Internet Engineering Task Force (IETF) N. Bitar, Ed. Request for Comments: 6934 Verizon Category: Informational S. Wadhwa, Ed. ISSN: 2070-1721 Alcatel-Lucent T. Haag Deutsche Telekom H. Li Huawei Technologies June 2013
Applicability of the Access Node Control Mechanism to Broadband Networks Based on Passive Optical Networks (PONs)
Abstract
The purpose of this document is to provide applicability of the Access Node Control Mechanism to broadband access based on Passive Optical Networks (PONs). The need for an Access Node Control Mechanism between a Network Access Server (NAS) and an Access Node Complex, composed of a combination of Optical Line Termination (OLT) and Optical Network Termination (ONT) elements, is described in a multi-service reference architecture in order to perform QoS-related, service-related, and subscriber-related operations. The Access Node Control Mechanism is also extended for interaction between components of the Access Node Complex (OLT and ONT). The Access Node Control Mechanism will ensure that the transmission of information between the NAS and Access Node Complex (ANX) and between the OLT and ONT within an ANX does not need to go through distinct element managers but rather uses direct device-to-device communication and stays on net. This allows for performing access-link-related operations within those network elements to meet performance objectives.
Status of This Memo
This document is not an Internet Standards Track specification; it is published for informational purposes.
This document is a product of the Internet Engineering Task Force (IETF). It represents the consensus of the IETF community. It has received public review and has been approved for publication by the Internet Engineering Steering Group (IESG). Not all documents approved by the IESG are a candidate for any level of Internet Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata, and how to provide feedback on it may be obtained at http://www.rfc-editor.org/info/rfc6934.
Bitar, et al. Informational [Page 1]
RFC 6934 ANCP in PON-Based Networks June 2013
Copyright Notice
Copyright (c) 2013 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 (http://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 Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
Table of Contents
1. Introduction ....................................................3 2. Terminology .....................................................4 3. Motivation for Explicit Extension of ANCP to FTTx PON ...........6 4. Reference Model for PON-Based Broadband Access Network ..........7 4.1. Functional Blocks ..........................................9 4.1.1. Home Gateway ........................................9 4.1.2. PON Access ..........................................9 4.1.3. Access Node Complex ................................10 4.1.4. Access Node Complex Uplink to the NAS ..............10 4.1.5. Aggregation Network ................................10 4.1.6. Network Access Server ..............................10 4.1.7. Regional Network ...................................10 4.2. Access Node Complex Control Reference Architecture Options ...................................................11 4.2.1. ANCP+OMCI ANX Control ..............................11 4.2.2. All-ANCP ANX Control ...............................12 5. Concept of Access Node Control Mechanism for PON-Based Access ..13 6. Multicast ......................................................16 6.1. Multicast Conditional Access ..............................16 6.2. Multicast Admission Control ...............................18 6.3. Multicast Accounting ......................................30 7. Remote Connectivity Check ......................................31 8. Access Topology Discovery ......................................32 9. Access Loop Configuration ......................................34 10. Security Considerations .......................................34 11. Differences in ANCP Applicability between DSL and PON .........35 12. ANCP versus OMCI between the OLT and ONT/ONU ..................36 13. Acknowledgements ..............................................37 14. References ....................................................37 14.1. Normative References .....................................37 14.2. Informative References ...................................38
Passive Optical Networks (PONs) based on Broadband PON (BPON) [G.983.1] and Gigabit PON (GPON) [G.984.1] are being deployed across carrier networks. There are two models for PON deployment: Fiber to the Building/Curb (FTTB/FTTC) and Fiber to the Premises (FTTP). In the FTTB/C deployment, the last-mile connectivity to the subscriber premises is provided over the local copper loop, often using Very High Speed Digital Subscriber Line (VDSL). In the FTTP case, PON extends to the premises of the subscriber. In addition, there are four main PON technologies: (1) BPON, (2) GPON, (3) 10-Gigabit PON (XG-PON), and (4) Ethernet PON (EPON). This document describes the applicability of the Access Node Control Protocol (ANCP) in the context of FTTB/C and FTTP deployments, focusing on BPON, GPON, and XG-PON. Architectural considerations lead to different ANCP compositions. Therefore, the composition of ANCP communication between Access Nodes (ANs) and Network Access Servers (NASs) is described using different models.
BPON, GPON, and XG-PON in FTTP deployments provide large bandwidth in the first mile, bandwidth that is an order of magnitude larger than that provided by xDSL. In the downstream direction, BPON provides 622 Mbit/s per PON, GPON provides 2.4 Gbit/s, and XG-PON provides 10 Gbit/s.
In residential deployments, the number of homes sharing the same PON is limited by the technology and the network engineering rules. Typical deployments have 32-64 homes per PON.
The motive behind BPON, GPON, and XG-PON deployment is to provide triple-play services over IP: voice, video, and data. Voice is generally low bandwidth but has requirements for low delay, low jitter, and low packet loss. Data services (e.g., Internet services) often require high throughput and can tolerate medium latency. Data services may include multimedia content download such as video. However, in that case, the video content is not required to be real- time, and/or it is low-quality video. Video services, on the other hand, are targeted to deliver Standard Definition or High Definition video content in real time or near real time, depending on the service model. Standard Definition content using MPEG2 encoding requires on the order of 3.75 Mbit/s per stream while High Definition content using MPEG2 encoding requires 15-19 Mbit/s depending on the level of compression used. Video services require low jitter and low packet loss with low start-time latency. There are two types of video services: on demand and broadcast (known also as linear programming content). While linear programming content can be provided over Layer 1 on the PON, the focus in this document is on
Bitar, et al. Informational [Page 3]
RFC 6934 ANCP in PON-Based Networks June 2013
delivering linear programming content over IP to the subscriber using IP multicast. Video on Demand (VoD) is also considered for delivery to the subscriber over IP using a unicast session model.
Providing simultaneous triple-play services over IP with unicast video and multicast video, VoIP, and data requires an architecture that preserves the quality of service of each service. Fundamental to this architecture is ensuring that the video content (unicast and multicast) delivered to the subscriber does not exceed the bandwidth allocated to the subscriber for video services. Architecture models often ensure that data is guaranteed a minimum bandwidth and that VoIP is guaranteed its own bandwidth. In addition, QoS control across services is often performed at a Network Access Server (NAS), often referred to as Broadband Network Gateway (BNG) for subscriber management, per subscriber and shared link resources. Efficient multicast video services require enabling multicast services in the access network between the subscriber and the subscriber management platform. In the FTTP/B/C PON environment, this implies enabling IP multicast on the ANX composed of the Optical Network Terminal (ONT) or Unit (ONU) and Optical Line Terminal (OLT), as applicable. This is as opposed to Digital Subscriber Line (DSL) deployments where multicast is enabled on the DSL Access Multiplexer (DSLAM) only. The focus in this document will be on the ANCP requirements needed for coordinated admission control of unicast and multicast video in FTTP/B/C PON environments between the ANX and the NAS, specifically focusing on bandwidth dedicated for multicast and shared bandwidth between multicast and unicast.
[RFC5851] provides the framework and requirements for coordinated admission control between a NAS and an AN with special focus on DSL deployments. This document extends that framework and the related requirements to explicitly address PON deployments.
