doc.: IEEE 802.11-15/1145r0

Submission

September 2015

Intel Corpor

ation

Slide 1

SU-MIMO Configurations for IEEE 802.11ay

Date: 2015-09-14

Authors:Name Affiliations Address Phone email

Alexander Maltsev Intel Turgeneva 30, Nizhny Novgorod, 603024, Russia

+7 (831) 2969444 alexander.maltsev@intel.com

Artyom Lomayev Intel artyom.lomayev@intel.com

Yaroslav Gagiev Intel yaroslav.p.gagiev@intel.com

Miki Genossar Intel miki.genossar@intel.com

Carlos Cordeiro Intel carlos.cordeiro@intel.com

doc.: IEEE 802.11-15/1145r0

Submission

September 2015

Intel Corpor

ation

Slide 2

Abstract

• This presentation describes SU-MIMO configurations proposed to be included in IEEE 802.11ay standard.

• These configurations exploit spatial and polarization diversity channel properties and allow system operation in LOS and NLOS conditions.

• The considered configurations should be supported by appropriate channel models and facilitate evaluation methodology development.

doc.: IEEE 802.11-15/1145r0

Submission

Single Array MIMO with Single Polarization

• Single array MIMO uses single Phased Antenna Array (PAA) of M x N rectangular geometry. All PAA elements have identical linear polarization of type H (horizontal) or V (vertical).

• Each PAA element is fed with a superposition of weighted (or phase shifted) signals pertained to different streams to create a desired resulting antenna pattern.

• This scheme exploits spatial channel diversity property and separates the streams in space domain maximizing the received power (finding strong reflector) and minimizing the impact of each stream on others (interference suppression).

• Figures at the left show an example of PAA of size 4 x 8 and supply chain for each PAA element in case of 2 transmit MIMO streams.

• This scheme can potentially work in NLOS environment, however in LOS environment two streams will be spatially correlated, therefore poor MIMO performance is expected.

September 2015

Intel Corpor

ation

Slide 3

Each element has single polarization

E

V pol

E

H pol

or

PAA elementSignal 1st stream

Signal 2nd stream

Phase shifter

doc.: IEEE 802.11-15/1145r0

Submission

Single Array MIMO with Dual Polarization

• Single array MIMO with dual polarization uses single PAA of rectangular geometry of size M x N.

• Each PAA element has dual linear polarization H (horizontal) and V (vertical).

• This scheme exploits polarization diversity property and can assign two streams to different H and V polarizations.

• Figures at the left show an example of PAA of size 4 x 8 and supply chain for each PAA element in case of 2 transmit MIMO streams.

• This scheme can potentially work in LOS and NLOS environments. The beamforming algorithm in NLOS can use single reflection (one spatial direction) for both streams or two strong reflections (two spatial directions). It can be selected by phase shifters.

September 2015

Intel Corpor

ation

Slide 4

Each element has dual polarization

E

V and H pol

PAA elementSignal 1st stream

Signal 2nd stream

Phase shifter V pol

H pol

doc.: IEEE 802.11-15/1145r0

Submission

Multi-Array MIMO

• Multi-array MIMO uses K physically independent PAAs with single or dual polarization type.

• Figure at the left shows an example of 2 PAAs separated by the distance d.

• The PAA #1 and PAA #2 arrays can use elements with single or dual polarization as considered at the previous slides.

• In case of dual polarization arrays this system can implement 4 x 4 MIMO scheme with 4 spatial streams.

• This scheme can work in LOS and NLOS environments. The possibility to use 4 x 4 MIMO scheme in LOS environment depends on the PAAs separation d, antenna arrays size, and the distance between TX and RX, [1].

• Each PAA can do independent beamforming search or cooperative search to find the best channel realization.

September 2015

Intel Corpor

ation

Slide 5

Distance between array centers - d

PAA #1

PAA #2

Each element can have single (H or V) polarization

Each element can have dual (H and V) polarization

doc.: IEEE 802.11-15/1145r0

Submission

SU-MIMO Configurations

• Configuration #1: single array, single polarization, 2 streams

September 2015

Intel Corpor

ation

Slide 6

PAA elementSignal 1st stream

Signal 2nd stream

Phase shifter

Beam #1

H or V polH or V pol

Device #1 Device #2

Beam #2

Each element has single polarization

E

V pol

E

H pol

or

Device 1 and device 2 have the same configuration: Examples of beamformed links:

Beam #1

H or V polH or V pol

Device #1 Device #2

Beam #2

doc.: IEEE 802.11-15/1145r0

Submission

SU-MIMO Configurations (Cont’d)

September 2015

Intel Corpor

ation

Slide 7

• Configuration #2: single array, dual polarization, 2 streams

PAA elementSignal 1st stream

Signal 2nd stream

Phase shifter V pol

H pol

H and V polH and V pol

Device #1 Device #2

H

V

H and V polH and V pol

Device #1 Device #2H

V

Beam #1

Beam #2

H and V polH and V pol

Device #1 Device #2H

V

H and V polH and V pol

Device #1 Device #2H

V

Beam #1

Beam #2

Each element has dual polarization

E

V and H pol

Device 1and device 2 have the same configuration: Examples of beamformed links:

doc.: IEEE 802.11-15/1145r0

Submission

SU-MIMO Configurations (Cont’d)

