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doc.: IEEE 802.11-10/0432r2
Submission
May 2010
Slide 1
PHY/MAC Complete Proposal to TGadDate: 2010-05-18
Author(s)/Supporter(s):
Name Company Address Phone email
Abu-Surra, Shadi Samsung [email protected]
Ban, Koichiro Toshiba [email protected]
Banerjea, Raja Marvell [email protected]
Basson, Gal Wilocity [email protected]
Blanksby, Andrew Broadcom [email protected]
Borges, Daniel Apple [email protected]
Borison, David Ralink [email protected]
Cariou, Laurent Orange [email protected]
Chamberlin, Philippe Technicolor R&I [email protected]
Chang, Kapseok ETRI [email protected]
Chin, Francois I2R [email protected]
Choi, Changsoon IHP GmbH [email protected]
Christin, Philippe Orange [email protected]
Chu, Liwen STMicroelectronics [email protected]
Chung, Hyun Kyu ETRI [email protected]
Coffey, Sean Realtek [email protected]
Cordeiro, Carlos Intel [email protected]
Derham, Thomas Orange [email protected]
Dorsey, John Apple [email protected]
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
May 2010
Slide 2
Author(s)/Supporter(s):Name Company Address Phone email
Elboim, Yaron Wilocity [email protected], Matthew Broadcom [email protected], Claude NXP [email protected], Ron Peraso Technologies [email protected]
Golan, Ziv Wilocity [email protected], Michelle Intel [email protected]
Grandhi, Sudheer InterDigital [email protected], Eckhard IHP GmbH [email protected], David Agilent [email protected]
Grodzinsky, Mark Wilocity [email protected], Christopher Broadcom [email protected]
Hart, Brian Cisco [email protected], Amer Microsoft [email protected]
Hong, Seung Eun ETRI [email protected], Kenichi NEC [email protected], Srinath Texas Instruments [email protected]
Hsu, Alvin MediaTek [email protected], Julan Samsung [email protected]
Hung, Kun-Chien MediaTek [email protected], Avinash Qualcomm [email protected]
Jauh, Alan MediaTek [email protected], Raymond Jararaj s/o I2R [email protected]
Jeon, Paul LGE [email protected], Sunggeun ETRI [email protected]
Jones, VK Qualcomm [email protected], Stacy Beam Networks [email protected]
Jun, Haeyoung Samsung [email protected], Harald Nokia [email protected], Padam Nokia [email protected]
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
Author(s)/Supporter(s):Name Company Address Phone email
Kakani, Naveen Nokia [email protected], Assaf Intel [email protected], Mika Nokia [email protected], Hodong Samsung [email protected], Yongsun ETRI [email protected], Rolf IHP GmbH [email protected], Rick Harman International [email protected], Edwin Samsung [email protected]
Kwon, Hyoungjin ETRI [email protected], Hyukchoon Samsung [email protected]
Laine, Tuomas Nokia [email protected], Ismail Tensorcom [email protected], Hoosung ETRI [email protected]
Lee, Keith AMD [email protected], Wooyong ETRI [email protected]
Liu, Yong Marvell [email protected], Hui-Ling Marvell [email protected], Brad Peraso Technologies [email protected]
Majkowski, Jakub Nokia [email protected], Janne Nokia [email protected]
Maruhashi, Kenichi NEC [email protected], Taisuke Panasonic [email protected]
Meerson, Yury Wilocity [email protected], Murat Broadcom [email protected]
Montag, Bruce Dell [email protected], Andrew Cisco [email protected]
Nandagopalan, Saishankar Broadcom [email protected], Chiu Samsung [email protected]
Nikula, Eero Nokia [email protected]
Slide 3
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
Author(s)/Supporter(s):Name Company Address Phone email
Park, DS Samsung [email protected], Minyoung Intel [email protected], Xiaoming I2R [email protected]
Pi, Zhouyue Samsung [email protected], Vish MediaTek [email protected]
Prasad, Narayan NEC [email protected], Gideon Intel [email protected], Xuhong I2R [email protected]
Ramachandran, Kishore NEC [email protected], Yu Zhan Panasonic [email protected]
