Date: 11 May, 2009
Abstract: This contribution contains framework and components proposal update for DOrC
NoticeContributors grant a free, irrevocable license to 3GPP2 and its Organizational Partners to incorporate text or other copyrightable material contained in the contribution and any modifications thereof in the creation of 3GPP2 publications; to copyright and sell in Organizational Partner’s name any Organizational Partner’s standards publication even though it may include all or portions of this contribution; and at the Organizational Partner’s sole discretion to permit others to reproduce in whole or in part such contribution or the resulting Organizational Partner’s standards publication. Contributors are also willing to grant licenses under such contributor copyrights to third parties on reasonable, non-discriminatory terms and conditions for purpose of practicing an Organizational Partner’s standard which incorporates this contribution. This document has been prepared by contributors to assist the development of specifications by 3GPP2. It is proposed to the Committee as a basis for discussion and is not to be construed as a binding proposal on Contributors. Contributors specifically reserves the right to amend or modify the material contained herein and nothing herein shall be construed as conferring or offering licenses or rights with respect to any intellectual property of Contributors other than provided in the copyright statement above.
DO Rev. C Framework Proposal Update
Recommendation: review and adopt
Source: Shu Wang and Tony Lee VIA Telecom
Contact: {shuwang, aslee}@via-telecom.com
C30-20090511-032
DO Rev. C Framework Proposal DO Rev. C Framework Proposal UpdateUpdate
Shu Wang and Tony Lee {shuwang, aslee}@via-telecom.com
VIA Telecom
IntroductionIntroduction
In the previous framework contribution, C00-20081201-019, VIA presented some views on DO Rev. C break the coverage/throughput dilemma improve the support for delay sensitive services improve the support for location services and local multicast
In this contribution, VIA would like to outline DO Rev. C framework from the following considerations Strictly backward compatibility Rank deficiency issue of multi-antenna transmission The impact of MIMO on DO VoIP The tradeoff between VoIP capacity and sector throughput
VIA proposes subband OFDMA/MIMO as well as many other enhancements for DO Rev. C.
DO Evolution: Keep the MomentumDO Evolution: Keep the Momentum
DO Rev. A: provides FL peak data rate of 3.1 Mbps and RL 1.8 Mbps in a 1.25 MHz FDD carrier.DO Rev. B: with the 64-QAM scheme, the FL peak data rate increase to 4.9 Mbps per 1.2288MHz. An aggregated 5 MHz will deliver up to 14.7 Mbps and up to 73.5 Mbps within 20 MHz. DO Rev. A/B have a very good support of delay sensitive service: multi-user packets, QoS scheduler, H-ARQ, etc.DO Rev. C promises higher link and sector throughput, improved delay sensitive service support, improved BCMCS, etc.
Strictly Backward CompatibilityStrictly Backward Compatibility
CDM or OFDMData 400 Chips M
AC
MIM
O P
ilots
CDM or OFDMData 400 ChipsM
AC CDM or OFDM
Data 400 Chips MA
C
MIM
O P
ilots
CDM or OFDMData 400 ChipsM
AC
½ Slot, 1024 Chips ½ Slot, 1024 Chips
Adding OFDM into DO Rev. A/B is not something completely new to us.
In DO Rev. A/B, the data portion in each interlace can be Unicast data as in traditional EV-DO, IS-856 Broadcast/Multicast data , CDM or OFDM
For the sake of strictly backward compatibility, it is recommended to replace a certain number of DO interlaces with DO Rev. C, which can be OFDMA or OFDM interlaces.
Break The Coverage/Throughput DilemmaBreak The Coverage/Throughput Dilemma
102
103
-35
-30
-25
-20
-15
-10
-5
0
5
10
15
Eq
uiv
alen
t S
NR
(d
B)
Coverage Distance (meter)
Single AntennaPath Loss Bound
Low throughput and large coverage
high throughput and small coverage
good throughput and large coverage
Adjacent Cell Interference
Multi-Antenna Transmission
Cooperation between ANs
Interference Limited Path Loss Bound
Multi-Antenna Path Loss Bound
Multi-Antenna Transmission for DOMulti-Antenna Transmission for DO
Multi-antenna techniques are believed to be critical in meeting the demand of high data rate and high link quality. Improve link quality: spatial diversity and beamforming Improve link throughput: spatial multiplexing
Multi-antenna techniques can be employed for both forward link and reverse link transmission.
