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Network Working Group J. Parello
Internet-Draft Cisco Systems, Inc.
Intended Status: Informational October 26, 2011
Expires: April 26, 2012
Energy Management Terminology
draft-parello-eman-definitions-03
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Abstract
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This document contains definitions and terms used in the Energy
Management Working Group. Each term contains a definition(s),
example, and reference to a normative, informative or well know
source. Terms originating in this draft should be either
composed of or adapted from other terms in the draft with a
source. The defined terms will then be used in other drafts as
defined here.
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Table of Contents
1. Introduction 3
2. Terminology 4
Energy Management 4
Energy Management System (EnMS) 5
ISO Energy Management System 6
Energy 6
Power 6
Demand 6
Power Quality 7
Electrical Equipment 7
Non-Electrical Equipment (Mechanical Equipment) 7
Energy Object 7
Electrical Energy Object 8
Non-Electrical Energy Object 8
Energy Monitoring 8
Energy Control 8
Energy Management Domain 8
Energy Object Identification 9
Energy Object Context 9
Energy Object Relationships 9
Aggregation Relationship 10
Metering Relationship 10
Power Source Relationship 10
Proxy Relationship 11
Dependency Relationship 11
Energy Object Parent 11
Energy Object Child 11
Power State 11
Manufacturer Power State 12
Power State Set 12
Nameplate Power 12
3. Security Considerations 12
4. IANA Considerations 13
5. Acknowledgments 13
6. References 13
Normative References 13
Informative References 13
1. Introduction
Within Energy Management there are terms that may seem obvious
to a casual reader but in fact require a rigorous and sourced
definition. To avoid any confusion in terms among the working
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group drafts, one glossary / lexicon of terms should exist that
all drafts can refer to. This will avoid a review of terms
multiplied across drafts.
This draft will contain a glossary of definitions of terms that
can be agreed upon by the working group outside of the context
of drafts and then included in or sourced to this draft.
Each term will contain a definition(s), a normative or
informative reference, an optional example, an optional
comment(s) listed a note(s).
All terms should be rooted with a well-known reference. If a
definition is taken verbatim from a reference then the source is
listed in square brackets. If a definition is derived from a
well-known reference then the source is listed as "Adapted from"
with the reference listed in square brackets. If a defined term
is newly defined here the reference will indicate as such by
stating "herein" and if applicable list any composing terms from
this document.
When applicable the [IEEE100] was used as the preferred source.
If a term was not available from [IEEE100], then [IEC60050] was
used. When there were multiple items from [IEEE100], [IEC60050]
or [ISO50001], there were all included.
2. Terminology
Energy Management
1.Energy Management is a set of functions for measuring,
modeling, planning, and optimizing networks to ensure that the
network elements and attached devices use energy efficiently and
is appropriate for the nature of the application and the cost
constraints of the organization.
Reference: Adapted from [ITU-T-M-3400]
2. Energy management refers to the activities, methods,
procedures and tools that pertain to measuring, modeling,
planning, controlling and optimizing the use of energy in
networked systems.
Reference: Adapted from [NMF]
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NOTE: Energy Management is a system congruent to any of FCAPS
areas of management in the ISO/OSI Network Management Model
[TMN]. Energy Management for communication networks and attached
devices is a subset or part of an organization's greater Energy
Management Policies.
Example: A set of computer systems that will poll electrical
meters and store the readings
Energy Management System (EnMS)
1. An Energy Management System is a combination of hardware and
software used to administer a network with the primarily purpose
being Energy Management.
Reference: Adapted from [1037C]
Example: A single computer system that polls data from devices
using SNMP
2. An Energy Management System (ISO-EnMS) is a set of systems or
procedures upon which organizations can develop and implement an
energy policy, set targets, action plans and take into account
legal requirements related to energy use. An EnMS allows
organizations to improve energy performance and demonstrate
conformity to requirements, standards, and/or legal requirements.
Reference: [ISO50001]
Example: Company A defines a set of policies and procedures
indicating there should exist multiple computerized systems that
will poll energy from their meters and pricing / source data from
their local utility. Company A specifies that their CFO should
collect information and summarize it quarterly to be sent to an
accounting firm to produce carbon accounting reporting as
required by their local government.
