/*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Header: FGGasCell.h Author: Anders Gidenstam Date started: 01/21/2006 ----- Copyright (C) 2006 - 2008 Anders Gidenstam (anders(at)gidenstam.org) -- This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. Further information about the GNU Lesser General Public License can also be found on the world wide web at http://www.gnu.org. FUNCTIONAL DESCRIPTION -------------------------------------------------------------------------------- See header file. HISTORY -------------------------------------------------------------------------------- 01/21/2006 AG Created %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% INCLUDES %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/ #include "FGFDMExec.h" #include "models/FGAuxiliary.h" #include "models/FGAtmosphere.h" #include "models/FGInertial.h" #include "models/FGMassBalance.h" #include "FGGasCell.h" #include "input_output/FGXMLElement.h" #include #include using std::cerr; using std::endl; using std::cout; using std::string; using std::max; namespace JSBSim { static const char *IdSrc = "$Id$"; static const char *IdHdr = ID_GASCELL; /*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% CLASS IMPLEMENTATION %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/ /* Constants. */ const double FGGasCell::R = 3.4071; // [lbs ft/(mol Rankine)] const double FGGasCell::M_air = 0.0019186; // [slug/mol] const double FGGasCell::M_hydrogen = 0.00013841; // [slug/mol] const double FGGasCell::M_helium = 0.00027409; // [slug/mol] FGGasCell::FGGasCell(FGFDMExec* exec, Element* el, int num) : FGForce(exec) { string token; Element* element; Auxiliary = exec->GetAuxiliary(); Atmosphere = exec->GetAtmosphere(); PropertyManager = exec->GetPropertyManager(); Inertial = exec->GetInertial(); MassBalance = exec->GetMassBalance(); gasCellJ = FGMatrix33(); gasCellM = FGColumnVector3(); Buoyancy = MaxVolume = MaxOverpressure = Temperature = Pressure = Contents = Volume = dVolumeIdeal = 0.0; Xradius = Yradius = Zradius = Xwidth = Ywidth = Zwidth = 0.0; ValveCoefficient = ValveOpen = 0.0; CellNum = num; // NOTE: In the local system X points north, Y points east and Z points down. SetTransformType(FGForce::tLocalBody); type = el->GetAttributeValue("type"); if (type == "HYDROGEN") Type = ttHYDROGEN; else if (type == "HELIUM") Type = ttHELIUM; else if (type == "AIR") Type = ttAIR; else Type = ttUNKNOWN; element = el->FindElement("location"); if (element) { vXYZ = element->FindElementTripletConvertTo("IN"); } else { cerr << "Fatal Error: No location found for this gas cell." << endl; exit(-1); } if ((el->FindElement("x_radius") || el->FindElement("x_width")) && (el->FindElement("y_radius") || el->FindElement("y_width")) && (el->FindElement("z_radius") || el->FindElement("z_width"))) { if (el->FindElement("x_radius")) { Xradius = el->FindElementValueAsNumberConvertTo("x_radius", "FT"); } if (el->FindElement("y_radius")) { Yradius = el->FindElementValueAsNumberConvertTo("y_radius", "FT"); } if (el->FindElement("z_radius")) { Zradius = el->FindElementValueAsNumberConvertTo("z_radius", "FT"); } if (el->FindElement("x_width")) { Xwidth = el->FindElementValueAsNumberConvertTo("x_width", "FT"); } if (el->FindElement("y_width")) { Ywidth = el->FindElementValueAsNumberConvertTo("y_width", "FT"); } if (el->FindElement("z_width")) { Zwidth = el->FindElementValueAsNumberConvertTo("z_width", "FT"); } // The volume is a (potentially) extruded ellipsoid. // However, currently only a few combinations of radius and width are // fully supported. if ((Xradius != 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth == 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Ellipsoid volume. MaxVolume = 4.0 * M_PI * Xradius * Yradius * Zradius / 3.0; } else if ((Xradius == 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth != 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Cylindrical volume. MaxVolume = M_PI * Yradius * Zradius * Xwidth; } else { cerr << "Warning: