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index of reproduced Figures for  TS 23.501  version:  16.0.2

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all figures have been reproduced; each entry links to the figure within the Table of Contents


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[001]  Figure 4.2.3-1
5G System architecture
[002]  Figure 4.2.3-2
Non-Roaming 5G System Architecture in reference point representation
[003]  Figure 4.2.3-3
Applying non-roaming 5G System architecture for multiple PDU Session in reference point representation
[004]  Figure 4.2.3-4
Applying non-roaming 5G System architecture for concurrent access to two (e.g. local and central) data networks (single PDU Session option) in reference point representation
[005]  Figure 4.2.3-5
Non-roaming architecture for Network Exposure Function in reference point representation
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[006]  Figure 4.2.4-1
Roaming 5G System architecture - local breakout scenario in service-based interface representation
[007]  Figure 4.2.4-3
Roaming 5G System architecture - home routed scenario in service-based interface representation
[008]  Figure 4.2.4-4
Roaming 5G System architecture - local breakout scenario in reference point representation
[009]  Figure 4.2.4-6
Roaming 5G System architecture - Home routed scenario in reference point representation
[010]  Figure 4.2.4-7
NRF Roaming architecture in reference point representation
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[011]  Figure 4.2.5-1
Data storage architecture for unstructured data from any NF
[012]  Figure 4.2.5-2
Data storage architecture
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[013]  Figure 4.2.8.2.1-1
Non-roaming architecture for 5G Core Network with untrusted non-3GPP access
[014]  Figure 4.2.8.2.1-2
Non-roaming architecture for 5G Core Network with trusted non-3GPP access
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[015]  Figure 4.2.8.2.2-1
LBO Roaming architecture for 5G Core Network with untrusted non-3GPP access - N3IWF in the same VPLMN as 3GPP access
[016]  Figure 4.2.8.2.2-2
LBO Roaming architecture for 5G Core Network with untrusted non-3GPP access - N3IWF in a different PLMN from 3GPP access
[017]  Figure 4.2.8.2.2-3
LBO Roaming architecture for 5G Core Network with trusted non-3GPP access using the same VPLMN as 3GPP access
[018]  Figure 4.2.8.2.2-4
LBO Roaming architecture for 5G Core Network with trusted non-3GPP access using a different PLMN than 3GPP access
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[019]  Figure 4.2.8.2.3-1
Home-routed Roaming architecture for 5G Core Network with untrusted non-3GPP access - N3IWF in the same VPLMN as 3GPP access
[020]  Figure 4.2.8.2.3-2
Home-routed Roaming architecture for 5G Core Network with untrusted non-3GPP access - N3IWF in a different VPLMN than 3GPP access
[021]  Figure 4.2.8.2.3-3
Home-routed Roaming architecture for 5G Core Network with untrusted non-3GPP access - N3IWF in HPLMN
[022]  Figure 4.2.8.2.3-4
Home-routed Roaming architecture for 5G Core Network with trusted non-3GPP access using the same VPLMN as 3GPP access
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[023]  Figure 4.2.8.4-1
Non-roaming architecture for 5G Core Network for 5G-RG with Wireline 5G Access network and NG RAN
[024]  Figure 4.2.8.4-2
Non-roaming architecture for 5G Core Network for FN-RG with Wireline 5G Access network and NG RAN
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[025]  Figure 4.2.10-1
Non-roaming and Roaming with Local Breakout architecture for ATSSS support
[026]  Figure 4.2.10-2
Roaming with Home-routed architecture for ATSSS support (UE registered to the same VPLMN)
[027]  Figure 4.2.10-3
Roaming with Home-routed architecture for ATSSS support (UE registered to different PLMNs)
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[028]  Figure 4.3.1-1
Non-roaming architecture for interworking between 5GS and EPC/E-UTRAN
[029]  Figure 4.3.2-1
Local breakout roaming architecture for interworking between 5GS and EPC/E-UTRAN
[030]  Figure 4.3.2-2
Home-routed roaming architecture for interworking between 5GS and EPC/E-UTRAN
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[031]  Figure 4.3.3.1-1
Non-roaming architecture for interworking between 5GC via non-3GPP access and EPC/E-UTRAN
[032]  Figure 4.3.3.2-1
Local breakout roaming architecture for interworking between 5GC via non-3GPP access and EPC/E-UTRAN
[033]  Figure 4.3.3.2-2
Home-routed roaming architecture for interworking between 5GC via non-3GPP access and EPC/E-UTRAN
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[034]  Figure 4.3.4.1-1
Non-roaming architecture for interworking between ePDG/EPC and 5GS
[035]  Figure 4.3.4.2-1
Local breakout roaming architecture for interworking between ePDG/EPC and 5GS
[036]  Figure 4.3.4.2-2
Home-routed roaming architecture for interworking between ePDG/EPC and 5GS
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[037]  Figure 4.3.5-1
Service Exposure Architecture for EPC-5GC Interworking
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[038]  Figure 4.4.2.1-1
Non-roaming System Architecture for SMS over NAS
[039]  Figure 4.4.2.1-2
Non-roaming System Architecture for SMS over NAS in reference point representation
[040]  Figure 4.4.2.1-3
Roaming architecture for SMS over NAS
[041]  Figure 4.4.2.1-4
Roaming architecture for SMS over NAS in reference point representation
