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ForwardTranslateThermalZone.cpp
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ForwardTranslateThermalZone.cpp
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/***********************************************************************************************************************
* OpenStudio(R), Copyright (c) 2008-2021, Alliance for Sustainable Energy, LLC, and other contributors. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification, are permitted provided that the
* following conditions are met:
*
* (1) Redistributions of source code must retain the above copyright notice, this list of conditions and the following
* disclaimer.
*
* (2) Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided with the distribution.
*
* (3) Neither the name of the copyright holder nor the names of any contributors may be used to endorse or promote products
* derived from this software without specific prior written permission from the respective party.
*
* (4) Other than as required in clauses (1) and (2), distributions in any form of modifications or other derivative works
* may not use the "OpenStudio" trademark, "OS", "os", or any other confusingly similar designation without specific prior
* written permission from Alliance for Sustainable Energy, LLC.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER(S) AND ANY CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER(S), ANY CONTRIBUTORS, THE UNITED STATES GOVERNMENT, OR THE UNITED
* STATES DEPARTMENT OF ENERGY, NOR ANY OF THEIR EMPLOYEES, BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
* USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
***********************************************************************************************************************/
#include "../ForwardTranslator.hpp"
#include "../../model/Model.hpp"
#include "../../model/ThermalZone.hpp"
#include "../../model/ThermalZone_Impl.hpp"
#include "../../model/Node.hpp"
#include "../../model/Node_Impl.hpp"
#include "../../model/PortList.hpp"
#include "../../model/PortList_Impl.hpp"
#include "../../model/ZoneHVACEquipmentList.hpp"
#include "../../model/ZoneHVACEquipmentList_Impl.hpp"
#include "../../model/ZoneHVACIdealLoadsAirSystem.hpp"
#include "../../model/ZoneHVACIdealLoadsAirSystem_Impl.hpp"
#include "../../model/ZoneVentilationDesignFlowRate.hpp"
#include "../../model/ZoneVentilationDesignFlowRate_Impl.hpp"
#include "../../model/ZoneVentilationWindandStackOpenArea.hpp"
#include "../../model/ZoneVentilationWindandStackOpenArea_Impl.hpp"
#include "../../model/SizingZone.hpp"
#include "../../model/SizingZone_Impl.hpp"
#include "../../model/Schedule.hpp"
#include "../../model/Schedule_Impl.hpp"
#include "../../model/ScheduleCompact.hpp"
#include "../../model/ScheduleCompact_Impl.hpp"
#include "../../model/SetpointManagerMixedAir.hpp"
#include "../../model/SetpointManagerSingleZoneReheat.hpp"
#include "../../model/AirLoopHVAC.hpp"
#include "../../model/AirLoopHVAC_Impl.hpp"
#include "../../model/AirLoopHVACReturnPlenum.hpp"
#include "../../model/AirLoopHVACReturnPlenum_Impl.hpp"
#include "../../model/Thermostat.hpp"
#include "../../model/Thermostat_Impl.hpp"
#include "../../model/ThermostatSetpointDualSetpoint.hpp"
#include "../../model/ThermostatSetpointDualSetpoint_Impl.hpp"
#include "../../model/ZoneControlContaminantController.hpp"
#include "../../model/ZoneControlHumidistat.hpp"
#include "../../model/ZoneControlThermostatStagedDualSetpoint.hpp"
#include "../../model/DesignSpecificationOutdoorAir.hpp"
#include "../../model/DesignSpecificationOutdoorAir_Impl.hpp"
#include "../../model/SizingPeriod.hpp"
#include "../../model/SizingPeriod_Impl.hpp"
#include "../../model/ModelObject.hpp"
#include "../../model/ModelObject_Impl.hpp"
#include "../../model/Space.hpp"
#include "../../model/Space_Impl.hpp"
#include "../../model/SpaceType.hpp"
#include "../../model/SpaceType_Impl.hpp"
#include "../../model/ShadingSurfaceGroup.hpp"
#include "../../model/ShadingSurfaceGroup_Impl.hpp"
#include "../../model/ShadingSurface.hpp"
#include "../../model/ShadingSurface_Impl.hpp"
#include "../../model/InteriorPartitionSurfaceGroup.hpp"
#include "../../model/InteriorPartitionSurfaceGroup_Impl.hpp"
#include "../../model/InteriorPartitionSurface.hpp"
#include "../../model/InteriorPartitionSurface_Impl.hpp"
#include "../../model/Surface.hpp"
#include "../../model/Surface_Impl.hpp"
#include "../../model/SubSurface.hpp"
#include "../../model/SubSurface_Impl.hpp"
#include "../../model/ConstructionBase.hpp"
#include "../../model/ConstructionBase_Impl.hpp"
#include "../../model/InternalMass.hpp"
#include "../../model/InternalMass_Impl.hpp"
#include "../../model/InternalMassDefinition.hpp"
#include "../../model/InternalMassDefinition_Impl.hpp"
#include "../../model/People.hpp"
#include "../../model/People_Impl.hpp"
#include "../../model/PeopleDefinition.hpp"
#include "../../model/PeopleDefinition_Impl.hpp"
#include "../../model/Lights.hpp"
#include "../../model/Lights_Impl.hpp"
#include "../../model/LightsDefinition.hpp"
#include "../../model/LightsDefinition_Impl.hpp"
#include "../../model/Luminaire.hpp"
#include "../../model/Luminaire_Impl.hpp"
#include "../../model/LuminaireDefinition.hpp"
#include "../../model/LuminaireDefinition_Impl.hpp"
