Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 1 Intra-Vehicle Channel Model Date: 20-Jan-2014 Authors:

Slides:

Advertisements

Similar presentations

Doc.: IEEE / hew Submission March 2014 Raja Banerjea, CSRSlide 1 A Simplified Simultaneous Transmit and Receive Mechanism Date:

Advertisements

Doc.: IEEE n Submission Jan 2004 M.Faulkner, ATcrcSlide 1 Low Overhead Pilot Structures Igor Tolochko and Mike Faulkner, ATcrc, Victoria.

Submission doc.: IEEE /0296r0 March 2015 Cagatay Capar, EricssonSlide 1 Long range indoor channel measurements for the 60 GHz band Date:

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

Doc.: IEEE /0630r0 Submission May 2015 Intel CorporationSlide 1 Verification of IEEE ad Channel Model for Enterprise Cubical Environment.

Submission doc.: IEEE 11-15/0629-r1 Using for Locating Purposes in the Vehicle Environment May 2015 Igal Kotzer, General MotorsSlide 1 Authors:

Submission doc.: IEEE / 0431 r0 March 2015 Dmitry Cherniavsky, SiBEAM, Inc.Slide 1 Shared MIMO Architecture for ay. Date: Authors:

Doc.: IEEE /0361r0 Submission March 2011 David Halasz, OakTree WirelessSlide 1 Indoor Channel Models for ah Date: Authors:

Channel Sounding for ay

Submission doc.: IEEE /0808 July 2015 Songnam Hong, EricssonSlide 1 Frequency-independent Digital Precoder for Hybrid MIMO Precoding Date:

By: Matthew Follett. Introduction  A Wireless local area network (WLAN) links two or more devices using some wireless distribution method and usually.

Submission doc.: IEEE 11-12/0844r0 Slide 1 Non-linear Multiuser MIMO for next generation WLAN Date: Authors: Shoichi Kitazawa, ATR.

Doc.: IEEE /0984r0 Submission September 2008 John R. Barr, Motorola, Inc.Slide 1 Bluetooth test cases with n 40 MHz Date: Authors:

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

Submission doc.: IEEE /0065r0 July 2015 Alaa Mourad, BMW GroupSlide 1 Coexistence Management in the 2.4GHz ISM Band in the automotive enviroment.

Doc.: IEEE /0493r1 Submission May 2010 Changsoon Choi, IHP microelectronicsSlide 1 Beamforming training for IEEE ad Date: Authors:

Doc.: IEEE htsg Submission July 2003 MetalinkSlide 1 Time Variable HT MIMO Channel Measurements Nir Tal Metalink

Submission doc.: IEEE 11-14/0586r0 May 2014 Igal Kotzer, General MotorsSlide 1 Automotive Considerations for the Simulation Scenarios Date: 12-May-2014.

Submission doc.: IEEE 11-14/0365r0 March 2014 Igal Kotzer, General MotorsSlide 1 Extended Intra-Vehicle Channel Model Date: 20-Jan-2014 Authors:

Doc.: IEEE /0364r1 SubmissionEldad Perahia, Intel CorporationSlide 1 Date: Authors: Antenna Array Gain from Measured Data for n/ac.

Submission doc.: IEEE /1487r0 November 2014 Amichai Sanderovich, QualcommSlide 1 NG60 Channel model challenges Date: Authors:

1 Energy Efficiency of MIMO Transmissions in Wireless Sensor Networks with Diversity and Multiplexing Gains Wenyu Liu, Xiaohua (Edward) Li and Mo Chen.

Doc.: IEEE d_Intra-Device_Propagation_Measuremets Submission March 2015 Slide 1 Project: IEEE P Working Group for Wireless Personal.

Doc.: IEEE /1011r0 Submission September 2009 Alexander Maltsev, IntelSlide 1 Verification of Polarization Impact Model by Experimental Data Date:

Doc.: IEEE /0553r1 Submission May 2009 Alexander Maltsev, Intel Corp.Slide 1 Path Loss Model Development for TGad Channel Models Date:

Submission doc.: IEEE /0081r0 October 2015 Alaa Mourad, BMW GroupSlide 1 Wireless Coexistence in the Automotive Environment – System Model Date:

J. Patrick Frantz Executive Director Center for Multimedia Communication Rice University IEEE Vehicular Technology Conference April 24, 2003 J. Patrick.

