Internet-Draft | 5G transport slices | July 2022 |
Szarkowicz, et al. | Expires 2 January 2023 | [Page] |
- Workgroup:
- TEAS Working Group
- Internet-Draft:
- draft-srld-teas-5g-slicing-00
- Published:
- Intended Status:
- Informational
- Expires:
A Realization of IETF Network Slices for 5G Networks Using Current IP/MPLS Technologies
Abstract
5G slicing is a new feature that was introduced by the 3rd Generation Partnership Project (3GPP) in mobile networks. It covers slicing requirements for all mobile domains, including RAN (Radio Access Network), Core and Transport.¶
This document describes a basic IETF Network Slice realization model in IP/MPLS networks, with a focus on fulfilling 5G slicing requirements. This IETF Network Slice realization model reuses many building blocks currently commonly used in communication service provider (CSP) networks.¶
Status of This Memo
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This Internet-Draft will expire on 2 January 2023.¶
Copyright Notice
Copyright (c) 2022 IETF Trust and the persons identified as the document authors. All rights reserved.¶
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License.¶
1. Introduction
[I-D.ietf-teas-ietf-network-slices] introduces the framework for network slicing in the context of networks built using IETF technologies. The IETF network slicing framework introduces the concept of a Network Resource Partition (NRP), which is simply a collection of resources identified in the underlay network. There could be multiple realizations of high-level IETF Network Slice and NRP concepts, where each realization might be optimized for the different network slicing use cases that are listed in [I-D.ietf-teas-ietf-network-slices].¶
This document describes a basic - using only single (default) NRP - IETF Network Slice realization model in IP/MPLS networks, with a focus on fulfilling 5G slicing requirements. This IETF Network Slice realization model reuses many building blocks currently commonly used in communication service provider (CSP) networks.¶
The reader may refer to [I-D.ietf-teas-ns-ip-mpls] for more advanced - using multiple NRPs - realization models.¶
The reader may refer to [RFC6459] and [TS-23.501] for more details about 3GPP network architectures.¶
1.1. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
2. 5G Slicing in Transport Networking
2.1. Overview of 5G Networking
This section provides a brief introduction to 5G mobile networking with a perspective on the Transport Network (TN). For a more exhaustive source of information, refer to [TS-23.501].¶
2.1.1. Building Blocks
[TS-23.501] defines the Network Functions (UPF, AMF, etc.) that compose the 5G System (5GS) Architecture together with related interfaces (e.g., N1, N2...). This architecture has native Control and User Plane separation, and the Control Plane leverages a service-based architecture.¶
Similar to previous versions [RFC6459], a 5G mobile network is split into 4 major domains:¶
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UE, MS, MN, and Mobile¶
The terms UE (User Equipment), MS (Mobile Station), MN (Mobile Node), and mobile refer to the devices that are hosts with the ability to obtain Internet connectivity via a 3GPP network. An MS is comprised of the Terminal Equipment (TE) and a Mobile Terminal (MT). The terms UE, MS, MN, and mobile are used interchangeably within this document.¶
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Radio Access Network (RAN)¶
Provides wireless connectivity to the UE devices via radio. It is made up of the Antenna that transmits and receives signals to the UE and the Base Station that digitizes the signal and converts the RF data stream to IP packets.¶
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Core Network (CN)¶
Controls the CP of the RAN and provides connectivity to the Data Network (e.g., the Internet or a private VPN). The Core Network hosts dozens of services such as authentication, phone registry, charging, access to PSTN and handover.¶
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Transport Network (TN)¶
Provides connectivity between sites where 5G Network Functions are located. The TN may connect sites from the RAN to the Core Network, as well as sites within the RAN or within the CN. This connectivity is achieved by IP Networking.¶
2.1.2. Core Network
The 5G Core Network (5GC) is made up of a set of Network Functions (NFs) which fall into two main categories:¶
- 5GC User Plane: the User Plane Function (UPF) is the interconnect point between the mobile infrastructure and the Data Network (DN). It interfaces with the RAN via the N3 interface by encapsulating/decapsulating the User Plane Traffic in GTP Tunnels (aka GTP-U or Mobile User Plane).¶
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5GC Control Plane: the 5G Control Plane is made up of a comprehensive set of Network Functions. An exhaustive list and description of these entities is out of the scope of this document. The following NFs and interfaces are worth mentioning, since their connectivity may rely on the Transport Network:¶
2.1.3. RAN
The radio access network (RAN) connects cellular wireless devices to a mobile Core Network. The RAN network is made up of 3 components, which form the Radio Base Station:¶
- The Baseband Unit (BBU) provides the interface between the Core Network and the Radio Network. It connects to the Radio Unit and is responsible for the baseband signal processing to packet.¶
- The Radio Unit (RU) is located close to the Antenna and controlled by the BBU. It converts the Baseband signal received from the BBU to a Radio frequency signal.¶
- The Antenna converts the electric signal received from the RU to radio waves¶
The 5G RAN Base Station is called a gNodeB (gNB). It connects to the Core Network via the N3 (user plane) and N2 (control plane) interfaces.¶
The 5G RAN architecture supports RAN disaggregation in various ways. Notably, the BBU can be split into a DU (Distributed Unit) for digital signal processing and a CU (Centralized Unit) for RAN Layer 3 processing. Furthermore, the CU can be itself split into Control Plane (CU-CP) and User Plane (CU-UP).¶
Figure 4 depicts a disaggregated RAN with NFs and interfaces.¶
2.1.4. Transport Network
Segments¶
The 3GPP defines three main segments for the Transport Network: Fronthaul (FH), Midhaul (MH), and Backhaul (BH).¶
- Fronthaul happens before the BBU processing. In 5G, this interface is based on eCPRI (Enhanced CPRI) with native Ethernet or IP encapsulation.¶
- Midhaul is optional: this segment is introduced in the BBU split presented in Section 2.1.3, where Midhaul network refers to the DU-CU interconnection (i.e., F1 interface). At this level, all traffic is encapsulated in IP (signaling and user plane).¶
