Wcdma rnsm11 hsdpa technology

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WCDMA SUBJECT——
HSDPA Technology
V0507
ZTE University
3G Course Team
WCDMA-RNSM11

•HSDPA Technology Overview
•ZTE HSDPA Network Planning and Implement
•ZTE HSDPA Radio Resource Management
•ZTE HSDPA Solution
Agenda

•HSDPA Technology Overview
•Driver to HSDPA
•HSDPA Theory
•HSDPA Terminal and Commercial Situation
Agenda

Competition to operator
Introduce HSDPA
to WCDMA
2.5G
 GPRS: 9.05 -171.2kbit/s,
Service deployment is bad
 CDMA2000 1x: 153.6kbit/s,
Service deployment is good
3G
CDMA 1x EV-DO: 2.4Mbit/s
WCDMA R99/R4: 2Mbit/s
Peak data rate (Kbps)
Mean data rate (Kbps)
R99

The driver to HSDPA
 HSDPA is a new technology to enhance WCDMA PS data service
 HSDPA gives subscribers new experience of more higher speed data
service with more shorter time delay
 HSDPA brings more bandwidth and more online subscribers
 It is necessary and feasible to introduce HSDPA to WCDMA network
 With consideration of network planning and deployment cost, HSDPA
should be applied at the beginning, or at least the Node B should
hardware ready for HSDPA
 HSDPA brings new requirement of transmission and network planning.
Pay more attention to it
High Speed Downlink Packet Access

HSDPA, Mature technology
2002.6 R5 released
2003.6 HSDPA (High Speed Downlink Packet Access) was added into R5
HSDPA is smoothly evolved from WCDMA R99 without any big effect to the existing
R99 network
 1 new transport channel: HS-DSCH
 3 new physical channels：HS-PDSCH, HS-SCCH and HS-DPCCH
 MAC-hs sub-layer, HARQ (Fast Hybrid Automatic Repeat reQuest), Fast
Scheduling and AMC (Adaptive Modulation and Coding)
HSDPA
Max. downlink data rate: 14.4Mbps

Competition advantage of HSDPA
Standard Data rate (Mbps) Subscribers per cell
WCDMA R99/R4 2M
31×PS64k, 15×PS128k or 7×PS384k
(SF=32, SF=16 or SF=8)
HSDPA 14.4
64
(117.7kbps per user, SF=16, R=3/4,
16QAM)
CDMA2000 1x EV-
DO
2.4
59
(only tens of kbps, 200kbps when 8
users is configured)
HSDPA supports more users while provides higher data rate!

Perspective of HSDPA application
HSDPA Modem
HSDPA fixed terminal
Flexible access
Higher data rate
More users
Richer service
Obvious advantage to compete with
other 3G technology like CDMA2000
HSDPA data card
HSDPA PDA
Mixed with WMAN (WiMAX)
and WLAN (Wi-Fi), more advantage of
broadband wireless access
HSDPA handset
HSDPA Modem
HSPDA data card
HSDPA PDA
WCDMA R99/R4 coverage
HSDPA coverage
HSDPA, roundly improves the value of WCDMA network

Evolve from R99/R4 to HSDPA
L2
L1
DSCH
FP
RLC
L2
L1
DSCH
FP
Iub/ Iur
PHY
MAC
PHY
RLC
Uu
MAC-d
HS-DSCH
FP
HS-DSCH
FP
MAC-hs
PHY
(add 3
channels)
RNC, Node B: add HS-DSCH FP protocol process, involve Iub/Iur
Node B: add MAC-hs, responsible for AMC, HARQ, etc.
Node B: add 3 physical channels: HS-PDSCH,HS-SCCH,HS-DPCCH
UE: add MAC-hs, physical channels and process, modulation
MAC
(add
MAC-hs)
PHY
(add
process)
UE UTRAN

