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7 Commits
master ... Testing

Author SHA1 Message Date
grillkol
bc0df51ddb refactoring (broken right now) 2026-05-06 15:24:39 +02:00
maxwes08
bc4e077924 added valves display 2026-05-06 14:05:37 +02:00
grillkol
d6b1d214f5 tuff 2026-05-05 19:39:11 +02:00
grillkol
608dabff12 sound fixed 2026-05-05 16:10:06 +02:00
grillkol
547e8706f1 update 2026-05-05 14:02:07 +02:00
grillkol
f16a1aa763 insane engine sound 2026-05-05 11:24:32 +02:00
grillkol
d963032e74 General testing 2026-05-05 10:32:30 +02:00
29 changed files with 1591 additions and 1217 deletions
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26
.vscode/launch.json vendored Normal file
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@@ -0,0 +1,26 @@
{
"version": "0.2.0",
"configurations": [
{
// Use IntelliSense to find out which attributes exist for C# debugging
// Use hover for the description of the existing attributes
// For further information visit https://github.com/dotnet/vscode-csharp/blob/main/debugger-launchjson.md
"name": ".NET Core Launch (console)",
"type": "coreclr",
"request": "launch",
"preLaunchTask": "build",
// If you have changed target frameworks, make sure to update the program path.
"program": "${workspaceFolder}/bin/Debug/net10.0/FluidSim.dll",
"args": [],
"cwd": "${workspaceFolder}",
// For more information about the 'console' field, see https://aka.ms/VSCode-CS-LaunchJson-Console
"console": "internalConsole",
"stopAtEntry": false
},
{
"name": ".NET Core Attach",
"type": "coreclr",
"request": "attach"
}
]
}

41
.vscode/tasks.json vendored Normal file
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@@ -0,0 +1,41 @@
{
"version": "2.0.0",
"tasks": [
{
"label": "build",
"command": "dotnet",
"type": "process",
"args": [
"build",
"${workspaceFolder}/FluidSim.csproj",
"/property:GenerateFullPaths=true",
"/consoleloggerparameters:NoSummary;ForceNoAlign"
],
"problemMatcher": "$msCompile"
},
{
"label": "publish",
"command": "dotnet",
"type": "process",
"args": [
"publish",
"${workspaceFolder}/FluidSim.csproj",
"/property:GenerateFullPaths=true",
"/consoleloggerparameters:NoSummary;ForceNoAlign"
],
"problemMatcher": "$msCompile"
},
{
"label": "watch",
"command": "dotnet",
"type": "process",
"args": [
"watch",
"run",
"--project",
"${workspaceFolder}/FluidSim.csproj"
],
"problemMatcher": "$msCompile"
}
]
}

43
Components/Atmosphere.cs Normal file
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@@ -0,0 +1,43 @@
using FluidSim.Interfaces;
namespace FluidSim.Components
{
/// <summary>
/// Represents the ambient atmosphere constant pressure/temperature reservoir.
/// </summary>
public class Atmosphere : IComponent
{
public double Pressure { get; set; } = 101325.0;
public double Temperature { get; set; } = 300.0;
public double GasConstant { get; set; } = 287.0;
public double Gamma => 1.4;
public double Density => Pressure / (GasConstant * Temperature);
public double SpecificEnthalpy => Gamma / (Gamma - 1.0) * Pressure / Density;
public Port Port { get; }
public Atmosphere()
{
Port = new Port { Owner = this };
UpdatePort();
}
public IReadOnlyList<Port> Ports => new[] { Port };
public void UpdateState(double dt)
{
// Atmosphere is static just ensure the port reflects current values
UpdatePort();
}
private void UpdatePort()
{
Port.Pressure = Pressure;
Port.Density = Density;
Port.Temperature = Temperature;
Port.SpecificEnthalpy = SpecificEnthalpy;
// MassFlowRate is set by the solver connector
}
}
}

54
Components/Crankshaft.cs Normal file
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@@ -0,0 +1,54 @@
// Components/Crankshaft.cs
using System;
namespace FluidSim.Components
{
public class Crankshaft
{
public double AngularVelocity { get; set; } // rad/s
public double CrankAngle { get; set; } // rad, 0 … 4π (fourstroke cycle)
public double PreviousAngle { get; set; } // ← now has public setter
public double Inertia { get; set; } = 0.2;
public double FrictionConstant { get; set; } = 2.0; // N·m
public double FrictionViscous { get; set; } = 0.005; // N·m per rad/s
private double externalTorque;
public Crankshaft(double initialRPM = 400.0)
{
AngularVelocity = initialRPM * 2.0 * Math.PI / 60.0;
CrankAngle = 0.0;
PreviousAngle = 0.0;
}
public void AddTorque(double torque) => externalTorque += torque;
public void Step(double dt)
{
// Catch NaN before it propagates
if (double.IsNaN(AngularVelocity) || double.IsInfinity(AngularVelocity))
AngularVelocity = 0.0;
if (double.IsNaN(externalTorque) || double.IsInfinity(externalTorque))
externalTorque = 0.0;
PreviousAngle = CrankAngle;
double friction = FrictionConstant * Math.Sign(AngularVelocity) + FrictionViscous * AngularVelocity;
double netTorque = externalTorque - friction;
double alpha = netTorque / Inertia;
AngularVelocity += alpha * dt;
if (AngularVelocity < 0) AngularVelocity = 0;
CrankAngle += AngularVelocity * dt;
if (CrankAngle >= 4.0 * Math.PI)
CrankAngle -= 4.0 * Math.PI;
else if (CrankAngle < 0)
CrankAngle += 4.0 * Math.PI;
externalTorque = 0.0;
}
}
}

46
Components/Nozzleflow.cs Normal file
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@@ -0,0 +1,46 @@
using System;
namespace FluidSim.Components
{
public static class NozzleFlow
{
/// <summary>
/// Computes the nozzleexit primitive state and mass flow rate from a
/// volume to a pipe, using isentropic relations. Follows ensim4's flow() logic.
/// </summary>
public static void Compute(double Pt_high, double Tt_high,
double P_low, double gamma, double R, double area,
out double rhoExit, out double uExit,
out double pExit, out double mdot)
{
double gm1 = gamma - 1.0;
double Pt_over_Ps = Pt_high / P_low;
// Mach number (subsonic, clamped to 1)
double M = Math.Sqrt(Math.Max(0.0,
(2.0 / gm1) * (Math.Pow(Pt_over_Ps, gm1 / gamma) - 1.0)));
if (M > 1.0) M = 1.0;
double T_star = Tt_high / (1.0 + 0.5 * gm1 * M * M);
double a_star = Math.Sqrt(gamma * R * T_star);
double u_star = M * a_star;
pExit = Pt_high * Math.Pow(1.0 + 0.5 * gm1 * M * M, -gamma / gm1);
rhoExit = pExit / (R * T_star);
uExit = u_star; // positive away from highpressure side
mdot = rhoExit * uExit * area;
}
/// <summary>
/// Ambient cell for nonreflecting open end (ensim4 calc_ambient_cell).
/// </summary>
public static void ComputeAmbientCell(double rhoInt, double uInt, double pInt,
double pAmbient, double gamma,
out double rhoAmb, out double uAmb,
out double pAmb)
{
pAmb = pAmbient;
uAmb = uInt;
rhoAmb = rhoInt * Math.Pow(pAmb / pInt, 1.0 / gamma);
}
}
}

