Submission doc.: IEEE 11-13/1080r0 September 2013 Joseph Levy, InterDigital Communications Inc..Slide 1 Markov Modeling of the Channel for HEW System Level.

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Submission doc.: IEEE 11-13/1080r0 September 2013 Joseph Levy, InterDigital Communications Inc..Slide 1 Markov Modeling of the Channel for HEW System Level Simulations Date: Authors:

Submission doc.: IEEE 11-13/1080r0 September 2013 Joseph Levy, InterDigital Communications Inc..Slide 2 Abstract This contribution proposes that a Markov Model be used in system level simulations to provide an accurate and efficient means of including fast fading of outdoor channels for HEW system level modelling. Similar methods have been used by 3GPP for LTE modelling and for e modelling.

Submission doc.: IEEE 11-13/1080r0 Motivation To provide an accurate and efficient outdoor physical channel model for HEW system level simulations. Markov modeling techniques can provide such a system level simulation model. ([2], [5], [10]) The Markov modeling technique can be used for any agreed channel model (e.g. WINNER2, ITU, or customized) The modeling approach and channel model(s) used for system level simulations are important considerations which should be agreed to allow for meaningful comparison of performance results. Slide 3 Joseph Levy, InterDigital Communications Inc.. September 2013 (10^5)

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 4 This contribution provides: A description of the proposed Finite State Markov Chain (FSMC) system level modeling Examples of calculated transition probability matrix (TPM) for some channel models of interest. Joseph Levy, InterDigital Communications Inc.. Discussion (10^5)

Submission doc.: IEEE 11-13/1080r0 Description of the proposed Finite State Markov Chain (FSMC) system level modeling September 2013 Joseph Levy, InterDigital Communications Inc..Slide 5

Submission doc.: IEEE 11-13/1080r0 Finite State Markov Chain Model the channel SNR as a finite-state Markov chain (FSMC) Each state represents a given value (range) of the SNR The following example has four different SNR states Slide 6Joseph Levy, InterDigital Communications Inc.. September 2013

Submission doc.: IEEE 11-13/1080r0 Use of FSMC in System Level Simulations Slide 7Joseph Levy, InterDigital Communications Inc.. September 2013

Submission doc.: IEEE 11-13/1080r0 Transition Probability Matrix (TPM) Slide 8Joseph Levy, InterDigital Communications Inc.. September 2013

Submission doc.: IEEE 11-13/1080r0 In modeling the physical channels, we need to convert multiple SNR values (one per subcarrier) into one single SNR value Potential approaches Throughput averaging (algo 1) Straightforward, not MCS dependent effective channel amplitude square SNR averaging (algo 2) Used by OPNET for LTE downlink/uplink Exponential effective SNR mapping (EESM), received bit mutual information (RBIR), Mean mutual information per bit (MMIB) [10] MCS dependent (not studied herein) Multi-Carrier SNR Mapping Slide 9Joseph Levy, InterDigital Communications Inc.. September 2013

Submission doc.: IEEE 11-13/1080r0 Examples of calculated transition probability matrix (TPM) for some channel models of interest. September 2013 Joseph Levy, InterDigital Communications Inc..Slide 10

Submission doc.: IEEE 11-13/1080r0 Proposed HEW Use Cases [9] Slide 11Joseph Levy, InterDigital Communications Inc.. September High density of APs and high density of STAs per AP astadium bairport/train stations cexhibition hall dshopping malls eE-Education f Multi-media Mesh backhaul 2 High density of STAs – Indoor adense wireless office bpublic transportation clecture hall dManufacturing Floor Automation 3 High density of APs (low/medium density of STAs per AP) – Indoor adense apartment building bCommunity Wi-Fi 4 High density of APs and high density of STAs per AP – Outdoor aSuper dense urban Street bPico-cell street deployment cMacro-cell street deployment 5 High throughput demanding applications asurgery/health care (similar to 2e from 11ac) bproduction in stadium (similar to 1d-1e from 11ac) csmart car

Submission doc.: IEEE 11-13/1080r0 Urban Micro Channels in HEW Urban Micro cellular environment fits well in HEW [8] “The microcellular test environment focuses on small cells and high user densities and traffic loads in city centers and dense urban areas. The key characteristics of this test environment are high traffic loads, outdoor and outdoor-to-indoor coverage. This scenario will therefore be interference-limited, using micro cells.” [7] Slide 12Joseph Levy, InterDigital Communications Inc.. September 2013 WINNER 2 model Metropolitan (C2) Typical Urban (B1, B4) Indoor to outdoor (A2) Rural macro (D1) ITU model Urban macro (UMa) Urban micro (UMi) Indoor (InH) High speed (RMa)

Submission doc.: IEEE 11-13/1080r0 TPM Generation Algorithm Generate multiple (10^5) pairs of channel samples, each pair are separated by N OFDM symbols (N * 3.2  s) Each consists of multiple taps according to the channel model, e.g. WINNER 2 or ITU Will serve as current state and next state in statistics collection For each sample in the channel sample pair, Convert it to freq domain using DFT Convert multiple subcarrier SNRs into one effective SNR (either SNR averaging or throughput averaging) Quantize the effective SNRs into P (16) equi-prob states Find the probability of each state transitioning into other states accordingly Slide 13Joseph Levy, InterDigital Communications Inc.. September 2013

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 14 Simulation Assumptions 1)Channel Scenarios: WINNER 2 B1, ITU UMi Directly comparable channel scenarios 2)Single transmit and single receive antenna 3)OFDM symbol separation between current and next state: 10 or 100 4)Large scale signal to noise ratio: 0 or 20dB 5)Mobile velocity: 3 or 30 km/hr 6)Two algorithms considered for determination of effective SNR: 1)Throughput averaging 2)SNR averaging Joseph Levy, InterDigital Communications Inc..