- Backhaul happens after BBU processing. Therefore, it maps to the interconnection between the RAN and the Core Network. All traffic is also encapsulated in IP.¶
Figure 5 illustrates the different segments of the Transport Network with the relevant Network Functions.¶
It is worth mentioning that a given part of the transport network can carry several 3GPP transport segments concurrently, as outlined in Figure 6. This is because different types of 5G network functions might be placed in the same location (e.g., the UPF from one slice might be placed in the same location as the CU-UP from another slice).¶
Transport Network¶
The 3GPP specifications loosely define the Transport Network as well as its integration in RAN and Core Network domains. The role of the Transport Network is to provide connectivity between a set of Network Functions that can be distributed over a myriad of locations. In other words, it is the end-to-end data path that interconnects mobile entities.¶
In practice, this interconnection can be achieved in multiple ways and is often a non-uniform architecture. Notably, we can highlight the following points:¶
- The end-to-end data path can be segmented, with individual segments potentially managed by different organizations.¶
- A site can be of different types such as Edge, Data Center, or Public Cloud, each with specific network design, hardware dependencies and management interface.¶
- The end-to-end data path can be made up of diverse networking technologies: MPLS, SRv6, VXLAN, L2VPN vs L3VPN...¶
In this document, the scope of the Transport Network is defined with a service provider scope. More precisely, the Transport Network extends up to the PE, or the CE when managed by the Service Provider (a.k.a., Service Demarcation Point (SDP)). It is also assumed that the network is MPLS or SRv6 capable.¶
Hence, the RAN and Core Network domains are extended with a set of IP devices, with a management scope driven by the domain orchestrator (i.e., RAN or Core SMO). In other words, the "Extended RAN or CN domain" is made up of the Network Functions and the associated IP routing devices when present.¶
2.2. 5G Network Slicing Integration in Transport Networks
2.2.1. 5G Network Slicing versus Transport Network Slicing
Network Slicing has a different meaning in 3GPP and IETF. Hence, for the sake of precision, this section provides a brief description of the objectives of 3GPP 5G Network Slicing and IETF Transport Network Slicing.¶
- The objective of 5G network slicing is to provide dedicated resources of the whole 5G infrastructure to certain users, application, customers or PLMN (e.g., RAN sharing). These resources are from the Transport Network, RAN and CORE Network Functions and the underlying infrastructure. [TS-28.530] defines 5G network slicing by introducing the concept of Network Slice Subnet (NSS) to represent slices within each of these domains: RAN, CORE and Transport Network (i.e., RAN NSS, CN NSS and TN NSS). As per 3GPP specifications, NSS can be shared or dedicated to a single slice.¶
- The objective of Transport Network slicing is to isolate, guarantee or prioritize Transport Network resources for slices such as buffers, link bandwidth or even RIB/FIB. Transport Network Slicing has two main flavors: Hard and Soft slicing. Hard slicing provides dedicated network capacity to slices. Soft Slicing provides shared network capacity with guarantees for each slice. There are different options to implement TN slices based on tooling such as VRFs for traffic separation, QoS and TE. Also, TN slice realization for 5G slices might combine elements of hard slicing in one part of the transport network, with elements of soft slicing in other parts of the transport network. An optimized 5G network slicing architecture should integrate Transport Network Slicing, however, it is possible to implement 5G network slicing without Transport Network Slicing, as explained in the next section.¶
2.2.2. 5G slice to TN slice mapping
There are multiple options to map 5G network slices to Transport Slices:¶
- 1 to N: A single 5G Network Slice can map to multiple Transport Network Slices (1 to N). One example of such a case is the separation of the 5G Control Plane and User Plane: this use case is represented in Figure 8 where a slice (EMBB) is deployed with a separation of User Plane and Control Plane at Transport Network level.¶
- N to 1: Multiple 5G Network Slices may rely on a same Transport Network Slice (i.e., in [TS-28.530] semantic, two RAN/CORE NSS rely on a shared TN NSS). In this case, the SLA differentiation of slices would be entirely controlled at 5G Control Plane, for example with appropriate placement strategies: this use case is represented in Figure 9, where a UPF network function for the URLLC slice is instantiated at the Edge Cloud close the gNB CU-UP User Plane for better latency/jitter control, while 5G Control Plane and the UPF for slice EMBB are instantiated in the Regional Cloud.¶
- N to M: the 5G to TN slice mapping combines both approaches with a mix of shared and dedicated associations.¶
Note that the actual realization of the mapping depends on several factors such as the actual business cases, the VNF vendor capabilities, the VNF vendor reference designs, as well as service provider or even legal requirements.¶
2.2.3. First slice versus subsequent slices
A 5G Network Slice is fully functional with both 5G Control Plane and User Plane capabilities (i.e., dedicated NF functions or contexts). In this regard, the creation of the "first slice" is subject to a specific logic since it must deploy both CP and UP. This is not the case for the deployment of subsequent slices because they can share the CP of the First Slice, while instantiating dedicated UP. An example of an incremental deployment is depicted in Figure 10¶
At the time of writing, [NG.113], Section 6.2, specifies that the eMBB slice (SST=1 and no SD) should be supported globally. This 5G slice would be the first slice in any 5G deployment.¶
Note that the actual realization of the mapping depends on several factors such as the actual business cases, the VNF vendor capabilities, the VNF vendor reference designs, as well as service providers or even legal requirements.¶
3. High-Level overview of the realization model
[I-D.ietf-teas-ietf-network-slices] introduces the concept of a Network Resource Partition (NRP), which is defined as a collection of resources identified in the underlay network. In the basic realization model described in this document, a single (default) NRP is used with following characteristics¶
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L2VPN/L3VPN instances for traffic separation¶
This realization model of transport for 5G slices assumes L3 delivery for midhaul and backhaul transport connections, and a L2 or L3 (eCPRI supports both) delivery model for fronthaul connections. L2VPN/L3VPN instances might be used as basic form of slice separation.¶
