Radio Network Planning for WCDMA
Introduction
With the emergence of
3G mobile communication technology, the construction of the
UMTS network will
bring a profound evolution, which makes higher requirements for
network planning. At
present, the public is greatly interested in this new technology.
mobile communication
technology is different from the traditional GSM network
planning in terms of
essence. Worldwide people are developing new planning tool and
algorithm and
designing new work flow.
Comparison between
UMTS network planning and GSM network planning:
1. GSM network planning
The GSM network
planning is based on radio wave propagation analysis. According to
the transmitting
power and antenna configuration of BTS, its coverage area is
calculated. Normally,
only the downlink coverage area is calculated, so the GSM
technology does not
take uplink coverage area into consideration. The next step is
performed by network
planning engineers to analyze the required cell capacity.
According to the
calculated cell area, the traffic of cells can be estimated with the help
of electronic map,
and then the required channel numbers are calculated through traffic
models (such as
Erlang-B or Erlang-C). Next, it is the frequency distribution for BTSs,
and the same
frequency can only be reused among enough-distanced cells, to avoid
interference.
To expand the network
in the future, the network planning engineer just needs to
distribute new
channels to the corresponding cells. As long as there is appropriate
frequency in the
overall frequency planning and the expansion does not exceed the
maximum capacity of
the BTS, the network does not require other adjustments.
Otherwise, new BTSs
or sectors should be added, and new frequency calculation and
channel distribution
are required.
2. UTMS network planning
Compared with the GSM
network planning, the UMTS network planning features the
following differences:
Cell breathing:-
The CDMA network is
totally different from the GSM network. Since channels and
users are not
separated for consideration, there is tight relation between coverage and
capacity. The cell
with more traffic has less coverage area. In the CDMA network, more
traffic means more
interferences. This kind of effect of dynamic change of cell area is
called as “cell
breathing”. This can be illustrated through the following visual example.
In a birthday party
of a friend, many guests come. More people taking will cause it is
harder to hear the
voice of opposite party clearly. If in the beginning, you can talk with a
friend at another end
of the room, you can not hear what he is saying at all when the
room is very noisy.
It indicates that the “cell radius” of talking area is shortened. The
UMTS network planning
engineer faces a network changing dynamically.
In UMTS network
planning, the network expandability should be taken into
consideration first
of all. The network planning engineer can not simply add frequency
to the related cell
as planning GSM network. In the beginning of network planning, a
determined traffic
signal redundancy should be taken into consideration, and this
redundancy will be
used as “compensation” to the interference caused by increased
traffic. This shows
that, from the very beginning, it is required to construct the network
with smaller cells or
more NodeBs, resulting in higher investment cost. If the traffic
signal surplus is too
small, there is only one way: adding NodeBs when expanding.
The network planning
engineer should notice the above issues, because enhancing
transmitting power
simply can not reduce the receiving signal deterioration caused by
traffic incensement.
Enhancing transmitting power can only improve the receiving
signal of a cell but
will add interference to the adjacent cells. As a result, the whole
network communication
quality will be influenced.
To enhance
transmitting power, the valid range or capacity (for the CDMA network, they
are homonymous) of
the CDMA cell is limited. When the UMTS network transmitting
power is doubled, the
cell capacity is increased by 10%. The enhanced transmitting
power raises the
valid range of cell, but to satisfy the requirements of remote mobile
subscribers, it is
necessary to enhance transmitting power by multiple times, which will
influence the talking
quality of other mobile subscribers. Let’s return to the above party
example. You can
enhance your voice to continue the conversation with the friend at
another end of the
room, but at the same time, other guests also raise voice to talk with
others. As a result,
the whole room is submerged in noise.
The corresponding
relationship between transmitting power and cell capacity is gradual.
Since the UMTS cell
load is subject to saturate, the UMTS network planning engineer
must reduce the
full-load ratio. The detailed parameters depend on different services
and how much the
network carrier would like to risk. Usually, the full-load factor is
preset as 60% in network
design. Here, the “cell breathing” effect is used. The adjacent
cells can mutually
compensate load, called as soft load. Due to cost, the network
capacity can not be
increased on a large scale. The mathematical demonstration on
the UMTS service with
large scale data transmission shows that, as data transmission
volume increases, it
is more possible for a service cell to borrow capacity from the
adjacent cells. This
result is satisfied.
Near-far effect:-
Another typical issue
of the CDMA network is near-far effect. Since all the subscribers
in the same cell
share the same frequency, it is important that each subscriber in the
whole system
transmits signal at the minimum power. Let’s return to the above party
example. If someone
is shouting in the room, the conversation among all the other
guests will be
influenced. In the CDMA network, this problem can be solved through
power control. For
example, the UMTS network uses closed loop power control at
frequency 1500 Hz.
For GSM network, however, the power control works at 2 Hz and is
for uplink only.
This kind of fast
power control mechanism has been implemented in the UMTS
hardware. But the
network planning engineer will face the other case of this problem.
When a subscriber is
far away from the NodeB, he needs a majority of transmitting
power, resulting in
power shortage for other subscribers. This means that the cell
capacity is related
to the actual subscriber geographical distribution. When subscriber
density is rather
large, statistics average value can be used to solve this problem.
When subscriber
quantity is small, it is necessary to perform dynamic analysis to the
network through
simulations.
Uplink and downlink:-
The UMTS network
traffic is asymmetrical, that is, the data transmission quantity in the
network uplink
differs from that in downlink. The network planning engineer should
calculate values in
two directions and then combine them together properly. In this way,
the network planning
work will be very complicated. Uplink is a typical limit factor for the
valid coverage range
of UMTS cell, or we can say that uplink is coverage-limited and
downlink is
capacity-limited. The transmitting power in uplink is provided by UE and the
one in downlink is
provided by NodeB.
The above problems
also occur in the existing CDMA network. For the UMTS network,
these problems are
more complicated. The UMTS network can satisfy different
services with
different requirements in communication quality and traffic at the same
time, including
simple voice service and packet service up to 2Mbps.
Integrated services:-
In fact, the UMTS
network should satisfy requirements of different services at the same
time. So, the network
planning engineer should take different services into
consideration. For
the service with low communication quality requirement, the UMTS
cell has rather large
coverage. For the service with high communication quality
requirement, the cell
has very small coverage. So, in the actual work, the network
planning engineer
should not just consider UMTS cell radius, because different
Basic Principles of
WCDMA System services correspond to different cell radiuses. If the minimum
cell radius, that is, the service with highest communication quality
requirement, is used as the standard for
network planning, the
network establishment cost will be very high and it is not realistic.
The UMTS network
planning engineer should start from the cell radius of middle-class
service. As a result,
the actual valid range of the cell can only satisfy the requirement of
high-class service
partially. At present, many network planning software companies
have started to
develop valid algorithms for this kind of new UMTS network integrated
service.
Other differences:-
Compared with GSM
network, the UMTS network features other differences. The GSM
network solves
capacity problem with sector partition method. The cell with too much
traffic is divided
into multiple sectors, and antennas are added correspondingly. This
method is also used
for the UMTS network, but its effect is not enough. The change of
cell coverage will
cause the near-far effect mentioned above, and overlapped sectors
will interfere
mutually because they use the same frequency.
The declination angle
(mechanical or electronic) of antenna plays an important role in
the UMTS network. It
can reduce the interference among adjacent cells and raise cell
capacity implicitly.
In the actual application, large declination angle can be chosen to
solve this problem.
In the WCDMA system,
multi-path propagation is not a negative factor but an ideal
result, because
receiver can combine the signal with delay of at least 1 Chip (the UMTS
network chip
transmission rate is 3.84 Mcps, that is, 1 Chip=0.26 microsecond, equal to
78 meters) into valid
signal.
In addition, the UMTS
network also uses the soft handover. In this case, a mobile
subscriber can
connect to several cells. This method solves network signal fluctuation,
but raises network
traffic. The traditional Erlang model is not applicable any more.
Compared with 2G
traditional GSM network, the UMTS network features many
differences.
Especially, the UMTS network can run asynchronously, which causes
“non-orthogonality”
of transmission channel. Let’s return to the party example again.
Even if the perfect
planning can be made theoretically, that is, planning the person to
talk in the certain
time, it is impossible to reach that ideal goal factually, because the
watches of all the
guests can not be synchronous exactly.