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[042]  Figure 4.4.6.1-1
Local-switch based user plane architecture in non-roaming scenario
[043]  Figure 4.4.6.1-2
Nx-based user plane architecture in non-roaming scenario
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[044]  Figure 4.4.8.2-1
System architecture view with 5GS appearing as TSN bridge
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[045]  Figure 5.3.2.2.4-1
RM state model in UE
[046]  Figure 5.3.2.2.4-2
RM state model in AMF
[047]  Figure 5.3.3.2.4-1
CM state transition in UE
[048]  Figure 5.3.3.2.4-2
CM state transition in AMF
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[049]  Figure 5.6.4.2-1
User plane Architecture for the Uplink Classifier
[050]  Figure 5.6.4.3-1
Multi-homed PDU Session: service continuity case
[051]  Figure 5.6.4.3-2
Multi-homed PDU Session: local access to same DN
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[052]  Figure 5.7.1.5-1
The principle for classification and User Plane marking for QoS Flows and mapping to AN Resources
[053]  Table 5.7.4-1
Standardized 5QI to QoS characteristics mapping
[054]  Figure 5.17.1.1-1
Architecture for migration scenario for EPC and 5G CN
[055]  Figure 5.18.1-1
A 5G Multi-Operator Core Network (5G MOCN) in which multiple CNs are connected to the same NG-RAN
[056]  Figure 5.26.1-1
inter NG-RAN Configuration Transfer basic network architecture
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[057]  Figure 5.32.5.4-1
UE/UPF measurements related protocol stack for 3GPP access
[058]  Figure 5.32.5.4-2
UE/UPF measurements related protocol stack for non-3GPP access
[059]  Figure 5.32.6.1-1
Steering functionalities in an example UE model
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[060]  Figure 5.33.2.1-1
Architecture for end to end redundant User Plane paths using Dual Connectivity
[061]  Figure 5.33.2.2-1
Redundant transmission with two N3 tunnels between the UPF and a single NGRAN node
[062]  Figure 5.33.2.2-2
Two N3 and N9 tunnels between NG-RAN and UPF for redundant transmission
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[063]  Figure 5.34.2.2-1
Non-roaming architecture with I-SMF insertion to the PDU Session in reference point representation, with no UL-CL/BP
[064]  Figure 5.34.2.2-2
Non-roaming architecture with I-SMF insertion to the PDU Session in reference point representation, with UL-CL/BP
[065]  Figure 5.34.2.3-1
Roaming 5G System architecture with SMF/I-SMF - local breakout scenario in reference point representation
[066]  Figure 5.34.4-1
User plane Architecture for the Uplink Classifier controlled by I-SMF
[067]  Figure 5.34.5-1
Multi-homed PDU Session: Branching Point controlled by I-SMF
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[068]  Figure 6.3.12.1-1
Example deployment scenario for trusted Non-3GPP access network selection
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[069]  Figure 7.1.1-1
NF/NF service inter communication
[070]  Figure 7.1.2-1
"Request-response" NF Service illustration
[071]  Figure 7.1.2-2
"Subscribe-Notify" NF Service illustration 1
[072]  Figure 7.1.2-3
"Subscribe-Notify" NF Service illustration 2
[073]  Figure 7.1.2-4
Request response using Indirect Communication
[074]  Figure 7.1.2-5
Subscribe-Notify using Indirect Communication
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[075]  Figure 7.2.1-1
Network Function and NF Service
[076]  Figure 7.2.1-2
Network Function, NF Service and NF Service Operation
[077]  Figure 7.2.1-3
System Procedures and NF Services
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[078]  Figure 8.2.1.2-1
Control Plane between the 5G-AN and the AMF
[079]  Figure 8.2.1.3-1
Control Plane between the AN and the SMF
[080]  Figure 8.2.2.1-1
NAS transport for SM, SMS, UE Policy and LCS
[081]  Figure 8.2.2.2-1
Control Plane between the UE and the AMF
[082]  Figure 8.2.2.3-1
Control Plane protocol stack between the UE and the SMF
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[083]  Figure 8.2.4-1
Control Plane before the signalling IPsec SA is established between UE and N3IWF
[084]  Figure 8.2.4-2
Control Plane after the signalling IPsec SA is established between UE and N3IWF
[085]  Figure 8.2.4-3
Control Plane for establishment of user-plane via N3IWF
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[086]  Figure 8.2.5-1
Control Plane before the NWt connection is established between UE and TNGF
[087]  Figure 8.2.5-2
Control Plane after the NWt connection is established between UE and TNGF
[088]  Figure 8.2.5-3
Control Plane for establishment of user-plane via TNGF
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[089]  Figure 8.3.1-1
User Plane Protocol Stack
[090]  Figure 8.3.2-1
User Plane via N3IWF
[091]  Figure 8.3.3-1
User Plane via TNGF
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[092]  Figure A-1
Example show a Reference Point replaced by two Service based Interfaces
[093]  Figure A-2
Example showing a Reference Point replaced by a single Service based Interface
[094]  Figure A-3
Reference Points vs. Service-based Interfaces representation of equal functionality on the interfaces
[095]  Figure A-4
One or more Services exposed by one Network Function
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[096]  Figure E.1-1
Communication options for NF/NF services interaction
[097]  Figure F-1
Architecture with redundancy based on multiple UEs in the device
[098]  Figure F-2
Reliability group-based redundancy concept in RAN