rfc7461









Internet Engineering Task Force (IETF)                        J. Parello
Request for Comments: 7461                                     B. Claise
Category: Standards Track                                M. Chandramouli
ISSN: 2070-1721                                      Cisco Systems, Inc.
                                                              March 2015


                       Energy Object Context MIB

Abstract

   This document defines a subset of a Management Information Base (MIB)
   for energy management of devices.  The module addresses device
   identification, context information, and the energy relationships
   between devices.

Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc7461.

Copyright Notice

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

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.







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Table of Contents

   1. Introduction ....................................................2
      1.1. Energy Management Document Overview ........................2
      1.2. Conventions Used in This Document ..........................3
   2. The Internet-Standard Management Framework ......................3
   3. Terminology .....................................................4
   4. Architecture Concepts Applied to the MIB Module .................4
      4.1. Energy Object Identification ...............................8
      4.2. Energy Object Context ......................................9
      4.3. Links to Other Identifiers ................................10
      4.4. Energy Object Relationships ...............................11
      4.5. Energy Object Identity Persistence ........................12
   5. MIB Definitions ................................................12
   6. Security Considerations ........................................27
   7. IANA Considerations ............................................28
   8. References .....................................................29
      8.1. Normative References ......................................29
      8.2. Informative References ....................................30
   Acknowledgments ...................................................31
   Authors' Addresses ................................................32

1.  Introduction

   The Energy Management (EMAN) standards provide a specification for
   Energy Management.  This document defines a subset of a Management
   Information Base (MIB) for use with network management protocols for
   Energy monitoring of network devices and devices attached to the
   network and possibly extending to devices in the industrial
   automation setting with a network interface.

   The focus of the MIB module specified in this document is on the
   identification of Energy Objects and reporting the context and
   relationships of Energy Objects as defined in [RFC7326].  The module
   addresses Energy Object identification, Energy Object context, and
   Energy Object relationships.

1.1.  Energy Management Document Overview

   This document specifies the Energy Object Context (ENERGY-OBJECT-
   CONTEXT-MIB) and IANA Energy Relationship (IANA-ENERGY-RELATION-MIB)
   modules.  The Energy Object Context MIB module specifies MIB objects
   for identification of Energy Objects, and reporting context and
   relationship of an Energy Object.  The IANA Energy Relationship MIB
   module specifies the first version of the IANA-maintained definitions
   of relationships between Energy Objects.





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   Firstly, to illustrate the importance of energy monitoring in
   networks and, secondly, to list some of the important areas to be
   addressed by the Energy Management Framework [RFC7326], several use
   cases and network scenarios are presented in the EMAN applicability
   statement document [EMAN-AS].  In addition, for each scenario, the
   target devices for energy management, and how those devices powered
   and metered are also presented.  To address the network scenarios,
   requirements for power and energy monitoring for networking devices
   are specified in [RFC6988].  Based on the requirements in [RFC6988],
   [RFC7326] presents a solution approach.

   Accordingly, the scope of the MIB modules in this document is in
   accordance to the requirements specified in [RFC6988] and the
   concepts from [RFC7326].

   This document is based on the Energy Management Framework [RFC7326]
   and meets the requirements on identification of Energy Objects and
   their context and relationships as specified in the Energy Management
   requirements document [RFC6988].

   A second MIB module meeting the EMAN requirements [RFC6988] the
   Monitoring and Control MIB for Power and Energy [RFC7460], monitors
   the Energy Objects for Power States, for the Power and Energy
   consumption.  Power State monitoring includes: retrieving Power
   States, Power State properties, current Power State, Power State
   transitions, and Power State statistics.  In addition, this MIB
   module provides the Power Characteristics properties of the Power and
   Energy, along with optional characteristics.

   The applicability statement document [EMAN-AS] provides the list of
   use cases, describes the common aspects between existing Energy
   standards and the EMAN standard, and shows how the EMAN framework
   relates to other frameworks.

1.2.  Conventions Used in This Document

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in
   [RFC2119].

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].





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   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 MIB
   modules that are compliant with SMIv2, which is described in STD 58,
   RFC 2578 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC 2580
   [RFC2580].

3.  Terminology

   Please refer to [RFC7326] for the definitions of the following
   terminology used in this document.

      Energy Management
      Energy Management System (EnMS)
      Energy Monitoring
      Energy Control
      electrical equipment
      non-electrical equipment (mechanical equipment)
      device
      component
      power inlet
      power outlet
      energy
      power
      demand
      provide energy
      receive energy
      meter (energy meter)
      battery
      Power Interface
      Nameplate Power
      Power Attributes
      Power Quality
      Power State
      Power State Set

4.  Architecture Concepts Applied to the MIB Module

   This section describes the basic concepts specified in the Energy
   Management Framework [RFC7326], with specific information related to
   the MIB modules specified in this document.








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   The Energy Object Context (ENERGY-OBJECT-CONTEXT-MIB) MIB module in
   this document specifies MIB objects for the identification of Energy
   Objects and reporting context and relationship of an Energy Object.
   The managed objects are contained in two tables: eoTable and
   eoRelationTable.

   The first table, eoTable, focuses on the link to the other MIB
   modules, on identification, and on the context of the Energy Object.
   The second table, eoRelationTable, specifies the relationships
   between Energy Objects.  This is a simplified representation of the
   relationship between Energy Objects.

   A "smidump-style" tree presentation of the MIB modules contained in
   the document is presented.  The meaning of the three symbols in is a
   compressed representation of the object's MAX-ACCESS clause, which
   may have the following values:

       "not-accessible"->"---"
       "accessible-for-notify"->"--n"
       "read-only"->"r-n"
       "read-write"->"rwn"

   +- eoTable(1)
      |
      +- eoEntry(1) [entPhysicalIndex]
         |
         +-- r-n PethPsePortIndexOrZero       eoEthPortIndex(1)
         +-- r-n PethPsePortGroupIndexOrZero  eoEthPortGrpIndex(2)
         +-- r-n LldpPortNumberOrZero         eoLldpPortNumber(3)
         +-- rwn MacAddress                   eoMgmtMacAddress(4)
         +-- r-n InetAddressType              eoMgmtAddressType(5)
         +-- r-n InetAddress                  eoMgmtAddress(6)
         +-- r-n OCTET STRING                 eoMgmtDNSName(7)
         +-- rwn SnmpAdminString              eoDomainName(8)
         +-- rwn SnmpAdminString              eoRoleDescription(9)
         +-- rwn EnergyObjectKeywordList      eoKeywords(10)
         +-- rwn Integer32                    eoImportance(11)
         +-- r-n INTEGER                      eoPowerCategory(12)
         +-- rwn SnmpAdminString              eoAlternateKey(13)
         +-- r-n INTEGER                      eoPowerInterfaceType(14)











