/// Perform disc-terrain collision detection.
/// This utility function checks for contact between a disc of specified
/// radius with given position and orientation (specified as the location of
/// its center and a unit vector normal to the disc plane) and the terrain
/// system associated with this tire. It returns true if the disc contacts the
/// terrain and false otherwise. If contact occurs, it returns a coordinate
/// system with the Z axis along the contact normal and the X axis along the
/// "rolling" direction, as well as a positive penetration depth (i.e. the
/// height below the terrain of the lowest point on the disc).
protected static bool disc_terrain_contact(
ChTerrain terrain, ///< [in] reference to terrain system
ChVector disc_center, ///< [in] global location of the disc center
ChVector disc_normal, ///< [in] disc normal, expressed in the global frame
double disc_radius, ///< [in] disc radius
ref ChCoordsys contact, ///< [out] contact coordinate system (relative to the global frame)
ref double depth ///< [out] penetration depth (positive if contact occurred)
)
{
// Find terrain height below disc center. There is no contact if the disc
// center is below the terrain or farther away by more than its radius.
double hc = terrain.GetHeight(disc_center.x, disc_center.y);
if (disc_center.z <= hc || disc_center.z >= hc + disc_radius)
{
return(false);
}
// Find the lowest point on the disc. There is no contact if the disc is
// (almost) horizontal.
ChVector nhelp = terrain.GetNormal(disc_center.x, disc_center.y);
ChVector dir1 = ChVector.Vcross(disc_normal, nhelp);
double sinTilt2 = dir1.Length2();
if (sinTilt2 < 1e-3)
{
return(false);
}
// Contact point (lowest point on disc).
ChVector ptD = disc_center + disc_radius * ChVector.Vcross(disc_normal, dir1 / Math.Sqrt(sinTilt2));
// Find terrain height at lowest point. No contact if lowest point is above
// the terrain.
double hp = terrain.GetHeight(ptD.x, ptD.y);
if (ptD.z > hp)
{
return(false);
}
// Approximate the terrain with a plane. Define the projection of the lowest
// point onto this plane as the contact point on the terrain.
ChVector normal = terrain.GetNormal(ptD.x, ptD.y);
ChVector longitudinal = ChVector.Vcross(disc_normal, normal);
longitudinal.Normalize();
ChVector lateral = ChVector.Vcross(normal, longitudinal);
ChMatrix33 <double> rot = new ChMatrix33 <double>(0); // Need to nest this.
rot.Set_A_axis(longitudinal, lateral, normal);
contact.pos = ptD;
contact.rot = rot.Get_A_quaternion();
depth = ChVector.Vdot(new ChVector(0, 0, hp - ptD.z), normal);
//assert(depth > 0);
return(true);
}
/// Collsion algorithm based on a paper of J. Shane Sui and John A. Hirshey II:
/// "A New Analytical Tire Model for Vehicle Dynamic Analysis" presented at 2001 MSC User Meeting
public static bool DiscTerrainCollisionEnvelope(
ChTerrain terrain, ///< [in] reference to terrain system
ChVector disc_center, ///< [in] global location of the disc center
ChVector disc_normal, ///< [in] disc normal, expressed in the global frame
double disc_radius, ///< [in] disc radius
ChFunction_Recorder areaDep, ///< [in] lookup table to calculate depth from intersection area
ref ChCoordsys contact, ///< [out] contact coordinate system (relative to the global frame)
ref double depth ///< [out] penetration depth (positive if contact occurred)
)
{
return(false);
}
public override void SyncPosition()
{
ChCoordsys mcsys = this.mcontactable.GetCsysForCollisionModel();
bt_collision_object.GetWorldTransform()._origin = new IndexedVector3(
(float)mcsys.pos.x, (float)mcsys.pos.y, (float)mcsys.pos.z);
ChMatrix33 <double> rA = new ChMatrix33 <double>(mcsys.rot);
IndexedBasisMatrix basisA = new IndexedBasisMatrix((float)rA.nm.matrix[0, 0], (float)rA.nm.matrix[0, 1], (float)rA.nm.matrix[0, 2], (float)rA.nm.matrix[1, 0],
(float)rA.nm.matrix[1, 1], (float)rA.nm.matrix[1, 2], (float)rA.nm.matrix[2, 0], (float)rA.nm.matrix[2, 1],
(float)rA.nm.matrix[2, 2]);
bt_collision_object.GetWorldTransform()._basis = basisA;
}
/// Calculate kinematics quantities based on the current state of the associated
/// wheel body.