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Fine-Grained resource control at the edge links of TN domain (attachment circuits)¶
This is sometimes called 'admission control' or 'traffic conditioning'. The main purpose is the enforcement of the bandwidth contract for the slice right at the edge of the transport domain where the traffic is handed-off between the transport domain and the 5G domains (i.e., RAN/Core). The toolset used here is granular ingress policing (rate limiting) to enforce contracted bandwidths per slice and, potentially, per traffic class within the slice. Out-of-contract traffic might be immediately dropped, or marked as high drop probability traffic, which is more likely to be dropped somewhere at the transit if congestion occurs. In the egress direction at the edge of the transport domain, hierarchical schedulers/shapers can be deployed, providing guaranteed rates per slice, as well as guarantees per traffic class within the slice.¶
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Coarse resource control at the TN transit (non-attachment circuits) links of the transport domain, using single (default) Network Resource Partition (NRP), spanning the entire TN domain¶
Transit nodes do not maintain any state of individual slices. Instead, only a flat (non-hierarchical) QoS model is used on transit links with up to 8 traffic classes. At the transport domain edge, traffic flows from multiple slice services are mapped to the limited number of traffic classes used on transit links.¶
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Capacity planning/management for efficient usage of TN edge and TN transit resources¶
The role of capacity management is to ensure the transport capacity can be utilized without causing any bottlenecks. The toolset used here can range from careful network planning, to ensure more less equal traffic distribution (i.e., equal cost load balancing), to advanced traffic engineering techniques, with or without bandwidth reservations, to force more consistent load distribution even in non-ECMP friendly network topologies.¶
The 5G control plane relies on S-NSSAI (Single Network Slice Selection Assistance Information: 32-bit slice identifier) for slice identification. The S-NSSAI is not visible to the transport domain, so instead 5G functions can expose the 5G slices to the transport domain by mapping to explicit L2/L3 identifiers such as VLAN, IP addresses or DSCP, as documented in [I-D.geng-teas-network-slice-mapping].¶
3.1. VLAN hand-off
In this option, the TN slice, fulfilling connectivity requirements between NFs of some 5G slice, is represented at the SDP by a VLAN, or double VLANs (commonly known as QinQ). Since the 5G interfaces are IP based interfaces (the only exception could be the F2 fronthaul-interface, where eCPRI with Ethernet encapsulation is used), this VLAN is not transported across the TN domain. It has only local significance at a particular SDP. For simplification it is recommended to rely on a same VLAN identifier for all ACs, when possible. However, SDPs for a same slice at different locations may also use different VLAN values. Therefore, a VLAN - TN-Slice mapping table MUST be maintained for each AC, and the VLAN allocation MUST be coordinated between TN domain and extended RAN/Core domains. Thus, while VLAN hand-off is simple from NF point of view, it adds complexity due to the requirement of maintaining mapping tables for each SDP.¶
3.2. IP hand-off
In this option, the TN slice is instantiated by IP tunnels (for example, IPsec, GTP tunnel) established between NFs. The Transport for a single 5G slice is constructed with multiple such tunnels, since a typical 5G slice contains many NFs - especially DUs and CUs. If a shared NF (i.e., an NF that serves multiple slices, for example a shared DU) is deployed, multiple tunnels are established, each tunnel representing a single slice. Similarly to the VLAN hand-off case, a mapping table tracking IP to TN-Slice mapping is required.¶
The mapping table can be simplified, if IPv6 addressing is used to address NFs. An IPv6 address is a 128-bit long field, while the S-NSSAI is a 32-bit field: Slice/Service Type (SST): 8 bits, Slice Differentiator (SD): 24 bits. 32 bits, out of 128 bits of the IPv6 address, MAY be used to encode the S-NSSAI, which makes an IP to Slice mapping table unnecessary. Different IPv6 address allocation schemes following this concept MAY be used, with one example allocation showed in Figure 14.¶
In the example, the most significant 96 bits of the IPv6 address are unique to NF, but do not carry any slice specific information, while the least significant 32 bits are used to embed S-NSSAI information. The 96-bit part of the address could be further divided, based for example on geographical location, or DC identification. 128 bits is wide enough to design an IPv6 addressing scheme, which is most suitable for particular 5G deployment.¶
Figure 15 shows an example slicing deployment, where S-NSSAI is embedded into IPv6 addresses used by NFs. NF-A has a loopback interface, used to terminate tunnels, with unique per slice IP addresses allocated from 2001:db8::a:0:0/96 subnet, while NF-B uses loopback interface with per slice IP addresses allocated from 2001:db8::b:0:0/96. This example shows two slices: eMBB (SST=1) and MIoT (SST=3). Therefore, for eMBB the tunnel IP addresses are auto-derived (without the need for a mapping table) as {2001:db8::a:100:0, 2001:db8::b:100:0}, while for MIoT (SST=3) tunnel uses {2001:db8::a:300:0, 2001:db8::b:300:0}.¶
4. QoS models in 5G slicing
The resources are managed via various QoS policies deployed in the network. QoS model in 5G slicing implemented over packet switched transport uses two layers of QoS¶
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5G QoS¶
At this layer QoS treatment is indicated by the 5QI (5G QoS indicator), as defined in [TS-23.501]. A 5QI is an ID that is used as a reference to 5G QoS characteristics (e.g., scheduling weights, admission thresholds, queue management thresholds, link layer protocol configuration, etc.) in the RAN domain. Given the fact that 5QI applies to the RAN domain, it is not visible to the TN domain. Therefore, if 5QI-aware treatment is desired in the TN domain as well, 5G components might set DSCP with a value representing 5QI, to allow differentiated treatment in TN domain as well. Based on these DSCP values, at SDP of each TN segment used to construct transport for given 5G slice, very granular QoS enforcement might be implemented. The mapping between 5QI and DSCP is out of scope for this document. Mapping recommendations are documented in [I-D.henry-tsvwg-diffserv-to-qci]. Each slice might have flows with multiple 5QIs, thus there could be many different 5QIs being deployed. 5QIs (or, more precisely, corresponding DSCP values) are visible to the TN domain at SDP (i.e., at the edge of the TN domain).¶