Through the above
analysis, we can clearly see that the UMTS network planning needs
more cost, compared
with the current mobile communication network planning. The
UMTS network planning
is rather complicated, because many system parameters are
closely related to
each other and should be calculated at the same time. In the current
mobile communication
network, however, these parameters are calculated separately.
3G Network Planning Procedure
Compared with the
second generation mobile communication, it is difficult to forecast
different service
models in the third generation system network owing to introduction of
several kinds of high
bit rate services. As for radio network planning, in any case, it is
required to calculate
the link budget, capacity and number of NodeBs, estimate the
coverage of base
station and design the parameters. In addition, it is required to design
the whole network,
calculate the number of channel units, capacity of transmit lines,
RNCs, MSCs and other
units in a base station.
In network planning,
performance measurements (such as dropped call rate and GOS)
should be introduced
to measure the network performance. High-bit rate services are
provided at the cell
area where base stations are covered equably, while low-bit rate
services are provided
to the edge of cell. The coverage can be designed as continuous
coverage or hotspot
coverage. You should estimate coverage of base station carefully
according to
different services and different implemented policies. Radio network
planning can be
divided into the following phases:
ü
Preparation Phase
1) Confirming
Coverage Object
2) Confirming
Capacity Object
3) Confirming
Coverage Policy
ü
Estimation Phase
1) Estimating Cell
Service Amount
2) Estimating Cell
Capacity
3) Estimating
Coverage Area
4) Calculating Capacity
and Link budget
ü
Design and Adjustment Phase
5) Wireless Coverage
Optimization Adjustment
6) Control Channel
Power Design
7) Pilot Design
8) Soft Handover
Parameter Design
9) PN Offset Handover
After the above
phases, you get to know the radio network features and confirm control
channel allocation
and design handover parameters, and then you may analyze the
coverage of base
station in detail. As for some cell, inter-cell interference vs. total
interference ratio is
unique. During the process of planning, you can continually take an
analysis to the
network and evaluate the interference ratio to estimate the coverage in
different cells. Such
iterative process may be repeated until the convergence of
coverage is achieved.
Design tools can be adopted to realize the process automation
and in the meantime
detect leaks in the coverage. Usually, the coverage in 3G network
service is not
equable, which would lower network performance. On the one hand, the
interference in the
service-intensive area gets more, resulting in low quality. On the
other hand, it is not
necessary to get high quality, for it will result in a waste of resources.
System effectiveness
can be improved with the method of self-adapting controlling cell
radius, antenna
direction and uplink received power threshold. Cell radius can be
varied with pilot
power adjustment. If signal-interference ratio (SIR) is higher than the
required value, cell
radius can be increased. If not, cell radius can be decreased. The
uplink/downlink cell
radius can be balanced by increasing/decreasing uplink received
power threshold. In
the configuration of separate sectors, the communication quality of
the base station can
be balanced by changing central angle of each sector.
3G Radio Network Antenna
Introduction
In 3G system
(including WCDMA and cdma2000), which is as a new generation mobile
communication system,
multi-access mode has changed from TDMA/FDMA to
CDMA/FDMA. However,
as far as the wireless signal is concerned, it’s still facing the
difficulties in
making use of frequency resources efficiently and decreasing network
interferences and
transforming electrical signals with the utmost of efficiency.
A antenna is a
communication system bridge between a user terminal and a base
station control
equipment, widely applying to cellular mobile communication system. As
the communication
technology is developing, antennas will be on progress
consequentially. The
mobile communication system in the seventies adopted
omnidirectional
antennas or angle reflector antennas, for the reason that a few carriers
and base stations can
meet the demands of few users in a mobile communication
system of a city. As
the economy goes forward, the amount of mobile terminals, whose
demands can not be
met by the old base stations, is boosting so rapidly. Especially as
the development of
digital cellular technology goes, new antennas are required to be
configured to improve
the multi-path fading, site assignment and multi-channel network
in metropolis.
Plate type antennas
are widely applying to 2G digital cellular system thanks to the
features of low
section, light framework, easy setting and good electrical specifications.
From the middle 80’s
to the late 90’s, vertical polarization (VP) antennas are usually
adopted. A cell is
usually divided into 3 sectors, each of which demands 3 antennas, so
9 antennas should be
set in a cell. However, too many antennas will result in many
problems, such as
high setting cost. In addition, the optimum diversity reception gains
are unable to be
achieved with diversity reception antennas set, saying nothing of that
the antennas are
unable to be set in some base stations. In that case, the technology of
dual polarized
antennas emerges as the times require.
In 3G phase, as the
wireless technology grows and the signal detection varies, the
cellular network
should be adjusted and optimized, which demands new base station
antennas, such as
self-adapting control antenna and intellectualized antenna.
3G Network Structure
3G system, a
board-band CDMA system, inherits the features of narrowband CDMA
system in the aspect
of network structure. Thanks to code division multiple access,
frequency reuse is
not a big problem any longer. The network interference sources
from itself, related
to the amount of calling users at the same time. In a metropolis,
three-sector base
stations are commonly configured. In suburb, town and road,
three-sector base
stations or omni-directional
base stations are configured as required
and in arterial
traffic, two-sector base stations are commonly configured, as shown in
Figure.
 |
3G Radio Network Structure |
 |
3G Antenna's |
For 3G (WCDMA), the channels per
carrier are decided together by OVSF code and
scrambling code, so capacity of
the channels per carrier is great. You should set the
number of the carriers and
traffic channels in each base station based on the
requirements of practical traffic
distribution in engineering design.
When implementing multi-carrier,
you should pay attention to the followings in
designing radio network.
1) Optimize hard handover to
minimize the possibility of call drops.
2) Avoid isolated multi-carrier
base station and implement multi-carrier in central
cells to avoid hard handover.
3)
Avoid heavy-traffic cells of being edge cells where hard handover occurs
3G Radio Network Typical Antennas
You have several options to
choose 3G typical antenna base on the following
principles:
1) Properly choosing half-power
beam width and gain of antenna based on the
number of base station sectors,
traffic density and coverage requirements.
2) Adopting duplexer to save
antenna locations.
3) Adopting dual polarization
antennas in the dense urban areas.
The adjustment of antenna
direction is the same as that in 2G engineering. The main
lobe direction and angle of tilt
of the directional antennas should be properly adjusted to
the traffic distribution and
communication quality requirements. When setting antennas,
you should note that the
isolation between antennas should meet the requirements of
horizontal and vertical isolation
to avoid interference. The setting height of antenna is
up to the coverage. Therefore, it
should be properly considered according to the
coverage, interference, isolation
and future development requirements.
The antennas used in 3G network
are similar to those used in 2G network, whose
requirements are as follows:
ü Sector antenna
gain: 13-16 dBd
ü Omnidirectional
antenna gain: 9-10 dBd
ü Sector antenna
half-power beam width: 60-65 degrees or 90 degrees
ü Omnidirectional
antenna deviation in roundness: < +/- 1 dB
ü Voltage standing
wave ratio (VSWR): <1.5
ü Impedance: 50
ohm (unbalanced type)
ü Maximum input:
>500W
Antenna diversity:
Space diversity or polarization
diversity is taken as standard
configurations.
3G Smart Antenna (SA)
1. Principles of SA Smart Antenna
By adopting SDMA that signals
differ in the direction of transmission path, SA reduces
the effects of time delay spread,
Rayleigh fading, multi-path, channel interference,
distinguishes the signals from
the same frequency and timeslot, and combines with
other multiple access
technologies to maximize the use of frequency spectrum
resources.
The SA in base stations is a kind
of array antenna comprising multiple antenna cells. By
adjusting the weight scope and
phase of each signal and changing array pattern, it can
cancel interferences and increase
S/N. In addition, it can measure a user’s direction so
that
a beam is directed to the user.
 |
"SA" Pattern
From the Figure, it can be shown
that the array antenna is composed of N antenna
units, each of which has a
corresponding weigher, totaling M groups of weighers and
forming beams in M directions. M
indicates the number of users, which can be greater
than the number of antenna units.
The dimension of array antenna and the number of
antenna units decide the maximum
gain and the minimum beam width, which means
that the dimension of array
antenna and antenna gain should keep balance with the
antenna side lobe performance. By
adjusting the signal phase and amplitude received
from each antenna, SA combines
them to a desired beam. This is called beam forming,
which can form all kinds of
beams, such as scanning beam, multi-beam, shaped beam
and the beam with zero position
controlled. According to the pattern, there are two
types of SA: self-adapting
pattern and shaped pattern.
