WCDMA RNP Radio Network Dimensioning Principle-20040719-A-1.1
WCDMA Capacity Dimensioning Procedure and Case Study
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Transcript of WCDMA Capacity Dimensioning Procedure and Case Study
Huawei Technologies Co
WCDMA Capacity Dimensioning Procedure and Case Study
Product name
WCDMA RNP
Product versionTotal 12 pages
1.2
WCDMA Capacity Dimensioning Procedure and Case StudyPrepared byUMTS RNPDate2007-11-28
Reviewed byDateyyyy-mm-dd
Reviewed byDateyyyy-mm-dd
Granted byDateyyyy-mm-dd
Huawei Technologies Co., Ltd.All rights reserved
Table of Contents 4WCDMA Capacity Dimensioning Procedure and Case Study
41Introduction
41.1Huawei capacity dimensioning procedure
52CS Capacity Dimensioning Principle and Example
52.1Uplink and downlink load factor per connection
52.2Calculation of CS load
62.3Case study
63PS Capacity Dimensioning Principle and Example
63.1Calculation of PS load
73.2Case study
84HSDPA Capacity Dimensioning Principle and Example
84.1HSDPA capacity dimensioning principle
84.2Case study
95HSUPA Capacity Dimensioning Principle and Example
95.1HSUPA Capacity dimensioning principle
95.2Case study
96Mixed Services Capacity Dimensioning
106.1Case study
WCDMA Capacity Dimensioning Procedure and Case StudyAbstractThis article presents an overview of WCDMA capacity dimensioning. The principle and procedure of capacity dimensioning for CS service and best effort for PS service is clearly depicted in the document.1 Introduction1.1 Huawei capacity dimensioning procedure
In order to perform capacity dimensioning for multiple CS services, Multidimensional ErlangB is used for CS services which considers resources sharing among CS services.Based on the cell target load and traffic profile, the number of subscribers supported by the cell at target load can be obtained. The procedure for mixed services capacity dimensioning is illustrated in figure 1, as shown below.
Figure1 Mixed services capacity dimensioning procedure2 CS Capacity Dimensioning Principle and Example2.1 Uplink and downlink load factor per connectionThe average uplink load factor of one connection for service:
1
The average downlink load factor of one connection for service:
2
: WCDMA chip rate.
: Bearer bit rate of the service.
: Average ratio of other cell to own cell base station power.
: Signal energy per bit divided by noise spectral density, required to meet a predefined Block error rate.
: Activity factor of the service.
: The average power consumed by one connection of the service.
: The maximum power of one cell.2.2 Calculation of CS load 1 Calculation of CS peak cell load
CS peak cell load can be calculated by multidimensional ErlangB algorithm. 2 Calculation of CS average cell load
According to CS traffic profile and the subscribers in the cell, we can easily obtain the average CS load in the cell.Traffic per cell of CS service:
3
CS average cell load in uplink:
4
CS average cell load in downlink:
In downlink the calculation of load should consider the ratio of SHO.
5
: The number of subscribers per cell
: The traffic per subscriber of CS service.
: Soft handover overhead including softer handover.
2.3 Case studyAssumptions:
Subscriber number per Cell: 1000
Voice traffic per user: 0.02Erl
VP traffic per user: 0.001Erl
Overhead of SHO (including softer handover): 40% Downlink target load: 90%
Maximum NodeB transmission power: 20W
GoS requirement of voice: 2%
GoS requirement of VP: 2% Uplink and downlink load factor of AMR12.2: 1.1873%, 0.9383%
Uplink and downlink load factor of CS64k:4.9901%, 5.2011%Then,Considering the load resources sharing between voice and VP, the total peak load needed by voice and VP in uplink is = 49.52%, in downlink is =55.83%Average load needed by voice in uplink is 1000*0.02*1.1873% = 23.74%, in downlink is 1000*0.02*(1+0.4)*0.9383%=26.27%Average load needed by VP in uplink is 1000*0.001*4.9901%=4.99%, in downlink is 1000*0.001*(1+0.4)*5.2011%=7.28%.