In this document, this layer of QoS will be referred as 5G QoS, or 5G DSCP.¶
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TN QoS¶
Controlling of the TN resources on transit links, as well as traffic scheduling/prioritization on transit links is based on a flat (non-hierarchical) QoS model in the TN slice realization. That is, TN slices are assigned dedicated resources (e.g., QoS queues) at the edge of the TN domain (at SDP), while all TN slices are sharing resources (sharing QoS queues) on the transit links of the TN domain. Typical router hardware can support up to 8 traffic queues per port, therefore the architecture assumes 8 traffic queues per port support in general.¶
At this layer, QoS treatment is indicated by QoS indicator specific to the encapsulation used in the TN domain, and it could be DSCP or MPLS TC. This layer of QoS will be referred as 'TN QoS Class', or 'TN QoS' for short, in this document.¶
While 5QI might be exposed to the TN domain, via the DSCP value (corresponding to specific 5QI value) set in the IP packet generated by NFs, some 5G deployments might use 5QI in the RAN domain only, without requesting per 5QI differentiated treatment from the TN domain. This can be due to an NF limitation (no capability to set DSCP), or it might simply depend on the overall slicing deployment model. The O-RAN Alliance, for example, defines a phased approach to the slicing, with initial phases utilizing only per slice, but not per 5QI, differentiated treatment in the TN domain ([O-RAN.WG9.XPSAAS], Annex F).¶
Therefore, from QoS perspective, the 5G slicing realization architecture defines two high-level TN slicing realization models: a 5QI-unaware model and a 5QI-aware model. Both TN slicing models could be used concurrently within the same 5G slice. For example, the TN segment for 5G midhaul (F2-U interface) might be 5QI-unaware, while at the same time the TN segment for 5G backhaul (N3 interface) might follow the 5QI-aware model.¶
4.1. 5QI-unaware TN slicing
In 5QI-unaware mode, the DSCP values in the packets received from NF at SDP are ignored. There is no QoS differentiation at the 5QI level. The entire TN slice is mapped to single TN QoS Class, and, therefore, to a single QoS queue on the routers in the TN domain. With a small number of deployed 5G slices (for example only two 5G slices: eMBB and MIoT), it is possible to dedicate a separate QoS queue for each slice on transit routers. However, with introduction of private/enterprises slices, as the number of 5G slices (and thus corresponding TN slices) increases, a single QoS queue on transit links serves multiple slices with similar characteristics. QoS enforcement on transit links is fully coarse (default NRP, sharing resources among all TN slices), as displayed in Figure 16.¶
When the IP traffic is handed over at the SDP from the extended RAN or extended Core domains to the TN domain, the PE encapsulates the traffic into MPLS (if MPLS transport is used in the TN domain), or IPv6 - optionally with some additional headers (if SRv6 transport is used in the TN domain), and sends out the packets on the TN transit link.¶
The original IP header retains the DCSP marking (which is ignored in 5QI-unaware mode), while the new header (MPLS or IPv6) carries QoS marking (MPLS Traffic Class bits for MPLS encapsulation, or DSCP for SRv6/IPv6 encapsulation) related to TN CoS. Based on TN QoS Class marking, per hop behavior for all TN slices is executed on TN links. TN domain transit routers do not evaluate the original IP header for QoS-related decisions. This model is outlined in Figure 17 for MPLS encapsulation, and in Figure 18 for SRv6 encapsulation.¶
From the QoS perspective, both options are similar. However, there is one difference between the two options. The MPLS TC is only 3 bits (8 possible combinations), while DSCP is 6 bits (64 possible combinations). Hence, SRv6 provides more flexibility for TN CoS design, especially in combination with soft policing with in-profile/out-profile, as discussed in Section 4.1.1.¶
Edge resources are controlled in a very granular, fine-grained manner, with dedicated resource allocation for each TN slice. The resource control/enforcement happens at each SDP in two directions: inbound and outbound.¶
4.1.1. Inbound Edge Resource Control
The main aspect of inbound edge resource control is per-slice traffic capacity enforcement. This kind of enforcement is often called 'admission control' or 'traffic conditioning'. The goal of this inbound enforcement is to ensure that the traffic above the contracted rate is dropped or deprioritized, depending on the business rules, right at the edge of TN domain. This, combined with appropriate network capacity planning/management, as described in Section 5, is required to ensure proper isolation between slices in scalable manner. As a result, traffic of one slice has no influence on the traffic of other slices, even if the slice is misbehaving (i.e., DDoS attack, equipment failure, etc.) and generates traffic volumes above the contracted rates.¶
The slice rates can be characterized with following parameters [I-D.ietf-teas-ietf-network-slice-nbi-yang]:¶
- CIR: Committed Information Rate (i.e., guaranteed bandwidth)¶
- PIR: Peak Information Rate (i.e., maximum bandwidth)¶
These parameters define the traffic characteristics of the slice and are part of SLO parameter set provided by the SMO to NSC. Based on these parameters the inbound policy can be implemented using one of following options:¶
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1r2c (single-rate two-color) rate limiter¶
This is the most basic rate limiter, which meters at the SDP a traffic stream of given slice and marks its packets as in-contract (below contracted CIR) or out-of-contract (above contracted CIR). In-contract packets are accepted and forwarded. Out-of contract packets are either dropped right at the SDP (hard rate limiting), or remarked (with different MPLS TC or DSCP TN markings) to signify 'this packet should be dropped in the first place, if there is a congestion' (soft rate limiting), depending on the business policy of the operator. In the second case, while packets above CIR are forwarded at the SDP, they are subject to be dropped during any congestion event at any place in the TN domain.¶
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2r3c (two-rate three-color) rate limiter¶
This was initially defined in [RFC2698], and its improved version in [RFC4115]. In essence, the traffic is assigned to one of the 3 categories:¶
