doc.: IEEE 802.11-13/1291r2

Submission Slide 1

Date: 2013-11-12

Presenter:

Dynamic Bandwidth Control for 802.11aj (60GHz New Technique Proposal)

Name Company Address Phone email Khiam-Boon Png Institute for

Infocomm Research (I2R) / CWPAN

1 Fusionopolis Way, #21-01 Connexis, Singapore

65-6408-2433

kbpng@i2r.a-star.edu.sg

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Author List

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Name Company EmailCHEN, Jiamin Huawei /CWPAN Jiamin.chen@mail01.huawei.com

CHEN, Qian I2R / CWPAN qchen@i2r.a-star.edu.sg

CHIN, Francois I2R /CWPAN chinfrancois@i2r.a-star.edu.sg

GAO, Bo Tsinghua /CWPAN bgao_cug@126.com

HAO, Peng JUST /CWPAN haopeng@just.edu.cn

HONG, Wei SEU /CWPAN weihong@seu.edu.cn

LI, Dejian Huawei/CWPAN lidejian@huawei.com

LI, Zhiqiang IMECAS /CWPAN lizhiqiang@ime.ac.cn

LIU, ZongruHangzhou Millimeter Wave

/CWPANjerry.liu@milliwave.cn

LIU, Pei Hisilicon /CWPAN liupei@hisilicon.com

LU, Su Huawei /CWPAN su.lu@huawei.com

PENG, Xiaoming I2R/CWPAN pengxm@i2r.a-star.edu.sg

PNG, Khiam Boon I2R /CWPAN kbpng@i2r.a-star.edu.sg

SUN, Bo ZTE/CWPAN sun.bo1@zte.com.cn

WANG, Haiming SEU /CWPAN hmwang@seu.edu.cn

YUE, Guangrong UESTC/CWPAN yuegr@uestc.edu.cn

ZHUO, Lan CESI/CWPAN this_zl7812@163.com

ZOU, Weixia BUPT/CWPAN zwx0218@bupt.edu.cn

doc.: IEEE 802.11-13/1291r2

Submission

Abstract

• This presentation is part and in support of the complete proposal described in IEEE 802.11-13-1301r0 (slides) and IEEE 802.11-13-1302r0 (text)

• This document is to propose a channelization for China 60GHz frequency band for 802.11aj (60GHz)

• This document is to propose a MAC protocol amendment to support dynamic bandwidth for 802.11aj (60GHz)

• The proposed MAC protocol supports the backward compatibility with 802.11ad legacy device

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Background: China 60GHz Spectrum• The released 60GHz spectrum in China only has 5GHz bandwidth, corresponding

to channel 2 & 3 used in IEEE 802.11ad.

USA, Canada, Korea

Europe

China

Japan

Australia

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Unlicensed 60 GHz spectrum bands.

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Proposed Channelization for 60GHz bands for 802.11aj (1/2)

Advantage of the proposed channelization for 60GHz bands in China China only has 5GHz bandwidth available in 59-64GHz only has two logical channels if only use 2.16 GHz BW Further divide 2.16GHz band used in 802.11ad channelization into two 1.08GHz sub-bands, then it become 6 logical channels: 2 bands with 2.16GHz bandwidth (Channel 2 & 3), 4 bands with 1.08GHz bandwidth (Channel 5, 6, 7, 8)；

Channelization for 60GHz bands in ChinaKB PngSlide 5

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Proposed Channelization for 60GHz bands for 802.11aj (2/2)

Support dynamic bandwidth Capable of supporting wider applications for lower power, e.g. Smart Phone, Tablet etc.

The impact to implementation in RF, Analog baseband is very minimal. It only needs to add to support four more new center frequency in PLL design, a new filter to support 1.08GHz in analog baseband etc；

The support of dynamic bandwidth in the channelization for China 60GHz bands provides the basis of keeping the interoperability with 802.11ad device；

Channelization for 60GHz bands in China

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Proposed MAC Protocol amendment for 802.11aj: support dynamic bandwidth and keep interoperability with 802.11adWhen operating in 2.16GHz channel （ Channel 2,3) ， it is capable of keeping interoperability with 802.11ad device；

When operating in 1.08GHz （ Channel 5,6,7,8）， it sends common beacon over 2.16GHz channel. The common beacon can use 802.11ad beacon as baseline so that 802.11ad device can also recognize the common beacon;

This allows 802.11aj device to keep the interoperability with 802.11ad device while exploring the benefits in channels with 1.08GHz bandwidth.

