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			docName="draft-ietf-detnet-oam-framework-11"
			number="9551"
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	<front>		<front>
	<title abbrev="Framework of OAM for DetNet">Framework of Operations, Adminis		<title abbrev="Framework of OAM for DetNet">Framework of Operations, Adminis
	tration and Maintenance (OAM) for Deterministic Networking (DetNet)</title>		tration, and Maintenance (OAM) for Deterministic Networking (DetNet)</title>
	<seriesInfo name="Internet-Draft" value="draft-ietf-detnet-oam-framework-11"		<seriesInfo name="RFC" value="9551"/>
	/>
	<author initials="G." surname="Mirsky" fullname="Greg Mirsky">		<author initials="G." surname="Mirsky" fullname="Greg Mirsky">
	<organization>Ericsson</organization>		<organization>Ericsson</organization>
	<address>		<address>
	<email>gregimirsky@gmail.com</email>		<email>gregimirsky@gmail.com</email>
	</address>		</address>
	</author>		</author>
	<author initials="F." surname="Theoleyre" fullname="Fabrice Theoleyre">		<author initials="F." surname="Theoleyre" fullname="Fabrice Theoleyre">
	<organization>CNRS</organization>		<organization>CNRS</organization>
	<address>		<address>
	<postal>		<postal>
			<extaddr>ICube Lab, Pole API</extaddr>
	<street>300 boulevard Sebastien Brant - CS 10413</street>		<street>300 boulevard Sebastien Brant - CS 10413</street>
	<city>Illkirch - Strasbourg</city>		<city>Illkirch - Strasbourg</city>
	<code>67400</code>		<code>67400</code>
	<country>FRANCE</country>		<country>France</country>
	</postal>		</postal>
	<phone>+33 368 85 45 33</phone>		<phone>+33 368 85 45 33</phone>
	<email>fabrice.theoleyre@cnrs.fr</email>		<email>fabrice.theoleyre@cnrs.fr</email>
	<uri>https://fabrice.theoleyre.cnrs.fr/</uri>		<uri>https://fabrice.theoleyre.cnrs.fr/</uri>
	</address>		</address>
	</author>		</author>
	<author initials="G.Z." surname="Papadopoulos" fullname="Georgios Z. Papadop
	oulos">		<author initials="G." surname="Papadopoulos" fullname="Georgios Papadopoulos
			">
	<organization>IMT Atlantique</organization>		<organization>IMT Atlantique</organization>
	<address>		<address>
	<postal>		<postal>
	<street>Office B00 - 102A</street>		<street>Office B00 - 102A</street>
	<street>2 Rue de la Châtaigneraie</street>		<street>2 Rue de la Châtaigneraie</street>
	<city>Cesson-Sévigné - Rennes</city>		<city>Cesson-Sévigné - Rennes</city>
	<code>35510</code>		<code>35510</code>
	<country>FRANCE</country>		<country>France</country>
	</postal>		</postal>
	<phone>+33 299 12 70 04</phone>		<phone>+33 299 12 70 04</phone>
	<email>georgios.papadopoulos@imt-atlantique.fr</email>		<email>georgios.papadopoulos@imt-atlantique.fr</email>
	</address>		</address>
	</author>		</author>
	<author initials="CJ." surname="Bernardos" fullname="Carlos J. Bernardos">		<author initials="CJ." surname="Bernardos" fullname="Carlos J. Bernardos">
	<organization abbrev="UC3M">		<organization abbrev="UC3M">
	Universidad Carlos III de Madrid		Universidad Carlos III de Madrid
	</organization>		</organization>
	<address>		<address>
	skipping to change at line 104 ¶		skipping to change at line 111 ¶
	<postal>		<postal>
	<street>Magyar Tudosok krt. 11.</street>		<street>Magyar Tudosok krt. 11.</street>
	<city>Budapest</city>		<city>Budapest</city>
	<country>Hungary</country>		<country>Hungary</country>
	<code>1117</code>		<code>1117</code>
	</postal>		</postal>
	<email>janos.farkas@ericsson.com</email>		<email>janos.farkas@ericsson.com</email>
	</address>		</address>
	</author>		</author>
	<date/>		<date year="2024" month="March"/>
			<area>RTG</area>
	<workgroup>DetNet</workgroup>		<workgroup>DetNet</workgroup>
	<abstract>		<abstract>
	<t>		<t>Deterministic Networking (DetNet), as defined in RFC 8655, aims to
	Deterministic Networking (DetNet), as defined in RFC 8655, aims to provide b		provide bounded end-to-end latency on top of the network infrastructure,
	ounded end-to-end latency		comprising both Layer 2 bridged and Layer 3 routed segments. This
	on top of the network infrastructure, comprising both Layer 2 bridged an		document's primary purpose is to detail the specific requirements of the
	d Layer 3 routed segments.		Operations, Administration, and Maintenance (OAM) recommended to maintain
	This document's primary purpose is to detail the specific requirements of the Op		a deterministic network. The document will be used in future work that
	eration, Administration, and Maintenance (OAM) recommended to maintain a		defines the applicability of and extension of OAM protocols for a
	deterministic network. The document will be used in future work that defines		deterministic network. With the implementation of the OAM framework in
	the applicability of and extension of OAM protocols for a deterministic network.		DetNet, an operator will have a real-time view of the network
	With the implementation of the OAM framework in DetNet, an operator will have		infrastructure regarding the network's ability to respect the Service
	a real-time		Level Objective (SLO), such as packet delay, delay variation, and packet-l
	view of the network infrastructure regarding the network's ability to res		oss
	pect the Service Level		ratio, assigned to each DetNet flow.
	Objective, such as packet delay, delay variation, and packet loss rati
	o, assigned to each DetNet flow.
	</t>		</t>
	</abstract>		</abstract>
	</front>		</front>
	<middle>		<middle>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Introduction</name>		<name>Introduction</name>
	<t>		<t>
	Deterministic Networking (DetNet) <xref target="RFC8655" format="default "/> has proposed to provide a bounded end-to-end latency		Deterministic Networking (DetNet) <xref target="RFC8655" format="default "/> has proposed to provide a bounded end-to-end latency
	on top of the network infrastructure, comprising both Layer 2 bridged an d Layer 3 routed segments.		on top of the network infrastructure, comprising both Layer 2 bridged an d Layer 3 routed segments.
	That work encompasses the data plane, OAM, time synchronization, managem ent, control, and security aspects.		That work encompasses the data plane, OAM, time synchronization, managem ent, control, and security aspects.
	</t>		</t>
	<t>		<t>
	Operations, Administration, and Maintenance (OAM) Tools are of primary i mportance		Operations, Administration, and Maintenance (OAM) tools are of primary i mportance
	for IP networks <xref target="RFC7276" format="default"/>.		for IP networks <xref target="RFC7276" format="default"/>.
	DetNet OAM should provide a toolset for fault detection, localization, a nd performance measurement.		DetNet OAM should provide a toolset for fault detection, localization, a nd performance measurement.