#include "../../model/ElectricEquipment.hpp"
#include "../../model/ElectricEquipment_Impl.hpp"
#include "../../model/ElectricEquipmentDefinition.hpp"
#include "../../model/ElectricEquipmentDefinition_Impl.hpp"
#include "../../model/ElectricEquipmentITEAirCooled.hpp"
#include "../../model/ElectricEquipmentITEAirCooled_Impl.hpp"
#include "../../model/ElectricEquipmentITEAirCooledDefinition.hpp"
#include "../../model/ElectricEquipmentITEAirCooledDefinition_Impl.hpp"
#include "../../model/GasEquipment.hpp"
#include "../../model/GasEquipment_Impl.hpp"
#include "../../model/GasEquipmentDefinition.hpp"
#include "../../model/GasEquipmentDefinition_Impl.hpp"
#include "../../model/HotWaterEquipment.hpp"
#include "../../model/HotWaterEquipment_Impl.hpp"
#include "../../model/SteamEquipment.hpp"
#include "../../model/SteamEquipment_Impl.hpp"
#include "../../model/OtherEquipment.hpp"
#include "../../model/OtherEquipment_Impl.hpp"
#include "../../model/DaylightingControl.hpp"
#include "../../model/DaylightingControl_Impl.hpp"
#include "../../model/IlluminanceMap.hpp"
#include "../../model/IlluminanceMap_Impl.hpp"
#include "../../model/SpaceInfiltrationDesignFlowRate.hpp"
#include "../../model/SpaceInfiltrationDesignFlowRate_Impl.hpp"
#include "../../model/SpaceInfiltrationEffectiveLeakageArea.hpp"
#include "../../model/SpaceInfiltrationEffectiveLeakageArea_Impl.hpp"
#include "../../model/SpaceInfiltrationFlowCoefficient.hpp"
#include "../../model/SpaceInfiltrationFlowCoefficient_Impl.hpp"
#include "../../model/GlareSensor.hpp"
#include "../../model/GlareSensor_Impl.hpp"
#include "../../model/LifeCycleCost.hpp"
#include "../../model/ZoneMixing.hpp"
#include "../../model/ConstructionAirBoundary.hpp"
#include "../../utilities/idf/IdfExtensibleGroup.hpp"
#include "../../utilities/idf/Workspace.hpp"
#include "../../utilities/idf/WorkspaceObjectOrder.hpp"
#include "../../utilities/core/Logger.hpp"
#include "../../utilities/core/Assert.hpp"
#include <utilities/idd/OS_ThermalZone_FieldEnums.hxx>
#include <utilities/idd/Zone_FieldEnums.hxx>
#include <utilities/idd/HVACTemplate_Zone_IdealLoadsAirSystem_FieldEnums.hxx>
#include <utilities/idd/Daylighting_Controls_FieldEnums.hxx>
#include <utilities/idd/Daylighting_ReferencePoint_FieldEnums.hxx>
#include <utilities/idd/Output_IlluminanceMap_FieldEnums.hxx>
#include <utilities/idd/Schedule_Compact_FieldEnums.hxx>
#include <utilities/idd/ZoneHVAC_EquipmentConnections_FieldEnums.hxx>
#include <utilities/idd/ZoneControl_Thermostat_FieldEnums.hxx>
#include <utilities/idd/ZoneControl_Humidistat_FieldEnums.hxx>
#include <utilities/idd/Sizing_Zone_FieldEnums.hxx>
#include <utilities/idd/DesignSpecification_OutdoorAir_FieldEnums.hxx>
#include <utilities/idd/ZoneVentilation_DesignFlowRate_FieldEnums.hxx>
#include "../../utilities/idd/IddEnums.hpp"
#include <utilities/idd/IddEnums.hxx>
#include <utilities/idd/IddFactory.hxx>
#include "../../utilities/geometry/Geometry.hpp"
#include <algorithm>
#include <numeric>
using namespace openstudio::model;
namespace openstudio {
namespace energyplus {
boost::optional<IdfObject> ForwardTranslator::translateThermalZone(ThermalZone& modelObject) {
std::string tzName = modelObject.nameString();
std::vector<Space> spaces = modelObject.spaces();
// INCLUDE SPACE TRANSLATION (new behavior)
if (spaces.empty()) {
LOG(Warn, "ThermalZone " << tzName << " does not have any geometry or loads associated with it. It will not be translated");
return boost::none;
}
// ThermalZone
// create, register, and name object
IdfObject idfObject = createRegisterAndNameIdfObject(openstudio::IddObjectType::Zone, modelObject);
for (LifeCycleCost lifeCycleCost : modelObject.lifeCycleCosts()) {
translateAndMapModelObject(lifeCycleCost);
}
idfObject.setString(openstudio::ZoneFields::Type, "");
idfObject.setInt(openstudio::ZoneFields::Multiplier, modelObject.multiplier());
if (modelObject.ceilingHeight()) {
idfObject.setDouble(openstudio::ZoneFields::CeilingHeight, modelObject.ceilingHeight().get());
}
if (modelObject.volume()) {
idfObject.setDouble(openstudio::ZoneFields::Volume, modelObject.volume().get());
}
// DLM: currently there is no setter for floorArea and the getter does not return the value from this field
if (modelObject.getDouble(openstudio::OS_ThermalZoneFields::FloorArea)) {
idfObject.setDouble(openstudio::ZoneFields::FloorArea, modelObject.getDouble(openstudio::OS_ThermalZoneFields::FloorArea).get());
}
if (modelObject.zoneInsideConvectionAlgorithm()) {
idfObject.setString(openstudio::ZoneFields::ZoneInsideConvectionAlgorithm, modelObject.zoneInsideConvectionAlgorithm().get());
}
if (modelObject.zoneOutsideConvectionAlgorithm()) {
idfObject.setString(openstudio::ZoneFields::ZoneOutsideConvectionAlgorithm, modelObject.zoneOutsideConvectionAlgorithm().get());
}
// Spaces
// Figure out the x, y, z and whether we write floor area or not
if (m_excludeSpaceTranslation) {
OS_ASSERT(spaces.size() == 1);
auto& space = spaces[0];
idfObject.setDouble(openstudio::ZoneFields::DirectionofRelativeNorth, spaces[0].directionofRelativeNorth());
idfObject.setDouble(openstudio::ZoneFields::XOrigin, space.xOrigin());
idfObject.setDouble(openstudio::ZoneFields::YOrigin, space.yOrigin());
idfObject.setDouble(openstudio::ZoneFields::ZOrigin, space.zOrigin());
if (space.partofTotalFloorArea()) {
