Indoor Propagation Modeling at 2.4 GHZ for IEEE 802.11 Networks Metadata

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Title

  • Main Title Indoor Propagation Modeling at 2.4 GHZ for IEEE 802.11 Networks

Creator

  • Author: Akl, Robert G.
    Creator Type: Personal
    Creator Info: University of North Texas
  • Author: Tummala, Dinesh
    Creator Type: Personal
    Creator Info: University of North Texas
  • Author: Li, Xinrong
    Creator Type: Personal
    Creator Info: University of North Texas

Contributor

  • Organizer of meeting: International Association of Science and Technology for Development
    Contributor Type: Organization

Publisher

  • Name: International Association of Science and Technology for Development
    Place of Publication: [Alberta, Canada]

Date

  • Creation: 2006-04

Language

  • English

Description

  • Content Description: This paper discusses indoor propagation modeling.
  • Physical Description: 6 p.

Subject

  • Keyword: WiFi
  • Keyword: Chi-square statistics
  • Keyword: path loss
  • Keyword: channel modeling

Source

  • Conference: Sixth International Association of Science and Technology for Development (IASTED) International Multi-Conference on Wireless and Optical Communications, 2006, Banff, Alberta, Canada

Collection

  • Name: UNT Scholarly Works
    Code: UNTSW

Institution

  • Name: UNT College of Engineering
    Code: UNTCOE

Rights

  • Rights Access: public

Resource Type

  • Paper

Format

  • Text

Identifier

  • Archival Resource Key: ark:/67531/metadc30827

Degree

  • Academic Department: Computer Science and Engineering
  • Academic Department: Electrical Engineering

Note

  • Display Note: Abstract: The purpose of this study is to characterize the indoor channel for 802.11 wireless local area networks at 2.4 GHz frequency. This work presents a channel model based on measurements conducted in commonly found scenarios in buildings. These scenarios include closed corridor, open corridor, classroom, and computer lab. Path loss equations are determined using log-distance path loss model and log-normal shadowing. The Chi-square test statistic values for each access point are calculated to prove that the observed fading is a normal distribution at 5% significance level. A numerical analysis of measurements in each scenario was conducted and the study determined equations that describe path loss for each scenario.