Roblot, Sandrine Orange [email protected], Roee Wilocity [email protected], Ohad Wilocity [email protected]
Sachdev, Devang NVIDIA [email protected], Ali Intel [email protected]
Sampath, Hemanth Qualcomm [email protected], Amichai Wilocity [email protected]
Sankaran, Sundar Atheros [email protected], Vincenzo STMicroelectronics [email protected]
Seok, Yongho LGE [email protected], Huai-Rong Samsung [email protected], Ba-Zhong Broadcom [email protected]
Sim, Michael Panasonic [email protected], Harkirat Samsung [email protected], Menashe Intel [email protected], Seungho SK Telecom [email protected]
Slide 4
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
Author(s)/Supporter(s):Name Company Address Phone email
Sorin, Simha Wilocity [email protected], Matt Atheros [email protected]
Stacey, Robert Intel [email protected], Ananth I2R [email protected]
Sutskover, Ilan Intel [email protected], Hossain Qualcomm [email protected]
Takahashi, Kazuaki Panasonic [email protected], Ichihiko NTT [email protected]
Trachewsky, Jason Self [email protected], Solomon Intel [email protected]
Usuki, Naoshi Panasonic [email protected], Prabodh Nokia [email protected]
Vertenten, Bart NXP [email protected], George STMicroelectronics [email protected]
Wang, Chao-Chun MediaTek [email protected], Homber TMC [email protected], James MediaTek [email protected]
Wong, David Tung Chong I2R [email protected], James MediaTek [email protected]
Yucek, Tevfik Atheros [email protected], Su Khiong Marvell [email protected], Hongyuan Marvell [email protected]
Slide 5
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
Proposal overview
• This presentation is part and in support of the complete proposal described in 802.11-10/432r2 (slides) and 802.11-10/433r2 (text) that:– Supports data transmission rates up to 7 Gbps
– Supplements and extends the 802.11 MAC and is backward compatible with the IEEE 802.11 standard
– Enables both the low power and the high performance devices, guaranteeing interoperability and communication at gigabit rates
– Supports beamforming, enabling robust communication at distances beyond 10 meters
– Supports GCMP security and advanced power management
– Supports coexistence with other 60GHz systems
– Supports fast session transfer among 2.4GHz, 5GHz and 60GHz
May 2010
Slide 6 Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
doc.: IEEE 802.11-10/0432r2
Submission
Proposal presentation plan
ID Item Type Subclauses from 802.11-
10/433r2Doc#
1 Complete proposal overviewComplete
proposal (CP) High-level proposal
overviewSlides: 802.11-10/0432r2Text: 802.11-10/0433r2
2 MAC (Channel Access & QoS)New Technique
(NT)7, 9.1-9.23, 9.26-9.27,
11.3-11.7802.11-10/0441
3 MAC (SFS & BSS mngmt) NT 7, 9.24, 11.22-11.29, 11.31-11.33, 11.35
802.11-10/0443
4 MAC (Sync & power saving) NT 7, 11.1, 11.2 802.11-10/0446
5 MAC (Link maintenance) NT 7, 11.8, 11.9, 11.10, 11.30 802.11-10/0445
6 Security NT 8 802.11-10/0438
7 FST NT 11.34 802.11-10/0436
8 PHY (Intro./SC) NT All in 21, except 21.3.6,
21.5, 21.7 802.11-10/0429
9 PHY (OFDM) NT 21.5 802.11-10/0440
10 PHY (CP) NT 21.3.6 802.11-10/0439
11 BF (SLS) NT All in 9.25 except 9.25.2, 9.25.5.3, 9.25.5.4, 9.25.6
802.11-10/0430
12 BF (BRP) NT 9.25.2, 9.25.5.3, 9.25.5.4,
9.25.6, 21.7 802.11-10/0450
13 Relay operation NT 11.37 802.11-10/0494
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 7
Thispresentation
doc.: IEEE 802.11-10/0432r2
Submission
• To meet the TGad PAR, FRD, EVM and selection procedure requirements, the following additional supporting documents complement this proposal
• Therefore, this proposal meets all the requirements in the TGad selection procedure to be classified as a complete proposal
Additional proposal supporting documents
ID Item Doc#20 PAR, FRD and EVM declaration 802.11-10/0434
21MAC simulation results and
methodology802.11-10/0435