New physical channels of HSDPA
 HS-PDSCH is the bearer of HS-DSCH, transfer HSDPA user data (downlink) 2ms TTI, 3 slots,
spread factor is fixed to 16, multiple users & multiple codes, modulation method: QPSK and
16QAM
 HS-SCCH bears information of HS-DSCH such as UE specialized mask code, modulation and
coding policy, etc. (downlink) 2ms TTI, 3 slots, spread factor is fixed to 128
 HS-DPCCH bears feedback information of HS-PDSCH such as Channel Quality Indication
(CQI), H-ARQ confirm information ACK/NACK, etc. (uplink) 2ms TTI, 3 slots, spread factor is
fixed to 256
HS-DPCCH
HS-PDSCH
HS-SCCH
UE
DPCH
DCCH（信令）＋UL DTCH（PS业务）
DL DTCH (PS业务)
CN UTRAN
R99 channel
HSDPA channel

HSDPA working procedure
RNCNode B
(AMC and HARQ)
Data Packet
 AMC, modulation and coding selection
 HARQ, lowers the time delay, improves the
data throughput
 Fast scheduling, quick decision
②Evaluation, HS-DSCH parameters setting
④Receive data from HS-DSCH
according to Detecting
HS-SCCH

Key technology: AMC (1)
 Adaptive Modulation and
Coding (AMC), Node B can
adjust modulation (QPSK,
16QAM) and coding rate (1/3,
3/4, etc) in time according to the
feedback channel state from UE.
So data transferring can follow
the step of channel state
changing in time, it is a good
technology for link self-adaptive
 For long time delay packet data,
AMC can improve system
capacity without add
interference to neighbor cells
Standard AMC Remark
R99/R4 N Quick power control
HSDPA Y Satisfy 15dB SIR dynamic range

Node B
CQI (Report periodically)
Modulation (QPSK, 16QAM) self-adaptive
Good channel state: 16QAM
Bad channel state: QPSK
Coding rate (1/3, 3/4, etc.) self-adaptive
Good channel state: 3/4
Bad channel state: 1/3
Efficiently utilize the channel condition
Good channel state: higher speed
Bad channel state: lower speed
Codes adjusting
Good channel state:
more codes
Bad channel state:
fewer codes

Standard Data rate (kbps) SF Modulation Coding rate
R99/R4 384 8 QPSK 1/3
HSDPA 720 16 16QAM 3/4
 HSDPA, the service bearing ability of one channel is further larger than
R99/R4 by using more efficient modulation and coding rate, while SF is
twice as R99/R4
 As using bigger SF, system can support more users
HSDPA, R99/R4 channel bearing ability comparison 16QAM and higher coding rate

Modulation coding
rate
Data rate
(1 code)
Data rate
(5 codes)
Data rate
(15 codes)
QPSK 1/4 120kbps 600kbps 1.8Mbps
QPSK 1/2 240kbps 1.2Mbps 3.6Mbps
QPSK 3/4 360kbps 1.8Mbps 5.4Mbps
16QAM 1/2 480kbps 2.4Mbps 7.2Mbps
16QAM 3/4 720kbps 3.6Mbps 10.8Mbps
HSDPA throughput, relative with modulation & coding rate
 HSDPA can provide data rate per user up to 10.8Mbps (16QAM, 3/4) by AMC and
multiple codes technology
 In the situation of high speed, HSDPA requires high channel condition
Multiple coding rates

Key technology: HARQ (1)
 Hybrid Automatic Repeat reQuest (HARQ) is a
combined technology with Forward Error
Correction (FEC) and Automatic Repeat reQuest
(ARQ)
 HARQ can provide flexible and subtle adjustment
for its process by cooperated with AMC
Standard HARQ Remark
R99/R4 N
FEC is in high layer
ARQ is in RLC layer, channel feedback is slow
HSDPA Y Includes physical layer HARQ and HARQ entity in MAC-hs
L1 HARQ
HARQ
MAC-hs
TFRC
L1
L2

Key technology: HARQ (2)
Advantage: improve transferring reliability
Disadvantage: lower utilization in bad
channel state
Advantage: good performance in
lower Bit Error Rate (BER)
Disadvantage: bad performance in
high BER
F
E
C
A
R
Q
H
A
R
Q
Combine FEC and ARQ, each
sending packet includes error
detection bit and error correction bit
Error packet A
Packet A
Packet A
Error packet A
Packet A
Packet A
missing data
Packet A
missing
data
HARQ phase I
（Resending is in RNC，R99）
HARQ phase II, III
（Resending is in Node B, HSDPA）
Packet A
Discard Reserve
Resend
whole packet Resend missing data
Soft
combination
Packet BPacket B
Send SendReceive Receive
Lower efficiency
Longer time delay
Higher efficiency
Shorter time delay