An inbound 2c3r meter implemented with [RFC4115], compared to [RFC2698], is more 'customer friendly' as it doesn't impose outbound peak-rate shaping requirements on customer edge (CE) devices. 2r3c meters in general give greater flexibility for edge enforcement regarding accepting the traffic (green), de-prioritizing and potentially dropping the traffic during congestion (yellow), or hard dropping the traffic (red).¶
Inbound edge enforcement mode for 5QI-unaware mode, where all packets belonging to the slice are treated the same way in the TN domain (no 5QI differentiation in the TN domain) is outlined in Figure 19.¶
4.1.2. Outbound Edge Resource Control
While inbound slice admission control at the transport edge is mandatory in the model, outbound edge resource control might not be required in all use cases. Use cases that specifically call for outbound edge resource control are:¶
- Slices use both CIR and PIR parameters, and transport edge links (attachment circuits) are dimensioned to fulfil the aggregate of slice CIRs. If at any given time, some slices send the traffic above CIR, congestion in outbound direction on the transport edge link might happen. Therefore, fine-grained resource control to guarantee at least CIR for each slice is required.¶
- Any-to-Any (A2A) connectivity constructs are deployed, again resulting in potential congestion in outbound direction on the transport edge links, even if only slice CIR parameters are used. This again requires fine-grained resource control per slice in outbound direction at transport edge links.¶
As opposed to inbound edge resource control, typically implemented with rate-limiters/policers, outbound resource control is implemented with a weighted/priority queuing, potentially combined with optional shapers (per slice). A detailed analysis of different queuing mechanisms is out of scope for this document, but is provided in [RFC7806].¶
Figure 20 outlines the outbound edge resource control model at the transport network layer for 5QI-unaware slices. Each slice is assigned a single egress queue. The sum of slice CIRs, used as the weight in weighted queueing model, MUST not exceed the physical capacity of the attachment circuit. Slice requests above this limit MUST be rejected by the NSC, unless an already established slice with lower priority, if such exists, is preempted.¶
4.2. 5QI-aware TN slicing
In the 5QI-aware model, potentially a large number of 5QIs (the architecture scales to thousands of 5Q slices) is mapped (multiplexed) to up to 8 TN Class of Services used in transport transit equipment, as outlined in Figure 21.¶
Given the fact that in large scale deployments (large number of 5G slices), the number of potential 5QIs is much higher that the number of TN QoS Classes, multiple 5QIs with similar characteristics - potentially from different TN slices - can be mapped to a same TN QoS Class when transported in the TN domain. That is, common per hop behavior (PHB) is executed on transit TN routers for all packets grouped together.¶
Like in 5QI-unaware model, the original IP header retains the DCSP marking corresponding to 5QI, while the new header (MPLS or IPv6) carries QoS marking related to TN QoS Class. Based on TN QoS Class marking, per hop behavior for all aggregated 5QIs from all TN slices is executed on TN links. TN domain transit routers do not evaluate original IP header for QoS related decisions. The original DSCP marking retained in the original IP header is used at the PE for fine-grained per slice and per 5QI inbound/outbound enforcement on AC link.¶
In 5QI-aware model edge resources are controlled in even more granular, fine-grained manner, with dedicated resource allocation for each TN slice and dedicated resource allocation for number of traffic classes (most commonly up 4 or 8 traffic classes, depending on the HW capability of the equipment) within each TN slice.¶
4.2.1. Inbound Edge Resource Control
Compared to the 5QI-unware model, admission control (traffic conditioning) in the 5QI-aware model is more granular, as it enforces not only per slice capacity constraints, but may as well enforce the constraints per 5QI within each slice.¶
5G slice using multiple 5QIs can potentially specify rates in one of the following ways¶
- rates per traffic class (CIR, or CIR+PIR), no rate per slice (sum of rates per class gives the rate per slice)¶
- rate per slice (CIR, or CIR+PIR), and rates per prioritized (premium) traffic classes (CIR only). Best effort traffic class uses the bandwidth (within slice CIR/PIR) not consumed by prioritized classes¶
In the first option, the slice admission control is executed at with traffic class granularity, as outlined in Figure 22. In this model, if a premium class doesn't consume all available class capacity, it cannot be reused by non-premium (i.e., Best Effort) class.¶
The second model combines the advantages of 5QI-unaware model (per slice admission control) with the per traffic class admission control, as outlined in Figure 22. Ingress admission control is at class granularity for premium classes (CIR only). Non-premium class (i.e. Best Effort) has no separate class admission control policy, but is allowed to use entire slice capacity, which is available at any given moment. I.e., slice capacity, which is not consumed by premium classes. It is a hierarchical model, as depicted in Figure 23.¶
4.2.2. Outbound Edge Resource Control
Figure 24 outlines the outbound edge resource control model at the transport network layer for 5QI-aware slices. Each slice is assigned multiple egress queues. The sum of queue weights (equal to 5QI CIRs within the slice) CIRs MUST not exceed the CIR of the slice itself. And, similarly to the 5QI-aware model, the sum of slice CIRs MUST not exceed the physical capacity of the attachment circuit.¶
4.3. Transit Resource Control
Transit resource control is much simpler than Edge resource control. As outlined in Figure 21, at the edge, 5QI marking (represented by DSCP set by mobile components in the packets handed off to the TN) is mapped to the TN QoS Class. Based in TN QoS Class, when the packet is encapsulated with outer header (MPLS or IPv6), TN QoS Class marking (MPLS TC or IPv6 DHCP in outer header, as depicted in Figure 17 and Figure 18) is set in the outer header. PHB on transit is based exclusively on that TN QoS Class marking, i.e., original DSCP representing 5QI is not taken into consideration on transit.¶
Transit resource control does not use any inbound interface policy, but only outbound interface policy, which is based on priority queue combined with weighted or deficit queuing model, without any shaper. The main purpose of transit resource control is to ensure that during network congestion events, for example caused by network failures and temporary rerouting, premium classes are prioritized, and any drops only occur in non-premium (best-effort) classes. Capacity planning and management, as described in Section 5, ensures that enough capacity is available to fulfill all approved slice requests.¶