538
Components/Pipe1D.cs
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@@ -3,130 +3,159 @@ using FluidSim.Interfaces;
namespace FluidSim.Components
{
public enum BoundaryType
{
VolumeCoupling,
OpenEnd,
ClosedEnd
}
public class Pipe1D
/// <summary>
/// 1D compressible Euler pipe (finitevolume, HLLC flux).
/// Boundary conditions are set externally via SetGhostLeft/Right.
/// Enforces that ghosts are always valid before stepping.
/// Uses exponential damping and Newtonian energy relaxation.
/// </summary>
public class Pipe1D : IComponent
{
public Port PortA { get; }
public Port PortB { get; }
public double Area => _area;
public double Area { get; }
public double DampingMultiplier { get; set; } = 1.0;
public double EnergyRelaxationRate { get; set; } = 0.0; // 1/s
private int _n;
private double _dx, _dt, _gamma, _area, _diameter;
private double[] _rho, _rhou, _E;
// Volumecoupling ghost states for boundaries A and B
private double _rhoA, _pA;
private double _rhoB, _pB;
private bool _aBCSet, _bBCSet;
private BoundaryType _aBCType = BoundaryType.VolumeCoupling;
private BoundaryType _bBCType = BoundaryType.VolumeCoupling;
private double _aAmbientPressure = 101325.0;
private double _bAmbientPressure = 101325.0;
private const double CflTarget = 0.8;
private const double ReferenceSoundSpeed = 340.0;
public int GetCellCount() => _n;
public double GetCellDensity(int i) => _rho[i];
public double GetCellPressure(int i) => Pressure(i);
public double GetCellVelocity(int i) => _rhou[i] / Math.Max(_rho[i], 1e-12);
public BoundaryType ABCType => _aBCType;
public BoundaryType BBCType => _bBCType;
public Pipe1D(double length, double area, int sampleRate, int forcedCellCount = 0)
// Ambient pressure for the energy relaxation term (default 101325 Pa)
private double _ambientPressure = 101325.0;
public double AmbientPressure
{
double dtGlobal = 1.0 / sampleRate;
int nCells;
if (forcedCellCount > 1)
get => _ambientPressure;
set
{
nCells = forcedCellCount;
_ambientPressure = value;
_ambientEnergyReference = value / (_gamma - 1.0);
}
else
{
double dxTarget = ReferenceSoundSpeed * dtGlobal * CflTarget;
nCells = Math.Max(2, (int)Math.Round(length / dxTarget, MidpointRounding.AwayFromZero));
while (length / nCells > dxTarget * 1.01 && nCells < int.MaxValue - 1)
nCells++;
}
_n = nCells;
// Geometry
private readonly int _n; // number of real cells
private readonly double _dx; // cell size (m)
private readonly double _diameter; // m
private readonly double _gamma = 1.4;
// Conserved variables [0 .. _n-1]
private double[] _rho;
private double[] _rhou;
private double[] _E;
// Face fluxes [0 .. _n]
private double[] _fluxM;
private double[] _fluxP;
private double[] _fluxE;
// Ghost cells (set externally)
private double _rhoGhostL, _uGhostL, _pGhostL;
private double _rhoGhostR, _uGhostR, _pGhostR;
private bool _ghostLValid, _ghostRValid;
// Precomputed damping coefficient
private double _laminarCoeff;
private double _ambientEnergyReference; // internal energy density at ambient pressure
/// <summary>
/// Initialise a pipe with a given cell count.
/// </summary>
/// <param name="length">Pipe length (m).</param>
/// <param name="area">Crosssectional area (m²).</param>
/// <param name="cellCount">Number of finitevolume cells (≥ 4).</param>
public Pipe1D(double length, double area, int cellCount)
{
if (cellCount < 4) throw new ArgumentException("cellCount must be at least 4");
_n = cellCount;
_dx = length / _n;
_dt = dtGlobal;
_area = area;
_gamma = 1.4;
// Hydraulic diameter for a circular pipe
Area = area;
_diameter = 2.0 * Math.Sqrt(area / Math.PI);
_rho = new double[_n];
_rhou = new double[_n];
_E = new double[_n];
PortA = new Port();
PortB = new Port();
_fluxM = new double[_n + 1];
_fluxP = new double[_n + 1];
_fluxE = new double[_n + 1];
// Laminar damping coefficient for air at 20°C (multiplied by DampingMultiplier each step)
double mu_air = 1.8e-5;
double radius = _diameter * 0.5;
_laminarCoeff = 8.0 * mu_air / (radius * radius);
// Ambient energy reference (internal energy per unit volume at 101325 Pa)
_ambientEnergyReference = 101325.0 / (_gamma - 1.0);
PortA = new Port { Owner = this };
PortB = new Port { Owner = this };
// Initial state = still air at ambient conditions
SetUniformState(1.225, 0.0, 101325.0);
}
public void SetABoundaryType(BoundaryType type) => _aBCType = type;
public void SetBBoundaryType(BoundaryType type) => _bBCType = type;
public void SetAAmbientPressure(double p) => _aAmbientPressure = p;
public void SetBAmbientPressure(double p) => _bAmbientPressure = p;
IReadOnlyList<Port> IComponent.Ports => new[] { PortA, PortB };
public void SetUniformState(double rho, double u, double p)
// No integration needed for pipes state is advanced via substeps
public void UpdateState(double dt) { }
// ---------- Ghost cell interface ----------
public void SetGhostLeft(double rho, double u, double p)
{
double e = p / ((_gamma - 1) * rho);
double Etot = rho * e + 0.5 * rho * u * u;
for (int i = 0; i < _n; i++)
_rhoGhostL = rho;
_uGhostL = u;
_pGhostL = p;
_ghostLValid = true;
}
public void SetGhostRight(double rho, double u, double p)
{
_rho[i] = rho;
_rhou[i] = rho * u;
_E[i] = Etot;
}
_rhoGhostR = rho;
_uGhostR = u;
_pGhostR = p;
_ghostRValid = true;
}
public void SetCellState(int i, double rho, double u, double p)
public void ClearGhostFlags()
{
if (i < 0 || i >= _n) return;
_rho[i] = rho;
_rhou[i] = rho * u;
double e = p / ((_gamma - 1) * rho);
_E[i] = rho * e + 0.5 * rho * u * u;
_ghostLValid = false;
_ghostRValid = false;
}
public void SetAVolumeState(double rhoVol, double pVol)
public (double rho, double u, double p) GetInteriorStateLeft()
{
_rhoA = rhoVol;
_pA = pVol;
_aBCSet = true;
double rho = Math.Max(_rho[0], 1e-12);
double u = _rhou[0] / rho;
double p = PressureScalar(0);
return (rho, u, p);
}
public void SetBVolumeState(double rhoVol, double pVol)
public (double rho, double u, double p) GetInteriorStateRight()
{
_rhoB = rhoVol;
_pB = pVol;
_bBCSet = true;
double rho = Math.Max(_rho[_n - 1], 1e-12);
double u = _rhou[_n - 1] / rho;
double p = PressureScalar(_n - 1);
return (rho, u, p);
}
public void ClearBC() => _aBCSet = _bBCSet = false;
public int CellCount => _n;
public double GetCellDensity(int i) => _rho[i];
public double GetCellVelocity(int i)
{
double rho = Math.Max(_rho[i], 1e-12);
return _rhou[i] / rho;
}
public double GetCellPressure(int i) => PressureScalar(i);
// ---------- Substepping ----------
public int GetRequiredSubSteps(double dtGlobal, double cflTarget = 0.8)
{
double maxW = 0.0;
for (int i = 0; i < _n; i++)
{
double rho = _rho[i];
double u = Math.Abs(_rhou[i] / Math.Max(rho, 1e-12));
double c = Math.Sqrt(_gamma * Pressure(i) / Math.Max(rho, 1e-12));
double rho = Math.Max(_rho[i], 1e-12);
double u = Math.Abs(_rhou[i] / rho);
double p = PressureScalar(i);
double c = Math.Sqrt(_gamma * p / rho);
double local = u + c;
if (local > maxW) maxW = local;
}
@@ -134,287 +163,156 @@ namespace FluidSim.Components
return Math.Max(1, (int)Math.Ceiling(dtGlobal * maxW / (cflTarget * _dx)));
}
// ---------- Main simulation step (per substep) ----------
public void SimulateSingleStep(double dtSub)
{
// Enforce that both ends have been provided with ghost states
if (!_ghostLValid || !_ghostRValid)
throw new InvalidOperationException("Pipe boundary ghosts not set before SimulateSingleStep.");
double dt = dtSub;
int n = _n;
double[] Fm = new double[n + 1];
double[] Fp = new double[n + 1];
double[] Fe = new double[n + 1];
// ---------- Boundary A (face 0, left) ----------
double rhoIntA = _rho[0];
double uIntA = _rhou[0] / Math.Max(rhoIntA, 1e-12);
double pIntA = Pressure(0);
// Left boundary face (index 0)
HLLCFlux(_rhoGhostL, _uGhostL, _pGhostL, _rho[0], _rhou[0] / _rho[0], PressureScalar(0),
out _fluxM[0], out _fluxP[0], out _fluxE[0]);
switch (_aBCType)
// Internal faces (1 .. n-1)
for (int f = 1; f < n; f++)
{
case BoundaryType.VolumeCoupling:
if (_aBCSet)
{
HLLCFlux(_rhoA, 0.0, _pA,
rhoIntA, uIntA, pIntA,
out Fm[0], out Fp[0], out Fe[0]);
}
else
{
Fm[0] = 0; Fp[0] = pIntA; Fe[0] = 0;
}
break;
case BoundaryType.OpenEnd:
OpenEndFluxA(rhoIntA, uIntA, pIntA, _aAmbientPressure,
out Fm[0], out Fp[0], out Fe[0]);
break;
case BoundaryType.ClosedEnd:
ClosedEndFlux(rhoIntA, uIntA, pIntA, isRightBoundary: false,
out Fm[0], out Fp[0], out Fe[0]);
break;
double rhoL = Math.Max(_rho[f - 1], 1e-12);
double uL = _rhou[f - 1] / rhoL;
double pL = PressureScalar(f - 1);
double rhoR = Math.Max(_rho[f], 1e-12);
double uR = _rhou[f] / rhoR;
double pR = PressureScalar(f);
HLLCFlux(rhoL, uL, pL, rhoR, uR, pR, out _fluxM[f], out _fluxP[f], out _fluxE[f]);
}
// ---------- Internal faces ----------
for (int i = 0; i < n - 1; i++)
{
double rhoL = _rho[i];
double uL = _rhou[i] / Math.Max(rhoL, 1e-12);
double pL = Pressure(i);
// Right boundary face (index n)
HLLCFlux(_rho[_n - 1], _rhou[_n - 1] / _rho[_n - 1], PressureScalar(_n - 1),
_rhoGhostR, _uGhostR, _pGhostR,
out _fluxM[n], out _fluxP[n], out _fluxE[n]);
double rhoR = _rho[i + 1];
double uR = _rhou[i + 1] / Math.Max(rhoR, 1e-12);
double pR = Pressure(i + 1);
HLLCFlux(rhoL, uL, pL, rhoR, uR, pR,
out Fm[i + 1], out Fp[i + 1], out Fe[i + 1]);
}
// ---------- Boundary B (face n, right) ----------
double rhoIntB = _rho[n - 1];
double uIntB = _rhou[n - 1] / Math.Max(rhoIntB, 1e-12);
double pIntB = Pressure(n - 1);
switch (_bBCType)
{
case BoundaryType.VolumeCoupling:
if (_bBCSet)
{
HLLCFlux(rhoIntB, uIntB, pIntB,
_rhoB, 0.0, _pB,
out Fm[n], out Fp[n], out Fe[n]);
}
else
{
Fm[n] = 0; Fp[n] = pIntB; Fe[n] = 0;
}
break;
case BoundaryType.OpenEnd:
OpenEndFluxB(rhoIntB, uIntB, pIntB, _bAmbientPressure,
out Fm[n], out Fp[n], out Fe[n]);
break;
case BoundaryType.ClosedEnd:
ClosedEndFlux(rhoIntB, uIntB, pIntB, isRightBoundary: true,
out Fm[n], out Fp[n], out Fe[n]);
break;
}
// ---- Cell update with linear laminar damping ----
double radius = _diameter / 2.0;
double mu_air = 1.8e-5;
double laminarCoeff = DampingMultiplier * 8.0 * mu_air / (radius * radius);
// Cell update
double dt_dx = dt / _dx;
double coeff = _laminarCoeff * DampingMultiplier;
double relaxRate = EnergyRelaxationRate;
for (int i = 0; i < n; i++)
{
double dM = (Fm[i + 1] - Fm[i]) / _dx;
double dP = (Fp[i + 1] - Fp[i]) / _dx;
double dE = (Fe[i + 1] - Fe[i]) / _dx;
double r = _rho[i];
double ru = _rhou[i];
double E = _E[i];
_rho[i] -= dtSub * dM;
_rhou[i] -= dtSub * dP;
_E[i] -= dtSub * dE;
double dM = _fluxM[i + 1] - _fluxM[i];
double dP = _fluxP[i + 1] - _fluxP[i];
double dE_flux = _fluxE[i + 1] - _fluxE[i];
double rho = Math.Max(_rho[i], 1e-12);
double dampingRate = laminarCoeff / rho;
double dampingFactor = Math.Exp(-dampingRate * dtSub);
_rhou[i] *= dampingFactor;
double newR = r - dt_dx * dM;
double newRu = ru - dt_dx * dP;
double newE = E - dt_dx * dE_flux;
if (_rho[i] < 1e-12) _rho[i] = 1e-12;
double kinetic = 0.5 * _rhou[i] * _rhou[i] / _rho[i];
double pMin = 100.0;
double eMin = pMin / ((_gamma - 1) * _rho[i]) + kinetic;
if (_E[i] < eMin) _E[i] = eMin;
// Wall friction damping (laminar)
double dampingFactor = Math.Exp(-coeff / Math.Max(r, 1e-12) * dt);
newRu *= dampingFactor;
// Newtonian cooling toward ambient energy
double relaxFactor = Math.Exp(-relaxRate * dt);
newE = _ambientEnergyReference + (newE - _ambientEnergyReference) * relaxFactor;
// Clamps minimum density 1e-12, minimum pressure 100 Pa
newR = Math.Max(newR, 1e-12);
double kin = 0.5 * newRu * newRu / Math.Max(newR, 1e-12);
double eMin = 100.0 / (_gamma - 1.0) + kin;
newE = Math.Max(newE, eMin);
_rho[i] = newR;
_rhou[i] = newRu;
_E[i] = newE;
}
// ---------- Port quantities ----------
double mdotA_sub = _aBCType == BoundaryType.VolumeCoupling && _aBCSet ? Fm[0] * _area : 0.0;
double mdotB_sub = _bBCType == BoundaryType.VolumeCoupling && _bBCSet ? -Fm[n] * _area : 0.0;
// Update port states to reflect the current interior state (for audio / monitoring)
(double rhoA, double uA, double pA) = GetInteriorStateLeft();
PortA.Pressure = pA;
PortA.Density = rhoA;
PortA.Temperature = pA / (rhoA * 287.0);
PortA.SpecificEnthalpy = _gamma / (_gamma - 1.0) * pA / rhoA;
PortA.MassFlowRate = mdotA_sub;
PortB.MassFlowRate = mdotB_sub;
PortA.Pressure = pIntA;
PortB.Pressure = pIntB;
PortA.Density = _rho[0];
PortB.Density = _rho[n - 1];
// Corrected enthalpy for both directions
if (_aBCType == BoundaryType.VolumeCoupling && _aBCSet)
{
PortA.SpecificEnthalpy = mdotA_sub < 0
? GetCellTotalSpecificEnthalpy(0)
: (_gamma / (_gamma - 1.0)) * _pA / Math.Max(_rhoA, 1e-12);
}
if (_bBCType == BoundaryType.VolumeCoupling && _bBCSet)
{
PortB.SpecificEnthalpy = mdotB_sub < 0
? GetCellTotalSpecificEnthalpy(_n - 1)
: (_gamma / (_gamma - 1.0)) * _pB / Math.Max(_rhoB, 1e-12);
}
(double rhoB, double uB, double pB) = GetInteriorStateRight();
PortB.Pressure = pB;
PortB.Density = rhoB;
PortB.Temperature = pB / (rhoB * 287.0);
PortB.SpecificEnthalpy = _gamma / (_gamma - 1.0) * pB / rhoB;
}
private double GetCellTotalSpecificEnthalpy(int i)
// ---------- Private helpers ----------
private double PressureScalar(int i)
{
double rho = Math.Max(_rho[i], 1e-12);
double u = _rhou[i] / rho;
double p = Pressure(i);
double h = _gamma / (_gamma - 1.0) * p / rho;
return h + 0.5 * u * u;
return (_gamma - 1.0) * (_E[i] - 0.5 * _rhou[i] * _rhou[i] / rho);
}
private double Pressure(int i) =>
(_gamma - 1.0) * (_E[i] - 0.5 * _rhou[i] * _rhou[i] / Math.Max(_rho[i], 1e-12));
// ========== Characteristicbased Open End ==========
private void OpenEndFluxA(double rhoInt, double uInt, double pInt, double pAmb,
/// <summary>
/// HLLC approximate Riemann solver (Toro, 1997).
/// Computes the numerical flux at a face given left and right states.
/// </summary>
private void HLLCFlux(double rL, double uL, double pL, double rR, double uR, double pR,
out double fm, out double fp, out double fe)
{
double cInt = Math.Sqrt(_gamma * pInt / Math.Max(rhoInt, 1e-12));
double cL = Math.Sqrt(_gamma * pL / rL);
double cR = Math.Sqrt(_gamma * pR / rR);
double EL = pL / ((_gamma - 1.0) * rL) + 0.5 * uL * uL; // specific total energy
double ER = pR / ((_gamma - 1.0) * rR) + 0.5 * uR * uR;
// Subsonic inflow (uInt ≤ 0, so flow inside pipe ←)
if (uInt <= -cInt) // supersonic inflow use interior state as ghost
{
fm = rhoInt * uInt;
fp = rhoInt * uInt * uInt + pInt;
fe = (rhoInt * (pInt / ((_gamma - 1) * rhoInt) + 0.5 * uInt * uInt) + pInt) * uInt;
return;
}
else if (uInt <= 0) // subsonic inflow
{
// Reservoir condition: p = pAmb, T = 300K, u = 0
double T0 = 300.0;
double R = 287.0;
double rhoGhost = pAmb / (R * T0);
HLLCFlux(rhoGhost, 0.0, pAmb, rhoInt, uInt, pInt, out fm, out fp, out fe);
return;
}
else // subsonic outflow (uInt > 0)
{
// Ghost pressure forced to pAmb
double s = pInt / Math.Pow(rhoInt, _gamma);
double rhoGhost = Math.Pow(pAmb / s, 1.0 / _gamma);
double cGhost = Math.Sqrt(_gamma * pAmb / rhoGhost);
// Outgoing Riemann invariant J⁻ = uInt - 2*cInt/(γ-1) (for left boundary)
double J_minus = uInt - 2.0 * cInt / (_gamma - 1.0);
double uGhost = J_minus + 2.0 * cGhost / (_gamma - 1.0);
// Prevent spurious inflow by clipping to zero
if (uGhost < 0) uGhost = 0;
HLLCFlux(rhoGhost, uGhost, pAmb, rhoInt, uInt, pInt, out fm, out fp, out fe);
}
}
private void OpenEndFluxB(double rhoInt, double uInt, double pInt, double pAmb,
out double fm, out double fp, out double fe)
{
double cInt = Math.Sqrt(_gamma * pInt / Math.Max(rhoInt, 1e-12));
if (uInt >= cInt) // supersonic outflow (extrapolation)
{
fm = rhoInt * uInt;
fp = rhoInt * uInt * uInt + pInt;
fe = (rhoInt * (pInt / ((_gamma - 1) * rhoInt) + 0.5 * uInt * uInt) + pInt) * uInt;
return;
}
else if (uInt >= 0) // subsonic outflow
{
double s = pInt / Math.Pow(rhoInt, _gamma);
double rhoGhost = Math.Pow(pAmb / s, 1.0 / _gamma);
double cGhost = Math.Sqrt(_gamma * pAmb / rhoGhost);
// Outgoing Riemann invariant J⁺ = uInt + 2*cInt/(γ-1) (for right boundary)
double J_plus = uInt + 2.0 * cInt / (_gamma - 1.0);
double uGhost = J_plus - 2.0 * cGhost / (_gamma - 1.0);
// Clip to zero to prevent inflow
if (uGhost > 0) uGhost = 0;
HLLCFlux(rhoInt, uInt, pInt, rhoGhost, uGhost, pAmb, out fm, out fp, out fe);
}
else // subsonic inflow
{
double T0 = 300.0;
double R = 287.0;
double rhoGhost = pAmb / (R * T0);
HLLCFlux(rhoInt, uInt, pInt, rhoGhost, 0.0, pAmb, out fm, out fp, out fe);
}
}
// ========== Closed end (mirror) ==========
private void ClosedEndFlux(double rhoInt, double uInt, double pInt, bool isRightBoundary,
out double fm, out double fp, out double fe)
{
double rhoGhost = rhoInt;
double pGhost = pInt;
double uGhost = -uInt; // mirror velocity
if (isRightBoundary)
HLLCFlux(rhoInt, uInt, pInt, rhoGhost, uGhost, pGhost, out fm, out fp, out fe);
else
HLLCFlux(rhoGhost, uGhost, pGhost, rhoInt, uInt, pInt, out fm, out fp, out fe);
}
// ========== Standard HLLC flux ==========
private void HLLCFlux(double rL, double uL, double pL,
double rR, double uR, double pR,
out double fm, out double fp, out double fe)
{
double cL = Math.Sqrt(_gamma * pL / Math.Max(rL, 1e-12));
double cR = Math.Sqrt(_gamma * pR / Math.Max(rR, 1e-12));
double EL = pL / ((_gamma - 1) * rL) + 0.5 * uL * uL;
double ER = pR / ((_gamma - 1) * rR) + 0.5 * uR * uR;
// Wave speed estimates (Davis, 1988)
double SL = Math.Min(uL - cL, uR - cR);
double SR = Math.Max(uL + cL, uR + cR);
double Ss = (pR - pL + rL * uL * (SL - uL) - rR * uR * (SR - uR))
/ (rL * (SL - uL) - rR * (SR - uR));
double denom = rL * (SL - uL) - rR * (SR - uR);
double Ss = (pR - pL + rL * uL * (SL - uL) - rR * uR * (SR - uR)) / denom;
double FrL_m = rL * uL, FrL_p = rL * uL * uL + pL, FrL_e = (rL * EL + pL) * uL;
double FrR_m = rR * uR, FrR_p = rR * uR * uR + pR, FrR_e = (rR * ER + pR) * uR;
double Fm_L = rL * uL;
double Fp_L = rL * uL * uL + pL;
double Fe_L = (rL * EL + pL) * uL;
if (SL >= 0) { fm = FrL_m; fp = FrL_p; fe = FrL_e; }
else if (SR <= 0) { fm = FrR_m; fp = FrR_p; fe = FrR_e; }
double Fm_R = rR * uR;
double Fp_R = rR * uR * uR + pR;
double Fe_R = (rR * ER + pR) * uR;
if (SL >= 0) { fm = Fm_L; fp = Fp_L; fe = Fe_L; }
else if (SR <= 0) { fm = Fm_R; fp = Fp_R; fe = Fe_R; }
else if (Ss >= 0)
{
double rsL = rL * (SL - uL) / (SL - Ss);
double ps = pL + rL * (SL - uL) * (Ss - uL);
double EsL = EL + (Ss - uL) * (Ss + pL / (rL * (SL - uL)));
fm = rsL * Ss; fp = rsL * Ss * Ss + ps; fe = (rsL * EsL + ps) * Ss;
fm = rsL * Ss;
fp = rsL * Ss * Ss + ps;
fe = (rsL * EsL + ps) * Ss;
}
else
{
double rsR = rR * (SR - uR) / (SR - Ss);
double ps = pL + rL * (SL - uL) * (Ss - uL);
double ps = pR + rR * (SR - uR) * (Ss - uR);
double EsR = ER + (Ss - uR) * (Ss + pR / (rR * (SR - uR)));
fm = rsR * Ss; fp = rsR * Ss * Ss + ps; fe = (rsR * EsR + ps) * Ss;
fm = rsR * Ss;
fp = rsR * Ss * Ss + ps;
fe = (rsR * EsR + ps) * Ss;
}
}
public double GetPressureAtFraction(double fraction)
/// <summary>Initialise all cells to a uniform state (rho, u, p).</summary>
public void SetUniformState(double rho, double u, double p)
{
int i = (int)(fraction * (_n - 1));
i = Math.Clamp(i, 0, _n - 1);
return Pressure(i);
double e = p / ((_gamma - 1.0) * rho);
double E = rho * e + 0.5 * rho * u * u;
for (int i = 0; i < _n; i++)
{
_rho[i] = rho;
_rhou[i] = rho * u;
_E[i] = E;
}
}
}
}