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   +- eoRelationTable(2)
      |
      +- eoRelationEntry(1) [entPhysicalIndex, eoRelationIndex]
         |
         +-- --n Integer32                   eoRelationIndex(1)
         +-- rwn UUIDorZero                  eoRelationID(2)
         +-- rwn IANAEnergyRelationship      eoRelationship(3)
         +-- rwn RowStatus                   eoRelationStatus(4)
         +-- rwn StorageType                 eoRelationStorageType(5)

   The following Unified Modeling Language (UML) diagram illustrates the
   relationship of the MIB objects in the eoTable, eoRelationTable, and
   ENTITY-MIB.  The MIB objects describe the identity, context, and
   relationship of an Energy Object.  The UML diagram, furthermore,
   contains objects from the ENTITY-MIB [RFC6933].




































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          +--------------------------+
          |  EO Context Information  |
          | ------------------------ |
          |  eoRoleDescription       |
          |  eoKeywords              |
          |  eoImportance            |
          |  eoPowerCategory         |
          |  eoPowerInterfaceType    |
          |  eoDomainName            |
          +--------------------------+
                 ^
                 |
              +------------------------------+
        |---  |  EO Identification           |
        |     | ---------------------------- |
        |     | entPhysicalIndex (*)         |
        |     | entPhysicalName (*)          |
        |     | entPhysicalUUID (*)          |
        |     | entPhysicalClass (*)         |
        |     --------------------------------
        |     +------------------------------+
        |---> | Link to other identifiers    |
        |     |------------------------------|
        |     | eoEthPortIndex (**)          |
        |     | eoEthPortGrpIndex (**)       |
        |     | eoLldpPortNumber (***)       |
        |     |                              |
        |     | eoMgmtMacAddress (optional)  |
        |     | eoMgmtAddressType (optional) |
        |     | eoMgmtAddress (optional)     |
        |     | eoMgmtDNSName (optional)     |
        |     | eoAlternateKey               |
        |     +------------------------------+
        |     +------------------------------+
        |---> |  EO Relationship             |
              | ---------------------------- |
              |  eoRelationIndex             |
              |  eoRelationID                |
              |  eoRelationship              |
              |  eoRelationStatus            |
              |  eoRelationStorageType       |
              +------------------------------+

    (*)   Compliance with entity4CRCompliance ENTITY-MIB [RFC6933]
    (**)  Link with the Power over Ethernet MIB [RFC3621]
    (***) Link with LLDP MIBs [LLDP-MIB] [LLDP-MED-MIB]

                    Figure 1: MIB Objects Grouping



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   As displayed in Figure 1, the MIB objects can be classified in
   different logical grouping of MIB objects.

   1) The Energy Object Identification.  See Section 5.1 "Energy Object
      Identification".  Devices and their sub-components are
      characterized by the power-related attributes of a physical entity
      present in the ENTITY-MIB [RFC6933].

   2) The Context Information.  See Section 4.1 "Energy Object Context".

   3) The links to other MIB modules.  See Section 4.3 "Links to Other
      Identifiers".

   4) The Energy Object Relationships specific information.  See Section
      4.4 "Energy Object Relationships".

   5) The Energy Object Identity Persistence.  See Section 4.5 "Energy
      Object Identity Persistence".

4.1.  Energy Object Identification

   Refer to the "Identification" section in [RFC7326] for background
   information about Energy Objects.

   Every Energy Object MUST implement the unique index,
   entPhysicalIndex, entPhysicalName, entPhysicalClass, and
   entPhysicalUUID from the ENTITY-MIB [RFC6933].  Module Compliance
   with respect to entity4CRCompliance of ENTITY-MIB MUST be supported,
   which requires a limited number of objects supported
   (entPhysicalIndex, entPhysicalName, entPhysicalClass, and
   entPhysicalUUID).  entPhysicalIndex is used as index for the Energy
   Object in the ENERGY-OBJECT-CONTEXT-MIB module.  Every Energy Object
   MUST have a printable name assigned to it.  Energy Objects MUST
   implement the entPhysicalName object specified in the ENTITY-MIB
   [RFC6933], which must contain the Energy Object name.

   For the ENERGY-OBJECT-CONTEXT-MIB compliance, every Energy Object
   instance MUST implement the entPhysicalUUID from the ENTITY-MIB
   [RFC6933].

   As displayed in [RFC4122], the following is an example of the string
   representation of a Universally Unique Identifier (UUID) as a URN:
   urn:uuid:f81d4fae-7dec-11d0-a765-00a0c91e6bf6.

   For example, to understand the relationship between Energy Object
   Components and Energy Objects, the ENTITY-MIB physical containment
   tree [RFC6933] MUST be implemented.




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   A second example deals with one of the ENTITY-MIB extensions: if the
   Energy Object temperature is required, the managed objects from the
   ENTITY-SENSOR-MIB [RFC3433] should be supported.

   Each Energy Object MUST belong to a single Energy Management Domain
   or in other words, an Energy Object cannot belong to more than one
   Energy Management Domain.  Refer to the "Context: Domain" section in
   [RFC7326] for background information.  The eoDomainName, which is an
   element of the eoTable, is a read-write MIB object.  The Energy
   Management Domain should map 1:1 with a metered or sub-metered
   portion of the network.  The Energy Management Domain MUST be
   configured on the Energy Object.  The Energy Object MAY inherit some
   of the domain parameters (possibly domain name, some of the context
   information such as role or keywords, importance) from the Energy
   Object or the Energy Management Domain MAY be configured directly in
   an Energy Object.

   When an Energy Object acts as a Power Aggregator, the Energy Objects
   for which Power should be aggregated MUST be members of the same
   Energy Management Domain, specified by the eoDomainName MIB Object.

4.2.  Energy Object Context

   Refer to the "Context: Domain" section in [RFC7326] for background
   information.

   An Energy Object must provide a value for eoImportance in the range
   of 1-100 to help differentiate the use or relative value of the
   device.  The importance range is from 1 (least important) to 100
   (most important).  The default importance value is 1.

   An Energy Object can provide a set of eoKeywords.  These keywords are
   a list of tags that can be used for grouping and summary reporting
   within or between Energy Management Domains.