The key technology of SA is to
identify the signal angle of arrival (AOA) and the
implement of digit-shaped. The
algorithms to identify the signal AOA are MUSIC
algorithm, ESPRIT algorithm,
maximum likelihood algorithm, etc. The implementation
of digit-shaped is to choose the
optimum weight coefficient to get the optimum beam.
For self-adapting algorithm, the
first step is to set rules, which commonly are maximum
likelihood, maximum S/N, minimum
mean square error (MMSE), minimum square error.
You should choose one of them
according to the specific conditions. Beam forming SA
pattern
is shown in the Figure.
Beam Forming SA Principle Pattern Shown Below |
2. Applications of SA in 3G
The application example of SA in
2G network indicates that SA can efficiently prevent
from interference. According to
the 3G criteria, the SA application is required to
improve the network capacity and
performance, and take the technical factors, such as
“converged beam”, “self-adapting
beam forming” and “beam handover”, into
consideration.
“Converged beam” is applied to
special areas, aiming at enlarging coverage and
increasing capacity. Such beam
does not associate with a user, nor does it trace mobile
users in the coverage. However,
by increasing link scope and converging beams, it can
reduce transmission power of
mobile users and according increase capacity. If mobile
user enters the area with great
transmission attenuation, the converged beam will point
to the mobile user and rest on
him. If a mobile user enters the area with good coverage
which converged beams become
unnecessary, the mobile user will be in the charge of
common pilot channel.
“Self-adapting beam forming”,
applying to downlink, is in favor of link budget for
individual user and a group of
users to improve the system performance. In poor
transmission conditions, such as
cell edge (basement), the coverage is required to be
spread to users with an aim to
improve link scope.
“Beam handover system” can switch
users between narrow beams to form narrow
sectors without handover loss. Because
the capacity in 3G system increases as the
number of sectors increases, four
30-degree beams coverage can substitute one
120-degree one, resulting in
increasing capacity by 2 to 4 times. Users are switched
between beams without the
requirement of any special auxiliary channel.
There are several options to
apply SA in 3G. Beam handover SA is an option in starting
phase. In network design, SA can
reduce the external network interference (such as
one
frequency interference, adjacent frequency interference and other-system
interference) and the internal
network interference as well. The order of magnitude
depends on the amount of beams.
3G Handover Design
Introduction
As the mobile station (MS) gets
out of the service cell and goes into another service cell,
the link between the former base
station and the MS will be substituted for the link
between the new base station and
the MS.
Handover, in mobility management,
is mostly performed by RRC layer protocol in 3G.
1. Protocol state
The UE state can be classified
into IDLE state and CONNECTED state. The IDLE state
can be classified into UTRAN
IDLE, GPRS IDLE and GSM IDLE, three of which has
CONNECTED state. The UTRAN
CONNECTED state can be classified into four states:
URA-PCH, CELL-PCH, CELL-FACH and
CELL-DCH. Handover, generally speaking, is
that UE is transferred from one
communication connection to another one in the
CONNECTED state. In this text,
handover refers to that UE in CELL-DCH state, unless
otherwise specified.
2. Handover Classification
According to the setup and
release of radio link between MS and network, handover
can be classified into softer
handover, soft handover and hard handover.
Soft handover refers to that a MS
begins to connect with a new base station, the
communication between the mobile
station and the former base station is still on. Soft
handover is only applying to the
CDMA cells with the same frequency.
The difference between soft
handover and softer handover is, softer handover is
performed in the same NodeB where
the maximum gain ratio combination of diversity
signals are implemented, while
soft handover is performed between two NodeBs,
diversity signals selective
combination in RNC.
Hard handover consists of
intra-frequency handover, inter-frequency handover and
inter-system handover. Note that
soft handover refers to the intra-frequency handover,
but not all intra-frequency
handovers are soft handovers. If the target cell and the
former cell have the
intra-frequency but belong to different RNC, and there is no Iur
interface between RNCs, the
intra-frequency hard handover will occur. Besides, the
internal code handover in the same
cell is also hard handover.
Inter-system hard handover
consists of the handover between FDD mode and TDD
mode, the handover between WCDMA
system and GSM system in R99, and the
handover between WCDMA and
cdma2000 in R2000.
The startup compress mode is
required to measure inter-frequency and inter-system
for inter-frequency hard handover
and inter-system hard handover.
According to the purpose,
handover can be classified into edge handover, urgent
handover at poor quality, urgent
handover at quick level decrease, interference
handover, velocity sensitivity
handover, charge handover, layered/leveled handover,
etc.
The typical process of handover
is measurement control → measurement report →
handover decision→ handover
implementation → new measurement control.
In the phase of measurement
control, the network informs UE of the measurement
parameters through the sent
measurement control message. In the phase of
measurement report, the
measurement report message is sent to the network by UE. In
the phase of handover decision,
the network makes a handover decision according to
the measurement report. In the
phase of handover implementation, UE and the
network go along the signalling
procedure and make a response to signalling.
Measurement Procedures
In WCDMA system, there are
intra-frequency measurements, inter-frequency
measurements, inter-RAT
measurements, traffic volume measurements and
UE-internal measurements.
The same type of measurements may
be adopted in different functions or processes of
UTRAN, such as cell reselection,
handover and power control. The UE shall support a
number of measurements running in
parallel. The UE shall also support that each
measurement is controlled and
reported independently of every other measurement.
Cells that the UE is monitoring
(e.g. for handover measurements) are grouped in the
UE into three different
categories:
1.Cells, which belong to the active
set. User information is sent from all these cells.
The cells in the active set are
involved in soft handover or softer handover.
2.Cells, which are not included
in the active set, but are monitored according to a
neighbour list assigned by the
UTRAN belong to the monitored set.
3.Cells detected by the UE, which
are neither included in the active set nor in the
monitored set belong to the detected
set. Reporting of measurements of the detected
set is only required for
intra-frequency measurements made by UEs in CELL_DCH
state.
In IDLE mode, the UE shall
perform measurements according to the measurement
control information included in
System Information Block Type 11 on BCCH. In
CELL-FACH, CELL-PCH or URA-PCH
state, the UE shall perform measurements
according to the measurement
control information included in System Information
Block Type 12 on BCCH, while in
CELL-DCH state, according to the measurement
control information transmitted
by UTRAN.
The measurement results will pass
two smoothness processing. The first processing is
on the physical layer, with an
aim to filter fast fading and report the measurement
results from physical layer to
higher layer; The second processing is done before event
evaluation, when the higher layer
takes weighted average on the measurement results
reported from the physical layer,
based on the time, to confirm the coefficient of filter.
1. UE Measurement
ü P-CCPCH RSCP
RSCP, Received Signal Code Power,
is a measured received power of a code from
P-CCPCH in TDD cell. The
reference point of RSCP is the antenna connector at UE.
ü SIR
S/N is defined as (RSCP/ISCP) × (SF/2).Measuring
SIR should be in DPCCH after the
combination of wireless link. The
reference point of SIR is the antenna connector at UE.
Where:
RSCP, Received Signal Code Power,
is a received power of pilot bit in a code.
ISCP, Interference Signal Code
Power, is a received signal interference measured in
pilot bits. Only
non-orthogonality of the interference is concerned in measurement.
SF=Spreading Factor.
ü P-CPICH RSCP
Received Signal Code Power is a
code power measured in P-CPICH. The reference
point of RSCP is the antenna
connector at UE. If transmission diversity is adopted in ,
the received code power from each
antenna should be measured separately, then
added, and sequentially be the
power of the whole received codes in P-CPICH.
ü UTRA carrier
RSSI
RSSI = Received Signal Strength
Indicator, a broadband received power within relative
channel width. The measurement
will be taken at the downlink of UTRAN. The
reference point of RSSI is the
antenna connector at UE.
ü GSM carrier RSSI
RSSI = Received Signal Strength
Indicator, a broadband received power within relative
channel width. The measurement
will be taken at the BCCH carrier of GSM. The
reference point of RSSI is
antenna connector at UE.
ü CPICH Ec/No
Ec/No refers to ratio of the
received energy of each code to noise power density in a
channel. Ec/No has something in
common with RSCP/RSSI. The measurement will be
taken at basic CPICH. The
reference point of Ec/No is the antenna connector at UE. If
basic CPICH adopts transmission
diversity, the received energy of each code (Ec) from
each antenna should be measured
separately. The value of adding the received energy
of each code on basic CPICH will
be Ec.