5. Capacity planning/management
This section describes the information conveyed by the SMO to the transport controller with respect to slice bandwidth requirements. Figure 25 shows three DCs that contain instances of network functions. Also shown are PEs that have links to the DCs. The PEs belong to the transport network. Other details of the transport network, such as P-routers and transit links are not shown. Also details of the DC infrastructure such as switches and routers are not shown.¶
The SMO is aware of the existence of the network functions and their locations. However, it is not aware of the details of the transport network. The transport controller has the opposite view - it is aware of the transport infrastructure and the links between the PEs and the DCs, but is not aware of the individual network functions.¶
Let us consider 5G Slice X that uses some of the network functions in the three DCs. If the slice has latency requirements, the SMO took those into account when deciding which network functions in which DC would participate in the slice. As a result of that placement decision, the three DCs shown are involved in 5G Slice X, rather than other DCs. In order to make this determination, the SMO needs information about the latency between DCs. How it acquires that is beyond the scope of this document. The SMO communicates to the NSC the bandwidth requirements of the slice.¶
Figure 26 shows the matrix of bandwidth demands for that 5G slice. Within the slice, multiple network function instances might be sending traffic from DCi to DCj. However, the SMO sums the associated demands into one value. For example, NF1A and NF1B in DC1 might be sending traffic to multiple NFs in DC2, but this is expressed as one value in the traffic matrix: the total bandwidth required for 5G Slice X from DC1 to DC2 (8 units). Each row in the right-most column in the traffic matrix shows the total amount of traffic going from a given DC into the transport network, regardless of the destination DC. Note that this number can be less than the sum of DC-to-DC demands in the same row, on the basis that not all the network functions are likely to be sending at their maximum rate simultaneously. For example, the total traffic from DC1 for Slice X is 11 units, which is less than the sum of the DC-to-DC demands in the same row (13 units). Note, as described in Section 4, a slice may have per-QoS class bandwidth requirements, and may have CIR and PIR limits. This is not included in the example, but the same principles apply in such cases.¶
[I-D.ietf-teas-ietf-network-slice-nbi-yang] can be used to convey all of the information in the traffic matrix to the NSC. The NSC applies policers corresponding to the last column in the traffic matrix to the appropriate PE routers, in order to enforce the bandwidth contract. For example, it applies a policer of 11 units to PE1A and PE1B that face DC1, as this is the total bandwidth that DC1 sends into the transport network corresponding to Slice X. Also, the controller may apply shapers in the direction from the TN to the DC, if otherwise there is the possibility of a link in the DC being oversubscribed.¶
Depending on the bandwidth model used in the network (Section 5.1), the other values in the matrix, i.e., the DC-to-DC demands, may not be directly applied to the transport network. Even so, the information may be useful to the NSC for capacity planning and failure simulation purposes. If, on the other hand, the DC-to-DC demand information is not used by the NSC, the IETF yang model for L3VPN Service Delivery [RFC8299] or the IETF YANG Data Model for L2VPN Service Delivery [RFC8466] could be used instead of [I-D.ietf-teas-ietf-network-slice-nbi-yang], as they support conveying the bandwidth information in the right-most column of the traffic matrix.¶
The transport network may be implemented in such a way that it has various types of paths, for example low-latency traffic might be mapped onto a different transport path to other traffic (for example a particular flex-algo or a particular set of TE LSPs), the SMO can use [I-D.ietf-teas-ietf-network-slice-nbi-yang] to request low-latency transport for a given slice if required. However, [RFC8299] or [RFC8466] do not support requesting a particular transport-type, e.g., low-latency. One option is to augment these models to convey this information. This can be achieved by reusing the underlay-transport construct used in [RFC9182] and [I-D.ietf-opsawg-l2nm].¶
5.1. Bandwidth models
This section describes three bandwidth management schemes that could be employed in the transport network. Many variations are possible, but each example describes the salient points of the corresponding scheme. Schemes 2 and 3 use TE, other variations on TE are possible as described in [I-D.ietf-teas-rfc3272bis].¶
5.1.1. Scheme 1: shortest path forwarding
Shortest path forwarding is used according to the IGP metric. Given that some slices are likely to have latency SLOs, the IGP metric on each link can be set to be in proportion to the latency of the link. In this way, all traffic follows the minimum latency path between endpoints.¶
In Scheme 1, although the operator provides bandwidth guarantees to the slice customers, there is no explicit end-to-end underpinning of the bandwidth SLO, in the form of bandwidth reservations across the transport network. Rather, the expected performance is achieved via capacity planning, based on traffic growth trends and anticipated future demands, in order to ensure that network links are not over-subscribed. This scheme is analogous to that used in many existing business VPN deployments, in that bandwidth guarantees are provided to the customers but are not explicitly underpinned end to end across the transport network.¶
A variation on the scheme is that Flex-Algo, defined in [I-D.ietf-lsr-flex-algo], is used, for example one Flex-Algo could use latency-based metrics and another Flex-Algo could use the IGP metric. There would be a many-to-one mapping of slices to Flex-Algos.¶
While Scheme 1 is technically feasible, it is vulnerable to unexpected changes in traffic patterns and/or network element failures resulting in congestion. This is because, unlike Schemes 2 and 3 that employ TE, traffic cannot be diverted from the shortest path.¶
5.1.2. Scheme 2: TE LSPs with fixed bandwidth reservations
