Considerations on down-clocking ratio

Slides:

Advertisements

Similar presentations

Doc.: IEEE Submission Sep 2013 Slide 1 Summary On HEW Channel Models Date: Authors:

Advertisements

Submission doc.: IEEE 11-13/0843r0 July 2013 Wookbong Lee, LG ElectronicsSlide 1 Further evaluation on outdoor Wi-Fi Date: Authors:

Submission doc.: IEEE 11-14/0801r0 July 2014 Dongguk Lim, LG ElectronicsSlide 1 Envisioning 11ax PHY Structure - Part II Date: Authors:

Doc.: IEEE /1387r0 Submission Nov Yan Zhang, et. Al.Slide 1 HEW channel modeling for system level simulation Date: Authors:

Doc.: IEEE /0272r0 Submission February 2011 Ron Porat, Broadcom Outdoor Path Loss Models for ah Date: Authors: Slide 1.

Doc.: IEEE /1146r0 Submission Update on HEW Channel Model Slide 1 Date: Authors: July 2013 Shahrnaz Azizi (Intel)

Preamble Considerations in Large Channel Delay Spread Scenarios

Submission doc.: IEEE 11-13/0996r2 Aug 2013 Josiam, Taori, Tong - SamsungSlide 1 Outdoor Channel Model Candidates for HEW Date: Authors:

Doc.: IEEE /1376r2 Submission Nov 2013 Slide 1 Discussions on Penetration Loss Date: Authors:

Doc.: IEEE /0323r0 SubmissionRon Porat, BroadcomSlide 1 Views on ah Use Cases Date: Authors: March 2011.

Submission doc.: IEEE 11-14/0627r0 May 2014 Josiam et.al., SamsungSlide 1 Outdoor Channel Models for System Level Simulations Date: Authors:

Submission doc.: IEEE 11-13/0536r0 May 2013 Wookbong Lee, LG ElectronicsSlide 1 HEW SG PHY Considerations For Outdoor Environment Date: Authors:

Doc.: IEEE /0786r0 Submission July 2013 Wu TianyuSlide 1 Discussions on System Level Simulation Methodology Date: Authors:

Doc.: IEEE /1125r1 Submission Sept 2013 Hongyuan Zhang, et. Al.Slide 1 HEW Outdoor Channel Model Discussions Date: Authors: Name AffiliationsAddressPhone .

Doc.: IEEE c Submission January 2006 Ali Sadri (Intel Corporation)Slide 1 Project: IEEE P Working Group for Wireless Personal.

Submission doc.: IEEE 11-13/1383r0 November 2013 Wookbong Lee, LG ElectronicsSlide 1 System Level Simulation Parameters Date: Authors:

WUR Link Budget Analysis

WUR Link Budget Analysis

Proposal for Statistical Channel Error Model

WUR Link Budget Analysis Follow-up: Data Rates and SIG Bits Protection

Channel Model Considerations for P802.11af

PHY Design Considerations for af

Estimated delay spread of industrial plant

Pathloss Model Considerations for ah

Considerations on HEW Evaluation Methodology

Month Year doc.: IEEE yy/xxxxr0 November 2017

On the Suitability of Repetition for ah

Comparisons of Simultaneous Downlink Transmissions

WF on scenarios and evaluation assumptions for flexible duplex

Simulation results for

PHY abstraction and performance for outdoor channel models

Signal Bandwidth and Sequence for OOK Signal Generation

OFDMA Performance Analysis

TGad Channel Model Update

6-10GHz Rate-Range and Link Budget

Jan Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Proposal for sub-GHz Interference Model] Date.

