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1 © Nokia Siemens Networks <LE number and name>
Radio Access System OverviewRU10 Release
2 © Nokia Siemens Networks <LE number and name>
Nokia Siemens Networks Academy
Legal notice
Intellectual Property RightsAll copyrights and intellectual property rights for Nokia Siemens Networks training documentation, product documentation and slide presentation material, all of which are forthwith known as Nokia Siemens Networks training material, are the exclusive property of Nokia Siemens Networks. Nokia Siemens Networks owns the rights to copying, modification, translation, adaptation or derivatives including any improvements or developments. Nokia Siemens Networks has the sole right to copy, distribute, amend, modify, develop, license, sublicense, sell, transfer and assign the Nokia Siemens Networks training material. Individuals can use the Nokia Siemens Networks training material for their own personal self-development only, those same individuals cannot subsequently pass on that same Intellectual Property to others without the prior written agreement of Nokia Siemens Networks. The Nokia Siemens Networks training material cannot be used outside of an agreed Nokia Siemens Networks training session for development of groups without the prior written agreement of Nokia Siemens Networks.
3 © Nokia Siemens Networks <LE number and name>
Document change history
Draft – Updated to RU10Suriansyah1.014.04.2009
Change commentNameVersionDate
4 © Nokia Siemens Networks <LE number and name>
Content
• RAN Architecture and Interfaces• RAN Functionalities• NSN RAN Roadmaps• NSN RAN Solution• RAN Operation and Management
5 © Nokia Siemens Networks <LE number and name>
UMTS Generic ArchitectureCN
BSS
UE
UTRAN
PS-Domain
CS-Domain
RNS
EIR HSS
VLR
PDN/Internet
PDN/Internet
VLR
PSTNPSTN
Um
Uu
Abis
A
A
IuCS
Gb Gs
F D C
PSTN
Gf Gc
Gn
Gp
Nc
Mc Mc
Nb
PSTNNc E G
IuPS
Iur
USIM
IuCS
Gr
Gi
PSTN
PSTN
SIM
Cu
GERAN
BSCBTS
Node B
RNC SGSN
GGSN
MGW
MSS
MSS
MGW
GMSS
Iub
IMSIMSGo
Other PLMN
Other PLMN
BG
The general idea in UMTS is to harmonise the CN with GSM/GPRS as much as possible. This can be done since there is no major difference in how subscribers or charging are handled in both systems. Therefore, CN is constituted of a Circuit Switched (CS) domain and a Packet Switched (PS) domain which have the same main elements as is GSM/GPRS beside the CN common elements.The biggest change is in the UMTS Radio Access Network that introduces several new functions and a totally new air interface. The Radio Access Network is controlled by a Radio Network Controller (RNC), unlike the Base Station Controller (BSC) in a GSM network. In the 3GPP specification, the WCDMA BTS is referred to as Node B.
6 © Nokia Siemens Networks <LE number and name>
RAN Architecture and Interfaces
Iub
IurIu-BC
Iu-CS Iu-PS ADIF*
Iu-PC
O&M
MSS/MGW SGSNA-GPS Server
SASRNCRNCCBC
Node B
UE
Uu
RNS
* Proprietary interface
NetAct
WCDMA Radio Access Network (WCDMA RAN)WCDMA RAN consists of one or more Radio Network Subsystem (RNS) where each RNS is constructed by a Radio Network Controller (RNC) and its controlled Node Bs. The main function of WCDMA RAN is handling all radio-related functionalities and managing radio resources in a 3G network. In addition, WCDMA RAN also handles telecommunication management for Circuit-switched and Packet-Switched traffic in a 3G network.The standardised interface between RNCs is called Iur, and interface RNC – Node Bs is called Iub.
Core NetworkCore Network (CN) is responsible for routing calls, data connections or other defined services to external network as well as handling user mobility.RAN interface toward Switching Core Network (SCN) is called Iu-CS, and it is implemented by connecting RNC to MSC Server (MSS) for control plane and to Multimedia Gateway (MGW) for user plane.RAN interface toward Packet Core Network (PCN) is called Iu-PS, and it is implemented by connecting RNC to Serving GPRS Support Node (SGSN).RAN interface toward Cell Broadcast Center (CBC), for Cell Broadcast Service (CBS), is called Iu-BC.RAN interface toward Positioning Center (PC), for Location Service (LCS), is called Iu-PC. It is implemented by connecting RNC to Standalone SMLC (SAS).NSN also provides alternative solution for LCS, which is implemented by connecting RNC directly to A-GPS server. For this solution, the position calculation is done by RNC. The proprietary interface toward A-GPS server is called A-GPS Data Interface (ADIF)
7 © Nokia Siemens Networks <LE number and name>
RAN Architecture and Interfaces
Iub
IurIu-BC
Iu-CS Iu-PS ADIF*
Iu-PC
O&M
NetAct MSS/MGW SGSNA-GPS Server
SASRNCRNCCBC
Node B
UE
Uu
RNS
* Proprietary interface
Operation Support SystemOperations Support System (OSS) is common for both 2G and 3G networks. The same management system is used for managing both the network and the services provided. In the NSN 3G solution, NetAct Framework is used for this task. The O&M interface toward OSS, called Network Interface for 3rd Generation Network (NWI3), is a CORBA based interface.