	</t>		</t>
	<t>		<t>
	This document's primary purpose is to detail the specific requirements o f the OAM features recommended to maintain a		This document's primary purpose is to detail the specific requirements o f the OAM features recommended to maintain a
	deterministic/reliable network.		deterministic/reliable network. Specifically, it investigates the requir
	Specifically, it investigates the requirements for a deterministic netwo		ements for a deterministic
	rk, supporting critical flows.		network that supports critical flows.
	</t>		</t>
	<t>		<t>
	In this document, the term OAM will be used according to its definition s		In this document, the term "OAM" will be used according to its definition
	pecified		specified
	in <xref target="RFC6291" format="default"/>.		in <xref target="RFC6291" format="default"/>. DetNet is expected to imple
	DetNet expects to implement an OAM framework to maintain a real-time		ment an OAM framework to maintain a real-time
	view of the network infrastructure, and its ability to respect the Servic e Level		view of the network infrastructure, and its ability to respect the Servic e Level
	Objectives (SLOs), such as in-order packet delivery, packet delay, del		Objectives (SLOs), such as in-order packet delivery, packet delay, del
	ay variation, and packet loss ratio, assigned to each DetNet flow.		ay variation, and packet-loss ratio, assigned to each DetNet flow.
	</t>
	<t>
	This document lists the functional requirements toward OAM for a DetNet doma
	in.
	The list can further be used for gap analysis of available OAM tools to ident
	ify
	possible enhancements of existing or whether new OAM tools are required to
	support proactive and on-demand path monitoring and service validation.
	</t>		</t>
			<t>This document lists the OAM functional requirements for a DetNet domain
			.
			The list can further be used for gap analysis of available OAM tools to iden
			tify:</t>
			<ul><li>possible enhancements of existing tools, or</li>
			<li>whether new OAM tools are required to
			support proactive and on-demand path monitoring and service validation.</li><
			/ul>
	<section anchor="define-sec" numbered="true" toc="default">		<section anchor="define-sec" numbered="true" toc="default">
	<name>Definitions</name>		<name>Definitions</name>
	<t>		<t>
	This document uses definitions, particularly of a DetNet flow, provi ded in Section 2.1 of <xref target="RFC8655"/>.		This document uses definitions, particularly of a DetNet flow, provi ded in <xref target="RFC8655" sectionFormat="of" section="2.1"/>.
	The following terms are used throughout this document as defined bel ow:		The following terms are used throughout this document as defined bel ow:
	</t>		</t>
	<ul spacing="normal">		<dl spacing="normal">
	<li>		<dt>
	DetNet OAM domain: a DetNet network used by the monitored De		DetNet OAM domain:</dt><dd>a DetNet network used by the moni
	tNet flow. A DetNet OAM domain		tored DetNet flow. A DetNet OAM domain
	(also referred to in this document as "OAM domain") may have		(also referred to in this document as "OAM domain") may have
	MEPs on its edge and MIPs within.		Maintenance End Points (MEPs) on its edge and Maintenance Intermediate Points (
	</li>		MIPs) within.
	<li>		</dd>
	DetNet OAM instance: a function that monitors a DetNet flow
	for defects and/or measures its performance metrics. Within this document,		<dt>DetNet OAM instance:</dt><dd>a function that monitors a
	a shorter version, OAM instance, is used interchangeably.		DetNet flow for defects and/or measures its performance metrics. Within this doc
	</li>		ument,
	<li>		the shorter version "OAM instance" is used interchangeably.
	Maintenance End Point (MEP): an OAM instance that is capable		</dd>
	of generating OAM test packets
			<dt>Maintenance End Point (MEP):</dt><dd>an OAM instance that
			is capable of generating OAM test packets
	in the particular sub-layer of the DetNet OAM domain.		in the particular sub-layer of the DetNet OAM domain.
	</li>		</dd>
	<li>
	Maintenance Intermediate Point (MIP): an OAM instance along t		<dt>Maintenance Intermediate Point (MIP):</dt><dd>an OAM inst
	he DetNet flow in the particular sub-layer of the DetNet OAM domain.		ance along the DetNet flow in the particular sub-layer of the DetNet OAM domain
	An active MIP MUST respond to an OAM message generated by the MEP at its sub-lay		.
	er of the same DetNet OAM domain.		An active MIP <bcp14>MUST</bcp14> respond to an OAM message generated by the MEP
	</li>		at its sub-layer of the same DetNet OAM domain.
	<li>		</dd>
	Control and management plane: the control and management planes a		<dt>Control and management plane:</dt><dd>the control and management p
	re used to configure and control the network.		lanes are used to configure and control the network.
	Relative to a DetNet flow, the control and/or management plane ca		Relative to a DetNet flow, the control and/or management plane ca
	n be out-of-band.		n be out of band.
	</li>		</dd>
	<li>		<dt>Active measurement methods:</dt><dd>(as defined in <xref target="R
	Active measurement methods (as defined in <xref target="RFC7799"		FC7799" format="default"/>)
	format="default"/>)		these methods modify a DetNet flow by injecting specially cons
	modify a DetNet flow by injecting specially constructed test p		tructed test packets <xref target="RFC2544" format="default"/>.
	ackets <xref target="RFC2544" format="default"/>).		</dd>
	</li>		<dt>Passive measurement methods:</dt> <dd>(as defined in <xref target=
	<li>Passive measurement methods <xref target="RFC7799" format="default		"RFC7799" format="default"/>) these methods infer information by observing unmod
	"/> infer information by observing unmodified existing flows.</li>		ified existing flows.</dd>
	<li>Hybrid measurement methods <xref target="RFC7799" format="default"		<dt>Hybrid measurement methods:</dt><dd>(as defined in <xref target="R
	/> is the combination of elements of both active and passive measurement methods		FC7799" format="default"/>) the combination of elements of both active and passi
	.</li>		ve measurement methods.</dd>
	<li>		<dt>In-band OAM:</dt><dd>an active OAM method that is in band within t
	In-band OAM is an active OAM that is in-band within the monitored		he monitored
	DetNet OAM domain when it traverses the same set of links and interfaces		DetNet OAM domain when it traverses the same set of links and
	receiving the same QoS and Packet Replication, Elimination, and Ordering F		interfaces receiving the same QoS and Packet Replication,
	unctions		Elimination, and Ordering Functions (PREOF) treatment as the
	(PREOF) treatment as the monitored DetNet flow.		monitored DetNet flow.</dd>
	</li>		<dt>Out-of-band OAM:</dt><dd>an active OAM method whose path through the DetNet
	<li>		domain may not be topologically identical to the
	Out-of-band OAM is an active OAM whose path through the DetNet domain is not		path of the monitored DetNet flow, its test packets may receive different QoS
	topologically identical to the		and/or PREOF treatment, or both.
	path of the monitored DetNet flow, or its test packets receive different QoS		</dd>
	and/or PREOF treatment, or both.		<dt>On-path telemetry:</dt><dd>on-path telemetry can be realized as a hybr
	</li>		id OAM method. The origination of the telemetry information
	<li>		is inherently in band as packets in a DetNet flow are used as triggers. Co
	On-path telemetry can be realized as a hybrid OAM method. The origination		llection of the on-path telemetry information
	of the telemetry information
	is inherently in-band as packets in a DetNet flow are used as triggers. Co
	llection of the on-path telemetry information
	can be performed using in-band or out-of-band OAM methods.		can be performed using in-band or out-of-band OAM methods.