22PHY simulation results and
methodology802.11-10/0431
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 8
doc.: IEEE 802.11-10/0432r2
Submission
Item This complete proposal Subclause of 802.11-10/433r2
Network architecture Infra-BSS, IBSS, PBSS 5.2
Scheduled access Scheduled Service Periods 9.23.6
Contention access EDCA tuned for directional access 9.2
Dynamic allocation of resources
(Re-)allocation of channel time with support to P2P and directionality
9.23.7, 9.23.8, 9.23.9
Power save Non-AP STA and PCP power save 11.2.3
Security mechanism GCMP 8
Measurements Amendments to 802.11k to support directionality
11.33
PHY SC and OFDM, with common preamble 21
Beamforming Unified and flexible beamforming scheme 9.25
Fast session transfer Multi-band operation across 2.4GHz, 5GHz and 60GHz
11.34
Coexistence Provides coexistence with other 60GHz systems 11.35
Notable amendments to IEEE 802.11
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 9
doc.: IEEE 802.11-10/0432r2
Submission
MAC/PHY proposal overview
• Provides an unified and interoperable MAC/PHY across all mmWave implementations– Scalable across different usages, devices, and platforms– Adjustable to meet different power vs. performance trade-offs
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
Point Coordination
Function (PCF)
HCF Contention
Access (EDCA)
HCF Controlled
Access (HCCA)
Distributed Coordination Function (DCF)
FHSS, IR, DSSS, OFDM, HR/DSSS, ERP, or HT PHY
mmWave Channel Access
mmWave PHY
MACextent
AT Access
Contention-based Access
Service Period Access
A-BFT Access
Polled Access
Protocol architecture
2.4/5GHz 60GHzSlide 10
doc.: IEEE 802.11-10/0432r2
Submission
MAC
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 11
doc.: IEEE 802.11-10/0432r2
Submission
MAC challenges
• As discussed in 802.11-09/572r0, the primary challenge for the MAC is how to deal with directional communication, which is used to combat the high propagation loss in 60GHz– Device discovery becomes a non-trivial problem
– Devices need to find the direction for communication, which necessitates the support for beamforming (802.11-09/1153r2)
– 802.11 DCF has limitations in the presence of directionality
– How to exploit spatial frequency reuse in face of directional communication (802.11-09/782r0)
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 12
doc.: IEEE 802.11-10/0432r2
Submission
New MAC features(described in detail in separate presentations)
• A new network architecture named Personal Basic Service Set (PBSS), while retaining the existent 802.11 network architectures
• Channel access that support directionality and spatial frequency reuse, including both random access and scheduled access
• A unified and flexible beamforming scheme that can be tuned to simple, low power devices as well as complex devices
• Enhanced security (GCMP), link adaptation and power saving
• Multi-band support (fast session transfer)
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 13
doc.: IEEE 802.11-10/0432r2
Submission
The Personal BSS (PBSS)
• New network architecture in addition to infrastructure BSS and IBSS, which are also supported• PBSS is defined to address some unique usages and challenges of 60GHz communication
– Usages: Rapid sync-n-go file transfer, projection to TV/projector, etc.– Challenges: directional channel access, power saving, etc.– More details in 802.11-09/391r0
• Ad hoc network similar to the IBSS, but:
• A STA assumes the role of the PBSS Central Point (PCP)
• Only the PCP transmits beacon frames
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 14
802.11 MAC/PHY
802.11 Personal BSS
STA 1/PCP STA 2
doc.: IEEE 802.11-10/0432r2
Submission
The Beacon Interval (BI) structure
• Beacon time (BT): An access period during which one or more mmWave Beacon frames is transmitted