ü BLER of
transmission channel c
It refers to the evaluation of
Block Error Rate (BLER) of transmission channel. The
evaluation of BLER is based on
CRC of each transmission block after the combination
of wireless link. Only the
transmission channel with CRC requires the evaluation of
BLER. In the connection mode,
BLER can be measured in any transmission channel.
In the idle mode, the BLER on the
transmission channel PCH should firstly be
measured if BLER needs measuring.
ü UE transmitting
power
It refers to the transmitting
power of the whole UE at a carrier. The reference point of
UE transmitting power is the
antenna connector at UE.
ü In UE, in
addition to the measurements above mentioned, there are the
measurements in the aspects of
time and order, which would not be described
here.
2. RNC Measurement
ü RSSI
RSSI, Received Signal Strength
Indicator, refers to a broadband received power within
UTRAN uplink carrier channel
bandwidth at the access point of UTRAN. The reference
point of RSSI measurement is the
antenna connector.
ü SIR
S/N is defined as (RSCP/ISCP)×SF.
Its measurement should be taken in DPCCH after
the combination of wireless link
at Node B. In the compression code, SIR should not be
measured at transmitting
interval. The reference point of SIR measurement is the
antenna connector.
Where:
RSCP, Received Signal Code Power,
refers to a received power in a code.
ISCP, Interference Signal Code
Power, refers to a received signal interference. Only
non-orthogonality of interference
is concerned in measurement.
SF refers to the spreading factor
used in DPCCH.
ü SIRerror
SIRerror = SIR – SIRtarget_ave,
where:
SIR refers to the SIR measured at
UTRAN in dB.
SIRtarget_ave = refers to the
average value of SIRtarget during a period of time. This period
of time is the same as that when
counting the average value of SIRerror. The average
value of SIRtarget is arithmetic
average, SIRtarget_ave in dB.
ü Transmitting
carrier power
The transmitting carrier power is
the ratio (0…100%) of the whole transmitting power to
the maximum transmitting power,
where the whole transmitting power [W] is related to
the average power [W] of a
carrier at an access point of UTRAN. The maximum
transmitting power is related to
the average transmitting power [W] of a carrier at an
access point of UTRAN under the
condition that each cell is on the maximum
power .The measurement may be
taken at any transmitting carrier from the access
point of UTRAN .The reference
point of measuring transmitting carrier frequency is the
antenna connector. The carrier
frequency of each branch should be measured in case
of transmitting diversity.
ü transmitting
code power
Transmitting code power goes
under the condition of given carrier, given scrambling
and channel code. You can take
measurements at DPCCH of any specific wireless link
from the access point of UTRAN,
to show the pilot bit power at DPCCH. All time slots
should be involved in the
measurement of transmitting power in the compression mode.
For example, the time slot of
transmitting interval should be involved. The reference
point of measuring transmit code
power is the antenna connector. The transmitting
code power [W] of each branch
should be measured and added in case of transmitting
diversity.
ü BER of
transmission channel
BER of transmission channel is to
evaluate the mean bit error rate of DPDCH data after
the combination of wireless link.
The BER of transmission channel (TrCH) is as a result
of measuring the puncture bits of
channel coding input terminal at Node B. The
evaluation of transmission
channel BER may be reported at the end of each TTI at
TrCH. The reported transmission
channel BER should be a BER evaluation at the latest
TTI of the current TrCH. Only the
BER of transmission channel through channel coding
are needed to be reported.
ü BER of physical
channel
BER of physical channel is to
evaluate the mean bit error rate of DPCCH data after the
combination of wireless link at
Node B. BER of physical channel may be reported at the
end of each TTI of all sent
transmission channels. The reported BER of physical
channel should be a mean BER
evaluation at the latest TTI of each transmission
channel.
Other measurements: round trip
time, transmission time delay, leading accesses,
etc.
Co-frequency Handover
The WCDMA handover algorithm is
briefed as follows. WCDMA soft handover
algorithm adopts Ec/Io of pilot
CPICH to be a measurement value of handover, which is
reported to RNC through
three-layer signaling.
The following terms are used for
describing handover:
Active set: The cells in active
set are connected to MS in the form of soft handover.
Neighboring set/Monitoring set:
They both list the cells which are measured by MS
continually, but the pilot Ec/Io
in these cells are not mature enough to enter active set.
WCDMA handover algorithm
WCDMA
soft handover algorithm is briefed as shown in Figure :
 |
WCDMA soft handover algorithm scheme common mechanism |
If during the period of ΔT, pilot
_Ec/Io> optimum pilot _Ec/Io reports range hysteresis
event 1A, and active set is not
full, the cell enters active set, which is called event 1A or
wireless link addition.
If during the period of ΔT, pilot
_Ec/Io> optimum pilot _Ec/Io reports range hysteresis
event 1B, the cell will be
deleted from active set, which is called event 1B or wireless
link
deletion.
If during the period of ΔT,
active set is full, optimum alternate pilot _Ec/Io> former worst
pilot _Ec/Io + _Ec/Io +
hysteresis event 1C, the strongest alternate cell (the strongest
cell in monitoring set) will
substitute for the weakest cell in active set. Such event is
called event 1C or the
combination of wireless link addition and deletion. Supposing
there are at most two cells in
active set as shown in Figure 5-20.
Where:
Reporting range indicates a
threshold value of soft handover;
Hysteresis event 1A indicates
adding hysteresis;
Hysteresis event 1B indicates
removing hysteresis;
Hysteresis event 1C indicates
replacing hysteresis;
ΔT indicates trigger time;
Optimum pilot _Ec/Io indicates
the highest value of cell measurement in active set;
Former worst pilot _Ec/Io indicates
the highest value of cell measurement in active set;
Optimum alternate pilot _Ec/Io
indicates the highest value of cell measurement in
monitor set;
Pilot _Ec/Io is a measured and
filtered value.
Handover between WCDMA System and GSM System
The WCDMA criteria and GSM
criteria support the bidirectional handover between
WCDMA and GSM. As a result of
coverage and load balancing, such handovers are
used. In the early WCDMA
configuration, it is necessary to hand off to GSM system for
continuous
coverage, and the handover from GSM to WCDMA can be used to reduce
the load in GSM cell. Due to
load, the bidirectional handover is significant as the service
of WCDMA network grows. The
inter-system handover is triggered by source
RNC/BSC. From the point view of
received system, the inter-system handover is
similar to the inter-RNC handover
or the inter-BSC handover.
1. Compression mode
If WCDMA adopts a way of
continuous sending and receiving, but no WCDMA signal
gap is generated, MS can not take
inter-system measurement through one receiver. In
this regard, the compression mode
is significant for the inter-frequency measurements
and the inter-system
measurements.
The introduction of compression
mode is to take alien frequency measurement or
alien-system measurement at FDD.
The reason for that is a set of transceiver can only
work
on a group of transceiver frequency at the same time. If you want to measure
the
signals with other frequencies,
you should power off the transceiver and hand off the
frequency to target frequency for
measurement. To ensure the normal transmission of
downlink signals, the former
signals should be transmitted during the transmission time
left, which is called downlink
compression mode. As the measurement frequency is
close to the uplink transmitting
frequency, to ensure good measurement, the uplink
signal transmit should be stopped
at the same time, which is called uplink compression
mode.
The
compression mode is shown in the following figure.
 |
Compression Mode Diagrammatic Sketch |
Fast power control can not be
used during the period of compression mode gap, so
some interleaved gain will be
lost; In this regard, during the compression frame, higher
Eb/No is demanded to decrease
capacity. The process of typical inter-system handover
is as follows:
The inter-system handover trigger
is implemented at RNC, for example MS is out of
WCDMA coverage range;
RNC commands MS to begin with the
inter-system measurements in compression
mode;
RNC chooses the target GSM cell
based on the MS measurements;
RNC sends a handover command to
MS.
The handover from GSM system to
WCDMA system sources from the BSC of GSM.
Due to discrete transmission and
receiving, the compression mode is not required for
the
measurement value of WCDMA from GSM.
Inter-frequency Handover in WCDMA
Most of UMTS operators have 2 ~ 3
available FDD carrier, where: one frequency is
enough to operate, while the
other ones will be used to meet the demands of increasing
capacity. We can adopt two
different ways on how to use the frequencies: For the site
with high capacities, several
frequencies can be used at the same site, or, different
frequencies can be used in
macro-cell layer and micro-cell layer. These schemes
should be supported for the
inter-frequency handover at WCDMA carrier.