Unsupported gas cell shape." << endl; MaxVolume = (4.0 * M_PI * Xradius * Yradius * Zradius / 3.0 + M_PI * Yradius * Zradius * Xwidth + M_PI * Xradius * Zradius * Ywidth + M_PI * Xradius * Yradius * Zwidth + 2.0 * Xradius * Ywidth * Zwidth + 2.0 * Yradius * Xwidth * Zwidth + 2.0 * Zradius * Xwidth * Ywidth + Xwidth * Ywidth * Zwidth); } } else { cerr << "Fatal Error: Gas cell shape must be given." << endl; exit(-1); } if (el->FindElement("max_overpressure")) { MaxOverpressure = el->FindElementValueAsNumberConvertTo("max_overpressure", "LBS/FT2"); } if (el->FindElement("fullness")) { const double Fullness = el->FindElementValueAsNumber("fullness"); if (0 <= Fullness) { Volume = Fullness * MaxVolume; } else { cerr << "Warning: Invalid initial gas cell fullness value." << endl; } } if (el->FindElement("valve_coefficient")) { ValveCoefficient = el->FindElementValueAsNumberConvertTo("valve_coefficient", "FT4*SEC/SLUG"); ValveCoefficient = max(ValveCoefficient, 0.0); } // Initialize state SetLocation(vXYZ); if (Temperature == 0.0) { Temperature = Atmosphere->GetTemperature(); } if (Pressure == 0.0) { Pressure = Atmosphere->GetPressure(); } if (Volume != 0.0) { // Calculate initial gas content. Contents = Pressure * Volume / (R * Temperature); // Clip to max allowed value. const double IdealPressure = Contents * R * Temperature / MaxVolume; if (IdealPressure > Pressure + MaxOverpressure) { Contents = (Pressure + MaxOverpressure) * MaxVolume / (R * Temperature); Pressure = Pressure + MaxOverpressure; } else { Pressure = max(IdealPressure, Pressure); } } else { // Calculate initial gas content. Contents = Pressure * MaxVolume / (R * Temperature); } Volume = Contents * R * Temperature / Pressure; Mass = Contents * M_gas(); // Bind relevant properties string property_name, base_property_name; base_property_name = CreateIndexedPropertyName("buoyant_forces/gas-cell", CellNum); property_name = base_property_name + "/max_volume-ft3"; PropertyManager->Tie( property_name.c_str(), &MaxVolume ); PropertyManager->SetWritable( property_name, false ); property_name = base_property_name + "/temp-R"; PropertyManager->Tie( property_name.c_str(), &Temperature ); property_name = base_property_name + "/pressure-psf"; PropertyManager->Tie( property_name.c_str(), &Pressure ); property_name = base_property_name + "/volume-ft3"; PropertyManager->Tie( property_name.c_str(), &Volume ); property_name = base_property_name + "/buoyancy-lbs"; PropertyManager->Tie( property_name.c_str(), &Buoyancy ); property_name = base_property_name + "/contents-mol"; PropertyManager->Tie( property_name.c_str(), &Contents ); property_name = base_property_name + "/valve_open"; PropertyManager->Tie( property_name.c_str(), &ValveOpen ); Debug(0); // Read heat transfer coefficients if (Element* heat = el->FindElement("heat")) { Element* function_element = heat->FindElement("function"); while (function_element) { HeatTransferCoeff.push_back(new FGFunction(PropertyManager, function_element)); function_element = heat->FindNextElement("function"); } } // Load ballonets if there are any if (Element* ballonet_element = el->FindElement("ballonet")) { while (ballonet_element) { Ballonet.push_back(new FGBallonet(exec, ballonet_element, Ballonet.size(), this)); ballonet_element = el->FindNextElement("ballonet"); } } } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% FGGasCell::~FGGasCell() { unsigned int i; for (i = 0; i < HeatTransferCoeff.size(); i++) delete HeatTransferCoeff[i]; HeatTransferCoeff.clear(); for (i = 0; i < Ballonet.size(); i++) delete Ballonet[i]; Ballonet.clear(); Debug(1); } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% void FGGasCell::Calculate(double dt) { const double AirTemperature = Atmosphere->GetTemperature(); // [Rankine] const double AirPressure = Atmosphere->GetPressure(); // [lbs/ft˛] const double AirDensity = Atmosphere->GetDensity(); // [slug/ftł] const double g = Inertial->gravity(); // [lbs/slug] const double OldTemperature = Temperature; const