Output Variable Dos and Don’ts[LINK]
For general output variables there aren’t many rules. For meter output variables there are quite a few. Here are some tips to keep you out of trouble.
What Variables Should I Output?[LINK]
The choice of variables to output is really up to the developer. Since variables don’t appear on the output file unless requested by the user in the IDF input file, it is better to “SetUp” too many rather than too few. For an HVAC component one should generally output the heating and cooling outputs of the component both in terms of energy and power. Energy is always output in Joules, power in Watts. If there is humidification or dehumidification both total and sensible cooling should be reported. Any electricity or fuel consumed by a component should be reported out, again both in terms of energy (Joules) and power (Watts). For HVAC components in most cases reporting inlet and outlet temperatures and humidities is unnecessary since these quantities can be obtained from the system node outputs.
Output Variable Naming Conventions[LINK]
The names for output variables need to be selected carefully to maintain a high level of consistency and clarity. Well-chosen names help users quickly understand the meaning of a specific output.
The following general guidelines are to be followed when choosing names for new output variables:
Output variable names shall be written in title case where every major word is capitalized (exceptions: “a”, “the”, “for”, etc.) with spaces separating words.
Output variable names shall be written using natural language terminology but should be relatively concise. The language is American English.
Although they should be avoided where practical, acronyms (and symbols) are acceptable where their use is commonplace and contributes to conciseness in identifying a complex engineering concept. Examples of acceptable acronyms for output variable names are listed in the table below.
Abbreviations should not be used and the words spelled out completely.
Where practical, reuse existing names for output variables across different models for similar components. For example, a new model for a zone baseboard heater should reuse the existing names for output variables already in use for other baseboard models rather than use new names that distinguish the kind of baseboard model that the output is associated with. The user-defined name of the component should allow the user to know the association without the basic name of the output variable reflecting that association. This has the advantage of reducing the total number of output variable names and making it simpler for users.
Engineering terminology should generally be consistent with that used in ASHRAE handbooks and literature (American Society of Heating, Refrigeration and Air-Conditioning Engineers, Inc., Atlanta, CA, USA)
Output variable names shall have no punctuation or special characters. The names are expected to contain many adjectives adjacent to each other and no hyphens or commas are needed to clarify.
Output variable names shall always be less than 100 characters long.
An output variable name should be constructed from up to five separate name elements. The following diagram shows the elements and the order that they are to be used in the name. The first three are each somewhat optional and are used as needed to identify the type of engineering model, object, or device being reported on. The last two are nearly always needed. .
Model Classification. This name element is used to identify the specific type of modeling being conducted. When used, it will form the first part of the name. This name element is often not needed, such as when the output is for a more or less usual aspect of buildings and HVAC system models. This is typically used to identify outputs that are associated with an alternative, usually more advanced, model, such as AirflowNetwork (AFN) or Conduction Finite Difference (CondFD). Although modeling domains such as Building, HVAC, or Internal Loads are usually obvious and not needed here, this classification can be useful for non-obvious sub-domains such as Environmental Impact, Refrigeration, or Daylighting.
Spatial Classification. This name element is used to identify spatial or topological location of the thing being reported on. It is generally used to identify which part of the building or system is being referred to by the output. For parts of the building, classifications such as “Zone” and “Surface” are the most common. For a model such as Refrigeration this classification may identify specific parts of the system, such as “Secondary Loop.” There is often no spatial or topological aspect needed and in that case this name element can be omitted.
Type of Component. This name element is used to identify the type of device or phenomena being modeled and reported on. For most component models this should be a simple generic term for the type of device and attempt to reuse established names for similar devices or models. In cases where the Model and Spatial Classifications are sufficient, this element can be omitted.
Specific Nature. This name element is used to identify the nature of what is being reported for the device or phenomena being modeled. This is where the most low-level and specific detail is applied to describe the output variable. This name element is nearly always needed.
Dimensional Nature. This name element is used to identify the nature of the physical dimensions of the quantity being reported in words. This name element is nearly always needed. This name element is the final part of the name so that names end with terms that reflect the nature of the value being reported. However, the name element should not be the actual units. For example, an output that has units of degrees Celsius, the final word in the name should be “Temperature.” Or an output for air flow that has units of kg/s, the final words in the name should be “Mass Flow Rate.” When reporting on electricity use in Watts, the term “Power” is used; however most other uses of Watts use the term “Rate.”