Key technology: Quick scheduling (1)
With quick channel
feedback, HSDPA
can suitably adjust
coding rate, codes,
modulation, etc. in
time according to
the channel state
Standard TTI (ms)
Channel feedback
time delay (ms)
Remark
R99 10 100 (at least)
HSDPA 2 5.67
Supports continuous
feedback, R5 also
supports 10ms TTI
HS-PDSCH
HS-SCCH
HS-DPCCH (ACK/NACK and CQI)
HS-SCCH
2 TS 7.5 TS +/- 128 Chip N TS
1 TS = 2560 Chip
HSDPA channel
feedback time delay
is about 8.5 TS
Quick channel feedback

Key technology: Quick scheduling (2)
Scheduling policy
Time fairness
Traffic fairness
Max-C/I
Proportional fairness
UE CNode B
UE A
UE B
HS-PDSCH
TS1
TS2
TS3Time fairness
Every user get equal service time, but the
traffic maybe not equal, the fairest
algorithm but has the lowest traffic
Every user get the same traffic, but the
time maybe not equal, has the lower
utility of system resource because it will
schedule the UE with bad channel state
Only the user in best channel state
(biggest C/I) will get the service priority in
each turn, the biggest traffic but has the
worst fairness
Weighted compromise of above
algorithms and has bigger system traffic
and better service fairness

Advantage of HSDPA
Comparing item R99/R4 HSDPA
System capacity (Mbps) 2.668 14.4
Spectrum efficiency
(Kbit/(MHz*Cell))
537.6 2795.2
System handover
Inter-frequency hard HO
Intra-frequency soft HO
Intra-frequency softer HO
Inter-system HO (GSM)
Only hard handover
Power control
Open loop, Close loop (Inner loop, Outer loop)
PC, Quick, Slow PC
HS-PDSCH adopts slow PC or
even no power control
Modulation QPSK QPSK, 16QAM
Link adaptive technology Quick PC and soft HO
AMC, HARQ, Short TTI and Quick
channel feedback
MAC-hs N/A For faster scheduling
Provides various speed
with stable power
(stable power,
adjustable speed)
Adjust power to
guarantee service speed
(stable speed,
adjustable power)
HSDPA R99/R4

System Changing caused by HSDPA
Control
plane
RAN changing
Base band
Physical layer
RF
MAC-hs
HS-PDSCH
HS-SCCH
HS-DPCCH
HS-DSCH
RRM Algorithm Upgrade
Interface protocol Upgrade
Add transmission interface
Add related
process
RNC
Node B
RNC, generally only
software upgrade is needed
According to various
venders, someone only
Needs software upgrade
and someone needs
hardware upgrade

Terminal Changing caused by HSDPA
UE changing
Powerful 3G terminals
Much more powerful, attractive HSDPA terminals
 faster processor
 larger memory
 advanced receive and process algorithm
 16QAM demodulation, multiple decoding
 MAC-hs process
 multiple codes
HSDPA terminal, first choice for high-end commercial application

HSDPA evolution
BASIC HSDPA
HSDPA enhancements
& MIMO HSDPA
3GPP R5
Peak Rate: 14.4M
Key: AMC, HARQ,
fast schedule and
feedback
3GPP R6/R7…
Peak Rate: 30M
Key: 64QAM, MIMO,
OFDM…
Apply HSUPA
……
……
4G
3G
B3G
……
Evolution of 3GPP:
 advanced technique
 smooth upgrade

