Channel Capacity Maximization using NQHN Approach at Heterogeneous Network

Patil, Savitha; Bhavikatti, A. M.

doi:10.11591/ijece.v9i4.pp2593-2602

Cited by 1 publication

(1 citation statement)

References 32 publications

(46 reference statements)

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“…Thus, by minimizing path loss, better signaling can be delivered to the receiver [27]. The indoor regions are characterized by the deployment of FBS', their role is to bring a better QoS and quality of experience (QoE) for users [11], [17], [18], [28], [29]. As a result, the QoS degrades to multiple environmental factors, such as floors and walls.…”

Section: System Model 21 Path Loss Modelmentioning

confidence: 99%

Pedestrian mobility management for heterogeneous networks

Hachemi

Irid²,

Benchehima³

et al. 2022

IJEECS

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Pending the arrival of the next generation of 5G which is not yet deployed in some countries like Algeria, 4G LTE remains one of the main mobile networks to ensure adequate quality services. Mostly, the deployment of femtocells to support the macrocell structure is crucial in the handover decision process. This paper presents a new approach called the epsilon Kalman Filter with normalized least-mean-square (ϵKFNLMS) to realize the handoff triggering in two-tier long-term evolution networks to ensure communication continuity to the pedestrian UE and improve mobility management. ϵKFNLMS uses a two-step process: a tracking process and a prediction process, to produce an optimal future state estimate at ”t+p”, where ”p” is the prediction footstep. The tracking process is performed by the Kalman filter, known for its precision in the state of the signal at time ”t”. It perfectly reduces the estimation error, injected afterward in the variable step-size NLMS algorithm (VSS-NLMS). While the prediction process is performed by the VSS-NLMS algorithm, an adaptive filter known for its prediction of the future state at ”t+p”. Thus, the goal is to achieve a faster convergence with a steady-state. ϵ value provides a precise setting of the handover trigger. Through different numerical simulations in several indoor environments, the results show that the performance and effectiveness of the proposed approach (ϵKFNLMS) provide lower mean square error (MSE), stable physical appearance in the prediction process (convergence with a steady-state), and excellent speed of convergence compared to the classical Normalized LMS (NLMS) and Li-NLMS adaptive filters.

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