Internet DRAFT - draft-galikunze-ccamp-g-698-2-snmp-mib

draft-galikunze-ccamp-g-698-2-snmp-mib







Internet Engineering Task Force                        G.Galimberti, Ed.
Internet-Draft                                                     Cisco
Intended status: Standards Track                            R.Kunze, Ed.
Expires: January 7, 2016                                Deutsche Telekom
                                                            Kam Lam, Ed.
                                                          Alcatel-Lucent
                                                     D. Hiremagalur, Ed.
                                                                 Juniper
                                                             L.Fang, Ed.
                                                        G.Ratterree, Ed.
                                                               Microsoft
                                                            July 6, 2015


An SNMP MIB extension to RFC3591 to manage optical interface parameters
            of "G.698.2 single channel" in DWDM applications
               draft-galikunze-ccamp-g-698-2-snmp-mib-12

Abstract

   This memo defines a module of the Management Information Base (MIB)
   used by Simple Network Management Protocol (SNMP) in TCP/IP- based
   internet.  In particular, it defines objects for managing single
   channel optical interface parameters of DWDM applications, using the
   approach specified in G.698.2 [ITU.G698.2] .  This interface,
   described in ITU-T G.872, G.709 and G.798, is one type of OTN multi-
   vendor Intra-Domain Interface (IaDI).  This RFC is an extension of
   RFC3591 to support the optical parameters specified in ITU-T G.698.2
   and application identifiers specified in ITU-T G.874.1 [ITU.G874.1].
   Note that G.874.1 encompasses vendor-specific codes, which if used
   would make the interface a single vendor IaDI and could still be
   managed.

   The MIB module defined in this memo can be used for Optical
   Parameters monitoring and/or configuration of the endpoints of the
   multi-vendor IaDI based on the Black Link approach.

Copyright Notice

   Copyright (c) 2015 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

Status of This Memo

   This Internet-Draft is submitted in full conformance with the
   provisions of BCP 78 and BCP 79.





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   Copyright (c) 2015 IETF Trust and the persons identified as the
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Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   3
   2.  The Internet-Standard Management Framework  . . . . . . . . .   4
   3.  Conventions . . . . . . . . . . . . . . . . . . . . . . . . .   5
   4.  Overview  . . . . . . . . . . . . . . . . . . . . . . . . . .   5
     4.1.  Use Cases . . . . . . . . . . . . . . . . . . . . . . . .   6
     4.2.  Optical Parameters Description  . . . . . . . . . . . . .  13
       4.2.1.  Rs-Ss Configuration . . . . . . . . . . . . . . . . .  13
       4.2.2.  Table of Application Identifiers  . . . . . . . . . .  14
     4.3.  Use of ifTable  . . . . . . . . . . . . . . . . . . . . .  15
       4.3.1.  Use of ifTable for OPS Layer  . . . . . . . . . . . .  16
       4.3.2.  Use of ifTable for OCh Layer  . . . . . . . . . . . .  17
       4.3.3.  Use of ifStackTable . . . . . . . . . . . . . . . . .  17
   5.  Structure of the MIB Module . . . . . . . . . . . . . . . . .  18
   6.  Object Definitions  . . . . . . . . . . . . . . . . . . . . .  18
   7.  Relationship to Other MIB Modules . . . . . . . . . . . . . .  25
     7.1.  Relationship to the [TEMPLATE TODO] MIB . . . . . . . . .  25
     7.2.  MIB modules required for IMPORTS  . . . . . . . . . . . .  25
   8.  Definitions . . . . . . . . . . . . . . . . . . . . . . . . .  25
   9.  Security Considerations . . . . . . . . . . . . . . . . . . .  25



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   10. IANA Considerations . . . . . . . . . . . . . . . . . . . . .  26
   11. Contributors  . . . . . . . . . . . . . . . . . . . . . . . .  26
   12. References  . . . . . . . . . . . . . . . . . . . . . . . . .  27
     12.1.  Normative References . . . . . . . . . . . . . . . . . .  27
     12.2.  Informative References . . . . . . . . . . . . . . . . .  29
   Appendix A.  Change Log . . . . . . . . . . . . . . . . . . . . .  30
   Appendix B.  Open Issues  . . . . . . . . . . . . . . . . . . . .  30
   Authors' Addresses  . . . . . . . . . . . . . . . . . . . . . . .  30

1.  Introduction

   This memo defines a portion of the Management Information Base (MIB)
   used by Simple Network Management Protocol (SNMP)in TCP/IP-based
   internets.  In particular, it defines objects for managing single
   channel optical interface parameters of DWDM applications, using the
   approach specified in G.698.2.  This RFC is an extension of RFC3591
   to support the optical parameters specified in ITU-T G.698.2
   [ITU.G698.2] and application identifiers specified in ITU-T G.874.1
   [ITU.G874.1] .  Note that G.874.1 encompasses vendor-specific codes,
   which if used would make the interface a single vendor IaDI and could
   still be managed.

   The Black Link approach allows supporting an optical transmitter/
   receiver pair of one vendor to inject an optical tributary signal and
   run it over an optical network composed of amplifiers, filters, add-
   drop multiplexers from a different vendor.  In the OTN architecture,
   the 'black-link' represents a pre-certified network media channel
   conforming to G.698.2 specifications at the S and R reference points.

   [Editor's note: In G.698.2 this corresponds to the optical path from
   point S to R; network media channel is also used and explained in
   draft-ietf-ccamp-flexi-grid-fwk-02]

   Management will be performed at the edges of the network media
   channel (i.e., at the transmitters and receivers attached to the S
   and R reference points respectively) for the relevant parameters
   specified in G.698.2 [ITU.G698.2], G.798 [ITU.G798], G.874
   [ITU.G874], and the performance parameters specified in G.7710/Y.1701
   [ITU-T G.7710] and G.874.1 [ITU.G874.1].

   G.698.2 [ITU.G698.2] is primarily intended for metro applications
   that include optical amplifiers.  Applications are defined in G.698.2
   [ITU.G698.2] using optical interface parameters at the single-channel
   connection points between optical transmitters and the optical
   multiplexer, as well as between optical receivers and the optical
   demultiplexer in the DWDM system.  This Recommendation uses a
   methodology which does not explicitly specify the details of the
   optical network between reference point Ss and Rs, e.g., the passive



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   and active elements or details of the design.  The Recommendation
   currently includes unidirectional DWDM applications at 2.5 and 10
   Gbit/s (with 100 GHz and 50 GHz channel frequency spacing).  Work is
   still under way for 40 and 100 Gbit/s interfaces.  There is
   possibility for extensions to a lower channel frequency spacing.
   This document specifically refers to the "application code" defined
   in the G.698.2 [ITU.G698.2] and included in the Application
   Identifier defined in G.874.1 [ITU.G874.1] and G.872 [ITU.G872], plus
   a few optical parameters not included in the G.698.2 application code
   specification.