The same as the inter-system
handover, inter-frequency handover requires the
compression mode measurement.
Handover Design
The soft handover design consists
of the configuration of the soft handover-related
parameters and the control of
soft handover rate. As WCDMA adopts soft
handover-related threshold, it
ensures a relatively stable configuration of the
parameters such as the threshold.
But the control of the handover rate is identical with
IS-95, which is about 30% to 40%,
because too much soft handover will not only
increase the cost on the radio
resources, but also reduce the capacity of the down link
when the soft handover is
increased to a certain degree.
On the down links, the system
interference will be increased along with the increase of
the soft handover link. In case
that the system interference exceeds the diversity gain
of the soft handover, the soft
handover will bring no benefit to the system capacity. In
this regards, a well-prepared
design is demanded before performing the soft handover
in WCDMA. We can keep the soft
handover rate in a suitable range by providing
enough diversity in the up/down
link.
Parameters with regard to the
network performance:
Reporting Range: It is used to
set the events 1a and 1b, namely the parameter R in
formulas 1a-1 and 1a-2, 1b-1 and
1b-2. The bigger the R value is, the wider the soft
handover area is. That is because
the bigger the R value is, the easier it is to access
ACTIVE SET.
W, which is used to calculate the
cell quality of the active set is the value adopted for
different cells. You will use it
when you calculate the formulas 1a-1, 1a-2, 1b-1 and1b-2.
Hystersis: The magnetic
hysteresis value in the event report. Like in GSM, the purpose
of introducing this value is to
avoid the Ping-pong effect as possible. If the value is set
too big will result in that the
handover may occur difficultly, but if it is set too small, the
Ping-pong
effect may not be avoided.
Reporting deactivation threshold:
The maximum number of cells in the active set when
the event is effective, is less
than the maximum number of cells in the active set by 1. It
is actually used to confirm the
maximum number of cells in the active set (only for 1A
event). If the value is set too
big, the system interference may exceed the diversity gain
of the soft handover, otherwise.
If it is set too small, it may fail to fully use the diversity
gain of soft handover.
Reporting activation threshold:
The minimum cell number of the active set when the
event is effective (only for 1C
event).
Time to trigger: Try to avoid the
impact of fast fading. If this value is too big, the
handover may be delayed while if
it is too small, the handover may occur frequently.
Amount of reporting: The maximum
amount of reporting after the event report changes
to the cycle report. It is often
used together with the Reporting interval.
Reporting interval: Reporting
cycle after the event report changes to the cycle report. It
is used together with the amount
of reporting. In using it, we should try to avoid
over-adding the signaling flow.
Reporting Cell Status: It is used
to indicate the cell composition principle of the
measured result, including the
maximum number of reporting cells and the attributes of
the reporting cell.
WCDMA Power Control Planning
Introduction
In the WCDMA system, radio
resource management includes power management,
mobility management, load
management, channel allocation and reconfiguration, and
AMR mode control. Of which, the
power management is a link of great importance.
Power is the ultimate radio
resource of the WCDMA system, so the only method to
make fully use of the radio
resources is to strictly control the use of power.
In terms of power management, the
QoS of a subscriber can be improved by increasing
the transmit power of the subscriber;
however, such improvement may result in
deteriorating other subscriber’s
receiving quality due to the self-interference feature of
the CDMA system. WCDMA adopts the
broadband spreading technology with all
signals sharing the same spectrum
and the signal energy of each MS is allocated within
the frequency band, thus for
other MSs it is a kind of wideband noise. Therefore, the
use of power in the CDMA system
is conflicting.
In addition, there are such
effects as shadow, multi-path fading and remote loss in the
radio environment. The position
of a cellular MS in the cell is random and changes
frequently,
so the path loss will fluctuate greatly, especially in the multi-cell DS/CDMA
system, where all the cells adopt
the same frequency. Theoretically, the address codes
allocated by different
subscribers are orthogonal, but in fact it is hard to guarantee them,
thus causing mutual interference
among the channels and serious “near-far effect” and
“corner effect”. Near-far effect
occurs in the uplink. If all the subscribers in the cell
transmit signals to the BS with
the same power, then the signals of the MS near the BS
are strong while the signals of
the MS far from the BS are weak. In such a case, the
weak signals will be masked by
the strong signals. Corner effect occurs in the downlink.
When the MS is at the corner of
the cell, the interference will be twice more than that in
the vicinity of the cell. When
the interference is severe, the communication quality of
the MS will be lowered promptly.
Therefore, on the basis of
ensuring QoS for subscribers, how to effectively control
power, how to reduce the transmit
power as much as possible, and how to reduce the
system interference and increase
the system capacity are the key to WCDMA
technologies. The WCDMA system
has such functions as forward power control (i.e.
control of the BS transmit power)
and reverse power control (i.e. control of the MS
transmit power}, of which the
reverse power control is especially important, because
with it, the system capacity and
communication quality may be ensured and the fading
and near-far effect may be
avoided to a great extent.
Principles of Power Control Implementation
1. Features of fast power control
The mode of power control
implementation in the WCDMA system is greatly different
from that in the GSM system. Fast
power control is a very important concept integrated
in the WCDMA system.
The radio propagation environment
is severe. In the typical cellular mobile
communication environment, the
transmitting signals between the BS and the MS
usually reach respective
receivers after many times of reflections, dispersions and
refractions. In this way, it is
easy to cause multi-path fading of the signal. Fast fading will
cause great impact on the
receiving quality of the slow mobile receiver. In the GSM
system, the MS reports the
measurement result every 480 ms, and the frequency of the
power control does not exceed
twice per second. Therefore, for the GSM system, the
multi-path fading is counteracted
through frequency hopping. For the WCDMA system,
in the uplink the DPCCH will
divide a 10 ms radio frame into 15 timeslots, each of which
includes a power control command
(TPC_cmd).As the speed of power control is higher
than that of fast fading, the
receiving quality of the slow MS is effectively ensured.
In other words, the fast power
control brings some gain to the slow MS by avoiding fast
fading.
Table 7-1 gives a comparison of the required Eb/Io values and required relevant
transmit power changes for the
slow and fast power control in the case of three different
motion
conditions.
 |
Changes of slow and fast power control in the case of three different conditions |
Another two advantages of fast
power control are that it can quickly adjust the power of
the MS to avoid far-near affect
to a great extent and the fast adjustment of the power
reduces the interference to other
cells and MSs.
2. Power control implementation
In the WCDMA system, power
control may be divided into inner loop power control and
outer loop power control.
The inner loop power control is
to converge the received SIR to the target SIR by
controlling the transmit power of
physical channels. In the WCDMA system, relevant
power adjustment commands are
sent out by estimating the received Eb/No (ratio of bit
energy to interference power
spectrum density). There is certain mapping relationship
between Eb/No and SIR. For
instance, for the 12.2 kbps voice service, the typical value
of Eb/No is 5.0 dB. If the chip
rate is 3.84 Mcps, the processing gain will be 10 log10
(3.84M/12.2k) = 25 dB. So, the
SIR is -20 dB (= 5 dB-25 dB), that is, the
Carrier-to-Interference Ratio
(C/I) is more than –20 dB.
The outer loop control mechanism
is to dynamically adjust the SIR target value of the
inner loop control, so as to
ensure that the communication quality always meets the
requirements (i.e. the specified
FER/BLER/BER value).The outer loop control is
conducted in the RNC. The radio
channels are complex, so the power control based
only on the SIR value cannot
reflect the real quality of the links. For instance, based on
the same FER, the requirements of
static subscribers, low speed subscribers (3 km/H)
and high speed subscribers (50
km/H) for SIR are different. The communication quality
is finally measured with
FER/BLER/BER, so it is necessary to dynamically adjust the
SIR target value according to the
actual FER/BLER value.
The inner power control may be
subdivided into open loop power control and closed
loop power control. The former
aims to providing the estimates of the initial transmit
power. It estimates the path loss
and the interference level according to the
measurement result, so as to
calculate the process of initial transmit power. In the
WCDMA system, the open loop power
control is adopted in both the uplink and
downlink.
In the WCDMA-FDD system, the fast
fading conditions in the uplink and downlink are
absolutely irrelevant because the
frequency spacing between the uplink and the
downlink is large. Therefore, the
path loss estimates obtained through the open loop
power control according to the
downlink signals are inaccurate for the uplink. The
method to solve this problem is
to introduce the fast closed loop power control
mechanism.