HSDPA terminal category and capability
UE category
Maximum
channels
Minimal TTI
Maximum service speed
(Mbps)
Modulation
Category 1-6 5 3 - 1 1.2~3.65
QPSK
16QAM
Category 7 10 1 7.2
Category 8 10 1 7.2
Category 9 15 1 10.12
Category 10 15 1 14.4
Category 11-12 5 2 1.8 QPSK
 Different UE supports various channels, minimal TTI and other parameters
 UE listed in Category 11 is in worst receive capability, Category 10 is the best
HSDPA terminal
HSDPA handset HSDPA pc card HSDPA PDA

HSDPA terminal mode
HSDPA network both supports UE with HSDPA function
or without HSDPA function.
To make full use of the network, we recommend to use
dual mode (GPRS/HSDPA) or multi mode
(GSM/GPRS/HSDPA) terminals.
If you want to access into HSDPA network, at least
you should prepare a normal WCDMA UE as in R99.
In the future, WCDMA terminal will use HSUPA to
improve the uplink speed.

HSDPA commercial process
 Terminals
2005 2Q, several manufacture promote HSDPA trial version terminal
2005 4Q, promote commercial HSDPA terminal
 Operator to deploy HSDPA
Cingular plan to deploy HSDPA in major city, 2006; till the end of 2006, to
provide the HSDPA service in most part of metropolitans.
NTT Docomo will deploy HSDPA in first quarter 2006; In UK, mmO2 will
launch the service in fourth quarter 2005；in HK H3G will provide commercial
service in first quarter 2006
 HSDPA standard has been determined
 HSDPA has adequate test instruments
 HSDPA technology has been tested in application
 Manufactures will provide HSDPA commercial terminals in 2005
 USA, Japan and the other operators start the HSDPA network construction
 ZTE equipment are HSDPA ready
In China, 3G license will be distributed later in
2005

High speed data demands bring the revenue
growth to operators
6360 6140
7010
5800
6730
5910
3250
1900
3260
1930
3550
1950
0
2,000
4,000
6,000
8,000
10,000
12,000
FOMA
04Q2
PDC
04Q2
FOMA
04Q4
PDC
04Q4
FOMA
04FY
PDC
04FY
数据通信
话音通信
7860
10280
7730
10270
8040
9610
ARPU（Japanese Yuan）
 Data demands Subscriber of FOMA is 6~7 times against to
2G. ARPU generated by data of FOMA in 2004/3Q reachs
3260 Japanese Yuan, is about 31.7% of total ARPU!
 High voice quality and video-call function of W-CDMA
increase the 3G users’ mean hold time (MOU of PDC drops
from 162 minutes in 2Q to 157 minutes in 4Q, but MOU of
FOMA increases form 171 to 227)!
227
162 157
171
0
50
100
150
200
250
04Q2 04Q4
PDC
FOMA
MOU（minute）
语音
通信
68%
数据
通信
32%
Revenue distribution
of FOMA
（04 3Q）
语音
通信
75%
数据
通信
25%
Revenue distribution
of PDC
（04 3Q）

High data service brings new
experience
Colorful email Multi-access
这家餐厅好像不错是啊，
明天去吧
 Adopt the HSDPA, operator can provide higher bandwidth service.
 To deploy new service.
Multimedia Download
NEWS MOVIE MUSIC
Cartoon mail

•ZTE HSDPA Network Planning and Implement
• HSDPA and R99/R4 coverage simulation analysis
• HSDPA and R99/R4 indoor/outdoor coverage
• HSDPA network planning study
• HSDPA effect on Iub transmission
Agenda

Link calculation for HSDPA
HSDPA link budget R99/R4 link budget
Max path loss
HSDPA can achieve the same coverage as R99/R4 under same data rate

Combination of HSDPA and R99/R4
 HSDPA makes the balance between the coverage and the throughput, increase the coverage
decrease the throughput.
 HSDPA provides about 200kbps in the edge of cell, Less than the R99/R4 DCH.
 Recommend to combine the HSDPA and R99/R4 DCH together, at the edge of cell UE can
“handover” into DCH. With this combination, you can take the most advantage from R99/R4 and
HSDPA.
 Refer to: radius of CDMA 2000 1x EV-DO cell is 907.5m.
0 10 20 30 40 50 60 70 80 90 100
0
1000
2000
3000
4000
5000
6000
7000
8000
9000
10000
DLCapability(kbps)
distance/cell_radius %
R99 PS
HSDPA