- PON (Passive Optical Network) [G.983.1][G.984.1]: a point-to- multipoint FTTP network architecture in which unpowered splitters are used to enable the splitting of an optical signal from a central office on a single optical fiber to multiple premises. Up to 32-128 may be supported on the same PON. A PON configuration consists of an Optical Line Terminal (OLT) at the service provider's central office (CO) and a number of Optical Network Units or Terminals (ONUs/ONTs) near end users, with an Optical Distribution Network (ODN) composed of fibers and splitters between them. A PON configuration reduces the amount of fiber and CO equipment required compared with point-to-point architectures.
Bitar, et al. Informational [Page 4]
RFC 6934 ANCP in PON-Based Networks June 2013
- Access Node Complex (ANX): composed of two geographically separated functional elements -- OLT and ONU/ONT. The general term Access Node Complex (ANX) will be used when describing a functionality that does not depend on the physical location but rather on the "black box" behavior of OLT and ONU/ONT.
- Optical Line Terminal (OLT): is located in the service provider's central office (CO). It terminates and aggregates multiple PONs (providing fiber access to multiple premises or neighborhoods) on the subscriber side and interfaces with the Network Access Server (NAS) that provides subscriber management.
- Optical Network Terminal (ONT): terminates PON on the network side and provides PON adaptation. The subscriber side interface and the location of the ONT are dictated by the type of network deployment. For an FTTP deployment (with fiber all the way to the apartment or living unit), ONT has Ethernet (Fast Ethernet (FE) / Gigabit Ethernet (GE) / Multimedia over Coax Alliance (MoCA)) connectivity with the Home Gateway (HGW) / Customer Premises Equipment (CPE). In certain cases, one ONT may provide connections to more than one Home Gateway at the same time.
- Optical Network Unit (ONU): a generic term denoting a device that terminates any one of the distributed (leaf) endpoints of an Optical Distribution Network (ODN), implements a PON protocol, and adapts PON PDUs to subscriber service interfaces. In the case of a multi-dwelling unit (MDU) or multi-tenant unit (MTU), a multi- subscriber ONU typically resides in the basement or a wiring closet (FTTB case) and has FE/GE/Ethernet over native Ethernet link or over xDSL (typically VDSL) connectivity with each CPE at the subscriber premises. In the case where fiber is terminated outside the premises (neighborhood or curb side) on an ONT/ONU, the last-leg-premises connections could be via existing or new copper, with xDSL physical layer (typically VDSL). In this case, the ONU effectively is a "PON-fed DSLAM".
- Network Access Server (NAS): network element that aggregates subscriber traffic from a number of ANs or ANXs. The NAS is often an injection point for policy management and IP QoS in the access network. It is also referred to as Broadband Network Gateway (BNG) or Broadband Remote Access Server (BRAS).
- Home Gateway (HGW): network element that connects subscriber devices to the AN or ANX and the access network. In the case of xDSL, the Home Gateway is an xDSL network termination that could either operate as a Layer 2 bridge or as a Layer 3 router. In the
Bitar, et al. Informational [Page 5]
RFC 6934 ANCP in PON-Based Networks June 2013
latter case, such a device is also referred to as a Routing Gateway (RG). In the case of PON, it is often a Layer 3 routing device with the ONT performing PON termination.
- PON-Customer-ID: identifier that uniquely identifies the ANX and the access loop logical port on the ANX to the subscriber (customer) premises and is used in any interaction between NAS and ANX that relates to access loops. Logically, it is composed of information containing identification of the OLT (the OLT may be physically and directly connected to the NAS), the PON port on the OLT, the ONT/ONU, and the port on the ONT/ONU connecting to the subscriber HGW. When acting as a DHCP relay agent, the OLT can encode PON-Customer-ID in the "Agent Circuit ID" sub-option in Option 82 of the DHCP messages [RFC3046].
3. Motivation for Explicit Extension of ANCP to FTTx PON
The fundamental difference between PON and DSL is that a PON is an optical broadcast network by definition. That is, at the PON level, every ONT on the same PON sees the same signal. However, the ONT filters only those PON frames addressed to it. Encryption is used on the PON to prevent eavesdropping.
The broadcast PON capability is very suitable for delivering multicast content to connected premises, maximizing bandwidth usage efficiency on the PON. Similar to DSL deployments, enabling multicast on the Access Node Complex (ANX) provides for bandwidth use efficiency on the path between the Access Node and the NAS as well as improves the scalability of the NAS by reducing the amount of multicast traffic being replicated at the NAS. However, the broadcast capability on the PON enables the AN (OLT) to send one copy on the PON as opposed to one copy to each receiver on the PON. The PON multicast capability can be leveraged in the case of GPON and BPON as discussed in this document.
Fundamental to leveraging the broadcast capability on the PON for multicast delivery is the ability to assign no key, a single encryption key for all PON frames carrying all multicast channels, or a key per set of multicast channels that correspond to a service package. When supporting encryption for multicast channels, the encryption key is generated by the OLT and sent by the OLT to each targeted ONT via the ONT Management and Control Interface (OMCI) as described in Section 15.5.2 of ITU-T G.987.3 [G.987.3] for XG-PON. It should be noted that the ONT can be a multi-dwelling unit (MDU) ONT with multiple Ethernet ports, each connected to a living unit. Thus, the ONT must not only be able to receive a multicast frame but must also be able to forward that frame only to the Ethernet port with receivers for the corresponding channel.
Bitar, et al. Informational [Page 6]
RFC 6934 ANCP in PON-Based Networks June 2013
In order to implement triple-play service delivery with necessary "quality-of-experience", including end-to-end bandwidth optimized multicast video delivery, there needs to be tight coordination between the NAS and the ANX. This interaction needs to be near real- time as services are requested via application- or network-level signaling by broadband subscribers. ANCP, as defined in [RFC5851] for DSL based networks, is very suitable to realize a control protocol (with transactional exchange capabilities) between the PON- enabled ANX and the NAS and also between the components comprising the ANX, i.e., between the OLT and the ONT. Typical use cases for ANCP in the PON environment include the following:
- Access topology discovery - Access loop configuration - Multicast - Optimized multicast delivery - Unified video resource control - NAS-based provisioning of ANX - Remote connectivity check
4. Reference Model for PON-Based Broadband Access Network
An overall end-to-end reference architecture of a PON access network is depicted in Figures 1 and 2 with ONT serving a single HGW, and ONT/ONU serving multiples HGWs, respectively. An OLT may provide FTTP and FTTB/C access at the same time but most likely not on the same PON port. Specifically, the following PON cases are addressed in the context of this reference architecture:
- BPON with Ethernet uplink to the NAS and ATM on the PON side - GPON/XG-PON with Ethernet uplink to the NAS and Ethernet on the PON side
In the case of an Ethernet aggregation network that supports new QoS- enabled IP services (including Ethernet multicast replication), the architecture builds on the reference architecture specified in the Broadband Forum (BBF) [TR-101]. The Ethernet aggregation network between a NAS and an OLT may be degenerated to one or more direct physical Ethernet links.
Given the industry move towards Ethernet as the new access and aggregation technology for triple-play services, the primary focus throughout this document is on GPON/XG-PON and BPON with Ethernet between the NAS and the OLT.