8 © Nokia Siemens Networks <LE number and name>
RAN Functionalities
• Transfer user data• Functions related to overall system access control• Radio channel ciphering and deciphering• Functions related to mobility • Functions related to radio resource management and control• Synchronisation• Functions related to broadcast/multicast services• Tracing• Volume reporting• RAN information Management• Functions related to MBMS
3GPP TS 25.401
The following are RAN functionalities defined in 3GPP specification number TS 25.401. RAN may have more functions in newer release.
1. Transfer user data. This function provides user data transfer capability across the UTRAN between the Iu and Uu reference points.
2. Functions related to overall system access control (e.g. admission control, congestion control, system information broadcasting, etc.)
3. Radio channel ciphering and deciphering. This function is a pure computation function whereby the radio transmitted data can be protected against a non-authorised third-party.
4. Functions related to mobility (e.g. handover, SRNC relocation, positioning, NAS node selection function, shared network access control, etc.)
5. Functions related to radio resource management and control6. Synchronisation7. Functions related to broadcast/multicast services8. Tracing. This function allows tracing of various events related to the UE and its
activities.9. Volume reporting. This function is used to report the volume of unacknowledged data
to the CN for accounting purpose.10. RAN information Management. This function is a generic mechanism that allows the
request and transfer of information between two RAN nodes.11. Functions related to MBMS
9 © Nokia Siemens Networks <LE number and name>
Rel.7 Packet Switched Network
2G RAN
3G RAN
BSC
RNCSGSN
(combi)
CG
GGSN
LIG
BG
DNS
Inter-PLMN Network
Data Network (internet)
Customer Billing Network
Corporate customer network
Common Packet Core
Infrastructure
Common Service Platforms
Common Network Management
Firewall
IP backbone
Mobile ISP
Radio Access Network access the PS Core network through SGSN. With the introduction of Combi SGSN, both 2G and 3G RAN are connected to the same network element in the PS Core Network. The implementation of Iu-PS over IP in RU10 allows the RNC to be directly connected to IP backbone.
10 © Nokia Siemens Networks <LE number and name>
Functionalities Split Between Network Elements
XXReal-time MultimediaXXIP TelephonyXXHigh Capacity Routing
X**XMobility ManagementXX*CompressionXX*CipheringXX*Radio Protocol to IP conversionXXGTP Tunnelling
XXXInterface toward OSSXCharging and StatisticsXInteraction with HLR, MSC/VLRXAuthentication
BSCRNCSGSNFunctionality
* in case of 2G RAN** URA concept
Some functionalities in handling packet data traffic are shifted from SGSN to RNC, e.g. Radio Protocol to IP conversion, Ciphering and Compression. Another packet data handling function, i.e. GTP tunnelling is implemented between RNC – SGSN, besides SGSN –GGSN.The ciphering is done in RLC layer of radio interface protocol, while IP packet compression is handled by PDCP layer. The RAN also has mobility concept which is implemented by UTRAN Registration Area (URA) to support packet data operation.
11 © Nokia Siemens Networks <LE number and name>
Radio Resource Management
DRNCNode B
UE
SRNCNode B
CRNC functionsAdmission ControlLoad ControlResource Manager
SRNC functionsPacket Scheduler Power ControlHandover Control
Iub
Iur
Iub
Power Control, packet scheduler
Power Control, packet scheduler
Cell Capacity
Cell Coverage Service Quality
Optimizationand Tailoring
The goal of Radio Resource Management (RRM) is to ensure that the radio network capacity is used as efficiently as possible, i.e. radio access network offers high capacity, maintains the planned coverage area and the required quality of service. In WCDMA, the radio resources are defined in terms of transmission power, received wideband power, logical codes, BTS HW, Iub/Iur transport, and RNC HW.To achieve the goal, RRM algorithms are implemented on the RAN Network Elements. They are:
• Cell-based algorithms, i.e. Admission Control (AC), Packet Scheduler (PS), Load Control (LC) and Resource Manager (RM).
