Exemplo n.º 1
0
void CustomCorkScrew::SubmitConstraints (dFloat timestep, int threadIndex)
{
	dMatrix matrix0;
	dMatrix matrix1;

	// calculate the position of the pivot point and the Jacobian direction vectors, in global space. 
	CalculateGlobalMatrix (matrix0, matrix1);

	// Restrict the movement on the pivot point along all two orthonormal axis direction perpendicular to the motion
	NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix0.m_up[0]);
	NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix0.m_right[0]);
	
	// two rows to restrict rotation around around the parent coordinate system
	dFloat sinAngle;
	dFloat cosAngle;
	CalculateYawAngle(matrix0, matrix1, sinAngle, cosAngle);
	NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &matrix1.m_up[0]);

	CalculateRollAngle(matrix0, matrix1, sinAngle, cosAngle);
	NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &matrix1.m_right[0]);

	// if limit are enable ...
	if (m_limitsLinearOn) {
		dFloat dist = (matrix0.m_posit - matrix1.m_posit) % matrix0.m_front;
		if (dist < m_minLinearDist) {
			// get a point along the up vector and set a constraint  
			NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix0.m_posit[0], &matrix0.m_front[0]);
			// allow the object to return but not to kick going forward
			NewtonUserJointSetRowMinimumFriction (m_joint, 0.0f);
			
			
		} else if (dist > m_maxLinearDist) {
			// get a point along the up vector and set a constraint  
			NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix0.m_posit[0], &matrix0.m_front[0]);
			// allow the object to return but not to kick going forward
			NewtonUserJointSetRowMaximumFriction (m_joint, 0.0f);
		}
	}

	CalculatePitchAngle (matrix0, matrix1, sinAngle, cosAngle);
	dFloat angle = -m_curJointAngle.Update (cosAngle, sinAngle);

	if (m_limitsAngularOn) {
		// the joint angle can be determine by getting the angle between any two non parallel vectors
		if (angle < m_minAngularDist) {
			dFloat relAngle = angle - m_minAngularDist;
			// the angle was clipped save the new clip limit
			//m_curJointAngle.m_angle = m_minAngularDist;

			// tell joint error will minimize the exceeded angle error
			NewtonUserJointAddAngularRow (m_joint, relAngle, &matrix0.m_front[0]);

			// need high stiffness here
			NewtonUserJointSetRowStiffness (m_joint, 1.0f);

			// allow the joint to move back freely 
			NewtonUserJointSetRowMaximumFriction (m_joint, 0.0f);


		} else if (angle  > m_maxAngularDist) {
			dFloat relAngle = angle - m_maxAngularDist;

			// the angle was clipped save the new clip limit
			//m_curJointAngle.m_angle = m_maxAngularDist;

			// tell joint error will minimize the exceeded angle error
			NewtonUserJointAddAngularRow (m_joint, relAngle, &matrix0.m_front[0]);

			// need high stiffness here
			NewtonUserJointSetRowStiffness (m_joint, 1.0f);

			// allow the joint to move back freely
			NewtonUserJointSetRowMinimumFriction (m_joint, 0.0f);
		}
	}

	if (m_angularmotorOn) {
		dVector omega0 (0.0f, 0.0f, 0.0f);
		dVector omega1 (0.0f, 0.0f, 0.0f);

		// get relative angular velocity
		NewtonBodyGetOmega(m_body0, &omega0[0]);
		if (m_body1) {
			NewtonBodyGetOmega(m_body1, &omega1[0]);
		}

		// calculate the desired acceleration
		dFloat relOmega = (omega0 - omega1) % matrix0.m_front;
		dFloat relAccel = m_angularAccel - m_angularDamp * relOmega;

		// if the motor capability is on, then set angular acceleration with zero angular correction 
		NewtonUserJointAddAngularRow (m_joint, 0.0f, &matrix0.m_front[0]);
		
		// override the angular acceleration for this Jacobian to the desired acceleration
		NewtonUserJointSetRowAcceleration (m_joint, relAccel);
	}
 }
Exemplo n.º 2
0
void CustomSlider::SubmitConstraints (dFloat timestep, int threadIndex)
{
	dMatrix matrix0;
	dMatrix matrix1;

	// calculate the position of the pivot point and the Jacobian direction vectors, in global space. 
	CalculateGlobalMatrix (matrix0, matrix1);

	// Restrict the movement on the pivot point along all two orthonormal axis direction perpendicular to the motion
	NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix1.m_up[0]);
	NewtonUserJointAddLinearRow (m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix1.m_right[0]);
	
 	// three rows to restrict rotation around around the parent coordinate system
	dFloat sinAngle;
	dFloat cosAngle;
	CalculatePitchAngle(matrix0, matrix1, sinAngle, cosAngle);
	NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &matrix1.m_front[0]);

	CalculateYawAngle(matrix0, matrix1, sinAngle, cosAngle);
	NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &matrix1.m_up[0]);

	CalculateRollAngle(matrix0, matrix1, sinAngle, cosAngle);
	NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &matrix1.m_right[0]);


