Internet-Draft | RAW and MEC integration | September 2023 |
Bernardos & Mourad | Expires 14 March 2024 | [Page] |
There are several scenarios involving multi-hop heterogeneous wireless networks requiring reliable and available features combined with multi-access edge computing, such as Industry 4.0. This document describes solutions integrating IETF RAW and ETSI MEC, fostering discussion about extensions at both IETF and ETSI MEC to better support these scenarios.¶
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Wireless operates on a shared medium, and transmissions cannot be fully deterministic due to uncontrolled interferences, including self-induced multipath fading. RAW (Reliable and Available Wireless) is an effort to provide Deterministic Networking on across a path that include a wireless interface. RAW provides for high reliability and availability for IP connectivity over a wireless medium. The wireless medium presents significant challenges to achieve deterministic properties such as low packet error rate, bounded consecutive losses, and bounded latency. RAW extends the DetNet Working Group concepts to provide for high reliability and availability for an IP network utilizing scheduled wireless segments and other media, e.g., frequency/time-sharing physical media resources with stochastic traffic: IEEE Std. 802.15.4 timeslotted channel hopping (TSCH), 3GPP 5G ultra-reliable low latency communications (URLLC), IEEE 802.11ax/be, and L-band Digital Aeronautical Communications System (LDACS), etc. Similar to DetNet, RAW technologies aim at staying abstract to the radio layers underneath, addressing the Layer 3 aspects in support of applications requiring high reliability and availability.¶
As introduced in [I-D.ietf-raw-architecture], RAW separates the path computation time scale at which a complex path is recomputed from the path selection time scale at which the forwarding decision is taken for one or a few packets. RAW operates at the path selection time scale. The RAW problem is to decide, amongst the redundant solutions that are proposed by the Patch Computation Element (PCE), which one will be used for each packet to provide a Reliable and Available service while minimizing the waste of constrained resources. To that effect, RAW defines the Path Selection Engine (PSE) that is the counter-part of the PCE to perform rapid local adjustments of the forwarding tables within the diversity that the PCE has selected for the Track. The PSE enables to exploit the richer forwarding capabilities with Packet (hybrid) ARQ, Replication, Elimination and Ordering (PAREO), and scheduled transmissions at a faster time scale.¶
Multi-access Edge Computing (MEC) -- formerly known as Mobile Edge Computing -- capabilities deployed in the edge of the mobile network can facilitate the efficient and dynamic provision of services to mobile users. The ETSI ISG MEC working group, operative from end of 2014, intends to specify an open environment for integrating MEC capabilities with service providers' networks, including also applications from 3rd parties. These distributed computing capabilities will make available IT infrastructure as in a cloud environment for the deployment of functions in mobile access networks.¶
One relevant exemplary scenario showing the need for an integration of RAW and MEC is introduced next. One of the main (and distinct) use cases of 5G is Ultra Reliable and Low Latency Communications (URLLC). Among the many so-called "verticals" that require URLLC features, the Industry 4.0 (also referred to as Wireless for Industrial Applications) is probably the one with more short-term potential. As identified in [RFC9450], this scenario also calls for RAW solutions, as cables are not that suitable for the robots and mobile vehicles typically used in factories. This is also a very natural scenario for MEC deployments, as bounded, and very low latencies are needed between the robots and physical actuators and the control logic managing them. Figure 1 depicts an exemplary scenario of a factory where terminals (robots and mobile automated guided vehicles) are wirelessly connected. Control applications running in the edge (implemented as MEC applications) require bounded low latencies and a guaranteed availability, despite the mobility of the terminals and the changing wireless conditions. An heterogeneous wireless mesh network is used to provide connectivity inside the factory.¶
This scenario includes a wireless domain, involving multiple MEC platforms to ensure low latency to applications, by being able to host MEC applications in several locations, and dynamically migrate the apps as the terminals move around and the serving MEC platform might no longer be capable of meeting the latency requirements.¶
The following terms used in this document are defined by the ETSI MEC ISG, and the IETF:¶
With current standards, the MEC platform(s) would have to interact with a Path Computation Element (PCE) for data plane requests and updates. This tremendously limits the capabilities to guarantee real-time forwarding decisions, as it will make it challenging and not possible to manage forwarding decisions in real or near-real time.¶