ZTE HSDPA construction solution
If necessary, use
a carrier only to
support PS data
Network construction
plan
Frequency point
assignment
Resource condition Advantage and disadvantage Recommended deployment
Intra-frequency plan
F1: HSDPA+R99/R4 Less inter-frequency handover,
admission control, load control and
power control can be achieved
within one same frequency cell.
Advantage: easy to do
resource control
Disadvantage: do not have
user detail classification
After the network
construction finished, to
achieve the high demand of
voice and PS downlink.
F2: HSDPA+R99/R4
Inter-frequency plan
F1: R99/R4
Situation I: if HSDPA frequency
point support normal handset, all
the resource have to be assigned
within various different frequency
cells.
Situation II: HSDPA frequency
point are only used for PC card,
resource management can be
achieved more easily.
Advantage: voice user
+HSDPA users get good
service
Disadvantage: resource
control will be difficult in
situation I, maybe some
frequency point resource will
be wasted at the beginning
With the development of 3G,
to provide dedicated
frequency point for HSDPA
PC card (only PS domain)
F2: HSDPA
HSDPA
(PC card)
f1 f2 f3
R99/R4+
HSDPA
R99/R4+
HSDPA
Phase I, IIPhase III
ZTE solution
HSDPA construction area
Phase I :several hot spot,
and the important building
to deploy HSDPA
Phase II :all the hot spot and
several macro sites to deploy HSDPA

Handover between HSDPA and R99/R4
 Support various handover method of HSDPA
 DCH to HS-DSCH channel handover
 HS-DSCH to DCH channel handover
 HS-DSCH to FACH channel handover
 FACH to HS-DSCH channel handover
 HS-DSCH to 2G “handover”
 With handover among HSDPA, R99/R4 and 2G network, achieve the HSDPA seamless coverage
handover policy motivation description
Handover based
on traffic
The traffic load for HSDPA
and R99/R4 has large
difference. Then we trigger
the handover
trigger handover while the traffic load of HSDPA cell is
too heavy and the load of R99/R4 cell is lower, or the
traffic load of different HSDPA cells are not in balance
Handover based
on service
According to the service type
and data rate to choose
HSDPA or R99/R4 network
Low speed data service can be handled with FACH,
Streaming service can be handled with DCH; the rest
high speed PS data service or non-real time data
service should be assigned to HSDPA
Handover between HSDPA, R99/R4 and DCH/FACH channels，can
guarantee the service stability of HSDPA

Network analysis for HSDPA and R99/R4
 After the 3G network construction, the basic demand of WCDMA network should adopt
HSDPA function, with soft smooth upgrade ability
 HSDPA is not constructed as a individual network, HSDPA is a enhanced technology of
WCDMA (throughput, users)
 Network construction and plan for R99 and HSDPA based on the “one-shot planning, multi-
stage deployment”
 HSDPA and R99 share the same network, Node B supports HSDPA function
 At dense traffic area (capacity is restricted), HSDPA can share the same site of R99
and achieve the same coverage of it.
 Capacity and coverage is a balance relationship, increase the network performance
to the maximum by making a balance between them.
 Have to take into consideration
 How to solve various radio environment coverage and capacity？
 How to ease the transmission resource after deployment of HSDPA？
 How to adjust the network plan?
 How to adjust the network construction investment?
 After deployment of HSDPA, any influence towards RNC, CN (capacity, networking)?
 Service type? And subscriber behavior changing caused by HSDPA will generate
new demand of network capacity?