The Home Gateway (HGW) connects the different CPEs to the ANX and the access network. In the case of PON, the HGW is a Layer 3 router. In this case, the HGW performs IP configuration of devices within the home via DHCP and performs Network Address and Port Translation (NAPT) between the LAN and WAN side. In the case of FTTP/B/C, the HGW connects to the ONT/ONU over an Ethernet interface. That Ethernet interface could be over an Ethernet physical port or over another medium. In the case of FTTP, it is possible to have a single box GPON CPE solution where the ONT encompasses the HGW functionality as well as the GPON adaptation function.
PON access is composed of the ONT/ONU and OLT. PON ensures physical connectivity between the ONT/ONU at the customer premises and the OLT. PON framing can be BPON or GPON. The protocol encapsulation on BPON is based on multi-protocol encapsulation over ATM Adaptation Layer 5 (AAL5), defined in [RFC2684]. This covers PPP over Ethernet (PPPoE, defined in [RFC2516]) or IP over Ethernet (IPoE). The protocol encapsulation on GPON is always IPoE. In all cases, the connection between the AN (OLT) and the NAS (or BNG) is assumed to be Ethernet in this document.
The ANX uplink connects the OLT to the NAS. The fundamental requirements for the ANX uplink are to provide traffic aggregation, Class of Service distinction, customer separation, and traceability. This can be achieved using an ATM or an Ethernet-based technology. As stated earlier, the focus in this document is on Ethernet.
The NAS is a network device that aggregates multiplexed subscriber traffic from a number of ANXs. The NAS plays a central role in per- subscriber policy enforcement and QoS. It is often referred to as a Broadband Network Gateway (BNG) or Broadband Remote Access Server (BRAS). A detailed definition of the NAS is given in [RFC2881]. The NAS interfaces to the aggregation network by means of 802.1Q or 802.1 Q-in-Q Ethernet interfaces and towards the Regional Network by means of transport interfaces (e.g., GigE, PPP over Synchronous Optical Network (SONET)). The NAS functionality corresponds to the BNG functionality described in BBF TR-101 [TR-101]. In addition, the NAS supports the Access Node Control functionality defined for the respective use cases in this document.
The Regional Network connects one or more NASs and associated access networks to Network Service Providers (NSPs) and Application Service Providers (ASPs). The NSP authenticates access and provides and manages the IP address to subscribers. It is responsible for overall service assurance and includes Internet Service Providers (ISPs). The ASP provides application services to the application subscriber (gaming, video, content on demand, IP telephony, etc.). The NAS can be part of the NSP network. Similarly, the NSP can be the ASP.
Bitar, et al. Informational [Page 10]
RFC 6934 ANCP in PON-Based Networks June 2013
4.2. Access Node Complex Control Reference Architecture Options
Section 3 details the differences between xDSL access and PON access and the implication of these differences on DSLAM control versus OLT and ONT/ONU (ANX) control. The following sections describe two reference models: (1) ANCP+OMCI ANX control and (2) All-ANCP ANX control. That is, the two models differ in the ONT/ONU control within the ANX. Choosing which model to implement may be based on the ONT/ONU type and the capabilities of the ONT/ONU and OLT; this is an implementation-specific decision that is outside the scope of this document. It is possible for an OLT or an OLT PON port to connect to ONTs/ONUs with different capabilities and for these two models to co- exist on the same OLT and same PON. Section 12 describes the differences between OMCI and ANCP in controlling the ONU/ONT.
OMCI is designed as a protocol between the OLT and ONT/ONU. It enables the OLT to configure and administer capabilities on the ONT/ONU in BPON, GPON, and XG-PON. ANCP is designed as a protocol between the NAS and Access Node. Among other functions, it enables the NAS to enforce dynamic policies on the Access Node and the Access Node to report events to the NAS.
Figure 3 depicts the reference model for ANCP+OMCI ANX control. In this model, ANCP is enabled between the NAS and a connected OLT, and OMCI is enabled between the OLT and an attached ONT/ONU. NAS communicates with the ANX via ANCP. The OLT acts as an ANCP/OMCI gateway for communicating necessary events and policies between the OLT and ONT/ONU within the ANX and for communicating relevant policies and events between the ONT/ONU and the NAS. The functionality performed by the OLT as an ANCP/OMCI gateway will be application dependent (e.g., multicast control, topology discovery) and should be specified in a related specification. It should be noted that some applications are expected to require ANCP and/or OMCI extensions to map messages between OMCI and ANCP. OMCI extensions are likely to be defined by the ITU-T. It should also be noted that in addition to configuration and administration, OMCI provides the capability to report status changes on an ONT/ONU with AVC (Attribute Value Change) notifications. When the ONT/ONU's DSL or Ethernet User-Network Interface (UNI) attributes change, a related Management Entity will send a corresponding notification (AVC) to the OLT. The OLT interworks such a notification into an ANCP report and sends it to the connected NAS via the ANCP session between the OLT and the NAS. As the ANCP report contains information of ONT/ONU's UNI and OLT's PON port, NAS can obtain accurate information of access topology.
Figure 4 depicts the All-ANCP ANX control reference model. In this model, an ANCP session is enabled between a NAS and a connected OLT, and another ANCP session is enabled between the OLT and a connected ONT/ONU. ANCP enables communication of policies and events between the OLT and the ANX. The OLT acts as a gateway to relay policies and events between the NAS and ONT/ONU within the ANX in addition to communicating policies and events between the OLT and ONT/ONU. It should be noted that in this model, OMCI (not shown) is expected to be simultaneously enabled between the ONT and OLT, supporting existing OMCI capabilities and applications on the PON, independent of ANCP or applications intended to be supported by ANCP.
HGW: Home Gateway NAS: Network Access Server PON: Passive Optical Network OLT: Optical Line Terminal ONT: Optical Network Terminal ONU: Optical Network Unit
Figure 4: All-ANCP ANX Control Reference Model
5. Concept of Access Node Control Mechanism for PON-Based Access
The high-level communication framework for an Access Node Control Mechanism is shown in Figure 5 for the All-ANCP ANX control model. The Access Node Control Mechanism defines a quasi-real-time, general- purpose method for multiple network scenarios with an extensible communication scheme, addressing the different use cases that are described in the sections that follow. The Access Node Control Mechanism is also extended to run between OLT and ONT/ONU. The mechanism consists of a controller function and a reporting and/or enforcement function. The controller function is used to receive status information or admission requests from the reporting function. It is also used to trigger a certain behavior in the network element where the reporting and/or enforcement function resides.
The reporting function is used to convey status information to the controller function that requires the information for executing local functions. The enforcement function can be contacted by the
Bitar, et al. Informational [Page 13]
RFC 6934 ANCP in PON-Based Networks June 2013
controller function to enforce a specific policy or trigger a local action. The messages shown in Figure 5 show the conceptual message flow. The actual use of these flows, and the times or frequencies when these messages are generated, depend on the actual use cases, which are described in later sections.
Figure 5: Conceptual Message Flow for Access Node Control Mechanism in All-ANCP ANX Control Model
Bitar, et al. Informational [Page 14]
RFC 6934 ANCP in PON-Based Networks June 2013
As discussed previously, in different PON deployment scenarios, ANCP may be used in variant ways and may interwork with other protocols, e.g., OMCI. In the ANCP+OMCI control model described earlier, the NAS maintains ANCP adjacency with the OLT while the OLT controls the ONT/ONU via OMCI. The messages shown in Figure 6 show the conceptual message flow for this model. The actual use of these flows, and the times or frequencies when these messages are generated, depend on the actual use cases.