The closed loop power control
mechanism is to rapidly adjust the power in the
uplink/downlink during the
communication period, thus making the link quality
converged to the target SIR. Two
algorithms may be adopted for the closed loop uplink
power control in 3GPP protocol.
In the two algorithms, the step length of the uplink
power control is 1 dB or 2 dB. In
the DPCCH, the step adjustment of the power control
is Δdpcch = Δtpc*TPC_cmd.TPC_cmd
is the synthesized TPC command from different
algorithms. The power of DPDCH is
set according to the power offset between the
DPDCH and the DPCCH.
Differences between the two modes
are: The open loop is not closed. It estimates the
downlink interference according
to the uplink interference, or estimates the uplink
interference according to the
downlink interference. In comparison, the closed loop is a
closed feedback loop. The initial
transmit power of the open loop power control is set by
the RNC (uplink) or the UE
(downlink), while the closed loop power control is completed
by
Node B with RNC only giving the target SIR value of the inner loop power control.
 |
Basic structure of the closed loop power control mechanism |
3. SSDT (Site Selection Diversity Transmission)
In the soft handover, there are
two or more BSs in the downlink transmitting signals to
an UE simultaneously, which
occupies additional system resources (transmit power),
causing additional interference
and reducing the forward capacity. Therefore, careful
selection of the power control
algorithm during the soft handover is important to
improve the system capacity.
Another algorithm of the power control in the soft
handover is SSDT (site selection
diversity transmission), according to which, the BS
with minimum path loss will
transmit signals, while other BSs will only receive signals of
the uplink and transmit DPCCH. In
this way, the total transmit power and additional
interference may be reduced. SSDT
is an optional macro diversity method in the
software handover mode.
The specific SSDT implementation
method is as follows: Firstly, the UE selects a cell
from ACTIVE SET as the PRIMARY
CELL, and all other cells fall into the NON
PRIMARY CELL. SSDT is to transmit
signals from the PRIMARY CELL in the downlink,
so as to reduce the interference
resulted from the multi-channel transmission in the soft
handover mode. Secondly, it is
required to implement the site address selection
promptly if there is no network
intervention, so as to maintain the advantages of the soft
handover. To select PRIMARY CELL,
a temporary identity code should be allocated to
each cell. Then, the UE will
notify other cells in ACTIVE SET of the identity code of
PRIMARY CELL on a regular basis.
NON PRIMARY CELL selected by the UE will turn
off the transmit power, and the
identity code of PRIMARY CELL will be transmitted via
the uplink FBI domain of the
uplink. The SSDT activation, stopping and ID code
allocation are implemented by the
upper signaling.
SSDT is initiated by the network
according to ACTIVE SET of the soft handover. Once
it is determined to adopt SSDT,
the network will notify the cell and the UE of the
message that SSDT is activated in
the period of current soft handover. Otherwise, TPC
will still operate in the usual
mode, that is, each cell controls the transmit power
according to the TPC instruction
of the uplink. The allocation of temporary identity code
should be implemented by the
network and notified to all the cells in ACTIVE SET and
the UE for site address
selection.
The UE measures the Received
Signal Code Power of Common Pilot Channels (RSCP
of CPICHs) transmitted by the
cells within ACTIVE SET on a regular basis to select the
PRIMARY CELL. The cell with
highest RSCP of CPICHs is the PRIMARY CELL.
Planning of the Power Control Parameters
In the 3G system, the design
criteria of the network planning is based on the SIR
optimization and the activity set
management. How to set proper RSCP of CPICHs,
SIR
target value of various services and handover area (changes to the activity set
scope), and how to determine the
coverage and quality of each service area are the
mandatory tasks of the network
planning.
In the WCDMA system, the inner
loop power control is implemented by NODE-B. The
inner loop power control makes
convergence to the target SIR, which is determined by
the outer loop power control.
Therefore, the power control parameters planning is
mainly reflected by the outer
loop parameters planning. With the research to and
experiment on the relevant
parameter settings of the outer loop power control, the outer
loop power control can satisfy
the requirements for the control accuracy and the control
speed.
Specific parameters involving the
outer loop power control are as follows:
ü Time factor of
BLER report: The target BLER value divided by the time factor is the
pieces N to be measured;
ü BLER measurement report parameters;
ü Maximum pieces
to be observed: This parameter is used to control the upper limit
of the pieces N to be measured;
ü SIR-converged
lagging value: Check the SIR lagging value (one of measurement
report parameters) converged by
SIR;
ü Control
parameters of the SIR measurement report: SIR measures the filter factor
used by the SIRerr;
ü Uplink outer
loop power control parameters: SIR variation range, SIR adjustment
factor, SIR target value falling
step length, SIR maximum falling step length;
ü Uplink soft
capacity control parameters: voice quality level and corresponding
BLER values;;
ü Default CPICH
power downlink power balancing parameters: Trigger/Stop the
threshold of DPB process,
adjustment period and proportion of the downlink
power balancing
ü Downlink outer
loop power control parameters: Trigger and stop the thresholds of
downlink outer loop power
control;
ü Inner loop power
control parameters: Initial SIR value, adjustment step length,
algorithm mode selection;
The above parameters are provided
by OM, and there is a close link among them.
WCDMA Radio Network Structure and Resource Planning
Basic Network Structure
1. Network structure
The basic network structure of
WCDMA has been described in the prior chapter. It is
divided
into core network and access network. This chapter introduces the structure
features of UTRAN and some key
technologies and network parameters affecting the
radio network structure from the
perspective of network planning.
Types of areas and the relationships
among them
1) Types of areas include:
Location Areas;
Routing Areas;
UTRAN Registration
Areas;
Cell Areas.
2)
Relationships among the areas are shown as Figure :
 |
Relationships among the areas |
The classification of location
areas and routing areas in the WCDMA system is similar
to that in the GSM and GRPS
systems.
2. Cell structure
The Node B of Huawei WCDMA system
supports omnidirectional, 31, 32, 34, 61, 62
and 64 (combined cabinet) cell
configurations. The cell structure of WCDMA is similar
to that of GSM with different
titles. “Cell” is similar to the “BS” in the GSM, while
“SECTOR” is equal to the cell in
the GSM system.
For instance: What are 3*1, 3*2,
3*4, 6*1, 6*2 and 6*4?
The first digit is the number of
sectors supported by each cell; the second digit is the
number of carrier frequencies
supported by each sector. 3*1 means the BS supports 3
sectors, each of which has one
carrier frequency; 6*4 means the BS supports 6 sectors,
each of which has 4 carrier
frequencies.
The cell structure planning is to
evenly provide high bit rate within the cell area, or the
data rate of the cell boundary
may be lower than that of the area near the BS, thus the
cell
area will be larger.
The number of cells is calculated
according to the capacity and the link budget. A
network may be coverage-limited
or capacity-limited. Capacity limited means the
maximum cell radius cannot
support the total traffic flow. Then, the number of cells may
be calculated according to the
number of subscribers supported by the cell per sq.km.
Coverage limited means there is
enough capacity in the cell to support all the traffic flow.
Then, the number of required BSs
may be calculated according to the maximum cell
area.
3. Hierarchical structure of the air interface
According to the protocol, the
air interface may functionally form a hierarchical structure.
From bottom to top, they are
physical layer, link layer and network layer. The physical
layer fulfills the coding,
modulation and spread spectrum of the physical channel. The
link layer may be subdivided into
two sub-layers: Medium Access Control (MAC) and
Link Access Control (LAC).The
former determines the resources provided by the
physical layer, while the latter
completes the establishment, maintenance and release
of the logic link connection. The
network layer includes such functions as call control,
mobility management and radio
resource management.
4. Channel allocation and reconfiguration
The channel allocation includes
the following types:
Connection-oriented
channel configuration:
Fundamental Channel Configuration
(FRC) and Dynamic Channel
Reconfiguration (DCCC)
Cell-oriented
channel configuration:
Cell code resource allocation, cell channel
resource allocation and uplink
scramble allocation
Of which:
Fundamental channel
configuration: Allocate the channel types and bandwidth
according to the service request;
and configure the parameters of each layer of the
channel according to the QoS.
