RadioWeaves for efficient connectivity: analysis and impact of constraints in actual deployments

Perre, Liesbet Van der; Larsson, Erik G.; Tufvesson, Fredrik; Strycker, Lieven De; Björnson, Emil; Edfors, Ove

doi:10.1109/ieeeconf44664.2019.9048825

Cited by 42 publications

(34 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, for practical scenarios, e.g., Manhattan-style street grid, it is typically not feasible to place the APs circularly or arbitrarily as considered in the literature. In those scenarios, for the sake of aesthetics and deployment simplicity, APs can be deployed along walls in the streets and be less visible [17]. Placing APs on walls also ensures that the APs are less impacted by bad weather, for example, rain or wind.…”

Section: Introductionmentioning

confidence: 99%

Array Placement in Distributed Massive MIMO for Power Saving considering Radiation Pattern

Zhu

Monteyne

Callebaut

et al. 2021

2021 IEEE 94th Vehicular Technology Conference (VTC2021-Fall)

Self Cite

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

Array Placement in Distributed Massive MIMO for Power Saving considering Radiation Pattern

Zhu

Monteyne

Callebaut

et al. 2021

2021 IEEE 94th Vehicular Technology Conference (VTC2021-Fall)

Self Cite

View full text Add to dashboard Cite

“…RadioWeaves technology is a new wireless access infrastructure proposed in [92], in which a fabric of distributed electronic circuits consisting of the radio and computing resources serve as a massive distributed antenna array. The fabric will get weaved into conventional buildings and objects and thus, the RadioWeaves will be invisibly embedded in the environment.…”

Section: Radioweavesmentioning

confidence: 99%

Distributed Massive MIMO : Random Access, Extreme Multiplexing and Synchronization

Ganesan

2022

Linköping Studies in Science and Technology. Licentiate Thesis

View full text Add to dashboard Cite

The data traffic in wireless networks has grown tremendously over the past few decades and is ever-increasing. Moreover, there is an enormous demand for speed as well. Future wireless networks need to support three generic heterogeneous services: enhanced mobile broadband(eMBB), ultrareliable low latency communication (URLLC) and massive machine type communication (mMTC). Massive MIMO has shown to be a promising technology to meet the demands and is now an integral part of 5G networks.To get high data rates, ultra densification of the network by deploying more base stations in the same geographical area is considered. This led to an increase in inter-cell interference which limits the capacity of the network. To mitigate the inter-cell interference, distributed MIMO is advocated. Cell-free massive MIMO is a promising technology to improve the capacity of the network. It leverages all the benefits from ultra densification, massive MIMO, and distributed MIMO technologies and operates without cell boundaries.In this thesis, we study random access, extreme multiplexing capabilities, and synchronization aspects of distributed massive MIMO. In Paper A studies the activity detection in grant-free random access for mMTC in cell-free massive MIMO network. An algorithm is proposed for activity detection based on maximum likelihood detection and the results show that the macrodiversity gain provided by the cell-free architecture improves the activity detection performance compared to co-located architecture when the coverage area is large.RadioWeaves technology is a new wireless infrastructure devised for indoor applications leveraging the benefits of massive MIMO and cell-free massive MIMO. In Paper B, we study the extreme multiplexing capabilities of RadioWeaves which can provide high data rates with very low power. We observe that the RadioWeaves deployment can spatially separate users much better than a conventional co-located deployment, which outweighs the losses caused by grating lobes and thus saves a lot on transmit power.Paper C studies the synchronization aspect of distributed massive MIMO. ContentsAcknowledgements ix List of Abbreviations xiLarsson for providing an opportunity to take up doctoral research under his guidance. In addition to Prof. Larsson, I am very grateful to my co-supervisor Prof. Emil Björnson for his guidance and encouragement. Thanks to both of you for your belief in me and supporting my Ph.D journey during the tough times and guiding me in the right direction. Your immense knowledge, expertise, patience to clear my doubts and the positive attitude helped me to grow not only as a researcher but also as a person.Thanks to all my colleagues especially Amin, Chien, Zakir, Ziya, Ema, Özge, Giovanni, Jianan, Manoj, Kate for creating a wonderful work environment and approachable for any concerns. Special thanks to Amin for being best buddy pushing me for running and to do workouts and for the wonderful conversations over the lunch. Special thanks to Zakir and Ziya for endless technical discussions...

show abstract

“…Finally, Paper C proposed an algorithm for maximizing the energy efficiency of the RadioWeaves network with underlay spectrum sharing. RadioWeaves is an emerging technology built upon the concepts of Cell-Free Massive MIMO and possibly large intelligent surfaces wherein the antennas and underlying signal processing circuitry are weaved into large surface areas such as conventional buildings and objects [50]. Abstract: Cell-free massive multiple-input-multiple-output (mMIMO) is an emerging technology for beyond 5G with its promising features such as higher spectral efficiency and superior spatial diversity as compared to conventional multiple-input-multiple-output (MIMO) technology.…”

Section: Contributions Of the Thesismentioning

confidence: 99%

Cell-Free Massive MIMO: Distributed Signal Processing and Energy Efficiency

Shaik

2022

Linköping Studies in Science and Technology. Licentiate Thesis

View full text Add to dashboard Cite

In this era of rapid wireless technological advancements, wireless connectivity between humans, humans with machines, and machines with machines is gradually becoming an absolute necessity. The initial motivation for wireless connectivity was to enable voice communication between humans over a geographical area. Thanks to cellular communications advancements in the past decade, cellular wireless connectivity has become a global success, starting from 1G to the present generation 5G. However, the needs of humans often evolve with time, and now the world is witnessing an ever-growing demand for the internet with high data rates besides reliable voice communication. Current cellular networks suffer from non-uniform data rates across a cell, i.e., users at the cell center and the cell edges experience significant variations in signal-to-noise ratio, making the cellular technology less reliable to meet the future data demands. Moreover, cellular networks operating as cells, i.e., an access point (AP, the term we would use instead of base station) serving the users within its geographical location, cannot leverage the network's total capacity without cooperation among APs of the neighboring cells. One potential solution is moving away from the cell to cell-free networks wherein all the APs will serve all the users within the geographical coverage area. Thus, there is a need for a paradigm shift in how cellular networks operate. Towards the goal mentioned above to fully leverage the network capacity, the Cell-Free Massive multiple-input-multiple-output (MIMO) technology is expected to be the next potential technology beyond 5G combining the benefits of Massive MIMO and cell-free distributed architectures.Distributed architectures require distributed signal processing algorithms, and also energy consumption of the network is crucial. Keeping in view the practical ease in deployment, we consider a sequentially connected Cell-Free Massive MIMO network called a "radio stripe". In the first part of the thesis, we focus on developing an optimal sequential algorithm in the sense of mean-square-error (MSE) which has the same performance as that of centralized Cell-Free Massive MIMO implementation with the i 4 Conclusion and Future Scope v Bibliography

show abstract

RadioWeaves for efficient connectivity: analysis and impact of constraints in actual deployments

Cited by 42 publications

References 21 publications

Array Placement in Distributed Massive MIMO for Power Saving considering Radiation Pattern

Array Placement in Distributed Massive MIMO for Power Saving considering Radiation Pattern

Distributed Massive MIMO : Random Access, Extreme Multiplexing and Synchronization

Cell-Free Massive MIMO: Distributed Signal Processing and Energy Efficiency

Contact Info

Product

Resources

About