   This draft refers and supports also the draft-kunze-g-698-2-
   management-control-framework

   The building of an SNMP MIB describing the optical parameters defined
   in G.698.2 [ITU.G698.2], and reflected in G.874.1 [ITU.G874], allows
   the different vendors and operator to retrieve, provision and
   exchange information across the G.698.2 multi-vendor IaDI in a
   standardized way.

   The MIB, reporting the Optical parameters and their values,
   characterizes the features and the performances of the optical
   components and allow a reliable black link design in case of multi
   vendor optical networks.

   Although RFC 3591 [RFC3591] describes and defines the SNMP MIB of a
   number of key optical parameters, alarms and Performance Monitoring,
   as this RFC is over a decade old, it is primarily pre-OTN, and a more
   complete and up-to-date description of optical parameters and
   processes can be found in the relevant ITU-T Recommendations.  The
   same considerations can be applied to the RFC 4054 [RFC4054]

2.  The Internet-Standard Management Framework

   For a detailed overview of the documents that describe the current
   Internet-Standard Management Framework, please refer to section 7 of
   RFC 3410 [RFC3410].

   Managed objects are accessed via a virtual information store, termed
   the Management Information Base or MIB.  MIB objects are generally
   accessed through the Simple Network Management Protocol (SNMP).
   Objects in the MIB are defined using the mechanisms defined in the
   Structure of Management Information (SMI).  This memo specifies a MIB
   module that is compliant to the SMIv2, which is described in STD 58,
   RFC 2578 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC 2580
   [RFC2580].





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3.  Conventions

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in RFC 2119 [RFC2119] In
   the description of OIDs the convention: Set (S) Get (G) and Trap (T)
   conventions will describe the action allowed by the parameter.

4.  Overview

   Figure 1 shows a set of reference points, for the linear "black link"
   approach, for single-channel connection (Ss and Rs) between
   transmitters (Tx) and receivers (Rx).  Here the DWDM network elements
   include an OM and an OD (which are used as a pair with the opposing
   element), one or more optical amplifiers and may also include one or
   more OADMs.


             +-------------------------------------------------+
         Ss  |              DWDM Network Elements              | Rs
    +---+ |  |  | \                                       / |  |  | +--+
    Tx L1----|->|   \    +------+            +------+   /   |--|-->Rx L1
    +---+    |  |    |   |      |  +------+  |      |  |    |  |    +--+
    +---+    |  |    |   |      |  |      |  |      |  |    |  |    +--+
    Tx L2----|->| OM |-->|------|->| OADM |--|------|->| OD |--|-->Rx L2
    +---+    |  |    |   |      |  |      |  |      |  |    |  |    +--+
    +---+    |  |    |   |      |  +------+  |      |  |    |  |    +--+
    Tx L3----|->|   /    | DWDM |    |  ^    | DWDM |   \   |--|-->Rx L3
    +---+    |  | /      | Link +----|--|----+ Link |     \ |  |    +--+
             +-----------+           |  |           +----------+
                                  +--+  +--+
                                  |        |
                               Rs v        | Ss
                               +-----+  +-----+
                               |RxLx |  |TxLx |
                               +-----+  +-----+
      Ss = reference point at the DWDM network element tributary output
      Rs = reference point at the DWDM network element tributary input
      Lx = Lambda x
      OM = Optical Mux
      OD = Optical Demux
      OADM = Optical Add Drop Mux


   from Fig. 5.1/G.698.2

                   Figure 1: Linear Black Link approach




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   G.698.2 [ITU.G698.2] defines also Ring "Black Link" approach
   configurations [Fig. 5.2/G.698.2] and Linear "black link" approach
   for Bidirectional applications[Fig. 5.3/G.698.2]

4.1.  Use Cases

   The use cases described below are assuming that power monitoring
   functions are available in the ingress and egress network element of
   the DWDM network, respectively.  By performing link property
   correlation it would be beneficial to include the current transmit
   power value at reference point Ss and the current received power
   value at reference point Rs.  For example if the Client transmitter
   power (OXC1) has a value of 0dBm and the ROADM interface measured
   power (at OLS1) is -6dBm the fiber patch cord connecting the two
   nodes may be pinched or the connectors are dirty.  More, the
   interface characteristics can be used by the OLS network Control
   Plane in order to check the Optical Channels feasibility.  Finally
   the OXC1 transceivers parameters (Application Code) can be shared
   with OXC2 using the LMP protocol to verify the Transceivers
   compatibility.  The actual route selection of a specific wavelength
   within the allowed set is outside the scope of LMP.  In GMPLS, the
   parameter selection (e.g. central frequency) is performed by RSVP-TE.

   G.698.2 defines a single channel optical interface for DWDM systems
   that allows interconnecting network-external optical transponders
   across a DWDM network.  The optical transponders are considered to be
   external to the DWDM network.  This so-called 'black link' approach
   illustrated in Figure 5-1 of G.698.2 and a copy of this figure is
   provided below.  The single channel fiber link between the Ss/Rs
   reference points and the ingress/egress port of the network element
   on the domain boundary of the DWDM network (DWDM border NE) is called
   access link in this contribution.  Based on the definition in G.698.2
   it is considered to be part of the DWDM network.  The access link
   typically is realized as a passive fiber link that has a specific
   optical attenuation (insertion loss).  As the access link is an
   integral part of the DWDM network, it is desirable to monitor its
   attenuation.  Therefore, it is useful to detect an increase of the
   access link attenuation, for example, when the access link fiber has
   been disconnected and reconnected (maintenance) and a bad patch panel
   connection (connector) resulted in a significantly higher access link
   attenuation (loss of signal in the extreme case of an open connector
   or a fiber cut).  In the following section, two use cases are
   presented and discussed:

        1) pure access link monitoring
        2) access link monitoring with a power control loop





