Abstract
Resource allocation mechanisms and management of inter-cell interference coordination (ICIC) are fundamental characteristics of the LTE-A network for achieving maximum capacity. Cell densification serves as a promising candidate solution for meeting the demand posed by mobile users, as well as optimizing coverage. However, the transmit power difference between the introduced picocells and the legacy macrocells essentially leads to challenges that limits system performance, especially for those users located at the edge of the cell. As a means of providing a clear understanding, the authors thus formulate the optimization problem as game theory, in order to maximize a modified utility function, which aims at making improvements on the eICIC. Based on exact potential game formulation, we optimize almost blank subframe (ABS) and cell selection bias (CSB) settings for both macrocells and picocells in a distributed manner. Simulation results illustrate important performance gains on the service fairness of the users, and especially for cell edge users, where the averaged throughput increases by up to 51%, when compared to eICIC optimization without our modified utility function.
Highlights
W ITH the rise of increasingly agile and efficient media [1], the high quality of service (QoS) has attracted the attention of mobile operators and the research areas in recent years
This paper proposes a study and improvement of the enhanced inter-cell interference coordination (eICIC) optimization in downlink in LTE-A Hetnets
Simulation results showed that eICIC+ optimization does improve spectral efficiency and energy efficiency, especially in scenarios of higher grid densification
Summary
W ITH the rise of increasingly agile and efficient media [1], the high quality of service (QoS) has attracted the attention of mobile operators and the research areas in recent years. Generation cellular systems promise a significant increase in cell throughput and improved spectral efficiency compared to current systems To achieve these goals, network densification is a key element in increasing system coverage and meeting the growing demands for mobile data in a costeffective manner due to its capability of frequency spectrum reuse and signal-to-interference-plus-noise ratio (SINR) [3]. The surrounding macrocells of a picocell can generate higher rates of interference for a user associated with the picocell In these networks, smart user association, resource allocation, and interference management schemes are required for achieving performance gains. To tackle these issues, enhanced inter-cell interference coordination (eICIC) has been introduced in 3GPP Release10 [5].
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