• Association beamforming training (A-BFT): An access period during which beamforming training is performed with a PCP or AP
• Announcement time (AT): A request-response based management access period during which a PCP or AP delivers non-MSDUs and provides access opportunities for STAs to return non-MSDUs
• Data transfer time (DTT): An access period during which frame exchanges are performed between STAs. The DTT is comprised of contention-based periods (CBPs) and service periods (SPs)
BI
Time
BT ATA-BFT
DTT
CBP 1 SP 1 SP 2 CBP 2
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 15
doc.: IEEE 802.11-10/0432r2
Submission
Channel access
• Channel access is coordinated using a schedule, which is delivered by the PCP/AP to non-PCP/non-AP STAs
• STAs are permitted to transmit data frames during contention-based periods (CBPs) and service periods (SPs)– Access during CBPs is based on EDCA fine-tuned for directional
access– Access during SPs is reserved to specific STAs as announced in
the schedule or granted by the PCP/AP
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 16
doc.: IEEE 802.11-10/0432r2
Submission
Fast session transfer (FST) support through multi-band operation
• Enables transition of communication of STAs from any band/channel to any other band/channel in which 802.11 is allowed to operate
• Supports both simultaneous and non-simultaneous operation• Supports both transparent and non-transparent FST
• In transparent FST, a STA uses the MAC same address in both bands/channels involved in the FST• In non-transparent FST, the MAC addresses are different
• Several improvements to speed-up the FST switching time such as transparent FST, security key establishment prior to FST, TS operation over multiple bands, and Block Ack operation over multiple bands
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 17
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
Beamforming (BF)
• A unified and flexible BF protocol is proposed that can be tuned to simple, low power devices as well as complex devices• Same protocol is used for PCP/AP-to-STA beamforming and
STA-to-STA beamforming
• BF comprised of two independent phases: sector level sweep (SLS) phase and beam refinement protocol (BRP) phase• SLS: enables communication at the control PHY rate (MCS0), and
typically only provides transmit training• BRP: enables receiver training and iterative refinement of the
AWV of both transmitter and receiver
• Support for beam tracking during data communication
Slide 18 Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
BF training examples
• Two phased arrays
• Two transmit sector sweeps followed by a beam refinement
• During a transmit sector sweep, the receiver may be using a quasi-omni receive pattern
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
• Initiator has a phased array, responder has a single antenna
• During the receive sector sweep, the responder transmit a sector sweep many times from its single antenna. The initiator switches receive pattern every packet.
Slide 19
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
Coexistence with other 60GHz systems• Proposal enables fair sharing of resources with 15.3c• The same channelization as other 60GHz systems is used, and the same SC chip rate as that
of 15.3c CMS is adopted• As required in the TGad EVM (802.11-09/296r16), an AP should not start a BSS where the
signal level is above a threshold or upon detecting a 15.3c CMS preamble at >= -60 dBm– In 802.11a/n, MCS 0 (BPSK, R=1/2) receive sensitivity is -82dBm and non-802.11 detection level is -62
dBm → 20 dB difference– In 60GHz, SC MCS 1 receive sensitivity is -68 dBm → 8 dB difference with respect to required 802.15.3c
CMS preamble detection threshold– Requirement of detection of 802.15.3c CMS preamble is 12dB more stringent than 802.11a/n and non-
802.11 detection!