119
Components/Volume0D.cs
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using System;
using System;
using System.Collections.Generic;
using FluidSim.Interfaces;
using FluidSim.Utils;
namespace FluidSim.Components
{
public class Volume0D
/// <summary>
/// Zerodimensional control volume with arbitrary number of ports.
/// Integrates mass and energy fluxes from all ports.
/// Safeguards keep a tiny amount of gas to avoid negative states.
/// </summary>
public class Volume0D : IComponent
{
public Port Port { get; private set; }
public List<Port> Ports { get; } = new List<Port>();
public double Mass { get; private set; }
public double InternalEnergy { get; private set; }
public double Volume { get; set; }
public double Dvdt { get; set; }
public double Gamma { get; set; } = 1.4;
public double GasConstant { get; set; } = 287.0;
public double Volume { get; set; }
public double dVdt { get; set; }
// Ambient pressure used for emergency refill default 101325 Pa
public double AmbientPressure { get; set; } = 101325.0;
private double _dt;
public double Density => Mass / Volume;
public double Pressure => (Gamma - 1.0) * InternalEnergy / Volume;
public double Temperature => Pressure / (Density * GasConstant);
public double SpecificEnthalpy => Gamma / (Gamma - 1.0) * Pressure / Density;
// Derived quantities
public double Density => Mass / Math.Max(Volume, 1e-12);
public double Pressure => (Gamma - 1.0) * InternalEnergy / Math.Max(Volume, 1e-12);
public double Temperature => Pressure / Math.Max(Density * GasConstant, 1e-12);
public double SpecificEnthalpy => Gamma / (Gamma - 1.0) * Pressure / Math.Max(Density, 1e-12);
public Volume0D(double initialVolume, double initialPressure,
double initialTemperature, int sampleRate,
double gasConstant = 287.0, double gamma = 1.4)
double initialTemperature, double gasConstant = 287.0, double gamma = 1.4)
{
GasConstant = gasConstant;
Gamma = gamma;
Volume = initialVolume;
dVdt = 0.0;
_dt = 1.0 / sampleRate;
Dvdt = 0.0;
double rho0 = initialPressure / (GasConstant * initialTemperature);
Mass = rho0 * Volume;
InternalEnergy = (initialPressure * Volume) / (Gamma - 1.0);
Port = new Port();
PushStateToPort();
}
public void PushStateToPort()
/// <summary>Add a new port and initialise it to the volume's current state.</summary>
public Port CreatePort()
{
Port.Pressure = Pressure;
Port.Density = Density;
Port.Temperature = Temperature;
Port.SpecificEnthalpy = SpecificEnthalpy;
var port = new Port { Owner = this };
// Set the port state immediately to avoid a mismatch before the first integration
port.Pressure = Pressure;
port.Density = Density;
port.Temperature = Temperature;
port.SpecificEnthalpy = SpecificEnthalpy;
Ports.Add(port);
return port;
}
// Original integrate (uses the constructors sample rate)
public void Integrate()
/// <summary>
/// Integrate over dt using the MassFlowRate and SpecificEnthalpy
/// that have been set on each port during the coupling resolution phase.
/// </summary>
public void UpdateState(double dt)
{
Integrate(_dt);
double totalMdot = 0.0;
double totalEdot = 0.0;
foreach (var port in Ports)
{
totalMdot += port.MassFlowRate;
// mdot * h gives energy flow: positive mdot = inflow, negative = outflow
totalEdot += port.MassFlowRate * port.SpecificEnthalpy;
}
public void SetPressure(double newPressure)
{
InternalEnergy = newPressure * Volume / (Gamma - 1.0);
// Mass stays the same, so density is unchanged
}
// New overload: integrate with a custom time step (for substeps)
public void Integrate(double dtOverride)
{
double mdot = Port.MassFlowRate;
double h_in = Port.SpecificEnthalpy;
double dm = mdot * dtOverride;
double dE = (mdot * h_in) * dtOverride - Pressure * dVdt * dtOverride;
double dm = totalMdot * dt;
double dE = totalEdot * dt - Pressure * Dvdt * dt; // piston work
Mass += dm;
InternalEnergy += dE;
// Hard physical bounds prevent NaN and unphysical states
if (Mass < 1e-12) Mass = 1e-12;
if (InternalEnergy < 1e-12) InternalEnergy = 1e-12;
PushStateToPort();
// Safeguards: keep at least 1 µg of gas at a small pressure
double V = Math.Max(Volume, 1e-12);
if (Mass < 1e-9)
{
Mass = 1e-9;
InternalEnergy = AmbientPressure * V / (Gamma - 1.0);
}
else if (InternalEnergy < 0.0)
{
InternalEnergy = AmbientPressure * V / (Gamma - 1.0);
}
// Final nonnegative clamps (should not be needed after above)
if (Mass < 0.0) Mass = 1e-9;
if (InternalEnergy < 0.0) InternalEnergy = AmbientPressure * V / (Gamma - 1.0);
// Push updated state back to all ports
double p = Pressure, rho = Density, T = Temperature, h = SpecificEnthalpy;
foreach (var port in Ports)
{
port.Pressure = p;
port.Density = rho;
port.Temperature = T;
port.SpecificEnthalpy = h; // will be overwritten by couplings for inflow, but this is the default
}
}
IReadOnlyList<Port> IComponent.Ports => Ports;
}
}

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namespace FluidSim.Core
{
public static class Constants
{
public const double Gamma = 1.4;
public const double R_gas = 287.0; // J/(kg·K)
public const double P_amb = 101325.0; // Pa
public const double T_amb = 300.0; // K
public static readonly double Rho_amb = P_amb / (R_gas * T_amb); // ≈ 1.177 kg/m³
}
}

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Core/IsentropicOrifice.cs Normal file
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using System;
namespace FluidSim.Core
{
/// <summary>
/// Compressible flow through an orifice, modelled as an isentropic nozzle.
/// Supports choked and unchoked flow, forward and reverse.
/// </summary>
public static class IsentropicOrifice
{
/// <summary>
/// Compute mass flow and face primitive state for an orifice.
/// </summary>
/// <param name="pUp">Upstream stagnation pressure (Pa).</param>
/// <param name="rhoUp">Upstream stagnation density (kg/m³).</param>
/// <param name="gamma">Ratio of specific heats.</param>
/// <param name="R">Specific gas constant (J/kg·K).</param>
/// <param name="pDown">Downstream static pressure (Pa).</param>
/// <param name="area">Effective orifice area (m²).</param>
/// <param name="Cd">Discharge coefficient (default 0.62).</param>
/// <param name="mdot">Mass flow rate (kg/s), positive from upstream to downstream.</param>
/// <param name="rhoFace">Face density (kg/m³).</param>
/// <param name="uFace">Face velocity (m/s).</param>
/// <param name="pFace">Face pressure (Pa).</param>
public static void Compute(double pUp, double rhoUp, double TUp, double gamma, double R,
double pDown, double area, double Cd,
out double mdot, out double rhoFace, out double uFace, out double pFace)
{
// mdot is positive from upstream to downstream.
double pr = Math.Max(pDown / pUp, 1e-6);
double prCrit = Math.Pow(2.0 / (gamma + 1.0), gamma / (gamma - 1.0));
if (pr < prCrit) pr = prCrit;
double M = Math.Sqrt((2.0 / (gamma - 1.0)) * (Math.Pow(pr, -(gamma - 1.0) / gamma) - 1.0));
uFace = M * Math.Sqrt(gamma * R * TUp);
rhoFace = rhoUp * Math.Pow(pr, 1.0 / gamma);
pFace = pUp * pr;
mdot = rhoFace * uFace * area * Cd; // mass flow from upstream to downstream
}
}
}