• ZTE HSDPA Network Planning and Implement
Agenda

HSDPA for major area
Area type Square (km2) Erl
Dense urban 91.5 3527
Urban 179.78 4873
Suburb 3000.5 2100
total 3271.78 10500
Major area have
no more than
10% proportion
Major area
occupy
80% traffic
Fully HSDPA
coverage for
major area!
Major area：dense urban + urban

HSDPA outdoor coverage
Node B
Adaptive modulation
Good channel state: 16QAM
Adaptive coding rate
Good channel state: 3/4
AMC
 3×1 macro Node B, downlink capability >= 9Mbps
 3×1 micro Node B, downlink capability >= 18Mbps
HSDPA requires a good channel condition for high speed service:
 Good channel state
 Near to Node B
At beginning, HSDPA is suitable for micro Node B coverage of outdoor
hotspot
Micro Node B is more suitable for HSDPA

HSDPA indoor coverage
HSDPA indoor coverage
 CBD (focus on)
 Office, hotel, etc
 Shopping center, airport, etc
 Macro Node B＋Indoor distributed system
 Macro Node B/base band pool＋RRU＋
Indoor distributed system
 Micro Node B＋Indoor distributed system
 Pico
Solution
Transm
ission
Pico
B01
C
RRU
B03
RPower
distributor
Twisted
pair
Fiber
Feede
r
Macro Node B
or base band
pool
 Concern of HSDPA indoor coverage
 Is the existing indoor distributed system
of R99/R4 suitable for HSDPA?
 Is capacity of the existing indoor
distributed system enough？Is the
transmission enough?
the indices of indoor distributed
components (like power distributor)
required by HSDPA and R99 are same,
So the existing indoor distributed system
of R99/R4 is suitable for HSDPA

Number of sites
(S111)
Site radius
Existing R99
planning
52 537m
Existing R99 sites
HSDPA planning NE Cost of NE Total cost Advantage
Planning the same
number of sites as
R99/R4
CN Same
Add 8％
The capacity of PS
increases 80 ~120％
RNC Add 5％
Node B Add 10％
Planning Area: 30Km2
Subscribers: 80000
HSDPA network planning case study

ZTE HSDPA Network Planning and Implement
Agenda

 Without considering HSDPA, the 2G transmission resource can be
used by the WCDMA network on Iub interface.
 With HSDPA on the initial phase of WCDMA network construction,
higher requirements are needed for the transmission resource on the
Iub interface!
 “3G(network) makes use of 2G(transmission resource) during the
initial phase while the 2G makes use of 3G during the later phase”
is not true any more!
 The transmission capacity expansion or even the new
transmission resource is necessary on Iub interface.
Transmission resource on Iub and 2G

 The ATM service process modules of MSTP devices endow the 3G
transmission network with the same functions as those of the ATM switching
but lower cost.
 Basing on the MSTP platform, ATM VP-Ring can be established to improve
the transmission efficiency of the dynamic services and protect the ring
network at the same time.
MSTP--the networking technology of WCDMA
transmission network

For capacity
 R99 cell peak data rate:
7×384Kbps=2.688Mbps
 HSDPA cell peak data rate:
15×960Kbps×3/4 = 10.8 Mbps
 Peak throughput of HSDPA cell is
4 times as that of R99 cell
 Peak traffic of 3CS HSDPA Node B:
10.8×3×1.3×80% ＝ 32M
For traffic mode
 The PS traffic mode will change greatly,
more PS traffic will rush into HSDPA
system
 Peak throughput of HSDPA cell is 4 times as that of R99 cell, and
mean throughput of HSDPA cell is 2 times as that of R99 cell
 Consider both capacity and traffic mode, transmission resource of Iub
at beginning should be reserved 4 times as before or at least 2 times
HSDPA requires more transmission resource, because of the changing
of capacity of Node B and traffic mode
HSDPA transmission solution

Conclusions of HSDPA network
planning and establishment
 A complementary relationship is existed between HSDPA and R99/R4
on the throughput efficiency and coverage.
 Great attention should be attached to the carrier planning and handover
scheme when designing the HSDPA network with R99/R4.
 The network potential values can be improved a lot, while HSDPA is
realized according to the sites of R99/R4.
 HSDPA is mainly implemented in the urban area. Indoor coverage and
outdoor hotspot coverage are of especial importance.
 More attention should be paid on the transmission resource of Iub
interface when introducing HSDPA into the network construction.