NOTE: For the purposes of EMAN, the definition from [1037C] is
the preferred meaning of an Energy Management System (EnMS). The
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definition from [ISO50001] can be referred to as ISO Energy
Management System (ISO-EnMS).
ISO Energy Management System
Energy Management System as defined by [ISO50001]
Reference: herein
Energy
1. That which does work or is capable of doing work. As used by
electric utilities, it is generally a reference to electrical
energy and is measured in kilo-watt hours (kWh).
Reference: [IEEE100]
2. Energy is the capacity of a system to produce external
activity or perform work
Reference: [ISO50001]
Power
The time rate at which energy is emitted, transferred, or
received; usually expressed in watts (or in joules per second).
Reference: [IEEE100]
Demand
The average value of power or a related quantity over a specified
interval of time. Note: Demand is expressed in kilowatts,
kilovolt-amperes, kilovars, or other suitable units.
NOTE 1: typically kilowatts
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NOTE 2: Energy providers typically bill by Demand measurements as
well as for maximum Demand per billing periods. Power values may
spike during short-terms by devices, but Demand measurements
recognize that maximum Demand does not equal maximum Power during
an interval.
Reference: [IEEE100]
Power Quality
Characteristics of the electric current, voltage and frequencies
at a given point in an electric power system, evaluated against a
set of reference technical parameters. These parameters might, in
some cases, relate to the compatibility between electricity
supplied in an electric power system and the loads connected to
that electric power system.
Reference: [IEC60050]
Electrical Equipment
A general term including materials, fittings, devices,
appliances, fixtures, apparatus, machines, etc., used as a part
of, or in connection with, an electric installation.
Reference: [IEEE100]
Non-Electrical Equipment (Mechanical Equipment)
A general term including materials, fittings, devices
appliances, fixtures, apparatus, machines, etc., used as a part
of, or in connection with, non-electrical power installations.
Reference: Adapted from [IEEE100]
Energy Object
An Energy Object (EO) is a piece of equipment that is part of or
attached to a communications network that is monitored,
controlled, or aids in the management of another device for
Energy Management.
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Reference: herein
Electrical Energy Object
An Electrical Energy Object (EEO) is an Energy Object that is a
piece of Electrical Equipment
Reference: herein, Electrical Equipment
Non-Electrical Energy Object
A Non-Electrical Energy Object (NEEO) an Energy Object that is a
piece of Non-Electrical Equipment.
Reference: herein, Non-Electrical Equipment.
Energy Monitoring
Energy Monitoring is a part of Energy Management that deals with
collecting or reading information from Energy Objects to aid in
Energy Management.
NOTE: This could include Energy, Power, Demand, Power Quality,
Context and/or Battery information.
Reference: herein
Energy Control
Energy Control is a part of Energy Management that deals with
directing influence over Energy Objects.
NOTE: Typically in order to optimize or ensure its efficiency.
Reference: herein
Energy Management Domain
An Energy Management Domain is a set of Energy Objects.
NOTE: Typically, this set will have as members all EO's that are
powered from the same source.
Reference: herein
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Example: All EEO's drawing power from the same distribution
panel with the same AC voltage within a building, or all EEO's
in a building for which there is one main meter, would comprise
an Energy Management Domain.
Energy Object Identification
Energy Object Identification is a set of attributes that enable
an Energy Object to be: uniquely identified among all Energy
Management Domains; linked to other systems; classified as to
type, model, and or manufacturer.
Reference: herein
Energy Object Context
Energy Object Context is a set of attributes that allow an Energy
Management System to classify the use of the Energy Object within
an organization.
NOTE: The classification could contain the use and/or the ranking
of the Energy Object as compared to other Energy Objects in the
Energy Management Domain.
Reference: herein
Energy Object Relationships
Energy Objects may have functional relationships to each other
within an Energy Management Domain.
NOTE 1: One Energy Object will provide a capability or
functional value in the relationship and another will be the
receiver of the capability.
NOTE 2: These capabilities could include Aggregation, Metering,
Power Source, Proxy and Dependency.
Reference: herein
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Aggregation Relationship
An Energy Object may aggregate the Energy Management information
of one or more Energy Objects and is referred to as an
Aggregation Relationship.
NOTE 1: An Energy Object may be aggregated by another Energy
Object(s).
