Daniel C. Alienyi scite author profile

Daniel C. Alienyi

3Publications

27Citation Statements Received

48Citation Statements Given

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University of Lagos

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Radial basis function neural network path loss prediction model for LTE networks in multitransmitter signal propagation environments

Ojo

Imoize

Alienyi³

2020

Int J Communication

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Summary Path loss prediction models occupy a central role in wireless signal propagation because of the continuous need to achieve reliable and high quality of service for subscribers satisfaction. However, the adoption of deterministic and empirical models for pathloss characterization presents a highly contending trade‐off between simplicity and accuracy. On the one hand, empirical models are relatively simple to apply but are mostly inaccurate and inconsistent. Deterministic models are more accurate but quite complex to develop, time‐consuming, and possess nonadaptable characteristics. Toward this end, this paper proposes to address the problems associated with the existing models (empirical and deterministic) through the introduction of machine learning algorithms to path loss predictions. The contribution of this paper is in threefold. First, experimental data were collected in multitransmitter scenarios via drive test in six base transceiver stations, and the pathloss of the received signal level was derived and analyzed. Two machine learning‐based path loss prediction models were then developed using the measured data as input variables. The developed path loss prediction models are the radial basis function neural network (RBFNN) and the multilayer perception neural network (MLPNN). Further to this, the MLPNN and the RBFNN models were compared with the measured path loss, and the RBFNN appears to be more accurate with lower values of root mean squared errors (RMSEs) in comparison with the MLPNN. Finally, the proposed machine language‐based path loss prediction models (MLPNN and RBFNN) were compared against five existing empirical models, and again, the RBFNN shows the most accurate results.

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An enhanced clustering analysis based on glowworm swarm optimization

Isimeto

Yinka-Banjo

Uwadia

et al. 2017

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An Adaptive Radial Basis Function Neural Network Glowworm Swarm Optimization for Time Series Forecasting

Isimeto

Sennaike

Alienyi

et al. 2018

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Daniel C. Alienyi

Radial basis function neural network path loss prediction model for LTE networks in multitransmitter signal propagation environments

An enhanced clustering analysis based on glowworm swarm optimization

An Adaptive Radial Basis Function Neural Network Glowworm Swarm Optimization for Time Series Forecasting

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