   An Energy Object can have Power Interfaces and those interfaces can
   be classified as Power Inlet, Power Outlet, or both.

   An Energy Object can be classified based on the physical properties
   of the Energy Object.  That Energy Object can be classified as
   consuming power or supplying power to other devices or that Energy
   Object can perform both of those functions and finally, an Energy
   Object can be a passive meter.

   Additionally, an Energy Object can provide an eoRoleDescription
   string that indicates the purpose the Energy Object serves in the
   network.




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4.3.   Links to Other Identifiers

   While the entPhysicalIndex is the primary index for all MIB objects
   in the ENERGY-OBJECT-CONTEXT-MIB module, the Energy Management
   Systems (EnMS) must be able to make the link with the identifier(s)
   in other supported MIB modules.

   If the Energy Object is a Power over Ethernet (PoE) port, and if the
   Power over Ethernet MIB [RFC3621] is supported by the SNMP agent
   managing the Energy Object, then the Energy Objects eoethPortIndex
   and eoethPortGrpIndex MUST contain the corresponding values of
   pethPsePortIndex and pethPsePortGroupIndex [RFC3621].

   If the LLDP-MED MIB [LLDP-MIB] is supported by the Energy Object SNMP
   agent, then the Energy Object eoLldpPortNumber MUST contain the
   corresponding lldpLocPortNum from the LLDP MIB.

   The intent behind the links to the other MIB module identifier(s) is
   to correlate the instances in the different MIB modules.  This will
   allow the ENERGY-OBJECT-CONTEXT-MIB module to reference other MIB
   modules in cases where the Power over Ethernet and the LLDP MIB
   modules are supported by the SNMP agent.  Some use cases may not
   implement either of these two MIB modules for the Energy Objects.
   However, in situations where either of these two MIB modules are
   implemented, the EnMS must be able to correlate the instances in the
   different MIB modules.

   The eoAlternateKey object specifies an alternate key string that can
   be used to identify the Energy Object.  Since an EnMS may need to
   correlate objects across management systems, this alternate key is
   provided to facilitate such a link.  This optional value is intended
   as a foreign key or alternate identifier for a manufacturer or EnMS
   to use to correlate the unique Energy Object Id in other systems or
   namespaces.  If an alternate key is not available or is not
   applicable, then the value is the zero-length string.

   An Energy Object can have additional MIB objects that can be used for
   easier identification by the EnMS.  The optional objects
   eoMgmtMacAddress, eoMgmtAddressType, and eoMgmtDNSName can be used to
   help identify the relationship between the Energy Objects and other
   NMS objects.  These objects can be used as an alternate key to help
   link the Energy Object with other keyed information that may be
   stored within the EnMS(s).  For the optional objects that may not be
   included in some vendor implementations, the expected behavior when
   those objects are polled is a response noSuchInstance.






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4.4.   Energy Object Relationships

   Refer to the "Relationships" section in [RFC7326] for the definition
   and background information.  In order to link two Energy Objects, a
   separate table (eoRelationTable) has been introduced in this MIB
   module.

   Each Energy Object can have one or more Energy Object relationships
   with other Energy Objects.  The relationship between Energy Objects
   is specified in eoRelationTable.  The relationship between the Energy
   Objects is specified with the entPhysicalIndex of the Energy Object
   and the UUID of the remote Energy Object.  The UUID MUST comply to
   the RFC 4122 specifications.  It is important to note that it is
   possible that an Energy Object may not have an Energy Object
   relationship with other Energy Objects.

   The following relationships between Energy Objects have been
   considered in the eoRelationTable.

               Metering Relationship     -> meteredBy / metering

               Power Source Relationship -> poweredBy / powering

               Aggregation Relationship  -> aggregatedBy / aggregating

   Energy Object B has a "meteredBy" relationship with Energy Object A,
   if the energy consumption of Energy Object B is measured by Energy
   Object A.  Equivalently, it is possible to indicate that Energy
   Object A has a "metering" relationship with Energy Object B.

   Energy Object B has a "poweredBy" relationship with Energy Object A,
   if the power source of Energy Object B is Energy Object A.
   Equivalently, it is possible to indicate that Energy Object A has a
   "powering" relationship with Energy Object B.

   Energy Object B has "aggregatedBy" relationship with Energy Object A,
   if Energy Object A is an aggregation point for energy usage of Energy
   Object B.  Equivalently, it is possible to indicate that Energy
   Object A has "aggregating" relationship with Energy Object B.

   The IANA-ENERGY-RELATION-MIB module in Section 5 below specifies the
   first version of the IANA-maintained definitions of relationships.
   This way, for Energy Relationships, new textual conventions can be
   specified, without updating the primary Energy Object Context MIB
   module.






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4.5.   Energy Object Identity Persistence

   In some situations, the Energy Object identity information should be
   persistent even after a device reload.  For example, in a static
   setup where a switch monitors a series of connected PoE phones, there
   is a clear benefit for the EnMS if the Energy Object Identification
   and all associated information persist, as it saves a network
   discovery.  However, in other situations, such as a wireless access
   point monitoring the mobile user PCs, there is not much advantage to
   persist the Energy Object Information.  The identity information of
   an Energy Object should be persisted and there is value in the
   writable MIB objects persisted.

5.  MIB Definitions

   -- ************************************************************
   --
   --
   -- This MIB is used for describing the identity and the
   -- context information of Energy Objects in network
   --
   --
   -- *************************************************************

   ENERGY-OBJECT-CONTEXT-MIB DEFINITIONS ::= BEGIN

   IMPORTS
       MODULE-IDENTITY,
       OBJECT-TYPE,
       mib-2, Integer32
           FROM SNMPv2-SMI                           -- RFC 2578
       TEXTUAL-CONVENTION, MacAddress, TruthValue,
          RowStatus, StorageType
           FROM SNMPv2-TC                            -- RFC 2579
       MODULE-COMPLIANCE,  OBJECT-GROUP
           FROM SNMPv2-CONF                          -- RFC 2580
       SnmpAdminString
           FROM SNMP-FRAMEWORK-MIB                   -- RFC 3411
       InetAddressType, InetAddress
          FROM INET-ADDRESS-MIB                      -- RFC 4001
       entPhysicalIndex
          FROM ENTITY-MIB                            -- RFC 6933
       UUIDorZero
          FROM UUID-TC-MIB                           -- RFC 6933
       IANAEnergyRelationship
          FROM IANA-ENERGY-RELATION-MIB;





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   energyObjectContextMIB MODULE-IDENTITY
       LAST-UPDATED    "201502090000Z"