However, there are issues which should be carefully considered in implementing multi-antenna techniques in DO Rev. C. The rank deficiency issue. The impact of multi-antenna techniques on other services.
Multi-Multi-ANTANTenna ATenna AT
It is non-trivial to “squeeze” more and more antennas and RFs into a mobile phone with considering Power consumption. Mechanical limitation.
Multiple radio interfaces there already: GPS, bluetooth, WiFi, … Antenna spacing requirement.
For more spatial diversity gain, the separation should be larger than 0.5λ For 2GHz, the wavelength is about 15cm or 5.9 inch.
Operating frequency bands.
In addition, the achievable MIMO channel capacity also depends on the scattering statistics as well as the antenna configuration. The scattering statistics is usually quantified with angular int
ervals. The antenna array configuration can be characterized by the
area/size limitation and the shape.
Achievable Spatial Degree of FreedomAchievable Spatial Degree of Freedom
5 10 15 20 250
0.5
1
1.5
2
2.5
3
3.5
SNR (dB)
Exp
ecte
d N
umbe
r of S
patia
l Cha
nnel
s
L=1, dual-polarized antenna array
L=2, dual-polarized antenna array
L=3, dual-polarized antenna array
6 spatial cluser, angle spread = 35o, dual-polarized antenna array, f = 2GHz
Rank Deficiency and Multiuser MIMORank Deficiency and Multiuser MIMO
Without considering AT size, the achievable spatial multiplexing gain is limited by spatial scattering. In the case of a typical 4x4 MIMO, less than 1% of the users are able to
use rank 4. Around 90% users have either rank 1 or 2.
For an AT with the physical size of a few times of wavelength, e.g., about 0.5~3, the achievable spatial multiplexing gain is limited by the angle spread, AT size and C/I ratio. This is the case for practical multi-antenna mobile devices. The expected spatial multiplexing gain mostly is less than 3.
For achieving the full potential of multi-antenna transmission, it is necessary to explore the spatial multiplexing gain not only in link level but also in system level.Therefore, it is recommended to include the following for DO Rev. C MIMO/OFDMA Multiuser MIMO
VoIP User Capacity in DO Rev. AVoIP User Capacity in DO Rev. A
Theoretically, DOrA VoIP capacity is upper bounded at 96 users/carrier with an assumption of 8-AT MUP for every VoIP frame.In reality, DOrA VoIP capacity is upper bounded at 66 ATs/sector due to the limitation of available MAC indices or RL RoTThe introduction of new MIMO/OFDM subtype(s) in DO Rev. C brings us new opportunities and challenges in optimizing DO VoIP services.
Source: Qualcomm Incorporated.
High sector throughput but low
VoIP capacity
High VoIP capacity but low
sector throughput
VoIP Capacity / Sector Throughput DilemmaVoIP Capacity / Sector Throughput Dilemma
Source: Qualcomm Incorporated.
The Impact of MIMO on DO VoIPThe Impact of MIMO on DO VoIP
The introduce of CL-MTD may help increase DO VoIP user capacity. It alleviates the existing RL limitation on VoIP capacity.
The introduce of FL-MIMO interlace/subtype might, however, limit DO VoIP user capacity if it is not treated carefully. A FL MIMO 8-subpack interlace might reduce the scheduling
opportunity for up to 32 VoIP ATs.
Source: Alcatel-Lucent and Qualcomm
VoIP User Capacity and Multiuser Packets VoIP User Capacity and Multiuser Packets
Through DO single-user packet has the advantage of high throughput, minimum control overhead and simple receiver design requirement, it is not friendly in supporting delay sensitive services.
Higher VoIP user capacity can be achievable through packing more than one users in single transmission.
It is recommended to include multiuser packet design in DO Rev. C. Besides the existing CDM MUP, OFDMA MUP should be included. For higher throughput with VoIP, it is recommended to provide
the capability to mix MIMO traffic with VoIP traffic in DO Rev. C.
DO Rev. C Air Interface: A VIA’s ViewDO Rev. C Air Interface: A VIA’s View
The adoption of multi-antenna techniques promises to improve the performance of existing DO network infrastructure. Improved link quality: spatial diversity and beamforming Higher Date rate: spatial multiplexing, multiuser MIMO
MIMO OFDMA with antenna selection provides a balance between DO Rev. A/B and the full MIMO DO. OFDMA can also bring additional dimensions in optimizing D
O network when combined with multi-antenna techniques. It can improve the delay-limited capacity for VoIP-liked servic
es
Subband interference avoidance through OFDMA can help improve cell-edge user experience.Simple Forward Link Multicast with Supercasting.