Total average load needed by voice and VP in uplink is
=23.74%+4.99%=28.73%,In downlink is =26.27%+7.28%=33.55%3 PS Capacity Dimensioning Principle and Example3.1 Calculation of PS load The following procedure shows how to calculate the PS average load.1 Calculation of PS average cell load for UL
(6)Where is the number of equivalent channels for service
(7)
: Throughput per user for service.
: PS data retransmission for service.
: PS burstiness ratio.2 Calculation of PS average cell load for DLCalculation of PS average cell load for DL is almost same as that for UL except that the impact on the load due to SHO should be considered in DL.3.2 Case studyAssumptions:
Subscriber number per cell: 1000UL PS64k throughput per user: 50kbit
DL PS64k throughput per user: 100kbit
DL PS128k throughput per user: 80kbit
Overhead of SHO (including softer handover): 40%
PS traffic burst is 20%
Retransmission rate of R99 PS services is 5%
Activity factor of PS is 0.9Uplink load factor of PS64k: 4.3072%
Downlink load factor of PS64k and PS128k: 3.3139%, 6.6454%Then,
Load for UL PS64k is
Load for DL PS64k is
Load for DL PS128k is
Total average downlink load needed by PS is 2.82%+2.26%=5.08%4 HSDPA Capacity Dimensioning Principle and Example
4.1 HSDPA capacity dimensioning principleFor HSDPA capacity dimensioning, average HSDAP cell throughput can be calculated based on available resources like power and codes for HSDPA and cell average radius. The following figure shows the procedure. Of course, the required power of HSDPA to guarantee HSDPA cell average throughput requirement can also be calculated.
Figure2 HSDPA capacity dimensioning procedure
4.2 Case studyAssumptions:
Subscriber number per cell: 1000
Traffic model of HSDPA is 1200kbit
HSDPA traffic burst is 25%
Retransmission rate of HSDPA is 10%
Then,
Target of HSDPA cell average throughput is
Based on the target HSDPA cell throughput and cell radius, the needed power for HSDPA including that for HS-SCCH is 10.37%5 HSUPA Capacity Dimensioning Principle and Example
5.1 HSUPA Capacity dimensioning principleSimilar with capacity dimensioning of HSDPA, average HSUPA cell throughput for input load or the load needed by HSUPA to achieve certain throughput can be calculated. The following figure shows the procedure of calculating HSUPA cell throughput from input load.
Figure3 HSUPA capacity dimensioning procedure
5.2 Case studyAssumption:
Subscriber number per cell: 1000
Traffic model of HSUPA is 700kbit
HSUPA traffic burst is 25%
Retransmission rate of HSUPA is 10%
Then,
Target of HSUPA cell average throughput is
Based on the target HSUPA cell throughput and cell radius, the needed load for HSUPA is 25.22%6 Mixed Services Capacity DimensioningPS service is the best effort service which is used in mixed services capacity dimensioning. Best effort means that the packet service can utilize the resource that is available, but there are no guarantees on blocking probability. Figure 4 illustrates the resource occupation by CS and PS services.
Figure4 Resource shared by CS and PS
According to the previous calculation we can obtain the actual total cell load by the formula:
When the actual total cell load equals to the cell target load, the number of subscribers is the capacity of one cell.6.1 Case studyBased on the assumption and calculation of previous case study, the total load can be obtained easily using the formula above (assuming downlink load for CCH is 20%):
=Max (49.52%, 28.73%+1.31%+25.22%) =55.26%
= Max (55.83%, 33.55%+5.08%+10.73%) +20%=75.83%User rate at distance r
EMBED Visio.Drawing.6
Ec/N0(R
Ec/N0
Cell Radius
HS-DPCCH load
R99 load
A-DCH load
HSUPA cell
throughput
Maximum rate of single user
HSUPA actual cell load
Uplink load
2007-11-28Page 1 , Total10
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