       ORGANIZATION    "IETF EMAN Working Group"
       CONTACT-INFO
          "WG Charter:
           http://datatracker.ietf.org/wg/eman/charter/

          Mailing Lists:
           General Discussion: eman@ietf.org
           To Subscribe: https://www.ietf.org/mailman/listinfo/eman
           Archive: http://www.ietf.org/mail-archive/web/eman

          Editors:
             John Parello
             Cisco Systems, Inc.
             3550 Cisco Way
             San Jose, California 95134
             United States
             Phone: +1 408 525 2339
             Email: jparello@cisco.com

             Benoit Claise
             Cisco Systems, Inc.
             De Kleetlaan 6a b1
             Degem 1831
             Belgium
             Phone:  +32 2 704 5622
             Email: bclaise@cisco.com

             Mouli Chandramouli
             Cisco Systems, Inc.
             Sarjapur Outer Ring Road
             Bangalore 560103
             India
             Phone: +91 80 4429 2409
             Email: moulchan@cisco.com"

       DESCRIPTION
          "Copyright (c) 2015 IETF Trust and the persons identified as
           authors of the code.  All rights reserved.

           Redistribution and use in source and binary forms, with or
           without modification, is permitted pursuant to, and subject
           to the license terms contained in, the Simplified BSD License
           set forth in Section 4.c of the IETF Trust's Legal Provisions
           Relating to IETF Documents
           (http://trustee.ietf.org/license-info).



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           This MIB is used for describing the identity and the
           context information of Energy Objects."
       REVISION
           "201502090000Z"
       DESCRIPTION
          "Initial version, published as RFC 7461."

      ::= { mib-2 231 }

   energyObjectContextMIBNotifs OBJECT IDENTIFIER
       ::= { energyObjectContextMIB 0 }

   energyObjectContextMIBObjects OBJECT IDENTIFIER
       ::= { energyObjectContextMIB 1 }

   energyObjectContextMIBConform  OBJECT IDENTIFIER
       ::= { energyObjectContextMIB 2 }

   -- Textual Conventions

   PethPsePortIndexOrZero ::= TEXTUAL-CONVENTION
      DISPLAY-HINT "d"
      STATUS            current
      DESCRIPTION
          "This textual convention is an extension of the
          pethPsePortIndex convention, which defines a greater-
          than-zero value used to identify a power Ethernet Power
          Sourcing Equipment (PSE) port.

          This extension permits the additional value of zero.  The
          semantics of the value zero are object-specific and must,
          therefore, be defined as part of the description of any
          object that uses this syntax.  Examples of the usage of
          this extension are situations where none or all physical
          entities need to be referenced."
      SYNTAX Integer32 (0..2147483647)

   PethPsePortGroupIndexOrZero ::= TEXTUAL-CONVENTION
       DISPLAY-HINT "d"
       STATUS            current
       DESCRIPTION
           "This textual convention is an extension of the
           pethPsePortGroupIndex convention from the Power Over
           Ethernet MIB in RFC 3621, which defines a greater-than-zero
           value used to identify the group containing the port to which
           a power Ethernet PSE is connected.  This extension
           permits the additional value of zero.  The semantics of
           the value zero are object-specific and must, therefore,



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           be defined as part of the description of any object that
           uses this syntax.  Examples of the usage of this
           extension are situations where none or all physical
           entities need to be referenced."
       SYNTAX Integer32 (0..2147483647)

   LldpPortNumberOrZero ::= TEXTUAL-CONVENTION
        DISPLAY-HINT "d"
        STATUS     current
        DESCRIPTION
           "This textual convention is an extension of the
           LldpPortNumber convention specified in the LLDP MIB,
           which defines a greater than zero value used to uniquely
           identify each port contained in the chassis (that is
           known to the LLDP agent) by a port number.  This
           extension permits the additional value of zero.  The
           semantics of the value zero are object-specific and must,
           therefore, be defined as part of the description of any
           object that uses this syntax.  Examples of the usage of
           this extension are situations where none or all physical
           entities need to be referenced."
      SYNTAX Integer32(0..4096)

    EnergyObjectKeywordList ::= TEXTUAL-CONVENTION
       STATUS          current
       DESCRIPTION
           "A list of keywords that can be used to group Energy
           Objects for reporting or searching.  If multiple keywords
           are present, then this string will contain all the
           keywords separated by the ',' character.  All alphanumeric
           characters and symbols (other than a comma), such as #,
           (, $, !, and &, are allowed.  White spaces before and
           after the commas are ignored, as well as within a keyword
           itself.

           For example, if an Energy Object were to be tagged with
           the keyword values 'hospitality' and 'guest', then the
           keyword list will be 'hospitality,guest'."
       SYNTAX OCTET STRING (SIZE (0..2048))

    -- Objects

    eoTable OBJECT-TYPE
        SYNTAX          SEQUENCE OF EoEntry
        MAX-ACCESS      not-accessible
        STATUS          current
        DESCRIPTION
           "This table lists Energy Objects."



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        ::= { energyObjectContextMIBObjects 1 }

    eoEntry OBJECT-TYPE
        SYNTAX          EoEntry
        MAX-ACCESS      not-accessible
        STATUS          current
        DESCRIPTION
           "An entry describes the attributes of an Energy Object.
           Whenever a new Energy Object is added or an existing
           Energy Object is deleted, a row in the eoTable is added
           or deleted."

         INDEX      {entPhysicalIndex }
        ::= { eoTable 1 }

    EoEntry ::= SEQUENCE {
            eoEthPortIndex              PethPsePortIndexOrZero,
            eoEthPortGrpIndex           PethPsePortGroupIndexOrZero,
            eoLldpPortNumber            LldpPortNumberOrZero,
            eoMgmtMacAddress            MacAddress,
            eoMgmtAddressType           InetAddressType,
            eoMgmtAddress               InetAddress,
            eoMgmtDNSName               OCTET STRING,
            eoDomainName                SnmpAdminString,
            eoRoleDescription           SnmpAdminString,
            eoKeywords                  EnergyObjectKeywordList,
            eoImportance                Integer32,
            eoPowerCategory             INTEGER,
            eoAlternateKey              SnmpAdminString,
            eoPowerInterfaceType        INTEGER
           }

    eoEthPortIndex   OBJECT-TYPE
        SYNTAX      PethPsePortIndexOrZero
        MAX-ACCESS   read-only
        STATUS       current
        DESCRIPTION
           "This variable uniquely identifies the power Ethernet
           port to which a Power over Ethernet device is connected.
           If the Power over Ethernet MIB in RFC 3621 is supported by
           the SNMP agent managing the Energy Object, then the
           Energy Object eoethPortIndex MUST contain the
           corresponding value of pethPsePortIndex.  If such a power
           Ethernet port cannot be specified or is not known, then
           the object is zero."
        REFERENCE
           "RFC 3621: Power Ethernet MIB"
        DEFVAL { 0 }



