public Particle(int Dim, double[] startPos = null, double startAngl = 0.0)
{
SpatialDim = Dim;
// Particle history
// =============================
for (int i = 0; i < m_HistoryLength; i++)
{
Position.Add(new double[Dim]);
Angle.Add(new double());
TranslationalVelocity.Add(new double[Dim]);
TranslationalAcceleration.Add(new double[Dim]);
RotationalVelocity.Add(new double());
RotationalAcceleration.Add(new double());
HydrodynamicForces.Add(new double[Dim]);
HydrodynamicTorque.Add(new double());
}
// =============================
if (startPos == null)
{
startPos = new double[Dim];
}
Position[0] = startPos;
Position[1] = startPos;
//From degree to radiant
Angle[0] = StartingAngle = startAngl * 2 * Math.PI / 360;
Angle[1] = startAngl * 2 * Math.PI / 360;
//UpdateLevelSetFunction();
}
/// <summary>
/// The standard description of motion including hydrodynamics.
/// </summary>
/// <param name="gravity">
/// The gravity (volume forces) acting on the particle.
/// </param>
/// <param name="density">
/// The density of the particle.
/// </param>
public Motion(Vector gravity, double density)
{
if (gravity.IsNullOrEmpty())
{
gravity = new Vector(0, 0);
}
Gravity = new Vector(gravity);
Density = density;
for (int i = 0; i < NumberOfHistoryEntries; i++)
{
Position.Add(new Vector(SpatialDim));
TranslationalVelocity.Add(new Vector(SpatialDim));
TranslationalAcceleration.Add(new Vector(SpatialDim));
HydrodynamicForces.Add(new Vector(SpatialDim));
Angle.Add(new double());
RotationalVelocity.Add(new double());
RotationalAcceleration.Add(new double());
HydrodynamicTorque.Add(new double());
}
}