Scheme 2 uses RSVP-TE or SR-TE LSPs with fixed bandwidth reservations. By "fixed", we mean a value that stays constant over time, unless the SMO communicates a change in slice bandwidth requirements, due to the creation or modification of a slice. Note that the "reservations" would be in the mind of the transport controller - it is not necessary (or indeed possible for SR-TE) to reserve bandwidth at the network layer. The bandwidth requirement acts as a constraint whenever the controller (re)computes the path of an LSP. There could be a single mesh of LSPs between endpoints that carry all of the traffic types, or there could be a small handful of meshes, for example one mesh for low-latency traffic that follows the minimum latency path and another mesh for the other traffic that follows the minimum IGP metric path. There would be a many-to-one mapping of slices to LSPs.¶
The bandwidth requirement from DCi to DCj is the sum of the DCi-DCj demands of the individual slices. For example, if only Slice X and Slice Y are present, then the bandwidth requirement from DC1 to DC2 is 12 units (8 units for Slice X and 4 units for Slice Y). When the SMO requests a new slice, the transport controller, in its mind, increments the bandwidth requirement according to the requirements of the new slice. For example, in Figure 25, suppose a new slice is instantiated that needs 0.8 Gbps from DC1 to DC2. The transport controller would increase its notion of the bandwidth requirement from DC1 to DC2 from 12 Gbps to 12.8 Gbps to accommodate the additional expected traffic.¶
In the example, each DC has two PEs facing it for reasons of resilience. The transport controller needs to determine how to map the DC1 to DC2 bandwidth requirement to bandwidth reservations of TE LSPs from DC1 to DC2. For example, if the routing configuration is arranged such that in the absence of any network failure, traffic from DC1 to DC2 always enters PE1A and goes to PE2A, the controller reserves 12.8 Gbps of bandwidth on the LSP from PE1A to PE2A. If, on the other hand, the routing configuration is arranged such that in the absence of any network failure, traffic from DC1 to DC2 always enters PE1A and is load-balanced across PE2A and PE2B, the controller reserves 6.4 Gbps of bandwidth on the LSP from PE1A to PE2A and 6.4 Gbps of bandwidth on the LSP from PE1A to PE2B. It might be tricky for the transport controller to be aware of all conditions that change the way traffic lands on the various PEs, and therefore know that it needs to change bandwidth reservations of LSPs accordingly. For example, there might be an internal failure within DC1 that causes traffic from DC1 to land on PE1B, rather than PE1A. The transport controller may not be aware of the failure and therefore may not know that it now needs to apply bandwidth reservations to LSPs from PE1B to PE2A/PE2B.¶
5.1.3. Scheme 3: TE LSPs without bandwidth reservations
Like Scheme 2, Scheme 3 uses RSVP-TE or SR-TE LSPs. There could be a single mesh of LSPs between endpoints that carry all of the traffic types, or there could be a small handful of meshes, for example one mesh for low-latency traffic that follows the minimum latency path and another mesh for the other traffic that follows the minimum IGP metric path. There would be a many-to-one mapping of slices to LSPs.¶
The difference between Scheme 2 and Scheme 3 is that Scheme 3 does not have fixed bandwidth reservations for the LSPs. Instead, actual measured data-plane traffic volumes are used to influence the placement of TE LSPs. One way of achieving this is to use distributed RSVP-TE with auto-bandwidth. Alternatively, the transport controller can use telemetry-driven automatic congestion avoidance. In this approach, when the actual traffic volume in the data plane on given link exceeds a threshold, the controller, knowing how much actual data plane traffic is currently travelling along each RSVP or SR-TE LSP, can tune the paths of one or more LSPs using the link such that they avoid that link.¶
It would be undesirable to move a minimum-latency LSP rather than another type of LSP in order to ease the congestion, as the new path will typically have a higher latency, if the minimum-latency LSP is currently following the minimum-latency path. This can be avoided by designing the algorithms described in the previous paragraph such that they avoid moving minimum-latency LSPs unless there is no alternative.¶
6. IANA Considerations
This memo includes no request to IANA.¶
7. Security Considerations
To be added later.¶
8. References
8.1. Normative References
- [RFC2119]
- Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, , <https://www.rfc-editor.org/info/rfc2119>.
- [RFC8174]
- Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, , <https://www.rfc-editor.org/info/rfc8174>.
- [RFC8299]
- Wu, Q., Ed., Litkowski, S., Tomotaki, L., and K. Ogaki, "YANG Data Model for L3VPN Service Delivery", RFC 8299, DOI 10.17487/RFC8299, , <https://www.rfc-editor.org/info/rfc8299>.
- [RFC8466]
- Wen, B., Fioccola, G., Ed., Xie, C., and L. Jalil, "A YANG Data Model for Layer 2 Virtual Private Network (L2VPN) Service Delivery", RFC 8466, DOI 10.17487/RFC8466, , <https://www.rfc-editor.org/info/rfc8466>.
8.2. Informative References
- [RFC2698]
- Heinanen, J. and R. Guerin, "A Two Rate Three Color Marker", RFC 2698, DOI 10.17487/RFC2698, , <https://www.rfc-editor.org/info/rfc2698>.
- [RFC4115]
- Aboul-Magd, O. and S. Rabie, "A Differentiated Service Two-Rate, Three-Color Marker with Efficient Handling of in-Profile Traffic", RFC 4115, DOI 10.17487/RFC4115, , <https://www.rfc-editor.org/info/rfc4115>.
- [RFC6459]
- Korhonen, J., Ed., Soininen, J., Patil, B., Savolainen, T., Bajko, G., and K. Iisakkila, "IPv6 in 3rd Generation Partnership Project (3GPP) Evolved Packet System (EPS)", RFC 6459, DOI 10.17487/RFC6459, , <https://www.rfc-editor.org/info/rfc6459>.
- [RFC7806]
- Baker, F. and R. Pan, "On Queuing, Marking, and Dropping", RFC 7806, DOI 10.17487/RFC7806, , <https://www.rfc-editor.org/info/rfc7806>.
- [RFC9182]
- Barguil, S., Gonzalez de Dios, O., Ed., Boucadair, M., Ed., Munoz, L., and A. Aguado, "A YANG Network Data Model for Layer 3 VPNs", RFC 9182, DOI 10.17487/RFC9182, , <https://www.rfc-editor.org/info/rfc9182>.
- [I-D.ietf-lsr-flex-algo]
- Psenak, P., Hegde, S., Filsfils, C., Talaulikar, K., and A. Gulko, "IGP Flexible Algorithm", Work in Progress, Internet-Draft, draft-ietf-lsr-flex-algo-20, , <https://datatracker.ietf.org/doc/html/draft-ietf-lsr-flex-algo-20>.
- [I-D.ietf-opsawg-l2nm]
- Boucadair, M., Dios, O. G. D., Barguil, S., and L. A. Munoz, "A YANG Network Data Model for Layer 2 VPNs", Work in Progress, Internet-Draft, draft-ietf-opsawg-l2nm-19, , <https://datatracker.ietf.org/doc/html/draft-ietf-opsawg-l2nm-19>.
- [I-D.ietf-teas-ietf-network-slices]
- Farrel, A., Drake, J., Rokui, R., Homma, S., Makhijani, K., Contreras, L. M., and J. Tantsura, "Framework for IETF Network Slices", Work in Progress, Internet-Draft, draft-ietf-teas-ietf-network-slices-12, , <https://datatracker.ietf.org/doc/html/draft-ietf-teas-ietf-network-slices-12>.