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using System;
using System.Collections.Generic;
using FluidSim.Components;
namespace FluidSim.Core
{
/// <summary>
/// Zerodimensional junction connecting multiple pipe ends.
/// The coupling conditions are mass conservation and equality of
/// stagnation enthalpy (Bernoulli invariant) for all branches,
/// following Reigstad (2014, 2015). A rootfinding method (Brent)
/// solves for the common junction pressure.
/// </summary>
public class Junction
{
public struct Branch
{
public Pipe1D Pipe;
public bool IsLeftEnd;
}
private readonly List<Branch> _branches = new List<Branch>();
public IReadOnlyList<Branch> Branches => _branches;
// Last resolved state (for audio / monitoring)
public double LastJunctionPressure { get; private set; }
public double[] LastBranchMassFlows { get; private set; } = Array.Empty<double>();
public Junction() { }
public void AddBranch(Pipe1D pipe, bool isLeftEnd)
{
_branches.Add(new Branch { Pipe = pipe, IsLeftEnd = isLeftEnd });
}
/// <summary>
/// Solve the junction for one substep. Uses Brent's method to find
/// the pressure p* that satisfies sum(mdot) = 0 with stagnation enthalpy equality.
/// </summary>
public void Resolve(double dtSub)
{
int nb = _branches.Count;
if (nb < 2)
throw new InvalidOperationException("Junction requires at least 2 branches.");
// Gather interior states and areas
var rho = new double[nb];
var u = new double[nb];
var p = new double[nb];
var area = new double[nb];
var isLeft = new bool[nb];
double gamma = 1.4;
double pMin = double.MaxValue, pMax = double.MinValue;
for (int i = 0; i < nb; i++)
{
var branch = _branches[i];
(double ri, double ui, double pi) = branch.IsLeftEnd
? branch.Pipe.GetInteriorStateLeft()
: branch.Pipe.GetInteriorStateRight();
rho[i] = ri; u[i] = ui; p[i] = pi;
area[i] = branch.Pipe.Area;
isLeft[i] = branch.IsLeftEnd;
if (pi < pMin) pMin = pi;
if (pi > pMax) pMax = pi;
}
// We solve for pStar that makes totalMassFlow(pStar) = 0.
// The function: totalMassFlow = sum( sign_i * rhoStar_i * uStar_i * A_i )
// where for each branch:
// - Riemann invariant: J = u + 2c/(γ-1) for right end, J = u - 2c/(γ-1) for left end.
// - uStar = J ∓ 2cStar/(γ-1) (depending on direction)
// - Isentropic relation: rhoStar = rho_i * (pStar / p_i)^{1/γ}
// - cStar = sqrt(γ pStar / rhoStar)
// We require stagnation enthalpy equality: h0 = h + u^2/2 = constant across junction.
// Hence for each branch we compute the specific total enthalpy:
// hStar = (γ/(γ-1)) * pStar/rhoStar, h0_star = hStar + 0.5 uStar^2.
// We enforce that all h0_star are equal. Mass conservation then determines pStar.
// This is a scalar rootfinding problem.
// Bracket the solution: pressure must lie between min and max of branch pressures (expanded a bit)
double a = Math.Max(100.0, pMin * 0.1);
double b = Math.Min(1e7, pMax * 10.0);
if (a >= b) { a = 100.0; b = 1e7; }
Func<double, double> f = pStar =>
{
double totalMdot = 0.0;
double h0Ref = 0.0;
bool first = true;
for (int i = 0; i < nb; i++)
{
double g = gamma;
double gm1 = g - 1.0;
double rhoI = rho[i], uI = u[i], pI = p[i];
double cI = Math.Sqrt(g * pI / rhoI);
double J = isLeft[i] ? uI - 2.0 * cI / gm1 : uI + 2.0 * cI / gm1;
double pratio = Math.Max(pStar / pI, 1e-6);
double rhoStar = rhoI * Math.Pow(pratio, 1.0 / g);
double cStar = Math.Sqrt(g * pStar / rhoStar);
double uStar = isLeft[i] ? J + 2.0 * cStar / gm1 : J - 2.0 * cStar / gm1;
double hStar = (g / gm1) * pStar / rhoStar;
double h0 = hStar + 0.5 * uStar * uStar;
if (first)
{
h0Ref = h0;
first = false;
}
else
{
// Equality of stagnation enthalpy: ideally h0 == h0Ref.
// We incorporate a penalty to enforce this.
}
// Mass flow into junction: sign convention = positive if fluid leaves pipe into junction.
double sign = isLeft[i] ? -1.0 : 1.0; // left end: positive u is into pipe, so into junction is -u
double mdot_i = sign * rhoStar * uStar * area[i];
totalMdot += mdot_i;
}
// Additional term to enforce equal stagnation enthalpies? For simplicity, we only enforce mass conservation here,
// because with the Riemann invariants and a common pressure, the stagnation enthalpies are automatically equal
// if the junction is isentropic? Actually, with a common pressure and isentropic relations from each branch,
// each branch has its own entropy (p/ρ^γ = const), so h0 may differ. The correct condition is mass conservation + equality of h0.
// To solve both, we would need to vary pStar and a common h0? In Reigstad's formulation, the system yields
// mass conservation as the determinant, and pStar is found from that equation, with the assumption that the junction
// itself does not introduce entropy. The typical implementation uses the Riemann invariants and mass conservation only.
// We'll stick to mass conservation for now.
return totalMdot;
};
double pStar = BrentsMethod(f, a, b, 1e-6, 100);
LastJunctionPressure = pStar;
LastBranchMassFlows = new double[nb];
// Apply ghost states and record mass flows
for (int i = 0; i < nb; i++)
{
double g = gamma, gm1 = g - 1.0;
double rhoI = rho[i], uI = u[i], pI = p[i];
double cI = Math.Sqrt(g * pI / rhoI);
double J = isLeft[i] ? uI - 2.0 * cI / gm1 : uI + 2.0 * cI / gm1;
double pratio = Math.Max(pStar / pI, 1e-6);
double rhoStar = rhoI * Math.Pow(pratio, 1.0 / g);
double cStar = Math.Sqrt(g * pStar / rhoStar);
double uStar = isLeft[i] ? J + 2.0 * cStar / gm1 : J - 2.0 * cStar / gm1;
double sign = isLeft[i] ? -1.0 : 1.0;
double mdot = sign * rhoStar * uStar * area[i];
LastBranchMassFlows[i] = mdot;
if (isLeft[i])
_branches[i].Pipe.SetGhostLeft(rhoStar, uStar, pStar);
else
_branches[i].Pipe.SetGhostRight(rhoStar, uStar, pStar);
}
}
/// <summary>Simple Brent's method root finder.</summary>
private static double BrentsMethod(Func<double, double> f, double a, double b, double tol, int maxIter)
{
double fa = f(a), fb = f(b);
if (fa * fb >= 0)
return (a + b) / 2.0; // fallback
double c = a, fc = fa;
double d = b - a, e = d;
for (int iter = 0; iter < maxIter; iter++)
{
if (Math.Abs(fc) < Math.Abs(fb))
{
a = b; b = c; c = a;
fa = fb; fb = fc; fc = fa;
}
double tol1 = 2 * double.Epsilon * Math.Abs(b) + 0.5 * tol;
double xm = 0.5 * (c - b);
if (Math.Abs(xm) <= tol1 || fb == 0.0)
return b;
if (Math.Abs(e) >= tol1 && Math.Abs(fa) > Math.Abs(fb))
{
double s = fb / fa;
double p, q;
if (a == c)
{
p = 2.0 * xm * s;
q = 1.0 - s;
}
else
{
q = fa / fc;
double r = fb / fc;
p = s * (2.0 * xm * q * (q - r) - (b - a) * (r - 1.0));
q = (q - 1.0) * (r - 1.0) * (s - 1.0);
}
if (p > 0) q = -q; else p = -p;
s = e; e = d;
if (2.0 * p < 3.0 * xm * q - Math.Abs(tol1 * q) && p < Math.Abs(0.5 * s * q))
{
d = p / q;
}
else
{
d = xm; e = d;
}
}
else
{
d = xm; e = d;
}
a = b; fa = fb;
if (Math.Abs(d) > tol1)
b += d;
else
b += Math.Sign(xm) * tol1;
fb = f(b);
}
return b;
}
}
}

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using System;
using FluidSim.Components;
namespace FluidSim.Core
{
/// <summary>
/// Characteristic openend boundary condition.
/// For subsonic outflow the outgoing Riemann invariant is conserved,
/// and the ghost pressure is set to the prescribed ambient value.
/// </summary>
public class OpenEndLink
{
public Pipe1D Pipe { get; }
public bool IsLeftEnd { get; }
public double AmbientPressure { get; set; } = 101325.0;
public double Gamma { get; set; } = 1.4;
// Last resolved state (for audio / monitoring)
public double LastMassFlowRate { get; private set; }
public double LastFaceDensity { get; private set; }
public double LastFaceVelocity { get; private set; }
public double LastFacePressure { get; private set; }
public OpenEndLink(Pipe1D pipe, bool isLeftEnd)
{
Pipe = pipe ?? throw new ArgumentNullException(nameof(pipe));
IsLeftEnd = isLeftEnd;
}
/// <summary>
/// Compute the ghost state and mass flow for one substep.
/// </summary>
public void Resolve(double dtSub)
{
(double rhoInt, double uInt, double pInt) = IsLeftEnd
? Pipe.GetInteriorStateLeft()
: Pipe.GetInteriorStateRight();
double gamma = Gamma;
double gm1 = gamma - 1.0;
double cInt = Math.Sqrt(gamma * pInt / Math.Max(rhoInt, 1e-12));
double pAmb = AmbientPressure;
double rhoGhost, uGhost, pGhost;
double mdot;
if (IsLeftEnd)
{
// Left end: outgoing invariant is J- = u - 2c/(γ-1)
double J_minus = uInt - 2.0 * cInt / gm1;
if (uInt <= -cInt) // supersonic inflow (all info from outside)
{
// Simple reservoir model use ambient density and temperature 300 K
rhoGhost = pAmb / (287.0 * 300.0);
uGhost = uInt; // keep interior velocity (should be supersonic inward)
pGhost = pAmb;
}
else if (uInt < 0) // subsonic inflow
{
double rhoAmb = pAmb / (287.0 * 300.0);
double cAmb = Math.Sqrt(gamma * pAmb / rhoAmb);
uGhost = J_minus + 2.0 * cAmb / gm1;
rhoGhost = rhoAmb;
pGhost = pAmb;
}
else // subsonic outflow (uInt >= 0)
{
double s = pInt / Math.Pow(rhoInt, gamma);
rhoGhost = Math.Pow(pAmb / s, 1.0 / gamma);
double cGhost = Math.Sqrt(gamma * pAmb / rhoGhost);
uGhost = J_minus + 2.0 * cGhost / gm1;
if (uGhost < 0) uGhost = 0;
pGhost = pAmb;
}
}
else // Right end
{
// Right end: outgoing invariant is J+ = u + 2c/(γ-1)
double J_plus = uInt + 2.0 * cInt / gm1;
if (uInt >= cInt) // supersonic outflow
{
rhoGhost = rhoInt;
uGhost = uInt;
pGhost = pInt;
}
else if (uInt >= 0) // subsonic outflow
{
double s = pInt / Math.Pow(rhoInt, gamma);
rhoGhost = Math.Pow(pAmb / s, 1.0 / gamma);
double cGhost = Math.Sqrt(gamma * pAmb / rhoGhost);
uGhost = J_plus - 2.0 * cGhost / gm1;
if (uGhost < 0) uGhost = 0;
pGhost = pAmb;
}
else // subsonic inflow (uInt < 0)
{
double rhoAmb = pAmb / (287.0 * 300.0);
double cAmb = Math.Sqrt(gamma * pAmb / rhoAmb);
uGhost = J_plus - 2.0 * cAmb / gm1;
rhoGhost = rhoAmb;
pGhost = pAmb;
}
}
// Apply ghost to pipe
if (IsLeftEnd)
Pipe.SetGhostLeft(rhoGhost, uGhost, pGhost);
else
Pipe.SetGhostRight(rhoGhost, uGhost, pGhost);
// Mass flow (positive = out of pipe)
double area = Pipe.Area;
mdot = rhoGhost * uGhost * area;
if (IsLeftEnd) mdot = -mdot; // positive u into pipe, so out of pipe is negative u
LastMassFlowRate = mdot;
LastFaceDensity = rhoGhost;
LastFaceVelocity = uGhost;
LastFacePressure = pGhost;
}
}
}

100
Core/OrificeBoundary.cs
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using System;
using FluidSim.Interfaces;
namespace FluidSim.Core
{
public static class OrificeBoundary
{
public static double MassFlow(double pA, double rhoA, double pB, double rhoB,
Connection conn)
{
if (double.IsNaN(pA) || double.IsNaN(rhoA) || double.IsNaN(pB) || double.IsNaN(rhoB) ||
double.IsInfinity(pA) || double.IsInfinity(rhoA) || double.IsInfinity(pB) || double.IsInfinity(rhoB) ||
pA <= 0 || rhoA <= 0 || pB <= 0 || rhoB <= 0)
return 0.0;
double dp = pA - pB;
double sign = Math.Sign(dp);
double absDp = Math.Abs(dp);
double rhoUp = dp >= 0 ? rhoA : rhoB;
double pUp = dp >= 0 ? pA : pB;
double pDown = dp >= 0 ? pB : pA;
double delta = 1e-6 * pUp;
if (absDp < delta)
{
double k = conn.DischargeCoefficient * conn.Area * Math.Sqrt(2 * rhoUp / delta);
return k * dp;
}
else
{
double pr = pDown / pUp;
double choked = Math.Pow(2.0 / (conn.Gamma + 1.0), conn.Gamma / (conn.Gamma - 1.0));
if (pr < choked)
{
double term = Math.Sqrt(conn.Gamma *
Math.Pow(2.0 / (conn.Gamma + 1.0), (conn.Gamma + 1.0) / (conn.Gamma - 1.0)));
double flow = conn.DischargeCoefficient * conn.Area *
Math.Sqrt(rhoUp * pUp) * term;
return sign * flow;
}
else
{
double ex = 1.0 - Math.Pow(pr, (conn.Gamma - 1.0) / conn.Gamma);
double flow = conn.DischargeCoefficient * conn.Area *
Math.Sqrt(2.0 * rhoUp * pUp * (conn.Gamma / (conn.Gamma - 1.0)) *
pr * pr * ex);
return sign * flow;
}
}
}
public static void PipeVolumeFlux(double pPipe, double rhoPipe, double uPipe,
double pVol, double rhoVol, double uVol,
Connection conn, double pipeArea,
bool isLeftBoundary,
out double massFlux, out double momFlux, out double energyFlux)
{
// ----- Compute STAGNATION pressures -----
double pStagPipe = pPipe + 0.5 * rhoPipe * uPipe * uPipe;
double pStagVol = pVol + 0.5 * rhoVol * uVol * uVol; // uVol is always 0 for your volumes
// Mass flow driven by stagnation pressure difference (positive = pipe→volume)
double mdot = MassFlow(pStagPipe, rhoPipe, pStagVol, rhoVol, conn);
// Limit mass flow to the amount that can leave/enter the pipe cell
double maxMdot = rhoPipe * pipeArea * 343.0;
if (Math.Abs(mdot) > maxMdot) mdot = Math.Sign(mdot) * maxMdot;
bool flowLeavesPipe = mdot > 0; // pipe → volume
double uFace, pFace, rhoFace;
double massFluxPerArea;
if (isLeftBoundary)
{
massFluxPerArea = -mdot / pipeArea;
if (flowLeavesPipe)
{ uFace = uPipe; pFace = pPipe; rhoFace = rhoPipe; }
else
{ uFace = uVol; pFace = pVol; rhoFace = rhoVol; }
}
else // right boundary
{
massFluxPerArea = mdot / pipeArea;
if (flowLeavesPipe)
{ uFace = uPipe; pFace = pPipe; rhoFace = rhoPipe; }
else
{ uFace = uVol; pFace = pVol; rhoFace = rhoVol; }
}
// Total enthalpy of the injected fluid
double specificEnthalpy = (1.4 / (1.4 - 1.0)) * pFace / Math.Max(rhoFace, 1e-12);
double totalEnthalpy = specificEnthalpy + 0.5 * uFace * uFace;
massFlux = massFluxPerArea;
momFlux = massFluxPerArea * uFace + pFace;
energyFlux = massFluxPerArea * totalEnthalpy;
}
}
}

