal association of users are described in Algorithm 1.

	Initialize the weights of criteria: , and
	Initialize the coverage of the BS: .
	Initialize the list of users: #ListUsers
	Initialize the list of the available BSs: #ListBS
	fordo
	fordo
	ifthen
	Compute , , using equations (7) and (8)
	Compute
	end if
	end for
	end for
	fordo
	fordo
	Compute using equations (4)–(6)
	Calculate EE
	Calculate SINR
	end for
	end for

4.3.2. Numerical Illustration

The cost matrix has been applied to associate users to the most suitable BS. We use the AHP method to determine criteria weights. Our decision problem is prioritizing the available BSs.

Our decision matrix is illustrated in Table 3, where we define all criteria importance. We observe that all matrices are consistent because each consistency rate is less than 0.1.

The normalized matrix is given in Table 4:

The next step focuses on generating criteria weights. After calculating such weights, we found that C1 = 0.77 and C2 = 0.16 and C3 = 0.07. To prove that the weights generating is valid, we calculate the CR value. Firstly, the weighted matrix is illustrated in Table 5:

LamdaMAx = 3.07 CI = 0.03 CR = 0.06 After calculating all criteria weights using the AHP model, we use these generated weights for alternatives costs.

5. Simulation Results

In this section, we present the performances of the proposed joint user association. In the simulation, we examine a HetNet scenario containing multiple overlapping area access networks. We supposed that all the MUE is arbitrarily and randomly located in the area. The main parameters used in the simulation are summarized in Table 6.

5.1. Energy Efficiency and SINR

We evaluate the proposed association approach in terms of energy efficiency and SINR factors. In the studied scenario, we consider two small BS and one macro BS, while the number of mobile users is varied between 30 and 90 (Figures 2–4). (Figures 5–7), and (Figures 8–10) depict the curves of the energy efficiency and the SINR for the association of 30, 60, and 90 MUE respectively. It is clearly shown from curves that the proposed approach increased significantly the energy efficiency due to the optimal association of users. Besides, we model the energy efficiency problem as minimal cost function where the weights are calculated using the AHP method. The calculation of the weights of importance using the AHP technique has eased making the optimal user association. Moreover, we observe that the values of the SINR are decreased for the users associated with the available BS. Also, We can conclude that the user association is individual. Indeed, user15, user16, …, and user25 (Figure 2) are not associated with macro BS because of their increased cost values. However, these users are associated with the small BSs due to their minimal cost compared to the macro BS. Hence, the interference problem is resolved.

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6. Conclusion

In this paper, we investigated an energy-efficient user association and interference mitigation in HetNet. For user association, we simultaneously considered the SINR, power consumption, and user distance. In our algorithm, users associated with BSs depending on their cost values. This optimized energy efficiency and mitigation of interference though concurrently preventing recurrent switching between users and SBSs. The simulation results presented that our proposed strategy can optimize network performance in HetNet. As future work, we intend to optimize energy consumption in both uplink and downlink transmissions.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

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Copyright © 2020 Samira Achki et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Advances in Materials Science and Engineering

User Association Strategy for Energy Efficiency and Interference Mitigation of Heterogeneous Networks

Abstract

1. Introduction

2. Related Works

3. Authors’ Contributions

4. Proposed Work

4.1. System Model and Problem Formulation

4.2. AHP Method

4.3. Optimal User Association

4.3.1. Our Algorithm

4.3.2. Numerical Illustration

5. Simulation Results

5.1. Energy Efficiency and SINR

6. Conclusion

Data Availability

Conflicts of Interest

References

Copyright