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This summary is machine-generated.

Millimeter-wave (mmWave) wireless backhaul offers high speeds but struggles with obstructions. This study analyzes a dataset from an outdoor IEEE 802.11ad network to understand performance impacts under blocked conditions.

Keywords:
5G802.11adBackhaul networkBlockageOutdoor networkWiGig

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Area of Science:

  • Wireless Communications
  • 5G Technology
  • Network Performance Analysis

Background:

  • Millimeter-wave (mmWave) wireless backhaul is a flexible, cost-effective alternative to fiber for 5G.
  • mmWave protocols like IEEE 802.11ad are susceptible to obstructions, limiting Line-of-Sight (LOS) operation.
  • Obstructions significantly reduce throughput and can cause link failures, impacting critical applications.

Purpose of the Study:

  • To assess the impact of different obstruction types and durations on mmWave WiGig networks for 5G backhaul.
  • To provide a valuable dataset for understanding real-world mmWave network behavior.
  • To determine the feasibility of mmWave technology in wireless backhaul scenarios.

Main Methods:

  • Collected a dataset from an experimental IEEE 802.11ad mmWave mesh network deployed outdoors.
  • Gathered multi-layer data, including MAC, PHY, and network information.
  • Evaluated network performance under normal, short-term blocked, and long-term blocked LOS scenarios.

Main Results:

  • The dataset offers insights into WiGig network behavior under varying obstruction conditions.
  • Characterized performance across PHY, MAC, and transport layers during blockage events.
  • Quantified the effects of different blockage durations on network throughput and stability.

Conclusions:

  • Understanding obstruction impacts is crucial for the viability of mmWave wireless backhaul.
  • The collected dataset serves as a valuable resource for researchers and professionals.
  • This work aids in optimizing mmWave network design for reliable 5G backhauling.