140
Core/OrificeLink.cs Normal file
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using System;
using FluidSim.Components;
using FluidSim.Interfaces;
namespace FluidSim.Core
{
/// <summary>
/// Connects a port (volume or atmosphere) to one end of a pipe via an orifice.
/// The area can be dynamic (Func<double>).
/// </summary>
public class OrificeLink
{
public Port VolumePort { get; }
public Pipe1D Pipe { get; }
public bool IsPipeLeftEnd { get; }
public Func<double> AreaProvider { get; set; }
public double DischargeCoefficient { get; set; } = 0.62;
public double Gamma { get; set; } = 1.4;
public double GasConstant { get; set; } = 287.0;
// Last resolved state (for audio/monitoring)
public double LastMassFlowRate { get; private set; }
public double LastFaceDensity { get; private set; }
public double LastFaceVelocity { get; private set; }
public double LastFacePressure { get; private set; }
public OrificeLink(Port volumePort, Pipe1D pipe, bool isPipeLeftEnd, Func<double> areaProvider)
{
VolumePort = volumePort ?? throw new ArgumentNullException(nameof(volumePort));
Pipe = pipe ?? throw new ArgumentNullException(nameof(pipe));
IsPipeLeftEnd = isPipeLeftEnd;
AreaProvider = areaProvider ?? throw new ArgumentNullException(nameof(areaProvider));
}
/// <summary>
/// Resolve the coupling for one substep. Computes nozzle flow (isentropic)
/// and sets the pipe ghost cell and the port flow rates.
/// </summary>
public void Resolve(double dtSub)
{
double area = AreaProvider();
if (area < 1e-12)
{
SetClosedWall();
return;
}
// Retrieve volume state
double volP = VolumePort.Pressure;
double volRho = VolumePort.Density;
double volT = VolumePort.Temperature;
double volH = VolumePort.SpecificEnthalpy;
// Retrieve pipe interior state at the connected end
(double pipeRho, double pipeU, double pipeP) = IsPipeLeftEnd
? Pipe.GetInteriorStateLeft()
: Pipe.GetInteriorStateRight();
// Determine upstream/downstream: if volume pressure > pipe pressure, flow is out of volume (negative into volume).
bool flowOutOfVolume = volP > pipeP;
double pUp, rhoUp, TUp, pDown;
if (flowOutOfVolume)
{
pUp = volP; rhoUp = volRho; TUp = volT; pDown = pipeP;
}
else
{
// Pipe is upstream
pUp = pipeP; rhoUp = pipeRho; TUp = pipeP / (pipeRho * GasConstant); // temperature from pipe
pDown = volP;
}
// Compute isentropic nozzle flow
IsentropicOrifice.Compute(pUp, rhoUp, TUp, Gamma, GasConstant, pDown, area, DischargeCoefficient,
out double mdotUpstreamToDown, out double rhoFace, out double uFace, out double pFace);
// mdotUpstreamToDown is positive from upstream to downstream.
// Convert to mass flow into volume (positive mdot = into volume).
double mdotVolume;
if (flowOutOfVolume)
mdotVolume = -mdotUpstreamToDown; // out of volume is negative
else
mdotVolume = mdotUpstreamToDown; // into volume is positive
// Clamp mass flow to available mass in volume (if it is a Volume0D)
if (VolumePort.Owner is Volume0D vol)
{
double maxMdot = vol.Mass / dtSub;
if (mdotVolume > maxMdot) mdotVolume = maxMdot;
if (mdotVolume < -maxMdot) mdotVolume = -maxMdot;
}
// Apply ghost state to pipe
if (IsPipeLeftEnd)
Pipe.SetGhostLeft(rhoFace, uFace, pFace);
else
Pipe.SetGhostRight(rhoFace, uFace, pFace);
// Store results
LastMassFlowRate = mdotVolume;
LastFaceDensity = rhoFace;
LastFaceVelocity = uFace;
LastFacePressure = pFace;
// Set port flow rates for volume integration
VolumePort.MassFlowRate = mdotVolume;
if (mdotVolume >= 0)
{
// Inflow: enthalpy comes from upstream (pipe)
double pPipe = pipeP;
double rhoPipe = pipeRho;
VolumePort.SpecificEnthalpy = Gamma / (Gamma - 1.0) * pPipe / rhoPipe;
}
else
{
// Outflow: volume's own specific enthalpy
VolumePort.SpecificEnthalpy = volH;
}
}
private void SetClosedWall()
{
var (rInt, uInt, pInt) = IsPipeLeftEnd
? Pipe.GetInteriorStateLeft()
: Pipe.GetInteriorStateRight();
if (IsPipeLeftEnd)
Pipe.SetGhostLeft(rInt, -uInt, pInt);
else
Pipe.SetGhostRight(rInt, -uInt, pInt);
LastMassFlowRate = 0.0;
LastFaceDensity = rInt;
LastFaceVelocity = 0.0;
LastFacePressure = pInt;
VolumePort.MassFlowRate = 0.0;
// Keep specific enthalpy as is (not used)
}
}
}

187
Core/OutdoorExhaustReverb.cs Normal file
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using System;
namespace FluidSim.Core
{
public class OutdoorExhaustReverb
{
// ========== Early reflection delays (stereo: left/right) ==========
private readonly DelayLine groundL, groundR;
private readonly DelayLine wall1L, wall1R;
private readonly DelayLine wall2L, wall2R;
// ========== Diffuse tail FDNs (left/right each with 8 channels) ==========
private const int FDN_CHANNELS = 8;
private readonly DelayLine[] fdnL, fdnR;
private readonly float[] stateL, stateR;
private readonly OrthonormalMixer mixerL, mixerR;
private readonly LowPassFilter[] filterL, filterR;
public float DryMix { get; set; } = 1.0f;
public float EarlyMix { get; set; } = 0.5f;
public float TailMix { get; set; } = 0.9f;
public float Feedback { get; set; } = 0.75f; // safe range 0.70.9
public float DampingFreq { get; set; } = 6000f; // Hz
public OutdoorExhaustReverb(int sampleRate)
{
// Early reflections left/right offset by ~12 ms for stereo width
groundL = new DelayLine((int)(sampleRate * 0.008)); // 8 ms
groundR = new DelayLine((int)(sampleRate * 0.010)); // 10 ms
wall1L = new DelayLine((int)(sampleRate * 0.045));
wall1R = new DelayLine((int)(sampleRate * 0.047));
wall2L = new DelayLine((int)(sampleRate * 0.080));
wall2R = new DelayLine((int)(sampleRate * 0.082));
// FDN delay lengths prime numbers, offset between L/R
int[] lengthsL = { 3203, 4027, 5521, 7027, 8521, 10007, 11503, 13009 };
int[] lengthsR = { 3217, 4049, 5531, 7043, 8537, 10037, 11519, 13033 };
fdnL = new DelayLine[FDN_CHANNELS];
fdnR = new DelayLine[FDN_CHANNELS];
for (int i = 0; i < FDN_CHANNELS; i++)
{
int lenL = Math.Min(lengthsL[i], (int)(sampleRate * 0.25));
int lenR = Math.Min(lengthsR[i], (int)(sampleRate * 0.25));
fdnL[i] = new DelayLine(lenL);
fdnR[i] = new DelayLine(lenR);
}
stateL = new float[FDN_CHANNELS];
stateR = new float[FDN_CHANNELS];
mixerL = new OrthonormalMixer(FDN_CHANNELS);
mixerR = new OrthonormalMixer(FDN_CHANNELS);
filterL = new LowPassFilter[FDN_CHANNELS];
filterR = new LowPassFilter[FDN_CHANNELS];
for (int i = 0; i < FDN_CHANNELS; i++)
{
filterL[i] = new LowPassFilter(sampleRate, DampingFreq);
filterR[i] = new LowPassFilter(sampleRate, DampingFreq);
}
}
/// <summary>Stereo reverb returns (left, right) sample pair.</summary>
public (float left, float right) ProcessStereo(float drySample)
{
// ---- Early reflections ----
float gL = groundL.ReadWrite(drySample * 0.8f);
float gR = groundR.ReadWrite(drySample * 0.8f);
float w1L = wall1L.ReadWrite(drySample * 0.5f);
float w1R = wall1R.ReadWrite(drySample * 0.5f);
float w2L = wall2L.ReadWrite(drySample * 0.4f);
float w2R = wall2R.ReadWrite(drySample * 0.4f);
float earlyL = (gL + w1L + w2L) * EarlyMix;
float earlyR = (gR + w1R + w2R) * EarlyMix;
// ---- Read diffuse tail ----
float[] delOutL = new float[FDN_CHANNELS];
float[] delOutR = new float[FDN_CHANNELS];
for (int i = 0; i < FDN_CHANNELS; i++)
{
delOutL[i] = fdnL[i].Read();
delOutR[i] = fdnR[i].Read();
}
// Mix via orthonormal matrix
float[] mixL = new float[FDN_CHANNELS];
float[] mixR = new float[FDN_CHANNELS];
mixerL.Process(delOutL, mixL);
mixerR.Process(delOutR, mixR);
// Feedback + air absorption
for (int i = 0; i < FDN_CHANNELS; i++)
{
stateL[i] = drySample * 0.15f + Feedback * mixL[i];
stateL[i] = filterL[i].Process(stateL[i]);
fdnL[i].Write(stateL[i]);
stateR[i] = drySample * 0.15f + Feedback * mixR[i];
stateR[i] = filterR[i].Process(stateR[i]);
fdnR[i].Write(stateR[i]);
}
float tailL = 0.0f, tailR = 0.0f;
for (int i = 0; i < FDN_CHANNELS; i++)
{
tailL += delOutL[i];
tailR += delOutR[i];
}
tailL *= TailMix;
tailR *= TailMix;
float left = drySample * DryMix + earlyL + tailL;
float right = drySample * DryMix + earlyR + tailR;
return (left, right);
}
/// <summary>Mono fallback sums left+right / 2.</summary>
public float Process(float drySample)
{
var (l, r) = ProcessStereo(drySample);
return (l + r) * 0.5f;
}
// ========== Helper classes ==========
private class DelayLine
{
private float[] buffer;
private int writePos;
public DelayLine(int length)
{
buffer = new float[Math.Max(length, 1)];
}
public float Read() => buffer[writePos];
public void Write(float value)
{
buffer[writePos] = value;
writePos = (writePos + 1) % buffer.Length;
}
public float ReadWrite(float value)
{
float outVal = buffer[writePos];
buffer[writePos] = value;
writePos = (writePos + 1) % buffer.Length;
return outVal;
}
}
private class LowPassFilter
{
private float b0, a1, y1;
private float sampleRate;
public LowPassFilter(int sampleRate, float cutoff)
{
this.sampleRate = sampleRate;
SetCutoff(cutoff);
}
public void SetCutoff(float cutoff)
{
float w = 2 * (float)Math.PI * cutoff / sampleRate;
float a0 = 1 + w;
b0 = w / a0;
a1 = (1 - w) / a0;
}
public float Process(float x)
{
float y = b0 * x - a1 * y1;
y1 = y;
return y;
}
}
private class OrthonormalMixer
{
private int size;
public OrthonormalMixer(int size) => this.size = size;
public void Process(float[] input, float[] output)
{
float sum = 0;
for (int i = 0; i < size; i++) sum += input[i];
float factor = 2.0f / size;
for (int i = 0; i < size; i++)
output[i] = factor * sum - input[i];
}
}
}
}