• Connection-based algorithms, i.e. Power Control (PC) and Handover Control (HC)In case of HSPA connection, the packet scheduler is shifted to Node B
12 © Nokia Siemens Networks <LE number and name>
NSN RAN 3G Roadmap
HSPA+ Release
HSDPA 28 MbpsHSUPA 11.5 Mbps CS-voice over HSPAAdv. FDE ReceiverFlexi Multiradio BTS3.5 Gbps RNC
HSPA+ Release
HSDPA 84 MbpsHSUPA 23 Mbps <100ms call set-upLTE InterworkingGigabit Flexi BTS 35 Gbps RNC Evolution
HSPA Streaming QoSHSPA Multi NRT RABsCommon Iub
I-HSPA Rel.1 – Rel.2CS Enabling HandoverBTS Sharing
3G Femto Rel.1
HSDPA 42 Mbps (Dual-Cell HSDPA / 64QAM + MIMO)
High Speed Cell_FACH (UL)Flexible RLC in UL
I-HSPA Rel.43G Femto Rel.3
Fast Inter-System HandoverMulti-Band HSDPA AggregationSelf Optimising Backhaul
I-HSPA Rel.53G Femto Rel.4
HSDPA 14 MbpsAll-IP ConnectivityFlat ArchitectureQuality of ServiceLTE- ready Flexi BTS2.8 Gbps RNC
HSDPA 21 Mbps (64QAM) HSUPA 5.8 MbpsFlexible RLC in DLContinuous Packet ConnectivityMBMS BroadcastHigh Speed Cell_FACH (DL)HSPA Conversational QoSSynchronous EthernetConcurrent Mode Multiradio BTS
I-HSPA Rel.33G Femto Rel.2
2008 2009 20102007 Q1/2010 Q1/2011 Q1/201204/2009
RU10Ready for Contract
RU20Under Planning
RU30Study Items
RU40Research Items
HSPA+ Release
Higher Bit RatesMulti-carrier HSPAActive Antenna System2ms TTI UL Range
Extension Local Break-Out
The key drivers of NSN WCDMA/HSPA evolution are:• Best user experience with the leading HSPA capability and evolution e.g. 40% lower
latency, real service differentiation (QoS) and extended terminal battery use time• Lowest Total Cost of Ownership (TCO). Typically 20-30% less sites and less site cost
with Flexi BTS. Flexi BTS SW upgradeable radio, baseband, and transport reduces site visits 50-90%. Most cost efficient RNC and unique Flat Architecture option with I-HSPA data network. Leading WCDMA 900MHz refarming solution with unique 4.2MHz carrier bandwidth and with faster and more accurate planning with NetAct Optimizer.
• Greenest 3G network with lowest power consumption and typically 70% lower CO2 emissions
• Shortest time to revenue with Flexi BTS true SW upgradeability.
13 © Nokia Siemens Networks <LE number and name>
All-IP Connectivity Solution in RU10
• Provides 3GPP compliant IPv4 transport option for all RNC interfaces
• Allows to use IP and/or Ethernet connectivity from RNC towards to
– core networks (Iu-CS and Iu-PCS), – other RNCs (Iur) and – base stations (Iub)
• New features available are:– Gigabit Ethernet Interfaces (optical
and electrical)– IP based Iu-PS, IP based Iu-CS– IP based Iur– IP based Iub
Iub/IP Iu-PS/IP
Iur/IPIu-CS/IP
3G BTS
3G BTS
RNC
RNC
MGW
SGSN
Ethernet
Iu-CS/IP
IPSCTPM3UASCCP
RANAP
UDP
RTP
Iu User PlaneIu-CS Control Plane Iu-CS User Plane
RTCP
Ethernet
Iu-PS/IP
IPSCTPM3UASCCP
RANAP
UDP
GTP-U
Iu User PlaneIu-PS Control Plane Iu-PS User Plane
Ethernet
Iur/IP
IPSCTPM3UASCCP
RNSAP
UDP
RTP
FP LayerIur Control Plane Iur User Plane
RTCP
Ethernet
Iub/IP
IPSCTP
NBAP
UDP
FP LayerIub Control Plane Iub User Plane
14 © Nokia Siemens Networks <LE number and name>
C-Iub: S-NB Operability in N-RNC
• This feature defines the basic O&M functions in the common NBAP interface
– BTS initialization– BTS logical resource management– BTS and RNC recovery Iub
NB/RSxxx RNC
15 © Nokia Siemens Networks <LE number and name>
PS RAB Reconfiguration
• PS RAB parameters can be reconfigured.
• It allows the deployment of single APN and UEs.
• The usage of network resources is optimized when the QoSparameters in the network are aligned with the QoSrequirements of the service.
UE BTS
RNC
Core network
RAB Assignment Request
RAB Assignment Response
Interactive to background or vice versa
RAB parameters– Traffic class
– Maximum bit rate
– THP
– ARP
Upgraded or downgraded
SGSN or UE can request the RAB reconfiguration procedure if there is a need to modify the characteristics of a RAB service. To the RAN the reconfiguration is triggered by the CN with a RAB Setup message requesting reconfiguration of the existing RAB. The following RAB parameters can be changed for the interactive and background traffic class RABs:
• Traffic class interactive <-> background • Maximum bit rate (UL/DL) • Change of Traffic Handling Priority (THP) of an interactive RAB • Change of Allocation and Retention Priority (ARP)
RNC reconfigures the RNC and BTS with the new RAB/SPI parameters after receiving the RAB reconfiguration request from CN.