September 2015

Intel Corpor

ation

Slide 8

• Configuration #3: dual array, single polarization, 2 streams

d2d1

Device #1 Device #2

H or V polH or V pol

d2d1

Device #1 Device #2

H or V polH or V pol

d2d1

Device #1 Device #2

H or V polH or V pol

d2d1

Device #1 Device #2

H or V polH or V pol

Distance between array centers - d

PAA #1

PAA #2

E

V pol

E

H pol

or

PAA elementSignal 1st stream

Phase shifter

PAA elementSignal 2nd stream

Phase shifter

E

V pol

E

H pol

or

Device 1 and device 2 have the same configuration: Examples of beamformed links:

doc.: IEEE 802.11-15/1145r0

Submission

SU-MIMO Configurations (Cont’d)

September 2015

Intel Corpor

ation

Slide 9

• Configuration #4: dual array, dual polarization, 4 streams

d2d1

Device #1 Device #2

H and V polH and V pol

H

V

H

V

d2d1

Device #1 Device #2

H and V polH and V pol

H

V

H

V

Distance between array centers - d

PAA #1

PAA #2

PAA elementSignal 1st stream

Signal 2nd stream

Phase shifter V pol

H pol

PAA elementSignal 3rd stream

Signal 4th stream

Phase shifter V pol

H pol

H and V pol

H and V pold2d1

Device #1 Device #2

H and V polH and V pol

Device 1 and device 2 have the same configuration: Examples of beamformed links:

d2d1

Device #1 Device #2

H and V polH and V pol

H

V

HV

doc.: IEEE 802.11-15/1145r0

Submission

SU-MIMO Configurations (Cont’d)

September 2015

Intel Corpor

ation

Slide 10

• Configuration #5: single array, single to dual polarization, 1 streamDevice 1 configuration:

Examples of beamformed links:

Device 2 configuration:

PAA #1

E

V pol

E

H pol

orPAA element

Signal 1st stream

Phase shifter

H and V polH or V pol

Device #1 Device #2

H and V polH or V pol

Device #1 Device #2

PAA #1

PAA elementSignal 1st stream

Signal 1st stream

Phase shifter V pol

H pol

H and V pol

doc.: IEEE 802.11-15/1145r0

Submission

Summary of SU-MIMO Configurations

• Table below summarizes the SU-MIMO configurations. PAA has rectangular geometry of M x N and distance between arrays d1, d2. M, N, and d1, d2 are parameters.

September 2015

Intel Corpor

ation

Slide 11

# Number of data

streams

MIMO configuration

Number of PAAs

(Device 1, Device 2)

Polarization type

(Device 1, Device 2)

PAAs separation (Device 1, Device 2)

Number of RF parts per PAA

(Device 1, Device 2)

LOS NLOS Mandatory / Optional*

1 2 2 x 2 (1, 1) (Single, single) (0, 0) (2, 2) No Yes Optional

2 2 2 x 2 (1, 1) (Dual, dual) (0, 0) (2, 2) Yes Yes Mandatory

3 2 2 x 2 (2, 2) (Single, single) (d1, d2) (1, 1) Yes Yes Mandatory

4 4 4 x 4 (2, 2) (Dual, dual) (d1, d2) (2, 2) Yes Yes Optional

5 1 1 x 2 (1, 2) (Single, dual) (0, 0) (1, 2) Yes Yes Mandatory

• *Mandatory / optional classification is applied in relation to the channel modeling.

doc.: IEEE 802.11-15/1145r0

Submission

MIMO Modes Evaluation

• In accordance with contribution IEEE doc. 11-14/0606r0 (ref. [2]), different MIMO techniques can be evaluated for the proposed MIMO configurations, including:– Maximum Ratio Combining (MRC) robust transmission– Open-Loop (OL) MIMO/STBC, optimal selection from:

• OL MIMO (two streams, double rate)• Alamouti space-time coding scheme

– Closed-Loop (CL) MIMO:• SVD fine subcarrier-wise beamforming

• The evaluation of these techniques should be done in reliable channel models that will be developed for the proposed MIMO configurations and approved use cases.

September 2015

Intel Corpor

ation

Slide 12

doc.: IEEE 802.11-15/1145r0

Submission

Conclusions

• This work proposes SU-MIMO configurations to be used to support channel models, evaluation methodology, and standard development in IEEE 802.11ay group.

• It is proposed to consider MIMO schemes utilizing one or two Phased Antenna Arrays (PAAs) with rectangular geometry. Each element of the PAA can have single linear (H or V) polarization or dual (H and V) polarization.

• The considered schemes exploit spatial and polarization diversity channel properties and allow system operation in LOS and NLOS conditions.

• The maximum SU-MIMO configuration is limited to 4 x 4 scheme and supports 4 streams.

September 2015

Intel Corpor

ation

Slide 13

doc.: IEEE 802.11-15/1145r0

Submission

September 2015

Intel Corpor

ation

Slide 14

References

1. A. Maltsev, et al, “Experimental Measurements for Short Range LOS SU-MIMO,” IEEE doc. 11-15/0632r1.

2. C. Cordeiro, et al, “Next Generation 802.11ad:30+ Gbps WLAN,” IEEE doc. 11-14/0606r0.

3. Rob Sun, et al, “IEEE 802.11 TGay Use Cases,” IEEE doc. 11-15/0625r2.