Multilayer Optimization of Heterogeneous Networks Using Grammatical Genetic Programming

Michael Fenton; David Lynch; Stepan Kucera; Holger Claussen; Michael O'Neill

doi:10.1109/TCYB.2017.2688280

Multilayer Optimization of Heterogeneous Networks Using Grammatical Genetic Programming

Michael Fenton
, David Lynch
, Stepan Kucera
, Holger Claussen
, Michael O'Neill

Research output: Contribution to journal › Article › peer-review

Abstract

Heterogeneous cellular networks are composed of macro cells (MCs) and small cells (SCs) in which all cells occupy the same bandwidth. Provision has been made under the third generation partnership project-long term evolution framework for enhanced intercell interference coordination (eICIC) between cell tiers. Expanding on previous works, this paper instruments grammatical genetic programming to evolve control heuristics for heterogeneous networks. Three aspects of the eICIC framework are addressed including setting SC powers and selection biases, MC duty cycles, and scheduling of user equipments (UEs) at SCs. The evolved heuristics yield minimum downlink rates three times higher than a baseline method, and twice that of a state-of-the-art benchmark. Furthermore, a greater number of UEs receive transmissions under the proposed scheme than in either the baseline or benchmark cases.

Original language	English
Article number	7893786
Pages (from-to)	2938-2950
Number of pages	13
Journal	IEEE Transactions on Cybernetics
Volume	47
Issue number	9
DOIs	https://doi.org/10.1109/TCYB.2017.2688280
Publication status	Published - Sep 2017
Externally published	Yes

Keywords

Evolutionary computation
grammatical genetic programming (GP)
wireless communications networks

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10.1109/TCYB.2017.2688280

Cite this

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title = "Multilayer Optimization of Heterogeneous Networks Using Grammatical Genetic Programming",

abstract = "Heterogeneous cellular networks are composed of macro cells (MCs) and small cells (SCs) in which all cells occupy the same bandwidth. Provision has been made under the third generation partnership project-long term evolution framework for enhanced intercell interference coordination (eICIC) between cell tiers. Expanding on previous works, this paper instruments grammatical genetic programming to evolve control heuristics for heterogeneous networks. Three aspects of the eICIC framework are addressed including setting SC powers and selection biases, MC duty cycles, and scheduling of user equipments (UEs) at SCs. The evolved heuristics yield minimum downlink rates three times higher than a baseline method, and twice that of a state-of-the-art benchmark. Furthermore, a greater number of UEs receive transmissions under the proposed scheme than in either the baseline or benchmark cases.",

keywords = "Evolutionary computation, grammatical genetic programming (GP), wireless communications networks",

author = "Michael Fenton and David Lynch and Stepan Kucera and Holger Claussen and Michael O'Neill",

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T1 - Multilayer Optimization of Heterogeneous Networks Using Grammatical Genetic Programming

AU - Fenton, Michael

AU - Lynch, David

AU - Kucera, Stepan

AU - Claussen, Holger

AU - O'Neill, Michael

PY - 2017/9

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AB - Heterogeneous cellular networks are composed of macro cells (MCs) and small cells (SCs) in which all cells occupy the same bandwidth. Provision has been made under the third generation partnership project-long term evolution framework for enhanced intercell interference coordination (eICIC) between cell tiers. Expanding on previous works, this paper instruments grammatical genetic programming to evolve control heuristics for heterogeneous networks. Three aspects of the eICIC framework are addressed including setting SC powers and selection biases, MC duty cycles, and scheduling of user equipments (UEs) at SCs. The evolved heuristics yield minimum downlink rates three times higher than a baseline method, and twice that of a state-of-the-art benchmark. Furthermore, a greater number of UEs receive transmissions under the proposed scheme than in either the baseline or benchmark cases.

KW - Evolutionary computation

KW - grammatical genetic programming (GP)

KW - wireless communications networks

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Multilayer Optimization of Heterogeneous Networks Using Grammatical Genetic Programming

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Keywords

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