16 © Nokia Siemens Networks <LE number and name>
HSPA Solution
HSDPA 64 users / cell HSUPA 60 users / bts
64 users
64 users64 users
64 users
60 users
17 © Nokia Siemens Networks <LE number and name>
I-HSPA Architecture and Interface
Iur C
Direct TunnelSGSN
GGSN
Gn U
Gn C
Iu-ps C
Uu
Iu-ps C Gn U
C-plane
U-plane
3GPP Rel5 or laterHSPA terminal
3GPP open air interface
3GPP open network interface
• I-HSPA is a simplified flat architecture network• Standard 3GPP packet core• RNC HSPA functionality integrated to Node B• Standard 3GPP HSPA terminal
I-HSPA is part of 3GPP R7 HSPA Evolution Work Item. It specifies• Flat PaCo: Direct Tunnel defined in SA WG2, for removing SGSN from the U-plane• Flat RAN: HSPA Evolution TR25.999 defines BTS collapsed RNC• RNC ID extension from 4096 to a higher value to allow large I-HSPA network
18 © Nokia Siemens Networks <LE number and name>
NSN Radio Access Solution
NSN provides Radio Access solution:• Radio Network Controller (RNC)• Base Station• Transmission and Transport Solution• RAN Operation and Management
19 © Nokia Siemens Networks <LE number and name>
NSN Radio Network Controller
RNAC
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4
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3
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2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
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1
RNBC
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38
4
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1
TSS
3
MXU
0
MXU
1
SFU
0
NPS
1(P)
/ NPG
E(P)
0
RSM
U 0
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CU
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MC
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HD
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MXU
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S)
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EHU
ICSU
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11
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4
ICSU
7
ICSU
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SU 6
DM
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8D
MC
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10
DM
CU
12
PD30
NPS
1(P)
/ NPG
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MXU
6
MXU
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1(P)
/ NPG
E(P)
3IC
SU 1
3
ICSU
8
DM
CU
16
ICSU
9IC
SU 1
0IC
SU 1
1IC
SU 1
2
DM
CU
17
DM
CU
13
DM
CU
14
DM
CU
15
PD30
NPS
1(P)
/ NPG
E(P)
13
MXU
14
MXU
15
NPS
1(P)
/ NPG
E(P)
11
ICSU
33
ICSU
32
ICSU
37
DM
CU
36
ICSU
35
ICSU
34
ICSU
36
DM
CU
33
DM
CU
34
DM
CU
35
DM
CU
37
PD30
MXU
12
MXU
13
NPS
1(P)
/ NPG
E(P)
12
NPS
1(P)
/ NPG
E(P)
10
ICSU
27
ICSU
26
ICSU
31
DM
CU
31
ICSU
29
ICSU
28
ICSU
30
DM
CU
28
DM
CU
29
DM
CU
30
DM
CU
32
PD30
NPS
1(P)
/ NPG
E(P)
9
MXU
10
MXU
11
NPS
1(P)
/ NP
GE(
P) 7
ICSU
21
ICSU
20
ICSU
25
DM
CU
23
DM
CU
26
ICSU
23
ICSU
22
ICSU
24
DM
CU
24
DM
CU
25
DM
CU
27
PD30
MXU
8
MXU
9
NPS
1(P)
/ NPG
E(P)
8
NPS
1(P)
/ NPG
E(P)
6
ICSU
15
ICSU
14
ICSU
19
DM
CU
21
ICSU
17
ICSU
16
ICSU
18
DM
CU
18
DM
CU
19
DM
CU
20
PD30
DM
CU
22
TBU
FTS
S3TS
S3TB
UF
TBU
FTB
UF
TBU
FTB
UF
TBU
FTB
UF
TBU
FTB
UF
TBU
FTB
UF
TBU
FTB
UF
CPD80-B 0 CPD80-B 1 CPD80-B 0 CPD80-B 1
DM
CU
MXU
7
MXU
6
DM
CU
DM
CU
DM
CU
ICS
U
DM
CU
DM
CU
A2S
U
PD20
TBU
FT
BUF
1
NIP
1 4
NIP
1 5
ICSU
GT
PU
ICSU
DM
CU
DM
CU
DM
CU
MX
U 9
MX
U 8
DM
CU
DM
CU
DM
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DM
CU
DM
CU
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PD2
0
TBU
FTB
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2
NIP
1 6
NIP
1 7
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U
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U
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CU
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CU
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11
MXU
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CU
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U
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PD20
TBU
FT
BUF
3
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1 8
NIP
1 9
ICSU
GT
PU
ICSU
DM
CU
DM
CU
DM
CU
MX
U 1
3
MX
U 1
2
DM
CU
DM
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DM
CU
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PD2
0
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UF
4
NIP
1 1
0
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1 1
1
ICS
U
GTP
U
ICS
U
DM
CU
DM
CU
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
Opt
iona
l ES
A24
ESA
12 /
ESA
24
NIS
1P 4
NIS
1P 5
MXU
0
RSM
U 0
SFU
0
NE
MU
OM
U 0
WD
U 0
(O
MU
)
PD
20
ESA
24
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1
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)
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4
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1 3
ICS
U
ICS
U
GT
PUG
TPU
NIS
x 2
NIS
x 3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
HD
D 0
(NE
MU
) H
DD
1
(NEM
U)
TSS3
-IC
SU
TSS3
RR
MU
0R
RM
U 1
NIS
1P 6
NIS
1P 7
NIS
x 0
NIS
x 1
RRMU removed. Release plug-in unit configured as ICSU.
