1. Basic TGad MAC Layer Proposals and Options for Coexistence
January 2010
doc.: IEEE xx/xxx1r0
Basic TGad MAC Layer Proposals and Options for Coexistence
Date:
Authors:
Name
Affiliations
Address
Phone
David Tung Chong Wong
Institute for Infocomm Research (I2R), A*STAR
1 Fusionopolis Way, #21-01 Connexis, Singapore
Xiaoming Peng
I2R, A*STAR
Same as above
Francois Chin
Xuhong Qu
Raymond Jararaj s/o Jayabal
David Wong, I2R

2. January 2010
doc.: IEEE xx/xxx1r0
Abstract
We propose two MAC layer beacon interval structures for Infrastructure BSS operations and IBSS operations.
We add options for coexistence between TGad network and another 60 GHz network.
Allow the TGad network to detect the other 60 GHz network.
Our scenario covers the case when both TGad network and another network are in operations and the other network move into the vicinity of the TGad network.
The other scenario which covers the case when the TGad network starts up in the vicinity of the other network is proposed in IEEE /1160r3.
David Wong, I2R

3. Infrastructure BSS AP Stations Sector 1 Sector 2 Sector 3 Sector n
January 2010
doc.: IEEE xx/xxx1r0
Infrastructure BSS AP
Stations
Sector 1
Sector 2
Sector 3
Sector n
AP with stations having n directions
David Wong, I2R

4. TGad MAC Layer Beacon Interval Structure 1
January 2010
doc.: IEEE xx/xxx1r0
TGad MAC Layer Beacon Interval Structure 1 …
Beacon interval n-1
Beacon interval n
Beacon interval n+1 …
Quasi-omni Beacon Period
Quasi-omni Beacon Period
Quasi-omni Beacon Period
Association CP
(A-CP)
Association CP
(A-CP)
Association CP
(A-CP)
CFP and regular sub-CP (RS-CP) in Direction #1
CFP and regular sub-CP (RS-CP) in Direction #1
CFP and regular sub-CP (RS-CP) in Direction #1 … …
CFP and regular sub-CP (RS-CP) in Direction #n
CFP and regular sub-CP (RS-CP) in Direction #n
Dir. #1 …
Dir. #n
A-CP for Dir. #1 …
A-CP for Dir. #n
CFP for Dir. #1
RS-CP for Dir. #1 …
CFP for Dir. #n
RS-CP for Dir. #n
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively
Association Sub-CPs
Broadcast and
multicast frames
Broadcast and
multicast frames
RS-CP for Dir. #1 – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #1 - using directional HCCA MAC …
RS-CP for Dir. #n – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #n - using directional HCCA MAC …
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
For Infrastructure BSS operation
David Wong, I2R

5. January 2010
doc.: IEEE xx/xxx1r0
BP/ A-CP / CFPs / RS-CPs
Quasi-omni Beacon Period
Association CP
(A-CP)
CFP and regular sub-CP (RS-CP) in Direction #1 …
CFP and regular sub-CP (RS-CP) in Direction #n
In the beacon, it is divided into three sections: quasi-omni beacon section, AP quasi-omni tracking section and sector training section.
The association contention period (A-CP) is used for devices to send association request commands to the AP.
The contention-free periods (CFPs) are used for broadcast or multicast packets.
The regular sub-contention periods (RS-CPs) are used for all other commands and data exchanges.
The CFPs and RS-CPs are divided according to the different directions.
David Wong, I2R

6. January 2010
doc.: IEEE xx/xxx1r0
CFP / RS-CPs BP
Dir. #1 … BP
Dir. #n
A-CP Dir. #1 …
A-CP Dir. #n
CFP for Dir. #1
RS-CP for Dir. #1 …
CFP for Dir. #n
RS-CP for Dir. #n
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively
Association Sub-CPs
Broadcast and
multicast frames
Broadcast and
multicast frames
RS-CP for Dir. #1 – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #1 - using directional HCCA MAC …
RS-CP for Dir. #n – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #n - using directional HCCA MAC …
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
For the CFPs after the A-CP, broadcast and multicast frames can be transmitted directionally.
For the RS-CPs, a directional CSMA/CA MAC enhanced distributed channel access (EDCA) can be used.
Can also have alternating RS-CPs and RS-Control Access Phase (CAP)s using directional EDCA MACs and a polling MAC like HCF controlled channel access (HCCA), respectively
David Wong, I2R

