Doc.: IEEE 802.11-14/0214r0 Submission February 2014 Perahia, Cariou, Cho, Inoue, Liu and TaoriSlide 1 High Efficiency WLAN Overview Date: 2014-02-06 Authors:

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doc.: IEEE /0214r0 Submission February 2014 Perahia, Cariou, Cho, Inoue, Liu and TaoriSlide 1 High Efficiency WLAN Overview Date: Authors:

doc.: IEEE /0214r0 Submission February 2014 Slide 2 Introduction and problem statement The vast majority of deployments will evolve towards high density scenarios in the near future –usage models in such scenarios are likely to suffer bottlenecks in the coming years, with inefficiencies in transforming the multi-Gbps peak capacity into real throughput experienced by users HEW aims to achieve a very substantial increase in the real-world throughput achieved by users in such scenarios, with improved power efficiency for battery powered devices –Creating an instantly recognizable improvement in User Experience of the major use cases IEEE HEW SG is proposing a PAR for a TG to create an amendment to for operations in frequency bands between 1 GHz and 6 GHz –focused primarily on 2.4 GHz and the 5 GHz frequency bands Expected MAC and PHY modifications in focused directions: –(1) To improve efficiency in the use of spectrum resources in dense networks with large no. of STAs and large no. of APs –(2) To improve efficiency and robustness in outdoor deployments –(3) To improve power efficiency Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission February 2014 Market Drivers Various market segments require enhancement of average throughput and user experience in dense deployment scenarios Operators desire cellular offload to lighten traffic explosion Annual global IP traffic will pass the Zetabyte threshold by end of ). PC/Mobile/CE vendors desire higher user experience 100% Wi-Fi attach-rate for smart phones, which requires improved power-efficiency Video traffic will be 55% of all consumer Internet traffic by ), which demands improved satisfaction of latency, jitter, and packet loss requirements of delay sensitive applications Attach-rate for smart pad/TV/appliances is substantially increasing Automotive is increasingly using Wi-Fi for in-car entertainment Chip/AP vendors desire successive Wi-Fi market evolution after 11ac Operator Manufacturer Chip/AP vendor 1) Source: Cisco VNI Global Forecast, Need a standard to enhance average throughput and user experience in real world Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission Need for the Project Very dense deployments –Enterprise, residential, operator hotspots, retail and ad-hoc scenarios –Characterized by the existence of many access points and non-AP stations in geographically limited areas –Increased interference from neighboring devices gives rise to performance degradation Growing use of WLAN outdoors Better support of real-time applications with improved power efficiency –Video traffic is expected to be the dominant type of traffic in many high efficiency WLAN deployments –WLAN users demand improved performance in delivering their real-time applications –Operators expect sufficient user experience to offload traffic on WLAN Focusing on improving metrics that reflect user experience in typical conditions –Improving the average per station throughput, the 5 th percentile of per station throughput, and area throughput, etc. –Evaluation with a set of typical deployment scenarios representative of the main expected usage models February 2014 Slide 4Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission Environments From Wi-Fi Alliance liaison report: –Airport / Train station –E-education –Public transportation –Dense apartment building –Pico-cell street deployment Additional environments from HEW SG submissions: –Enterprise On desk and in cubicle Conference room Dense deployment –Small Office –Hotspot in public places (Exhibition halls, Shopping malls) –Outdoor hotspots park, streets, stadium, special crowded events co-location with cellular base stations (small cell deployments) or user equipment (e.g. private mobile APs such as mobile routers) in dense zones –Hospital February 2014 Slide 5 Environments discussed in the study group include: Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission New and Enhanced Applications: Cellular Offloading Cloud Computing - including VDI (Virtual Desktop Infrastructure) Display Sharing - 1-to-1 (Phone - TV), 1-to-many (classroom), Many-to-1 (security) Interactive Multimedia & Gaming Progressive Streaming Real-time Video Analytics & Augmented Reality Support of wearable devices Unified Communications - Including Video conferencing User Generated Content (UGC) Upload & Sharing Video conferencing/tele-presence Video distribution at home – new video resolution (VHD, UHD) Wireless docking February 2014 Slide 6Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission HEW Differentiating Features Previous AmendmentsHEW Amendments being considered Objectives Increase the per-link peak throughput Increase the average per STA throughput in dense environments Scenarios Single application for a single client in indoor situations Dense deployment environments with a mix of clients/APs and traffic types including outdoor situations KPIs/ Metrics Peak rate driven - Link throughput, - Aggregate throughput User Experience Driven -Average per station throughput, -5 th %ile per station throughput, -Area throughput -Power efficiency Slide 7 February 2014 Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission Technologies HEW will consider MAC and PHY technologies that improve WLAN efficiency in focused directions: –Make more efficient use of spectrum resources in scenarios with a high density of STAs per BSS. –Significantly increase spectral frequency reuse and manage interference between neighboring overlapping BSS (OBSS) in scenarios with a high density of both STAs and BSSs. –Increase robustness in outdoor propagation environments and uplink transmissions. –Maintain or improve the power efficiency per station The next few slides show some examples –These example slides do not represent technologies agreed for inclusion in the standard Slide 8 February 2014 Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 SubmissionSlide 9 Possible Technologies (1 of 3) Freq a n (40 MHz) ac (80 MHz) ac (160 MHz) Freq a n (40 MHz) ac (80 MHz) OFDMA Capable STA OFDMA Capable STA OFDMA Capable STA OFDMA Capable STA, or ac STA (160 MHz) Ch.1 Ch.2 Ch.3 Ch.4 Ch.5 Ch.6 Ch.7 Ch.8 Guard Band UL MU-MIMO Interference management Dynamic Sensitivity Control (DSC) DL MU-MIMO (802.11ac)  Spatial domain techniques for dense reuse of spectrum:  Frequency domain techniques for a more effective channel utilization February 2014 Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission Possible Technologies (2 of 3) Present: Either Tx or RXSimultaneous Tx & Rx Slide 10 AP Wireless devices either transmit or receive, but not both Low Spectral Utilization! AP ~2x throughput improvements! On the same time and frequency resource February 2014 PHY/MAC mechanisms for enabling In-Band simultaneous Tx and Rx to improve spectral efficiency Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission February 2014 Slide 11 Possible Technologies (3 of 3)  Technologies to mitigate the impact of management frames Many management frames impact the throughput of WLANs. Beacons, Probe Responses induced by a Probe Request. Those frames are usually transmitted using the lowest MCS. An example of captured frames in Tokyo area Efficient handling of management frames to minimize overhead Reference: A. Kishida, et. al., hew-Issues of Low-Rate Transmission.pptx Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission February 2014 Slide 12 HEW PAR Scope Four times improvement in the average throughput per station in a dense deployment scenario –Throughput is measured at the MAC data service access point –Expected to provide improvements of 5 – 10x Maintaining or improving the power efficiency per station Indoor and outdoor operations in frequency bands between 1 GHz and 6 GHz Enabling backward compatibility and coexistence with legacy IEEE devices operating in the same band Perahia, Cariou, Cho, Inoue, Liu and Taori

doc.: IEEE /0214r0 Submission February 2014 Slide 13 Related Submissions 11-13/0657r6, “HEW SG usage models and requirements - Liaison with WFA”11-13/0657r /1443r0, “Liaison from Wi-Fi Alliance on HEW Use Cases”11-13/1443r /1001r6, “Simulation Scenarios Document Template”11-13/1001r /1000r2, “Simulation Scenarios”11-13/1000r /331r5, “High efficiency WLAN”11-13/331r /339r10, “High efficiency WLAN straw poll”11-13/339r /1122r1, “Considerations for In-Band Simultaneous Transmit and Receive (STR) feature in HEW”11-13/1122r /169r0, “IEEE HEW SG Proposed CSD”11-14/169r /165r0, “ HEW SG Proposed PAR”11-14/165r0 Perahia, Cariou, Cho, Inoue, Liu and Taori