 The introduction of HSDPA increases 3 HSDPA-related physical
channels. Thus, R99 RMM algorithm should be upgraded!
HSDPA influence on the RMM
algorithm of R99/R4
 Add special processing method on code resource management for HS-
PDSCH and HS-SCCH
 Add admission control on HS-DSCH
 Add HSDPA power control method
 Add DRBC (Dynamic Radio Bearer Control) after the introduction of HS-
DSCH
 Handover policy should be upgraded
 Load balance policy should be upgraded, e.g. the status transferring
between HS-DSCH and DCH
 Update congestion control
 Update load control

 After the introduction of HSDPA, more deep research and
discussion on how to optimize and allocate the radio
resource of HS-DSCH and DCH should be carried out in
order to make full use of the advantages of HSDPA.
 The radio resource balance between DCH and HS-DSCH
 The balance between power resource and code resource
HSDPA radio resource allocation
principles (1)

HSDPA radio resource allocation
principles (2)
 Basic methods of radio resource configuration:
 Static Configuration: Reserve partial radio resources in RAN for HSDPA subscribers,
such as power, channel code, etc.
 Dynamic Configuration: System will adjust the allocation of the resources (power,
channel code, etc.) between the R99 services and HSDPA services according to the
load status.
 It is simple, stable and reliable for the static configuration. As for the dynamic
method, more complexity will result in the improvement of the efficiency of resource
usage.
 Use the same carrier for HSDPA and R99:
 With static configuration, the allocation of radio resources for HSDPA and R99 is
made according to the forecast of the traffic model.
 With dynamic configuration, there is no need for the precise forecast of the traffic
model.
 Under the co-carrier environment, the dynamic method is recommended.
 HSDPA use independent carrier (There are enough carrier available):
 CS services are not supported. Only support data card for PS service.
 Either static or dynamic configuration is suitable.

 HSDPA Network Handover Type
 A: R99 soft-handover
 B: HSDPA intra-frequency cell
changing
 C: Intra-frequency “handover”
between SH and NHS (maybe status
transferring)
 D/F: R99 Inter-frequency hard-
handover
 E/G: Inter-frequency handover
between SH and NHS
 H: HSDPA Inter-frequency cell
changing
 I: 3G and 2G cell changing
NSH: Not Support HSDPA
SH: Support HSDPA
本图是示例图
2G小区 2G小区
f1(NSH) f1( NSH)
f2（SH）
f3 f3 f3 f3
f2（SH）
f1(NSH)
f2(NSH)
f3（SH）
A
B C
H
G
I
FE
D
Mobile Management

The powerful RMM algorithms
make the efficiency of resource
usage higher and the control of
resource more flexible. The
algorithms can be modified or
customized according to the
requirements of operators.
Conclusion of HSDPA RRM
 The share of the radio resource between ZTE HSDPA and
R99/R4 is realized.
 The following functions should be enhanced in RMM due to the
introduction of HSDPA.
 Power control
 Code resource management
 Handover control
 Mobility management
 Admission control
 Load control
 Congestion control

Control
HSDPA Processor
DL Coder
DL Base-band
HSDPA Processor
UL Decoder
UL Base-band
Mid-frequency
After HSDPA
Update
Before HSDPA
Update
After HSDPA
Update
Before HSDPA
Update
Iub Interface Features
 Advanced design，HSDPA
functions have been embedded
into hardware.
 Just update software to support
HSDPA functions.
 No additional hardware is needed!
ZTE serialized Node B support
HSDPA flexible update

ZTE Node B hardware support HSDPA
 HSDPA functions have already been embedded into ZTE serialized Node B
hardware. The base-band processing chip supports 16QAM modulation. Only
software update is needed for Node B to support HSDPA.
 Powerful base-band processing ability. For the case of updating the R99 cell into
R99/HSDPA, no more base-band processing board is needed for Node B.
 As for RNC and CN, the introduction of HSDPA will only increase the data traffic
which means only additional interface hardware resource are needed.
ZTE Node B is designed based on the most advanced
HSDPA technology in the world. It is absolutely ensured
that to upgrade from R99 to HSDPA, no board is
required to be changed! The base-band processing
board also possesses a unique feature that is it
supports the networking of HSDPA and R99 with either
the same carrier or not! The most advanced base band
processing in the world!