In some situations, a model may lend itself to generating a series of related output variables that depend on input. For example a surface heat transfer model may have results for numerous individual nodes or cells across the thickness of the surfaces. The number of nodes in the model will vary at runtime depending on the Construction. When this is the case, the standard approach used in EnergyPlus is to produce a series of output variables by enumerating the output variable name (rather than the key value) to generate a specific name for each instance. The generated name element for each instance in the series is appended to the end of the name and should end in a number. For example, the third node in a stratified tank model is called “Chilled Water Thermal Storage Temperature Node 3 [C].” This is done to facilitate wildcarding when postprocessing output.
For Version 8.0, a comprehensive effort was made to rename output variables to follow the guidelines and scheme described above. As of Version 8.0 the existing output variables demonstrate the pattern and should serve as good examples to follow for future output variables. The following table lists a few examples of terms, but these are not meant to be comprehensive or restrictive. It is expected that new models may have valid reasons to introduce new terms. Developers should examine RDD output files for comprehensive lists of example output variable names.
Output Variable Classifications
AFN |
Zone |
Inside Face |
Rate |
Refrigeration |
Surface |
Outside Face |
Rate per Area |
Room Air |
Linkage |
Air Terminal |
Energy |
HAMT |
Interior |
Boiler |
Temperature |
CondFD |
Exterior |
Chiller |
Mass Flow Rate |
EMPD |
Site |
Cooling Coil |
COP |
Plant |
Supply Side |
Infiltration |
Power (electric) |
Environmental Impact |
Air System |
Unit Heater |
Level |
HVAC |
Facility |
Generator |
Fraction |
Setpoint Manager |
Node |
Baseboard |
Status |
The following table lists acronyms and symbols used in output variable names.
Output Variable Example Abbreviations
AC |
Alternating Current |
AFN |
AirflowNetwork |
Ar |
Argon |
ASHRAE |
American Society of Heating, Refrigeration, and Air-Conditioning Engineers, Inc. |
BSDF |
Bidirectional Scattering Distribution Function |
CEN |
European Committee for Standardization (Comite Europeen de Normalisation) |
CH4 |
Methane |
CO |
Carbon Monoxide |
CO2 |
Carbon Dioxide |
CondFD |
Conduction Finite Difference |
COP |
Coefficient of Performance |
DC |
Direct Current |
DX |
Direct Expansion |
EIR |
Energy Input Ratio |
EMPD |
Effective Moisture Penetration Depth |
H20 |
Water |
HAMT |
Heat and Moisture Transfer |
Hg |
Mercury |
HHV |
Higher Heating Value |
HVAC |
Heating Ventilation and Air Conditioning |
KSU |
Kansas State University |
LHV |
Lower Heating Value |
N2 |
Nitrogen |
N2O |
Nitrous Oxide |
NH3 |
Ammonia |
NMVOC |
Non-Methane Volatile Organic Compounds |
NOx |
Nitrogen Oxides |
O2 |
Oxygen |
Pb |
Lead |
PM |
Particulate Matter |
PM10 |
Particulate Matter of 10 microns or less in size |
PM2.5 |
Particulate Matter of 2.5 microns or less in size |
PMV |
Predicted Mean Vote |
PPD |
Percent People Dissatisfied |
PV |
Photovoltaic |
PVT |
Photovoltaic-Thermal |
SO2 |
Sulfur Dioxide |
VAV |
Variable Air Volume |
VRF |
Variable Refrigerant Flow |
WAHP |
Water to Air Heat Pump |
What are Meters?[LINK]
In EnergyPlus meters are an additional output reporting capability. A meter is a way of grouping similar output variables. Meters are output variables just like ordinary output variables except that they sum or average a collection of ordinary output variables. In EnergyPlus the meter variables serve two purposes.
Providing output of fuel and electricity consumption by end use categories and at the system plant, building and facility level.
Providing a way of summing heating or cooling outputs for a category of components. The resource type EnergyTransfer is used for this purpose. An example would be reporting out the sum of the heating energy from all the heating coils in a system.
How Do I Create A Meter?[LINK]
Meter output variables are created at the same time and in the same manner as ordinary output variables. SetupOutputVariable is called but the optional arguments ResourceTypeKey, EndUseKey, and GroupKey must be used in addition to the usual arguments. For example, in the electric steam humidifier module
SetupOutputVariable( "Humidifier Electric Energy", OutputProcessor::Unit::J,
Humidifier( HumNum ).ElecUseEnergy, "System", "Sum", Humidifier( HumNum ).Name);
creates an output variable labeled ‘Humidifier Electric Energy [J]’ with the value of Humidifier(HumNum)%ElecUseEnergy.