With the rise of supporting IPTV services in a resource-efficient way, multicast services are becoming increasingly important.
In order to gain bandwidth optimization with multicast, the replication of multicast content per access loop needs to be distributed to the ANX. This can be done by ANX (OLT and ONT/ONU) becoming multicast aware by implementing an IGMP [RFC3376] snooping and/or proxy function [RFC4605]. The replication thus needs to be distributed between NAS, aggregation nodes, and ANX. In the case of GPON and in the case of BPON with Ethernet uplink, this is very viable. By introducing IGMP processing on the ANX and aggregation nodes, the multicast replication process is now divided between the NAS, the aggregation node(s), and ANX. This is in contrast to the ATM-based model where NAS is the single element responsible for all multicast control and replication. In order to ensure backward compatibility with the ATM-based model, the NAS, aggregation node, and ANX need to behave as a single logical device. This logical device must have exactly the same functionality as the NAS in the ATM access/aggregation network. The Access Node Control Mechanism can be used to make sure that this logical/functional equivalence is achieved by exchanging the necessary information between the ANX and the NAS.
An alternative to multicast awareness in the ANX is for the subscriber to communicate the IGMP "join/leave" messages with the NAS, while the ANX is being transparent to these messages. In this scenario, the NAS can use ANCP to create replication state in the ANX for efficient multicast replication. The NAS sends a single copy of the multicast stream towards the ANX. The NAS can perform network- based conditional access and multicast admission control on multicast joins and create replication state in the ANX if the request is admitted by the NAS.
The following sections describe various use cases related to multicast.
In a broadband FTTP/B/C access scenario, service providers may want to dynamically control, at the network level, access to some multicast flows on a per user basis. This may be used in order to differentiate among multiple Service Offers or to realize/reinforce conditional access based on customer subscription. Note that, in some environments, application-layer conditional access by means of Digital Rights Management (DRM), for instance, may provide sufficient control so that network-based multicast conditional access may not be
Bitar, et al. Informational [Page 16]
RFC 6934 ANCP in PON-Based Networks June 2013
needed. However, network-level access control may add to the service security by preventing the subscriber from receiving a non-subscribed channel. In addition, it enhances network security by preventing a multicast stream from being sent on a link or a PON based on a non- subscriber request.
Where network-based channel conditional access is desired, there are two approaches. First, it can be done on the NAS along with bandwidth-based admission control. The NAS can control the replication state on the ANX based on the outcome of access and bandwidth-based admission control. This is covered in a later section. A second approach is to provision the necessary conditional access information on the ANX (ONT/ONU and/or OLT) so the ANX can perform the conditional access decisions autonomously. For these cases, the NAS can use ANCP to provision black and white lists as defined in [RFC5851] on the ANX so that the ANX can decide locally to honor a join or not. It should be noted that in the PON case, the ANX is composed of the ONT/ONU and OLT. Thus, this information can be programmed on the ONT/ONU and/or OLT. Programming this information on the ONT/ONU prevents illegitimate joins from propagating further into the network. A third approach, outside of the scope of this document, may be to program the HGW with the access list. A white list associated with an Access Port identifies the multicast channels that are allowed to be replicated to that port. A black list associated with an Access Port identifies the multicast channels that are not allowed to be replicated to that port. It should be noted that the black list, if not explicitly programmed, is the complement of the white list and vice versa.
If the ONT/ONU performs IGMP snooping and is programmed with a channel access list, the ONT/ONU will first check if the requested multicast channel is part of a white list or a black list associated with the Access Port on which the IGMP join is received. If the channel is part of a white list, the ONT/ONU will pass the join request upstream towards the NAS. The ONT/ONU must not start replicating the associated multicast stream to the Access Port if such a stream is received until it gets confirmation that it can do so from the upstream node (NAS or OLT). Passing the channel access list is one of the admission control criteria whereas bandwidth-based admission control is another. If the channel is part of a black list, the ONT/ONU can autonomously discard the message because the channel is not authorized for that subscriber.
The ONT/ONU, in addition to forwarding the IGMP join, sends an ANCP admission request to the OLT identifying the channel to be joined and the premises. Premises identification to the OLT can be based on a Customer-Port-ID that maps to the Access Port on the ONT/ONU and is known at the ONT/ONU and OLT. If the ONT/ONU has a white list and/or
Bitar, et al. Informational [Page 17]
RFC 6934 ANCP in PON-Based Networks June 2013
a black list per premises, the OLT need not have such a list. If the ONT/ONU does not have such a list, the OLT may be programmed with such a list for each premises. In the latter case, the OLT would perform the actions described earlier on the ONT/ONU. Once the outcome of admission control (conditional access and bandwidth-based admission control) is determined by the OLT (either by interacting with the NAS or locally), it is informed to the ONT/ONU. OLT bandwidth-based admission control scenarios are defined in a later section.
The white list and black list can contain entries allowing:
- An exact match for a (*,G) Any-Source Multicast (ASM) group (e.g., <G=g.h.i.l>)
- An exact match for a (S,G) Source-Specific Multicast (SSM) channel (e.g., <S=s.t.u.v,G=g.h.i.l>)
- A mask-based range match for a (*,G) ASM group (e.g., <G=g.h.i.l/Mask>)
- A mask-based range match for a (S,G) SSM channel (e.g., <S=s.t.u.v,G=g.h.i.l/Mask>)
The use of a white list and black list may be applicable, for instance, to regular IPTV services (i.e., Broadcast TV) offered by an Access Provider to broadband (e.g., FTTP) subscribers. For this application, the IPTV subscription is typically bound to a specific FTTP home, and the multicast channels that are part of the subscription are well-known beforehand. Furthermore, changes to the conditional access information are infrequent, since they are bound to the subscription. Hence, the ANX can be provisioned with the conditional access information related to the IPTV service.
Instead of including the channel list(s) at the ONT/ONU, the OLT or NAS can be programmed with these access lists. Having these access lists on the ONT/ONU prevents forwarding of unauthorized joins to the OLT or NAS, reducing unnecessary control load on these network elements. Similarly, performing the access control at the OLT instead of the NAS, if not performed on the ONT/ONU, will reduce unnecessary control load on the NAS.
The successful delivery of triple-play broadband services is quickly becoming a big capacity-planning challenge for most of the service providers nowadays. Solely increasing available bandwidth is not always practical, cost-economical, and/or sufficient to satisfy end-
Bitar, et al. Informational [Page 18]
RFC 6934 ANCP in PON-Based Networks June 2013
user experience given not only the strict QoS requirements of unicast applications like VoIP and Video on Demand but also the fast growth of multicast interactive applications such as "video conferencing", digital TV, and digital audio. These applications typically require low delay, low jitter, low packet loss, and high bandwidth. These applications are also typically "non-elastic", which means that they operate at a fixed bandwidth that cannot be dynamically adjusted to the currently available bandwidth.