double OldPressure = Pressure; unsigned int i; const unsigned int no_ballonets = Ballonet.size(); //-- Read ballonet state -- // NOTE: This model might need a more proper integration technique. double BallonetsVolume = 0.0; double BallonetsHeatFlow = 0.0; for (i = 0; i < no_ballonets; i++) { BallonetsVolume += Ballonet[i]->GetVolume(); BallonetsHeatFlow += Ballonet[i]->GetHeatFlow(); } //-- Gas temperature -- if (HeatTransferCoeff.size() > 0) { // The model is based on the ideal gas law. // However, it does look a bit fishy. Please verify. // dT/dt = dU / (Cv n R) double dU = 0.0; for (i = 0; i < HeatTransferCoeff.size(); i++) { dU += HeatTransferCoeff[i]->GetValue(); } // Don't include dt when accounting for adiabatic expansion/contraction. // The rate of adiabatic cooling looks about right: ~5.4 Rankine/1000ft. if (Contents > 0) { Temperature += (dU * dt - Pressure * dVolumeIdeal - BallonetsHeatFlow) / (Cv_gas() * Contents * R); } else { Temperature = AirTemperature; } } else { // No simulation of complex temperature changes. // Note: Making the gas cell behave adiabatically might be a better // option. Temperature = AirTemperature; } //-- Pressure -- const double IdealPressure = Contents * R * Temperature / (MaxVolume - BallonetsVolume); if (IdealPressure > AirPressure + MaxOverpressure) { Pressure = AirPressure + MaxOverpressure; } else { Pressure = max(IdealPressure, AirPressure); } //-- Manual valving -- // FIXME: Presently the effect of manual valving is computed using // an ad hoc formula which might not be a good representation // of reality. if ((ValveCoefficient > 0.0) && (ValveOpen > 0.0)) { // First compute the difference in pressure between the gas in the // cell and the air above it. // FixMe: CellHeight should depend on current volume. const double CellHeight = 2 * Zradius + Zwidth; // [ft] const double GasMass = Contents * M_gas(); // [slug] const double GasVolume = Contents * R * Temperature / Pressure; // [ftł] const double GasDensity = GasMass / GasVolume; const double DeltaPressure = Pressure + CellHeight * g * (AirDensity - GasDensity) - AirPressure; const double VolumeValved = ValveOpen * ValveCoefficient * DeltaPressure * dt; Contents = max(0.0, Contents - Pressure * VolumeValved / (R * Temperature)); } //-- Update ballonets. -- // Doing that here should give them the opportunity to react to the // new pressure. BallonetsVolume = 0.0; for (i = 0; i < no_ballonets; i++) { Ballonet[i]->Calculate(dt); BallonetsVolume += Ballonet[i]->GetVolume(); } //-- Automatic safety valving. -- if (Contents * R * Temperature / (MaxVolume - BallonetsVolume) > AirPressure + MaxOverpressure) { // Gas is automatically valved. Valving capacity is assumed to be infinite. // FIXME: This could/should be replaced by damage to the gas cell envelope. Contents = (AirPressure + MaxOverpressure) * (MaxVolume - BallonetsVolume) / (R * Temperature); } //-- Volume -- Volume = Contents * R * Temperature / Pressure + BallonetsVolume; dVolumeIdeal = Contents * R * (Temperature / Pressure - OldTemperature / OldPressure); //-- Current buoyancy -- // The buoyancy is computed using the atmospheres local density. Buoyancy = Volume * AirDensity * g; // Note: This is gross buoyancy. The weight of the gas itself and // any ballonets is not deducted here as the effects of the gas mass // is handled by FGMassBalance. vFn.InitMatrix(0.0, 0.0, - Buoyancy); // Compute the inertia of the gas cell. // Consider the gas cell as a shape of uniform density. // FIXME: If the cell isn't ellipsoid or cylindrical the inertia will // be wrong. gasCellJ = FGMatrix33(); const double mass = Contents * M_gas(); double Ixx, Iyy, Izz; if ((Xradius != 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth == 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Ellipsoid volume. Ixx = (1.0 / 5.0) * mass * (Yradius*Yradius + Zradius*Zradius); Iyy = (1.0 / 5.0) * mass * (Xradius*Xradius + Zradius*Zradius); Izz = (1.0 / 5.0) * mass * (Xradius*Xradius + Yradius*Yradius); } else