System Model Considerations for mmWave PHY - PowerPoint PPT Presentation

About This Presentation
Title:

System Model Considerations for mmWave PHY

Description:

Title: System Model Considerations for mmWave PHY Subject: IEEE 802.15 SG4 Author: Chandos Rypinski Keywords: DSBSC, phase-independent Description – PowerPoint PPT presentation

Number of Views:32
Avg rating:3.0/5.0
Slides: 17
Provided by: Chand155
Learn more at: https://mentor.ieee.org
Category:

less

Transcript and Presenter's Notes

Title: System Model Considerations for mmWave PHY


1
Project IEEE P802.15 Working Group for Wireless
Personal Area Networks (WPANs) Submission Title
Adapting the IEEE 802.15.3 MAC to WPAN systems
employing directional antennas Date
Submitted 7 May 07 Source Khusro Saleem,
Bryan Beresford-Smith (NICTA Ltd) Address
Building 193, University of Melbourne Melbourn
e, VIC, 3010, Australia Voice 61 3 8344 8407
FAX none, E-Mail khusro.saleem_at_nicta.com.au Re
Adapting the IEEE 802.15.3 MAC to WPAN systems
employing directional antennas Purpose This is
a discussion only document. No action is
recommended. Notice This document has been
prepared to assist the IEEE P802.15. It is
offered as a basis for discussion and is not
binding on the contributing individual(s) or
organization(s). The material in this document is
subject to change in form and content after
further study. The contributor(s) reserve(s) the
right to add, amend or withdraw material
contained herein. Release The contributor
acknowledges and accepts that this contribution
becomes the property of IEEE and may be made
publicly available by P802.15.
2
Adapting the IEEE 802.15.3 MAC to WPAN systems
employing directional antennas
  • Khusro Saleem, Bryan Beresford-Smith
  • NICTA Ltd

3
Outline
  • Overview
  • Benefits of directional antennas
  • Challenges at the MAC layer
  • Proposed amendments to the IEEE 802.15.3 MAC
    layer
  • Conclusions and further work

4
Overview
  • IEEE 802.15.3 TG3c is developing a mm-wave-based
    alternative PHY for the existing WPAN standard
    IEEE 802.15.3-2003
  • Signal propagation at mm-wave frequencies has
    high path loss
  • Signals also experience greater attenuation
    through most materials
  • High TX power not expected to overcome
    attenuation
  • Directional antennas are a cost-effective
    solution to this problem
  • How do we adapt IEEE 802.15.3-2003 to work
    effectively with directional antennas?

5
Directional antennas - benefits
  • Antenna elements are small in the mm-wave
    spectrum and can be integrated into the package
  • This in-turn allows for beam-forming thereby
    increased antenna gain and spatial re-use
  • A side benefit is increased resilience to
    multi-path fading and interference

6
Challenges at the MAC layer
  • Neighbor discovery
  • PNC-DEV communication
  • DEV-DEV communication
  • Hidden node problems
  • Exposed node problems
  • Spatial reuse

7
Adapting IEEE 802.15.3
  • The following proposals enhance the current
    standard whilst ensuring
  • Interoperability with DEVs that only employ
    omni-directional antennas.

8
Adapting IEEE 802.15.3 Main change
  • MAC beacons are transmitted by the PNC
    omni-directionally
  • To overcome the resulting antenna gain asymmetry
    in the PNC-DEV links, the MAC beacons are
    transmitted at a lower rate
  • The lower rate transmission rate results in a
    lower SNR requirement
  • Select the lower rate, such that the lower SNR
    requirement overcomes for the antenna gain
    asymmetry in the PNC-DEV links
  • We should end up with the same probability of
    correct frame reception
  • We can readily adapt this to any PHY
    specification with the addition of a few PHY-SAP
    primitives
  • This represents a form of cross-layer optimization

9
Adapting IEEE 802.15.3 Main change
  • For example, consider the current 2.4GHz PHY
    specification in IEEE 802.15.3-2003
  • For 64-QAM-TCM, to achieve FER8, we need
    SNR20dB
  • Assume we transmit MAC beacon as per the MAC
    header at 22Mb/s using DQPSK
  • To achieve FER8, SNR13dB
  • ?SNR7dB
  • Loosely speaking, we can lose about 7dB in
    antenna gain
  • Yes, there will be a reduction in throughput but
    the beacon is a small fraction of the superframe
    anyway

10
Adapting IEEE 802.15.3 Main change
  • How do we address Neighbor Discovery?
  • The PNC MAC beacon is transmitted
    omni-directionally and DEVs scan using
    directional beams
  • By transmitting the PNC MAC beacon
    omni-directionally, neighbor discovery is a
    trivial process
  • And by lowering the data rate we overcome the
    asymmetric antenna gain
  • This approach is interoperable with
    omni-directional DEVs as well
  • The beacon must be lengthened to facilitate
    Angle-Of-Arrival (AOA) estimation

11
Adapting IEEE 802.15.3 PNC-DEV communication
  • So what does the PNC-DEV link look like?
  • The PNC is omni and the DEV is directional or
    omni (depending on capability)
  • So when the directional-capable DEVs are
    expecting the beacon they point their beams at
    the PNC
  • The beam pointing direction (AOA) is learned each
    time a PNC beacon is received

12
Adapting IEEE 802.15.3 DEV-DEV communication
  • So what does the DEV-DEV link look like?
  • The DEV-DEV link could be omni-omni,
    omni-directional, or directional-directional
    depending on device capability
  • The main question is how to two DEVs employ a
    directional-directional link?
  • This requires a training sequence for AOA
    estimation, so lets reuse our PNC-DEV link
    communication model again

13
Adapting IEEE 802.15.3 DEV-DEV communication
  • How do two DEVs establish a directional-directiona
    l link?
  • After successful stream creation, the two DEVs
    undergo an AOA estimation sequence during the
    first allocated CTAP
  • Assume DEV1 initiated the stream request
  • DEV1 transmits an DEV-beacon omni-directionally,
    just like the PNC beacon, at a lower rate
  • DEV2 scans directionally and receives this and
    estimates the AOA
  • DEV2 then acknowledges this DEV-beacon
    directionally which is then received by DEV1 and
    used to estimate its AOA
  • The training sequence is complete
  • DEVs use this training phase to ascertain if
    there is sufficient gain in the link to meet the
    stream throughput and latency requirements.

14
Adapting IEEE 802.15.3 DEV-DEV communication
PNC
DEV2
DEV1
Create stream procedure
Omni beacon
AOA estimation
Directional special-ACK
AOA estimation
Directional-directional link
15
Adapting IEEE 802.15.3 Communicating in the CAP
  • How do we communicate during the CAP?
  • This is where we should exploit spatial reuse
  • Borrow ideas from 1, employ
  • Directional RTS/CTS
  • Directional NAV (DNAV)
  • AOA caching
  • Beam lock and unlocking
  • Combat hidden node problem

16
Conclusions and further work
  • A simple set of amendments to the existing IEEE
    802.15.3-2003 standard are proposed
  • Ensuring compatibility with omni-directional DEVs
  • Many outstanding issues
  • Impact on throughput
  • Modulation format (PHY dependent)
  • Details training sequence for DEV-DEV AOA
    training phase
  • Need simulation results for overall MAC behaviour
    with these modifications
Write a Comment
User Comments (0)
About PowerShow.com