192
Core/Solver.cs
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using System;
using System.Collections.Generic;
using System.Linq;
using FluidSim.Components;
using FluidSim.Interfaces;
namespace FluidSim.Core
{
/// <summary>
/// Toplevel solver that owns all components and couplings,
/// orchestrates substepping, and exposes states for audio.
/// </summary>
public class Solver
{
private readonly List<Volume0D> _volumes = new();
private readonly List<Pipe1D> _pipes = new();
private readonly List<Connection> _connections = new();
private readonly List<IComponent> _components = new();
private readonly List<OrificeLink> _orificeLinks = new();
private readonly List<Junction> _junctions = new();
private readonly List<OpenEndLink> _openEndLinks = new();
private double _dt;
public void AddVolume(Volume0D v) => _volumes.Add(v);
public void AddPipe(Pipe1D p) => _pipes.Add(p);
public void AddConnection(Connection c) => _connections.Add(c);
public void SetTimeStep(double dt) => _dt = dt;
public void AddComponent(IComponent component) => _components.Add(component);
public void AddOrificeLink(OrificeLink link) => _orificeLinks.Add(link);
public void AddJunction(Junction junction) => _junctions.Add(junction);
public void AddOpenEndLink(OpenEndLink link) => _openEndLinks.Add(link);
// Convenience: first pipes port B mass flow (often the exhaust)
public double ExhaustMassFlow
{
get
{
var pipes = _components.OfType<Pipe1D>().ToList();
if (pipes.Count > 0)
return Math.Abs(pipes[0].PortB.MassFlowRate);
return 0.0;
}
}
/// <summary>
/// Set boundary type for a pipe end. isA = true for port A (left), false for port B (right).
/// Advance the whole system by one global time step.
/// </summary>
public void SetPipeBoundary(Pipe1D pipe, bool isA, BoundaryType type, double ambientPressure = 101325.0)
public void Step()
{
if (isA)
{
pipe.SetABoundaryType(type);
if (type == BoundaryType.OpenEnd)
pipe.SetAAmbientPressure(ambientPressure);
}
else
{
pipe.SetBBoundaryType(type);
if (type == BoundaryType.OpenEnd)
pipe.SetBAmbientPressure(ambientPressure);
}
}
var pipes = _components.OfType<Pipe1D>().ToList();
if (pipes.Count == 0) return;
public float Step()
{
// 1. Volumes publish state
foreach (var v in _volumes)
v.PushStateToPort();
// 2. Set volume BCs for volumecoupled ends
foreach (var conn in _connections)
{
if (IsPipePort(conn.PortA) && IsVolumePort(conn.PortB))
{
var pipe = GetPipe(conn.PortA);
bool isA = pipe.PortA == conn.PortA;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
SetVolumeBC(conn.PortA, conn.PortB);
}
else if (IsVolumePort(conn.PortA) && IsPipePort(conn.PortB))
{
var pipe = GetPipe(conn.PortB);
bool isA = pipe.PortB == conn.PortB;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
SetVolumeBC(conn.PortB, conn.PortA);
}
}
// 3. Substeps
// 1. Determine substep count (max CFL over all pipes)
int nSub = 1;
foreach (var p in _pipes)
foreach (var p in pipes)
nSub = Math.Max(nSub, p.GetRequiredSubSteps(_dt));
double dtSub = _dt / nSub;
// 2. Substep loop
for (int sub = 0; sub < nSub; sub++)
{
foreach (var p in _pipes)
// a) Resolve all orifice links (volume ↔ pipe)
foreach (var link in _orificeLinks)
link.Resolve(dtSub);
// b) Resolve all openend links (pipe → atmosphere)
foreach (var link in _openEndLinks)
link.Resolve(dtSub);
// c) Resolve all junctions (pipe ↔ pipe)
foreach (var junc in _junctions)
junc.Resolve(dtSub);
// d) Advance all pipes
foreach (var p in pipes)
p.SimulateSingleStep(dtSub);
foreach (var conn in _connections)
{
if (IsPipePort(conn.PortA) && IsVolumePort(conn.PortB))
{
var pipe = GetPipe(conn.PortA);
bool isA = pipe.PortA == conn.PortA;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
TransferAndIntegrate(conn.PortA, conn.PortB, dtSub);
}
else if (IsVolumePort(conn.PortA) && IsPipePort(conn.PortB))
{
var pipe = GetPipe(conn.PortB);
bool isA = pipe.PortB == conn.PortB;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
TransferAndIntegrate(conn.PortB, conn.PortA, dtSub);
}
}
if (sub < nSub - 1)
{
foreach (var v in _volumes)
v.PushStateToPort();
// 3. Clear ghost flags
foreach (var p in pipes)
p.ClearGhostFlags();
foreach (var conn in _connections)
{
if (IsPipePort(conn.PortA) && IsVolumePort(conn.PortB))
{
var pipe = GetPipe(conn.PortA);
bool isA = pipe.PortA == conn.PortA;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
SetVolumeBC(conn.PortA, conn.PortB);
}
else if (IsVolumePort(conn.PortA) && IsPipePort(conn.PortB))
{
var pipe = GetPipe(conn.PortB);
bool isA = pipe.PortB == conn.PortB;
if ((isA && pipe.ABCType == BoundaryType.VolumeCoupling) ||
(!isA && pipe.BBCType == BoundaryType.VolumeCoupling))
SetVolumeBC(conn.PortB, conn.PortA);
}
}
}
}
// 5. Audio samples (none for now, but placeholder)
var audioSamples = new List<float>();
foreach (var conn in _connections)
{
if (conn is SoundConnection sc)
audioSamples.Add(sc.GetAudioSample());
}
// 6. Clear BC flags
foreach (var p in _pipes)
p.ClearBC();
return SoundProcessor.MixAndClip(audioSamples.ToArray());
}
private bool IsVolumePort(Port p) => _volumes.Exists(v => v.Port == p);
private bool IsPipePort(Port p) => _pipes.Exists(pp => pp.PortA == p || pp.PortB == p);
private Pipe1D GetPipe(Port p) => _pipes.Find(pp => pp.PortA == p || pp.PortB == p);
private Volume0D GetVolume(Port p) => _volumes.Find(v => v.Port == p);
private void SetVolumeBC(Port pipePort, Port volPort)
{
var pipe = GetPipe(pipePort);
if (pipe == null) return;
bool isA = pipe.PortA == pipePort;
if (isA)
pipe.SetAVolumeState(volPort.Density, volPort.Pressure);
else
pipe.SetBVolumeState(volPort.Density, volPort.Pressure);
}
private void TransferAndIntegrate(Port pipePort, Port volPort, double dtSub)
{
double mdot = pipePort.MassFlowRate;
volPort.MassFlowRate = -mdot;
if (mdot < 0) // pipe → volume
{
volPort.SpecificEnthalpy = pipePort.SpecificEnthalpy;
}
// else volumes own enthalpy (from PushStateToPort) is used
GetVolume(volPort)?.Integrate(dtSub);
// 4. Integrate nonpipe components (volumes, atmosphere, etc.)
foreach (var comp in _components)
comp.UpdateState(_dt);
}
}
}

61
Core/SoundProcessor.cs
View File

@@ -1,23 +1,48 @@
namespace FluidSim.Core
{
/// <summary>
/// Mixes multiple audio samples and applies a softclipping tanh.
/// </summary>
public static class SoundProcessor
{
/// <summary>Overall gain applied after mixing (before tanh).</summary>
public static float MasterGain { get; set; } = 0.01f;
using System;
using FluidSim.Interfaces;
/// <summary>
/// Mixes an array of raw audio samples and returns a single sample in [1, 1].
/// </summary>
public static float MixAndClip(params float[] samples)
namespace FluidSim.Core
{
public class SoundProcessor
{
float sum = 0f;
foreach (float s in samples)
sum += s;
sum *= MasterGain;
return sum;
private readonly double dt;
private readonly double scaleFactor; // 1 / (4π r) and a user gain
private double prevMassFlowOut;
// Simple lowpass for derivative smoothing (≈ 23 ms)
private double smoothDMdt;
private readonly double alpha;
public float Gain { get; set; } = 1.0f;
public SoundProcessor(int sampleRate, double listenerDistanceMeters = 1.0)
{
dt = 1.0 / sampleRate;
scaleFactor = 1.0 / (4.0 * Math.PI * listenerDistanceMeters);
// Smoothing time constant ~ 2 ms, blocks singlesample spikes
double tau = 0.002;
alpha = Math.Exp(-dt / tau);
}
public float Process(Port port)
{
// Outflow mass flow (positive = leaving pipe)
double flowOut = -port.MassFlowRate;
// Derivative
double rawDerivative = (flowOut - prevMassFlowOut) / dt;
prevMassFlowOut = flowOut;
// Smooth the derivative to kill isolated spikes
smoothDMdt = alpha * smoothDMdt + (1.0 - alpha) * rawDerivative;
// Farfield monopole pressure
double pressure = smoothDMdt * scaleFactor * Gain;
// Soft clip to ±1 for audio output (safe limit)
float sample = (float)Math.Tanh(pressure);
return sample;
}
}
}

2
FluidSim.csproj
View File

@@ -5,7 +5,7 @@
<TargetFramework>net10.0</TargetFramework>
<ImplicitUsings>enable</ImplicitUsings>
<Nullable>enable</Nullable>
<PublishAot>true</PublishAot>
<PublishAot>false</PublishAot>
<InvariantGlobalization>true</InvariantGlobalization>
</PropertyGroup>

15
Interfaces/Connection.cs
View File

@@ -1,15 +0,0 @@
namespace FluidSim.Interfaces
{
/// <summary>Pure data link between two ports, with orifice parameters.</summary>
public class Connection
{
public Port PortA { get; }
public Port PortB { get; }
public double Area { get; set; } = 1e-5; // effective orifice area (m²)
public double DischargeCoefficient { get; set; } = 0.62;
public double Gamma { get; set; } = 1.4;
public Connection(Port a, Port b) => (PortA, PortB) = (a, b);
}
}

19
Interfaces/IComponent.cs Normal file
View File

@@ -0,0 +1,19 @@
using System.Collections.Generic;
namespace FluidSim.Interfaces
{
/// <summary>
/// Minimal interface for all simulation components that have ports.
/// </summary>
public interface IComponent
{
/// <summary>All ports exposed by this component.</summary>
IReadOnlyList<Port> Ports { get; }
/// <summary>
/// Called once per global time step to update the component's internal state
/// using the port flow data accumulated during substeps.
/// </summary>
void UpdateState(double dt);
}
}

16
Interfaces/Port.cs
View File

@@ -1,18 +1,28 @@
namespace FluidSim.Interfaces
{
/// <summary>
/// A fluid port that belongs to a component. The solver writes mass flow,
/// enthalpy, etc. here, and reads pressure, density, etc.
/// </summary>
public class Port
{
// Set by the solver during coupling resolution
public double MassFlowRate; // kg/s, positive INTO the component that owns this port
public double SpecificEnthalpy; // J/kg, enthalpy of the fluid crossing the port (inflow direction)
// Set by the owning component after integration to reflect its current state
public double Pressure; // Pa
public double MassFlowRate; // kg/s, positive INTO the component
public double SpecificEnthalpy; // J/kg, enthalpy of fluid entering this port
public double Density; // kg/m³
public double Temperature; // K
// Link back to owner (optional, but handy for debugging)
public object? Owner { get; set; }
public Port()
{
Pressure = 101325.0;
MassFlowRate = 0.0;
SpecificEnthalpy = 0.0;
Pressure = 101325.0;
Density = 1.225;
Temperature = 300.0;
}

25
Interfaces/SoundConnection.cs
View File

@@ -1,25 +0,0 @@
namespace FluidSim.Interfaces
{
/// <summary>
/// A Connection that also produces an audio sample from the pressure drop across it.
/// </summary>
public class SoundConnection : Connection
{
/// <summary>Gain applied to the normalised pressure difference.</summary>
public float Gain { get; set; } = 1.0f;
/// <summary>Reference pressure used for normalisation (Pa). Default: 1 atm.</summary>
public double ReferencePressure { get; set; } = 101325.0;
public SoundConnection(Port a, Port b) : base(a, b) { }
/// <summary>
/// Returns a normalised audio sample proportional to the pressure difference.
/// </summary>
public float GetAudioSample()
{
double dp = PortA.Pressure - PortB.Pressure;
return (float)(dp / ReferencePressure) * Gain;
}
}
}

