Fix typos in outputs/docs/src/etc.

doc/ems-application-guide/src/ems-actuators/hvac-systems-001.tex

@@ -180,7 +180,7 @@ \subsection{Pump}\label{pump}
 \end{equation}
 
 where $P$ is the pump power (\si{\watt}), $\dot{Q}$ is the volume flow rate (\si{\volumeFlowRate}), $\eta_{total}$ is the pump total efficiency (\%)
-and $\Delta P_{override}$ is your EMS-overriden pressure rise (\si{\pascal}).
+and $\Delta P_{override}$ is your EMS-overridden pressure rise (\si{\pascal}).
 
 The unique identifier in both these actuator is the name of Pump Input object.
 

doc/engineering-reference/src/advanced-surface-concepts/exterior-naturally-vented-cavity.tex

@@ -237,6 +237,6 @@ \subsection{Radiation Coefficients}\label{radiation-coefficients}
 
 \subsection{References}\label{references-023}
 
-ASHRAE HOF 2001.~ 2001 ASHRAE Fundamentals Handbook.~ American Society of Heating Refrigeration and Air-Conditioning Engineers. Altanta GA.
+ASHRAE HOF 2001.~ 2001 ASHRAE Fundamentals Handbook.~ American Society of Heating Refrigeration and Air-Conditioning Engineers. Atlanta GA.
 
 ISO. 2003. ISO 15099:2003. Thermal performance of windows, doors, and shading devices -- Detailed calculations. International Organization for Standardization.

doc/engineering-reference/src/simulation-models-encyclopedic-reference-001/coils.tex

@@ -392,7 +392,7 @@ \subsubsection{Coil Completely Wet Calculations (operating block)}\label{coil-co
 and
 
 \begin{equation}
-OutletAirHumdityRatio = PsyWFnTdbH(OutletAirTemp,EnthAirOutlet)
+OutletAirHumIdityRatio = PsyWFnTdbH(OutletAirTemp,EnthAirOutlet)
 \end{equation}
 
 \textbf{ELSE}
@@ -2294,7 +2294,7 @@ \subsubsection{Waste heat calculation}\label{waste-heat-calculation-000}
 {Q_{WasteHeat}} = (Fraction)(TempModifier)(CoolingPower)
 \end{equation}
 
-where Fraction is the rated waste heat fraction of the energy input and TempModifer is the waste heat modifier as a function of indoor and outdoor air dry-bulb temperature.
+where Fraction is the rated waste heat fraction of the energy input and TempModifier is the waste heat modifier as a function of indoor and outdoor air dry-bulb temperature.
 
 \subsubsection{Basin Heater For Multi-Speed DX Coil}\label{basin-heater-for-multi-speed-dx-coil}
 
@@ -2306,10 +2306,10 @@ \subsubsection{Standard Rating of Multi-Speed DX Cooling Coils}\label{standard-r
 
 ANSI/AHRI Standard 210-240 (AHRI 2017 and 2023)
 [AHRI 2017] For multi-speed direct expansion cooling coils, the industry standard ratings are calculated according to ANSI/AHRI Standard 210-240 (AHRI 2017). These Standard Ratings are: Standard Rating Cooling Capacity and Seasonal Energy Efficiency Ratio (SEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:MultiSpeed object. These AHRI Standard ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19,000 Watts). The equations required to calculate the net cooling capacity and SEER values according to the AHRI 2017 standard are outlined in the next two sections. Further detail can be found in the AHRI Standard 210-240 (2017) (section 11).
-[AHRI 2023] Support for the 2023 version of this Standard was added in EnergyPlus version 22.2. The updated Standard Ratings are designated as: Standard Rating (Net) Cooling Capacity, Energy Efficiency Ratio (EER2), and Seasonal Energy Efficiency Ratio (SEER2). As with th 2017 version, this standard and ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19 kW). The equations used in this implementation are detailed in the AHRI standard (Section 11). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-210240-2023-2020-performance-rating-unitary-air-conditioning-air-source-heat).
+[AHRI 2023] Support for the 2023 version of this Standard was added in EnergyPlus version 22.2. The updated Standard Ratings are designated as: Standard Rating (Net) Cooling Capacity, Energy Efficiency Ratio (EER2), and Seasonal Energy Efficiency Ratio (SEER2). As with the 2017 version, this standard and ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19 kW). The equations used in this implementation are detailed in the AHRI standard (Section 11). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-210240-2023-2020-performance-rating-unitary-air-conditioning-air-source-heat).
 