RR
MU
0R
RM
U 1
ICS
UIC
SU
RNC196 CS1-5
Opt
iona
l ESA
24
ESA
12 /
ESA
24
NIS
x 4
NIS
x 5
MX
U 0
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0
SFU
0
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U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
1
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(OM
U)
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TBU
F
2
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A2S
U
MXU
1
RSM
U 1
SFU
1
OM
U 1
WD
U 1
(O
MU
)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
HD
D 0
(NE
MU)
H
DD
1 (N
EM
U)
TSS
3TS
S3
NIS
x 6
NIS
x 7
NIS
x 0
NIS
x 1
RR
MU
0R
RMU
1IC
SU
ICSU
RNC196 CS1-5
Opt
iona
l ESA
24
NIS
1P 6
NIS
1P 4
NIS
1P 5
NIS
1P 7
SFU
0
A2S
U
NIS
x 0
SFU
1
NIS
x 1
NPG
EP
2
NPG
EP
0N
PGEP
1
NPG
EP 3
NPS
1P 2
NP
S1P
3
RR
MU
0R
RMU
1-
-
GTP
UG
TPU
NIS
x 2
NIS
x 3
NP
GEP
4N
PGEP
5
ICSU
ICSU
GTP
UG
TPU
GTP
UG
TPU
ICSU
ICS
UIC
SUIC
SU
CPD80-B 0 CPD80-B 1 CPD80-B 0 CPD80-B 1
DM
CU
MXU
7
MXU
6
DMC
U
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2S
U
PD20
TBU
FTB
UF
1
ICSU
GTP
U
ICSU
DM
CU
MXU
9
MXU
8
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CU
DM
CU
DM
CU
ICS
U
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CU
A2S
U
PD20
TBU
FTB
UF
2
ICSU
GTP
U
ICSU
DM
CU
MX
U 1
1
MX
U 1
0
DM
CU
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2SU
PD
20
TBUF
TBUF
3
ICSU
GTP
U
ICSU
DM
CU
MXU
13
MXU
12
DM
CU
DM
CU
DM
CU
ICSU
DMC
U
DM
CU
A2SU
PD2
0
TBU
FTB
UF
4
ICS
U
GTP
U
ICS
U
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
MX
U 0
RS
MU
0
RR
MU
0
SFU
0
NEM
U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
1
PD20
TBU
F
2
DM
CU
MX
U 3
MX
U 2
DM
CU
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2SU
EHU
PD
20
TBUF
TBUF
3
A2S
U
ICSU
ICSU
MXU
1
RSM
U 1
RRM
U 1
SFU
1
OM
U 1
WD
U 1
(O
MU
)
DM
CU
MXU
5
MXU
4
DM
CU
DM
CU
DM
CU
ICSU
DMC
U
DM
CU
A2SU
PD2
0
TBU
FTB
UF
4
ICS
U
ICS
U
GTP
UG
TPU
NIS
x 2
NIS
x 3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
HD
D 0
(NE
MU)
TSS
3TS
S3
Opt
iona
l ESA
24
A2S
U 7
A2SU
8
MX
U 0
MXU
14
MXU
15
ESA
12 /
ESA
24
MX
U 1
NIS
1P 1
NIS
1P 0
ICSU
6
DM
CU 2
6
DM
CU 2
7
DM
CU
18
DM
CU
19
ICSU
19
ICS
U 2
0
ICS
U 2
1
GTP
U 6
GTP
U 7
--
- -
-
DMC
U 4
3D
MC
U 3
5D
MC
U 2
5
Opt
iona
l NIP
1 0
- DMC
U 4
2D
MC
U 3
4
--- -
NIS
1P 6
NIS
1P 4
NIS
1P 5
NIS
1P 7
NIS
1P 1
0
NIS
1P 8
NIS
1P 9
NIS
1P 1
1
EHU
B: H
DD
1
(NE
MU
)
A: W
DU
1
(OM
U)
B: H
DD
0 (N
EMU
)
A: W
DU 0
(O
MU
)
A2S
UA2
SU
DM
CU
DM
CU
DM
CU
DM
CU
MX
U 0
NEM
U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
PD20
TBU
F
EHU
MXU
1
OM
U 1
WD
U 1
(O
MU
)
38
HD
D 0
(NE
MU)
TSS
3TS
S3
MX
U 0
MXU
14
MXU
15
ESA
12 /
ESA
24
MX
U 1
ICSU
ICSU
ICS
U
ICS
U
GTP
U
EHU
B: H
DD
1
(NE
MU
)
A: W
DU
1
(OM
U)
B: H
DD
0 (N
EMU
)
A: W
DU 0
(O
MU
)
Opt
iona
l ESA
24A2
SU
RS
MU
0R
SMU
1
SFU
0S
FU 1
RR
MU
0R
RMU
1IC
SU
ICSU
1
2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
RNC196 CS6-7
RRMU removed. Release plug-in unit configured as ICSU.