SetupOutputVariable( "Humidifier Electric Energy", OutputProcessor::Unit::J,
Humidifier( HumNum ).ElecUseEnergy, "System", "Sum", Humidifier( HumNum ).Name, _,
"ELECTRICITY", "HUMIDIFIER", _, "System" );
Creates the same output variable but in addition creates a meter output variable Humidifier:Electricity . This variable will contain the sum of all the electricity consumption of the humidifiers in the system. In addition, this electrical consumption will be added into the meter variables Electricity:HVAC and Electricity:Facility.
Rules for Meter Variables[LINK]
There are a number of rules developers must follow in order to account for all electricity and fuel consumption as well as to prevent consumables from being double counted.
Electricity and fuel meters must always be defined at the simple component level. Some EnergyPlus components are compound components: they are built up from simple components. Examples are fan coils (composed of heating coils, cooling coils, and fans), terminal units etc. Some example simple components are heating and cooling coils, fans, humidifiers etc. Electricity and fuel consumption should always be metered at the simple component level and never at the compound component level. This prevents double counting of the fuel or energy consumption.
A variable should be metered once only. This means a variable can be assigned to only one resource type and to only one end use category.
Energy Transfer should be metered in the same way as fuel or electricity use. Energy Transfer meters should only be defined for simple components and should be assigned the same end use category as the fuel or electricity consumption.
All fuel and electricity consumption must be put in some (one) meter.
Use Energy Transfer judiciously; if in doubt, leave it out.
Output Variable Dos and Don’ts[LINK]
For general output variables there aren’t many rules. For meter output variables there are quite a few. Here are some tips to keep you out of trouble.
What Variables Should I Output?[LINK]
The choice of variables to output is really up to the developer. Since variables don’t appear on the output file unless requested by the user in the IDF input file, it is better to “SetUp” too many rather than too few. For an HVAC component one should generally output the heating and cooling outputs of the component both in terms of energy and power. Energy is always output in Joules, power in Watts. If there is humidification or dehumidification both total and sensible cooling should be reported. Any electricity or fuel consumed by a component should be reported out, again both in terms of energy (Joules) and power (Watts). For HVAC components in most cases reporting inlet and outlet temperatures and humidities is unnecessary since these quantities can be obtained from the system node outputs.
Output Variable Naming Conventions[LINK]
The names for output variables need to be selected carefully to maintain a high level of consistency and clarity. Well-chosen names help users quickly understand the meaning of a specific output.
The following general guidelines are to be followed when choosing names for new output variables:
Output variable names shall be written in title case where every major word is capitalized (exceptions: “a”, “the”, “for”, etc.) with spaces separating words.
Output variable names shall be written using natural language terminology but should be relatively concise. The language is American English.
Although they should be avoided where practical, acronyms (and symbols) are acceptable where their use is commonplace and contributes to conciseness in identifying a complex engineering concept. Examples of acceptable acronyms for output variable names are listed in the table below.
Abbreviations should not be used and the words spelled out completely.
Where practical, reuse existing names for output variables across different models for similar components. For example, a new model for a zone baseboard heater should reuse the existing names for output variables already in use for other baseboard models rather than use new names that distinguish the kind of baseboard model that the output is associated with. The user-defined name of the component should allow the user to know the association without the basic name of the output variable reflecting that association. This has the advantage of reducing the total number of output variable names and making it simpler for users.
Engineering terminology should generally be consistent with that used in ASHRAE handbooks and literature (American Society of Heating, Refrigeration and Air-Conditioning Engineers, Inc., Atlanta, CA, USA)
Output variable names shall have no punctuation or special characters. The names are expected to contain many adjectives adjacent to each other and no hyphens or commas are needed to clarify.
Output variable names shall always be less than 100 characters long.
An output variable name should be constructed from up to five separate name elements. The following diagram shows the elements and the order that they are to be used in the name. The first three are each somewhat optional and are used as needed to identify the type of engineering model, object, or device being reported on. The last two are nearly always needed. .
Model Classification. This name element is used to identify the specific type of modeling being conducted. When used, it will form the first part of the name. This name element is often not needed, such as when the output is for a more or less usual aspect of buildings and HVAC system models. This is typically used to identify outputs that are associated with an alternative, usually more advanced, model, such as AirflowNetwork (AFN) or Conduction Finite Difference (CondFD). Although modeling domains such as Building, HVAC, or Internal Loads are usually obvious and not needed here, this classification can be useful for non-obvious sub-domains such as Environmental Impact, Refrigeration, or Daylighting.
Spatial Classification. This name element is used to identify spatial or topological location of the thing being reported on. It is generally used to identify which part of the building or system is being referred to by the output. For parts of the building, classifications such as “Zone” and “Surface” are the most common. For a model such as Refrigeration this classification may identify specific parts of the system, such as “Secondary Loop.” There is often no spatial or topological aspect needed and in that case this name element can be omitted.