 ANSI/AHRI Standard 340-360 (AHRI 2022) 
-The Standard Rating calulations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:MultiSpeed object (see the EnergyPlus I/O Reference manual for details). According to AHRI Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capcities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are detailed in this standard (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
+The Standard Rating calculations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:MultiSpeed object (see the EnergyPlus I/O Reference manual for details). According to AHRI Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capacities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are detailed in this standard (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
 
 Standard Ratings Reporting
 The values for these Standard Ratings are reported in the eplusout.eio output file and also in the predefined tabular output reports (Output:Table:SummaryReports object, '2017 Standard Ratings for DX Coils' and '2023 Standard Ratings for DX Coils').
@@ -2670,7 +2670,7 @@ \subsubsection{Standard Rating of Two-Speed DX Cooling Coils}\label{standard-rat
 For Two-Speed direct expansion cooling coils, the following industry standard ratings are calculated and reported according to the industry standards listed below:
 
 ANSI/AHRI Standard 340-360 (AHRI 2022) 
-The Standard Rating calulations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:TwoSpeed object (see the I/O Reference manual for details). According to Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capcities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are outlined in the next section.  For more detail is provided in this standard itself (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
+The Standard Rating calculations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:TwoSpeed object (see the I/O Reference manual for details). According to Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capacities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are outlined in the next section.  For more detail is provided in this standard itself (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
 
 Standard Ratings Reporting
 The values for these Standard Ratings are reported in the eplusout.eio output file and also in the predefined tabular output reports (Output:Table:SummaryReports object, '2017 Standard Ratings for DX Coils' and '2023 Standard Ratings for DX Coils').
@@ -3134,11 +3134,11 @@ \subsubsection{Standard Rating of Variable Speed DX Cooling Coils}\label{standar
 
 For variable speed direct expansion cooling coils, the following industry standard ratings are calculated and reported according to the industry standards listed below:
 ANSI/AHRI Standard 210-240 (AHRI 2017 and 2023) 
-[AHRI 2017] The Standard Rating calulations defined in the 2017 version of this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER), Integrated Energy Efficiency Ratio (IEER), and Seasonal Energy Efficiency Ratio (SEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:MultiSpeed object. These AHRI Standard ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19,000 Watts). The equations required to calculate the net cooling capacity and SEER values aaccording to the AHRI 2017 standard are outlined below (sections 15.2.5.9 and 15.2.5.10) further detail can be found in the AHRI Standard 210-240 (2017) (section 11).
-[AHRI 2023] Support for the 2023 version of this Standard was added in EnergyPlus version 22.2. The updated Standard Ratings are designated as: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER2), and Seasonal Energy Efficiency Ratio (SEER2). As with th 2017 version, this standard and ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19 kW). The equations used in this implementation are detailed in the AHRI standard (Section 11). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-210240-2023-2020-performance-rating-unitary-air-conditioning-air-source-heat). 
+[AHRI 2017] The Standard Rating calculations defined in the 2017 version of this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER), Integrated Energy Efficiency Ratio (IEER), and Seasonal Energy Efficiency Ratio (SEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:DX:MultiSpeed object. These AHRI Standard ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19,000 Watts). The equations required to calculate the net cooling capacity and SEER values according to the AHRI 2017 standard are outlined below (sections 15.2.5.9 and 15.2.5.10) further detail can be found in the AHRI Standard 210-240 (2017) (section 11).
+[AHRI 2023] Support for the 2023 version of this Standard was added in EnergyPlus version 22.2. The updated Standard Ratings are designated as: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER2), and Seasonal Energy Efficiency Ratio (SEER2). As with the 2017 version, this standard and ratings apply only to air-to-air unitary heat pumps and air conditioners with rated cooling capacities less than 65,000 Btu/h (19 kW). The equations used in this implementation are detailed in the AHRI standard (Section 11). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-210240-2023-2020-performance-rating-unitary-air-conditioning-air-source-heat). 
 