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   These use cases require a power monitor as described in G.697 (see
   section 6.1.2), that is capable to measure the optical power of the
   incoming or outgoing single channel signal.  The use case where a
   power control loop is in place could even be used to compensate an
   increased attenuation as long as the optical transmitter can still be
   operated within its output power range defined by its application
   code.












































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   Figure 2 Access Link Power Monitoring



                                      +--------------------------+
                                      |    P(in) = P(Tx) - a(Tx) |
                                      |    ___                   |
      +----------+                    |    \ /  Power Monitor    |
      |          | P(Tx)              |     V                    |
      |  +----+  | Ss    //\\         |     |    |\              |
      |  | TX |----|-----\\//------------------->| \             |
      |  +----+  | Access Link (AL-T) |       .  |  |            |
      |          | attenuation a(Tx)  |       .  |  |==============>
      |          |                    |       .  |  |            |
      | External |                    |      --->| /             |
      | Optical  |                    |          |/              |
      |Transpond.|                    |    P(out)                |
      |          |                    |    ___                   |
      |          |                    |    \ /  Power Monitor    |
      |          | P(Rx)              |     V                    |
      |  +----+  | Rs    //\\         |     |    |\              |
      |  | RX |<---|-----\\//--------------------| \             |
      |  +----+  | Access Link (AL-R) |       .  |  |            |
      |          | Attenuation a(Rx)  |       .  |  |<==============
      +----------+                    |       .  |  |            |
                                      |      <---| /             |
      P(Rx) = P(out) - a(Rx)          |          |/              |
                                      |                          |
                                      |           ROADM          |
                                      +--------------------------+

        -  For AL-T monitoring: P(Tx) and a(Tx) must be known
        -  For AL-R monitoring: P(RX) and a(Rx) must be known

       An alarm shall be raised if P(in) or P(Rx) drops below a
       configured threshold (t [dB]):
       -  P(in) < P(Tx) - a(Tx) - t (Tx direction)
       -  P(Rx) < P(out) - a(Rx) - t (Rx direction)
       -  a(Tx) =| a(Rx)


                       Figure 2: Extended LMP Model









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   Pure Access Link  (AL) Monitoring Use Case

   Figure 4 illustrates the access link monitoring use case and the
   different physical properties involved that are defined below:

    - Ss, Rs: G.698.2 reference points
    - P(Tx):  current optical output power of transmitter Tx
    - a(Tx):  access link attenuation in Tx direction (external
              transponder point of view)
    - P(in):  measured current optical input power at the input port
              of border DWDM NE
    - t:      user defined threshold (tolerance)
    - P(out): measured current optical output power at the output
              port of border DWDM NE
    - a(Rx):  access link attenuation in Rx direction (external
              transponder point of view)
    - P(Rx):  current optical input power of receiver Rx

   Assumptions:
    - The access link attenuation in both directions (a(Tx), a(Rx))
      is known or can be determined as part of the commissioning
      process.  Typically, both values are the same.
    - A threshold value t has been configured by the operator. This
      should also be done during commissioning.
    - A control plane protocol is in place that allows
      to periodically send the optical power values P(Tx) and P(Rx)
      to the control plane protocol instance on the DWDM border NE.
      This is llustrated in Figure 3.
    - The DWDM border NE is capable to periodically measure the optical
      power Pin and Pout as defined in G.697 by power monitoring points
      depicted as yellow triangles in the figures below.

   AL monitoring process:
    - Tx direction: the measured optical input power Pin is compared
      with the expected optical input power P(Tx) - a(Tx). If the
      measured optical input power P(in) drops below the value
      (P(Tx) - a(Tx) - t) a low power alarm shall be raised indicating
      that the access link attenuation has exceeded a(Tx) + t.
    - Rx direction: the measured optical input power P(Rx) is
      compared with the expected optical input power P(out) - a(Rx).
      If the measured optical input power P(Rx) drops below the value
      (P(out) - a(Rx) - t) a
      low power alarm shall be raised indicating that the access link
      attenuation has exceeded a(Rx) + t.







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   Figure 3 Use case 1: Access Link power monitoring



     +----------+                    +--------------------------+
     | +------+ |    P(Tx), P(Rx)    |  +-------+               |
     | |      | | =================> |  |       |               |
     | | LMP  | |    P(in), P(out)   |  |  LMP  |               |
     | |      | | <================= |  |       |               |
     | +------+ |                    |  +-------+               |
     |          |                    |                          |
     |          |                    |    P(in) - P(Tx) - a(Tx) |
     |          |                    |    ___                   |
     |          |                    |    \ /  Power Monitor    |
     |          | P(Tx)              |     V                    |
     |  +----+  | Ss    //\\         |     |    |\              |
     |  | TX |----|-----\\//------------------->| \             |
     |  +----+  | Access Link (AL-T) |       .  |  |            |
     |          | attenuation a(Tx)  |       .  |  |==============>
     |          |                    |       .  |  |            |
     | External |                    |      --->| /             |
     | Optical  |                    |          |/              |
     |Transpond.|                    |    P(out)                |
     |          |                    |    ___                   |
     |          |                    |    \ /  Power Monitor    |
     |          | P(Rx)              |     V                    |
     |  +----+  | Rs    //\\         |     |    |\              |
     |  | RX |<---|-----\\//--------------------| \             |
     |  +----+  | Access Link (AL-R) |       .  |  |            |
     |          | Attenuation a(Rx)  |       .  |  |<==============
     +----------+                    |       .  |  |            |
                                     |      <---| /             |
     P(Rx) = P(out) - a(Rx)          |          |/              |
                                     |                          |
                                     |           ROADM          |
                                     +--------------------------+

      - For AL-T monitoring: P(Tx) and a(Tx) must be known
      - For AL-R monitoring: P(RX) and a(Rx) must be known
      An alarm shall be raised if P(in) or P(Rx) drops below a
      configured threshold  (t [dB]):
      -  P(in) < P(Tx) - a(Tx) - t (Tx direction)
      -  P(Rx) < P(out) - a(Rx) - t (Rx direction)
      -  a(Tx) = a(Rx)


                       Figure 3: Extended LMP Model




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   Power Control Loop Use Case

     This use case is based on the access link monitoring use case as
     described above. In addition, the border NE is running a power
     control application that is capable to control the optical output
     power of the single channel tributary signal at the output port
     of the border DWDM NE (towards the external receiver Rx) and the
     optical output power of the single channel tributary signal at
     the external transmitter Tx within their known operating range.
     The time scale of this control loop is typically relatively slow
     (e.g. some 10s or minutes) because the access link attenuation
     is not expected to vary much over time (the attenuation only
     changes when re-cabling occurs).
     From a data plane perspective, this use case does not require
     additional data plane extensions. It does only require a protocol
     extension in the control plane (e.g. this LMP draft) that allows
     the power control application residing in the DWDM border NE to
     modify the optical output power of the DWDM domain-external
     transmitter Tx within the range of the currently used application
     code. Figure 5 below illustrates this use case utilizing the LMP
     protocol with extensions defined in this draft.






