• STAs can perform channel measurements and report results to AP/PCP• Several mechanisms can be used to mitigate interference with other 60GHz systems,
including:– Change operating channel, beamforming, reduce transmit power, move the BT (and thus the BI) in case of
an AP or PCP, change or request the change of scheduled SPs and CBPs in the BI, defer transmission for a later time
Slide 20 Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
PHY
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 21
doc.: IEEE 802.11-10/0432r2
Submission
Agenda• Channelization• PHY Overview
– PHY general parameters
• Common Preamble Preview– Golay sequences– Preamble structure
• Short preamble• CEF
• Coding scheme-LDPC• Single Carrier modulation
– Control MCS– Single carrier MCS set– Single carrier low power mode
• OFDM modulation• RF General parameters
Slide 22 Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
Channelization
Channel separation 2160MHzSame channelization as 15.3c, compatible Mask Requirement for coexistence
Channel ID
Center Freq.(GHz)
Channel width(GHz)
OFDM Sampling Rate (MHz)
SC Chip Rate (MHz)
1 58.32 2.16 2640 1760
2 60.48 2.16 2640 1760
3 62.64 2.16 2640 1760
4 64.80 2.16 2640 1760
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 23
doc.: IEEE 802.11-10/0432r2
Submission
PHY Overview
• Unified and interoperable PHY
– Common preamble
– Common MCS
– Common coding
• Different MCS sets for different usages: OFDM and SC
– OFDM MCSs for high performance on frequency selective channels up to 64 QAM
– SC modulation for low power/low complexity transceivers • SC MCS for control signaling (Channel, SNR durability)
• SC Low Power MCS set– Simpler coding and shorter symbol structure to enable low power
implementation
• Embedded support in BF
• Different presentation (802.11-10/0430r0, 802.11-10/0450r0)
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 24
doc.: IEEE 802.11-10/0432r2
Submission
PHY Parameters
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 25
doc.: IEEE 802.11-10/0432r2
Submission
PHY General parameters• Sampling rate
• SC PHY MCS set Symbol Rate = 1760MHz
• OFDM MCS set Sampling Rate = 2640 MHz• Sampling Rate is Exactly 1.5x the SC symbol rate
• SC block – 512 symbols of which 64 chips GI
• OFDM nominal sample rate 2640MHz = 1.5 times SC symbol rate• 512 samples FFT
• 128 samples GI
• 336 data subcarriers
• 16 pilot subcarriers
• Common Packet Structure
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 26
doc.: IEEE 802.11-10/0432r2
Submission
Common Preambles
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 27
doc.: IEEE 802.11-10/0432r2
Submission
Complementary sequences
• Time domain channel estimation
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 28
0 100 200 300 400 500 600 700-50
0
50
100
150Ra
0 100 200 300 400 500 600 700-50
0
50
100
150Rb
0 100 200 300 400 500 600
0
50
100
150
200
250
Ra+Rb= delta(t)
a H a*h Golay Correlator
Ra=a*a*h
b H b*h Golay Correlator
Rb=b*b*h
∑
( ) ( )a a h b b h a a b b h k h h
0
0
1 1
1 1
( ) ( )
( ) ( )
( ) ( ) ( )
( ) ( ) ( )n n n n n
n n n n n
a i i
b i i
a i W a i b i S
b i W a i b i S
1SZ
1W
+
-
1a
1b
2SZ
2W
+
-2b
1NSZ
1NW
+
-
1Na 2a
1Nb
( )k
0 1 12 , 2 ,..., 2
1, 1
N
i
S permutation of
W
1*
0
1*
0
1 0( ) ( ) ( )
0
( ) ( ) ( )
( ) ( ) ( )
a b
N k
an
N k
bn
for kR k R k k
else
R k a n a n k
R k b n b n k
doc.: IEEE 802.11-10/0432r2
Submission
Short Preambles
• Complementary sequences are used to differentiate control MCS and high rate MCSs– 38 repetition for CP
– 14 repetition for SC/OFDM
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 29
CP:
Gb128 Gb128
STF=38xGb128, -Gb, -Ga CEF
… -Gb128
High rate:
Ga128 Ga128
STF=14xGa128,-Ga CEF
… -Gb128
-Gb128 -Ga128
-Ga128
doc.: IEEE 802.11-10/0432r2
Submission
Common Preamble
• Transmitted using π/2-BPSK at SC symbol rate
• Short Training field composed of 15 repetitions of a 128 samples Golay sequence