idfObject.setString(openstudio::ZoneFields::PartofTotalFloorArea, "Yes");
} else {
idfObject.setString(openstudio::ZoneFields::PartofTotalFloorArea, "No");
}
} else {
// sort by space name
std::sort(spaces.begin(), spaces.end(), WorkspaceObjectNameLess());
boost::optional<double> directionofRelativeNorth;
if (!spaces[0].isDirectionofRelativeNorthDefaulted()) {
directionofRelativeNorth = spaces[0].directionofRelativeNorth();
}
double xOrigin = spaces[0].xOrigin();
double yOrigin = spaces[0].yOrigin();
double zOrigin = spaces[0].zOrigin();
double totalFloorArea = 0.0; // only area included in total floor area
bool needToSetFloorArea = false;
bool anyNotPartofTotalFloorArea = false;
bool partofTotalFloorArea = spaces[0].partofTotalFloorArea();
for (const Space& space : spaces) {
// if all spaces have same directionOfRelativeNorth use that, otherwise clear it
if (!space.isDirectionofRelativeNorthDefaulted()) {
if (directionofRelativeNorth && (*directionofRelativeNorth == space.directionofRelativeNorth())) {
// no-op
} else {
directionofRelativeNorth.reset();
}
}
// pick the lower left corner if specified
xOrigin = std::min(xOrigin, space.xOrigin());
yOrigin = std::min(yOrigin, space.yOrigin());
zOrigin = std::min(zOrigin, space.zOrigin());
double floorArea = space.floorArea();
// space floor area is counted if any space is part of floor area
if (space.partofTotalFloorArea()) {
partofTotalFloorArea = true;
totalFloorArea += floorArea;
if (anyNotPartofTotalFloorArea) {
needToSetFloorArea = true;
}
} else {
anyNotPartofTotalFloorArea = true;
if (partofTotalFloorArea) {
needToSetFloorArea = true;
}
}
} // End loop on space
// set the origin the Thermal Zone (lower-left corner of all spaces)
idfObject.setDouble(openstudio::ZoneFields::XOrigin, xOrigin);
idfObject.setDouble(openstudio::ZoneFields::YOrigin, yOrigin);
idfObject.setDouble(openstudio::ZoneFields::ZOrigin, zOrigin);
// Important: we need to call Space::changeTransformation to align for the xOrigin, yOrigin, zOrigin (lower left corner) we identified above
// Because in E+ all coordinates are still relative to the Zone. The E+ 'Space' object has no specific origin x, y, z coordinates
auto newTranslation = Transformation::translation(Vector3d(xOrigin, yOrigin, zOrigin));
double degNorth = 0.0;
if (directionofRelativeNorth) {
idfObject.setDouble(openstudio::ZoneFields::DirectionofRelativeNorth, directionofRelativeNorth.get());
degNorth = directionofRelativeNorth.get();
}
// rotate negative amount around the z axis, EnergyPlus defines rotation clockwise
auto newRotation = Transformation::rotation(Vector3d(0, 0, 1), -openstudio::degToRad(degNorth));
auto newTransformation = newTranslation * newRotation;
// This will also change the transformation for surfaces, daylighting controls, etc
for (auto& space : spaces) {
space.changeTransformation(newTransformation);
}
if (partofTotalFloorArea) {
idfObject.setString(openstudio::ZoneFields::PartofTotalFloorArea, "Yes");
} else {
idfObject.setString(openstudio::ZoneFields::PartofTotalFloorArea, "No");
}
if (needToSetFloorArea) {
if (modelObject.getDouble(openstudio::OS_ThermalZoneFields::FloorArea)) {
LOG(Info, "ThermalZone " << tzName << " has a user-specified Floor Area, using this number");
idfObject.setDouble(openstudio::ZoneFields::FloorArea, modelObject.getDouble(openstudio::OS_ThermalZoneFields::FloorArea).get());
} else {
LOG(Info, "ThermalZone '" << tzName << "' has spaces with mis-matched 'Part of Total Floor Area' flags. "
<< "Setting the flag to 'Yes', but hard-coding the total floor area to only take into account the spaces "
<< "that are part of total Floor Area");
idfObject.setDouble(openstudio::ZoneFields::FloorArea, totalFloorArea);
}
}
// TODO: JM 2021-10-15: Aren't we having a lot of problems with DaylightingControls? Yes we are!
// Sooooo. Our API prevents us from effectively writing the daylightng objects to a Space because the ThermalZone itself bears the
// Primary/Secondary daylighting control + fraction of lights controlled.
// E+ will yell if you have space enclosures but the Daylighting objects are on Zone-level (also, it currently does not work, IlluminanceMap
// only accepts Zone level, and Daylighting:ReferencePoint should support Space Name but it doesn't)
// So here if the zone has daylighting control, we make an airwall between spaces and convert non airwalls to InternalMass
// another awesome thing is that z.primaryDaylightingControl() || z.secondaryDaylightingControl() || z.illuminanceMap() is probably not safe, since a
// DaylightingControl that isn't directly referenced to a zone might be translated too, because DaylightingControl does reference a space itself
int nDayligthingObjects = std::accumulate(spaces.cbegin(), spaces.cend(), 0, [](int sum, const Space& space) {
return sum + space.daylightingControls().size() + space.illuminanceMaps().size();
});
if (nDayligthingObjects > 0) {
boost::optional<InteriorPartitionSurfaceGroup> interiorPartitionSurfaceGroup;
std::set<Surface> mergedSurfaces;
std::vector<Surface> zoneSurfaces;
for (const auto& space : spaces) {
for (const auto& surface : space.surfaces()) {
zoneSurfaces.emplace_back(surface);
}
}
// sort by surface name, for repeatability
std::sort(zoneSurfaces.begin(), zoneSurfaces.end(), WorkspaceObjectNameLess());
for (const auto& surface : zoneSurfaces) {
// Already processed?