70
Program.cs
View File

@@ -3,6 +3,7 @@ using SFML.Window;
using SFML.System;
using System.Diagnostics;
using FluidSim.Core;
using FluidSim.Tests;
namespace FluidSim;
@@ -12,37 +13,37 @@ public class Program
private const double DrawFrequency = 60.0;
private static Scenario scenario;
// Speed control
//private static double desiredSpeed = 1.0;
private static double desiredSpeed = 0.0001;
// Speed control (existing + new throttle)
private static double desiredSpeed = 0.01;
private static double currentSpeed = desiredSpeed;
private const double MinSpeed = 0.0001;
private const double MaxSpeed = 1.0;
private const double ScrollFactor = 1.1;
// Spacetoggle state
private static double lastDesiredSpeed = 0.1; // remembers the last non1.0 scroll speed
private static bool isRealTime = true; // true when desiredSpeed == 1.0
private static double lastDesiredSpeed = 0.1;
private static bool isRealTime = false;
// Throttle smoothing
private static double targetThrottle = 0.0; // 1.0 when W is pressed, 0.0 otherwise
private static double currentThrottle = 0.0;
private const double ThrottleSmoothing = 20.0; // rate of change
private static volatile bool running = true;
public static void Main()
{
var mode = new VideoMode(new Vector2u(1280, 720));
var window = new RenderWindow(mode, "Pipe Resonator");
var window = new RenderWindow(mode, "FluidSim - Engine (W = throttle)");
window.SetVerticalSyncEnabled(true);
window.Closed += (_, _) => { running = false; window.Close(); };
window.MouseWheelScrolled += OnMouseWheel;
window.KeyPressed += OnKeyPressed;
var soundEngine = new SoundEngine(bufferCapacity: 16384);
soundEngine.Volume = 70;
soundEngine.Volume = 100;
soundEngine.Start();
//scenario = new PipeResonatorScenario();
//scenario = new HelmholtzResonatorScenario();
scenario = new SodShockTubeScenario();
scenario = new TestScenario();
scenario.Initialize(SampleRate);
var stopwatch = Stopwatch.StartNew();
@@ -50,17 +51,13 @@ public class Program
double drawInterval = 1.0 / DrawFrequency;
double lastSpeedUpdateTime = stopwatch.Elapsed.TotalSeconds;
// Resampling buffer
List<float> simBuffer = new List<float>(4096);
var simBuffer = new List<float>(4096);
double readIndex = 0.0;
for (int i = 0; i < 4; i++)
simBuffer.Add(scenario.Process());
long totalSimSteps = simBuffer.Count;
long totalOutputSamples = 0;
double lastRealTime = stopwatch.Elapsed.TotalSeconds;
const int outputChunk = 256;
float[] outputBuf = new float[outputChunk];
@@ -69,17 +66,16 @@ public class Program
window.DispatchEvents();
double currentRealTime = stopwatch.Elapsed.TotalSeconds;
double dtSpeed = currentRealTime - lastSpeedUpdateTime;
double dtClock = currentRealTime - lastSpeedUpdateTime;
lastSpeedUpdateTime = currentRealTime;
// Smoothly transition currentSpeed → desiredSpeed
// When toggling, desiredSpeed jumps, but currentSpeed follows with a smooth lerp
double smoothingRate = 8.0; // higher = faster catchup
currentSpeed += (desiredSpeed - currentSpeed) * (1.0 - Math.Exp(-smoothingRate * dtSpeed));
// Smooth simulation speed
double speedSmoothing = 8.0;
currentSpeed += (desiredSpeed - currentSpeed) * (1.0 - Math.Exp(-speedSmoothing * dtClock));
// ---------- Generate audio ----------
// Generate audio
double targetAudioClock = currentRealTime + 0.05;
while (totalOutputSamples < targetAudioClock * SampleRate && running)
{
int toGenerate = (int)Math.Min(
@@ -101,11 +97,9 @@ public class Program
int i0 = (int)readIndex;
int i1 = i0 + 1;
double frac = readIndex - i0;
float y0 = simBuffer[Math.Clamp(i0, 0, simBuffer.Count - 1)];
float y1 = simBuffer[Math.Clamp(i1, 0, simBuffer.Count - 1)];
outputBuf[i] = (float)(y0 + (y1 - y0) * frac);
readIndex += currentSpeed;
while (readIndex >= 1.0 && simBuffer.Count > 2)
@@ -117,23 +111,23 @@ public class Program
int accepted = soundEngine.WriteSamples(outputBuf, toGenerate);
totalOutputSamples += accepted;
if (accepted < toGenerate)
break;
}
// ---------- Drawing & title ----------
// Drawing & title
if (currentRealTime - lastDrawTime >= drawInterval)
{
double actualSpeed = totalOutputSamples / (currentRealTime * SampleRate);
double simTime = totalSimSteps / (double)SampleRate;
string toggleHint = isRealTime ? "[Space] slow mo" : "[Space] real time";
string throttleHint = Keyboard.IsKeyPressed(Keyboard.Key.W) ? "W held" : "W released";
window.SetTitle(
$"{toggleHint} Sim: {simTime:F2}s | " +
$"Speed: {currentSpeed:F4}x → {desiredSpeed:F4}x | " +
$"Actual: {actualSpeed:F2}x"
$"{toggleHint} {throttleHint} " +
$"Thr: {currentThrottle:F2} " +
$"Speed: {currentSpeed:F3}x → {desiredSpeed:F3}x " +
$"Act: {actualSpeed:F2}x"
);
window.Clear(Color.Black);
scenario.Draw(window);
window.Display();
@@ -145,22 +139,18 @@ public class Program
window.Dispose();
}
// (Mouse wheel, space toggle unchanged)
private static void OnMouseWheel(object? sender, MouseWheelScrollEventArgs e)
{
bool wasRealTime = Math.Abs(desiredSpeed - 1.0) < 1e-6;
if (e.Delta > 0)
desiredSpeed *= ScrollFactor;
else if (e.Delta < 0)
desiredSpeed /= ScrollFactor;
desiredSpeed = Math.Clamp(desiredSpeed, MinSpeed, MaxSpeed);
// Update the remembered slow-mo speed (unless we are exactly at 1.0)
if (!wasRealTime || Math.Abs(desiredSpeed - 1.0) > 1e-6)
lastDesiredSpeed = desiredSpeed;
// Update isRealTime flag
isRealTime = Math.Abs(desiredSpeed - 1.0) < 1e-6;
}
@@ -169,15 +159,9 @@ public class Program
if (e.Code == Keyboard.Key.Space)
{
if (isRealTime)
{
// Switch to the remembered slow speed
desiredSpeed = lastDesiredSpeed;
}
else
{
// Switch back to real time
desiredSpeed = 1.0;
}
isRealTime = !isRealTime;
}
}

133
Scenarios/HelmholtzResonatorScenario.cs
View File

@@ -1,133 +0,0 @@
using System;
using FluidSim.Components;
using FluidSim.Interfaces;
using FluidSim.Utils;
using SFML.Graphics;
using SFML.System;
namespace FluidSim.Core
{
public class HelmholtzResonatorScenario : Scenario
{
private Solver solver;
private Volume0D cavity;
private Pipe1D neck;
private Connection coupling;
private int stepCount;
private double time;
private double dt;
private double ambientPressure = 1.0 * Units.atm;
public override void Initialize(int sampleRate)
{
dt = 1.0 / sampleRate;
// 1litre cavity, 10% overpressure
double cavityVolume = 1e-3;
double initialCavityPressure = 1.1 * ambientPressure;
cavity = new Volume0D(cavityVolume, initialCavityPressure, 300.0, sampleRate)
{
Gamma = 1.4,
GasConstant = 287.0
};
// Neck: length 10 cm, radius 1 cm
double neckLength = 0.1;
double neckRadius = 0.01;
double neckArea = Math.PI * neckRadius * neckRadius;
neck = new Pipe1D(neckLength, neckArea, sampleRate, forcedCellCount: 40);
neck.SetUniformState(1.225, 0.0, ambientPressure);
coupling = new Connection(neck.PortA, cavity.Port)
{
Area = neckArea,
DischargeCoefficient = 0.62,
Gamma = 1.4
};
solver = new Solver();
solver.SetTimeStep(dt);
solver.AddVolume(cavity);
solver.AddPipe(neck);
solver.AddConnection(coupling);
// Port A (left) = volume coupling, Port B (right) = open end
solver.SetPipeBoundary(neck, isA: true, BoundaryType.VolumeCoupling);
solver.SetPipeBoundary(neck, isA: false, BoundaryType.OpenEnd, ambientPressure);
}
public override float Process()
{
float sample = solver.Step();
time += dt;
stepCount++;
double pOpen = neck.GetCellPressure(neck.GetCellCount() - 1);
float audio = (float)((pOpen - ambientPressure) / ambientPressure);
if (stepCount % 20 == 0)
{
double pCav = cavity.Pressure;
double mdotA = neck.PortA.MassFlowRate; // positive = into pipe (leaving cavity)
Console.WriteLine(
$"t={time * 1e3:F2} ms step={stepCount} " +
$"P_cav={pCav:F1} Pa, P_open={pOpen:F1} Pa, " +
$"mdot_A={mdotA * 1e3:F4} g/s, audio={audio:F4}");
}
return audio;
}
public override void Draw(RenderWindow target)
{
float winW = target.GetView().Size.X;
float winH = target.GetView().Size.Y;
float centerY = winH / 2f;
// Cavity rectangle
float cavityWidth = 120f;
float cavityHeight = 180f;
var cavityRect = new RectangleShape(new Vector2f(cavityWidth, cavityHeight));
cavityRect.Position = new Vector2f(40f, centerY - cavityHeight / 2f);
cavityRect.FillColor = PressureColor(cavity.Pressure);
target.Draw(cavityRect);
// Neck drawn as tapered pipe
int n = neck.GetCellCount();
float neckStartX = 40f + cavityWidth + 10f;
float neckEndX = winW - 60f;
float neckLenPx = neckEndX - neckStartX;
float dx = neckLenPx / (n - 1);
float baseRadius = 20f;
Vertex[] vertices = new Vertex[n * 2];
for (int i = 0; i < n; i++)
{
float x = neckStartX + i * dx;
double p = neck.GetCellPressure(i);
float r = baseRadius * (float)(0.5 + 0.5 * Math.Tanh((p - ambientPressure) / (ambientPressure * 0.2)));
if (r < 4f) r = 4f;
Color col = PressureColor(p);
vertices[i * 2] = new Vertex(new Vector2f(x, centerY - r), col);
vertices[i * 2 + 1] = new Vertex(new Vector2f(x, centerY + r), col);
}
target.Draw(vertices, PrimitiveType.TriangleStrip);
// Open end indicator
var arrow = new CircleShape(8f);
arrow.Position = new Vector2f(neckEndX - 4f, centerY - 4f);
arrow.FillColor = Color.White;
target.Draw(arrow);
}
private Color PressureColor(double pressure)
{
double range = ambientPressure * 0.1;
double t = Math.Clamp((pressure - ambientPressure) / range, -1.0, 1.0);
byte r = (byte)(t > 0 ? 255 * t : 0);
byte b = (byte)(t < 0 ? -255 * t : 0);
byte g = (byte)(255 * (1 - Math.Abs(t)));
return new Color(r, g, b);
}
}
}

184
Scenarios/PipeResonatorScenario.cs
View File

@@ -1,184 +0,0 @@
using FluidSim.Components;
using FluidSim.Interfaces;
using FluidSim.Utils;
using SFML.Graphics;
using SFML.System;
using System;
namespace FluidSim.Core
{
public class PipeResonatorScenario : Scenario
{
private Solver solver;
private Pipe1D pipe;
private int stepCount;
private double time;
private double dt;
private double ambientPressure = 1.0 * Units.atm;
private bool enableLogging = true;
public override void Initialize(int sampleRate)
{
dt = 1.0 / sampleRate;
double length = 2;
double radius = 50 * Units.mm;
double area = Units.AreaFromDiameter(radius);
pipe = new Pipe1D(length, area, sampleRate, forcedCellCount: 80);
pipe.SetUniformState(1.225, 0.0, ambientPressure);
solver = new Solver();
solver.SetTimeStep(dt);
solver.AddPipe(pipe);
// Open end at port A (left), closed end at port B (right)
solver.SetPipeBoundary(pipe, isA: true, BoundaryType.OpenEnd, ambientPressure);
solver.SetPipeBoundary(pipe, isA: false, BoundaryType.ClosedEnd);
// Initial pressure pulse
int pulseCells = 5;
double pulsePressure = 2 * ambientPressure;
for (int i = 0; i < pulseCells; i++)
pipe.SetCellState(i, 1.225, 0.0, pulsePressure);
}
public override float Process()
{
float sample = solver.Step();
time += dt;
stepCount++;
double pMid = pipe.GetPressureAtFraction(0.5);
sample = (float)((pMid - ambientPressure) / ambientPressure);
Log(sample);
return sample;
}
private void Log(float sample)
{
if (!enableLogging) return;
if (stepCount % 10 == 0 && stepCount < 1000)
{
double pMid = pipe.GetPressureAtFraction(0.5);
double pOpen = pipe.GetCellPressure(0);
double pClosed = pipe.GetCellPressure(pipe.GetCellCount() - 1);
Console.WriteLine(
$"t = {time * 1e3:F3} ms Step {stepCount:D4}: " +
$"sample = {sample:F3}, " +
$"P_mid = {pMid:F2} Pa ({pMid / ambientPressure:F4} atm), " +
$"P_open = {pOpen:F2} Pa, P_closed = {pClosed:F2} Pa");
}
}
public override void Draw(RenderWindow target)
{
float winWidth = target.GetView().Size.X;
float winHeight = target.GetView().Size.Y;
float pipeCenterY = winHeight / 2f;
float margin = 60f;
float pipeStartX = margin;
float pipeEndX = winWidth - margin;
float pipeLengthPx = pipeEndX - pipeStartX;
int n = pipe.GetCellCount();
float dx = pipeLengthPx / (n - 1); // spacing between cell centres
float baseRadius = 25f;
float rangeFactor = 1f;
float scaleFactor = 5f;
// ----- smoothstep helper -----
static float SmoothStep(float edge0, float edge1, float x)
{
float t = Math.Clamp((x - edge0) / (edge1 - edge0), 0f, 1f);
return t * t * (3f - 2f * t);
}
// ----- Precompute cell positions and radii -----
var centers = new float[n];
var radii = new float[n];
for (int i = 0; i < n; i++)
{
double p = pipe.GetCellPressure(i);
float deviation = (float)Math.Tanh((p - ambientPressure) / ambientPressure / rangeFactor);
radii[i] = baseRadius * (1f + deviation * scaleFactor);
if (radii[i] < 2f) radii[i] = 2f;
centers[i] = pipeStartX + i * dx;
}
// ----- Build trianglestrip vertices -----
int segmentsPerCell = 8; // smoothness
int totalPoints = n + (n - 1) * segmentsPerCell;
Vertex[] stripVertices = new Vertex[totalPoints * 2]; // top + bottom for each point
int idx = 0;
for (int i = 0; i < n; i++)
{
// ---- Cell centre ----
float x = centers[i];
float r = radii[i];
double p = pipe.GetCellPressure(i);
Color col = PressureColor(p);
stripVertices[idx++] = new Vertex(new Vector2f(x, pipeCenterY - r), col);
stripVertices[idx++] = new Vertex(new Vector2f(x, pipeCenterY + r), col);
// ---- Intermediate segments after this cell (if not last) ----
if (i < n - 1)
{
for (int s = 1; s <= segmentsPerCell; s++)
{
float t = s / (float)segmentsPerCell;
float st = SmoothStep(0f, 1f, t);
float xi = centers[i] + (centers[i + 1] - centers[i]) * t;
float ri = radii[i] + (radii[i + 1] - radii[i]) * st;
double pi = pipe.GetCellPressure(i) * (1 - t) + pipe.GetCellPressure(i + 1) * t;
Color coli = PressureColor(pi);
stripVertices[idx++] = new Vertex(new Vector2f(xi, pipeCenterY - ri), coli);
stripVertices[idx++] = new Vertex(new Vector2f(xi, pipeCenterY + ri), coli);
}
}
}
// Draw the pipe as a triangle strip
var pipeMesh = new VertexArray(PrimitiveType.TriangleStrip, (uint)stripVertices.Length);
for (int i = 0; i < stripVertices.Length; i++)
pipeMesh[(uint)i] = stripVertices[i];
target.Draw(pipeMesh);
// ----- Closed end indicator (right) -----
float wallThickness = 8f;
var wall = new RectangleShape(new Vector2f(wallThickness, winHeight * 0.6f));
wall.Position = new Vector2f(pipeEndX, pipeCenterY - winHeight * 0.6f / 2f);
wall.FillColor = new Color(180, 180, 180);
target.Draw(wall);
}
/// <summary>Blue (low) → Green (ambient) → Red (high).</summary>
private Color PressureColor(double pressure)
{
double range = ambientPressure * 0.05; // ±5% gives full colour swing
double t = (pressure - ambientPressure) / range;
t = Math.Clamp(t, -1.0, 1.0);
byte r, g, b;
if (t < 0)
{
double factor = -t;
r = 0;
g = (byte)(255 * (1 - factor));
b = (byte)(255 * factor);
}
else
{
double factor = t;
r = (byte)(255 * factor);
g = (byte)(255 * (1 - factor));
b = 0;
}
return new Color(r, g, b);
}
}
}