Dynamic channel configuration:
During the communication, dynamically change the
channel configurations according
to current service status, including the channel types
and the parameters of each layer
of the channel
Cell channel resource allocation:
Common channel is the resource in the cell, including
RACH, FACH, DSCH and CPCH.
Cell code resource management:
Cell downlink code resource allocation policy and
code
resource maintenance.
Uplink scramble allocation: The
uplink scramble includes the scramble reserved for the
common channels RACH and CPCH,
and the scramble allocated to the UE with
dedicated channel.
If RRC is connected or RAB sets
up the request, the fundamental channel configuration
entity determines the channel
type according to the service type and rate requirements,
and configures parameters of each
layer of the channel according to the QoS. It makes
a request to the call admission
control entity for admission control according to the
channel configuration parameter
(QoS).If it is permitted, then go ahead; or the process
of the channel setup is failed.
The dedicated channel is used to
allocate the uplink scrambles; while the cell code
resource maintenance entity is
used to allocate the downlink channel code. The
common channel is used to
allocate the common channel parameters.
If the channel is set up
successfully, the dynamic channel configuration entity will
monitor the traffic flow for the
specific service, and make dynamic adjustment to the
channel parameters.
The cell channel resources are
allocated according to the current cell service and the
load conditions, so as to adjust
the resource configuration of the cell common channel
and optimize the system
performances. The cell code resource management entity is
used to maintain the cell code
resources.
Hierarchical Network Structure
1. Basic concept of the hierarchical network structure
Similar to the GSM system, the
cell may be divided into macro cell (umbellate cell),
micro cell and pico cell
according to the features and scope of the cell services. The
macro cell, micro cell and pico
cell form a hierarchical network structure (HCS).
The third generation mobile
communication system should be able to support the
services with wide coverage in
various radio operation environments. The cell type
varies with the requirements:
Continuous coverage should be ensured for the large cell,
while the small cell needs high
spectral efficiency and capacity. The cell with small
coverage is used to the terminal
with low mobility and high capacity, while the cell with
large coverage is used to the
terminal with high mobility and low capacity. In addition,
cells should be able to operate
on other cells of different types. The coverage area of
micro cell is hundreds meters,
while the coverage area of macro is one or just over one
kilometers. In the rural area, it
can provide the micro cell with continuous coverage and
the fast mobile subscribers with
services. The pico cell covers an indoor scope with the
radius of several meters. The
satellite cell provides global continuous coverage. The
traffic
should be based on the minimum available cell.
There are two methods to design
multi-layer cell in the CDMA system: Different
hierarchical cells operating on
the same band, or different hierarchical cells operating
on the different bands. The
multi-layer structure also can be applied to the
multi-operator environment.
2. Micro cell and macro cell with the same frequency
The frequency reusability factor
is 1. The processing gain of the system enables
subscribers to bear the interference
from the cells of different layers. The intra-layer
interference is controlled by the
power control, while the inter-layer interference is
controlled by the spatial
isolation. Generally, the attenuation of the micro cell is larger
than that of the macro cell,
because its antenna is lower. Soft handover can offset the
attenuation valley of the
boundary of micro cell.
3. Micro cell and macro cell with
different frequencies
It is easy to manage when the
cells of different layers adopt different frequencies,
because there is no interference
among the layers. The disadvantage of this method is
that it needs large spectrum. At
least 15 MHz bandwidth is required if the WCDMA
system is divided into three
layers. The impact on the total spectral efficiency from the
non-linear power amplifier
depends on the neighboring channel interference and the
link performance deterioration.
The increase of the neighboring channel interference
will reduce the spectral
efficiency.
Although different carrier
frequencies are adopted in the multi-layer cells, interference
will occur between neighboring
channel carriers if the capacity is high.
4. Antennas selection and
parameters setting of the hierarchical network
Similar to the GSM system, the
traffic of the hierarchical network should be deployed as
much as possible to the cell with
minimum coverage area; that is, the macro cell is used
to satisfy the requirements of
the system for wide coverage, while the micro cell and the
pico cell are used to absorb the
traffic and the data traffic.
For this purpose, as to the
engineering parameters setting, the antenna and the
transmit power of the macro cell
are high; while the antenna and the transmit power of
the micro cell are low; as to the
software parameters setting, it is easier for the MS to
access the micro cell and the
pico cell. Most of the data traffic is convergent in the pico
cell,
so higher QoS of the pico cell should be ensured for higher service rate.
Mobility Management
1. Cell selection and
re-selection
1) MS status
According to the protocol, five
statuses are available for the MS (UE): IDLE,
CELL_DCH, CELL_FACH, CELL_PCH and
URA_PCH.
In the CELL_DCH status, the
cell-crossing is judged by the measurement report, and
the location is updated by the
handover process.
In the CELL_FACH and CELL_PCH
statuses, the cell-crossing is judged by the UE cell
reselection, and the location is
updated by CELL UPDATE.
In the URA_PCH status, the
cell-crossing is judged by the UE URA, and the location is
updated by URA UPDATE.
2) Mobility management policy in
the IDLE status
When the UE starts up, it will
carry out PLMN selection, cell selection and location
registration.
Upon the completion of the cell
selection, the cell re-selection will be carried out. If a
new cell is selected to stay, the
location registration will be carried out for the new
location area entry.
If access and immediate cell
evaluation are required, then initiate the access in the
optimized cell.
If the MS is in the CELL_DCH
status, the UE crosses the cell through the handover
flow.
3) Potential subscriber control
The stay cell selection by the MS
is determined by adjusting the parameters of the cell
reselection, so as to adjust the
cell load direction and achieve the load self-adaptive
adjustment.
2. Random access procedure
Random access procedure is a
process: A MS requests the access system, then the
network responses and allocates a
service channel to the MS. The random access is
carried out when the MS begins to
transmit power; or when synchronization loss for
some reasons occurs; or when
message packets should be transmitted. The random
access is fulfilled after
following steps are completed: 1) synchronization between the
code and frame; 2) search for the
cell parameters, such as the random access code; 3)
evaluation
of the downlink path loss and random access to the initial power level.
The optimal criterion for the
random access procedure is the process rate and the low
transmission power. The
requirement for the random access procedure speed is
determined by the requirement for
the initial synchronization time. The number of
access channels is depending on
the involved access load. In addition, it also will be
affected by the information transmitted
in the random access status. Too high
transmission power will reduce
the capacity of the CDMA system, and the transmit
power in the random access status
cannot be controlled by the fast closed loop power
control, so it is most important
to make the total transmit power in the random access
status minimum. If the initial
transmission power is lowest, there is a long time for the
access attempt. On the other
hand, the high transmission power in the initial access will
cause interference to other
subscribers during the fast synchronization. The least
information that needs to be
transmitted in the random access attempt is the identity
numbers of the MSs of some types.
A kind of typical random access information
includes the pre-field, the
synchronization and the data. The data should include at
least the MS identity number,
while the pre-field is the unmodulated wideband spread
spectrum signal.
3. Call Admission Control
Call Admission Control is a part
of the load management.
The call admission control
algorithm is used to accept new calls as many as possible
on the basis of ensuring the
existing QoS. Its principle is: Current Status of the Cell
Resources + Service Request ⇒
YES/NO.
The current status of the cell
resources is depending on the uplink interference and the
downlink load; while the
requested service is depending on the QoS.
4. SNRS migration
The structure shown in the left
figure may occur for some reasons, such as the
handover, cell update, URA
update, RRC reconnection and direct retry. To save Iur
interface resource and reduce the
time delay, it is required to migrate the Iu interface as
shown in Figure 7-8, that is,
SNRS migration. The SNRS migration may effectively
reduce
the traffic of the Iur interface and improve the adaptability of the system.
 |
SNRS migration |
Factors Affecting the Network Structure
1. Universal antenna and smart
antenna (narrow-beam antenna)
Smart antenna is widely used in
the WCDMA system. In some relevant articles, it is
also called self-adaptive antenna
or narrow-beam antenna.
The smart antenna adopts the
concept of SDMA, monitoring and extracting the space
information of every subscriber
via the self-adaptive array antenna. It separates the
signals of different directions
without any interference according to the differences of
the antenna array in the incident
signal direction. In fact, it makes the communication
resources are no longer
restricted by the time domain, the frequency domain and the
code domain, and extended to the
space domain.