Evaluation of WUR sync sequence

Evaluation of WUR sync sequence

HEW Outdoor Channel Model Discussions

Outdoor Channel Model Simulation Follow-up

OFDMA Performance Analysis

Signal Bandwidth and Sequence for OOK Signal Generation

Month Year doc.: IEEE yy/xxxxr0 July 2015

Simulation of NGV Channel Models

Simulation of NGV Channel Models

802.11ac Channel Modeling Authors: Jan 19, 2009 Month Year

Simulation of NGV Channel Models

19, Yangjae-daero 11gil, Seocho-gu, Seoul , Korea

Signal Bandwidth and Sequence for OOK Signal Generation

Discussion on WUR Multi-Antenna Transmission

HEW Outdoor Channel Model Discussions

Synchronization Requirements

Submission Title: [Wireless Display Throughput Requirements]

Simulation of NGV Channel Models

PHY designs for NGV Date: Authors:

doc.: IEEE yy/xxxxr0 Date:

PHY designs for NGV Date: Authors:

Link Budget Analysis Date: Authors: November 2015

LDPC Investigation for 11bd

OFDMA Performance Analysis

Discussion on IMT-2020 mMTC and URLLC

Numerology for 11ax Date: Authors: March 2015 Month Year

PHY Performance Evaluation with 60 GHz WLAN Channel Models

DSC Calibration Result

Simulation of LTE-V and WAVE

Signal Bandwidth and Sequence for OOK Signal Generation

Consideration on System Level Simulation

<month year> IEEE Jan

doc.: IEEE yy/xxxxr0 Date: September, 2019

Presentation transcript:

Considerations on down-clocking ratio March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 Considerations on down-clocking ratio Date: 2012-03-09 Authors: Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 Abstract This document includes considerations for selecting down- clocking ratio. Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

Introduction There are two major use cases for IEEE 802.11af system March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 Introduction There are two major use cases for IEEE 802.11af system In-home media distribution Cellular offloading One of the consideration point when we decide down-clockin g ratio is channel statistics of possible use cases (especially d elay spread) To see delay spread statistics, we examine well-kwon channe l model used for IMT-Adv. Evaluation Guidelines for evaluation of radio interface technologies for IMT-Adv anced, REPORT ITU-R M.2135 [1] (especially annex A 1.3.1 to 1.3. 2.1) IST-4-027756 WINNER II D1.1.1 V1.1 [2] (especially section 4.2) Since channel model depends on user location (LoS/NLoS/Ot oI), we examine multiple location for each channel model Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

Channel model (Summary) March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 Channel model (Summary) Scenario InH UMi UMa LoS NLoS O-to-I Delay Spread (log10(s)) (-7.7, 0.18)* (-7.41, 0.14) * (-7.19,0.4)* (-6.89,0.54)* (-6.62,0.32)* (-7.03,0.66)* (-6.44,0.39)* K-factor (K) (dB) (7,4)* N/A (9,5)* (9,3.5)* Delay distribution Exp Delay scaling parameter 3.6 3 3.2 2.2 2.5 2.3 Number of cluster 20 Per cluster shadowing std ζ (dB) 6 4 LoS probability as a function of distance, d(m) * (μ,σ) For SNR evaluation, we assume noise figure 5dB, cable loss 2dB, 700MHz center frequency, signal power -1.8dBm per 100kHz (PSD). Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

Indoor Hotspot (InH) March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 User Location Average SNR (dB) Mean rms delay (ns) 10m 66.62 8.2 50m 54.73 22.6 100m 49.69 Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

Urban Micro (UMi) March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 User Location Average SNR (dB) Mean rms delay (ns) 30m 54.90 180 100m 31.42 238 500m -1.67 Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

Urban Macro (UMa) March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 User Location Average SNR (dB) Mean rms delay (ns) 30m 53.07 163 100m 37.42 364 500m 1.4742 Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 Observation In most cases, CP size with 4us provides enough protection (90% probability of 5 times rms delay spread are within CP length) So, 5x down-clock from IEEE 802.11ac PHY will be good candidates for IEEE 802.11af PHY And we may need to think about 4x down-clock if 5MHz BW can be fit into 6MHz TV channel Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics

March 2012 doc.: IEEE 802.11-12/0330r0 March 2012 References [1] Report M.2135, “Guidelines for evaluation of radio interface technologies for IMT-Advanced, ” available at http://www.itu.int/pub/R-REP-M.2135 [2] IST-4-027756 WINNER II D1.1.1 V1.1, “WINNER II i nterim channel models,” available at http://www.ist-wi nner.org/deliverables.html Wookbong Lee, LG Electronics Wookbong Lee, LG Electronics