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   Figure 4 Use case 2: Power Control Loop



    +----------+                       +--------------------------+
    | +------+ | P(Tx),P(Rx),Set(Pout) |  +-------+   +--------+  |
    | |      | | ====================> |  |       |   | Power  |  |
    | | LMP  | | P(in),P(out),Set(PTx) |  |  LMP  |   |Control |  |
    | |      | | <==================== |  |       |   | Loop   |  |
    | +------+ |                       |  +-------+   +--------+  |
    |     |    |                       |                          |
    | +------+ |                       |    P(in) = P(Tx) - a(Tx) |
    | |C.Loop| |                       |    ___                   |
    | +------+ |                       |    \ /  Power Monitor    |
    |     |    | P(Tx)                 |     V                    |
    | +------+ | Ss    //\\            |     |    |\              |
    | | TX  |>---|-----\\//---------------------->| \             |
    | +------+ | Access Link (AL-T)    |       .  |  |            |
    |  VOA(Tx) | attenuation a(Tx)     |       .  |  |==============>
    |          |                       |       .  |  |            |
    | External |                       |      --->| /             |
    | Optical  |                       |          |/              |
    |Transpond.|                       |    P(out)                |
    |          |                       |    ___                   |
    |          |                       |    \ /  Power Monitor    |
    |          | P(Rx)                 |     V                    |
    |  +----+  | Rs    //\\            |     |  VOA(out) |\       |
    |  | RX |<---|-----\\//---------------------<|-------| \      |
    |  +----+  | Access Link (AL-R)    |             .   |  |     |
    |          | attenuation a(Rx)     |             .   |  |<=======
    +----------+                       |        VOA(out) |  |     |
                                       |     <--<|-------| /      |
    P(Rx) = P(out) - a(Rx)             |                 |/       |
                                       |                          |
                                       |            ROADM         |
                                       +--------------------------+

     The Power Control Loops in Transponder and ROADM regulate
     the Variable Optical Attenuators (VOA) to adjust the
     proper power in base of the ROADM and Receiver
     caracteristics and the Access Link attenuation


                       Figure 4: Extended LMP Model







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4.2.  Optical Parameters Description

   The G.698.2 pre-certified network media channels are managed at the
   edges, i.e. at the transmitters (Tx) and receivers (Rx) attached to
   the S and R reference points respectively.  The set of parameters
   that could be managed are specified in G.698.2 [ITU.G698.2] section
   5.3 referring the "application code" notation

   The definitions of the optical parameters are provided below to
   increase the readability of the document, where the definition is
   ended by (G) the parameter can be retrieve with a GET, when (S) it
   can be provisioned by a SET, (G,S) can be either GET and SET.

   To support the management of these parameters, the SNMP MIB in RFC
   3591 [RFC3591] is extended with a new MIB module defined in section 6
   of this document.  This new MIB module includes the definition of new
   configuration table of the OCh Layer for the parameters at Tx (S) and
   Rx (R).

4.2.1.  Rs-Ss Configuration

   The Rs-Ss configuration table allows configuration of Central
   Frequency, Power and Application identifiers as described in
   [ITU.G698.2] and G.694.1 [ITU.G694.1]
   This parameter report the current Transceiver Output power, it can be
   either a setting and measured value (G, S).

   Central frequency (see G.694.1 Table 1):
      This parameter indicates the central frequency value that Ss and
      Rs will be set, to work (in THz), in particular Section 6/G.694.1
      (G, S).

   Single-channel application identifiers (see G.698.2):
      This parameter indicates the transceiver application identifier at
      Ss and Rs as defined in [ITU.G698.2] Chapter 5.4 - this parameter
      can be called Optical Interface Identifier OII as per [draft-
      martinelli-wson-interface-class] (G).

   Number of Single-channel application identifiers Supported
      This parameter indicates the number of Single-channel application
      codes supported by this interface (G).

   Current Laser Output power:
      This parameter report the current Transceiver Output power, see
      RFC3591.

   Current Laser Input power:




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      This parameter report the current Transceiver Input power see
      RFC3591.

   +---------------------------------------------+---------+-----------+
   | PARAMETERS                                  | Get/Set | Reference |
   +---------------------------------------------+---------+-----------+
   | Central Frequency                           |   G,S   |  G.694.1  |
   |                                             |         |    S.6    |
   | Single-channel Application Identifier       |    G    |  G.874.1  |
   | number in use                               |         |           |
   | Single-channel Application Identifier Type  |    G    |  G.874.1  |
   | in use                                      |         |           |
   | Single-channel Application Identifier in    |    G    |  G.874.1  |
   | use                                         |         |           |
   | Number of Single-channel Application        |    G    |    N.A.   |
   | Identifiers Supported                       |         |           |
   | Current Output Power                        |   G,S   |  RFC3591  |
   | Current Input Power                         |    G    |  RFC3591  |
   +---------------------------------------------+---------+-----------+

                       Table 1: Rs-Ss Configuration

4.2.2.  Table of Application Identifiers

   This table has a list of Application Identifiers supported by this
   interface at point R are defined in G.698.2.

     Application Identifier Number:
       The number that uniquely identifies the Application Identifier.

     Application Identifier Type:
      Type of application Identifier: STANDARD / PROPRIETARY in G.874.1

      Note: if the A.I. type = PROPRIETARY, the first 6 Octets of the
      Application Identifier (PrintableString) must contain the
      Hexadecimal representation of an OUI (organizationally unique
      identifier) assigned to the vendor whose implementation generated
      the Application Identifier; the remaining octets of the
      PrintableString are unspecified.

     Application Identifier:
      This is the application Identifier that is defined in G.874.1.









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4.3.  Use of ifTable

   This section specifies how the MIB II interfaces group, as defined in
   RFC 2863 [RFC2863], is used for the link ends of a black link.  Only
   the ifGeneralInformationGroup will be supported for the ifTable and
   the ifStackTable to maintain the relationship between the OCh and OPS
   layers.  The OCh and OPS layers are managed in the ifTable using
   IfEntries that correlate to the layers depicted in Figure 1.