MIMO-OFDMA Multiuser Packet for DO Rev. CMIMO-OFDMA Multiuser Packet for DO Rev. C
MA
C
Pilo
t(s)
MIMO-OFDM
MA
C
MA
C
Pilo
t(s)
MIMO-OFDM
MA
C
½ Slot, 1024 Chips ½ Slot, 1024 Chips
MIMO-OFDMMIMO-OFDM
OFDM MUP OFDM MUPOFDM MUPOFDM MUPSub
band
MA
C
Pilo
t(s) Multiuser
MIMO-OFDMMA
C
MA
C
Pilo
t(s) Multiuser
MIMO-OFDMMA
C
½ Slot, 1024 Chips ½ Slot, 1024 Chips
MultiuserMIMO-OFDM
MultiuserMIMO-MIMO
Sub
band
MIMO Reliability/Throughput TradeoffMIMO Reliability/Throughput Tradeoff
0 1 2 3 4 0
2
4
6
8
10
12
14
16 Full Antennas; Nt=4, L
r=N
r=4
Full Antennas; Nt=4, L
r=N
r=2
Antenna Selection; Nt=4, L
r=2, N
r=4
Antenna Selection; Nt=4, L
r=3,N
r=4
Not much spatial diversity gain loss, which happens only when Lr is less than a certain threshold
The difference between achievable spatial multiplexing gains
Spatial Multiplexing Gain r ( How fast the achievable throughput increases )
Sp
atia
l D
ive
rsity G
ain
d(r
) (H
ow
re
liab
le t
he
lin
k b
eco
me
s )
Interference Avoidance with Subband FFRInterference Avoidance with Subband FFR
Subband 1.1
Subband 1.2
Subband 2.1
Subband 2.2
Subband 3.1
Subband 3.2
f1
f2
f1
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
Cell 1
the common suband shared by the sectors in cell 1
the common suband shared by all sectors
the common suband shared by the sectors in cell 3
Sector 1.α
Sector 1.β
Sector 1.γ
Cell 1Sector
1.αSector
1.βSector
1.γCell 1
Sector 1.α
Sector 1.β
Sector 1.γ
Cell 1Sector
1.αSector
1.β
Cell 1/2/3
Sectors α
Sectors β
Sector γ
Cell 1/2/3
Sectors α
Sectors β
Sector γ
Cell 1/2/3
Sectors α
Sectors β
Sector γ
Cell 1/2/3
Sectors β
Sector γ
Cell 3Sector
3.αSector
3.βSector
3.γCell 3
Sector 3.α
Sector 3.β
Sector 3.γ
Cell 3Sector
3.αSector
3.βSector
3.γCell 3
Sector 3.α
Sector 3.γ
Shopping centre
Stadium
Park
Time
Frequency
Interference management can be done in the subband level. Interference avoidance is achievable in time domain (slots), frequency
domain (subbands), space domain (sectors) and even through power allocations.
Finer granularity means higher achievable efficiency. It help mobile do handoffs with less ping-pong.
Subband frequency reuse can be done either through network planning or the full CQI report from the cell-edge ATs.
OFDM
OFDM
OFDM
OFDM
OFDMA with Subband DRC Feedback, especially for cell-edge ATs
OFDMA and SupercastingOFDMA and Supercasting
0 0.5 1 1.5 2 2.5 3 3.50
0.5
1
1.5
2
2.5
3
3.5
4
4.5
Achievable Spectral Efficiency by the AT with bad reception (b/s/Hz) Ext
ra g
ain
by th
e A
T w
ith g
ood
rece
iptio
n (b
/s/H
z)
Superpostion CodingTDM/FDM with Uniform Power Allocation
DO Rev. A/B MUP operating pointExpected
Capacity Gain FDM MUP operating point
Single-Frequency Reuse
Simple FL Multicast with SupercastingSimple FL Multicast with Supercasting
Many emerging mobile services, e.g., alert service and positioning assistance service, require the same FL multicast to cover multiple sectors. It is similar to the full-fledged BCMCS but only for low data rate service,
such as text message broadcast. Its coverage is expected to be more flexible. For example, a couple of
sectors or even one sector only. Simple FL multicast with superimpose multicast traffic and unicast traffic help achieve higher spectral efficiency in DO network and minimize the impact of multicast traffic on the existing DO traffic.