NOTE 2: Aggregate values may be obtained by reading values from
multiple Energy Objects and producing a single value of more
significant meaning such as average, count, maximum, median,
minimum, mode and most commonly sum.
Reference: Adapted from [SQL]
Metering Relationship
An Energy Object may measure the Energy of another Energy
Object(s) and is referred to as a Metering Relationship.
NOTE: An Energy Object may be metered by another Energy
Object(s).
Reference: herein
Example: a PoE port on a switch measures the Power it provides
to the connected Energy Object.
Power Source Relationship
An Energy Object may be the source of or distributor of power to
another Energy Object(s) and is referred to as a Power Source
Relationship.
NOTE: An Energy Object may be powered by another Energy
Object(s).
Reference: herein
Example: a PDU provides power for a connected host.
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Proxy Relationship
An Energy Object that provides Energy Management capabilities on
behalf of another Energy Object so that is appears to be Energy
Aware is referred to a Proxy Relationship.
NOTE: An Energy Object may be proxied by another Energy
Object(s).
Reference: herein
Example: a protocol gateways device for Building Management
Systems (BMS) with subtended devices.
Dependency Relationship
An Energy Object may be a component of or rely completely upon
another Energy Object to operate and is referred to as a
Dependency Relationship. An Energy Object may be dependent on
another Energy Object(s).
Reference: herein
Example: A Switch chassis with multiple line cards.
Energy Object Parent
An Energy Object Parent is an Energy Object that provides one or
more of the Energy Object Relationships capabilities.
Reference: herein
Energy Object Child
An Energy Object Child is an Energy Object that has at least one
Energy Object Relationship capability provided by another Energy
Object.
Reference: herein
Power State
A Power State is a generalized way to classify a setting on an
Energy Object (e.g., on, off, or sleep).
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NOTE: A Power State can be viewed as one method for Energy
Control
Reference: herein
Manufacturer Power State
A Manufacturer Power State is a device-specific way to classify
a setting implemented on an Energy Object.
Reference: herein
Power State Set
A collection of Power States that comprise one named or logical
grouping of control is a Power State Set.
Reference: herein
Example: The states {on, off, and sleep} as defined in
[IEEE1621], or the 16 power states as defined by the [DMTF] can
be considered two different Power State Sets.
Nameplate Power
The Nameplate Power is the maximal (nominal) Power that a device
can support.
NOTE: This is typically determined via load testing and is
specified by the manufacturer as the maximum value required for
operating the device. This is sometimes referred to as the
worst-case Power. The actual or average Power may be lower.
The Nameplate Power is typically used for provisioning and
capacity planning.
Reference: herein
3. Security Considerations
None
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4. IANA Considerations
None
5. Acknowledgments
The author would like to thank the authors of the current
working group drafts for the discussions and definition
clarifications
6. References
Normative References
Informative References
[IEEE100] "The Authoritative Dictionary of IEEE Standards Terms"
http://ieeexplore.ieee.org/xpl/mostRecentIssue.jsp?punumber=4116
785
[IEEE1621] "Standard for User Interface Elements in Power
Control of Electronic Devices Employed in
Office/Consumer Environments", IEEE 1621, December
2004.
[IEC60050] International Electrotechnical Vocabulary
http://www.electropedia.org/iev/iev.nsf/welcome?openfo
rm
[ISO50001] "ISO 50001:2011 Energy management systems -
Requirements with guidance for use",
http://www.iso.org/
[DMTF] "Power State Management Profile DMTF DSP1027 Version
2.0" December 2009
http://www.dmtf.org/sites/default/files/standards/docu
ments/DSP1027_2.0.0.pdf
[TMN] "TMN Management Functions : Performance Management", ITU-T
M.3400
[NMF] "Network Management Fundamentals", Alexander Clemm, ISBN:
1-58720-137-2, 2007
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[ITU-T-M-3400] TMN recommandation on Management Functions
(M.3400), 1997
[1037C] US Department of Commerce, Federal Standard 1037C,
http://www.its.bldrdoc.gov/fs-1037/fs-1037c.htm
[SQL] ISO/IEC 9075(1-4,9-11,13,14):2008
Authors' Addresses
John Parello
Cisco Systems, Inc.
3550 Cisco Way
San Jose, California 95134
US
Phone: +1 408 525 2339
Email: jparello@cisco.com
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