   For example, a device with TX and/or RX will have an Optical Physical
   Section (OPS) layer, and an OCh layer.  There is a one to n
   relationship between the OPS and OCh layers.

   EDITOR NOTE: Reason for changing from OChr to OCh: Edition 3 of G.872
   removed OChr from the architecture and G.709 was subsequently updated
   to account for this architectural change.

   Figure 5 In the following figures, opticalPhysicalSection are
   abbreviated as OPS.


      _____________________
                           \
         Path Data Unit    |\
             (ODUk)        | \
      _____________________|  \ __________________
                           |   |                  |  >
        Tandem Data Unit   |   |                  |  |
             (ODUkT)       |   |    OCh  Layer    |   > n och IfEntries
      _____________________|   |                  |  |
                           |   |__________________|  >
              Optical      |  /|                  |  >
          Transport Unit   | / |                  |  |
              (OTUk)       |/  |    OPSn Layer    |   > m ops IfEntries
      _____________________/   |                  |  |
                               |__________________|  >




                   Figure 5: OTN Layers for OPS and OCh

   Each opticalChannel IfEntry is mapped to one of the m
   opticalPhysicalSection IfEntries, where m is greater than or equal to
   1.  Conversely, each opticalTransPhysicalSection port entry is mapped
   to one of the n opticalChannel IfEntries, where n is greater than or
   equal to 1.




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   The design of the Optical Interface MIB provides the option to model
   an interface either as a single bidirectional object containing both
   sink and source functions or as a pair of unidirectional objects, one
   containing sink functions and the other containing source functions.

   If the sink and source for a given protocol layer are to be modelled
   as separate objects, then there need to be two ifTable entries, one
   that corresponds to the sink and one that corresponds to the source,
   where the directionality information is provided in the configuration
   tables for that layer via the associated Directionality objects.  The
   agent is expected to maintain consistent directionality values
   between ifStackTable layers (e.g., a sink must not be stacked in a
   1:1 manner on top of a source, or vice-versa), and all protocol
   layers that are represented by a given ifTable entry are expected to
   have the same directionality.

   When separate ifTable entries are used for the source and sink
   functions of a given physical interface, association between the two
   uni-directional ifTable entries (one for the source function and the
   other for the sink functions) should be provided.  It is recommended
   that identical ifName values are used for the two ifTable entries to
   indicate such association.  An implementation shall explicitly state
   what mechanism is used to indicate the association, if ifName is not
   used.

4.3.1.  Use of ifTable for OPS Layer

    Only the ifGeneralInformationGroup needs to be supported.

       ifTable Object      Use for OTN OPS Layer
   ==================================================================


     ifIndex           The interface index.

     ifDescr           Optical Transport Network (OTN) Optical
                       Physical Section (OPS)

     ifType            opticalPhysicalSection (xxx)

   <<<Editor Note: Need new IANA registration value for xxx. >>>

     ifSpeed           Actual bandwidth of the interface in bits per
                       second.  If the bandwidth of the interface is
                       greater than the maximum value of 4,294,967,295
                       then the maximum value is reported and
                       ifHighSpeed must be used to report the
                       interface's speed.



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     ifPhysAddress     An octet string with zero length.  (There is
                       no specific address associated with the
                       interface.)

     ifAdminStatus     The desired administrative state of the
                       interface.  Supports read-only access.

     ifOperStatus      The operational state of the interface.  The
                       value lowerLayerDown(7) is not used, since
                       there is no lower layer interface.  This object
                       is set to notPresent(6) if a component is
                       missing, otherwise it is set to down(2) if
                       either of the objects optIfOPSnCurrentStatus
                       indicates that any defect is present.

     ifLastChange      The value of sysUpTime at the last change in
                       ifOperStatus.

     ifName            Enterprise-specific convention (e.g., TL-1 AID)
                       to identify the physical or data entity
                       associated with this interface or an
                       OCTET STRING of zero length.  The
                       enterprise-specific convention is intended to
                       provide the means to reference one or more
                       enterprise-specific tables.

     ifLinkUpDownTrapEnable  Default value is enabled(1).  Supports
                             read-only access.

     ifHighSpeed       Actual bandwidth of the interface in Mega-bits
                       per second.  A value of n represents a range of
                       'n-0.5' to 'n+0.499999'.

     ifConnectorPresent Set to true(1).

     ifAlias           The (non-volatile) alias name for this interface
                       as assigned by the network manager.


4.3.2.  Use of ifTable for OCh Layer

   Use of ifTable for OCh Layer See RFC 3591 [RFC3591] section 2.4

4.3.3.  Use of ifStackTable

   Use of the ifStackTable and ifInvStackTable to associate the
   opticalPhysicalSection and opticalChannel interface entries is best
   illustrated by the example shown in Figure 3.  The example assumes an



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   ops interface with ifIndex i that carries two multiplexed OCh
   interfaces with ifIndex values of j and k, respectively.  The example
   shows that j and k are stacked above (i.e., multiplexed into) i.
   Furthermore, it shows that there is no layer lower than i and no
   layer higher than j and/or k.

   Figure 6


                         HigherLayer   LowerLayer
                       --------------------------
                            0             j
                            0             k
                            j             i
                            k             i
                            i             0


               Figure 6: Use of ifStackTable for an OTN port

   For the inverse stack table, it provides the same information as the
   interface stack table, with the order of the Higher and Lower layer
   interfaces reversed.