auto it = mergedSurfaces.find(surface);
if (it != mergedSurfaces.end()) {
continue;
}
auto adjacentSurface_ = surface.adjacentSurface();
if (!adjacentSurface_) {
continue;
}
auto adjacentSpace_ = adjacentSurface_->space();
if (!adjacentSpace_) {
continue;
}
// Adjacent Space must be part of this thermalZone as well
if (std::find(spaces.cbegin(), spaces.cend(), adjacentSpace_.get()) == spaces.end()) {
continue;
}
// handling both the surface and the adjacentSurface
mergedSurfaces.insert(surface);
mergedSurfaces.insert(adjacentSurface_.get());
// don't make interior partitions for interior air walls
bool isAirWall = surface.isAirWall();
bool isAdjacentAirWall = adjacentSurface_->isAirWall();
if (isAirWall && isAdjacentAirWall) {
continue;
} else if (isAirWall) {
LOG(Warn, "Interior surface '" << surface.nameString() << "' is an air wall but adjacent surface '" << adjacentSurface_->nameString()
<< "' is not, ignoring internal mass.")
continue;
} else if (isAdjacentAirWall) {
LOG(Warn, "Interior surface '" << adjacentSurface_->nameString() << "' is an air wall but adjacent surface '" << surface.nameString()
<< "' is not, ignoring internal mass.")
continue;
}
if (!interiorPartitionSurfaceGroup) {
interiorPartitionSurfaceGroup = InteriorPartitionSurfaceGroup(modelObject.model());
// TODO: I don't think I care about which space I assign it to, since currently that's only written at Zone Level but this might change
interiorPartitionSurfaceGroup->setSpace(adjacentSpace_.get());
}
// is there a better way to pick which vertices to keep based on outward normal?
InteriorPartitionSurface interiorPartitionSurface(surface.vertices(), modelObject.model());
interiorPartitionSurface.setName("Merged " + surface.name().get() + " - " + adjacentSurface_->name().get());
interiorPartitionSurface.setInteriorPartitionSurfaceGroup(*interiorPartitionSurfaceGroup);
boost::optional<ConstructionBase> construction = surface.construction();
if (construction) {
interiorPartitionSurface.setConstruction(*construction);
}
}
if (!mergedSurfaces.empty()) {
LOG(Warn, modelObject.briefDescription() << " has DaylightingControl Objects assigned. The interior walls between Spaces will be merged. "
"Make sure these are correctly Matched!");
}
ConstructionAirBoundary airWallConstruction(modelObject.model());
// std::set forces a const iterator, hence why I take a copy...
for (Surface mergedSurface : mergedSurfaces) {
mergedSurface.setConstruction(airWallConstruction);
}
} // End Combine surfaces if daylighting
}
for (Space& space : spaces) {
// translate the space now: it will translate it's geometry children (ShadingSurface/InteriorPartition Groups + Surfaces)
// and all SpaceLoad directly associated with the space
translateAndMapModelObject(space);
} // end spaces
// translate daylighting controls
// TODO: move this out somewhere, figure out the right format.
// Maybe `translateDaylightingControl(DaylightingControl primaryDaylightingControl, boost::optional<DaylightingControl> secondaryDaylightingControl)` ?
auto translateDaylightingControls = [this, &tzName](model::ThermalZone& thermalZone) {
boost::optional<DaylightingControl> primaryDaylightingControl = thermalZone.primaryDaylightingControl();
if (primaryDaylightingControl) {
boost::optional<DaylightingControl> secondaryDaylightingControl = thermalZone.secondaryDaylightingControl();
IdfObject daylightingControlObject(openstudio::IddObjectType::Daylighting_Controls);
// Name it like the Zone name + " DaylightingControls"
daylightingControlObject.setName(tzName + " DaylightingControls");
m_idfObjects.push_back(daylightingControlObject);
// Zone Name
daylightingControlObject.setString(Daylighting_ControlsFields::ZoneorSpaceName, tzName);
// Availability Schedule Name
if (boost::optional<Schedule> sched = thermalZone.daylightingControlsAvailabilitySchedule()) {
if (boost::optional<IdfObject> idfo = translateAndMapModelObject(sched.get())) {
daylightingControlObject.setString(Daylighting_ControlsFields::AvailabilityScheduleName, idfo->nameString());
}
}
// Primary Control
IdfObject primaryReferencePoint(openstudio::IddObjectType::Daylighting_ReferencePoint);
// Name it like the OS:Daylighting:Control corresponding to the Primary Reference Point
primaryReferencePoint.setName(primaryDaylightingControl->nameString());
m_idfObjects.push_back(primaryReferencePoint);
OptionalSpace refSpace = primaryDaylightingControl->space();
if (refSpace) {
OptionalThermalZone refThermalZone = refSpace->thermalZone();
// TODO: I think we should catch the case when refThermalZone != thermalZone...