• Channel Estimation based on 512 points complementary sequences followed by a guard interval
Ga128 Ga128 Ga128 Ga128 Ga128 Ga128 Ga128 -Ga128 Gu512 Gv512
Short Training Field (STF) 1920 Tc Channel Estimation Field (CEF) 1152 Tc
Gv128
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 30
doc.: IEEE 802.11-10/0432r2
Submission
SC/OFDM Channel Estimation Sequence
• The use of SC/OFDM MCS set is signaled using the CEF pattern as shown below
SC:
Ga128 -Ga128
STF CEF
u512 v512
… -Ga128 Gb128 -Ga128-Gb128 Ga128 -Gb128 -Gb128-Ga128-Gb128
v128
OFDM:
STF CEF
v512 u512
… -Gb128
v128
-Ga128Ga128 Ga128 -Gb128 -Ga128-Gb128 -Ga128 Gb128 -Ga128-Gb128
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 31
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Coding
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 32
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Code Set Overview
• Four codes of common codeword length of 672
• Cyclic shifted identity (CSI) construction
• Submatrix size 42
• Excellent coding gain on realistic channels
• Construction supports high throughput implementation
• Single construction supports code rates of 1/2, 5/8, 3/4, and 13/16
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 33
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Code Set Implementation
• Low complexity / low latency encoding– Shared terms in systematic product calculation across all codes
– Back substitution for parity calculation
• High throughput / low power decoding– Layer decoding
• Each code matrix H has 4 layers with a single set element per column
• 4 clock cycles per decoder iteration
– Fully parallel belief propagation decoding• Code set super-position matrix has single CSI value per location which
minimizes decoder multiplexing and routing
• 1 clock cycle per decoder iteration
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 34
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Matrices40 38 13 5 18
34 35 27 30 2 1
36 31 7 34 10 41
27 18 12 20 15 6
35 41 40 39 28 3 28
29 0 22 4 28 27 23
31 23 21 20 12 0 13
22 34 31 14 4 13 22 24
20 36 34 31 20 7 41 34 10 41
30 27 18 12 20 14 2 25 15 6
35 41 40 39 28 3 28
29 0 22 4 28 27 24 23
31 23 21 20 9 12 0 13
22 34 31 14 4 22 24
35 19 41 22 40 41 39 6 28 18 17 3 28
29 30 0 8 33 22 17 4 27 28 20 27 24 23
37 31 18 23 11 21 6 20 32 9 12 29 0 13
25 22 4 34 31 3 14 15 4 14 18 13 13 22 24
29 30 0 8 33 22 17 4 27 28 20 27 24 23
37 31 18 23 11 21 6 20 32 9 12 29 10 0 13
25 22 4 34 31 3 14 15 4 2 14 18 13 13 22 24
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 35
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Code Set Performance on AWGN
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 36
doc.: IEEE 802.11-10/0432r2
Submission
LDPC Code Set Performance• OFDM with QPSK modulation on 3ns Exp Decaying PDP
Channel
• 20 iterations floating point belief propagation decoding
4 6 8 10 12 14 16 1810
-8
10-7
10-6
10-5
10-4
10-3
SNR (dB)
BLE
R
Rate-1/2
Rate-5/8Rate-3/4
Rate-13/16
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 37
doc.: IEEE 802.11-10/0432r2
Submission
SC MCS 0: Control MCS
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 38
doc.: IEEE 802.11-10/0432r2
Submission
Control MCS• Very low SNR modem to allow pre-beamforming link• Control MCS based on SC modulation ~27.5 Mbps• π/2 32 Golay spreading sequence• Differential encoding• Short rate 1/2 LDPC code using the existing rate 3/4 LDPC code
– Effective shorter block size-336 bits
• Spreading mitigates long channels• Differential encoding allows shorter preambles, and results in a
robust modem in the presence of phase noise• Short LDPC code is efficient for short packets• Bits are evenly divided between codewords to allow equal protection• A-MPDU aggregation is not allowed using Control MCS• Maximum length is limited to 1024 bytes