5.  Structure of the MIB Module

   EDITOR NOTE:text will be provided based on the MIB module in
   Section 6

6.  Object Definitions

   EDITOR NOTE: Once the scope in Section 1 and the parameters in
   Section 4 are finalized, a MIB module will be defined.  It could be
   an extension to the OPT-IF-MIB module of RFC 3591. >>>

















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   OPT-IF-698-MIB DEFINITIONS ::= BEGIN

      IMPORTS
              MODULE-IDENTITY,
              OBJECT-TYPE,
              Gauge32,
              Integer32,
              Unsigned32,
              Counter64,
              transmission,
              NOTIFICATION-TYPE
                      FROM SNMPv2-SMI
              TEXTUAL-CONVENTION,
              RowPointer,
              RowStatus,
              TruthValue,
              DisplayString,
              DateAndTime
                      FROM SNMPv2-TC
              SnmpAdminString
                      FROM SNMP-FRAMEWORK-MIB
              MODULE-COMPLIANCE, OBJECT-GROUP
                      FROM SNMPv2-CONF
              ifIndex
                      FROM IF-MIB
              optIfMibModule
                     FROM OPT-IF-MIB;


   --  This is the MIB module for the optical parameters -
   --  Application codes associated with the black link end points.




   optIfXcvrMibModule MODULE-IDENTITY
       LAST-UPDATED "201401270000Z"
       ORGANIZATION "IETF Ops/Camp MIB Working Group"
       CONTACT-INFO
          "WG charter:
             http://www.ietf.org/html.charters/

           Mailing Lists:
           Editor: Gabriele Galimberti
           Email:  ggalimbe@cisco.com"
       DESCRIPTION
          "The MIB module to describe Black Link tranceiver
           characteristics to rfc3591.



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           Copyright (C) The Internet Society (2014).  This version
           of this MIB module is an extension to rfc3591;  see the RFC
           itself for full legal notices."
       REVISION  "201305050000Z"
       DESCRIPTION
          "Draft version 1.0"
       REVISION  "201305050000Z"
       DESCRIPTION
          "Draft version 2.0"
       REVISION  "201302270000Z"
       DESCRIPTION
          "Draft version 3.0"
       REVISION  "201307020000Z"
       DESCRIPTION
          "Draft version 4.0
           Changed the draft to include only the G.698 parameters."
       REVISION  "201311020000Z"
       DESCRIPTION
          "Draft version 5.0
           Mib has a table of application code/vendor
           transcievercode G.698"
       REVISION  "201401270000Z"
       DESCRIPTION
          "Draft version 6.0"
       REVISION  "201407220000Z"
       DESCRIPTION
          "Draft version 8.0
          Removed Vendor transceiver code"
       REVISION  "201502220000Z"
       DESCRIPTION
          "Draft version 11.0
           Added reference to OUI in the first 6 Octets of a
           proprietary Application code
           Added a Length field for the Application code
           Changed some names"
       REVISION  "201507060000Z"
       DESCRIPTION
          "Draft version 12.0
          Added Power Measurement Use Cases
          and ITU description" "
          ::= { optIfMibModule 4 }


       ::= { optIfMibModule 4 }

   -- Addition to the RFC 3591 objects
   optIfOChSsRsGroup   OBJECT IDENTIFIER  ::= { optIfXcvrMibModule 1 }




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   -- OCh Ss/Rs config table
   -- The application code/vendor tranceiver class for the Black Link
   -- Ss-Rs will be added to the OchConfigTable

   optIfOChSsRsConfigTable OBJECT-TYPE
       SYNTAX  SEQUENCE OF OptIfOChSsRsConfigEntry
       MAX-ACCESS  not-accessible
       STATUS  current
       DESCRIPTION
           "A table of Och General config extension parameters"
       ::= {  optIfOChSsRsGroup 1 }

   optIfOChSsRsConfigEntry OBJECT-TYPE
       SYNTAX      OptIfOChSsRsConfigEntry
       MAX-ACCESS  not-accessible
       STATUS  current
       DESCRIPTION
           "A conceptual row that contains G.698 parameters for an
           interface."
       INDEX   { ifIndex }
       ::= { optIfOChSsRsConfigTable 1 }

   OptIfOChSsRsConfigEntry ::=
       SEQUENCE {
           optIfOChCentralFrequency                     Unsigned32,
           optIfOChCfgApplicationIdentifierNumber       Unsigned32,
           optIfOChCfgApplicationIdentifierType         Unsigned32,
           optIfOChCfgApplicationIdentifierLength       Unsigned32,
           optIfOChCfgApplicationIdentifier             DisplayString,
           optIfOChNumberApplicationCodesSupported      Unsigned32
      }

   optIfOChCentralFrequency  OBJECT-TYPE
       SYNTAX  Unsigned32
       MAX-ACCESS  read-write
       UNITS "THz"
       STATUS  current
       DESCRIPTION
           " This parameter indicates the frequency of this interface.
           "
       ::= { optIfOChSsRsConfigEntry  1 }

   optIfOChCfgApplicationIdentifierNumber  OBJECT-TYPE
       SYNTAX Unsigned32
       MAX-ACCESS  read-write
       STATUS  current
       DESCRIPTION
           "This parameter uniquely indicates the transceiver



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            application code at Ss and Rs as defined in [ITU.G874.1],
            that is used by this interface.
            The optIfOChSrcApplicationIdentifierTable has all the
            application codes supported by this interface. "
       ::= { optIfOChSsRsConfigEntry  2 }

   optIfOChCfgApplicationIdentifierType  OBJECT-TYPE
       SYNTAX Unsigned32
       MAX-ACCESS  read-write
       STATUS  current
       DESCRIPTION
           "This parameter indicates the transceiver type of
            application code at Ss and Rs as defined in [ITU.G874.1],
            that is used by this interface.
            The optIfOChSrcApplicationIdentifierTable has all the
            application codes supported by this interface
            Standard = 0, PROPRIETARY = 1. "
       ::= { optIfOChSsRsConfigEntry  3 }

   optIfOChCfgApplicationIdentifierLenght  OBJECT-TYPE
       SYNTAX Unsigned32
       MAX-ACCESS  read-write
       STATUS  current
       DESCRIPTION
           "This parameter indicates the number of octets in the
            Application Identifier.
            "
       ::= { optIfOChSsRsConfigEntry  4 }


   optIfOChCfgApplicationIdentifier  OBJECT-TYPE
       SYNTAX DisplayString
       MAX-ACCESS  read-write
       STATUS  current
       DESCRIPTION
           "This parameter indicates the transceiver application code
            at Ss and Rs as defined in [ITU.G698.2] Chapter 5.3, that
            is used by this interface. The
            optIfOChSrcApplicationCodeTable has all the application
            codes supported by this interface.
            If the optIfOChCfgApplicationIdentifierType is 1
            (Proprietary), then the first 6 octets of the printable
            string will be the OUI (organizationally unique identifier)
            assigned to the vendor whose implementation generated the
            Application Identifier."
       ::= { optIfOChSsRsConfigEntry  5 }

   optIfOChNumberApplicationIdentifiersSupported  OBJECT-TYPE



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       SYNTAX Unsigned32
       MAX-ACCESS  read-only
       STATUS  current
       DESCRIPTION
          " Number of Application codes supported by this interface."
       ::= { optIfOChSsRsConfigEntry  6 }