The advantages of the smart
antenna are: The result of antenna beam forming is equal
to increase the gains of the
antenna; the antenna beam forming algorithm may take the
multi-path transmission into
consideration, avoiding the multi-path communication from
affecting the digital wireless
communication system with the performance enhanced;
the antenna beam forming greatly
reduces the multiple access interference. In this way,
the communication capacity can be
expanded in multiple. It also can improve the
channel multiplexing rate of the
communication system and the BS coverage area, and
solve the increasingly serious
interference problems (like common channel and
multi-path fading). In addition,
it can optimize the network structure.
2. The transmission models of
GSM, CDMA and WCDMA and the affects of radio
transmission on the system
structure
From the perspective of signal
transmission, in the same frequency band range, the
signals of the GSM, CDMA and
WCDMA transmitted in the space have the same
features, including the path
loss, the slow and fast fading from the transmitter to the
receiver.
However, the transmission
bandwidth in the WCDMA reaches 5M or more, so the
multi-path fading performance is
powerful. Its signal frequency band is far larger than
the relevant bandwidth of the
channel. The multi-path components may be separated,
making fully use of the
multi-path diversity receiving technology.
3. Parameters
The network planning structure is
realized by setting proper network engineering
parameters and the network
functional parameters. Different antenna gains, antenna
heights, antenna types, network
connection parameters, power control parameters,
handover parameters and service
rates are set for the cells of different layers of the
hierarchical
network.
4. Power control
The power control plays an
important role in the CDMA network performance and the
network capacity.
5. Coverage
The maximum cell coverage is
determined by the link budget. Besides the data rate
and the Eb/N performance, such
specific factors as the cable loss, the antenna gain
and the receiver noise should be
calculated. In addition, the affects of the soft handover
gain and asymmetric traffic
should be taken into consideration. Different service
coverage area has different
service rate requirements. The design basis of the
hierarchical network is as
follows:
Outdoor in the rural: Terminal
speed 250 kmph, 144 Kpbs at least, 384 Kpbs optimal
Outdoor in the urban or suburb:
Terminal speed 150 Kmph, 384 Kpbs at least, 512
Kpbs optimal
Indoor or outdoor with a small
area: Terminal speed 10 Km, 2 Mbps at least.
Real-time fixed time delay:
BER--, time delay 20-300 ms.
Non-real time variable time
delay: BER--, time delay 150 ms.
Erl/km2 may be adopted for in a
geometrical area. The data traffic may be Mbps/km2.
The BS adopts multi-subscriber
detection technology to provide a favorable coverage
and lower the transmit power of
the MS. The increase of the data rate will reduce the
coverage
area of the uplink. It differs from the narrowband system.
Radio Resource Planning
1. WCDMA frequency resource
The W-CDMA spectral efficiency is
related to the link performance. According to the
theoretical analysis and the
emulation, the uplink capacity is 2 to 2.5 times of the
downlink capacity. Besides the
antenna diversity in the BS, the uplink adopts the
multi-subscriber signal detection
technology, which provides almost two times capacity
than the common receiver. In the
downlink, two BSs transmit to the same MS the
signals, which are not
orthogonal, but only cause multi-path diversity. For the spectral
efficiency, the bandwidth of 15-
to 20-MHz is required for each cell to support an
effective
2-Mbps subscriber.
2. Relationship between the
resource planning and the network structure
The WCDMA carrier interval is 200
KHz, ranging from 4.2 MHz to 5.4 MHz. The carrier
intervals are adopted according
to the interference to obtain proper protection for the
neighboring channels. The
bandwidth of 15 MHz may be divided for the use of three
cells. The interval between
different operators may be longer to avoid interference
among
them.
3G Network Capacity Estimation
Introduction
In the WCDMA system, the capacity
of the uplink is lower that of the downlink, because
the BS has better receiving
technologies than the MS, such as the antenna diversity
and multi-subscriber detection.
In the UMTS, the downlink capacity is considered more
important than the uplink
capacity because the asymmetrical traffic is closely related to
download services. In the 3G,
more consideration is given to the downlink capacity. The
factors causing the differences
between the capacity uplink and the downlink capacity
are the orthogonal code and the
BS transmit diversity. WCDMA system adopts long
extended code to distinguish
cells in the downlink and subscribers in the uplink.
Downlink Orthogonal Code
The downlink orthogonal code will
affect the capacity, so it is considered to adopt
irregular short code, which is
orthogonal in the case of one path. Part of the
orthogonality will disappear in
case of multi-path, causing mutual interference among
the subscribers in the cell. In
the GSM system, there is no mutual interference in the
same cell, because the time
domain is orthogonal.
Link Budget
To estimate the maximum area of
the cell, it is required to carry out RLB ( Radio link
budget) calculation. In the RLB,
it is necessary to consider such factors as antenna
gain, cable loss, diversity gain
and fading margin. The RLB calculation result is the
maximum allowed transmission path
loss, based on which the cell radius and the
number of required sites may be
obtained. Compared with the TDMA-based radio
access system (like the GSM
system), the WCDMA system has some special problems
in the link budget, including
interference margin, fast fading margin, transmit power
increasing
and soft handover gain.
Capacity and Coverage Analysis
If the maximum allowable path
loss of a cell is known, it is easy to calculate the
coverage area of the cell with
the known transmission model. If the coverage area of
the cell is known, it is required
to select such sites as the channel elements, sector and
carrier frequency and site
density (cell radius) to configure, so as to satisfy the traffic
requirements. The cell radius is
also closely related to the number of access
subscribers. Therefore, the
coverage is correlative with the capacity, and the network
operator should know the
subscriber distribution and the growth trend, because it will
directly affect the coverage. The
network should be configured properly to meet the
traffic requirements and reduce
the network cost as much as possible. The number of
carrier frequencies, number of
sectors, cell load, number of subscribers and cell radius
will
affect the final result.
Soft Capacity
The number of required cells may
be calculated with the available spectrum,
subscribers amount forecast and
traffic density information. The traffic density is
indicated by erl. The calculation
is conditional on the given congestion. If the
congestion is caused by the
hardware, then the result may be obtained in Table B. If the
maximum capacity is caused by the
interference, then the capacity is defined as soft
capacity. For the system with
soft capacity restriction, it cannot be calculated with
Ireland Table. The total channel
capacity is larger than the average number of the
channels of each cell. The
neighboring cells share a part of interference, so more traffic
may be processed if the
congestions are the same. If the interference from the
neighboring cell is less, there
will be more available channels in the middle cell as
shown
in Figure
 |
Interference sharing in the WCDMA |
If the cell has few channels,
that is, there are high bit rate real-time subscribers, then
the average load should be reduced
to ensure low congestion. With the reduction of
average load, there is additional
capacity to be provided to the neighboring cell for use.
This part of capacity is borrowed
from the neighboring cell, so the interference sharing
provides soft capacity. It is
important for the high bit rate real-time subscribers to
connect
as shown in the figure.
The soft capacity depends on the
transmission environment (i.e. network planning).
The value of α is of great
importance, and determined by the equipment radio resource
management algorithm.
In the WVDMA system, all
subscribers share the interference source in the space
channel, so the analysis cannot
be conducted separately. The mutual affects among
subscribers result in the changes
of transmit power, which in turn cause further
changes and repeating mutual
affects. Forecast processing repeats unless it is stable.
In the WCDMA system, the
uplink/downlink fast power control, soft handover/softer
handover and orthogonal downlink
channels will affect its performance. Unlike the
GSM, the BS sensitivity is
depending on the number of subscribers and the rate of
subscribers. It is constant in
the GSM.
The interference planning and
capacity planning are even more important in the 3G.
Planning Conclusion
The WCDMA cell capacity (at full
load) is inversely proportional to the cell coverage
radius. Under certain I/C,
reducing the cell radius can improve the cell capacity.
Essentially, it is to offset the
cell capacity loss caused by the system noise. Reducing
the cell capacity can increase
the coverage radius. Of course, the coverage area
should be subject to the radio
coverage conditions. In the cell planning, it is required to
determine proper coverage radius
to meet the cell capacity requirements.
The cell coverage requirements
for the capacity in the urban and rural are different. In
the urban, there are many hot
areas and the unit area traffic demand is high. In such a
case, to solve the capacity problem
is a main task. Whereas, in the rural area, the traffic
demand is low and the main task
is to solve the coverage problem. The CDMA system
features soft capacity and can
satisfy this requirement.
The unit area capacity may be
improved by the cell splitting and multi-sector. Such
improvement may be realized
easier in the CDMA cell, which dynamically changes the
cell
coverage by controlling the pilot transmit power.
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