RAW solutions and approaches being explored today consider the role of the PSE, which computes at a short time scale which of the available paths (called tracks) -- computed by a PCE -- should be used per flow/packet and also which PAREO functions can be used, in order to provide the flow with the required availability and reliability features. The PSE interacts with the PCE and with the RAW nodes so they can setup the required per-flow state, to recognize the flow and determine the forwarding policy to be applied. These RAW forwarding decisions can be distributed among the necessary nodes using in-band signaling (e.g., extending Segment Routing, BIER-TE or DETNET tagging) or can be taken autonomously by each forwarding node locally (based on its knowledge of the status of the network, gained via OAM RAW-specific mechanisms).¶
Figure 1 shows an exemplary scenario, depicting an industrial environment where different nodes are wirelessly connected to provide connectivity to several stationary and mobile terminals (i.e., robots). Industry environments are a good example of applications where reliability and availability are critical. Ensuring this in wireless heterogeneous and multi-hop networks requires using multiple paths, using PAREO functions and even using dual or multiple connectivity. Terminal mobility makes it even more challenging to guarantee certain reliability and availability levels, due to the dynamic and fast changes that this needs at the data plane level. The short-time scale forwarding decisions that are required to ensure reliability and availability with terminal mobility cannot be managed if MEC platforms can only interact with the data plane through the PCE.¶
The PCE is responsible for routing computation and maintenance in a network and it is typically a centralized entity that can even reside outside the network. It is meant to compute and establish redundant paths, but not to be sensitive/reactive to transient changes, and therefore is not capable of ensuring a certain level of reliability and availability in a wireless heterogeneous mesh network, especially if some of the nodes (e.g., the end terminals) might be mobile. With currently standardized solutions, a MEC platform could only interact with the RAW network through the PCE, most possibly through the Mp2 reference point defined by ETSI MEC. This reference point is defined between the MEC platform and the data plane of the virtualization infrastructure to instruct the data plane on how to route traffic among applications, networks, services, etc. This reference point is not further specified by ETSI MEC, but it would be the one that could be used by current solutions to allow for MEC to request the data plane on the RAW network a certain behavior (in terms of availability and reliability) for MEC app traffic flows. With existing solutions, the PCE would be the entry point for configuring and managing the RAW network, probably through the Mp2 reference point. Note that the PCE might reside outside the RAW network, the path between the RAW network and the PCE might be expensive and slow (e.g., it might need to traverse the whole RAW network) and reaching to the PCE can also be slow in regards to the speed of events that affect the forwarding operation at the radio layer.¶
Additionally, the MEC architecture as currently defined by ETSI does not have any component designed to deal with the specifics of an heterogeneous wireless multi-hop networks (such a RAW one), and therefore, it is very limited in terms of what a MEC app (through the MEC platform) can request to the data plane of an heterogeneous wireless multi-hop network. Besides, this lack of RAW-aware component at the ETSI MEC architecture prevents any enhancement at either the MEC side (e.g., MEC app migrations triggered by RAW status updates) or the RAW side (e.g., PAREO function updates triggered by MEC app/terminal mobility).¶
Because of all these aforementioned reasons, it is needed to define a new RAW-enabled component at the ETSI MEC architecture, aimed at enabling a more direct interaction between the MEC platform and the RAW network, allowing the MEC platform to notify events and/or request actions to the RAW network quick enough. This involves some challenges, as the RAW PSE has to understand the needs from the running MEC applications, so it can properly configure the RAW nodes so the data plane provides the required reliability and availability.¶
This document defines a new entity inside the MEC platform: the RAW ctrl. This entity is responsible for computing what to instruct the RAW PSE, based on the requirements of the MEC apps, as well as to take decisions at the MEC side (e.g., migration of apps) based on information about the RAW network status.¶