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 15Joseph Levy, InterDigital Communications Inc.. The generated TPM are more or less similar for WINNER 2 B1 and ITU UMi ITU/WINNER 2 Comparison, 100 symbols. 20dB SNR, 30 km/h, Throughput Averaging

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 16Joseph Levy, InterDigital Communications Inc.. The generated TPM are more or less similar for WINNER 2 B1 and ITU UMi ITU/WINNER 2 Comparison, 100 symbols. 20dB SNR, 30 km/h, SNR Averaging

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 17Joseph Levy, InterDigital Communications Inc.. Large scale SNR does not change the TPM noticeably (throughput averaging) SNR Comparison, 20dB vs. 0dB, 100 symbols, 30 km/h, WINNER 2 B1 Throughput Averaging

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 18 Discussion on Multi-Carrier SNR Mapping SNR averaging Simple, independent of large scale SNR SNR averaging occurs in the linear domain Throughput averaging Strictly speaking depending on large scale SNR This dependence is weak though (see comparison on previous page) and may be removed for simplicity The mapping may thus be approximated by SNR averaging in the dB domain Joseph Levy, InterDigital Communications Inc.. Throughput averaging SNR averaging in the dB domain

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 19 Simulation Summary Markov modeling of PHY multipath channels in HEW TPM more or less similar for ITU UMi and WINNER 2 B1 channel Faster velocity leads to more state changes in TPM Larger separation leads to more state changes in TPM Converting multiple subcarrier SNRs into a single value SNR averaging in the linear domain Throughput averaging may be approximated by SNR averaging in the dB domain More complex averaging may be used The general method may be applied to any other indoor or outdoor channels for HEW system level simulations ITU channels WINNER 2 channels and others Joseph Levy, InterDigital Communications Inc..

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 20 Potential Items of Agreement 1.Use of Markov modeling of PHY multipath channels Channel model(s) to be used (e.g. ITU UMi and WINNER 2 B1) Velocities to be considered SNR to be considered Number of Symbols to be averaged 2.Method of converting multiple subcarrier SNR Throughput averaging More complex averaging 3.TPM for each agreed configuration Generate multiple (e.g. 10^5) pairs, number of symbols separating pairs, N Number of equi-probable states, P (e.g. 16) Joseph Levy, InterDigital Communications Inc..

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 21 References [1] IEEE /0722r1, “HEW SG Evaluation Methodology”, Intel. [2] IEEE /0184r0, “802.11n TGn proposal for PHY abstraction in MAC simulators,” ST Microelectronics. [3] R. Yaniv et. Al., “CINR measurements using the EESM method”, IEEE C802.16e- 05/141r3. [4] L. Hentilä, P. Kyösti, M. Käske, M. Narandzic, and M. Alatossava. (2007, December.) MATLAB implementation of the WINNER Phase II Channel Model ver1.1 [Online]. Available: [5] OPNET Technologies Inc., “LTE PHY Multipath Fading Models – Design Document”. [6] Software implementation of IMT.EVAL channel model, doc num: IST [7] Report ITU-R M (12/2009) Guidelines for evaluation of radio interface technologies for IMT Advanced [8] IEEE /0996r1,. “Outdoor Channel Model Candidates for HEW”, K. Josiam, R. Taori, and F. Tong, [9] IEEE /0657, “Usage models for IEEE High Efficiency WLAN study group (HEW SG) – Liaison with WFA”, Laurent Cariou [10] IEEE m-08/004r5, “IEEE m Evaluation Methodology Document (EMD)” Joseph Levy, InterDigital Communications Inc..

Submission doc.: IEEE 11-13/1080r0 Additional TPM plots September 2013 Joseph Levy, InterDigital Communications Inc..Slide 22

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 23Joseph Levy, InterDigital Communications Inc.. Faster velocity leads to more state transitions Velocity Comparison, 30 km/h vs. 3 km/h, 100 symbols, 20dB, WINNER 2 B1 Throughput Averaging

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 24Joseph Levy, InterDigital Communications Inc.. Larger separation leads to more state transitions Packet Duration Comparison, 10 vs. 100 symbols, 20dB, 30 km/h, WINNER 2 B1 Throughput Averaging

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 25Joseph Levy, InterDigital Communications Inc.. Algorithm Comparison,100 symbols, 20dB, 30 km/h, WINNER 2 B1

Submission doc.: IEEE 11-13/1080r0September 2013 Slide 26Joseph Levy, InterDigital Communications Inc.. Algorithm Comparison,100 symbols, 20dB, 30 km/h, ITU Channel UMi