RNAC
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
4
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1
RNBC
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
4
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1
MXU
5
MXU
4
A2SU
DM
CU
PD30
ICSU
ICSU
MXU
7
MXU
6
A2SU
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
PD30
ICS
U
NIS
1P /
NIS
1 0
NIS
1P /
NIS
1 1
NIS
1P /
NIS
1 2
NIS
1P /
NIS
1 3
GTP
UG
TPU
ICS
U
DMC
U
DMC
U
ICSU
DM
CU
DM
CU
DM
CU
DM
CUDM
CU
MXU
13
MXU
12
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
PD30
ICSU
GTP
U
ICSU
MXU
15
MXU
14
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
DM
CU
PD30
ICS
U
GTP
U
ICS
U
DM
CU
--
DM
CU
DM
CU
A2SU
A2SU
DM
CU
DM
CU
NIS
1P 9
NIS
1P 1
1N
IS1P
/ N
IS1
10
MXU
9
MXU
8
DM
CU
DM
CU
ICS
U
DM
CU
DM
CU
PD30
ICSU
GT
PU
ICSU
MXU
11
MXU
10
DM
CU
-ICS
U
DM
CU
DM
CU
PD30
ICSU
GTP
U
ICSU
GT
PU
NIS
1P 5
DM
CU
NIS
1P /
NIS
1 4
--
DM
CU
DM
CU
A2S
UA
2SU
DM
CU
DM
CU
NIS
1P 7
NIS
1P /
NIS
1 6
MX
U 0
SFU
0
OM
U 0
PD
30
ESA
24
PD3
0
DM
CU
DM
CU
MXU
2
SFU
1
OM
U 1
DM
CU
DM
CU
A2SU
B: H
DD 1
NE
MU
Opt
iona
l ESA
24
MXU
3
EHU
MX
U 1
RSM
U 0
RR
MU
0
RSM
U 1
RR
MU
1
A2SU
A2SU
GTP
U
A: W
DU
1 O
MU
ICSU
ICS
U
ICSU
ICS
U
NIS
1P /
NIS
1 8
NIS
1P /
NIS
1 5
NIS
1P /
NIS
1 4
/
(Opt
. NIP
1)
DM
CU
DM
CU
B: H
DD
0 N
EMU
A2S
U
A: W
DU 0
OM
U
OM
S
TBU
FTB
UF
TBU
FTB
UF
TBU
FTB
UFTB
UF
TBUF
TBUF
TSS
3TB
UFT
BUF
TBUF
TBU
FTB
UFTS
S3
TSS
3
RR
MU
0R
RM
U 1
ICSU
ICS
U
RRMU removed. Release plug-in unit configured as ICSU.