if (refThermalZone) {
primaryReferencePoint.setString(Daylighting_ReferencePointFields::ZoneorSpaceName, refThermalZone->nameString());
}
}
primaryReferencePoint.setDouble(Daylighting_ReferencePointFields::XCoordinateofReferencePoint,
primaryDaylightingControl->positionXCoordinate());
primaryReferencePoint.setDouble(Daylighting_ReferencePointFields::YCoordinateofReferencePoint,
primaryDaylightingControl->positionYCoordinate());
primaryReferencePoint.setDouble(Daylighting_ReferencePointFields::ZCoordinateofReferencePoint,
primaryDaylightingControl->positionZCoordinate());
double primaryFrac = thermalZone.fractionofZoneControlledbyPrimaryDaylightingControl();
if (istringEqual("None", primaryDaylightingControl->lightingControlType())) {
if (primaryFrac > 0.0) {
primaryFrac = 0.0;
LOG(Warn, "Fraction of Zone Controlled by Primary Daylight Control is "
<< primaryFrac << " but lighting control type is 'None'. Reseting Primary Fraction to " << 0.0);
}
}
std::vector<std::string> firstGroup{primaryReferencePoint.nameString(), toString(primaryFrac),
toString(primaryDaylightingControl->illuminanceSetpoint())};
daylightingControlObject.pushExtensibleGroup(firstGroup);
// Secondary Control
if (secondaryDaylightingControl) {
IdfObject secondaryReferencePoint(openstudio::IddObjectType::Daylighting_ReferencePoint);
// Name it like the OS:Daylighting:Control corresponding to the Secondary Reference Point
secondaryReferencePoint.setName(secondaryDaylightingControl->nameString());
m_idfObjects.push_back(secondaryReferencePoint);
refSpace = secondaryDaylightingControl->space();
if (refSpace) {
OptionalThermalZone refThermalZone = refSpace->thermalZone();
// TODO: catch if refThermalZone != thermalZone
if (refThermalZone) {
secondaryReferencePoint.setString(Daylighting_ReferencePointFields::ZoneorSpaceName, refThermalZone->nameString());
}
}
secondaryReferencePoint.setString(Daylighting_ReferencePointFields::ZoneorSpaceName, tzName);
secondaryReferencePoint.setDouble(Daylighting_ReferencePointFields::XCoordinateofReferencePoint,
secondaryDaylightingControl->positionXCoordinate());
secondaryReferencePoint.setDouble(Daylighting_ReferencePointFields::YCoordinateofReferencePoint,
secondaryDaylightingControl->positionYCoordinate());
secondaryReferencePoint.setDouble(Daylighting_ReferencePointFields::ZCoordinateofReferencePoint,
secondaryDaylightingControl->positionZCoordinate());
double secondaryFrac = thermalZone.fractionofZoneControlledbySecondaryDaylightingControl();
if (istringEqual("None", secondaryDaylightingControl->lightingControlType())) {
if (secondaryFrac > 0.0) {
secondaryFrac = 0.0;
LOG(Warn, "Fraction of Zone Controlled by Secondary Daylight Control is "
<< secondaryFrac << " but lighting control type is 'None'. Reseting Secondary Fraction to " << 0.0);
}
} else {
if ((primaryFrac + secondaryFrac) > 1) {
// Reset secondary to 1 - Primary
secondaryFrac = std::max(1.0 - primaryFrac, 0.0);
LOG(Warn, "Fraction of Zone Controlled by Primary Daylight Control is "
<< primaryFrac << " while Secondary Fraction is " << secondaryFrac << ". Reseting Secondary Fraction to " << secondaryFrac);
}
}
std::vector<std::string> secondGroup{secondaryReferencePoint.nameString(), toString(secondaryFrac),
toString(secondaryDaylightingControl->illuminanceSetpoint())};
daylightingControlObject.pushExtensibleGroup(secondGroup);
}
// Shared Data
std::string lightingControlType = primaryDaylightingControl->lightingControlType();
if (istringEqual("None", lightingControlType)) {
// fraction for first point have been set to 0, try to get control type from second point
if (secondaryDaylightingControl) {
lightingControlType = secondaryDaylightingControl->lightingControlType();
}
}
if (istringEqual("None", lightingControlType)) {
// both fractions are 0
} else if (istringEqual("Continuous", lightingControlType)) {
daylightingControlObject.setString(Daylighting_ControlsFields::LightingControlType, "Continuous");
} else if (istringEqual("Stepped", lightingControlType)) {
daylightingControlObject.setString(Daylighting_ControlsFields::LightingControlType, "Stepped");
} else if (istringEqual("Continuous/Off", lightingControlType)) {
daylightingControlObject.setString(Daylighting_ControlsFields::LightingControlType, "ContinuousOff");
} else {
LOG(Warn,
"Unknown lighting control type '" << lightingControlType << "' for OS:Daylighting:Control " << primaryDaylightingControl->nameString());
}
if (primaryDaylightingControl->psiRotationAroundXAxis() != 0.0) {
LOG(Warn, "Rotation of " << primaryDaylightingControl->psiRotationAroundXAxis()
<< " degrees about X axis not mapped for OS:Daylighting:Control " << primaryDaylightingControl->nameString());
}
if (primaryDaylightingControl->thetaRotationAroundYAxis() != 0.0) {
LOG(Warn, "Rotation of " << primaryDaylightingControl->thetaRotationAroundYAxis()
<< " degrees about Y axis not mapped for OS:Daylighting:Control " << primaryDaylightingControl->nameString());
}
// glare:
// * openstudio uses the right-hand rule, y points North and x points east.
// So a positive rotation around the z-axis is counter-clockwise in the horizontal plane
// * E+ on the other hand is looking for something that is clockwise:
// > Field: Glare Calculation Azimuth Angle of View Direction Clockwise from Zone y-Axis
// > It is the angle, measured clockwise in the horizontal plane, between the zone y-axis and the occupant view direction
// 3D View:
// z
// ▲
// │
// │
// | │ ▲
// +└►├─┘
// │ . OS convention for ϕ
// │ .
// │ .<-◝
// │. ) ϕ
// ○─────────────────► y
// ╱ * )
// ╱ *<-◞ E+ Field
// ╱ *
// ╱
// ╱
// x
//
// 2D View, from the top:
//
// y
// ▲ Glare Calculation Azimuth Angle of View Direction Clockwise from Zone y axis
// \ │ E+ /
// \ OS ϕ ├─────┐ /
// \ ┌────┤ ▼/
// \▼ │ /
// \ │ /
// \ │ /
// \ │ /
// \ | /
// (◯)───────────────►x
// z
//
double glareAngle = -primaryDaylightingControl->phiRotationAroundZAxis();
// Force [0,360[
glareAngle = normalizeAngle0to360(glareAngle);
daylightingControlObject.setDouble(Daylighting_ControlsFields::GlareCalculationAzimuthAngleofViewDirectionClockwisefromZoneyAxis, glareAngle);
if (OptionalDouble d = primaryDaylightingControl->maximumAllowableDiscomfortGlareIndex()) {