	</li>		</dd>
	</ul>		</dl>
	</section>		</section>
	<section anchor="acronyms-sec" numbered="true" toc="default">
	<name>Abbreviations</name>
	<t>OAM: Operations, Administration, and Maintenance</t
	>
	<t>DetNet: Deterministic Networking</t>
	<t>PREOF: Packet Replication, Elimination and Ordering Func
	tions</t>
	<t>SLO: Service Level Objective</t>
	</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Requirements Language</name>		<name>Requirements Language</name>
	<t>		<t>
	The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL		The key words "<bcp14>MUST</bcp14>", "<bcp14>MUST NOT</bcp14>",
	NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED",		"<bcp14>REQUIRED</bcp14>", "<bcp14>SHALL</bcp14>", "<bcp14>SHALL NOT</bcp14>
	"MAY", and "OPTIONAL" in this document are to be interpreted as		",
	described in BCP 14 <xref target="RFC2119" format="default"/> <xref target="R		"<bcp14>SHOULD</bcp14>", "<bcp14>SHOULD NOT</bcp14>",
	FC8174" format="default"/>		"<bcp14>RECOMMENDED</bcp14>", "<bcp14>NOT RECOMMENDED</bcp14>",
	when, and only when, they appear in all capitals, as shown here.		"<bcp14>MAY</bcp14>", and "<bcp14>OPTIONAL</bcp14>" in this document are to
	The requirements language is used in <xref target="define-sec"/>, <xref targe		be
	t="req-list"/>,		interpreted as described in BCP&nbsp;14 <xref target="RFC2119"/> <xref
			target="RFC8174"/> when, and only when, they appear in all capitals, as
			shown here.
			The requirements language is used in Sections <xref target="define-sec" forma
			t="counter"/> and <xref target="req-list" format="counter"/>,
	and applies to the implementations of DetNet OAM.		and applies to the implementations of DetNet OAM.
	</t>		</t>
	</section>		</section>
	</section>		</section>
	<!-- INTEREST OF OAM -->
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Role of OAM in DetNet</name>		<name>Role of OAM in DetNet</name>
	<t>		<t>
	DetNet networks expect to provide communications with predictable low		DetNet networks are expected to provide communications with predictable l
	packet delay, packet loss, and packet misordering. Most critical applications wi		ow packet delay, packet loss, and packet misordering. Most critical application
	ll define		s will define
	a set of SLOs to be required for the DetNet flows it generates.		a set of SLOs to be required for the DetNet flows they generate.
	</t>		</t>
	<t>		<t>
	To respect strict guarantees, DetNet can use an orchestrator able to		To respect strict guarantees, DetNet can use an orchestrator able to
	monitor and maintain the network. Typically, a Software-Defined		monitor and maintain the network. Typically, a Software-Defined
	Network controller places DetNet flows in the deployed network		Network (SDN) controller places DetNet flows in the deployed network
	based on their SLOs. Thus, resources have to be provisioned a		based on their SLOs. Thus, resources have to be provisioned a
	priori for the regular operation of the network.		priori for the regular operation of the network.
	</t>		</t>
	<t>		<t>
	Most of the existing OAM tools can be used in DetNet networks,		Most of the existing OAM tools can be used in DetNet networks,
	but they can only cover some aspects of deterministic networking.		but they can only cover some aspects of deterministic networking.
	Fulfilling strict guarantees is essential for DetNet flows,		Fulfilling strict guarantees is essential for DetNet flows,
	resulting in new DetNet-specific functionalities that must be covered with OAM.		resulting in new DetNet-specific functionalities that must be covered with OAM.
	Filling these gaps is inevitable and needs accurate consideration of		Filling these gaps is inevitable and needs accurate consideration of
	DetNet specifics. Similar to DetNet flows, their OAM also needs careful		DetNet specifics. Similar to DetNet flows, their OAM also needs careful
	end-to-end engineering.		end-to-end engineering.
	</t>		</t>
	<t>		<t>
	For example, appropriate placing of MEPs along the path of a DetNet flow is		For example, appropriate placing of MEPs along the path of a DetNet flow is
	not always a trivial task and may require proper design, together with the		not always a trivial task and may require proper design together with the
	design of the service component of a given DetNet flow.		design of the service component of a given DetNet flow.
	</t>		</t>
	<t>		<t>
	There are several DetNet-specific challenges for OAM. Bounded network		There are several DetNet-specific challenges for OAM. Bounded network
	characteristics (e.g., delay, loss) are inseparable service parameters;		characteristics (e.g., delay, loss) are inseparable service parameters;
	therefore, Performance Monitoring OAM is a key topic for DetNet. OAM tools are n eeded to monitor each		therefore, Performance Monitoring (PM) OAM is a key topic for DetNet. OAM tools are needed to monitor each
	SLO without impacting the DetNet flow characteristics. A further challenge		SLO without impacting the DetNet flow characteristics. A further challenge
	is strict resource allocation. Resources used by OAM must be considered		is strict resource allocation. Resources used by OAM must be considered
	and allocated to avoid disturbing DetNet flows.		and allocated to avoid disturbing DetNet flows.
	</t>		</t>
	<t>		<t>
	The DetNet Working Group has defined two sub-layers:		The DetNet Working Group has defined two sub-layers:
	</t>		</t>
	<ul empty="true" spacing="normal">		<ul empty="true" spacing="normal">
	<li>		<li>
	DetNet service sub-layer, at which a DetNet service (e.g., service		The DetNet service sub-layer at which a DetNet service (e.g., service
	protection) is provided.		protection) is provided.
	</li>		</li>
	<li>		<li>
	DetNet forwarding sub-layer, which		The DetNet forwarding sub-layer, which
	optionally provides resource allocation for DetNet flows over paths		optionally provides resource allocation for DetNet flows over paths
	provided by the underlying network.		provided by the underlying network.
	</li>		</li>
	</ul>		</ul>
	<t>		<t>
	OAM mechanisms exist for the		OAM mechanisms exist for the
	DetNet forwarding sub-layer, but the service		DetNet forwarding sub-layer, but the service
	sub-layer requires new OAM procedures. These new OAM functions		sub-layer requires new OAM procedures. These new OAM functions
	must allow, for example, to recognize/discover DetNet relay		must allow, for example, recognizing/discovering DetNet relay
	nodes, to get information about their configuration, and to		nodes, getting information about their configuration, and
	check their operation or status.		checking their operation or status.
	</t>		</t>
	<t>		<t>
	DetNet service sub-layer functions use a sequence number for PREOF. That creates		DetNet service sub-layer functions use a sequence number for PREOF, which create s
	a challenge for inserting OAM packets in the DetNet flow.		a challenge for inserting OAM packets in the DetNet flow.
	</t>		</t>
	<t>		<t>
	Fault tolerance also assumes that multiple paths could be provisioned		Fault tolerance also assumes that multiple paths could be provisioned
	to maintain an end-to-end circuit by adapting to the existing conditions.		to maintain an end-to-end circuit by adapting to the existing conditions.