7. TGad MAC Layer Beacon Interval Structure 2
January 2010
doc.: IEEE xx/xxx1r0
TGad MAC Layer Beacon Interval Structure 2 …
Beacon interval n-1
Beacon interval n
Beacon interval n+1 …
Quasi-omni Beacon Period
Contention Period
(Any Directional CSMA/CA MAC)
Dir. #1 …
Dir. #n
For IBSS operation
*Any of the directional CSMA/CA MAC in IEEE /0796r0 can be used in the contention period.
David Wong, I2R

8. Options for Coexistence in Structure 1
January 2010
doc.: IEEE xx/xxx1r0
Options for Coexistence in Structure 1
Quasi-omni Beacon Period
CFP and regular sub-CP (RS-CP) in Direction #1
Association CP
(A-CP)
Beacon interval n
Beacon interval n+1
Beacon interval n-1 …
Dir. #1
Dir. #n
RS-CAP for Dir. #1 - using directional HCCA MAC
AS-CP for Dir. #1
AS-CP for Dir. #n
RS-CP for Dir. #1 – using directional CSMA/CA EDCA MAC
Association Sub-CPs
CFP and regular sub-CP (RS-CP) in Direction #n
RS-CP for Dir. #n – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #n - using directional HCCA MAC
RS-CP for Dir. #1
CFP for Dir. #1
CFP for Dir. #n
RS-CP for Dir. #n
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
Broadcast and
multicast frames
Can also have alternating RS-
CPs and RS-CAPs using directional
EDCA and HCCA MACs, respectively.
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively.
Station #1 sensingreport
Quasi-omni Quiet Period
Quasi-omni Reporting Period
Station #m sensingreport
Mini-slots for sensing reports by all stations in direction #1.
David Wong, I2R

9. Main Additions for Coexistence (1/3)
January 2010
doc.: IEEE xx/xxx1r0
Main Additions for Coexistence (1/3)
Quasi-omni Beacon Period
Quasi-omni Quiet Period
Quasi-omni Reporting Period
Association CP
(A-CP)
CFP and regular sub-CP (RS-CP) in Direction #1 …
CFP and regular sub-CP (RS-CP) in Direction #n
The main additions to the MAC layer beacon interval structure are the quasi-omni quiet period and the quasi-omni reporting period.
There are multiple sub-quiet periods within the Quiet Period in different directions. Each sub-quiet period is used by the AP or station to sense for the other 60GHz network in their particular direction out of the n possible directions.
Example of collaborative multi-direction sensing in the quiet period
David Wong, I2R

10. Main Additions for Coexistence (2/3)
January 2010
doc.: IEEE xx/xxx1r0
Main Additions for Coexistence (2/3)
Note that the initial direction of sensing by each station should be in such a way that all stations in that sector cover different directions.
This can be assigned to the station by the AP when it associates with the AP.
Another way is to use the station’s MAC address and compute it, that is, (MAC address MOD n).
Thus, the AP and the stations are sensing collaboratively in multiple directions as whole during the quiet period.
There are also multiple mini-slots in the different directions for the stations to report their sensing outcomes.
David Wong, I2R

11. Main Additions for Coexistence (3/3)
January 2010
doc.: IEEE xx/xxx1r0
Main Additions for Coexistence (3/3)
The mini-slots in different direction can be dynamically assigned to stations by the AP when the stations associate with the AP in the A-CP and indicated in a new field in the quasi-omni beacon period in that direction.
The particular mini-slot for a station will be removed when the station disassociates from the AP.
The AP decides if the other 60 GHz network is present or not, based on the data fusion rules like OR-fusion rule, AND-fusion rule or Majority fusion rule.
David Wong, I2R

