Publication result detail

Performance Scaling of mmWave Personal IoT Networks (PINs) for XR Applications

ALI, A.; GALININA, O.; HOŠEK, J.; ANDREEV, S.

Original Title

Performance Scaling of mmWave Personal IoT Networks (PINs) for XR Applications

English Title

Performance Scaling of mmWave Personal IoT Networks (PINs) for XR Applications

Type

Paper in proceedings (conference paper)

Original Abstract

To provide a high-quality user experience in Extended Reality (XR) applications, high-throughput and low-latency communication is essential. A promising solution is the use of distributed networks operating in the higher frequency bands, such as millimeter-wave (mmWave) wearable Personal IoT Networks (PINs). However, in crowded environments, intra-network interactions can disrupt the Quality of Experience (QoE) for users. To improve the QoE, the understanding of the system-level performance trade-offs in these networks is important. This paper investigates the impact of various system parameters on the system-level performance of mmWave wearable PINs with 3D beamforming and data rate adaptation to the channel conditions in an environment with human body blockage. We employ an analytical methodology that combines stochastic geometry and queueing theory to devise an expression for the stationary distribution of the system and use it to compute the key metrics that describe the system-level performance. To assess mmWave PINs for XR in crowded environments, we examine the system operation trade-offs and explore the performance scaling.

English abstract

To provide a high-quality user experience in Extended Reality (XR) applications, high-throughput and low-latency communication is essential. A promising solution is the use of distributed networks operating in the higher frequency bands, such as millimeter-wave (mmWave) wearable Personal IoT Networks (PINs). However, in crowded environments, intra-network interactions can disrupt the Quality of Experience (QoE) for users. To improve the QoE, the understanding of the system-level performance trade-offs in these networks is important. This paper investigates the impact of various system parameters on the system-level performance of mmWave wearable PINs with 3D beamforming and data rate adaptation to the channel conditions in an environment with human body blockage. We employ an analytical methodology that combines stochastic geometry and queueing theory to devise an expression for the stationary distribution of the system and use it to compute the key metrics that describe the system-level performance. To assess mmWave PINs for XR in crowded environments, we examine the system operation trade-offs and explore the performance scaling.

Keywords

elastic traffic; millimeter-wave communication; queueing theory; spatial sharing; stochastic geometry; Wearable Personal IoT Networks

Key words in English

elastic traffic; millimeter-wave communication; queueing theory; spatial sharing; stochastic geometry; Wearable Personal IoT Networks

Authors

ALI, A.; GALININA, O.; HOŠEK, J.; ANDREEV, S.

RIV year

2024

Released

23.10.2023

Publisher

Institute of Electrical and Electronics Engineers Inc.

Location

New York

ISBN

979-8-3503-3307-7

Book

2023 IEEE International Conference on Communications Workshops: Sustainable Communications for Renaissance, ICC Workshops 2023

Pages from

1136

Pages to

1142

Pages count

7

URL

https://ieeexplore.ieee.org/document/10283621

BibTex

@inproceedings{BUT188117,
  author="Asad {Ali} and Olga {Galinina} and Jiří {Hošek} and Sergey {Andreev}",
  title="Performance Scaling of mmWave Personal IoT Networks (PINs) for XR Applications",
  booktitle="2023 IEEE International Conference on Communications Workshops: Sustainable Communications for Renaissance, ICC Workshops 2023",
  year="2023",
  pages="1136--1142",
  publisher="Institute of Electrical and Electronics Engineers Inc.",
  address="New York",
  doi="10.1109/ICCWorkshops57953.2023.10283621",
  isbn="979-8-3503-3307-7",
  url="https://ieeexplore.ieee.org/document/10283621"
}