   -- Table of Application codes supported by the interface
   --  OptIfOChSrcApplicationCodeEntry

   optIfOChSrcApplicationIdentifierTable  OBJECT-TYPE
       SYNTAX  SEQUENCE OF OptIfOChSrcApplicationIdentifierEntry
       MAX-ACCESS  not-accessible
       STATUS  current
       DESCRIPTION
           "A Table of Application codes supported by this interface."
       ::= { optIfOChSsRsGroup 2 }

   optIfOChSrcApplicationIdentifierEntry OBJECT-TYPE
       SYNTAX      OptIfOChSrcApplicationIdentifierEntry
       MAX-ACCESS  not-accessible
       STATUS  current
       DESCRIPTION
           "A conceptual row that contains the Application code for
            this interface."
       INDEX  { ifIndex, optIfOChApplicationIdentiferNumber  }
       ::= { optIfOChSrcApplicationIdentifierTable 1 }

   OptIfOChSrcApplicationIdentifierEntry ::=
       SEQUENCE {
           optIfOChApplicationIdentiferNumber            Integer32,
           optIfOChApplicationIdentiferType              Integer32,
           optIfOChApplicationIdentiferLength            Integer32,
           optIfOChApplicationIdentifier                 DisplayString
        }


   optIfOChApplicationIdentiferNumber  OBJECT-TYPE
       SYNTAX  Integer32 (1..255)
       MAX-ACCESS  not-accessible
       STATUS  current
       DESCRIPTION
         " The number/identifier of the application code supported at
           this interface. The interface can support more than one
           application codes.
         "
       ::= { optIfOChSrcApplicationIdentifierEntry  1}




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   optIfOChApplicationIdentiferType  OBJECT-TYPE
       SYNTAX  Integer32 (1..255)
       MAX-ACCESS  read-only
       STATUS  current
       DESCRIPTION
         " The type of identifier of the application code supported at
           this interface. The interface can support more than one
           application codes.
           Standard = 0, PROPRIETARY = 1
         "
       ::= { optIfOChSrcApplicationIdentifierEntry  2}


   optIfOChApplicationIdentiferLength  OBJECT-TYPE
       SYNTAX  Integer32 (1..255)
       MAX-ACCESS  read-only
       STATUS  current
       DESCRIPTION
         " This parameter indicates the number of octets in the
           Application Identifier.
         "
       ::= { optIfOChSrcApplicationIdentifierEntry  3}

   optIfOChApplicationIdentifier  OBJECT-TYPE
       SYNTAX DisplayString
       MAX-ACCESS  read-only
       STATUS  current
       DESCRIPTION
           " The application code supported by this interface DWDM
             link.
             If the optIfOChApplicationIdentiferType is 1 (Proprietary),
             then the first 6 octets of the printable string will be
             the OUI (organizationally unique identifier) assigned to
             the vendor whose implementation generated the Application
             Identifier."
       ::= { optIfOChSrcApplicationIdentifierEntry  4}




   -- Notifications

   -- Central Frequency Change Notification
   optIfOChCentralFrequencyChange NOTIFICATION-TYPE
       OBJECTS { optIfOChCentralFrequency }
       STATUS  current
       DESCRIPTION
           "Notification of a change in the central frequency."



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       ::= { optIfXcvrMibModule 1 }

   END


7.  Relationship to Other MIB Modules

7.1.  Relationship to the [TEMPLATE TODO] MIB

7.2.  MIB modules required for IMPORTS

8.  Definitions

   [TEMPLATE TODO]: put your valid MIB module here.
   A list of tools that can help automate the process of
   checking MIB definitions can be found at
   http://www.ops.ietf.org/mib-review-tools.html

9.  Security Considerations

   There are a number of management objects defined in this MIB module
   with a MAX-ACCESS clause of read-write and/or read-create.  Such
   objects may be considered sensitive or vulnerable in some network
   environments.  The support for SET operations in a non-secure
   environment without proper protection can have a negative effect on
   network operations.  These are the tables and objects and their
   sensitivity/vulnerability:

   o

   Some of the readable objects in this MIB module (i.e., objects with a
   MAX-ACCESS other than not-accessible) may be considered sensitive or
   vulnerable in some network environments.  It is thus important to
   control even GET and/or NOTIFY access to these objects and possibly
   to even encrypt the values of these objects when sending them over
   the network via SNMP.

   SNMP versions prior to SNMPv3 did not include adequate security.
   Even if the network itself is secure (for example by using IPsec),
   even then, there is no control as to who on the secure network is
   allowed to access and GET/SET (read/change/create/delete) the objects
   in this MIB module.

   It is RECOMMENDED that implementers consider the security features as
   provided by the SNMPv3 framework (see [RFC3410], section 8),
   including full support for the SNMPv3 cryptographic mechanisms (for
   authentication and privacy).




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   Further, deployment of SNMP versions prior to SNMPv3 is NOT
   RECOMMENDED.  Instead, it is RECOMMENDED to deploy SNMPv3 and to
   enable cryptographic security.  It is then a customer/operator
   responsibility to ensure that the SNMP entity giving access to an
   instance of this MIB module is properly configured to give access to
   the objects only to those principals (users) that have legitimate
   rights to indeed GET or SET (change/create/delete) them.

10.  IANA Considerations

   Option #1:

        The MIB module in this document uses the following IANA-assigned
        OBJECT IDENTIFIER values recorded in the SMI Numbers registry:

        Descriptor        OBJECT IDENTIFIER value
        ----------        -----------------------

        sampleMIB  { mib-2 XXX }

   Option #2:

   Editor's Note (to be removed prior to publication): the IANA is
   requested to assign a value for "XXX" under the 'mib-2' subtree and
   to record the assignment in the SMI Numbers registry.  When the
   assignment has been made, the RFC Editor is asked to replace "XXX"
   (here and in the MIB module) with the assigned value and to remove
   this note.

   Note well: prior to official assignment by the IANA, an internet
   draft MUST use place holders (such as "XXX" above) rather than actual
   numbers.  See RFC4181 Section 4.5 for an example of how this is done
   in an internet draft MIB module.

   Option #3:

   This memo includes no request to IANA.