MAC Protocol: Support Dynamic Bandwidth

Proposed frame structure for IEEE 802.11aj

Revised 60GHz Channelization

Common Beacon(e.g., 802.11ad DMG Beacon frames)

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Proposed MAC Protocols (1)• Suppose that PCP/AP 1 operates in Channel 2 with 3 devices (STA 1, STA 2 and STA 3)• STA (to become PCP/AP 2) wants to share Channel 2

– STA (to become PCP/AP 2) may join PCP/AP 1’s network and send a Channel Split Request frame for the split of Channel 2.

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Channel Split Request frame Action field format

Order Information

1 Category

2 DMG Action

3 Dialog Token

4 Channel Switch Announcement element

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Proposed MAC Protocols (2)

Proposed Frame Structure to support Dynamic Bandwidth for 802.11aj

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Order Information

1 Category

2 DMG Action

3 Dialog Token

4 Channel Splitting field

5 Beacon Interval field (optional)

6 Channel Switch Announcement element (optional)

7 Extended Schedule element (optional)

Channel Split Response frame Action field format

• If PCP/AP 1 agrees to split Channel 2– PCP/AP 1 replies a Channel Split

Response frame to the STA (to become PCP/AP 2).

– PCP/AP 1 informs other STAs through a Channel Switch Announcement element contained in DMG Beacon/Announce frames .

– PCP/AP 1 proceeds to split Channel 2

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Proposed MAC Protocols (3)• After the split of Channel 2 into Channel 5 and Channel 6,

– PCP/AP 1 sends out common DMG beacons in Channel 2 during NP1 to announce its operation and shows its channel bandwidth status (using the reserved B45-46 to indicate Channel Bandwidth info) contained in Beacon Interval Control field).

– Following which PCP/AP 2 (The STA become PCP/AP 2) sends out common DMG beacon in Channel 2 during NP2 to announce its operation and shows its channel bandwidth status .

• PCP/AP 1 and PCP/AP 2 each creates a quiet period (QP) in their respective networks.• PCP/AP 2 synchronizes with PCP/AP 1 by receiving the time stamps in PCP/AP 1’s common DMG

beacons in its BTI.• Non-AP/non-PCP STAs continue their packet transmissions in small band network in Channel 5

after tuning in and receiving the DMG Beacon frames sent out by PCP/AP 1 in its BTI, coupled with the necessary procedures like beamforming, associations and new schedules for service periods (SPs) and contention-based periods (CBAPs).

• Non-AP/non-PCP devices STAs that want to join the network in Channel 6 have to tune in and receive DMG Beacon frames sent by PCP/AP 2 in its BTI, coupled with the necessary procedures.

Notification Period(NP) for PCP/AP 1

Notification Period (NP) for PCP/AP 2

Guard Interval(GI)

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Proposed MAC Protocols (4)• Constant monitoring of Channel 2 common DMG beacons sent out by

PCP/APs 1 and 2 in NP1 and NP2, respectively.• Assume Channel 6 ceases its network operation.

– Absence is noted by PCP/AP 1 when it detects no common DMG beacon frames sent during NP1.

– PCP/AP 1 shall wait for a aMaxExpireDuration duration before making the decision that Channel 6 network has ceased operation.

• Case 1: After which, the PCP/AP 1 can proceed to expand its bandwidth from Channel 5 to Channel 2 (see the following figure), or

• Case 2: After which, the PCP/AP1 can proceed to remain its operation in Channel 5.

Notification Period (NP) for PCP/AP 1 Notification Period (NP) for PCP/AP 2

Guard Interval(GI) Idle Period

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Proposed MAC Protocols (5)• Suppose that PCP/AP 1 starts up or operates in the small band, e.g., Channel

5. To mitigate interference, PCP/AP 1 must periodically send notification signals during notification periods (NPs) on Channel 2.

• Each NP contains at least a beacon header interval (BHI) which may include beacon transmission interval (BTI), association beamforming training (A-BFT) and / or announcement transmission interval (ATI) as shown in the following figure.

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Proposed MAC Protocols (6)• Later, a new PCP/AP 2 intends to start its network in the adjacent Channel 6.• First, PCP/AP 2 scans the channel to know whether Channel 6 is empty or not. • If Channel 6 is available, PCP/AP 2 will send a Channel Request frame to PCP/AP 1 for NP

allocation. • PCP/AP 1 may reject the PCP/AP 2 request if another network has been successfully

established in Channel 6. Otherwise, PCP/AP 1 should accept PCP/AP 2 request through a Chanel Response frame.

• PCP/AP 1 shall allocate a pseudo-static SP for the NP of PCP/AP 2 (i.e., BHI 2) on Channel 2 through an Extended Schedule element.

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Backward Compatibility of IEEE 802.11aj

[3] has described “Backward Compatibility Feature for 802.11aj”

•Legacy Mode Case 1: An IEEE 802.11ad device scans to find an available large band and starts its

network as normal 802.11ad device. Case 2: An IEEE 802.11ad device scans to find an IEEE802.11ad or IEEE 802.11aj

network operating in the large band and joins as a non-PCP/non-AP STA.