 ANSI/AHRI Standard 340-360 (AHRI 2022) 
-The Standard Rating calulations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:VariableSpeed object (see the EnergyPlus I/O Reference manual for details). According to AHRI Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capcities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are detailed in this standard (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
+The Standard Rating calculations defined in this standard include: Standard Rating Cooling Capacity, Energy Efficiency Ratio (EER) and Integrated Energy Efficiency Ratio (IEER). These standard ratings are calculated using the user-entered data in the Coil:Cooling:VariableSpeed object (see the EnergyPlus I/O Reference manual for details). According to AHRI Standard, these ratings apply to factory-made Commercial and Industrial Unitary Air-conditioning and Heat Pump Equipment with rated cooling/heating capacities greater than 65,000 Btu/h (19 kW) and less than 250,000 Btu/h (73.2 kW). The equations used in this implementation are detailed in this standard (Section 6). The reader can download the standard document to view these details from AHRI(https://www.ahrinet.org/search-standards/ahri-340360-i-p2022-performance-rating-commercial-and-industrial-unitary-air). 
 
 Standard Ratings Reporting
 The values for these Standard Ratings are reported in the eplusout.eio output file and also in the predefined tabular output reports (Output:Table:SummaryReports object, '2017 Standard Ratings for DX Coils' and '2023 Standard Ratings for DX Coils').

doc/engineering-reference/src/simulation-models-encyclopedic-reference-002/air-system-compound-component-groups.tex

@@ -207,7 +207,7 @@ \subsubsection{Load based control:}\label{load-based-control}
 
 \emph{\({\dot m_{Speed1}}\)} is the air mass flow rate through unitary system at Speed 1 (kg/s)
 
-\(\Delta_{sen,Speed1}\) is th sensible load difference between the system output node and the zone inlet node at full-load conditions at Speed 1.
+\(\Delta_{sen,Speed1}\) is the sensible load difference between the system output node and the zone inlet node at full-load conditions at Speed 1.
 
 \begin{equation}
   \begin{split}

doc/essentials/src/essentials.tex

@@ -42,7 +42,7 @@ \section{What is BEM?}
 \begin{itemize}
 \item \href{https://www.ashrae.org/technical-resources/ashrae-handbook/description-2017-ashrae-handbook-fundamentals}{2017 ASHRAE Handbook - Fundamentals }Chapter
 19 Energy Estimating and Modeling Methods
-\item \href{https://www.bemlibrary.com/}{BEM Libary}
+\item \href{https://www.bemlibrary.com/}{BEM Library}
 \item \href{http://www.ibpsa.org/?page_id=695}{IBPSA}, \href{https://www.ibpsa.us/videos/all}{IBPSA-USA},
 and \href{https://www.youtube.com/results?search_query=building+energy+modeling}{YouTube}
 videos
@@ -89,7 +89,7 @@ \section{Questions that BEM can answer}
 The most common questions that BEM can answer are:
 \begin{itemize}
 \item If my building was made or operated differently, how would the required
-equpment capacity and energy consumption change?
+equipment capacity and energy consumption change?
 \item Does my building comply with a building energy code or standard?
 \item What kind of rating or how many points can I get in an environmental
 certification program?
@@ -983,7 +983,7 @@ \section{What Are All These Output Files?}
 \item ERR -- list of errors and warnings
 \item TABLE.HTML, TABLE.TXT, TABLE.TAB, TABLE.CSV, TABLE.XML -- tabulated
 report of the bin and monthly data in HTML, space delimited, tab delimited,
-comma delimited, or XML format. This is one of the primary otuput
+comma delimited, or XML format. This is one of the primary output
 files.
 \item CSV, TAB, or TXT -- time series output from the Output:Variable input
 object in a comma, tab, or space delimited format (generated by the
@@ -1101,7 +1101,7 @@ \section{Data Sets}
 DataSets -- which contains IDF snippets and MacroDataSets -- which
 also contain IDF snippets but are in a form such that they can be
 easily used with the EPMacro program. Another data set are DDY files
-that acompany each EPW weather file. The DDY files include several
+that accompany each EPW weather file. The DDY files include several
 varieties of the corresponding design day data for each weather file
 location.
 