11.  Contributors












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               Arnold Mattheus
                 Deutsche Telekom
                 Darmstadt
                 Germany
                 email a.mattheus@telekom.de

               Manuel Paul
                 Deutsche Telekom
                 Berlin
                 Germany
                 email Manuel.Paul@telekom.de

               Frank Luennemann
                 Deutsche Telekom
                 Munster
                 Germany
                 email Frank.Luennemann@telekom.de

               Scott Mansfield
                 Ericsson Inc.
                 email scott.mansfield@ericsson.com

               Najam Saquib
                 Cisco
                 Ludwig-Erhard-Strasse 3
                 ESCHBORN, HESSEN 65760
                 GERMANY
                 email nasaquib@cisco.com

               Walid Wakim
                 Cisco
                 9501 Technology Blvd
                 ROSEMONT, ILLINOIS 60018
                 UNITED STATES
                 email wwakim@cisco.com

               Ori Gerstel
                 Sedona System
                 ISRAEL
                 email orig@sedonasys.com

12.  References

12.1.  Normative References

   [RFC2863]  McCloghrie, K. and F. Kastenholz, "The Interfaces Group
              MIB", RFC 2863, June 2000.




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   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2578]  McCloghrie, K., Ed., Perkins, D., Ed., and J.
              Schoenwaelder, Ed., "Structure of Management Information
              Version 2 (SMIv2)", STD 58, RFC 2578, April 1999.

   [RFC2579]  McCloghrie, K., Ed., Perkins, D., Ed., and J.
              Schoenwaelder, Ed., "Textual Conventions for SMIv2", STD
              58, RFC 2579, April 1999.

   [RFC2580]  McCloghrie, K., Perkins, D., and J. Schoenwaelder,
              "Conformance Statements for SMIv2", STD 58, RFC 2580,
              April 1999.

   [RFC3591]  Lam, H-K., Stewart, M., and A. Huynh, "Definitions of
              Managed Objects for the Optical Interface Type", RFC 3591,
              September 2003.

   [RFC6205]  Otani, T. and D. Li, "Generalized Labels for Lambda-
              Switch-Capable (LSC) Label Switching Routers", RFC 6205,
              March 2011.

   [ITU.G698.2]
              International Telecommunications Union, "Amplified
              multichannel dense wavelength division multiplexing
              applications with single channel optical interfaces",
              ITU-T Recommendation G.698.2, November 2009.

   [ITU.G709]
              International Telecommunications Union, "Interface for the
              Optical Transport Network (OTN)", ITU-T Recommendation
              G.709, February 2012.

   [ITU.G872]
              International Telecommunications Union, "Architecture of
              optical transport networks", ITU-T Recommendation G.872
              and Amd.1, October 2012.

   [ITU.G798]
              International Telecommunications Union, "Characteristics
              of optical transport network hierarchy equipment
              functional blocks", ITU-T Recommendation G.798 and Amd.1,
              December 2012.







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   [ITU.G874]
              International Telecommunications Union, "Management
              aspects of optical transport network elements", ITU-T
              Recommendation G.874, August 2013.

   [ITU.G874.1]
              International Telecommunications Union, "Optical transport
              network (OTN): Protocol-neutral management information
              model for the network element view", ITU-T Recommendation
              G.874.1, October 2012.

   [ITU.G959.1]
              International Telecommunications Union, "Optical transport
              network physical layer interfaces", ITU-T Recommendation
              G.959.1, November 2009.

   [ITU.G826]
              International Telecommunications Union, "End-to-end error
              performance parameters and objectives for international,
              constant bit-rate digital paths and connections", ITU-T
              Recommendation G.826, November 2009.

   [ITU.G8201]
              International Telecommunications Union, "Error performance
              parameters and objectives for multi-operator international
              paths within the Optical Transport Network (OTN)", ITU-T
              Recommendation G.8201, April 2011.

   [ITU.G694.1]
              International Telecommunications Union, "Spectral grids
              for WDM applications: DWDM frequency grid", ITU-T
              Recommendation G.694.1, February 2012.

   [ITU.G7710]
              International Telecommunications Union, "Common equipment
              management function requirements", ITU-T Recommendation
              G.7710, February 2012.

12.2.  Informative References

   [RFC3410]  Case, J., Mundy, R., Partain, D., and B. Stewart,
              "Introduction and Applicability Statements for Internet-
              Standard Management Framework", RFC 3410, December 2002.

   [RFC2629]  Rose, M., "Writing I-Ds and RFCs using XML", RFC 2629,
              June 1999.





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   [RFC4181]  Heard, C., "Guidelines for Authors and Reviewers of MIB
              Documents", BCP 111, RFC 4181, September 2005.

   [I-D.kunze-g-698-2-management-control-framework]
              Kunze, R., "A framework for Management and Control of
              optical interfaces supporting G.698.2", draft-kunze-
              g-698-2-management-control-framework-00 (work in
              progress), July 2011.

   [RFC4054]  Strand, J. and A. Chiu, "Impairments and Other Constraints
              on Optical Layer Routing", RFC 4054, May 2005.

Appendix A.  Change Log

   This optional section should be removed before the internet draft is
   submitted to the IESG for publication as an RFC.

   Note to RFC Editor: please remove this appendix before publication as
   an RFC.

Appendix B.  Open Issues

   Note to RFC Editor: please remove this appendix before publication as
   an RFC.

Authors' Addresses

   Gabriele Galimberti (editor)
   Cisco
   Via Santa Maria Molgora, 48 c
   20871 - Vimercate
   Italy

   Phone: +390392091462
   Email: ggalimbe@cisco.com


   Ruediger Kunze (editor)
   Deutsche Telekom
   Dddd, xx
   Berlin
   Germany

   Phone: +49xxxxxxxxxx
   Email: RKunze@telekom.de






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   Hing-Kam Lam (editor)
   Alcatel-Lucent
   600-700 Mountain Avenue, Murray Hill
   New Jersey, 07974
   USA

   Phone: +17323313476
   Email: kam.lam@alcatel-lucent.com


   Dharini Hiremagalur (editor)
   Juniper
   1194 N Mathilda Avenue
   Sunnyvale - 94089 California
   USA

   Phone: +1408
   Email: dharinih@juniper.net


   Luyuan Fang (editor)
   Microsoft
   5600 148th Ave NE
   Redmond, WA 98502
   USA

   Email: lufang@microsoft.com


   Gary Ratterree (editor)
   Microsoft
   5600 148th Ave NE
   Redmond, WA 98502
   USA

   Email: gratt@microsoft.com















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