RNC196 RNC196/300
RNC450 RNC2600
Opt
iona
l ESA
24
ESA
12 /
ESA
24
NIS
x 4
NIS
x 5
MX
U 0
RS
MU
0
SFU
0
NEM
U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
1
FDU
(OM
U)
PD20
TBU
F
2
EHU
A2S
U
MXU
1
RSM
U 1
SFU
1
OM
U 1
WD
U 1
(O
MU
)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
HD
D 0
(NE
MU)
H
DD
1 (N
EM
U)
TSS
3TS
S3
NIS
x 6
NIS
x 7
NIS
x 0
NIS
x 1
RR
MU
0R
RMU
1IC
SU
ICSU
RNC196 CS1-5
Opt
iona
l ESA
24
NIS
1P 6
NIS
1P 4
NIS
1P 5
NIS
1P 7
SFU
0
A2S
U
NIS
x 0
SFU
1
NIS
x 1
NPG
EP
2
NPG
EP
0N
PGEP
1
NPG
EP 3
NPS
1P 2
NP
S1P
3
RR
MU
0R
RMU
1-
-
GTP
UG
TPU
NIS
x 2
NIS
x 3
NP
GEP
4N
PGEP
5
ICSU
ICSU
GTP
UG
TPU
GTP
UG
TPU
ICSU
ICS
UIC
SUIC
SU
CPD80-B 0 CPD80-B 1 CPD80-B 0 CPD80-B 1
DM
CU
MXU
7
MXU
6
DMC
U
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2S
U
PD20
TBU
FTB
UF
1
ICSU
GTP
U
ICSU
DM
CU
MXU
9
MXU
8
DM
CU
DM
CU
DM
CU
ICS
U
DM
CU
A2S
U
PD20
TBU
FTB
UF
2
ICSU
GTP
U
ICSU
DM
CU
MX
U 1
1
MX
U 1
0
DM
CU
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2SU
PD
20
TBUF
TBUF
3
ICSU
GTP
U
ICSU
DM
CU
MXU
13
MXU
12
DM
CU
DM
CU
DM
CU
ICSU
DMC
U
DM
CU
A2SU
PD2
0
TBU
FTB
UF
4
ICS
U
GTP
U
ICS
U
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
MX
U 0
RS
MU
0
RR
MU
0
SFU
0
NEM
U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
1
PD20
TBU
F
2
DM
CU
MX
U 3
MX
U 2
DM
CU
DM
CU
DM
CU
ICSU
DM
CU
DM
CU
A2SU
EHU
PD
20
TBUF
TBUF
3
A2S
U
ICSU
ICSU
MXU
1
RSM
U 1
RRM
U 1
SFU
1
OM
U 1
WD
U 1
(O
MU
)
DM
CU
MXU
5
MXU
4
DM
CU
DM
CU
DM
CU
ICSU
DMC
U
DM
CU
A2SU
PD2
0
TBU
FTB
UF
4
ICS
U
ICS
U
GTP
UG
TPU
NIS
x 2
NIS
x 3
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
HD
D 0
(NE
MU)
TSS
3TS
S3
Opt
iona
l ESA
24
A2S
U 7
A2SU
8
MX
U 0
MXU
14
MXU
15
ESA
12 /
ESA
24
MX
U 1
NIS
1P 1
NIS
1P 0
ICSU
6
DM
CU 2
6
DM
CU 2
7
DM
CU
18
DM
CU
19
ICSU
19
ICS
U 2
0
ICS
U 2
1
GTP
U 6
GTP
U 7
--
- -
-
DMC
U 4
3D
MC
U 3
5D
MC
U 2
5
Opt
iona
l NIP
1 0
- DMC
U 4
2D
MC
U 3
4
--- -
NIS
1P 6
NIS
1P 4
NIS
1P 5
NIS
1P 7
NIS
1P 1
0
NIS
1P 8
NIS
1P 9
NIS
1P 1
1
EHU
B: H
DD
1
(NE
MU
)
A: W
DU
1
(OM
U)
B: H
DD
0 (N
EMU
)
A: W
DU 0
(O
MU
)
A2S
UA2
SU
DM
CU
DM
CU
DM
CU
DM
CU
MX
U 0
NEM
U
OM
U 0
WD
U 0
(O
MU
)
PD20
ESA
24
TBU
FT
SS3
PD20
TBU
F
EHU
MXU
1
OM
U 1
WD
U 1
(O
MU
)
38
HD
D 0
(NE
MU)
TSS
3TS
S3
MX
U 0
MXU
14
MXU
15
ESA
12 /
ESA
24
MX
U 1
ICSU
ICSU
ICS
U
ICS
U
GTP
U
EHU
B: H
DD
1
(NE
MU
)
A: W
DU
1
(OM
U)
B: H
DD
0 (N
EMU
)
A: W
DU 0
(O
MU
)
Opt
iona
l ESA
24A2
SU
RS
MU
0R
SMU
1
SFU
0S
FU 1
RR
MU
0R
RMU
1IC
SU
ICSU
1
2
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
RNC196 CS6-7
RRMU removed. Release plug-in unit configured as ICSU.
RNC196/450
New delivery in RU10/RN4.0 release
Basic new delivery configuration steps in RN4.0 are: • RNC2600/900, configuration for capacity step 1• RNC2600/1450 ,configuration for capacity step 2• RNC2600/2000, configuration for capacity step 3
Feature upgrade configuration steps in RN4.0 are:• RNC196/196 configuration for RNC196 capacity step 1-5• RNC196/300 configuration for RNC196 capacity step 6• RNC196/450 configuration for RNC196 capacity step 7• RNC450/150 configuration for RNC450 capacity step 1• RNC450/300 configuration for RNC450 capacity step 2• RNC450/450 configuration for RNC450 capacity step 3
20 © Nokia Siemens Networks <LE number and name>
RNC2600
• With full configuration:• Total Iub throughput 2839
(DL+UL)• 2800 carriers or Node Bs
connectivity• 20000 Erl Iu capacity
• Full load sharing, regardless cabinet or subrack
• Scalability through hardware configuration and capacity licensing
• Upgrade path is available for RNC450
• Upgradeable to support RU20
21 © Nokia Siemens Networks <LE number and name>
Nokia Siemens Networks WCDMA Base Station
MetroSite
FlexiBTS
UltraSite
3G MetroSite
MetroSite50
Optima Indoor
Flexi WCDMA
BTS
Optima Compact Outdoor
Supreme Indoor
Supreme Outdoor Triple Mode
@vantage Node B
NB880 (indoor)
22 © Nokia Siemens Networks <LE number and name>
Flexi WCDMA BTS Rel.2 HW
• Flexi BTS multimode system module is also prepared for LTE evolution with a SW upgrade.