	The DetNet Controller Plane, e.g., central controller/orchestrator, controls the PREOF on a node. OAM is expected to support monitoring and		The DetNet Controller Plane, e.g., central controller/orchestrator, controls the PREOF on a node. OAM is expected to support monitoring and
	troubleshooting PREOF on a particular node and within the domain.		troubleshooting PREOF on a particular node and within the domain.
	</t>		</t>
	<t>		<t>
	Note that a distributed architecture of the DetNet Control Plane can also contro l PREOF		Note that a distributed architecture of the DetNet Control Plane can also contro l PREOF
	in those scenarios where DetNet solutions involve more than one single central c ontroller.		in those scenarios where DetNet solutions involve more than one single central c ontroller.
	</t>		</t>
	<t>		<t>
	The DetNet forwarding sub-layer is based on preexisting technologies and has		The DetNet forwarding sub-layer is based on preexisting technologies and has
	much better coverage regarding OAM. However, the forwarding sub-layer		much better coverage regarding OAM. However, the forwarding sub-layer
	is terminated at DetNet relay nodes, so the end-to-end OAM state of forwarding		is terminated at DetNet relay nodes, so the end-to-end OAM state of forwarding
	may be created only based on the status of multiple forwarding sub-layer segment s		may be created only based on the status of multiple forwarding sub-layer segment s
	serving a given DetNet flow (e.g., in case of DetNet MPLS, there may be		serving a given DetNet flow (e.g., in case of DetNet MPLS, there may be
	no end-to-end LSP below the DetNet Pseudowire).		no end-to-end LSP below the DetNet pseudowire).
	</t>		</t>
	<!--
	<t>
	It is undwerstood that the existing OAM tools broadly used in networks can
	be used in DetNet domains.
	At the same time, it is expected that addressiing specific DetNet use case
	, for example,
	PREOF, will require extensions to the existing OAM protocols.
	</t>
	-->
	</section>		</section>
	<!-- OPERATION -->
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Operation</name>		<name>Operation</name>
	<t>		<t>
	OAM features will enable DetNet with robust operation both for forwarding and routing		OAM features will enable DetNet with robust operation both for forwarding and routing
	purposes.		purposes.
	</t>		</t>
	<t>		<t>
	It is worth noting that the test and data packets are exp ected to follow the same		It is worth noting that the test and data packets are exp ected to follow the same
	path, i.e., connectivity verification has to be conducted in-band wi thout		path, i.e., connectivity verification has to be conducted in band wi thout
	impacting data traffic.		impacting data traffic.
	It is expected that test packets share fate with the monitored data traffic		It is expected that test packets share fate with the monitored data traffic
	without introducing congestion in normal network conditions.		without introducing congestion in normal network conditions.
	</t>		</t>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Information Collection</name>		<name>Information Collection</name>
	<t>		<t>
	Information about the state of the network can be collected using several mechanisms. Some protocols,		Information about the state of the network can be collected using several mechanisms. Some protocols,
	e.g., Simple Network Management Protocol, polls for updated data.		e.g., the Simple Network Management Protocol (SNMP), poll for upda ted data.
	Other protocols, such as YANG-Push <xref target="RFC8641"/>, can b e used		Other protocols, such as YANG-Push <xref target="RFC8641"/>, can b e used
	to set up subscriptions for the data defined in the YANG data mode ls		to set up subscriptions for the data defined in the YANG data mode ls
	to be published periodically or when the underlying data changes.		to be published periodically or when the underlying data changes.
	In either way, information is collected and sent using the DetNet Controller Plane.		Either way, information is collected and sent using the DetNet Con troller Plane.
	</t>		</t>
	<t>		<t>
	Also, we can characterize methods of transporting OAM information relative to the path of data.		Also, we can characterize methods of transporting OAM information relative to the path of data.
	For instance, OAM information may be transported in-band or out-o		For instance, OAM information may be transported in band or out o
	f-band relative to the DetNet flow.		f band relative to the DetNet flow.
	In case of the former, the telemetry information uses resources a		In the case of the former, the telemetry information uses resourc
	llocated for the monitored DetNet flow.		es allocated for the monitored DetNet flow.
	If an in-band method of transporting telemetry is used, the amoun t of generated information needs		If an in-band method of transporting telemetry is used, the amoun t of generated information needs
	to be carefully analyzed, and additional resources must be reserv ed. <xref target="RFC9197"/> defines the in-band		to be carefully analyzed, and additional resources must be reserv ed. <xref target="RFC9197"/> defines the in-band
	transport mechanism where telemetry information is collected in t he data packet on which information is generated.		transport mechanism where telemetry information is collected in t he data packet on which information is generated.
	Two tracing methods are described - end-to-end, i.e., from the in		Two tracing methods are described:</t>
	gress and egress nodes,		<ul>
	and hop-by-hop, i.e., like end-to-end with additional information		<li>end-to-end, i.e., from the ingress and egress nodes,
	from transit nodes.		and</li>
	<xref target="RFC9326"/> and <xref target="I-D.mirsky-ippm-hybrid		<li>hop-by-hop, i.e., like end-to-end with additional information from
	-two-step"/> are examples of out-of-band		transit nodes.</li></ul>
			<t><xref target="RFC9326"/> and <xref target="I-D.ietf-ippm-hybri
			d-two-step"/> are examples of out-of-band
	telemetry transport. In the former case, information is transport ed by each node traversed		telemetry transport. In the former case, information is transport ed by each node traversed
	by the data packet of the monitored DetNet flow in a specially co nstructed packet. In the latter,		by the data packet of the monitored DetNet flow in a specially co nstructed packet. In the latter,
	information is collected in a sequence of follow-up packets that traverse the same path as the data packet of the monitored DetNet flow.		information is collected in a sequence of follow-up packets that traverse the same path as the data packet of the monitored DetNet flow.
	In both methods, transport of the telemetry can avoid using resou rces allocated for the DetNet domain.		In both methods, transport of the telemetry can avoid using resou rces allocated for the DetNet domain.
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Continuity Check</name>		<name>Continuity Check</name>
	<t>		<t>
	Continuity check is used to monitor the continuity of a p ath, i.e.,		A continuity check is used to monitor the continuity of a path, i.e.,
	that there exists a way to deliver packets between		that there exists a way to deliver packets between
	MEP A and MEP B. The continuity check detects a network failure in o		MEP A and MEP B. The continuity check detects a network failure in o
	ne direction,		ne direction:
	from the MEP transmitting test packets to the remote egress MEP. Con		from the MEP transmitting test packets to the remote egress MEP. The
	tinuity check in a DetNet OAM domain		continuity check in a DetNet OAM domain
	monitors the DetNet forwarding sub-layer and thus is not affected		monitors the DetNet forwarding sub-layer; thus, it is not affected
	by a PREOF that operates at the DetNet service sub-layer (<xref targe		by a PREOF that operates at the DetNet service sub-layer (<xref targe
	t="RFC8655"/>.		t="RFC8655"/>).
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Connectivity Verification</name>		<name>Connectivity Verification</name>
	<t>		<t>
	In addition to the Continuity Check, DetNet solutions have to verify connectivity.		In addition to the Continuity Check, DetNet solutions have to verify connectivity.