public void CalculateKinematics(double time, ///< [in] current time
ChSubsysDefs.WheelState state, ///< [in] current state of associated wheel body
RigidTerrain terrain ///< [in] reference to the terrain system
)
{
// Wheel normal (expressed in global frame)
ChVector wheel_normal = state.rot.GetYaxis();
// Terrain normal at wheel location (expressed in global frame)
ChVector Z_dir = terrain.GetNormal(state.pos.x, state.pos.y);
// Longitudinal (heading) and lateral directions, in the terrain plane
ChVector X_dir = ChVector.Vcross(wheel_normal, Z_dir);
X_dir.Normalize();
ChVector Y_dir = ChVector.Vcross(Z_dir, X_dir);
// Tire reference coordinate system
// ChMatrix33<double> rot = new ChMatrix33<double>(0); // Needs nesting
rot.Set_A_axis(X_dir, Y_dir, Z_dir);
ChCoordsys tire_csys = new ChCoordsys(state.pos, rot.Get_A_quaternion());
// Express wheel linear velocity in tire frame
ChVector V = tire_csys.TransformDirectionParentToLocal(state.lin_vel);
// Express wheel normal in tire frame
ChVector n = tire_csys.TransformDirectionParentToLocal(wheel_normal);
// Slip angle
double abs_Vx = Mathfx.Abs(V.x);
double zero_Vx = 1e-4;
m_slip_angle = (abs_Vx > zero_Vx) ? Math.Atan(V.y / abs_Vx) : 0;
// Longitudinal slip
m_longitudinal_slip = (abs_Vx > zero_Vx) ? -(V.x - state.omega * GetRadius()) / abs_Vx : 0;
// Camber angle
m_camber_angle = Math.Atan2(n.z, n.y);
}
/// Perform disc-terrain collision detection considering the curvature of the road
/// surface. The surface normal is calculated based on 4 different height values below
/// the wheel center. The effective height is calculated as average value of the four
/// height values.
/// This utility function checks for contact between a disc of specified
/// radius with given position and orientation (specified as the location of
/// its center and a unit vector normal to the disc plane) and the terrain
/// system associated with this tire. It returns true if the disc contacts the
/// terrain and false otherwise. If contact occurs, it returns a coordinate
/// system with the Z axis along the contact normal and the X axis along the
/// "rolling" direction, as well as a positive penetration depth (i.e. the
/// height below the terrain of the lowest point on the disc).
public bool DiscTerrainCollision4pt(
RigidTerrain terrain, ///< [in] reference to terrain system
ChVector disc_center, ///< [in] global location of the disc center
ChVector disc_normal, ///< [in] disc normal, expressed in the global frame
double disc_radius, ///< [in] disc radius
double width, ///< [in] tire width
ref ChCoordsys contact, ///< [out] contact coordinate system (relative to the global frame)
ref double depth, ///< [out] penetration depth (positive if contact occurred)
ref double camber_angle ///< [out] tire camber angle
)
{
double dx = 0.1 * disc_radius;
double dy = 0.3 * width;
// Find terrain height below disc center. There is no contact if the disc
// center is below the terrain or farther away by more than its radius.
double hc = terrain.GetHeight(disc_center.x, disc_center.z);
if (disc_center.y <= hc || disc_center.y >= hc + disc_radius)
{
return(false);
}
// Find the lowest point on the disc. There is no contact if the disc is
// (almost) horizontal.
ChVector dir1 = ChVector.Vcross(disc_normal, new ChVector(0, 1, 0));
double sinTilt2 = dir1.Length2();
if (sinTilt2 < 1e-3)
{
return(false);
}
// Contact point (lowest point on disc).
ChVector ptD = disc_center + disc_radius * ChVector.Vcross(disc_normal, dir1 / Math.Sqrt(sinTilt2));
// Approximate the terrain with a plane. Define the projection of the lowest
// point onto this plane as the contact point on the terrain.
ChVector normal = terrain.GetNormal(ptD.x, ptD.z);
ChVector longitudinal = ChVector.Vcross(disc_normal, normal);
longitudinal.Normalize();
ChVector lateral = ChVector.Vcross(normal, longitudinal);
// Calculate four contact points in the contact patch
ChVector ptQ1 = ptD + dx * longitudinal;
ptQ1.y = terrain.GetHeight(ptQ1.x, ptQ1.z);
ChVector ptQ2 = ptD - dx * longitudinal;
ptQ2.y = terrain.GetHeight(ptQ2.x, ptQ2.z);
ChVector ptQ3 = ptD + dy * lateral;
ptQ3.y = terrain.GetHeight(ptQ3.x, ptQ3.z);
ChVector ptQ4 = ptD - dy * lateral;
ptQ4.y = terrain.GetHeight(ptQ4.x, ptQ4.z);
// Calculate a smoothed road surface normal
ChVector rQ2Q1 = ptQ1 - ptQ2;
ChVector rQ4Q3 = ptQ3 - ptQ4;
ChVector terrain_normal = ChVector.Vcross(rQ2Q1, rQ4Q3);
terrain_normal.Normalize();
// Find terrain height as average of four points. No contact if lowest point is above
// the terrain.
ptD = 0.25 * (ptQ1 + ptQ2 + ptQ3 + ptQ4);
ChVector d = ptD - disc_center;
double da = d.Length();
if (da >= disc_radius)
{
return(false);
}
// Calculate an improved value for the camber angle
camber_angle = Math.Asin(ChVector.Vdot(disc_normal, terrain_normal));
// ChMatrix33<double> rot = new ChMatrix33<double>(0);
rot.Set_A_axis(longitudinal, lateral, terrain_normal);
contact.pos = ptD;
contact.rot = rot.Get_A_quaternion();
depth = disc_radius - da;
// assert(depth > 0);
return(true);
}