As a result of the introduction of the RAW ctrl and the actions it is responsible of, new interactions and interface semantics are added. These interactions and semantics can be terminated at either the PCE or the RAW PSE, depending on the requirements of the MEC apps. For near real-time coordination and control between MEC and RAW mechanisms, the interactions are between the RAW ctrl and the RAW PSE. We mostly refer to this deployment model from now on, as it is the one that allow for near real-time updates on the forwarding plane, but note that an alternative deployment model in which the RAW ctrl interacts with the PCE is also possible, though only supporting non real-time interactions.¶
The MEC-RAW new interface semantics/extensions depicted in Figure 2 allows the MEC platform to issue requests to the RAW network, through the RAW PSE, so it can behave as required by MEC apps.¶
The new semantics of the interface between the MEC platform and the RAW PSE do not only serve to convey the requests, but also to synchronize the status and topology of the RAW (relevant portion of the) network, enabling to perform real-time or near-real time forwarding decisions. In the sequel, we show different exemplary signaling diagrams for the most relevant procedures.¶
Here we specify the interface extensions and signaling procedures needed to enable a MEC app describe and request its needs in terms of availability and reliability. As it will be further developed in other subsections, the wireless network conditions could also have an impact back on the MEC platform (e.g., by triggering the migration of the MEC app).¶
Figure 3 shows an exemplary signaling flow diagram, in which a certain MEC app request a given behavior for the treatment of the packets the app generates. We consider an industrial wireless application scenario, as the one used in previous sections, as an example for the sake of describing the interface and specified interactions.¶
The MEC platform is enhanced with a RAW ctrl entity, as introduced in the previous section. The RAW ctrl is a RAW-aware component within the MEC architecture that enables the required interactions with the RAW network, through the RAW PSE. This allows MEC apps to: (i) adapt to RAW conditions (e.g., if the requested reliability and availability is not possible), and (ii) dynamically modify the requested flow forwarding to the RAW network, based on the MEC app and mobility conditions.¶
We next explain each of the steps illustrated in the figure:¶
The MEC platform -- namely the RAW ctrl component, which is RAW-aware and knows the characteristics of the deployment -- analyzes the characteristics of the MEC app traffic and the provided requirements, and generates a new request -- over a new interface between the MEC platform and the RAW PSE -- that includes, among others, the following parameters:¶
The RAW PSE processes the request, and based on its knowledge of the network (topology, node capabilities and ongoing flows) computes the best way of transmitting the packets over the RAW network (using the available paths/tracks, previously computed by a PCE). Note that at this point it might be possible that the RAW PSE realizes that it is not possible to provide the requested reliability and availability characteristics, and would report that back to the MEC platform (which might issue a new request with less requirements). The RAW PSE sends control packets to each of the RAW nodes involved, instructing how to deal with the packets belonging to the MEC app flow. This includes:¶
Here we specify the mechanisms for MEC to benefit from RAW OAM information, for example, to trigger the migration of a MEC application to a different MEC platform, to ensure that the requirements of the MEC app continue to be met.¶
Figure 4 shows an exemplary signaling flow diagram, in which changes in the RAW network, detected thanks to RAW OAM, trigger the migration of a MEC app. We assume there is already a MEC app deployed and traffic is already flowing (i.e., all the procedures explained in the previous section took already place). We next explain each of the steps illustrated in the figure:¶
There are scenarios and situations where -- due to the mobility of the terminals or the nodes hosting the MEC platform hosting a given MEC app -- it might be needed to take actions on the RAW network: e.g., to update the paths, apply different PAREO functions, migrate the MEC app (thus involving a change in the RAW forwarding). This triggers the need for mechanisms enabling the RAW PSE to get and use MEC OAM information to update traffic forwarding at the RAW network as needed to adapt to varying conditions, e.g., due to node mobility.¶
Figure 5 shows an exemplary signaling flow diagram, in which the mobility of the a node (in this case the terminal, but it could have been the MEC platform hosting the MEC app) triggers the need for updating RAW forwarding mechanisms. As in the previous section, we assume there is already a MEC app deployed and traffic is already flowing (i.e., all the procedures explained in Section 4.1 took already place). We next explain each of the steps illustrated in the figure:¶
TBD.¶
The work of Carlos J. Bernardos in this document has been partially supported by the Horizon Europe PREDICT-6G (Grant 101095890) and UNICO I+D 6G-DATADRIVEN-04 project.¶