•Mixed Mode Support the backward compatibility for IEEE 802.11ad devices when IEEE 802.11aj

networks are operating in small bands.

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Mixed Mode (1/3)

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Case 1: Suppose that only PCP/AP 1 operates in Channel 5 while Channel 6 is empty.

• If an 802.11ad legacy device requests to join, 802.11aj PCP/AP 1 may change its channel to Channel 2 first, and then operate like 802.11ad PCP/AP and accept 802.11ad legacy device as non-PCP/AP STA

• PCP/AP 1 may also decide to operate in Channel 5 and allocate SPs or CBAPs to 802.11ad legacy device in Channel 2 through DMG Beacon or Announce frames as show in the following figure.

– To distinguish different channel bandwidths, we use the reserved Bit 5 of the Allocation Type field to indicate allocation type, which supports the backward compatibility to IEEE 802.11ad devices.

Bit 4 Bit 5 Bit 6 Meaning0 0 0 SP allocation in large band0 1 0 SP allocation in the small band1 0 0 CBAP allocation in large band1 1 0 CBAP allocation in small band

All other combinations Reserved

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Mixed Mode (2/3)

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Case 2 : Both Channel 5 and 6 are occupied by PCP/AP 1 and PCP/AP2, respectively.

Suppose that 11ad legacy STA A intends to join in PCP/AP 1’s network.

• PCP/AP 1’s allocations for STA A must abide by TWO conditions: 1) No overlaps with the existing allocations either in large band or in small bands.

2) PCP/AP 2 shall avoid to schedule the allocations time-overlapping with that of STA A.

• The mixed mode works as below: First, PCP/AP 1 shall hear the latest DMG Beacon or Announce frames or directly request PCP/AP

2 to reply with Extended Schedule elements . Second, PCP/AP 1 schedules the allocations for STA A and may notify the result to PCP/AP 2

through an Allocation Request frame. Third, PCP/AP 2 may reply with an Allocation Grant frame to grant this schedule or not. Lastly, PCP/AP 1 sends the schedule result to STA A (and PCP/AP 2) through Extended Scheduling

element transmitted in DMG Beacon or Announce frame.

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Mixed Mode (3/3)

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Case 3: Suppose that only PCP/AP 1 operates in Channel 5 and has scheduled the allocations for 802.11ad legacy devices within Channel 2.

• In this case, another PCP/AP 2 that intends to start up will know that Channel 6 is empty.

• PCP/AP 2 follows the same procedures in Slide 14 to establish its BSS in Channel 6.

• Since PCP/AP 2 has received the Extended Schedule element through the Beacon/Announce frames transmitted by PCP/AP 1, it will avoid to schedule its SPs or CBAPs that would overlap with the allocations for 802.11ad legacy devices in the following medium time.

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Case Study A: Support Dynamic Bandwidth

• Case A: Two PCP/APs operate in two adjacent small bands within the same large band.

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Case Study B: Support Dynamic Bandwidth

• Case B: Only one PCP/AP operates in a small band when the adjacent small band is unoccupied.

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Case Study C: Support Dynamic Bandwidth

• Case C: Only one PCP/AP operates in a large band when the large band is available.

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This is similar to 802.11ad

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Case Study D: Mixed Mode

• Case D: Only one PCP/AP operates in a small band when the adjacent small band is unoccupied.

• In this case, IEEE 802.11ad devices join as non-PCP/non-AP STAs.

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Case Study E: Mixed Mode

• Case E: Two PCP/APs operate in two adjacent small bands within the same large band.

• In this case, IEEE 802.11ad legacy devices join one of BSSs as non-PCP/non-AP STAs.

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Conclusion

• This presentation is part and in support of the complete proposal described IEEE 802.11-13-1301r0 (slides) and IEEE 802.11-13-1302r0 (text)

• This presentation proposed a channelization for China 60GHz frequency band for 802.11aj (60GHz)

• This presentation proposed a MAC protocol amendment to support dynamic bandwidth for 802.11aj (60GHz)

• The proposed MAC protocol supports the backward compatibility with 802.11ad legacy devices

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Reference

[1] 11-12-1197r0 - Physical Channel Consideration for Chinese 60GHz band

[2] 11-13-0176r0 - Proposal of Channelization for 802.11aj

[3] 11-13-0175r1 - Backward Compatibility Feature for 802.11aj

[4] 11-12-0140r9 - IEEE 802.11.aj PAR

[5] 11-12-0141r7 - IEEE 802.11.aj 5C

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Thank YOU

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