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 39
doc.: IEEE 802.11-10/0432r2
Submission
Control MCS Performance
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 40
Simulation Conditions:
• Packet Length-256 Bytes• AWGN• No impairments
doc.: IEEE 802.11-10/0432r2
Submission
Single Carrier MCS Set
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 41
doc.: IEEE 802.11-10/0432r2
Submission
SC Modulation
MCS Index Modulation NCBPS Repetition Code RateData Rate
(Mbps)
0 π/2-DBPSK 1/2 27.51 π/2-BPSK 1 2 1/2 3852 π/2-BPSK 1 1 1/2 7703 π/2-BPSK 1 1 5/8 962.54 π/2-BPSK 1 1 3/4 11555 π/2-BPSK 1 1 13/16 1251.256 π/2-QPSK 2 1 1/2 15407 π/2-QPSK 2 1 5/8 19258 π/2-QPSK 2 1 3/4 23109 π/2-QPSK 2 1 13/16 2502.5
10 π/2-16QAM 4 1 1/2 308011 π/2-16QAM 4 1 5/8 385012 π/2-16QAM 4 1 3/4 4620
Mandatory
• 448 chips per symbol
• 64 chips constant GI• Tracking purposes
• Can be used for equalization
• Pi/2 rotation applied to all modulations
• • To reduce PAPR for BPSK
• To enable GMSK equivalent modulation
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 42
doc.: IEEE 802.11-10/0432r2
Submission
6 7 8 9 10 11 12 13 14 15 1610
-2
10-1
100
RX SNR (dB)
PE
R
mcs=10mcs=11
mcs=12
mcs=10
mcs=11mcs=12
SCM Performance-AWGN
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 43
Simulation Conditions:
• Packet Length-8192 Bytes• AWGN • Red line-With impairments (PN, PA)• Blue line-no impairments
-3 -2 -1 0 1 2 3 4 510
-2
10-1
100
RX SNR (dB)P
ER
mcs=1mcs=2
mcs=3
mcs=4
mcs=5mcs=1
mcs=2
mcs=3
mcs=4mcs=5
2 3 4 5 6 7 8 9 1010
-2
10-1
100
RX SNR (dB)
PE
R
mcs=6
mcs=7mcs=8
mcs=9
mcs=6
mcs=7mcs=8
mcs=9
BPSK MCSs
QPSK MCSs16QAM MCSs
doc.: IEEE 802.11-10/0432r2
Submission
SC Low Power MCS set
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 44
doc.: IEEE 802.11-10/0432r2
Submission
Low Power SC Mode Motivation
• Targets:– Peak power for the entire solution including PHY, MAC, Memory, RF,
IOs, peripheral < 500 mW (e.g., USB 2.0)
– Average power of PHY/MAC < 150 mW
– Maximum delay spread for a 2 m range is in the order of 5 ns
• Therefore, there is a need for a low complexity low power mode that satisfies these requirements:– Simple FEC:
• Reed Solomon (224,208) for high data rate
• Outer Reed Solomon (224,208) + Inner Hamming like block code(16,8) for medium data rate
– Simple Equalizer for very short multipath
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 45
doc.: IEEE 802.11-10/0432r2
Submission
SC Low Power MCS set
• The FEC is one of the major contributor to the relatively high power consumption of the current SC mode
• Simple FEC: – Reed Solomon (224, 208) for high data rate– Outer Reed Solomon (224, 208) + Inner Hamming like block code (16,8) for medium
data rate
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 46
May 2010
doc.: IEEE 802.11-10/0432r2
Submission
Low Power Mode Blocking
• Compatible and built upon current SC mode
• Block size is 64 chips
• Sampling rate of 1.76GHz
PreamblePreamble HeaderHeader DataData
STFSTFGa128 x 15;-GaGa128 x 15;-Ga SC CEFSC CEF
~ 0.655 μs~ 1.091 μs
~ 1.745 μs
Ga64Ga64 d56d56 G8G8 d56d56 G8G8 d56d56 G8G8
~ 218.18 ns
Block 2 Block 3 Block 7Block 1
Block-512Block-512 Block-512Block-512 Block-512Block-512 Ga64Ga64... ... ...
Ga64Ga64 d56d56 G8G8 d56d56 G8G8
Block 2 Block 7Block 1...
Ga64Ga64 d448d448
LP MCS set
Current SC
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 47
doc.: IEEE 802.11-10/0432r2
Submission
Low Power MCS Performance
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 48
Simulation Conditions:
• Packet Length-4096 Bytes• AWGN-Upper Figure• 1ns RMS Delay Spread-Lower Figure• No impairments
0 1 2 3 4 5 6 7 8
10-4
10-3
10-2
10-1
100
SNRdB
FE
R
Frame Error Rate vs. SNR (4K octets frames)
RS(224,208)+Block(16,8) - AWGN
RS(224,208)- AWGN
0 2 4 6 8 10 12 14 16 1810
-4
10-3
10-2
10-1
100
SNRdB
FE
R