daylightingControlObject.setDouble(Daylighting_ControlsFields::MaximumAllowableDiscomfortGlareIndex, *d);
}
daylightingControlObject.setString(Daylighting_ControlsFields::GlareCalculationDaylightingReferencePointName,
primaryReferencePoint.nameString());
daylightingControlObject.setDouble(Daylighting_ControlsFields::MinimumInputPowerFractionforContinuousorContinuousOffDimmingControl,
primaryDaylightingControl->minimumInputPowerFractionforContinuousDimmingControl());
daylightingControlObject.setDouble(Daylighting_ControlsFields::MinimumLightOutputFractionforContinuousorContinuousOffDimmingControl,
primaryDaylightingControl->minimumLightOutputFractionforContinuousDimmingControl());
daylightingControlObject.setInt(Daylighting_ControlsFields::NumberofSteppedControlSteps,
primaryDaylightingControl->numberofSteppedControlSteps());
daylightingControlObject.setDouble(Daylighting_ControlsFields::ProbabilityLightingwillbeResetWhenNeededinManualSteppedControl,
primaryDaylightingControl->probabilityLightingwillbeResetWhenNeededinManualSteppedControl());
}
};
translateDaylightingControls(modelObject);
// translate illuminance map
boost::optional<IlluminanceMap> illuminanceMap = modelObject.illuminanceMap();
if (illuminanceMap) {
if (!modelObject.primaryDaylightingControl()) {
LOG(Warn,
"Daylighting:Controls object is required to trigger daylighting calculations in EnergyPlus, adding a minimal one to Zone " << tzName);
IdfObject referencePoint(openstudio::IddObjectType::Daylighting_ReferencePoint);
referencePoint.setName(tzName + " Daylighting Reference Point");
m_idfObjects.push_back(referencePoint);
referencePoint.setString(Daylighting_ReferencePointFields::ZoneorSpaceName, tzName);
referencePoint.setDouble(Daylighting_ReferencePointFields::XCoordinateofReferencePoint,
illuminanceMap->originXCoordinate() + 0.5 * illuminanceMap->xLength());
referencePoint.setDouble(Daylighting_ReferencePointFields::YCoordinateofReferencePoint,
illuminanceMap->originYCoordinate() + 0.5 * illuminanceMap->yLength());
referencePoint.setDouble(Daylighting_ReferencePointFields::ZCoordinateofReferencePoint, illuminanceMap->originZCoordinate());
IdfObject daylightingControlObject(openstudio::IddObjectType::Daylighting_Controls);
// Name it like the Zone name + " DaylightingControls"
daylightingControlObject.setName(tzName + " DaylightingControls");
m_idfObjects.push_back(daylightingControlObject);
daylightingControlObject.setString(Daylighting_ControlsFields::ZoneorSpaceName, tzName);
std::vector<std::string> group{referencePoint.nameString(), // ref point name
"0.0", // fraction controlled
""}; // illuminance setpoint
daylightingControlObject.pushExtensibleGroup(group);
}
// TODO: move this to its own file
auto translateIlluminanceMap = [this](model::IlluminanceMap& illuminanceMap) -> IdfObject {
IdfObject illuminanceMapObject = createRegisterAndNameIdfObject(openstudio::IddObjectType::Output_IlluminanceMap, illuminanceMap);
illuminanceMapObject.setDouble(Output_IlluminanceMapFields::Zheight, illuminanceMap.originZCoordinate());
illuminanceMapObject.setDouble(Output_IlluminanceMapFields::XMinimumCoordinate, illuminanceMap.originXCoordinate());
illuminanceMapObject.setDouble(Output_IlluminanceMapFields::XMaximumCoordinate,
illuminanceMap.originXCoordinate() + illuminanceMap.xLength());
illuminanceMapObject.setInt(Output_IlluminanceMapFields::NumberofXGridPoints, illuminanceMap.numberofXGridPoints());
illuminanceMapObject.setDouble(Output_IlluminanceMapFields::YMinimumCoordinate, illuminanceMap.originYCoordinate());
illuminanceMapObject.setDouble(Output_IlluminanceMapFields::YMaximumCoordinate,
illuminanceMap.originYCoordinate() + illuminanceMap.yLength());
illuminanceMapObject.setInt(Output_IlluminanceMapFields::NumberofYGridPoints, illuminanceMap.numberofYGridPoints());
if (illuminanceMap.psiRotationAroundXAxis() != 0.0) {
LOG(Warn, "Rotation of " << illuminanceMap.psiRotationAroundXAxis() << " degrees about X axis not mapped for OS:IlluminanceMap "
<< illuminanceMap.nameString());
}
if (illuminanceMap.thetaRotationAroundYAxis() != 0.0) {
LOG(Warn, "Rotation of " << illuminanceMap.thetaRotationAroundYAxis() << " degrees about Y axis not mapped for OS:IlluminanceMap "
<< illuminanceMap.nameString());
}
if (illuminanceMap.phiRotationAroundZAxis() != 0.0) {
LOG(Warn, "Rotation of " << illuminanceMap.phiRotationAroundZAxis() << " degrees about Z axis not mapped for OS:IlluminanceMap "
<< illuminanceMap.nameString());
}
return illuminanceMapObject;
};
auto illuminanceMapObject = translateIlluminanceMap(illuminanceMap.get());
illuminanceMapObject.setString(Output_IlluminanceMapFields::ZoneName, tzName);
}
// TODO: this is definitely shared between both paths
// translate zone mixing objects which supply air to this zone
ZoneMixingVector supplyZoneMixing = modelObject.supplyZoneMixing();
std::sort(supplyZoneMixing.begin(), supplyZoneMixing.end(), WorkspaceObjectNameLess());
for (ZoneMixing& mixing : supplyZoneMixing) {
translateAndMapModelObject(mixing);
}
auto zoneEquipment = modelObject.equipment();
// In OS ZoneVentilationDesignFlowRate and ZoneVentilationWindandStackOpenArea are considered zone equipment,
// but for the E+ perspective it is not so we have to remove them and treat them differently.
auto isZoneVentilationObject = [](const ModelObject& mo) {
return ((mo.iddObjectType() == ZoneVentilationDesignFlowRate::iddObjectType())
|| (mo.iddObjectType() == ZoneVentilationWindandStackOpenArea::iddObjectType()));
};
std::vector<model::ModelObject> zoneVentilationObjects;
std::copy_if(zoneEquipment.begin(), zoneEquipment.end(), std::back_inserter(zoneVentilationObjects), isZoneVentilationObject);
auto zoneVentilationBegin = std::remove_if(zoneEquipment.begin(), zoneEquipment.end(), isZoneVentilationObject);
zoneEquipment.erase(zoneVentilationBegin, zoneEquipment.end());
// translate thermostat and/or humidistat
if ((!zoneEquipment.empty()) || modelObject.useIdealAirLoads()) {
// Thermostat
if (auto thermostat = modelObject.thermostat()) {
if (thermostat->iddObjectType() == ZoneControlThermostatStagedDualSetpoint::iddObjectType()) {
// This one we translate already
translateAndMapModelObject(thermostat.get());
} else {
// This is a OS:ThermostatSetpoint:DualSetpoint as it's the only other choice.