12. Alternate Option for Coexistence in Structure 1
January 2010
doc.: IEEE xx/xxx1r0
Alternate Option for Coexistence in Structure 1 …
Beacon interval n-1
Beacon interval n
Beacon interval n+1 …
Quasi-omni Beacon Period
Quasi-omni Quiet Period
Association CP
(A-CP)
CFP and regular sub-CP (RS-CP) in Direction #1 …
CFP and regular sub-CP (RS-CP) in Direction #n
Dir. #1 …
Dir. #n
Dir. #1 …
Dir. #n
AS-CP for Dir. #1 …
AS-CP for Dir. #n
CFP for Dir. #1
RS-CP for Dir. #1 …
CFP for Dir. #n
RS-CP for Dir. #n
Association Sub-CPs
Can also have alternating RS-
CPs and RS-CAPs using directional
EDCA and HCCA MACs, respectively.
Can also have alternating RS-CPs and RS-CAPs using directional EDCA and HCCA MACs, respectively.
Broadcast and
multicast frames
Broadcast and
multicast frames
RS-CP for Dir. #1 – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #1 - using directional HCCA MAC …
RS-CP for Dir. #n – using directional CSMA/CA EDCA MAC
RS-CAP for Dir. #n - using directional HCCA MAC …
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
Regular sub-CP(s) with EDCA-TXOPs and
Regular sub-CAP(s) with HCCA-TXOPs
David Wong, I2R

13. Main Additions in the Alternate Option
January 2010
doc.: IEEE xx/xxx1r0
Main Additions in the Alternate Option
The only addition to the MAC layer beacon interval structure is the quasi-omni quiet period.
There are multiple sub-quiet periods in the different directions for the AP and stations to sense for the other 60 GHz network as before.
However, the stations can report their sensing outcomes to the AP through directional EDCA MAC using CSMA/CA or through directional HCCA MAC in the RS-CAPs for different directions.
The AP then decides if the other 60 GHz network is present or not, based on the data fusion rules.
David Wong, I2R

14. Options for Coexistence in Structure 2
January 2010
doc.: IEEE xx/xxx1r0
Options for Coexistence in Structure 2 …
Beacon interval n-1
Beacon interval n
Beacon interval n+1 …
Quasi-omni Beacon Period
Quasi-omni Quiet Period
Quasi-omni Reporting Period
Contention Period
(Any Directional CSMA/CA MAC)
Dir. #1 …
Dir. #n
Dir. #1 …
Dir. #n
Dir. #1 …
Dir. #n
This option is similar to the coexistence in MAC structure 1, except that the association and setting up of the mini-slot for sensing reporting is done in the contention period using any directional CSMA/CA MAC as in IEEE /0796r0.
Station #1 sensingreport …
Station #m sensingreport
Mini-slots for sensing reports by all stations in direction #1.
David Wong, I2R

15. Alternate Option for Coexistence in Structure 2
January 2010
doc.: IEEE xx/xxx1r0
Alternate Option for Coexistence in Structure 2 …
Beacon interval n-1
Beacon interval n
Beacon interval n+1 …
Quasi-omni Beacon Period
Quasi-omni Quiet Period
Contention Period
(Any Directional CSMA/CA MAC)
Dir. #1 …
Dir. #n
Dir. #1 …
Dir. #n
Similarly, this option is similar to the alternate option for coexistence in MAC structure 1, except that data communication and sensing report by the stations to the AP or the station that sends out the beacon target transmission time (TBTT) are done in the contention period using any directional CSMA/CA MAC as in IEEE /0796r0.
David Wong, I2R

16. January 2010
doc.: IEEE xx/xxx1r0
Summary
We propose two MAC layer beacon interval structures for Infrastructure BSS operations and IBSS operations.
We add options for coexistence with another 60 GHz network by detecting it.
The TGad network could then move to another band.
The options for coexistence cater for the case when the TGad network and another 60 GHz network, both in operations, come into contact.
These coexistence options can be used in every beacon interval, or once in a number of beacon intervals.
David Wong, I2R

17. January 2010
doc.: IEEE xx/xxx1r0
References
ad-proposed-evaluation methodology-additions
contention-based directional MAC protocols: a survey
IEEE Std c™-2009
ECMA-387
David Wong, I2R

18. January 2010
doc.: IEEE xx/xxx1r0
Straw Poll
Do you think an optional feature that includes quiet period and reporting period for coexistence is worth further investigation within TGad? Y: N: A:
Slide 18
Slide 18
Page 18
David Wong, I2R