	This verification considers an additional constraint, i.e, the absen ce of		This verification considers an additional constraint: the absence of
	misconnection. The misconnection error state is entered after severa l consecutive test packets		misconnection. The misconnection error state is entered after severa l consecutive test packets
	from other DetNet flows are received. The definition of the conditio ns for entry and exit of a misconnection		from other DetNet flows are received. The definition of the conditio ns for entry and exit of a misconnection
	error state is outside the scope of this document. Connectivity veri fication in a DetNet OAM domain		error state is outside the scope of this document. Connectivity veri fication in a DetNet OAM domain
	monitors the DetNet forwarding sub-layer and thus is not affected		monitors the DetNet forwarding sub-layer; thus, it is not affected
	by PREOF that operates at the DetNet service sub-layer (<xref target=		by PREOF that operates at the DetNet service sub-layer (<xref target=
	"RFC8655"/>.		"RFC8655"/>).
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Route Tracing</name>		<name>Route Tracing</name>
	<t>		<t>
	Ping and traceroute are two ubiquitous tools that help lo calize and characterize a failure in the network		Ping and traceroute are two ubiquitous tools that help lo calize and characterize a failure in the network
	using an echo request/reply mechanism.		using an echo request/reply mechanism.
	They help to identify a subset of the routers in the path .		They help to identify a subset of the routers in the path .
	However, to be predictable, resources are reserved per fl ow in DetNet.		However, to be predictable, resources are reserved per fl ow in DetNet.
	Thus, DetNet needs to define route tracing tools able to trace the route for a		Thus, DetNet needs to define route tracing tools able to trace the route for a
	specific flow. Also, tracing can be used for the discover y of the Path Maximum Transmission Unit or location of elements of PREOF		specific flow. Also, tracing can be used for the discover y of the Path Maximum Transmission Unit (PMTU) or location of elements of PREOF
	for the particular route in the DetNet domain.		for the particular route in the DetNet domain.
	</t>		</t>
	<t>		<t>
	DetNet is not expected to use Equal-Cost Multipath (ECMP) <xref target="RFC8939" format="default"/>.		DetNet is not expected to use Equal-Cost Multipath (ECMP) <xref target="RFC8939" format="default"/>.
	As the result, DetNet OAM in an ECMP environment is outsi de the scope of this document.		As a result, DetNet OAM in an ECMP environment is outside the scope of this document.
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Fault Verification/Detection</name>		<name>Fault Verification/Detection</name>
	<t>		<t>
	DetNet expects to operate fault-tolerant networks.		DetNet expects to operate fault-tolerant networks.
	Thus, mechanisms able to detect faults before they impact network performance are needed.		Thus, mechanisms able to detect faults before they impact network performance are needed.
	</t>		</t>
	<t>		<t>
	The network has to detect when a fault has occurred, i.e., the ne twork has deviated		The network has to detect when a fault has occurred, i.e., the ne twork has deviated
	from its expected behavior. Fault detection can be based on proacti ve OAM protocols		from its expected behavior. Fault detection can be based on proacti ve OAM protocols
	like continuity check or on-demand methods like ping.		like continuity check or on-demand methods like ping.
	While the network must report an alarm, the cause may not be iden tified		While the network must report an alarm, the cause may not be iden tified
	precisely.		precisely.
	Examples of such alarms are significant degradation of the end-to -end reliability, or a		Examples of such alarms are significant degradation of the end-to -end reliability or when a
	buffer overflow occurs.		buffer overflow occurs.
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Fault Localization and Characterization</name>		<name>Fault Localization and Characterization</name>
	<t>		<t>
	An ability to localize a network defect and provide its character		The ability to localize a network defect and provide its characte
	ization are necessary elements of network operation.		rization are necessary elements of network operation.
	</t>		</t>
	<ul empty="true" spacing="normal">
	<li>Fault localization, a process of deducing the location of a networ		<dl spacing="normal">
	k failure from a set of observed failure indications,		<dt>Fault localization:</dt><dd>a process of deducing the location of
	might be achieved, for example, by tracing the route of the DetNe		a network failure from a set of observed failure indications.
	t flow in which the network failure was detected.		For example, this might be achieved by tracing the route of the D
	Another method of fault localization can correlate reports of fai		etNet flow in which the network failure was detected.
	lures from a set of interleaved sessions monitoring path continuity.</li>		Another method of fault localization can correlate reports of fai
	<li>		lures from a set of interleaved sessions monitoring path continuity.</dd>
	Fault characterization is a process of identifying the root cause of t		<dt>Fault characterization:</dt><dd>a process of identifying the
	he problem. For instance, misconfiguration or malfunction of PREOF elements		root cause of the problem. For instance, misconfiguration or malfunction of PREO
			F elements
	can be the cause of erroneous packet		can be the cause of erroneous packet
	replication or extra packets being flooded in the DetNet domain.		replication or extra packets being flooded in the DetNet domain.
	</li>		</dd>
	</ul>		</dl>
	</section>		</section>
	<section anchor="hybrid-oam" numbered="true" toc="default">		<section anchor="hybrid-oam" numbered="true" toc="default">
	<name>Use of Hybrid OAM in DetNet</name>		<name>Use of Hybrid OAM in DetNet</name>
	<t>Hybrid OAM methods are used in performance monitoring and defined in <xref target="RFC7799" format="default"/> as:		<t>Hybrid OAM methods are used in performance monitoring and defined in <xref target="RFC7799" format="default"/> as follows:
	</t>		</t>
	<ul empty="true" spacing="normal">		<blockquote>
	<li>Hybrid Methods are Methods of Measurement that use a combination o		<t>Hybrid Methods are Methods of Measurement that use a combination of
	f		Active Methods and Passive Methods.</t>
	Active Methods and Passive Methods.</li>		</blockquote>
	</ul>
	<t>		<t>
	A hybrid measurement method can produce metrics as close to measured using a pas sive measurement method.		A hybrid measurement method can produce metrics as close to measured using a pas sive measurement method.
	The passive methods measure metrics closest to the network's actual conditions. A hybrid method,		The passive methods measure metrics closest to the network's actual conditions. A hybrid method,
	even if it alters something in a data packet, even if that is as little as the v alue of a designated field in the packet encapsulation,		even if it alters something in a data packet, even if that is as little as the v alue of a designated field in the packet encapsulation,
	is considered an approximation of a passive measurement method.		is considered an approximation of a passive measurement method.
	One example of such a hybrid measurement method		One example of such a hybrid measurement method
	is the Alternate Marking method (AMM) described in <xref target="RFC9341" for		is the Alternate-Marking Method (AMM) described in <xref target="RFC9341" for
	mat="default"/>.		mat="default"/>.
	As with all on-path telemetry methods, AMM in a DetNet domain with the IP dat		As with all on-path telemetry methods, AMM in a DetNet domain with the IP dat
	a plane is natively in-band		a plane is, by design, in band
	with respect to the monitored DetNet flow. Because the marking is applied to a data flow,		with respect to the monitored DetNet flow. Because the marking is applied to a data flow,
	measured metrics are directly applicable to the DetNet flow. AMM minimizes the additional load on		measured metrics are directly applicable to the DetNet flow. AMM minimizes the additional load on
	the DetNet domain by using nodal collection and computation of performance met		the DetNet domain by using nodal collection and computation of performance met
	rics in combination with		rics optionally in combination with
	optionally using out-of-band telemetry collection for further network analysis		using out-of-band telemetry collection for further network analysis.