auto dualSetpoint = thermostat->cast<ThermostatSetpointDualSetpoint>();
auto createZoneControlThermostat = [&]() {
IdfObject zoneControlThermostat(openstudio::IddObjectType::ZoneControl_Thermostat);
zoneControlThermostat.setString(ZoneControl_ThermostatFields::Name, tzName + " Thermostat");
zoneControlThermostat.setString(ZoneControl_ThermostatFields::ZoneorZoneListName, tzName);
m_idfObjects.push_back(zoneControlThermostat);
// Need to handle the control type base don thermostat type (1: Single heating, 2: single cooling, 4: Dual setpoint)
IdfObject scheduleCompact(openstudio::IddObjectType::Schedule_Compact);
scheduleCompact.setName(tzName + " Thermostat Schedule");
m_idfObjects.push_back(scheduleCompact);
scheduleCompact.setString(1, tzName + " Thermostat Schedule Type Limits");
scheduleCompact.setString(2, "Through: 12/31");
scheduleCompact.setString(3, "For: AllDays");
scheduleCompact.setString(4, "Until: 24:00");
scheduleCompact.setString(5, "4");
IdfObject scheduleTypeLimits(openstudio::IddObjectType::ScheduleTypeLimits);
scheduleTypeLimits.setName(tzName + " Thermostat Schedule Type Limits");
m_idfObjects.push_back(scheduleTypeLimits);
scheduleTypeLimits.setString(1, "0");
scheduleTypeLimits.setString(2, "4");
scheduleTypeLimits.setString(3, "DISCRETE");
zoneControlThermostat.setString(ZoneControl_ThermostatFields::ControlTypeScheduleName, scheduleCompact.nameString());
if (boost::optional<IdfObject> idfThermostat = translateAndMapModelObject(dualSetpoint)) {
// TODO: JM 2019-09-04 switch back to an extensible object once/if https://github.com/NREL/EnergyPlus/issues/7484 is addressed and the
// 'Temperature Difference Between Cutout And Setpoint' field is moved before the extensible fields
// For now, we revert to a non extensible object, so we can still write that field
//StringVector values(zoneControlThermostat.iddObject().properties().numExtensible);
//values[ZoneControl_ThermostatExtensibleFields::ControlObjectType] = idfThermostat->iddObject().name();
//values[ZoneControl_ThermostatExtensibleFields::ControlName] = idfThermostat->nameString();
//IdfExtensibleGroup eg = zoneControlThermostat.pushExtensibleGroup(values);
zoneControlThermostat.setString(ZoneControl_ThermostatFields::Control1ObjectType, idfThermostat->iddObject().name());
zoneControlThermostat.setString(ZoneControl_ThermostatFields::Control1Name, idfThermostat->nameString());
if (idfThermostat->iddObject().name() == "ThermostatSetpoint:SingleHeating") {
scheduleCompact.setString(5, "1");
} else if (idfThermostat->iddObject().name() == "ThermostatSetpoint:SingleCooling") {
scheduleCompact.setString(5, "2");
} else {
// DualSetpoint
scheduleCompact.setString(5, "4");
}
// Thermostat's Temperature Difference Between Cutout And Setpoint is placed here on the ZoneControl:Thermostat
zoneControlThermostat.setDouble(ZoneControl_ThermostatFields::TemperatureDifferenceBetweenCutoutAndSetpoint,
dualSetpoint.temperatureDifferenceBetweenCutoutAndSetpoint());
}
};
// Only translate ThermostatSetpointDualSetpoint if there is at least one schedule attached
// The translation to SingleHeating, SingleCooling, or DualSetpoint as appropriate is handled in ForwardTranslateThermostatSetpointDualSetpoint
if (dualSetpoint.heatingSetpointTemperatureSchedule() || dualSetpoint.coolingSetpointTemperatureSchedule()) {
createZoneControlThermostat();
}
}
}
// Humidistat
if (boost::optional<ZoneControlHumidistat> humidistat = modelObject.zoneControlHumidistat()) {
if (boost::optional<IdfObject> idfHumidistat = translateAndMapModelObject(humidistat.get())) {
idfHumidistat->setString(ZoneControl_HumidistatFields::ZoneName, tzName);
}
}
// ZoneControlContaminantController
if (auto controller = modelObject.zoneControlContaminantController()) {
translateAndMapModelObject(controller.get());
}
}
// Ideal air loads
if (modelObject.useIdealAirLoads()) {
auto& idealLoadsAirSystem = m_idfObjects.emplace_back(IddObjectType::HVACTemplate_Zone_IdealLoadsAirSystem);
idealLoadsAirSystem.setString(HVACTemplate_Zone_IdealLoadsAirSystemFields::ZoneName, tzName);
}
// ZoneVentilationDesignFlowRate and ZoneVentilationWindandStackOpenArea do not go on equipment connections or associated list
for (auto& zone_vent : zoneVentilationObjects) {
translateAndMapModelObject(zone_vent);
}
bool zoneHVACIdealWorkaround = false;
boost::optional<ZoneHVACIdealLoadsAirSystem> ideal;
if (zoneEquipment.size() == 1) {
ideal = zoneEquipment.front().optionalCast<model::ZoneHVACIdealLoadsAirSystem>();
if (ideal) {
auto returnPlenum = ideal->returnPlenum();
if (returnPlenum) {
auto allIdealHVAC = returnPlenum->getImpl<model::detail::AirLoopHVACReturnPlenum_Impl>()->zoneHVACIdealLoadsAirSystems();
if (!allIdealHVAC.empty()) {
zoneHVACIdealWorkaround = true;
}
}
}
}
if (zoneHVACIdealWorkaround) {
// ZoneHVAC_EquipmentConnections
IdfObject connectionsObject(openstudio::IddObjectType::ZoneHVAC_EquipmentConnections);
m_idfObjects.push_back(connectionsObject);
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneName, tzName);
//set the inlet port list
PortList inletPortList = modelObject.inletPortList();
if (!inletPortList.modelObjects().empty()) {
boost::optional<IdfObject> _inletNodeList = translateAndMapModelObject(inletPortList);
if (_inletNodeList) {
_inletNodeList->setName(tzName + " Inlet Node List");
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneAirInletNodeorNodeListName, _inletNodeList->nameString());
}
}
//set the zone air node
Node node = modelObject.zoneAirNode();