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        ::= { eoEntry 1 }

    eoEthPortGrpIndex   OBJECT-TYPE
        SYNTAX      PethPsePortGroupIndexOrZero
        MAX-ACCESS   read-only
        STATUS       current
        DESCRIPTION
           "This variable uniquely identifies the group containing
           the port to which a power over Ethernet device PSE is
           connected (RFC 3621).  If the Power over Ethernet MIB (RFC
           3621) is supported by the SNMP agent managing the Energy
           Object, then the Energy Object eoEthPortGrpIndex MUST
           contain the corresponding value of eoethPortGrpIndex.  If
           such a power Ethernet port cannot be specified or is not
           known, then the object is zero."
        REFERENCE
           "RFC 3621: Power Ethernet MIB"
        DEFVAL { 0 }
        ::= { eoEntry 2 }

    eoLldpPortNumber   OBJECT-TYPE
        SYNTAX      LldpPortNumberOrZero
        MAX-ACCESS   read-only
        STATUS       current
        DESCRIPTION
           "This variable uniquely identifies the port component
           (contained in the local chassis with the LLDP agent) as
           defined by the lldpLocPortNum in the LLDP-MIB and
           LLDP-MED-MIB.  If the LLDP-MIB is supported by the
           SNMP agent managing the Energy Object, then the Energy
           Object eoLldpPortNumber MUST contain the corresponding
           value of lldpLocPortNum from the LLDP-MIB.  If such a
           port number cannot be specified or is not known, then the
           object is zero."
        REFERENCE
           "LLDP MIB, IEEE 802.1AB-2005; LLDP-MED-MIB, ANSI/TIA-1057"
        DEFVAL { 0 }

        ::= { eoEntry 3 }

    eoMgmtMacAddress OBJECT-TYPE
        SYNTAX          MacAddress
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object specifies a Media Access Control (MAC) address
           of the Energy Object."
        ::= { eoEntry 4  }



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    eoMgmtAddressType OBJECT-TYPE
        SYNTAX          InetAddressType
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object specifies the eoMgmtAddress type, i.e., an
           IPv4 or IPv6 address.  This object MUST be
           populated when eoMgmtAddress is populated."
        ::= { eoEntry 5  }

    eoMgmtAddress OBJECT-TYPE
        SYNTAX          InetAddress
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object specifies the management address as an IPv4
           address or IPv6 address of Energy Object.  The IP address
           type, i.e. IPv4 or IPv6, is determined by the
           eoMgmtAddressType value.  This object can be used as an
           alternate key to help link the Energy Object with other
           keyed information that may be stored within the EnMS(s)."
        ::= { eoEntry 6  }

    eoMgmtDNSName OBJECT-TYPE
        SYNTAX          OCTET STRING
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object specifies a DNS name of the eoMgmtAddress.
           This object can be used as an alternate key to help link
           the Energy Object with other keyed information that may
           be stored within the EnMS(s).  A DNS Name must always be a
           fully qualified name.  This MIB uses the same encoding as
           the DNS protocol."
         REFERENCE
           "RFC 1034: Domain names - concepts and facilities,
            Section 3.1."
        ::= { eoEntry 7  }

    eoDomainName OBJECT-TYPE
        SYNTAX          SnmpAdminString
        MAX-ACCESS      read-write
        STATUS          current
        DESCRIPTION
           "This object specifies the name of an Energy Management
           Domain for the Energy Object.  By default, this object
           should be an empty string.  The value of eoDomainName must
           remain constant at least from one re-initialization of



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           the entity local management system to the next re-
           initialization."
        ::= { eoEntry 8   }

    eoRoleDescription OBJECT-TYPE
        SYNTAX          SnmpAdminString
        MAX-ACCESS      read-write
        STATUS          current
        DESCRIPTION
           "This object specifies an administratively assigned name
           to indicate the purpose an Energy Object serves in the
           network.

           For example, we can have a phone deployed to a lobby with
           eoRoleDescription as 'Lobby phone'.

           This object specifies that the value is the zero-length
           string value if no role description is configured.
           The value of eoRoleDescription must remain constant at
           least from one re-initialization of the entity local
           management system to the next re-initialization."
        ::= { eoEntry 9   }

    eoKeywords OBJECT-TYPE
        SYNTAX          EnergyObjectKeywordList
        MAX-ACCESS      read-write
        STATUS          current
        DESCRIPTION
           "This object specifies a list of keywords that can be
           used to group Energy Objects for reporting or searching.
           The value is the zero-length string if no keywords have
           been configured.  If multiple keywords are present, then
           this string will contain all the keywords separated by
           the ',' character.  For example, if an Energy Object were
           to be tagged with the keyword values 'hospitality' and
           'guest', then the keyword list will be
           'hospitality,guest'.

           If write access is implemented and a value is written
           into the instance, the agent must retain the supplied
           value in the eoKeywords instance associated with
           the same physical entity for as long as that entity
           remains instantiated.  This includes instantiations
           across all re-initializations/reboots of the local
           management agent."
        ::= { eoEntry 10     }

    eoImportance OBJECT-TYPE



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        SYNTAX          Integer32 (1..100)
        MAX-ACCESS      read-write
        STATUS          current
        DESCRIPTION
           "This object specifies a ranking of how important the
           Energy Object is (on a scale of 1 to 100) compared with
           other Energy Objects in the same Energy Management
           Domain.  The ranking should provide a business or
           operational context for the Energy Object as compared to
           other similar Energy Objects.  This ranking could be used
           as input for policy-based network management.

           Although network managers must establish their own
           ranking, the following is a broad recommendation:

           90 to 100 Emergency response
           80 to 89  Executive or business critical
           70 to 79  General or average
           60 to 69  Staff or support
           40 to 59  Public or guest
            1 to 39  Decorative or hospitality

           The value of eoImportance must remain constant at least
           from one re-initialization of the Energy Object local
           management system to the next re-initialization."
        DEFVAL          { 1 }
        ::= { eoEntry 11   }

    eoPowerCategory OBJECT-TYPE
        SYNTAX          INTEGER {
                            consumer(0),
                            producer(1),
                            meter(2),
                            distributor(3),
                            store(4)
                        }
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object describes the Energy Object category, which
           indicates the expected behavior or physical property of
           the Energy Object, based on its design.  An Energy Object
           can be a consumer(0), producer(1), meter(2),
           distributor(3), or store(4).