MA
C
MIM
O P
ilots Superimpose
FL-MC with Unicast Traffic
MA
C
Superimpose FL-MC with
Unicast Traffic
MA
C
MIM
O P
ilots Superimpose
FL-MC with Unicast Traffic
MA
C
½ Slot, 1024 Chips ½ Slot, 1024 ChipsFrequency
Superimpose FL-MC with
Unicast Traffic
Mobile Radio Access Network
Assistance Server
Data Network
Assistance Server
ConclusionsConclusions
For DO Rev. C, it is important to consider the following issues when we introduce OFDM/MIMO into the existing CDM DO. Strictly backward compatibility Rank deficiency issue of multi-antenna transmission The impact of MIMO on DO VoIP The tradeoff between VoIP capacity and sector throughput
VIA proposes the followings for DO Rev. C MIMO-OFDM single-user packet MIMO-OFDMA multiuser packet Subband Interference avoidance capability Low Data Rate FL multicast with supercasting
VIA Forward Link Configuration (1/4)VIA Forward Link Configuration (1/4)
Frame Structure. The CDM pilots and MAC channels of DO Rev. A/B are kept for SBC.Numerologies: follow the same design as Qualcomm proposed. OFDM symbol length 200 chips. OFDM preamble length 20 chips.
OFDMA subband unit: 45 tons each subband, which is one quarter of 1.2288MHz. Subband Configuration can be
1) [1], 2) [¼ ¼ ¼ ¼], 3) [½, ½], 4) [¼ ½ ¼], 5) [½ ¼ ¼], 6) [¼ ¼ ½]
Subband Configuration 1) is OFDMAntenna Configurations: Forward Link
Baseline: 2x2 or 4x2 Optional: 4x4
Reverse Link Baseline: 1x2 or 1x4 Optional: 2x2 or 2x4
VIA Forward Link Configuration (2/4): SUPVIA Forward Link Configuration (2/4): SUP
The same as Qualcomm’s OFDM/MIMO proposal. C30-20081201-015 Preamble:
8-bit MAC ID 2-bit packet format indication relative to requested DRC Enables AN
to serve user a smaller than max size packet format
Data:
VIA Forward Link Configuration (3/4): MUPVIA Forward Link Configuration (3/4): MUP
Preamble: Additional OFDMA Preamble Subchannel, which is tail-biting convolutional coded Coding rate: 1/3 Constraint length: 9 Generator polynomials: (0557, 0663, 0711)
OFDMA Preamble Subchannel includes the fields Subband Configuration (2 bits) SubpacketInfo(10 bits): 8-bit MAC ID + 2 bit Rate Indicator.
As indicated by the SubpacketInfo field in OFDMA Preamble Subchannel, It is allowed to transmit the following packet types in each subband, regular OFDM single-user packet, MIMO/OFDM single-user packet, either SCW, MCW, or precoded. DO Rev. A MUP
OFDMA-MIMOOFDMA-MIMO
Each AT reports DRC for desired subband(s). For example, For each single-antenna AT, it reports DRC/PMI for each of the four subba
nds. For each dual-antenna AT, it reports two DRC/PMI for each of two subband
s.
Four bits indicate the data rate request and 3 bits indicate the desired serving sector. The channel has 64-ary bi-orthogonal modulation.
The DRC is sent on the Walsh codes W832 and W24
32 and multiplexed on the I and Q branches, which is similar to the DRC report in the MCW mode.
MA
C
Pilo
t(s)
MIMO-OFDM
MA
C
MA
C
Pilo
t(s)
MIMO-OFDM
MA
C
½ Slot, 1024 Chips ½ Slot, 1024 Chips
MIMO-OFDMMIMO-OFDM
OFDM MUP OFDM MUPOFDM MUPOFDM MUPSub
band
Multiuser MIMOMultiuser MIMO
MA
C
Pilo
t(s) Multiuser
MIMO-OFDMMA
C
MA
C
Pilo
t(s) Multiuser
MIMO-OFDMMA
C
½ Slot, 1024 Chips ½ Slot, 1024 Chips
MultiuserMIMO-OFDM
MultiuserMIMO-MIMO
Sub
band
Each AT reports DRCs/PMIs for the desired subband(s). For each single-antenna AT, it reports DRC/PMI for each of the four
subbands. For each dual-antenna AT, it reports two DRC/PMI for each of two su
bbands.
The AN does the MIMO spatial multiplexing based on the PMI feedbacks from multiple ATs. Optional: transmitted DRCs/PMIs may be broadcasted through FL
preamble.
Top Related