	.
	</t>		</t>
	</section>		</section>
	</section>		</section>
	<!-- ADMINISTRATION -->
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Administration</name>		<name>Administration</name>
	<t>		<t>
	The ability to expose a collection of metrics to support an operator's dec ision-making is essential.		The ability to expose a collection of metrics to support an operator's dec ision-making is essential.
	The following performance metrics are useful:		The following performance metrics are useful:
	</t>		</t>
	<ul spacing="normal">		<dl>
	<li>		<dt>Queuing Delay:</dt><dd>the time elapsed between enqueuing a packet a
	Queuing Delay: the time elapsed between enqueuing a packet and its t		nd its transmission to the next hop.
	ransmission to the next hop.		</dd>
	</li>		<dt>Buffer occupancy:</dt><dd>the number of packets present in the buffe
	<li>		r for each of the existing flows.
	Buffer occupancy: the number of packets present in the buffer, for e		</dd>
	ach of the existing flows.		<dt>Per DetNet flow:</dt><dd>a metric reflecting end-to-end performance
	</li>		for a given flow.
	<li>
	Per DetNet flow, a metric reflecting end-to-end performance for a gi
	ven flow.
	Each of the paths has to be isolated in a multipath routing environm ent.		Each of the paths has to be isolated in a multipath routing environm ent.
	</li>		</dd>
	<li>		<dt>Per-path:</dt><dd>detection of a misbehaving path or paths when mult
	Per path, detection of misbehaving path(s) when multiple paths are u		iple paths are used for the service protection.
	sed for the service protection.		</dd>
	</li>		<dt>Per-device:</dt><dd>detection of a misbehaving device.
	<li>		</dd>
	Per device, detection of a misbehaving device.		</dl>
	</li>
	</ul>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Collection of metrics</name>		<name>Collection of Metrics</name>
	<t>		<t>
	It is important to optimize the volume and frequency of statistics/ measurement collection,		It is important to optimize the volume and frequency of statistics/ measurement collection,
	whether the mechanisms are distributed, centralized, or both. Perio dic and		whether the mechanisms are distributed, centralized, or both. Perio dic and
	event-triggered collection information characterizing the state of a network is		event-triggered collection information characterizing the state of a network is
	an example of mechanisms to achieve the optimization.		an example of mechanisms to achieve the optimization.
	</t>		</t>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Worst-case metrics</name>		<name>Worst-Case Metrics</name>
	<t>		<t>
	DetNet aims to enable real-time communications on top of a heterogeneou s multi-hop architecture.		DetNet aims to enable real-time communications on top of a heterogeneou s multi-hop architecture.
	To make correct decisions, the DetNet Controller Plane <xref target="RF C8655"/> needs timely information		To make correct decisions, the DetNet Controller Plane <xref target="RF C8655"/> needs timely information
	about packet losses/delays for each flow, and each hop of the paths.		about packet losses/delays for each flow and each hop of the paths.
	In other words, just the average end-to-end statistics are not enough.		In other words, just the average end-to-end statistics are not enough.
	The collected information must be sufficient to allow a system to predi ct the worst-case scenario.		The collected information must be sufficient to allow a system to predi ct the worst-case scenario.
	</t>		</t>
	</section>		</section>
	</section>		</section>
	<!-- MAINTENANCE -->
	<!-- speak about predictive maintenance? -->
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Maintenance</name>		<name>Maintenance</name>
	<t>		<t>
	Service protection (provided by the DetNet Service sub-layer) is designed to mitigate simple network failures more rapidly		Service protection (provided by the DetNet Service sub-layer) is designed to mitigate simple network failures more rapidly
	than the expected response time of the DetNet Controller Plane.		than the expected response time of the DetNet Controller Plane.
	In the face of events that impact network operation (e.g., link up/down,		In the face of events that impact network operation (e.g., link up/down,
	device crash/reboot, flows starting and ending), the DetNet Controller		device crash/reboot, flows starting and ending), the DetNet Controller
	Plane needs to perform		Plane needs to perform
	repair and re-optimization actions in order to permanently ensure		repair and reoptimization actions in order to permanently ensure
	SLOs of all active flows with minimal waste of resources.		SLOs of all active flows with minimal waste of resources.
	The Controller Plane is expected to be able to continuously retrieve th e state of the network,		The Controller Plane is expected to be able to continuously retrieve th e state of the network,
	to evaluate conditions and trends about the relevance of a reconfigurat ion, quantifying:		to evaluate conditions and trends about the relevance of a reconfigurat ion, quantifying the following:
	</t>		</t>
	<ul spacing="normal">		<dl spacing="normal">
	<li> the cost of the sub-optimality: resources may not be used optimally		<dt>the cost of the suboptimality:</dt><dd>resources may not be used opt
	(i.e., a better path exists).		imally (i.e., a better path exists).
	</li>		</dd>
	<li>		<dt>the reconfiguration cost:</dt><dd>the DetNet Controller Plane needs
	the reconfiguration cost: the DetNet Controller Plane needs an ab		an ability to trigger some reconfigurations.
	ility to trigger some reconfigurations.
	For this transient period, resources may be twice reserved, and c ontrol packets have to be transmitted.		For this transient period, resources may be twice reserved, and c ontrol packets have to be transmitted.
	</li>		</dd>
	</ul>		</dl>
	<t>		<t>
	Thus, reconfiguration may only be triggered if the gain is significant.		Thus, reconfiguration may only be triggered if the gain is significant.
	</t>		</t>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Replication / Elimination</name>		<name>Replication/Elimination</name>
	<t>		<t>
	When multiple paths are reserved between two MEPs,		When multiple paths are reserved between two MEPs,
	packet replication may be used to introduce redundancy and alleviate transmiss ion errors and collisions.		packet replication may be used to introduce redundancy and alleviate transmiss ion errors and collisions.
	For instance, in <xref target="fig_replication" format="default"/> , the source device S transmits		For instance, in <xref target="fig_replication" format="default"/> , the source device S transmits
	a packet to devices A and B to reach the destination node R.		a packet to devices A and B to reach the destination node R.
	</t>		</t>
	<figure anchor="fig_replication">		<figure anchor="fig_replication">
	<name>Packet Replication and Elimination Functions</name>		<name>Packet Replication and Elimination Functions</name>
	<artwork align="center" name="" type="" alt=""><![CDATA[		<artwork align="center" name="" type="" alt=""><![CDATA[
	skipping to change at line 549 ¶		skipping to change at line 536 ¶
	===> (A) => (C) => (E) ===		===> (A) => (C) => (E) ===
	// \\// \\// \\		// \\// \\// \\
	source (S) //\\ //\\ (R) (root)		source (S) //\\ //\\ (R) (root)
	\\ // \\ // \\ //		\\ // \\ // \\ //
	===> (B) => (D) => (F) ===		===> (B) => (D) => (F) ===
	]]></artwork>		]]></artwork>
	</figure>		</figure>
	</section>		</section>
	<section numbered="true" toc="default">		<section numbered="true" toc="default">
	<name>Resource Reservation</name>		<name>Resource Reservation</name>
	<t>		<t>Because the quality of service associated with a path may degrade, th
			e network has
	Because the quality of service criteria associated with a path may d
	egrade, the network has
	to provision additional resources along the path.		to provision additional resources along the path.