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneAirNodeName, node.nameString());
// Use the exhaust node as the zone return node in this workaround
//set the zone return air node
auto exhaustPortList = modelObject.exhaustPortList();
auto exhaustNodes = subsetCastVector<model::Node>(exhaustPortList.modelObjects());
OS_ASSERT(exhaustNodes.size() == 1);
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneReturnAirNodeorNodeListName,
exhaustNodes.front().nameString());
// ZoneHVAC_EquipmentList
ZoneHVACEquipmentList equipmentList = modelObject.getImpl<model::detail::ThermalZone_Impl>()->zoneHVACEquipmentList();
boost::optional<IdfObject> _equipmentList = translateAndMapModelObject(equipmentList);
if (_equipmentList) {
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneConditioningEquipmentListName, _equipmentList->nameString());
}
} else if (!zoneEquipment.empty()) {
// ZoneHVAC_EquipmentConnections
IdfObject connectionsObject(openstudio::IddObjectType::ZoneHVAC_EquipmentConnections);
m_idfObjects.push_back(connectionsObject);
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneName, tzName);
//set the inlet port list
PortList inletPortList = modelObject.inletPortList();
if (!inletPortList.modelObjects().empty()) {
boost::optional<IdfObject> _inletNodeList = translateAndMapModelObject(inletPortList);
if (_inletNodeList) {
_inletNodeList->setName(tzName + " Inlet Node List");
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneAirInletNodeorNodeListName, _inletNodeList->nameString());
}
}
//set the exhaust port list
PortList exhaustPortList = modelObject.exhaustPortList();
if (!exhaustPortList.modelObjects().empty()) {
boost::optional<IdfObject> _exhaustNodeList = translateAndMapModelObject(exhaustPortList);
if (_exhaustNodeList) {
_exhaustNodeList->setName(tzName + " Exhaust Node List");
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneAirExhaustNodeorNodeListName,
_exhaustNodeList->nameString());
}
}
//set the zone air node
Node node = modelObject.zoneAirNode();
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneAirNodeName, node.nameString());
//set the zone return air node
auto returnPortList = modelObject.returnPortList();
if (!returnPortList.modelObjects().empty()) {
auto _returnNodeList = translateAndMapModelObject(returnPortList);
if (_returnNodeList) {
_returnNodeList->setName(tzName + " Return Node List");
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneReturnAirNodeorNodeListName,
_returnNodeList->nameString());
}
}
// ZoneHVAC_EquipmentList
ZoneHVACEquipmentList equipmentList = modelObject.getImpl<model::detail::ThermalZone_Impl>()->zoneHVACEquipmentList();
boost::optional<IdfObject> _equipmentList = translateAndMapModelObject(equipmentList);
if (_equipmentList) {
connectionsObject.setString(openstudio::ZoneHVAC_EquipmentConnectionsFields::ZoneConditioningEquipmentListName, _equipmentList->nameString());
}
}
// SizingZone
if ((!zoneEquipment.empty()) || modelObject.useIdealAirLoads()) {
// get sizing period objects from the model
std::vector<SizingPeriod> sizingPeriod = modelObject.model().getModelObjects<SizingPeriod>();
// map the sizing object only if a sizing period object exists
boost::optional<IdfObject> sizingZoneIdf;
if (!sizingPeriod.empty()) {
SizingZone sizingZone = modelObject.sizingZone();
sizingZoneIdf = translateAndMapModelObject(sizingZone);
OS_ASSERT(sizingZoneIdf);
}
boost::optional<IdfObject> dsoaList;
bool needToRegisterDSOAList = false;
bool atLeastOneDSOAWasWritten = true;
if (!m_excludeSpaceTranslation && sizingZoneIdf) {
// DO not register it yet! E+ will crash if the DSOA Space List ends up empty
dsoaList = IdfObject(openstudio::IddObjectType::DesignSpecification_OutdoorAir_SpaceList);
needToRegisterDSOAList = true;
atLeastOneDSOAWasWritten = false;
dsoaList->setName(tzName + " DSOA Space List");
}
// map the design specification outdoor air
boost::optional<DesignSpecificationOutdoorAir> designSpecificationOutdoorAir;
// For the ZoneVentilation workaround
bool createZvs = false;
double zvRateForPeople = 0.0;
double zvRateForArea = 0.0;
double zvRate = 0.0;
double zvRateForVolume = 0.0;
double totVolume = 0.0;
for (const Space& space : spaces) {
designSpecificationOutdoorAir = space.designSpecificationOutdoorAir();
if (designSpecificationOutdoorAir) {
// TODO: We definitely need to do something here...
// TODO: this isn't good. We also need to check the SpaceType-level DSOA...
boost::optional<IdfObject> thisDSOA = translateAndMapModelObject(*designSpecificationOutdoorAir);
if (sizingZoneIdf) {
if (m_excludeSpaceTranslation) {
// point the sizing object to the outdoor air spec
sizingZoneIdf->setString(Sizing_ZoneFields::DesignSpecificationOutdoorAirObjectName, designSpecificationOutdoorAir->nameString());
} else {
if (needToRegisterDSOAList) {
m_idfObjects.emplace_back(dsoaList.get());
sizingZoneIdf->setString(Sizing_ZoneFields::DesignSpecificationOutdoorAirObjectName, dsoaList->nameString());
needToRegisterDSOAList = false;
}
// push an extensible group on the DSOA:SpaceList
dsoaList->pushExtensibleGroup(std::vector<std::string>{space.nameString(), thisDSOA->nameString()});
atLeastOneDSOAWasWritten = true;
}
}
// create zone ventilation if needed
// TODO: we could remove all this code if we used ZoneHVAC:IdealLoadsAirSystem instead of HVACTemplate:Zone:IdealLoadsAirSystem
// We have space level stuff, that we need to write at Zone-level. So we compute the rate for each component (per Person, Floor Area,