Doc.: IEEE /232r0 Submission March 2002 Todor Cooklev, AwareSlide 1 Extended Data Rate a Marcos Tzannes Todor Cooklev Dongjun Lee Colin.

Jan doc.: ban Slide 1 Submission Dries Neirynck - University of Bristol - MVCE Project: IEEE P Working Group for Wireless Personal.

Doc.: IEEE /0493r0 Submission May 2010 Changsoon Choi, IHP microelectronicsSlide 1 Beamforming training for IEEE ad Date: Authors:

Submission doc.: IEEE /1094 Overview and discussion about the next steps for ay channel modeling Date: Authors: Slide 1.

Doc.: IEEE /235r0 Submission May 2001 Philips SemiconductorsSlide 1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)

Doc.: IEEE /1044r0 Submission September 2008 Alexander Maltsev, IntelSlide 1 60 GHz WLAN Experimental Investigations Date: Authors:

Submission doc.: IEEE /1347r0 November 2015 Filippo Tosato, ToshibaSlide 1 Strategies to reduce MIMO feedback overhead Date: Authors:

Submission doc.: IEEE 19-15/0084r0 Nov 2015 Igal Kotzer, General MotorsSlide 1 On The Intra-Vehicle Channel Model Date: 21-Oct-2015 Authors:

Doc.: IEEE /0568r0 Submission April 2011 Shusaku Shimada 1 Industrial Channels of Usecase 1d/2 Date: Authors:

Doc.: IEEE /1229r1 Submission November 2009 Alexander Maltsev, IntelSlide 1 Application of 60 GHz Channel Models for Comparison of TGad Proposals.

Doc.: IEEE /0992r1 Submission September 2008 John R. Barr, Motorola Inc.Slide 1 20/40 MHz 11n Interference on Bluetooth Date: Authors:

Doc.: IEEE /0632r0 Submission May 2015 Intel CorporationSlide 1 Experimental Measurements for Short Range LOS SU-MIMO Date: Authors:

Doc.: IEEE /0632r0 Submission May 2008 Vinko Erceg, BroadcomSlide 1 VHT 60 GHz Channel Model Recommendation Date: Authors:

Doc.: IEEE /327 Submission July 2002 Intel Research and Development Slide 1 Project: IEEE P Working Group for Wireless Personal Area Networks.

Doc.: IEEE /0112r2 Submission January, 2010 Hirokazu Sawada, Tohoku UniversitySlide 1 [Intra-cluster response model and parameter for channel.

Doc.: IEEE Submission Nov 2014 Link Budget Analysis for 40-50GHz Indoor Usage Date: Authors: Slide 1Jianhan Liu, Mediatek Inc.

Doc.: IEEE Submission Nov 2008 Slide 1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission.

Doc.: IEEE /1121r0 Submission November 2009 I. Siaud, Orange LabsSlide 1 Path Loss Models for TGad Channel Models: Antenna and Dispersion Impact.

Doc.: IEEE /1313r2 Submission November 2010 Roberto Aiello, Jim LansfordSlide 1 Channel model need for ah Date: Authors:

Antenna Developments for WiFi Phase Applications Diversity MIMO.

Submission doc.: IEEE 11-13/1420r0 November 2013 Igal Kotzer, General MotorsSlide 1 HEW Considerations for the Vehicular Environment Date: Authors:

Submission doc.: IEEE /0043r0 March 2016 Alaa Mourad, BMWSlide 1 Wireless Coexistence in the Automotive Domain – Testing Scenarios Date:

Doc.: IEEE /0992r0 Submission September 2008 John R. Barr, Motorola Inc.Slide 1 20/40 MHz 11n Interference on Bluetooth Date: Authors:

Doc.: IEEE /0015r1 Submission Large-Scale Characteristics of 45 GHz Based on Channel Measurement Authors/contributors: Date: Presenter:

Submission doc.: IEEE /0061r0 Slide 1Igal Kotzer, General Motors March 2016 Automotive Environment Interference Evaluation Proposal Date:

InterDigital, Inc. Submission doc.: IEEE /0911r1 July 2016 Link Level Performance Comparisons of Open Loop, Closed Loop and Antenna Selection.

Submission doc.: IEEE /0106r0 July 2016 Sirius XM Radio, Inc.Slide 1 In-Vehicle Wireless Interference Date: Authors: Notice: This document.