- [I-D.ietf-teas-ietf-network-slice-nbi-yang]
- Wu, B., Dhody, D., Rokui, R., Saad, T., and L. Han, "IETF Network Slice Service YANG Model", Work in Progress, Internet-Draft, draft-ietf-teas-ietf-network-slice-nbi-yang-01, , <https://datatracker.ietf.org/doc/html/draft-ietf-teas-ietf-network-slice-nbi-yang-01>.
- [I-D.ietf-teas-ns-ip-mpls]
- Saad, T., Beeram, V. P., Dong, J., Wen, B., Ceccarelli, D., Halpern, J., Peng, S., Chen, R., Liu, X., Contreras, L. M., Rokui, R., and L. Jalil, "Realizing Network Slices in IP/MPLS Networks", Work in Progress, Internet-Draft, draft-ietf-teas-ns-ip-mpls-00, , <https://datatracker.ietf.org/doc/html/draft-ietf-teas-ns-ip-mpls-00>.
- [I-D.ietf-teas-rfc3272bis]
- Farrel, A., "Overview and Principles of Internet Traffic Engineering", Work in Progress, Internet-Draft, draft-ietf-teas-rfc3272bis-16, , <https://datatracker.ietf.org/doc/html/draft-ietf-teas-rfc3272bis-16>.
- [I-D.geng-teas-network-slice-mapping]
- Geng, X., Dong, J., Pang, R., Han, L., Rokui, R., Jin, J., and J. Tantsura, "5G End-to-end Network Slice Mapping from the view of Transport Network", Work in Progress, Internet-Draft, draft-geng-teas-network-slice-mapping-05, , <https://datatracker.ietf.org/doc/html/draft-geng-teas-network-slice-mapping-05>.
- [I-D.henry-tsvwg-diffserv-to-qci]
- Henry, J., Szigeti, T., and L. M. C. Murillo, "Diffserv to QCI Mapping", Work in Progress, Internet-Draft, draft-henry-tsvwg-diffserv-to-qci-04, , <https://datatracker.ietf.org/doc/html/draft-henry-tsvwg-diffserv-to-qci-04>.
- [TS-23.501]
- 3GPP, "TS 23.501: System architecture for the 5G System (5GS)", , <https://portal.3gpp.org/desktopmodules/Specifications/SpecificationDetails.aspx?specificationId=3144>.
- [TS-28.530]
- 3GPP, "TS 23.530: Management and orchestration; Concepts, use cases and requirements)", , <https://portal.3gpp.org/desktopmodules/Specifications/SpecificationDetails.aspx?specificationId=3273>.
- [O-RAN.WG9.XPSAAS]
- O-RAN Alliance, "O-RAN.WG9.XPSAAS: O-RAN WG9 Xhaul Packet Switched Architectures and Solutions Version 02.00", , <https://www.o-ran.org/specifications>.
- [NG.113]
- GSMA, "NG.113: 5GS Roaming Guidelines Version 4.0", , <https://www.gsma.com/newsroom/wp-content/uploads//NG.113-v4.0.pdf>.
Appendix A. Acronyms and Abbreviations
3GPP: 3rd Generation Partnership Project¶
5GC: 5G Core¶
5QI: 5G QoS Indicator¶
A2A: Any-to-Any¶
AC: Attachment Circuit¶
AMF: Access and Mobility Management Function¶
AUSF: Authentication Server Function¶
BBU: Baseband Unit¶
BH: Backhaul¶
BS: Base Station¶
CE: Customer Edge¶
CIR: Committed Information Rate¶
CN: Core Network¶
CoS: Class of Service¶
CP: Control Plane¶
CSP: Communication Service Provider¶
CU: Centralized Unit¶
CU-CP: Centralized Unit Control Plane¶
CU-UP: Centralized Unit User Plane¶
DC: Data Center¶
DDoS: Distributed Denial of Services¶
DN: Data Network¶
DSCP: Differentiated Services Code Point¶
DU: Distributed Unit¶
eCPRI: enhanced Common Public Radio Interface¶
FH: Fronthaul¶
FIB: Forwarding Information Base¶
GPRS: Generic Packet Radio Service¶
gNB: gNodeB¶
GTP: GPRS Tunneling Protocol¶
GTP-U: GPRS Tunneling Protocol User plane¶
HW: Hardware¶
ID: Identifier¶
IGP: Interior Gateway Protocol¶
IP: Internet Protocol¶
L2VPN: Layer 2 Virtual Private Network¶
L3VPN: Layer 3 Virtual Private Network¶
LSP: Label Switched Path¶
MH: Midhaul¶
MIoT: Massive Internet of Things¶
MPLS: Multiprotocol Label Switching¶
NF: Network Function¶
NR: New Radio¶
NRF: Network Function Repository¶
NRP: Network Resource Partition¶
NSC: Network Slice Controller¶
NSS: Network Slice Subnet¶
PE: Provider Edge¶
PIR: Peak Information Rate¶
PLMN: Public Land Mobile Network¶
PSTN: Public Switched Telephony Network¶
QoS: Quality of Service¶
RAN: Radio Access Network¶
RF: Radio Frequency¶
RIB: Routing Information Base¶
RSVP: Resource Reservation Protocol¶
RU: Radio Unit¶
SD: Slice Differentiator¶
SDP: Service Demarcation Point¶
SLA: Service Level Agreement¶
SLO: Service Level Objective¶
SMF: Session Management Function¶
SMO: Service Management and Orchestration¶
S-NSSAI: Single Network Slice Selection Assistance Information¶
SST: Slice/Service Type¶
SR: Segment Routing¶
SRv6: Segment Routing version 6¶
TC: Traffic Class¶
TE: Traffic Engineering¶
TN: Transport Network¶
TS: Technical Specification¶
UDM: Unified Data Management¶
UE: User Equipment¶
UP: User Plane¶
UPF: User Plane Function¶
URLLC: Ultra Reliable Low Latency Communication¶
VLAN: Virtual Local Area Network¶
VNF: Virtual Network Function¶
VPN: Virtual Private Network¶
VRF: Virtual Routing and Forwarding¶
VXLAN: Virtual Extensible Local Area Network¶
Acknowledgements
The authors would like to thank Tarek Saad for his review of this document and for providing valuable feedback on it.¶
Contributors
To be added later¶