Tshiamo Sigwele scite author profile

Next-generation cellular networks such as fifthgeneration (5G) will experience tremendous growth in traffic. To accommodate such traffic demand, there is a necessity to increase the network capacity that eventually requires the deployment of more base stations (BSs). Nevertheless, BSs are very expensive and consume a significant amount of energy. Meanwhile, cloud radio access networks (C-RAN) has been proposed as an energyefficient architecture that leverages cloud computing technology where baseband processing is performed in the cloud, i.e., the computing servers or baseband processing units (BBUs) are located in the cloud. With such an arrangement, more energy saving gains can be achieved by reducing the number of BBUs used. This paper proposes a bin packing scheme with three variants such as First-fit (FT), First-fit decreasing (FFD) and Next-fit (NF) for minimizing energy consumption in 5G C-RAN. The number of BBUs are reduced by matching the right amount of baseband computing load with traffic load. In the proposed scheme, BS traffic items that are mapped into processing requirements, are to be packed into computing servers, called bins, such that the number of bins used are minimized and idle servers can then be switched off to save energy. Simulation results demonstrate that the proposed bin packing scheme achieves an enhanced energy performance compared to the existing distributed BS architecture.

show abstract

An Intelligent Edge Computing Based Semantic Gateway for Healthcare Systems Interoperability and Collaboration

Sigwele

Ali

et al. 2018

View full text Add to dashboard Cite

The use of Information and Communications Technology (ICTs) in healthcare has the potential of minimizing medical errors, reducing healthcare cost and improving collaboration between healthcare systems which can dramatically improve the healthcare service quality. However interoperability within different healthcare systems (clinics/hospitals/pharmacies) remains an issue of further research due to a lack of collaboration and exchange of healthcare information. To solve this problem, cross healthcare system collaboration is required. This paper proposes a conceptual semantic based healthcare collaboration framework based on Internet of Things (IoT) infrastructure that is able to offer a secure cross system information and knowledge exchange between different healthcare systems seamlessly that is readable by both machines and humans. In the proposed framework, an intelligent semantic gateway is introduced where a web application with restful Application Programming Interface (API) is used to expose the healthcare information of each system for collaboration. A case study that exposed the patient's data between two different healthcare systems was practically demonstrated where a pharmacist can access the patient's electronic prescription from the clinic.

show abstract

Intelligent and Energy Efficient Mobile Smartphone Gateway for Healthcare Smart Devices Based on 5G

Sigwele

Ali

et al. 2018

View full text Add to dashboard Cite

Energy-efficient cloud radio access networks by cloud based workload consolidation for 5G

Sigwele

Alam

Pillai

et al. 2017

Journal of Network and Computer Applications

View full text Add to dashboard Cite

Next-generation cellular systems like fth generation (5G) is are expected to experience tremendous trac growth. To accommodate such trac demand, there is a need to increase the network capacity that eventually requires the deployment of more base stations (BSs). Nevertheless, BSs are very expensive and consume a lot of energy. With growing complexity of signal processing, baseband units are now consuming a signicant amount of energy. As a result, cloud radio access networks (C-RAN) have been proposed as an energy ecient (EE) architecture that leverages cloud computing technology where baseband processing is performed in the cloud. This paper proposes an energy reduction technique based on baseband workload consolidation using virtualized general purpose processors (GPPs) in the cloud. The rationale for the cloud based workload consolidation technique model is to switch o idle baseband units (BBUs) to reduce the overall network energy consumption. The power consumption model for C-RAN is also formulated with considering radio side, fronthaul and BS cloud power consumption. Simulation results demonstrate that the proposed scheme achieves an enhanced energy performance compared to the existing distributed long term evolution (LTE) RAN system. The proposed scheme saves up to 80% of energy during low trac periods and 12% during peak trac periods compared to baseline LTE system. Moreover, the proposed scheme saves 38% of energy compared to $ This document is a collaborative eort.

show abstract

Saving Energy in Mobile Devices Using Mobile Device Cloudlet in Mobile Edge Computing for 5G

Sigwele¹,

Pillai²,

2017

View full text Add to dashboard Cite

iTREE: Intelligent Traffic and Resource Elastic Energy Scheme for Cloud-RAN

Sigwele

Pillai

2015

View full text Add to dashboard Cite

By 2020, next generation (5G) cellular networks are expected to support a 1000 fold traffic increase. To meet such traffic demands, Base Station (BS) densification through small cells are deployed. However, BSs are costly and consume over half of the cellular network energy. Meanwhile, Cloud Radio Access Networks (C-RAN) has been proposed as an energy efficient architecture that leverage cloud computing technology where baseband processing is performed in the cloud. With such an arrangement, more energy gains can be acquired through statistical multiplexing by reducing the number of BBUs used. This paper proposes a green Intelligent Traffic and Resource Elastic Energy (iTREE) scheme for C-RAN. In iTREE, BBUs are reduced by matching the right amount of baseband processing with traffic load. This is a bin packing problem where items (BS aggregate traffic) are to be packed into bins (BBUs) such that the number of bins used are minimized. Idle BBUs can then be switched off to save energy. Simulation results show that iTREE can reduce BBUs by up to 97% during off peak and 66% at peak times with RAN power reductions of up to 27% and 18% respectively compared with conventional deployments.

show abstract

Energy-efficient 5G cloud RAN with virtual BBU server consolidation and base station sleeping

Sigwele

Susanto

2020

Computer Networks

View full text Add to dashboard Cite

12 3

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Tshiamo Sigwele

Call Admission Control in Cloud Radio Access Networks

Evaluating Energy-Efficient Cloud Radio Access Networks for 5G

An Intelligent Edge Computing Based Semantic Gateway for Healthcare Systems Interoperability and Collaboration

Intelligent and Energy Efficient Mobile Smartphone Gateway for Healthcare Smart Devices Based on 5G

Energy-efficient cloud radio access networks by cloud based workload consolidation for 5G

Saving Energy in Mobile Devices Using Mobile Device Cloudlet in Mobile Edge Computing for 5G

iTREE: Intelligent Traffic and Resource Elastic Energy Scheme for Cloud-RAN

Energy-efficient 5G cloud RAN with virtual BBU server consolidation and base station sleeping

Contact Info

Product

Resources

About