           In some cases, a meter is required to measure the power
           consumption.  In such a case, this meter Energy Object
           category is meter(2).  If a device is distributing



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           electric Energy, the category of the Energy Object is
           distributor (3).  If a device is storing electric Energy,
           the category of the device can be store (4)."
        ::= { eoEntry 12    }

    eoAlternateKey OBJECT-TYPE
        SYNTAX          SnmpAdminString
        MAX-ACCESS      read-write
        STATUS          current
        DESCRIPTION
           "The eoAlternateKey object specifies an alternate key
           string that can be used to identify the Energy Object.
           Since Energy Management Systems (EnMS) and Network
           Management Systems (NMSs) may need to correlate objects
           across management systems, this alternate key is provided
           to provide such a link.  This optional value is intended
           as a foreign key or alternate identifier for a
           manufacturer or EnMS/NMS to use to correlate the unique
           Energy Object Id in other systems or namespaces.  If an
           alternate key is not available or is not applicable, then
           the value is the zero-length string.
           The value of eoAlternateKey must remain constant at
           least from one re-initialization of the entity local
           management system to the next re-initialization."
        ::= { eoEntry 13 }

    eoPowerInterfaceType            OBJECT-TYPE
        SYNTAX          INTEGER {
                            inlet(0),
                            outlet(1),
                            both(2)
                        }
        MAX-ACCESS      read-only
        STATUS          current
        DESCRIPTION
           "This object describes the Power Interface for an Energy
           Object.  A Power Interface is an interface at which an
           Energy Object is connected to a power transmission
           medium, at which it can in turn receive power, provide
           power, or both.  A Power Interface type can be an inlet(0),
           an outlet(1), or both(2), respectively."
        ::= { eoEntry 14 }

    eoRelationTable OBJECT-TYPE
        SYNTAX          SEQUENCE OF EoRelationEntry
        MAX-ACCESS      not-accessible
        STATUS          current
        DESCRIPTION



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           "This table describes the relationships between Energy
           Objects."
        ::= { energyObjectContextMIBObjects 2 }

    eoRelationEntry OBJECT-TYPE
        SYNTAX          EoRelationEntry
        MAX-ACCESS      not-accessible
        STATUS          current
        DESCRIPTION
           "An entry in this table specifies the Energy relationship
           between Energy objects.  Energy relations between two
           Energy objects are defined in RFC 7326."
        REFERENCE
           " RFC 7326: Energy Management Framework"
        INDEX        { entPhysicalIndex, eoRelationIndex }
        ::= { eoRelationTable 1 }

    EoRelationEntry ::= SEQUENCE {
                   eoRelationIndex        Integer32,
                   eoRelationID           UUIDorZero,
                   eoRelationship         IANAEnergyRelationship,
                   eoRelationStatus       RowStatus,
                   eoRelationStorageType  StorageType
                  }

    eoRelationIndex     OBJECT-TYPE
        SYNTAX          Integer32 (0..2147483647)
        MAX-ACCESS      not-accessible
        STATUS          current
        DESCRIPTION
           "This object is an arbitrary index to identify the Energy
           Object related to another Energy Object."
        ::= { eoRelationEntry 1 }

    eoRelationID        OBJECT-TYPE
        SYNTAX          UUIDorZero
        MAX-ACCESS      read-create
        STATUS          current
        DESCRIPTION
           "This object specifies the Universally Unique Identifier
           (UUID) of the peer (other) Energy Object.  The UUID must
           comply with the specifications of UUID in UUID-TC-MIB.

           If the UUID of the Energy Object is unknown or nonexistent,
           the eoRelationID will be set to a zero-length string
           instead.  It is preferable that the value of
           entPhysicalUUID from ENTITY-MIB is used for values for
           this object."



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     REFERENCE
           "RFC 6933: Entity MIB (Version 4)"
        ::= { eoRelationEntry 2 }

    eoRelationship      OBJECT-TYPE
        SYNTAX          IANAEnergyRelationship
        MAX-ACCESS      read-create
        STATUS          current
        DESCRIPTION
           "This object describes the relations between Energy
           Objects.  For each Energy Object, the relations between
           the other Energy Objects are specified using the bitmap."
        ::= { eoRelationEntry 3 }

    eoRelationStatus OBJECT-TYPE
        SYNTAX          RowStatus
        MAX-ACCESS      read-create
        STATUS          current
        DESCRIPTION
         "The status controls and reflects the creation and
          activation status of a row in this table to specify energy
          relationship between Energy Objects.

         An entry status may not be active(1) unless all objects in
         the entry have the appropriate values.

         No attempt to modify a row columnar object instance value
         in the eoRelationTable should be issued while the value of
         eoRelationStatus is active(1).  The data can be destroyed by
         setting up the eoRelationStatus to destroy(2)."

    ::= { eoRelationEntry 4 }

     eoRelationStorageType OBJECT-TYPE
       SYNTAX          StorageType
       MAX-ACCESS      read-create
       STATUS          current
       DESCRIPTION
        "This variable indicates the storage type for this row."
           DEFVAL { nonVolatile }
     ::= {eoRelationEntry 5 }

    -- Conformance

    energyObjectContextMIBCompliances  OBJECT IDENTIFIER
        ::= { energyObjectContextMIBConform 1   }

    energyObjectContextMIBGroups  OBJECT IDENTIFIER



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        ::= { energyObjectContextMIBConform 2   }

    energyObjectContextMIBFullCompliance MODULE-COMPLIANCE
        STATUS          current
        DESCRIPTION
            "When this MIB is implemented with support for
            read-write, then such an implementation can
            claim full compliance.  Such devices can then
            be both monitored and configured with this MIB.
            Module Compliance of ENTITY-MIB with respect to
            entity4CRCompliance MUST be supported."