An Admission Control (AC) Mechanism covering admission of multicast traffic for the FTTP/B/C access is required in order to avoid over- subscribing the available bandwidth and negatively impacting the end- user experience. Before honoring a user request to join a new multicast flow, the combination of ANX and NAS must ensure admission control is performed to validate that there is enough video bandwidth remaining on the PON and on the uplink between the OLT and NAS to carry the new flow (in addition to all other existing multicast and unicast video traffic) and that there is enough video bandwidth for the subscriber to carry that flow. The solution needs to cope with multiple flows per premises and needs to allow bandwidth to be dynamically shared across multicast and unicast video traffic per subscriber, PON, and uplink (irrespective of whether unicast AC is performed by the NAS or by some off-path policy server). It should be noted that the shared bandwidth between multicast and unicast video is under operator control. That is, in addition to the shared bandwidth, some video bandwidth could be dedicated to Video on Demand, while other video bandwidth could be dedicated for multicast.
The focus in this document is on multicast-allocated bandwidth including the shared unicast and multicast bandwidth. Thus, supporting admission control requires some form of synchronization between the entities performing multicast AC (e.g., the ANX and/or NAS), the entity performing unicast AC (e.g., the NAS or a policy server), and the entity actually enforcing the multicast replication (i.e., the NAS and the ANX). This synchronization can be achieved in a number of ways.
One approach is for the NAS to perform bandwidth-based admission control on all multicast video traffic and unicast video traffic that requires using the shared bandwidth with multicast. Based on the outcome of admission control, NAS then controls the replication state on the ANX. The subscriber generates an IGMP join for the desired stream on its logical connection to the NAS. The NAS terminates the IGMP message and performs conditional access and bandwidth-based admission control on the IGMP request. The bandwidth admission control is performed against the following:
Bitar, et al. Informational [Page 19]
RFC 6934 ANCP in PON-Based Networks June 2013
1. Available video bandwidth on the link to OLT
2. Available video bandwidth on the PON interface
3. Available video bandwidth on the last mile (Access Port on the ONT/ONU)
The NAS can locally maintain and track video bandwidth it manages for all the three levels mentioned above. The NAS can maintain identifiers corresponding to the PON interface and the last mile (customer interface). It also maintains a channel map, associating every channel (or a group of channels sharing the same bandwidth requirement) with a data rate. For instance, in the case of 1:1 VLAN representation of the premises, the outer tag (S-VLAN) could be inserted by the ANX to correspond to the PON interface on the OLT, and the inner-tag could be inserted by the ANX to correspond to the access-line towards the customer. Bandwidth tracking and maintenance for the PON interface and the last mile could be done on these VLAN identifiers. In the case of N:1 representation, the single VLAN inserted by ANX could correspond to the PON interface on the OLT. The access loop is represented via Customer-Port-ID received in the "Agent Circuit ID" sub-option in DHCP messages.
The NAS can perform bandwidth accounting on received IGMP messages. The video bandwidth is also consumed by any unicast video being delivered to the CPE. NAS can perform video bandwidth accounting and control on both IGMP messages and on requests for unicast video streams when either all unicast admission control is done by the NAS or an external policy server makes a request to the NAS for using shared bandwidth with multicast as described later in the document.
This particular scenario assumes the NAS is aware of the bandwidth on the PON and can track the changes in available bandwidth on the PON under all conditions. On receiving an IGMP join message, NAS will perform bandwidth check on the subscriber bandwidth. If this passes and the stream is already being forwarded on the PON by the OLT (which also means that it is already forwarded by the NAS to the OLT), NAS will admit the join, update the available subscriber bandwidth, and transmit an ANCP message to the OLT and in turn to the ONT/ONU to start replication on the customer port. If the stream is not already being replicated to the PON by the OLT, the NAS will also check the available bandwidth on the PON, and if it is not already being replicated to the OLT, it will check the bandwidth on the link towards the OLT. If this passes, the available PON bandwidth and the bandwidth on the link towards the OLT are updated. The NAS adds the OLT as a leaf to the multicast tree for that stream. On receiving the message to start replication, the OLT will add the PON interface to its replication state if the stream is not already being forwarded
Bitar, et al. Informational [Page 20]
RFC 6934 ANCP in PON-Based Networks June 2013
on that PON. Also, the OLT will send an ANCP message to direct the ONT/ONU to add or update its replication state with the customer port for that channel. The interaction between ANX and NAS is shown in Figures 7 and 8. For unicast video streams, application-level signaling from the CPE typically triggers an application server to request bandwidth-based admission control from a policy server. The policy server can, in turn, interact with the NAS to request the bandwidth for the unicast video flow if it needs to use shared bandwidth with multicast. If the bandwidth is available, NAS will reserve the bandwidth; update the bandwidth pools for subscriber bandwidth, the PON bandwidth, and the bandwidth on the link towards the OLT; and send a response to the policy server, which is propagated back to the application server to start streaming. Otherwise, the request is rejected.
Figure 7: Interactions for NAS-Based Multicast Admission Control (No IGMP Processing on ANX and NAS Maintains Available Video Bandwidth for PON) upon Channel Join
Figure 8: Interactions for NAS-Based Multicast Admission Control (No IGMP Processing on ANX and NAS Maintains Available Video Bandwidth for PON) upon Channel Leave
An alternate approach is required if the NAS is not aware of the bandwidth on the PON. In this case, the OLT does the PON bandwidth management and requests NAS to perform bandwidth admission control on subscriber bandwidth and the bandwidth on the link to the OLT. Following are operations of various elements:
ANX operation:
- ONT/ONU can snoop IGMP messages. If conditional access is configured and the channel is in the black list (or it is not on the white list), ONT will drop the IGMP join. If the channel
Bitar, et al. Informational [Page 23]
RFC 6934 ANCP in PON-Based Networks June 2013
passes the conditional access check, the ONT will forward the IGMP join and will send a bandwidth admission control request to the OLT. If the multicast stream is already being received on the PON, the ONT/ONU does not forward the stream to the Access Port where IGMP is received until it has received a positive admission control response from the OLT.
- OLT can snoop IGMP messages. It also receives a bandwidth admission control request from the ONT/ONU for the requested channel. It can be programmed with a channel bandwidth map. If the multicast channel is already being streamed on the PON or the channel bandwidth is less than the available multicast bandwidth on the PON, the OLT forwards the IGMP request to the NAS and keeps track of the subscriber (identified by Customer-Port-ID) as a receiver. If the channel is not already being streamed on the PON but the PON has sufficient bandwidth for that channel, the OLT reduces the PON multicast video bandwidth by the channel bandwidth and may optionally add the PON to the multicast tree without activation for that channel. This is biased towards a forward expectation that the request will be accepted at the NAS. The OLT forwards the IGMP join to the NAS. It also sends a bandwidth admission request to the NAS identifying the channel and the premises for which the request is made. It sets a timer for the subscriber multicast entry within which it expects to receive a request from the NAS that relates to this request. If the available PON bandwidth is less than the bandwidth of the requested channel, the OLT sends an admission response (with a reject) to the ONT/ONU and does not forward the IGMP join to the NAS.