Type of Component. This name element is used to identify the type of device or phenomena being modeled and reported on. For most component models this should be a simple generic term for the type of device and attempt to reuse established names for similar devices or models. In cases where the Model and Spatial Classifications are sufficient, this element can be omitted.
Specific Nature. This name element is used to identify the nature of what is being reported for the device or phenomena being modeled. This is where the most low-level and specific detail is applied to describe the output variable. This name element is nearly always needed.
Dimensional Nature. This name element is used to identify the nature of the physical dimensions of the quantity being reported in words. This name element is nearly always needed. This name element is the final part of the name so that names end with terms that reflect the nature of the value being reported. However, the name element should not be the actual units. For example, an output that has units of degrees Celsius, the final word in the name should be “Temperature.” Or an output for air flow that has units of kg/s, the final words in the name should be “Mass Flow Rate.” When reporting on electricity use in Watts, the term “Power” is used; however most other uses of Watts use the term “Rate.”
In some situations, a model may lend itself to generating a series of related output variables that depend on input. For example a surface heat transfer model may have results for numerous individual nodes or cells across the thickness of the surfaces. The number of nodes in the model will vary at runtime depending on the Construction. When this is the case, the standard approach used in EnergyPlus is to produce a series of output variables by enumerating the output variable name (rather than the key value) to generate a specific name for each instance. The generated name element for each instance in the series is appended to the end of the name and should end in a number. For example, the third node in a stratified tank model is called “Chilled Water Thermal Storage Temperature Node 3 [C].” This is done to facilitate wildcarding when postprocessing output.
For Version 8.0, a comprehensive effort was made to rename output variables to follow the guidelines and scheme described above. As of Version 8.0 the existing output variables demonstrate the pattern and should serve as good examples to follow for future output variables. The following table lists a few examples of terms, but these are not meant to be comprehensive or restrictive. It is expected that new models may have valid reasons to introduce new terms. Developers should examine RDD output files for comprehensive lists of example output variable names.
The following table lists acronyms and symbols used in output variable names.
What are Meters?[LINK]
In EnergyPlus meters are an additional output reporting capability. A meter is a way of grouping similar output variables. Meters are output variables just like ordinary output variables except that they sum or average a collection of ordinary output variables. In EnergyPlus the meter variables serve two purposes.
Providing output of fuel and electricity consumption by end use categories and at the system plant, building and facility level.
Providing a way of summing heating or cooling outputs for a category of components. The resource type EnergyTransfer is used for this purpose. An example would be reporting out the sum of the heating energy from all the heating coils in a system.
How Do I Create A Meter?[LINK]
Meter output variables are created at the same time and in the same manner as ordinary output variables. SetupOutputVariable is called but the optional arguments ResourceTypeKey, EndUseKey, and GroupKey must be used in addition to the usual arguments. For example, in the electric steam humidifier module
creates an output variable labeled ‘Humidifier Electric Energy [J]’ with the value of Humidifier(HumNum)%ElecUseEnergy.
Creates the same output variable but in addition creates a meter output variable Humidifier:Electricity . This variable will contain the sum of all the electricity consumption of the humidifiers in the system. In addition, this electrical consumption will be added into the meter variables Electricity:HVAC and Electricity:Facility.
Rules for Meter Variables[LINK]
There are a number of rules developers must follow in order to account for all electricity and fuel consumption as well as to prevent consumables from being double counted.
Electricity and fuel meters must always be defined at the simple component level. Some EnergyPlus components are compound components: they are built up from simple components. Examples are fan coils (composed of heating coils, cooling coils, and fans), terminal units etc. Some example simple components are heating and cooling coils, fans, humidifiers etc. Electricity and fuel consumption should always be metered at the simple component level and never at the compound component level. This prevents double counting of the fuel or energy consumption.
A variable should be metered once only. This means a variable can be assigned to only one resource type and to only one end use category.
Energy Transfer should be metered in the same way as fuel or electricity use. Energy Transfer meters should only be defined for simple components and should be assigned the same end use category as the fuel or electricity consumption.
All fuel and electricity consumption must be put in some (one) meter.
Use Energy Transfer judiciously; if in doubt, leave it out.
Documentation content copyright © 1996-2018 The Board of Trustees of the University of Illinois and the Regents of the University of California through the Ernest Orlando Lawrence Berkeley National Laboratory. All rights reserved. EnergyPlus is a trademark of the US Department of Energy.
This documentation is made available under the EnergyPlus Open Source License v1.0.