        MODULE          -- this module
        MANDATORY-GROUPS {
                    energyObjectContextMIBTableGroup,
                    energyObjectRelationTableGroup
                         }

        GROUP     energyObjectOptionalMIBTableGroup
                  DESCRIPTION
                  "A compliant implementation does not have to
                  implement."
        ::= { energyObjectContextMIBCompliances 1 }

    energyObjectContextMIBReadOnlyCompliance MODULE-COMPLIANCE
        STATUS          current
        DESCRIPTION
            "When this MIB is implemented without support for
            read-write (i.e., in read-only mode), then such an
            implementation can claim read-only compliance.
            Such a device can then be monitored but cannot be
            configured with this MIB.
            Module Compliance of ENTITY-MIB with respect to
            entity4CRCompliance MUST be supported."
        MODULE          -- this module

        MANDATORY-GROUPS {
                     energyObjectContextMIBTableGroup,
                     energyObjectRelationTableGroup
                         }

       GROUP energyObjectOptionalMIBTableGroup
          DESCRIPTION
          "A compliant implementation does not have to implement
           the managed objects in this GROUP."

       ::= { energyObjectContextMIBCompliances 2 }




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    -- Units of Conformance
    energyObjectContextMIBTableGroup OBJECT-GROUP
        OBJECTS         {
                            eoDomainName,
                            eoRoleDescription,
                            eoAlternateKey,
                            eoKeywords,
                            eoImportance,
                            eoPowerCategory,
                            eoPowerInterfaceType
                        }
        STATUS          current
        DESCRIPTION
            "This group contains the collection of all the objects
            related to the EnergyObject."

        ::= { energyObjectContextMIBGroups 1 }

    energyObjectOptionalMIBTableGroup OBJECT-GROUP
           OBJECTS         {
                            eoEthPortIndex,
                            eoEthPortGrpIndex,
                            eoLldpPortNumber,
                            eoMgmtMacAddress,
                            eoMgmtAddressType,
                            eoMgmtAddress,
                            eoMgmtDNSName
                           }
        STATUS          current
        DESCRIPTION
            "This group contains the collection of all the objects
            related to the Energy Object."
        ::= { energyObjectContextMIBGroups 2 }

    energyObjectRelationTableGroup OBJECT-GROUP
         OBJECTS         {

                        eoRelationID,
                        eoRelationship,
                        eoRelationStatus,
                        eoRelationStorageType
                         }
         STATUS          current
         DESCRIPTION
            "This group contains the collection of all objects
            specifying the relationship between Energy Objects."
        ::= { energyObjectContextMIBGroups 3 }
    END



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    IANA-ENERGY-RELATION-MIB DEFINITIONS ::= BEGIN
         IMPORTS
           MODULE-IDENTITY, mib-2
               FROM SNMPv2-SMI
           TEXTUAL-CONVENTION
               FROM SNMPv2-TC;

         ianaEnergyRelationMIB MODULE-IDENTITY
           LAST-UPDATED "201502090000Z"  -- February 9, 2015
           ORGANIZATION "IANA"
           CONTACT-INFO "
                         Internet Assigned Numbers Authority
                         Postal: ICANN
                         12025 Waterfront Dr., Suite 300
                         Los Angeles, CA 90094
                         United States
                         Tel: +1-310-301-5800
                         EMail: iana@iana.org"

           DESCRIPTION
            "Copyright (c) 2015 IETF Trust and the persons identified as
             authors of the code.  All rights reserved.

             Redistribution and use in source and binary forms, with or
             without modification, is permitted pursuant to, and subject
             to the license terms contained in, the Simplified BSD
             License set forth in Section 4.c of the IETF Trust's Legal
             Provisions Relating to IETF Documents
             (http://trustee.ietf.org/license-info).

             This MIB module defines a TEXTUAL-CONVENTION that
             describes the relationships between Energy Objects.

             The initial version of this MIB module was published in
             RFC 7461; for full legal notices see the RFC itself."

           REVISION     "201502090000Z"  -- February 9, 2015
           DESCRIPTION  "Initial version of this MIB as published in
                         RFC 7461."
           ::= { mib-2 232 }

         -- Textual Conventions

   IANAEnergyRelationship ::= TEXTUAL-CONVENTION
       STATUS            current
       DESCRIPTION
              "An enumerated value specifying the type of
               relationship between an Energy Object A, on



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               which the relationship is specified, with the
               Energy Object B, identified by the UUID.

               The enumeration 'poweredBy' is applicable if
               Energy Object A is poweredBy Energy Object B.

               The enumeration 'powering' is applicable if
               Energy Object A is powering Energy Object B.

               The enumeration 'meteredBy' is applicable if
               Energy Object A is meteredBy Energy Object B.

               The enumeration 'metering' is applicable if
               Energy Object A is metering Energy Object B.

               The enumeration 'aggregatedBy' is applicable if
               Energy Object A is aggregatedBy Energy Object B.

               The enumeration 'aggregating' is applicable if
               Energy Object A is aggregating Energy Object B."

       SYNTAX      INTEGER  {
                    poweredBy(1),   --  power relationship
                    powering(2),
                    meteredBy(3),   --  meter relationship
                    metering(4),
                    aggregatedBy(5), -- aggregation relationship
                    aggregating(6)
                    }

   END

6.  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 opens devices to attack.  These
   are the tables and objects and their sensitivity/vulnerability:

      Unauthorized changes to the eoDomainName, entPhysicalName,
      eoRoleDescription, eoKeywords, eoImportance, eoAlternateKey,
      eoRelationID, eoRelationship, eoRelationStatus, and/or
      eoRelationStorageType MAY disrupt power and energy collection, and
      therefore any predefined policies defined in the network.





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   SNMP versions prior to SNMPv3 did not include adequate security.
   Even if the network itself is secure (for example by using IPsec),
   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.

   Implementations SHOULD provide the security features described by the
   SNMPv3 framework (see [RFC3410]), and implementations claiming
   compliance to the SNMPv3 standard MUST include full support for
   authentication and privacy via the User-based Security Model (USM)
   [RFC3414] with the AES cipher algorithm [RFC3826].  Implementations
   MAY also provide support for the Transport Security Model (TSM)
   [RFC5591] in combination with a secure transport such as SSH
   [RFC5592] or TLS/DTLS [RFC6353].

   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.

   In certain situations, energy and power monitoring can reveal
   sensitive information about individuals' activities and habits.
   Implementors of this specification should use appropriate privacy
   protections as discussed in Section 9 of RFC 6988 and monitoring of
   individuals and homes should only occur with proper authorization.

7.  IANA Considerations

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

       Descriptor                    OBJECT IDENTIFIER Value
       ----------                    -----------------------
     energyObjectContextMIB              { mib-2 231 }

   This document defines the first version of the IANA-maintained IANA-
   ENERGY-RELATION-MIB module, which allows new definitions of
   relationships between Energy Objects.