• High capacity system module– FSMC with 180 CEs– FSMD with 396 CEs
• Can be used as capacity extension for Rel.1 HW (FSMB)
• Transmission sub module FTIB to support All-IP transport and Timing over Packet (TOPA)
• FRGF, triple RF Modules, support configuration:
– 2+2+2@30W or 20W– 1+1+1@40W or 60W.
23 © Nokia Siemens Networks <LE number and name>
RAN Transmission and Transport
SDH/PDH
ATM
IP IPATM
WBTS
WBTS
RNC
OSS
Ethernet
OAM
CoCo
MGW
SGSN
WBTS
RAN supports different transport solution, i.e. ATM and IP. Both types are possible to be used independently for signalling or user plane, even used toward the same network element in RAN (called hybrid transport)
24 © Nokia Siemens Networks <LE number and name>
• Standalone AXC (S-AXC) is ATM transmission node.
• One subrack (on the figure) supports 2 x 1.2 Gbps of switching capacity.
• Various interface unit are available
Transmission and Transport Solution
• Short to long hop length• Various frequency band: 6, 7, 8, 13,
15, 18, 23, 26, 28, 32, 38 and 58 GHz• PDH radio• SDH radio (PowerHopper)• Various indoor unit type: FIU19, IFUE
or FXC-RRI• Flexbus interface
PowerHopper FlexiHopper
Standalone AXC
25 © Nokia Siemens Networks <LE number and name>
NetAct® Framework
Reporter
Network
Administrator
3rd party tools
Rating & Charging
Unified Mediationand Adaptation
Service QualityManager
Monitor
Configurator & Provisioning
Planner
Workflow Manager
2G GPRS3GEDGE1GFixed NW
4G
The new NSN OSS product architecture provides a lot of benefits to the service provider. The separation of the element management from network and service management allows for fast adaptation to new network technologies and new releases of network elements. This kind of architecture is capable of supporting any combination of network technologies. The main principle is that current and new systems and applications can co-exits smoothly in the same network.
Highlights of the NetAct Framework:1. 3rd party tools: Building blocks allow the use of 3rd party products as an integrated part
of OSS.2. Common Network Topology: Access to OSS data is available through open interfaces.
This enables the integration to other OSS/IT systems.3. The use of a CORBA (Common Object Request Broker Architecture) based message
bus allows peer-to-peer communication within the OSS.4. Common WEB-GUI (Graphical User Interface):
• user access via Web interface• application location transparent to the users• all user interface applications work on network level
5. Management applications are developed separately as system components which are based on operator processes.
26 © Nokia Siemens Networks <LE number and name>
Top Level User Interface
•Presents a graphical, hierarchical view of the network or part of the network •General alarm situation of managed objects can be viewed. •Uses pop-up menus for a variety of applications•Activates also other Nokia NetAct applications. •The users can easily create and tailor the view hierarchy as well as the contents of the views.
27 © Nokia Siemens Networks <LE number and name>
RAN Configuration Management
Radio AccessNetwork
Radio networkplanning tool
3rd partyplanning
tool
CM Plan Manager:Import & Export Plans
Plan management in NetAct
CM Editor:Edit Plans
Radionetworkplanning
CM Provisioner:Activate &Download Plans
NetAct providesa web site forRNW plans:• Storage• Edit• Download, activate and
rollback• Upload actual
configuration
RNW planin XMLformat
WBTS
MGWWBTS
WBTS
RNC
OSS Database
Nokia NetAct Planner
intranetCM Editor:Edit Plans
The NetAct solution supports the capability to plan the RAN with NetAct Planner or a 3rd
party planning tool. The plan is transferred to NetAct electronically and the planned parameters, settings and software are downloaded to the actual network equipment.Storing the plan for later use is also possible.
The main advantages of the NSN tools for RAN network development are:• Faster planning and implementation of network coverage provides for an early launch
of service.• Less manual work and site visits are required to put parameters into network
elements. This results in fewer errors and an improved effectiveness.• Optimised infrastructure investments and improved network quality can be achieved
by analysing the network behaviour, performance and usage.