	</t>		</t>
	</section>		</section>
	</section>		</section>
	<section anchor="req-list" numbered="true" toc="default">		<section anchor="req-list" numbered="true" toc="default">
	<name>Requirements</name>		<name>Requirements</name>
	<t>		<t>
	According to <xref target="RFC8655"/>, DetNet functionality is divided int o forwarding and service sub-layers.		According to <xref target="RFC8655"/>, DetNet functionality is divided int o forwarding and service sub-layers.
	The DetNet forwarding sub-layer includes DetNet transit nodes and may allo cate resources for a DetNet flow over paths provided by the underlay network.		The DetNet forwarding sub-layer includes DetNet transit nodes and may allo cate resources for a DetNet flow over paths provided by the underlay network.
	The DetNet service sub-layer includes DetNet relay nodes and provides a De tNet service (e.g., service protection).		The DetNet service sub-layer includes DetNet relay nodes and provides a De tNet service (e.g., service protection).
	This section lists general requirements for DetNet OAM as well as requirements in each of the DetNet sub-layers of a DetNet domain.		This section lists general requirements for DetNet OAM as well as requirements in each of the DetNet sub-layers of a DetNet domain.
	</t>		</t>
	<ol spacing="normal" type="1">		<ol spacing="normal" type="1">
	<li>		<li>
	It MUST be possible to initiate a DetNet OAM session from a MEP locate		It <bcp14>MUST</bcp14> be possible to initiate a DetNet OAM session fr
	d at a		om a MEP located at a
	DetNet node towards MEP(s) downstream from that DetNet node		DetNet node towards a MEP or MEPs downstream from that DetNet node
	within the given domain at a particular DetNet sub-layer.		within the given domain at a particular DetNet sub-layer.
	</li>		</li>
	<li>		<li>
	It MUST be possible to initiate a DetNet OAM session from using any of DetNet Controller Plane solutions, e.g., centralized controller.		It <bcp14>MUST</bcp14> be possible to initiate a DetNet OAM session using any of the DetNet Controller Plane solutions, e.g., a centralized controller.
	</li>		</li>
	<li>		<li>
	DetNet OAM MUST support proactive OAM monitoring and measurement methods.		DetNet OAM <bcp14>MUST</bcp14> support proactive OAM monitoring and measuremen t methods.
	</li>		</li>
	<li>		<li>
	DetNet OAM MUST support on-demand OAM monitoring and measurement methods.		DetNet OAM <bcp14>MUST</bcp14> support on-demand OAM monitoring and measuremen
	</li>		t methods.
	<li>
	DetNet OAM MUST support unidirectional OAM methods, continuity check,
	connectivity verification, and performance measurement.
	</li>		</li>
	<!--
	<li>		<li>
	DetNet OAM methods MAY combine in-band monitoring or measurement in the forwar		DetNet OAM <bcp14>MUST</bcp14> support unidirectional OAM methods, continuity
	d direction and out-of-band		checks,
	notification in the reverse direction, i.e., towards the ingress MEP.		connectivity verification, and performance measurements.
	</li>		</li>
	-->
	<li>		<li>
	DetNet OAM MUST support bi-directional DetNet flows,		DetNet OAM <bcp14>MUST</bcp14> support bidirectional DetNet flows,
	but is not required to support bi-directional OAM methods for bi-directional		but it is not required to support bidirectional OAM methods for bidirectiona
	DetNet flows.		l DetNet flows.
	DetNet OAM test packets used for monitoring and measurements		DetNet OAM test packets used for monitoring and measurements
	of a bi-directional DetNet flow MUST be in-band in both directions.		of a bidirectional DetNet flow <bcp14>MUST</bcp14> be in band in both direct ions.
	</li>		</li>
	<li>		<li>
	DetNet OAM MUST support proactive monitoring of a DetNet device reachability for a given DetNet flow.		DetNet OAM <bcp14>MUST</bcp14> support proactive monitoring of a DetNet device's reachability for a given DetNet flow.
	</li>		</li>
	<li>		<li>
	DetNet OAM MUST support hybrid performance measurement methods.		DetNet OAM <bcp14>MUST</bcp14> support hybrid performance measurement methods.
	</li>		</li>
	<li>		<li>
	Calculated performance metrics MUST include but are not limited to throughput, p		Calculated performance metrics <bcp14>MUST</bcp14> include, but are not limited
	acket loss, out of order,		to, throughput, packet-loss, out-of-order,
	delay, and delay variation metrics. <xref target="RFC6374" format="default"/> pr		delay, and delay-variation metrics. <xref target="RFC6374" format="default"/> pr
	ovides detailed information on performance		ovides detailed information on performance
	measurement and performance metrics.		measurement and performance metrics.
	</li>		</li>
	</ol>		</ol>
	<section anchor="req-on-dfs-oam" title="For the DetNet Forwarding Sub-la yer">		<section anchor="req-on-dfs-oam" title="For the DetNet Forwarding Sub-la yer">
			<t>DetNet OAM <bcp14>MUST</bcp14> support:</t>
	<ol spacing="normal" type="1">		<ol spacing="normal" type="1">
	<li>		<li>PMTU discovery.
	DetNet OAM MUST support Path Maximum Transmission Unit discovery.
	</li>		</li>
	<li>		<li>Remote Defect Indication (RDI) notification to the DetNet OAM instan
	DetNet OAM MUST support Remote Defect Indication notification to the DetNet OAM		ce
	instance
	performing continuity checking.		performing continuity checking.
	</li>		</li>
	<li>		<li>the monitoring of levels of resources allocated for a particular D
	DetNet OAM MUST support monitoring levels of resources allocated for a particu		etNet flow.
	lar DetNet flow.		Such resources include, but are not limited to, buffer utilization and schedul
	Such resources include but are not limited to buffer utilization and scheduler		er transmission calendar.
	transmission calendar.
	</li>		</li>
	<li>		<li>the monitoring of any subset of paths traversed through the DetNet d
	DetNet OAM MUST support monitoring any subset of paths traversed through the D		omain by a DetNet flow.
	etNet domain by a DetNet flow.
	</li>		</li>
	</ol>		</ol>
	</section>		</section>
	<section anchor="req-on-dss-oam" title="For the DetNet Service Sub-layer">		<section anchor="req-on-dss-oam" title="For the DetNet Service Sub-layer">
	<t>		<t>
	The OAM functions for the DetNet service sub-layer allow, for example, t		The OAM functions for the DetNet service sub-layer allow, for example, t
	o		he
	recognize/discover DetNet relay nodes, to get information about their		recognizing/discovery of DetNet relay nodes, the gathering of informatio
	configuration, and to check their operation or status.		n about their
			configuration, and the checking of their operation or status.