if ((Xradius == 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth != 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Cylindrical volume (might not be valid with an elliptical cross-section). Ixx = (1.0 / 2.0) * mass * Yradius * Zradius; Iyy = (1.0 / 4.0) * mass * Yradius * Zradius + (1.0 / 12.0) * mass * Xwidth * Xwidth; Izz = (1.0 / 4.0) * mass * Yradius * Zradius + (1.0 / 12.0) * mass * Xwidth * Xwidth; } else { // Not supported. Revert to pointmass model. Ixx = Iyy = Izz = 0.0; } // The volume is symmetric, so Ixy = Ixz = Iyz = 0. gasCellJ(1,1) = Ixx; gasCellJ(2,2) = Iyy; gasCellJ(3,3) = Izz; Mass = mass; gasCellM.InitMatrix(); gasCellM(eX) += GetXYZ(eX) * Mass*slugtolb; gasCellM(eY) += GetXYZ(eY) * Mass*slugtolb; gasCellM(eZ) += GetXYZ(eZ) * Mass*slugtolb; if (no_ballonets > 0) { // Add the mass, moment and inertia of any ballonets. const FGColumnVector3 p = MassBalance->StructuralToBody( GetXYZ() ); for (i = 0; i < no_ballonets; i++) { Mass += Ballonet[i]->GetMass(); // Add ballonet moments. gasCellM(eX) += Ballonet[i]->GetXYZ(eX) * Ballonet[i]->GetMass()*slugtolb; gasCellM(eY) += Ballonet[i]->GetXYZ(eY) * Ballonet[i]->GetMass()*slugtolb; gasCellM(eZ) += Ballonet[i]->GetXYZ(eZ) * Ballonet[i]->GetMass()*slugtolb; // Moments of inertia must be converted to the gas cell frame here. FGColumnVector3 v = MassBalance->StructuralToBody( Ballonet[i]->GetXYZ() ) - p; // Body basis is in FT. const double mass = Ballonet[i]->GetMass(); gasCellJ += Ballonet[i]->GetInertia() + FGMatrix33( 0, - mass*v(1)*v(2), - mass*v(1)*v(3), - mass*v(2)*v(1), 0, - mass*v(2)*v(3), - mass*v(3)*v(1), - mass*v(3)*v(2), 0 ); } } } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% // The bitmasked value choices are as follows: // unset: In this case (the default) JSBSim would only print // out the normally expected messages, essentially echoing // the config files as they are read. If the environment // variable is not set, debug_lvl is set to 1 internally // 0: This requests JSBSim not to output any messages // whatsoever. // 1: This value explicity requests the normal JSBSim // startup messages // 2: This value asks for a message to be printed out when // a class is instantiated // 4: When this value is set, a message is displayed when a // FGModel object executes its Run() method // 8: When this value is set, various runtime state variables // are printed out periodically // 16: When set various parameters are sanity checked and // a message is printed out when they go out of bounds void FGGasCell::Debug(int from) { if (debug_lvl <= 0) return; if (debug_lvl & 1) { // Standard console startup message output if (from == 0) { // Constructor cout << " Gas cell holds " << Contents << " mol " << type << endl; cout << " Cell location (X, Y, Z) (in.): " << vXYZ(eX) << ", " << vXYZ(eY) << ", " << vXYZ(eZ) << endl; cout << " Maximum volume: " << MaxVolume << " ft3" << endl; cout << " Relief valve release pressure: " << MaxOverpressure << " lbs/ft2" << endl; cout << " Manual valve coefficient: " << ValveCoefficient << " ft4*sec/slug" << endl; cout << " Initial temperature: " << Temperature << " Rankine" << endl; cout << " Initial pressure: " << Pressure << " lbs/ft2" << endl; cout << " Initial volume: " << Volume << " ft3" << endl; cout << " Initial mass: " << GetMass() << " slug mass" << endl; cout << " Initial weight: " << GetMass()*lbtoslug << " lbs force" << endl; cout << " Heat transfer: " << endl; } } if (debug_lvl & 2 ) { // Instantiation/Destruction notification if (from == 0) cout << "Instantiated: FGGasCell" << endl; if (from == 1) cout << "Destroyed: FGGasCell" << endl; } if (debug_lvl & 4 ) { // Run() method entry print for FGModel-derived objects } if (debug_lvl & 8 ) { // Runtime state variables cout << " " << type << " cell holds " << Contents << " mol " << endl; cout << " Temperature: " << Temperature << " Rankine" << endl; cout << " Pressure: " << Pressure << " lbs/ft2" << endl; cout << " Volume: " << Volume << " ft3" << endl; cout << " Mass: " << GetMass() << " slug mass" << endl; cout << " Weight: " << GetMass()*lbtoslug << " lbs force" << endl; } if (debug_lvl & 16) { // Sanity checking } if (debug_lvl & 64) { if (from == 0) { // Constructor cout << IdSrc << endl; cout << IdHdr << endl; } } } /*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% CLASS IMPLEMENTATION %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/ const double FGBallonet::R = 3.4071; // [lbs ft/(mol Rankine)] const double FGBallonet::M_air = 0.0019186; // [slug/mol] const double FGBallonet::Cv_air = 5.0/2.0; // [??] FGBallonet::FGBallonet(FGFDMExec* exec, Element* el, int num, FGGasCell* parent) { string token; Element* element; Auxiliary = exec->GetAuxiliary(); Atmosphere = exec->GetAtmosphere(); PropertyManager = exec->GetPropertyManager(); Inertial = exec->GetInertial(); ballonetJ = FGMatrix33(); MaxVolume = MaxOverpressure = Temperature = Pressure = Contents = Volume = dVolumeIdeal = dU = 0.0; Xradius = Yradius = Zradius = Xwidth = Ywidth = Zwidth = 0.0; ValveCoefficient = ValveOpen = 0.0; BlowerInput = NULL; CellNum = num; Parent = parent; // NOTE: In the local system X points north, Y points east and Z points down. element = el->FindElement("location"); if (element) { vXYZ = element->FindElementTripletConvertTo("IN"); } else { cerr << "Fatal Error: No location found for this ballonet." << endl; exit(-1); } if ((el->FindElement("x_radius") || el->FindElement("x_width")) && (el->FindElement("y_radius") || el->FindElement("y_width")) && (el->FindElement("z_radius") || el->FindElement("z_width"))) { if (el->FindElement("x_radius")) { Xradius = el->FindElementValueAsNumberConvertTo("x_radius", "FT"); } if (el->FindElement("y_radius")) { Yradius = el->FindElementValueAsNumberConvertTo("y_radius", "FT"); } if (el->FindElement("z_radius")) { Zradius = el->FindElementValueAsNumberConvertTo("z_radius", "FT"); } if (el->FindElement("x_width")) { Xwidth = el->FindElementValueAsNumberConvertTo("x_width", "FT"); } if (el->FindElement("y_width")) { Ywidth = el->FindElementValueAsNumberConvertTo("y_width", "FT"); } if (el->FindElement("z_width")) { Zwidth = el->FindElementValueAsNumberConvertTo("z_width", "FT"); } // The volume is a (potentially) extruded ellipsoid. // FIXME: However, currently only a few combinations of radius and // width are fully supported. if ((Xradius != 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth == 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Ellipsoid volume. MaxVolume = 4.0 * M_PI * Xradius * Yradius * Zradius / 3.0; } else if ((Xradius == 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth != 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Cylindrical volume. MaxVolume = M_PI * Yradius * Zradius * Xwidth; } else { cerr << "Warning: Unsupported ballonet shape." << endl; MaxVolume = (4.0 * M_PI * Xradius * Yradius * Zradius / 3.0 + M_PI * Yradius * Zradius * Xwidth + M_PI * Xradius * Zradius * Ywidth + M_PI * Xradius * Yradius * Zwidth + 2.0 * Xradius * Ywidth * Zwidth + 2.0 * Yradius * Xwidth * Zwidth + 2.0 * Zradius * Xwidth * Ywidth + Xwidth * Ywidth * Zwidth); } } else { cerr << "Fatal Error: Ballonet shape must be given." << endl; exit(-1); } if (el->FindElement("max_overpressure")) { MaxOverpressure = el->FindElementValueAsNumberConvertTo("max_overpressure", "LBS/FT2"); } if (el->FindElement("fullness")) { const double Fullness = el->FindElementValueAsNumber("fullness"); if (0 <= Fullness) { Volume = Fullness * MaxVolume; } else { cerr << "Warning: Invalid initial ballonet fullness value." << endl; } } if (el->FindElement("valve_coefficient")) { ValveCoefficient = el->FindElementValueAsNumberConvertTo("valve_coefficient", "FT4*SEC/SLUG"); ValveCoefficient = max(ValveCoefficient, 0.0); } // Initialize state if (Temperature == 0.0) { Temperature = Parent->GetTemperature(); } if (Pressure == 0.0) { Pressure = Parent->GetPressure(); } if (Volume != 0.0) { // Calculate initial air content. Contents = Pressure * Volume / (R * Temperature); // Clip to max allowed value. const double IdealPressure = Contents * R * Temperature / MaxVolume; if (IdealPressure > Pressure + MaxOverpressure) { Contents = (Pressure + MaxOverpressure) * MaxVolume / (R * Temperature); Pressure = Pressure + MaxOverpressure; } else { Pressure = max(IdealPressure, Pressure); } } else { // Calculate initial air content. Contents = Pressure * MaxVolume / (R * Temperature); } Volume = Contents * R * Temperature / Pressure; // Bind relevant properties string property_name, base_property_name; base_property_name = CreateIndexedPropertyName("buoyant_forces/gas-cell", Parent->GetIndex()); base_property_name = CreateIndexedPropertyName(base_property_name + "/ballonet", CellNum); property_name = base_property_name + "/max_volume-ft3"; PropertyManager->Tie( property_name, &MaxVolume ); PropertyManager->SetWritable( property_name, false ); property_name = base_property_name + "/temp-R"; PropertyManager->Tie( property_name, &Temperature ); property_name = base_property_name + "/pressure-psf"; PropertyManager->Tie( property_name, &Pressure ); property_name = base_property_name + "/volume-ft3"; PropertyManager->Tie( property_name, &Volume ); property_name = base_property_name + "/contents-mol"; PropertyManager->Tie( property_name, &Contents ); property_name = base_property_name + "/valve_open"; PropertyManager->Tie( property_name, &ValveOpen ); Debug(0); // Read heat transfer coefficients if (Element* heat = el->FindElement("heat")) { Element* function_element = heat->FindElement("function"); while (function_element) { HeatTransferCoeff.push_back(new FGFunction(PropertyManager, function_element)); function_element = heat->FindNextElement("function"); } } // Read blower input function if (Element* blower = el->FindElement("blower_input")) { Element* function_element = blower->FindElement("function"); BlowerInput = new FGFunction(PropertyManager, function_element); } } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% FGBallonet::~FGBallonet() { unsigned int i; for (i = 0; i < HeatTransferCoeff.size(); i++) delete HeatTransferCoeff[i]; HeatTransferCoeff.clear(); delete BlowerInput; BlowerInput = NULL; Debug(1); } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% void FGBallonet::Calculate(double dt) { const double ParentPressure = Parent->GetPressure(); // [lbs/ft˛] const double AirPressure = Atmosphere->GetPressure(); // [lbs/ft˛] const double OldTemperature = Temperature; const double OldPressure = Pressure; unsigned int i; //-- Gas temperature -- // The model is based on the ideal gas law. // However, it does look a bit fishy. Please verify. // dT/dt = dU / (Cv n R) dU = 0.0; for (i = 0; i < HeatTransferCoeff.size(); i++) { dU += HeatTransferCoeff[i]->GetValue(); } // dt is already accounted for in dVolumeIdeal. if (Contents > 0) { Temperature += (dU * dt - Pressure * dVolumeIdeal) / (Cv_air * Contents * R); } else { Temperature = Parent->GetTemperature(); } //-- Pressure -- const double IdealPressure = Contents * R * Temperature / MaxVolume; // The pressure is at least that of the parent gas cell. Pressure = max(IdealPressure, ParentPressure); //-- Blower input -- if (BlowerInput) { const double AddedVolume = BlowerInput->GetValue() * dt; if (AddedVolume > 0.0) { Contents += Pressure * AddedVolume / (R * Temperature); } } //-- Pressure relief and manual valving -- // FIXME: Presently the effect of valving is computed using // an ad hoc formula which might not be a good representation // of reality. if ((ValveCoefficient > 0.0) && ((ValveOpen > 0.0) || (Pressure > AirPressure + MaxOverpressure))) { const double DeltaPressure = Pressure - AirPressure; const double VolumeValved = ((Pressure > AirPressure + MaxOverpressure) ? 