NAS operation:
The NAS receives the IGMP join from the subscriber on the subscriber connection. When NAS receives the admission control request from ANX (also signifying the bandwidth on the PON is available), it performs admission control against the subscriber's available multicast bandwidth. If this check passes, and the NAS is already transmitting that channel to the OLT, the request is accepted. If the check passes and the NAS is not transmitting the channel to the OLT yet, it performs admission control against the available multicast video bandwidth (this includes the dedicated multicast bandwidth and the shared bandwidth between multicast and Video on Demand) on the link(s) to the OLT. If the check passes, the request is accepted, the available video bandwidth for the subscriber and downlink to the OLT are reduced by the channel bandwidth, and the NAS sends an ANCP admission control response (indicating accept) to the OLT, requesting the addition of the subscriber to the multicast tree for that channel. The OLT activates the corresponding multicast entry if not
Bitar, et al. Informational [Page 24]
RFC 6934 ANCP in PON-Based Networks June 2013
active and maintains state of the subscriber in the list of receivers for that channel. The OLT also sends an ANCP request to the ONT/ONU to enable reception of the multicast channel and forwarding to the subscriber Access Port. Otherwise, if the request is rejected, the NAS will send an admission reject to the OLT, which, in turn, removes the subscriber as a receiver for that channel (if it was added) and credits back the channel bandwidth to the PON video bandwidth if there is no other receiver on the PON for that channel. The interactions between ANX and NAS are shown in Figures 9 and 10.
If the OLT does not receive a response from the NAS within a set timer, the OLT removes the subscriber from the potential list of receivers for the indicated channel. It also returns the allocated bandwidth to the available PON bandwidth if there are no other receivers. In this case, the NAS may send a response to the OLT with no matching entry as the entry has been deleted. The OLT must perform admission control against the available PON bandwidth and may accept the request and send an ANCP request to the ONT/ONU to activate the corresponding multicast entry as described earlier. If it does not accept the request, it will respond back to the NAS with a reject. The NAS shall credit back the channel bandwidth to the subscriber. It shall also stop sending the channel to the OLT if that subscriber was the last leaf on the multicast tree towards the OLT.
On processing an IGMP leave, the OLT will send an ANCP request to NAS to release resources. NAS will release the subscriber bandwidth. If this leave causes the stream to be no longer required by the OLT, the NAS will update its replication state and release the bandwidth on the NAS to OLT link.
If the subscriber makes a request for a unicast video stream (i.e., Video on Demand), the request results in appropriate application- level signaling, which typically results in an application server requesting a policy server for bandwidth-based admission control for the VoD stream. After authorizing the request, the policy server can send a request to the NAS for the required bandwidth if it needs to use bandwidth that is shared with multicast. This request may be based on a protocol outside of the scope of this document. The NAS checks if the available video bandwidth (accounting for both multicast and unicast) per subscriber and for the link to the OLT is sufficient for the request. If it is, it temporarily reserves the bandwidth and sends an ANCP admission request to the OLT for the subscriber, indicating the desired VoD bandwidth. If the OLT has sufficient bandwidth on the corresponding PON, it reserves that bandwidth and returns an accept response to the NAS. If not, it returns a reject to the NAS. If the NAS receives an accept, it returns an accept to the policy server, which, in turn, returns an
Bitar, et al. Informational [Page 25]
RFC 6934 ANCP in PON-Based Networks June 2013
accept to the application server, and the video stream is streamed to the subscriber. This interaction is shown in Figure 11. If the NAS does not accept the request from the policy server, it returns a reject. If the NAS receives a reject from the OLT, it returns the allocated bandwidth to the subscriber and the downlink to the OLT.
It should be noted that similar functionality to that described in this section and depicted in Figures 9, 10, and 11 will be required when OMCI is enabled between the OLT and ONT/ONU in the ANCP+OMCI ANX control model. In the latter case, the OLT will act as an ANCP-OMCI gateway.
Figure 11: Interactions for VoD Bandwidth Admission Control in the All-ANCP ANX Control Model
A third possible approach is where the ANX is assumed to have full knowledge to make an autonomous decision on admitting or rejecting a multicast and a unicast join. With respect to the interaction between ONT/ONU and OLT, the procedure is similar to the first approach (i.e., NAS-controlled replication). However, when the OLT receives an IGMP request from a subscriber, it performs admission control against that subscriber multicast video bandwidth (dedicated
Bitar, et al. Informational [Page 29]
RFC 6934 ANCP in PON-Based Networks June 2013
and shared with Video on Demand), the PON, and uplink to the NAS. It should be noted in this case that if there are multiple NAS-OLT links, either the link on which the multicast stream must be sent is pre-determined, needs to be selected by the OLT based on downstream bandwidth from NAS to OLT and the selection is communicated to the NAS, or the OLT has to be ready to receive the stream on any link. If the check passes, the OLT updates the available video bandwidth per PON and subscriber. The OLT adds the subscriber to the list of receivers and the PON to the multicast tree if it is not already on it. It also sends an ANCP request to the ONT/ONU to add the subscriber Access Port to that channel multicast tree and sends an ANCP message to the NAS informing it of the subscriber and link available video bandwidth and the channel the subscriber joined. The NAS, upon receiving the ANCP information message, updates the necessary information, including the OLT to the multicast tree if it is not already on it. It should be noted in this case that the ANCP message from the OLT to the NAS is being used to add the OLT to a multicast tree as opposed to an IGMP message. The IGMP message can also be sent by the OLT with the OLT acting as an IGMP proxy at the expense of added messages. In this option, the OLT acts as the network IGMP router for the subscriber.
For unicast video streams, the policy server receiving an admission request from an application server, as described before, may query the OLT for admission control as it has all information. If the OLT has sufficient bandwidth for the stream, it reserves that bandwidth for the subscriber, the PON, and OLT uplink to the NAS and returns an accept to the policy server. It also updates the NAS (via an ANCP message) of the subscriber's available video bandwidth. If the OLT rejects the policy server request, it will return a reject to the policy server.
It should be noted that if the policy server adjacency is with the NAS, the policy server may make the admission request to the NAS. The NAS then sends an ANCP admission request to the OLT on behalf of the policy server. The NAS returns an accept or reject to the policy server if it gets a reject or accept, respectively, from the OLT.
It may be desirable to perform accurate time- or volume-based accounting per user or per access loop. If the ANX is performing the traffic replication process, it knows when replication of a multicast flow to a particular Access Port or user starts and stops. Multicast accounting can be addressed in two ways:
Bitar, et al. Informational [Page 30]
RFC 6934 ANCP in PON-Based Networks June 2013
- ANX keeps track of when replication starts or stops and reports this information to the NAS for further processing. In this case, ANCP can be used to send the information from the ANX to the NAS. This can be done with the Information Report message. The NAS can then generate the appropriate time and/or volume accounting information per access loop and per multicast flow to be sent to the accounting system. The ANCP requirements to support this approach are specified in [RFC5851]. If the replication function is distributed between the OLT and ONT/ONU, a query from the NAS will result in OLT generating a query to the ONT/ONU.