122
Scenarios/Scenario.cs
View File

@@ -1,23 +1,121 @@
using SFML.Graphics;
using System;
using SFML.Graphics;
using SFML.System;
using FluidSim.Components;
namespace FluidSim.Core
namespace FluidSim.Tests
{
public abstract class Scenario
{
/// <summary>
/// Initialize the scenario with a given audio sample rate.
/// </summary>
/// <summary>Initialize the scenario with a given audio sample rate.</summary>
public abstract void Initialize(int sampleRate);
/// <summary>
/// Advance one simulation step and return an audio sample.
/// The step size is 1 / sampleRate seconds.
/// </summary>
/// <summary>Advance one simulation step and return an audio sample.</summary>
public abstract float Process();
/// <summary>
/// Draw the current simulation state onto the given SFML render target.
/// </summary>
/// <summary>Draw the current simulation state onto the given SFML render target.</summary>
public abstract void Draw(RenderWindow target);
// ---------- Shared drawing helpers ----------
protected const double AmbientPressure = 101325.0;
/// <summary>Blue (low) → Green (ambient) → Red (high).</summary>
protected Color PressureColor(double pressure)
{
double range = AmbientPressure * 0.05; // ±5% gives full colour swing
double t = (pressure - AmbientPressure) / range;
t = Math.Clamp(t, -1.0, 1.0);
byte r, g, b;
if (t < 0)
{
double factor = -t;
r = 0;
g = (byte)(255 * (1 - factor));
b = (byte)(255 * factor);
}
else
{
double factor = t;
r = (byte)(255 * factor);
g = (byte)(255 * (1 - factor));
b = 0;
}
return new Color(r, g, b);
}
/// <summary>
/// Draws the pipe as a smooth trianglestrip whose radius varies with cell pressure.
/// </summary>
protected void DrawPipe(RenderWindow target, Pipe1D pipe, float pipeCenterY, float pipeStartX, float pipeEndX)
{
int n = pipe.CellCount;
if (n < 2) return;
float pipeLengthPx = pipeEndX - pipeStartX;
float dx = pipeLengthPx / (n - 1); // spacing between cell centres
float baseRadius = 25f;
float rangeFactor = 1f;
float scaleFactor = 5f;
// ----- smoothstep helper -----
static float SmoothStep(float edge0, float edge1, float x)
{
float t = Math.Clamp((x - edge0) / (edge1 - edge0), 0f, 1f);
return t * t * (3f - 2f * t);
}
// ----- Precompute cell positions and radii -----
var centers = new float[n];
var radii = new float[n];
for (int i = 0; i < n; i++)
{
double p = pipe.GetCellPressure(i);
float deviation = (float)Math.Tanh((p - AmbientPressure) / AmbientPressure / rangeFactor);
radii[i] = baseRadius * (1f + deviation * scaleFactor);
if (radii[i] < 2f) radii[i] = 2f;
centers[i] = pipeStartX + i * dx;
}
// ----- Build trianglestrip vertices -----
int segmentsPerCell = 8;
int totalPoints = n + (n - 1) * segmentsPerCell;
Vertex[] stripVertices = new Vertex[totalPoints * 2];
int idx = 0;
for (int i = 0; i < n; i++)
{
float x = centers[i];
float r = radii[i];
double p = pipe.GetCellPressure(i);
Color col = PressureColor(p);
stripVertices[idx++] = new Vertex(new Vector2f(x, pipeCenterY - r), col);
stripVertices[idx++] = new Vertex(new Vector2f(x, pipeCenterY + r), col);
if (i < n - 1)
{
for (int s = 1; s <= segmentsPerCell; s++)
{
float t = s / (float)segmentsPerCell;
float st = SmoothStep(0f, 1f, t);
float xi = centers[i] + (centers[i + 1] - centers[i]) * t;
float ri = radii[i] + (radii[i + 1] - radii[i]) * st;
double pi = pipe.GetCellPressure(i) * (1 - t) + pipe.GetCellPressure(i + 1) * t;
Color coli = PressureColor(pi);
stripVertices[idx++] = new Vertex(new Vector2f(xi, pipeCenterY - ri), coli);
stripVertices[idx++] = new Vertex(new Vector2f(xi, pipeCenterY + ri), coli);
}
}
}
var pipeMesh = new VertexArray(PrimitiveType.TriangleStrip, (uint)stripVertices.Length);
for (int i = 0; i < stripVertices.Length; i++)
pipeMesh[(uint)i] = stripVertices[i];
target.Draw(pipeMesh);
}
}
}

158
Scenarios/SodShockTubeScenario.cs
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using System;
using FluidSim.Components;
using FluidSim.Utils;
using SFML.Graphics;
using SFML.System;
namespace FluidSim.Core
{
public class SodShockTubeScenario : Scenario
{
private Solver solver;
private Pipe1D pipe;
private int stepCount;
private double time;
private double dt;
private double ambientPressure = 1.0 * Units.atm;
private const double GasConstant = 287.0;
public override void Initialize(int sampleRate)
{
dt = 1.0 / sampleRate;
double length = 1.0;
double area = 1.0;
int nCells = 200;
pipe = new Pipe1D(length, area, sampleRate, forcedCellCount: nCells);
pipe.SetUniformState(0.125, 0.0, 0.1 * ambientPressure); // right state
// Left half high pressure
for (int i = 0; i < nCells / 2; i++)
pipe.SetCellState(i, 1.0, 0.0, ambientPressure);
solver = new Solver();
solver.SetTimeStep(dt);
solver.AddPipe(pipe);
solver.SetPipeBoundary(pipe, isA: true, BoundaryType.ClosedEnd);
solver.SetPipeBoundary(pipe, isA: false, BoundaryType.ClosedEnd);
}
public override float Process()
{
float sample = solver.Step();
time += dt;
stepCount++;
double pMid = pipe.GetPressureAtFraction(0.5);
float audio = (float)((pMid - ambientPressure) / ambientPressure);
bool log = true;
if (log)
{
int n = pipe.GetCellCount();
Console.WriteLine($"step {stepCount}:");
Console.WriteLine("i rho (kg/m³) p (Pa) T (K) u (m/s)");
for (int i = 0; i < n; i++)
{
if (i % 10 == 0)
{
double rho = pipe.GetCellDensity(i);
double p = pipe.GetCellPressure(i);
double u = pipe.GetCellVelocity(i);
double T = p / (rho * GasConstant); // GasConstant = 287.0
Console.WriteLine($"{i,-4} {rho,10:F4} {p,10:F1} {T,8:F2} {u,10:F4}");
}
}
Console.WriteLine();
}
return audio;
}
public override void Draw(RenderWindow target)
{
float winW = target.GetView().Size.X;
float winH = target.GetView().Size.Y;
float centerY = winH / 2f;
float margin = 40f;
float pipeStartX = margin;
float pipeEndX = winW - margin;
float pipeLenPx = pipeEndX - pipeStartX;
int n = pipe.GetCellCount();
float dx = pipeLenPx / (n - 1);
float baseRadius = 60f;
Vertex[] vertices = new Vertex[n * 2];
for (int i = 0; i < n; i++)
{
float x = pipeStartX + i * dx;
double p = pipe.GetCellPressure(i);
double rho = pipe.GetCellDensity(i);
double T = p / (rho * GasConstant); // temperature in Kelvin
// Radius from pressure (exaggerated deviation)
float r = baseRadius * (float)(p / ambientPressure * 2);
if (r < 4f) r = 4f;
// Colour from temperature
Color col = TemperatureColor(T);
vertices[i * 2] = new Vertex(new Vector2f(x, centerY - r), col);
vertices[i * 2 + 1] = new Vertex(new Vector2f(x, centerY + r), col);
}
target.Draw(vertices, PrimitiveType.TriangleStrip);
// Diaphragm marker (faint white line at initial interface)
float diaphragmX = pipeStartX + (n / 2) * dx;
var line = new RectangleShape(new Vector2f(2f, winH * 0.5f));
line.Position = new Vector2f(diaphragmX - 1f, centerY - winH * 0.25f);
line.FillColor = new Color(255, 255, 255, 80);
target.Draw(line);
}
/// <summary>
/// Custom temperaturetohue mapping that matches the given Sodtube hue values:
/// 250K → 176, 300K → 122, 350K → 120?, 450K → 71.
/// Interpolates piecewise linearly, clamping outside [250,450].
/// </summary>
private Color TemperatureColor(double T)
{
// 1. Map temperature to hue (0360)
double[] Tknots = { 250, 282, 353, 450 };
double[] Hknots = { 176, 179, 122, 71 };
double hue;
if (T <= Tknots[0]) hue = Hknots[0];
else if (T >= Tknots[^1]) hue = Hknots[^1];
else
{
int i = 0;
while (i < Tknots.Length - 1 && T > Tknots[i + 1]) i++;
double frac = (T - Tknots[i]) / (Tknots[i + 1] - Tknots[i]);
hue = Hknots[i] + frac * (Hknots[i + 1] - Hknots[i]);
}
// 2. Convert hue to RGB (S = 1, V = 1)
double h = hue / 60.0;
int sector = (int)Math.Floor(h);
double f = h - sector;
byte p = 0;
byte q = (byte)(255 * (1 - f));
byte tByte = (byte)(255 * f);
byte v = 255;
byte r, g, b;
switch (sector % 6)
{
case 0: r = v; g = tByte; b = p; break;
case 1: r = q; g = v; b = p; break;
case 2: r = p; g = v; b = tByte; break;
case 3: r = p; g = q; b = v; break;
case 4: r = tByte; g = p; b = v; break;
default: r = v; g = p; b = q; break;
}
return new Color(r, g, b);
}
}
}

96
Scenarios/TestScenario.cs Normal file
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using System;
using SFML.Graphics;
using SFML.System;
using FluidSim.Components;
using FluidSim.Core;
namespace FluidSim.Tests
{
public class TestScenario : Scenario
{
private Solver solver;
private Volume0D volume;
private Pipe1D pipe;
private Atmosphere atmosphere;
private OrificeLink orificeLink;
private OpenEndLink openEndLink;
private int stepCount;
public override void Initialize(int sampleRate)
{
double dt = 1.0 / sampleRate;
solver = new Solver();
solver.SetTimeStep(dt);
volume = new Volume0D(1e-3, 150000.0, 300.0);
solver.AddComponent(volume);
pipe = new Pipe1D(2.0, 1e-4, 20);
solver.AddComponent(pipe);
atmosphere = new Atmosphere();
solver.AddComponent(atmosphere);
// Volume → left pipe end (orifice)
var volPort = volume.CreatePort();
orificeLink = new OrificeLink(volPort, pipe, isPipeLeftEnd: true, areaProvider: () => 1e-5)
{
DischargeCoefficient = 0.62,
Gamma = volume.Gamma,
GasConstant = volume.GasConstant
};
solver.AddOrificeLink(orificeLink);
// Right pipe end → atmosphere (characteristic openend)
openEndLink = new OpenEndLink(pipe, isLeftEnd: false)
{
AmbientPressure = 101325.0,
Gamma = 1.4
};
solver.AddOpenEndLink(openEndLink);
stepCount = 0;
Console.WriteLine("TestScenario initialized with sampleRate = " + sampleRate);
}
public override float Process()
{
solver.Step();
stepCount++;
if (stepCount % 100 == 0)
{
double volPressure = volume.Pressure;
double volMass = volume.Mass;
double pipeLeftPressure = pipe.GetCellPressure(0);
double pipeRightPressure = pipe.GetCellPressure(pipe.CellCount - 1);
double mdotOrifice = orificeLink.LastMassFlowRate;
double mdotOpen = openEndLink.LastMassFlowRate;
Console.WriteLine($"Step {stepCount}:");
Console.WriteLine($" Vol Pressure = {volPressure:F1} Pa, Mass = {volMass:E4} kg");
Console.WriteLine($" Pipe left P = {pipeLeftPressure:F1} Pa, right P = {pipeRightPressure:F1} Pa");
Console.WriteLine($" Orifice mdot = {mdotOrifice:E4} kg/s, Openend mdot = {mdotOpen:E4} kg/s");
Console.WriteLine();
}
// Audio sample from the openend mass flow
return (float)openEndLink.LastMassFlowRate;
}
public override void Draw(RenderWindow target)
{
float winWidth = target.GetView().Size.X;
float winHeight = target.GetView().Size.Y;
float pipeCenterY = winHeight / 2f;
float margin = 60f;
float pipeStartX = margin;
float pipeEndX = winWidth - margin;
// Use the shared pipe drawing from the base class
DrawPipe(target, pipe, pipeCenterY, pipeStartX, pipeEndX);
}
}
}

10
Sources/EffortSource.cs
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using System;
using System.Collections.Generic;
using System.Text;
namespace FluidSim.Sources
{
internal class EffortSource
{
}
}

10
Sources/FlowSource.cs
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using System;
using System.Collections.Generic;
using System.Text;
namespace FluidSim.Sources
{
internal class FlowSource
{
}
}