Frame Error Rate vs. SNR (4K octets frames)
RS(224,208)+Block(16,8) - Multipath
RS(224,208)- Multipath
doc.: IEEE 802.11-10/0432r2
Submission
OFDM MCS set
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 49
doc.: IEEE 802.11-10/0432r2
Submission
OFDM Modulation
• 512 points FFT
• GI length of 128
• Symbol interleaver for 16 QAM and 64 QAM
• 16 QAM – 2 code words per symbol
• 64 QAM – 3 code words per symbol
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 50
MCS index Modulation Code Rate NBPSC NCBPS NDBPS Data Rate
13 SQPSK 1/2 1 336 168 693.00
14 SQPSK 5/8 1 336 210 866.25
15 QPSK 1/2 2 672 336 1386.00
16 QPSK 5/8 2 672 420 1732.50
17 QPSK 3/4 2 672 504 2079.00
18 16-QAM 1/2 4 1344 672 2772.00
19 16-QAM 5/8 4 1344 840 3465.00
20 16-QAM 3/4 4 1344 1008 4158.00
21 16-QAM 13/16 4 1344 1092 4504.50
22 64-QAM 5/8 6 2016 1260 5197.50
23 64-QAM 3/4 6 2016 1512 6237.00
24 64-QAM 13/16 6 2016 1638 6756.75
doc.: IEEE 802.11-10/0432r2
Submission
• SQPSK-Spread QPSK
• QPSK Modulation (DCM)
• DTP (Dynamic tone pairing)– Via feedback from the receiver to the transmitter
– Number of tone per group, index
• Pilots– Positions: 20 carriers spacing -150:20:150
– LFSR switched per symbol
OFDM Modulation
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 51
doc.: IEEE 802.11-10/0432r2
Submission
OFDM Performance-AWGN
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 52
-2 0 2 4 6 8 10 12 14 16 18 2010
-3
10-2
10-1
100
SNR (dB)
Pac
ket E
rror
Rat
e
mcs 13mcs 14mcs 15mcs 16mcs 17mcs 18mcs 19mcs 20mcs 21mcs 22mcs 23mcs 24
Simulation Conditions:
• Packet Length-8192 Bytes• AWGN upper diagram• 4ns EXP PDP lower diagram• Timing and Freq Sync• Ideal PA• 13.75ppm CF/Symbol Clock Offset • No Phase Noise
doc.: IEEE 802.11-10/0432r2
Submission
General RF parameters
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 53
doc.: IEEE 802.11-10/0432r2
Submission
RF General Parameters
• Transmit EVM for all PHYs
• Unified mask for all PHYs
• Tx RF Delay
• Operating Temperature range
• Center Frequency leakage
• Transmit Ramp up/down
• Center Frequency Tolerance– ±20 ppm
• Symbol Clock Tolerance– ±20ppm locked
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 54
-3 -2 -1 0 1 2 3
x 109
-45
-40
-35
-30
-25
-20
-15
-10
-5
0
5
Frequency (Hz)
Spe
ctru
m n
orm
aliz
ed f
or 0
dB a
t in
band
(dB
)
Using PA model given by 11ad docs
PA output backoff from P-Sat=8.8
PA output backoff from P-Sat=8.0PA output backoff from P-Sat=7.2
PA output backoff from P-Sat=6.5
PA output backoff from P-Sat=5.9
PA output backoff from P-Sat=5.2
PA output backoff from P-Sat=4.6
PA output backoff from P-Sat=4.1PA output backoff from P-Sat=3.6
PA output backoff from P-Sat=3.1
0 2 4 6 8 10 12 14 15-28
-27
-26
-25
-24
-23
-22
-21
-20
-19
PA output backoff from P-sat (dB)
TX
EV
M (
dB)
TX EVM vs. PA backoff, MCS =9
doc.: IEEE 802.11-10/0432r2
Submission
Conclusions
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.
May 2010
Slide 55
doc.: IEEE 802.11-10/0432r2
Submission
Conclusions
• This complete proposal meets all the requirements of the TGad PAR and FRD:– Supports data transmission rates up to 7 Gbps
– Supplements and extends the 802.11 MAC and is backward compatible with the IEEE 802.11 standard
– Enables both the low power and the high performance devices, guaranteeing interoperability and communication at gigabit rates
– Supports beamforming, enabling robust communication
– Supports GCMP security and power management
– Supports coexistence with other 60GHz systems
– Supports fast session transfer among 2.4GHz, 5GHz and 60GHz
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 56
doc.: IEEE 802.11-10/0432r2
Submission
Strawpoll
• Do you support adopting the complete proposal in 802.11-10/433r1 as the first draft specification D0.1 of the TGad amendment?– Y:
– N:
– A:
May 2010
Carlos Cordeiro, Intel /Gal Basson, Wilocity/et. al.Slide 57