- ANX keeps track of when replication starts or stops and generates the time- and/or volume-based accounting information per access loop and per multicast flow, before sending it to a central accounting system for logging. Since ANX communicates with this accounting system directly, the approach does not require the use of ANCP. It is therefore beyond the scope of this document. It may also be desirable for the NAS to have the capability to asynchronously query the ANX to obtain an instantaneous status report related to multicast flows currently replicated by the ANX. Such a reporting functionality could be useful for troubleshooting and monitoring purposes. If the replication function in the ANX is distributed between the OLT and the ONT/ONU, then for some of the information required by the NAS (such as the list of Access Ports on which a flow is being forwarded or list of flows being forwarded on an Access Port), a query to the OLT from the NAS will result in a query from the OLT to the ONT/ONU. The OLT responds back to the NAS when it receives the response from the ONT/ONU. Also, if the list of PONs on which replication is happening for a multicast channel or the list of channels being replicated on a PON is what is desired, the OLT can return this information.
In an end-to-end Ethernet aggregation network, end-to-end Ethernet Operations, Administration, and Maintenance (OAM), as specified in IEEE 802.1ag [802.1ag] and ITU-T Recommendation Y.1730/1731 [Y.1731], can provide access loop connectivity testing and fault isolation. However, most HGWs do not yet support these standard Ethernet OAM procedures. Also, in a mixed Ethernet and ATM access network (e.g., Ethernet-based aggregation upstream from the OLT and BPON downstream), interworking functions for end-to-end OAM are not yet standardized or widely available. Until such mechanisms become standardized and widely available, the Access Node Control Mechanism between NAS and ANX can be used to provide a simple mechanism to test connectivity of an access loop from the NAS.
Bitar, et al. Informational [Page 31]
RFC 6934 ANCP in PON-Based Networks June 2013
Triggered by a local management interface, the NAS can use the Access Node Control Mechanism (Control Request message) to initiate an access loop test between an Access Node and a HGW or ONT/ONU. On reception of the ANCP message, the OLT can trigger native OAM procedures defined for BPON in [G.983.1] and for GPON in [G.984.1]. The Access Node can send the result of the test to the NAS via a Control Response message.
In order to avoid congestion in the network, manage and utilize the network resources better, and ensure subscriber fairness, NAS performs hierarchical shaping and scheduling of the traffic by modeling different congestion points in the network (such as the last mile, Access Node uplink, and the access-facing port).
Such mechanisms require that the NAS gains knowledge about the topology of the access network, the various links being used, and their respective rates. Some of the information required is somewhat dynamic in nature (e.g., DSL line rate if the last mile is xDSL based, such as in the case of "PON-fed DSLAMs" for FTTC/FTTB scenarios) and hence cannot come from a provisioning and/or inventory management Operations Support System (OSS). Some of the information varies less frequently (e.g., capacity of the OLT uplink) but nevertheless needs to be kept strictly in sync between the actual capacity of the uplink and the image the NAS has of it.
OSSs are rarely able to enforce the consistency of such data in a reliable and scalable manner, notably across organizational boundaries under certain deployment scenarios. The Access Topology Discovery function allows the NAS to perform these advanced functions without having to depend on an error-prone and possibly complex integration with an OSS.
The rate of the access loop can be communicated via ANCP (Information Report message) from the ONT/ONU to the OLT in the All-ANCP ANX control model or via OMCI in the ANCP+OMCI ANX control model, and then from OLT to the NAS via ANCP. Additionally, during the time the DSL NT is active, data rate changes can occur due to environmental conditions (the DSL access loop can get "out of sync" and can retrain to a lower value, or the DSL access loop could use Seamless Rate Adaptation to make the actual data rate fluctuate while the line is active). In this case, ANX sends an additional Information Report to the NAS each time the access loop attributes change above a threshold value. Existing DSL procedures are not applicable in this case because an adapted message flow and additional TLVs are needed.
Figure 12: Message Flow for the Use Case of Topology Discovery for the ANCP+OMCI Control Model
Figure 12 depicts a message flow for topology discovery when using the ANCP+OMCI control model. Basically, when an ONT/ONU gets connected to a PON, the OLT detects a new device and a GPON Ranging process starts. During this process, the ONT/ONU becomes authorized by the OLT and identified by ONT/ONU ID, PON Port ID, and max Bandwidth. This port status is reported via ANCP to the NAS and then potentially the policy server via another mechanism that is out of scope of this document. In a second step, after the GPON service profile is assigned from OLT to ONT/ONU, the OLT reports the final status to NAS with information about the service profile and other information such as the ONT/ONU port rate to the subscriber, for instance.
Topology Discovery provides Access Port Identification to the NAS when sending an Access Port Discovery message. This informs NAS identification of a PON port on an Access Node. Based on Access Port Identification and on customer identification, service-related parameters could be configured on an OLT and an ONU/ONT.
Service-related parameters could be sent to OLT via ANCP before or after an ONU/ONT is up. Sending of ANCP loop configuration messages from NAS can be triggered by a management system or by customer identification and authentication after Topology Discovery. It may be used for first-time configuration (zero touch) or for updating/upgrading customer's profile like C-VLAN ID, S-VLAN ID, and service bandwidth.
Parameters of the User-Network Interface (UNI), which is the subscriber interface to HGW/CPE of ONU/ONT, can also be configured via ANCP. When the ONU/ONT supports ANCP, parameters of the UNI on ONU/ONT are sent to the ONU/ONT via ANCP. If the ONU/ONT does not support ANCP but only OMCI, parameters have to be sent from the NAS to the OLT via ANCP first. Then, the OLT translates such configuration into OMCI and sends it to the ONU/ONT.
[RFC5713] lists the ANCP-related security threats that could be encountered on the Access Node and the NAS. It develops a threat model for ANCP security and lists the security functions that are required at the ANCP level.
With multicast handling as described in this document, ANCP protocol activity between the ANX and the NAS is triggered by join/leave requests coming from the end-user equipment. This could potentially be used for a denial-of-service attack against the ANX and/or the NAS.
To mitigate this risk, the NAS and ANX may implement control plane protection mechanisms such as limiting the number of multicast flows a given user can simultaneously join or limiting the maximum rate of join/leave from a given user.
Protection against invalid or unsubscribed flows can be deployed via provisioning black lists as close to the subscriber as possible (e.g., in the ONT).
Bitar, et al. Informational [Page 34]
RFC 6934 ANCP in PON-Based Networks June 2013
User activity logging for accounting or tracking purposes could raise privacy concerns if not appropriately protected. To protect such information, logging/accounting information can be exchanged with the corresponding server over a secure channel, and the information can be stored securely with policy-driven controlled access.
11. Differences in ANCP Applicability between DSL and PON
As it currently stands, both ANCP framework [RFC5851] and protocol [RFC6320] are defined in the context of DSL access. Due to inherent differences between PON and DSL access technologies, ANCP needs a few extensions for supporting the use cases outlined in this document for PON-based access. These specific differences and extensions are outlined below.
- In PON, the access-node functionality is split between OLT and ONT. Therefore, ANCP interaction between NAS and AN translates to transactions between NAS and OLT and between OLT and ONT. The processing of ANCP messages (e.g., for multicast replication control) on the OLT can trigger generation of ANCP messages from OLT to ONT. Similarly, ANCP messages from ONT to the OLT can trigger ANCP exchange between the OLT and the NAS (e.g., admission request messages). This is illustrated in the generic message flows in Figures 5 and 6 of Section 5. In the case of DSL, the ANCP exchange is contained between two network elements (NAS and the DSLAM).