@@ -1168,7 +1168,7 @@ \section{Simulation Parameters}
 related to the simulation that, in general, should be allowed to default.
 \end{itemize}
 For a new modeler, the following input objects may be omitted. They
-can be added later for special cases althought they and appear in
+can be added later for special cases although they appear in
 almost all of the example files:
 \begin{itemize}
 \item Timestep - the number of timesteps each hour and usually set to 6.
@@ -1204,7 +1204,7 @@ \section{Location and Climate}
 to the full year. When debugging a file, a shorter period of time
 can be used to speed up the simulation portion of the Run-Check-Edit
 cycle.
-\item RunPeriodControl:SpecialDays - allows specfication of holidays and
+\item RunPeriodControl:SpecialDays - allows specification of holidays and
 a good example can be seen in 5ZoneCostEst.idf.
 \item RunPeriodControl:DaylightSavingTime - allows the specification of
 the start and ending period for daylight savings time. This will impact

doc/input-output-reference/src/overview/group-airflow.tex

@@ -1927,7 +1927,7 @@ \subsubsection{Outputs}\label{zoneearthtube-outputs}
 
 This is the wet bulb temperature of the air entering the zone after passing through the earth tube {[}C{]}.
 
-\paragraph{Earth Tube Zone Inlet Humidity Ratio {[}kgWater/krDryAir{]}}\label{earth-tube-zone-inlet-humidity-ratio-kgWater/kgDryAir}
+\paragraph{Earth Tube Zone Inlet Humidity Ratio {[}kgWater/krDryAir{]}}\label{earth-tube-zone-inlet-humidity-ratio-kgWater-kgDryAir}
 
 This is the humidity ratio of the air entering the zone after passing through the earth tube {[}kgWater/kgDryAir{]}.
 

doc/input-output-reference/src/overview/group-daylighting.tex

@@ -20,7 +20,7 @@ \subsubsection{Inputs}\label{inputs-009}
 
 The name of the \hyperref[zone]{Zone} or \hyperref[space]{Space} to which the following daylighting-related input applies. If a zone name is specified, the zone must lie completely within a single solar enclosure.
 
-\paragraph{Field: Daylighting Method}\label{field-Daylighting Method}
+\paragraph{Field: Daylighting Method}\label{field-daylighting-method}
 
 The Daylighting Method field can be set to either of the following: SplitFlux or DElight. Different Zones can have different settings in the same file but in a single zone only one method should be used at a time. Guidelines for using the SplitFlux method and additional details on the DElight method are shown in following sections.
 
@@ -89,7 +89,7 @@ \subsubsection{Inputs}\label{inputs-009}
 
 May be specified if a stepped lighting control system (Lighting Control Type set to Stepped) is manually operated, such as in a simple, one-step (on-off) system. Gives the probability the occupants of a daylit zone will set the electric lights to the correct level to obtain the required illuminance. The rest of the time the lights are assumed to be set one step too high. For example, consider an on-off lighting system (Number of Steps = 1) with a set point of 600 lux and 0.7 reset probability. Then, when daylighting exceeds 600 lux, the electric lights will be off 70\% of the time and on 30\% of the time.
 
-\paragraph{Field: Glare Calculation Daylighting Reference Point Name}\label{field-glare calculation-daylighting-reference-point-name}
+\paragraph{Field: Glare Calculation Daylighting Reference Point Name}\label{field-glare-calculation-daylighting-reference-point-name}
 
 The \hyperref[daylightingreferencepoint-000]{Daylighting:ReferencePoint} name should be specified that is used for determining the glare. Only one reference point is used to calculate the glare. This input is only used in when the Daylighting Method is set to SplitFlux. This input is ignored when Daylighting Method is set to DElight.