 New modules in Node B
 HSDPA MAC functional modules
 HSDPA FP functional modules
 HSDPA control functional modules
 HSDPA downlink link processing module
 HSDPA uplink link processing module
 For RNC software modules, only updating
 HSDPA radio resource management
module
 HSDPA control plane process module
 HSDPA user plane process module
Software upgrade to support HSDPA

 B09 indoor macro: support up to 3C3S and 6CS RRU
 B09A outdoor macro: support up to 3C3S and 6CS RRU
 B06C/B03C indoor/outdoor micro: support up to 2C3S/3C1S.
 B03R indoor/outdoor RRU: support up to 3C1S
 BBUA indoor/outdoor base-band pool: maximum processing capacity is up to 15CS
 B01C pico Node B: 1C1S configuration
B09
BBUA
B06C
B03C/B03R
B09AB01C
ZTE serialized Node B totally support HSDPA

RNC solution for HSDPA
Master
Rack
Slave
Rack
Single resource shelf
(bi-directional):
 120Mbps
Single rack (bi-directional):
 360Mbps
Maximum configuration
(bi-directional)：
 1.68Gbps
 Single resource shelf supports: 120 Mbps data throughput. Single rack supports: 225K
subscribers (3 resource shelves).
 Once data traffic exceeds the processing ability of single resource shelf, smooth
expansion can be adopted by adding at most 14 resource shelves. Full configuration
supports 1M subscribers (5 racks).
ZTE RNC, data throughput is up to 1.68Gbps!
Top one in the field. Sound basement for the future development of HSDPA
Slave
Rack
Slave
Rack
Slave
Rack
Control
Shelf
Resource
Shelf
Resource
Shelf
Switch
Shelf
Control
Shelf
Resource
Shelf
Resource
Shelf
Resource
Shelf
Control
Shelf
Resource
Shelf
Resource
Shelf
Resource
Shelf
Control
Shelf
Resource
Shelf
Resource
Shelf
Resource
Shelf
Control
Shelf
Resource
Shelf
Resource
Shelf
Resource
Shelf

V2.0
V3.0
2004/4Q 2005/3Q Time
Version
2003/2Q
V4.0
V4.5
2006/1Q
R99
R4
R5
HSDPA
Phase I
R5
HSDPA
Phase II
 Serialized Node B
hardware support
HSDPA
 Completed HSDPA
trial system
HSDPA commercial
phase I
HSDPA commercial
phase II
HSDPA PC card,
05/3Q test, 06/1Q
commercial
HSDPA terminal,
06/1Q test, 06/2Q
commercial
ZTE HSDPA Roadmap

HSDPA PC card (MU330)
 Functions
 WCDMA 2.1GHz, GSM900/1800/1900
 WCDMA 384KDL/128KUL, GPRS Class 10
 SMS, Voice
 HSDPA
 ETSI AT command interface
 OS: Windows 2000, XP
 Language: Chinese, English, etc.
 3V SIM/USIM card

HSDPA handset (Q508)
 Functions
 WCDMA, GSM900/1800/1900
 WCDMA 384DL/128KUL, GPRS Class 10
 Voice, MMS, WAP, Email, JAVA, Download
 Video phone, Streaming media, PTT
 LCS (A-GPS)
 MP3/MPEG4
 Blue tooth/USB/mini-SD
 HSDPA
 Specs
 Dual camera (2000K pixels)
 Dual LCD: 260K colors
 Main LCD: 2.2”（240×320）
 MIDI: 72 chord

 ZTE serialized Node B is already hardware ready
for downlink 14.4M, only software upgrade is
needed
 ZTE RNC and CN, unified platform, 80G switching
capability, high integration, high capacity, smooth
evolution, to ensure the deployment of HSDPA
 HSDPA can share carrier with R99/R4, or use a
exclusive carrier
 Support handover between HSDPA, R99/R4 and
2G
 Support simultaneous service of HSDPA and voice
(or video telephony)
 Support at least 64 users per cell
 HSDPA can share base band board with R99/R4
All the Node Bs support HSDPA
ZTE HSDPA solution conclusion

Wcdma rnsm11 hsdpa technology

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