- The PON connection to the ONT is a shared medium between multiple ONTs on the same PON. In the case of DSL, the local loop is point-to-point. In the case of a DSL access network, the access- facing port on the NAS (i.e., port to the network between NAS and the DSLAM) and the access-facing ports on the DSLAM (i.e., customer's local loop) are the two bandwidth constraint points that need to be considered for performing bandwidth-based admission control for multicast video and VoD delivered to the customer. In the case of PON access, in addition to the bandwidth constraint on the NAS to OLT facing ports and the subscriber- allocated bandwidth for video services, the bandwidth available on the PON for video is an additional constraint that needs to be considered for bandwidth-based admission control. If the bandwidth control is centralized in the NAS (as described in the first approach in Section 6.2), then the NAS needs to support additional logic to consider available PON bandwidth before admitting a multicast request or a VoD request by the user. Accordingly, ANCP needs to identify the customer Access Port and the PON on which the customer ONT is. If the PON bandwidth control is performed on the OLT (as defined in the second approach in Section 6.2), then additional ANCP request and response
Bitar, et al. Informational [Page 35]
RFC 6934 ANCP in PON-Based Networks June 2013
messages are required for NAS to query the OLT to determine available PON bandwidth when a request to admit a VoD flow is received on the NAS (as shown in Figure 9 in Section 6.2) or for the OLT to inform the NAS what stream bandwidth is sent to the subscriber for the NAS to take appropriate action (e.g., bandwidth adjustment for various types of traffic).
- In PON, the multicast replication can potentially be performed on three different network elements: (1) on the NAS, (2) on the OLT for replication to multiple PON ports, and (3) on the ONT/ONU for replication to multiple customer ports. In the case of DSL, the replication can potentially be performed on NAS and/or the DSLAM. Section 6.2 defines options for multicast replication in the case of PON. In the first option, the multicast replication is done on the AN but is controlled from NAS via ANCP (based on the reception of per-customer IGMP messages on the NAS). In this option, the NAS needs to supply the OLT the set of PON-customer-IDs (as defined in Section 2) to which the multicast stream needs to be replicated. The PON-customer-ID identifies the OLT and the PON ports on the OLT as well as the ONT and the Access Ports on the ONT where the multicast stream needs to be replicated. Upon receiving the request to update its multicast replication state, the OLT must update its replication state with the indicated PON ports but may also need to interact with the ONT via ANCP to update the multicast replication state on the ONT with the set of Access Ports (as indicated by the NAS). In the case of DSL, the DSLAM only needs to update its own replication state based on the set of Access Ports indicated by the NAS.
- For reporting purposes, ANCP must enable the NAS to query the OLT for channels replicated on a PON or a list of PONs and to specific Access Ports. The latter should trigger the OLT to query the ONT for a list of channels being replicated on all Access Ports or on specific Access Ports to the premises. In a DSL case, it is sufficient to query the DSLAM for a list of channels being replicated on an Access Port or a list of Access Ports.
ONT Management and Control Interface (OMCI) [OMCI] is specified for in-band ONT management via the OLT. This includes configuring parameters on the ONT/ONU. Such configuration can include adding an Access Port on the ONT to a multicast tree and the ONT to a multicast tree. Thus, OMCI can be a potential replacement for ANCP between the OLT and ONT/ONU, albeit it may not be a suitable protocol for dynamic transactions as required for the multicast application.
Bitar, et al. Informational [Page 36]
RFC 6934 ANCP in PON-Based Networks June 2013
If OMCI is selected to be enabled between the OLT and ONT/ONU to carry the same information elements that would be carried over ANCP, the OLT must perform the necessary translation between ANCP and OMCI for replication control messages received via ANCP. OMCI is an already available control channel, while ANCP requires a TCP/IP stack on the ONT/ONU that can be used by an ANCP client, and accordingly, it requires that the ONT/ONU be IP addressable for ANCP. Most ONTs/ONUs today have a TCP/IP stack used by certain applications (e.g., VoIP and IGMP snooping). ANCP may use the same IP address that is often assigned for VoIP or, depending on the implementation, may require a different address. Sharing the same IP address between VoIP and ANCP may have other network implications on how the VoIP agent is addressed and on traffic routing. For instance, the VoIP traffic to/from the ONT is often encapsulated in a VLAN-tagged Ethernet frame and switched at Layer 2 through the OLT to the NAS where it is routed. The VoIP agent in this case looks like another subscriber to the NAS. On the other hand, the ANCP session between the ONT and OLT is terminated at the OLT. Thus, the OLT must be able to receive/send IP traffic to/from the OLT, which will not work using this setting. Using a separate IP address for the purpose of ONT/ONU management or ANCP specifically may often be required when supporting ANCP. These considerations may favor OMCI in certain environments. However, OMCI will not allow some of the transactions required in approach 2, where the ONT/ONU sends unsolicited requests to the OLT rather than being queried or configured by OLT requests.
[RFC2516] Mamakos, L., Lidl, K., Evarts, J., Carrel, D., Simone, D., and R. Wheeler, "A Method for Transmitting PPP Over Ethernet (PPPoE)", RFC 2516, February 1999.
[RFC2684] Grossman, D. and J. Heinanen, "Multiprotocol Encapsulation over ATM Adaptation Layer 5", RFC 2684, September 1999.
[RFC3376] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A. Thyagarajan, "Internet Group Management Protocol, Version 3", RFC 3376, October 2002.
Bitar, et al. Informational [Page 37]
RFC 6934 ANCP in PON-Based Networks June 2013
[RFC4605] Fenner, B., He, H., Haberman, B., and H. Sandick, "Internet Group Management Protocol (IGMP) / Multicast Listener Discovery (MLD)-Based Multicast Forwarding ("IGMP/MLD Proxying")", RFC 4605, August 2006.
[802.1ag] IEEE 802.1ag, "Connectivity Fault Management", December 2007.
[RFC2881] Mitton, D. and M. Beadles, "Network Access Server Requirements Next Generation (NASREQNG) NAS Model", RFC 2881, July 2000.
[RFC5851] Ooghe, S., Voigt, N., Platnic, M., Haag, T., and S. Wadhwa, "Framework and Requirements for an Access Node Control Mechanism in Broadband Multi-Service Networks", RFC 5851, May 2010.
[G.983.1] ITU-T G.983.1, "Broadband optical access systems based on Passive Optical Networks (PON)", January 2005.
[G.984.1] ITU-T G.984.1, "Gigabit-capable Passive Optical Networks (GPON): General characteristics", March 2008.
[RFC3046] Patrick, M., "DHCP Relay Agent Information Option", RFC 3046, January 2001.
[TR-101] Cohen, A. and E. Shrum, "Migration to Ethernet-Based DSL Aggregation", DSL Forum TR-101, May 2006.
[RFC5713] Moustafa, H., Tschofenig, H., and S. De Cnodder, "Security Threats and Security Requirements for the Access Node Control Protocol (ANCP)", RFC 5713, January 2010.
[OMCI] ITU-T G.984.4, "Gigabit-capable passive optical networks (G-PON): ONT management and control interface specification", February 2008.
[RFC6320] Wadhwa, S., Moisand, J., Haag, T., Voigt, N., and T. Taylor, Ed., "Protocol for Access Node Control Mechanism in Broadband Networks", RFC 6320, October 2011.