1.0 : ValveOpen) * ValveCoefficient * DeltaPressure * dt; // FIXME: Too small values of Contents sometimes leads to NaN. // Currently the minimum is restricted to a safe value. Contents = max(1.0, Contents - Pressure * VolumeValved / (R * Temperature)); } //-- Volume -- Volume = Contents * R * Temperature / Pressure; dVolumeIdeal = Contents * R * (Temperature / Pressure - OldTemperature / OldPressure); // Compute the inertia of the ballonet. // Consider the ballonet as a shape of uniform density. // FIXME: If the ballonet isn't ellipsoid or cylindrical the inertia will // be wrong. ballonetJ = FGMatrix33(); const double mass = Contents * M_air; double Ixx, Iyy, Izz; if ((Xradius != 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth == 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Ellipsoid volume. Ixx = (1.0 / 5.0) * mass * (Yradius*Yradius + Zradius*Zradius); Iyy = (1.0 / 5.0) * mass * (Xradius*Xradius + Zradius*Zradius); Izz = (1.0 / 5.0) * mass * (Xradius*Xradius + Yradius*Yradius); } else if ((Xradius == 0.0) && (Yradius != 0.0) && (Zradius != 0.0) && (Xwidth != 0.0) && (Ywidth == 0.0) && (Zwidth == 0.0)) { // Cylindrical volume (might not be valid with an elliptical cross-section). Ixx = (1.0 / 2.0) * mass * Yradius * Zradius; Iyy = (1.0 / 4.0) * mass * Yradius * Zradius + (1.0 / 12.0) * mass * Xwidth * Xwidth; Izz = (1.0 / 4.0) * mass * Yradius * Zradius + (1.0 / 12.0) * mass * Xwidth * Xwidth; } else { // Not supported. Revert to pointmass model. Ixx = Iyy = Izz = 0.0; } // The volume is symmetric, so Ixy = Ixz = Iyz = 0. ballonetJ(1,1) = Ixx; ballonetJ(2,2) = Iyy; ballonetJ(3,3) = Izz; } //%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% // The bitmasked value choices are as follows: // unset: In this case (the default) JSBSim would only print // out the normally expected messages, essentially echoing // the config files as they are read. If the environment // variable is not set, debug_lvl is set to 1 internally // 0: This requests JSBSim not to output any messages // whatsoever. // 1: This value explicity requests the normal JSBSim // startup messages // 2: This value asks for a message to be printed out when // a class is instantiated // 4: When this value is set, a message is displayed when a // FGModel object executes its Run() method // 8: When this value is set, various runtime state variables // are printed out periodically // 16: When set various parameters are sanity checked and // a message is printed out when they go out of bounds void FGBallonet::Debug(int from) { if (debug_lvl <= 0) return; if (debug_lvl & 1) { // Standard console startup message output if (from == 0) { // Constructor cout << " Ballonet holds " << Contents << " mol air" << endl; cout << " Location (X, Y, Z) (in.): " << vXYZ(eX) << ", " << vXYZ(eY) << ", " << vXYZ(eZ) << endl; cout << " Maximum volume: " << MaxVolume << " ft3" << endl; cout << " Relief valve release pressure: " << MaxOverpressure << " lbs/ft2" << endl; cout << " Relief valve coefficient: " << ValveCoefficient << " ft4*sec/slug" << endl; cout << " Initial temperature: " << Temperature << " Rankine" << endl; cout << " Initial pressure: " << Pressure << " lbs/ft2" << endl; cout << " Initial volume: " << Volume << " ft3" << endl; cout << " Initial mass: " << GetMass() << " slug mass" << endl; cout << " Initial weight: " << GetMass()*lbtoslug << " lbs force" << endl; cout << " Heat transfer: " << endl; } } if (debug_lvl & 2 ) { // Instantiation/Destruction notification if (from == 0) cout << "Instantiated: FGBallonet" << endl; if (from == 1) cout << "Destroyed: FGBallonet" << endl; } if (debug_lvl & 4 ) { // Run() method entry print for FGModel-derived objects } if (debug_lvl & 8 ) { // Runtime state variables cout << " Ballonet holds " << Contents << " mol air" << endl; cout << " Temperature: " << Temperature << " Rankine" << endl; cout << " Pressure: " << Pressure << " lbs/ft2" << endl; cout << " Volume: " << Volume << " ft3" << endl; cout << " Mass: " << GetMass() << " slug mass" << endl; cout << " Weight: " << GetMass()*lbtoslug << " lbs force" << endl; } if (debug_lvl & 16) { // Sanity checking } if (debug_lvl & 64) { if (from == 0) { // Constructor cout << IdSrc << endl; cout << IdHdr << endl; } } } }