HEW Considerations for the Vehicular Environment

Using for Locating Purposes in the Vehicle Environment

Open Loop vs Closed Loop SU-MIMO for 11ay

On the Channel Model for Short Range Communications

Discussions on 11ac PHY Efficiency

Summery of Channel Measurement for the ay Channel Model Document

Potential TGbb task group documents

Discussions on 11ac PHY Efficiency

Elevation Effect on MIMO Channel

Discussions on 11ac PHY Efficiency

Discussions on 11ac PHY Efficiency

September 2009doc.: IEEE wng0

January, 2010 [Intra-cluster response model and parameter for channel modeling at 60GHz (Part 3)] Date: Authors: Hirokazu Sawada, Tohoku University.

September 2009doc.: IEEE wng0

Outdoor measurement for a rooftop to street scenario at 60 GHz

<month year> IEEE Jan

Presentation transcript:

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 1 Intra-Vehicle Channel Model Date: 20-Jan-2014 Authors:

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 2 Abstract In this submission the wireless channel inside a vehicle is discussed.

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 3 Introduction Wireless LAN is becoming a leading standard in vehicular communications Many vehicle models today have a built in WLAN communication WLAN is present in virtually every consumer electronic device Vehicle manufacturers adapt the vehicles to the changes in consumer electronics WLAN is used in intra-vehicle infotainment systems WLAN can also be used for vehicular sensor linking The number of vehicle models equipped with WLAN is constantly increasing

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 4 WLAN in the Vehicle – Channel Perspective The vehicular environment posts some unique challenges for WLAN systems aiming at providing top performance WLAN can be used in three vehicular scenarios: Intra-vehicle communication – mainly for infotainment Inter-vehicle communication such as multimedia, mesh networking Vehicle to infrastructure In this submission the intra-vehicle 2.4GHz wireless channel will be discussed

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 5 Intra-Vehicle Wireless Channel Measurements Setup The wireless channel measurements were performed using the following equipment: GM SUV vehicle Agilent PNA N5242A network analyser 4 omni-directional WiFi antennas in a 2x2 configuration In this setup there was no driver / passengers in the vehicle

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 6 Intra-Vehicle Wireless Channel Measurements Setup

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 7 Intra-Vehicle Wireless Channel Measurements Locations Front of the vehicleRear of the vehicle 1, 2, 3Dashboard heightA, B, C, DRear passenger head height 4, 5, 6, 7Kick Panels (Low behind dashboard) E, F, G, HRear passenger seat height I, J, K, LRear passenger foot height M, N, O, PTrunk floor height All possible rear-front combinations were measured (112 measurements)

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 8 Intra-Vehicle Wireless Channel Measurements Locations A B C D E F G H Trunk I J K L M N O P

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 9 Intra-Vehicle Wireless Channel Path Loss

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 10 Intra-Vehicle Wireless Channel Path Loss Wireless indoor model Intra-vehicle based model Mean path lossFree space path loss 1.5m 19dB Shadowing variance 10dB

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 11 Intra-Vehicle Wireless Channel Delay Spread

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 12 Intra-Vehicle Wireless Channel Path Loss RMS channel delay spread: 22ns No clustering effect was seen Wireless indoor modelIntra-vehicle based model RMS channel delay spread40ns – 600ns for one cluster22ns

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 13 Intra-Vehicle MIMO Channel Matrix Condition Number and Rank All of the measured 2x2 MIMO channel matrices have a rank of 2 The channel matrix’s condition number varies significantly between bands and within bands. Based on the measurements the condition number varies between 0dB to 30dB

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 14 Intra-Vehicle Wireless Channel Matrix Condition Number and Rank

Submission doc.: IEEE 11-14/0088r0 Jan 2014 Igal Kotzer, General MotorsSlide 15 Intra-Vehicle Wireless Channel Discussion The RX power of an intra-vehicle WLAN system is strong relative to indoor scenarios Initial measurements of inter-vehicle interference suggest RX SNR of about 30dB The intra-vehicle channel delay spread is very short, thus it is possible to shorten the CP and gain efficiency It is theoretically possible to achieve full 2x2 MIMO, however due to large changes in the streams’ power it is hard to implement practically. Addressing this issue, especially in a non Rx power limited environment can increase performance.