• DocumentCode
    1420581
  • Title

    Moving elevator-cell system in indoor buildings

  • Author

    Kim, Tai Suk ; Cho, Ho-Shin ; Sung, Dan Keun

  • Author_Institution
    Dept. of Electr. Eng., Korea Adv. Inst. of Sci. & Technol., Seoul, South Korea
  • Volume
    49
  • Issue
    5
  • fYear
    2000
  • fDate
    9/1/2000 12:00:00 AM
  • Firstpage
    1743
  • Lastpage
    1751
  • Abstract
    To plan efficient future PCS networks, indoor environments as well as outdoor environments must be considered. Users typically exhibit vertical motion through elevators and horizontal motion on building floors in indoor environments. A user on the way into or out of an elevator may experience difficulty in communicating with a base station (BS) due to large signal attenuation caused by the metal structure of the elevator, especially the door. The user also may suffer from handoffs as the user passes several floors during the course of a call as the elevator moves. It is necessary to overcome these problems related to elevators for indoor cell planning. In this paper, a nonmoving and two moving elevator-cell systems for a building are considered. The undesirable inter-floor handoffs while the user is inside the elevator of the nonmoving elevator-cell system (N-system) are eliminated by introduction of two moving elevator-cell systems: a simple moving elevator-cell system (S-system) and a proposed moving elevator-cell system (P-system). The S-system does not seamlessly maintain calls between an elevator and adjacent floors due to insufficient time when the elevator is open to complete the handoff, while the P-system seamlessly maintains calls using a macro diversity with a distributed antenna scheme. The movements of an elevator and users are modeled and the P-system is compared with the S-system in terms of the required number of channels. The P-system reduces the total required number of channels compared with the S-system under heavy traffic conditions. The elevator-cell system and modeling results can be used in the design of future indoor wireless systems
  • Keywords
    Rayleigh channels; cellular radio; diversity reception; indoor radio; lifts; multipath channels; personal communication networks; radiowave propagation; PCS networks; Rayleigh fading; base station; building floors; distributed antenna; elevators; handoff; heavy traffic conditions; horizontal motion; indoor buildings; indoor cell planning; indoor environments; indoor wireless systems design; inter-floor handoffs; macro diversity; metal structure; moving elevator-cell system; multipath fading; nonmoving elevator-cell system; outdoor environments; signal attenuation; signal propagation model; vertical motion; Attenuation; Base stations; Buildings; Elevators; Floors; Indoor environments; Personal communication networks; Radio propagation; Telecommunication traffic; Traffic control;
  • fLanguage
    English
  • Journal_Title
    Vehicular Technology, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9545
  • Type

    jour

  • DOI
    10.1109/25.892579
  • Filename
    892579