   A Specification Required as defined in [RFC5226] is REQUIRED for each
   modification of the energy relationships.

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




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        Descriptor                  OBJECT IDENTIFIER Value
        ----------                  -----------------------
      ianaEnergyRelationMIB             { mib-2 232 }

8.  References

8.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997,
              <http://www.rfc-editor.org/info/rfc2119>.

   [RFC2578]  McCloghrie, K., Ed., Perkins, D., Ed., and J.
              Schoenwaelder, Ed., "Structure of Management Information
              Version 2 (SMIv2)", STD 58, RFC 2578, April 1999,
              <http://www.rfc-editor.org/info/rfc2578>.

   [RFC2579]  McCloghrie, K., Ed., Perkins, D., Ed., and J.
              Schoenwaelder, Ed., "Textual Conventions for SMIv2", STD
              58, RFC 2579, April 1999,
              <http://www.rfc-editor.org/info/rfc2579>.

   [RFC2580]  McCloghrie, K., Ed., Perkins, D., Ed., and J.
              Schoenwaelder, Ed., "Conformance Statements for SMIv2",
              STD 58, RFC 2580, April 1999,
              <http://www.rfc-editor.org/info/rfc2580>.

   [RFC3414]  Blumenthal, U. and B. Wijnen, "User-based Security Model
              (USM) for version 3 of the Simple Network Management
              Protocol (SNMPv3)", STD 62, RFC 3414, December 2002,
              <http://www.rfc-editor.org/info/rfc3414>.

   [RFC3621]  Berger, A. and D. Romascanu, "Power Ethernet MIB", RFC
              3621, December 2003,
              <http://www.rfc-editor.org/info/rfc3621>.

   [RFC3826]  Blumenthal, U., Maino, F., and K. McCloghrie, "The
              Advanced Encryption Standard (AES) Cipher Algorithm in the
              SNMP User-based Security Model", RFC 3826, June 2004,
              <http://www.rfc-editor.org/info/rfc3826>.

   [RFC4122]  Leach, P., Mealling, M., and R. Salz, "A Universally
              Unique IDentifier (UUID) URN Namespace", RFC 4122, July
              2005, <http://www.rfc-editor.org/info/rfc4122>.







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   [RFC5591]  Harrington, D. and W. Hardaker, "Transport Security Model
              for the Simple Network Management Protocol (SNMP)", STD
              78, RFC 5591, June 2009,
              <http://www.rfc-editor.org/info/rfc5591>.

   [RFC5592]  Harrington, D., Salowey, J., and W. Hardaker, "Secure
              Shell Transport Model for the Simple Network Management
              Protocol (SNMP)", RFC 5592, June 2009,
              <http://www.rfc-editor.org/info/rfc5592>.

   [RFC6353]  Hardaker, W., "Transport Layer Security (TLS) Transport
              Model for the Simple Network Management Protocol (SNMP)",
              STD 78, RFC 6353, July 2011,
              <http://www.rfc-editor.org/info/rfc6353>.

   [RFC6933]  Bierman, A., Romascanu, D., Quittek, J., and M.
              Chandramouli, "Entity MIB (Version 4)", RFC 6933, May
              2013, <http://www.rfc-editor.org/info/rfc6933>.

   [RFC7460] Chandramouli, Claise, B., Schoening, B., Quittek, J., and
              Dietz, T., "Monitoring and Control MIB for Power and
              Energy", RFC 7460, March 2015,
              <http://www.rfc-editor.org/info/rfc7460>.

   [LLDP-MED-MIB]
              ANSI/TIA-1057, "The LLDP Management Information Base
              extension module for TIA-TR41.4 media endpoint discovery
              information", July 2005.

   [LLDP-MIB] IEEE, "Management Information Base module for LLDP
              configuration, statistics, local system data and remote
              systems data components", IEEE 802.1AB, May 2005.

8.2.  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,
              <http://www.rfc-editor.org/info/rfc3410>.

   [RFC3433]  Bierman, A., Romascanu, D., and K. Norseth, "Entity Sensor
              Management Information Base", RFC 3433, December 2002,
              <http://www.rfc-editor.org/info/rfc3433>.

   [RFC5226]  Narten, T. and H. Alvestrand, "Guidelines for Writing an
              IANA Considerations Section in RFCs", BCP 26, RFC 5226,
              May 2008, <http://www.rfc-editor.org/info/rfc5226>.




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RFC 7461                Energy Object Context MIB             March 2015


   [RFC6988]  Quittek, J., Ed., Chandramouli, M., Winter, R., Dietz, T.,
              and B. Claise, "Requirements for Energy Management", RFC
              6988, September 2013,
              <http://www.rfc-editor.org/info/rfc6988>.

   [RFC7326]  Parello, J., Claise, B., Schoening, B., and J. Quittek,
              "Energy Management Framework", RFC 7326, September 2014,
              <http://www.rfc-editor.org/info/rfc7326>.

   [EMAN-AS]  Schoening, B., Chandramouli, M., and B. Nordman, "Energy
              Management (EMAN) Applicability Statement", Work in
              Progress, draft-ietf-eman-applicability-statement-08,
              December 2014.

Acknowledgements

   We would like to thank Juergen Quittek and Juergen Schoenwalder for
   their suggestions on the new design of eoRelationTable, which was a
   proposed solution for the open issue on the representation of Energy
   Object as a UUID list.

   Many thanks to Juergen Quittek for many comments on the wording,
   text, and design of the MIB thus resulting in an improved document.

   Many thanks to Alan Luchuk for the review of the MIB and his
   comments.

   In addition, the authors thank Bill Mielke for his multiple reviews,
   Brad Schoening and Juergen Schoenwaelder for their suggestions, and
   Michael Brown for dramatically improving this document.

   Finally, thanks to the EMAN WG chairs: Nevil Brownlee and Tom Nadeau.



















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Authors' Addresses

   John Parello
   Cisco Systems, Inc.
   3550 Cisco Way
   San Jose, California 95134
   United States

   Phone: +1 408 525 2339
   EMail: jparello@cisco.com


   Benoit Claise
   Cisco Systems, Inc.
   De Kleetlaan 6a b1
   Diegem 1813
   Belgium

   Phone: +32 2 704 5622
   EMail: bclaise@cisco.com


   Mouli Chandramouli
   Cisco Systems, Inc.
   Sarjapur Outer Ring Road
   Bangalore 560103
   India

   Phone: +91 80 4429 2409
   EMail: moulchan@cisco.com





















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