	</t>		</t>
	<t>		<t>
	The requirements on OAM for a DetNet relay node are:		The requirements on OAM for a DetNet relay node are that DetNet OAM <bcp14> MUST</bcp14>:
	</t>		</t>
	<ol spacing="normal" type="1">		<ol spacing="normal" type="1">
	<li>DetNet OAM MUST provide OAM functions for the DetNet service sub-la		<li>provide OAM functions for the DetNet service sub-layer. </li>
	yer. </li>		<li>support the discovery of DetNet relay nodes in a DetNet network.
	<li>
	DetNet OAM MUST support the discovery of DetNet relay nodes in a DetNet
	network.
	</li>		</li>
	<li>		<li>support the discovery of PREOF locations in the domain.
	DetNet OAM MUST support the discovery of PREOF locations in the domain.
	</li>		</li>
	<li>		<li>support the collection of information specific to the DetNet servic
	DetNet OAM MUST support the collection of the DetNet service sub-layer		e sub-layer
	specific		(configuration/operation/status) from DetNet relay nodes.
	(configuration/operation/status) information from DetNet relay nodes.
	</li>		</li>
	<li>		<li>support exercising functionality of PREOF in the domain.
	DetNet OAM MUST support excercising functionality of PREOF in t
	he domain.
	</li>		</li>
	<li>DetNet OAM MUST work for DetNet data planes - MPLS and IP. <		<li>work for DetNet data planes: MPLS and IP. </li>
	/li>		<li>support a defect notification mechanism, like Alarm Indicatio
	<li>		n Signal.
	DetNet OAM MUST support a defect notification mechanism, like Alarm Indication S
	ignal.
	Any DetNet relay node providing service for a given DetNet flow		Any DetNet relay node providing service for a given DetNet flow
	MAY originate a defect notification addressed to any subset of DetNet relay node s along that flow.		<bcp14>MAY</bcp14> originate a defect notification addressed to any subset of De tNet relay nodes along that flow.
	</li>		</li>
	<li>		<li>be able to measure metrics (e.g. delay) inside a collection of OAM sessi
	DetNet OAM MUST be able to measure metrics (e.g. delay) inside a collection of O		ons, specially for complex DetNet flows, with PREOF features.
	AM sessions, specially for complex DetNet flows, with PREOF features.
	</li>		</li>
	</ol>		</ol>
	</section> <!-- end of service sub-layer requirements -->		</section>
	</section>		</section>
	<section anchor="iana-consider" numbered="true" toc="default">		<section anchor="iana-consider" numbered="true" toc="default">
	<name>IANA Considerations</name>		<name>IANA Considerations</name>
	<t>This document has no actionable requirements for IANA. This section can
	be removed before publication.</t>		<t>This document has no IANA actions.</t>
	</section>		</section>
	<section anchor="security" numbered="true" toc="default">		<section anchor="security" numbered="true" toc="default">
	<name>Security Considerations</name>		<name>Security Considerations</name>
	<t>		<t>
	This document lists the OAM requirements for a DetNet domain		This document lists the OAM requirements for a DetNet domain
	and does not raise any security concerns or issues in addition to ones common to networking and		and does not raise any security concerns or issues in addition to ones common to networking and
	those specific to DetNet discussed in Section 9 of <xref target="RFC9055" for		those specific to DetNet that are discussed in <xref target="RFC9055" section
	mat="default"/>.		Format="of" section="9"/>.
	Furthermore, the analysis of OAM security concerns in Section 6 of <xref t		Furthermore, the analysis of OAM security concerns in <xref target="RFC727
	arget="RFC7276"/>		6" sectionFormat="of" section="6"/>
	also applies to DetNet OAM, including the use of OAM for network reconnais sance.</t>		also applies to DetNet OAM, including the use of OAM for network reconnais sance.</t>
	</section>		</section>
	<section anchor="privacy" numbered="true" toc="default">		<section anchor="privacy" numbered="true" toc="default">
	<name>Privacy Considerations</name>		<name>Privacy Considerations</name>
	<t>		<t>
	Privacy considerations of DetNet discussed in Section 13 of <xref target="RFC9 055" format="default"/>		Privacy considerations of DetNet discussed in <xref target="RFC9055" sectionFo rmat="of" section="13"/>
	are also applicable to DetNet OAM. If any privacy mechanism is used for the mo nitored DetNet flow, then		are also applicable to DetNet OAM. If any privacy mechanism is used for the mo nitored DetNet flow, then
	the same privacy method MUST be applied to the active DetNet OAM used to monit		the same privacy method <bcp14>MUST</bcp14> be applied to the active DetNet OA
	or the flow.		M used to monitor the flow.
	</t>
	</section>
	<section numbered="true" toc="default">
	<name>Acknowledgments</name>
	<t>
	The authors express their appreciation and gratitude to Pascal Thubert f
	or the review, insightful questions, and helpful comments.
	</t>		</t>
	</section>		</section>
	</middle>		</middle>
	<back>		<back>
			<displayreference target="I-D.ietf-ippm-hybrid-two-step" to="HYBRID-TWO-STEP"/
			>
	<references>		<references>
	<name>References</name>		<name>References</name>
	<references>		<references>
	<name>Normative References</name>		<name>Normative References</name>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R
	FC.2119.xml"/>		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.21
	<!-- Key words for use in RFCs to Indicate Requirement Levels -->		19.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.RFC.8		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.81
	174.xml"/>		74.xml"/>
	<!-- Ambiguity of Uppercase vs Lowercase -->		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.86
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/ref		55.xml"/>
	erence.RFC.8655.xml"/>
	<!-- Deterministic Networking Architecture -->
	</references>		</references>
	<references>		<references>
	<name>Informative References</name>		<name>Informative References</name>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R
	FC.6291.xml"/>
	<!-- OAM definition -->
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R
	FC.7276.xml"/>
	<!-- An Overview of Operations, Administration, and Maintenance (OAM) To
	ols -->
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.62
	FC.7799.xml"/>		91.xml"/>
	<!-- passive / active methods -->		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.72
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		76.xml"/>
	FC.2544.xml"/>		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.77
	<!-- test packets -->		99.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.25
	FC.8939.xml"/>		44.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.89
	FC.6374.xml"/>		39.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.63
	FC.9055.xml"/>		74.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.90
	FC.8641.xml"/>		55.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.86
	FC.9197.xml"/>		41.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.91
	.RFC.9326.xml"/>		97.xml"/>
	<xi:include href="https://datatracker.ietf.org/doc/bibxml3/draft-mirs		<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.93
	ky-ippm-hybrid-two-step.xml"/>		26.xml"/>
			<xi:include href="https://datatracker.ietf.org/doc/bibxml3/reference.I-D
			.ietf-ippm-hybrid-two-step.xml"/>
			<xi:include href="https://bib.ietf.org/public/rfc/bibxml/reference.RFC.9
			341.xml"/>
	<xi:include href="https://xml2rfc.ietf.org/public/rfc/bibxml/reference.R FC.9341.xml"/>
	</references>		</references>
	</references>		</references>
			<section numbered="false" toc="default">
			<name>Acknowledgments</name>
			<t>
			The authors express their appreciation and gratitude to <contact fullna
			me="Pascal Thubert"/> for the review, insightful questions, and helpful comments
			.
			</t>
			</section>
	</back>		</back>
	</rfc>		</rfc>
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