	// calculate position and speed	
	dVector veloc0(0.0f, 0.0f, 0.0f, 0.0f); 
	dVector veloc1(0.0f, 0.0f, 0.0f, 0.0f);  
	if (m_body0) {
		NewtonBodyGetVelocity(m_body0, &veloc0[0]);
	}
	if (m_body1) {
		NewtonBodyGetVelocity(m_body1, &veloc1[0]);
	}
	m_posit = (matrix0.m_posit - matrix1.m_posit) % matrix1.m_front;
	m_speed = (veloc0 - veloc1) % matrix1.m_front;

	// if limit are enable ...
	m_hitLimitOnLastUpdate = false;
	if (m_limitsOn) {
		if (m_posit < m_minDist) {
			// indicate that this row hit a limit
			m_hitLimitOnLastUpdate = true;

			// get a point along the up vector and set a constraint  
			const dVector& p0 = matrix0.m_posit;
			dVector p1 (p0 + matrix0.m_front.Scale (m_minDist - m_posit));
			NewtonUserJointAddLinearRow (m_joint, &p0[0], &p1[0], &matrix0.m_front[0]);
			// allow the object to return but not to kick going forward
			NewtonUserJointSetRowMinimumFriction (m_joint, 0.0f);
			
		} else if (m_posit > m_maxDist) {
			// indicate that this row hit a limit
			m_hitLimitOnLastUpdate = true;

			// get a point along the up vector and set a constraint  

			const dVector& p0 = matrix0.m_posit;
			dVector p1 (p0 + matrix0.m_front.Scale (m_maxDist - m_posit));
			NewtonUserJointAddLinearRow (m_joint, &p0[0], &p1[0], &matrix0.m_front[0]);
			// allow the object to return but not to kick going forward
			NewtonUserJointSetRowMaximumFriction (m_joint, 0.0f);

		} else {

/*
			// uncomment this for a slider with friction

			// take any point on body0 (origin)
			const dVector& p0 = matrix0.m_posit;

			dVector veloc0; 
			dVector veloc1; 
			dVector omega1; 

			NewtonBodyGetVelocity(m_body0, &veloc0[0]);
			NewtonBodyGetVelocity(m_body1, &veloc1[0]);
			NewtonBodyGetOmega(m_body1, &omega1[0]);

			// this assumes the origin of the bodies the matrix pivot are the same
			veloc1 += omega1 * (matrix1.m_posit - p0);

			dFloat relAccel; 
			relAccel = ((veloc1 - veloc0) % matrix0.m_front) / timestep;

			#define MaxFriction 10.0f
			NewtonUserJointAddLinearRow (m_joint, &p0[0], &p0[0], &matrix0.m_front[0]);
			NewtonUserJointSetRowAcceleration (m_joint, relAccel);
			NewtonUserJointSetRowMinimumFriction (m_joint, -MaxFriction);
			NewtonUserJointSetRowMaximumFriction(m_joint, MaxFriction);
*/
		}
	} 
 }
Exemplo n.º 3
0
void CustomUniversal::SubmitConstraints(dFloat timestep, int threadIndex)
{
    dMatrix matrix0;
    dMatrix matrix1;

    // calculate the position of the pivot point and the Jacobian direction vectors, in global space.
    CalculateGlobalMatrix(matrix0, matrix1);

    // Restrict the movement on the pivot point along all tree orthonormal direction
    NewtonUserJointAddLinearRow(m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix1.m_front[0]);
    NewtonUserJointAddLinearRow(m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix1.m_up[0]);
    NewtonUserJointAddLinearRow(m_joint, &matrix0.m_posit[0], &matrix1.m_posit[0], &matrix1.m_right[0]);


    // get the pin fixed to the first body
    const dVector& dir0 = matrix0.m_front;
    // get the pin fixed to the second body
    const dVector& dir1 = matrix1.m_up;

    // construct an orthogonal coordinate system with these two vectors
    dVector dir2(dir0 * dir1);
    dir2 = dir2.Scale(1.0f / dSqrt(dir2 % dir2));
    dVector dir3(dir1 * dir2);

    dFloat sinAngle = ((dir3 * dir0) % dir2);
    dFloat cosAngle = dir3 % dir0;
    NewtonUserJointAddAngularRow(m_joint, -dAtan2(sinAngle, cosAngle), &dir2[0]);

    dFloat sinAngle_0;
    dFloat cosAngle_0;
    CalculatePitchAngle(matrix0, matrix1, sinAngle_0, cosAngle_0);
    dFloat angle0 = -m_curJointAngle_0.Update(cosAngle_0, sinAngle_0);

    dFloat sinAngle_1;
    dFloat cosAngle_1;
    CalculateYawAngle(matrix0, matrix1, sinAngle_1, cosAngle_1);
    dFloat angle1 = -m_curJointAngle_1.Update(cosAngle_1, sinAngle_1);

    dVector omega0(0.0f, 0.0f, 0.0f, 0.0f);
    dVector omega1(0.0f, 0.0f, 0.0f, 0.0f);
    NewtonBodyGetOmega(m_body0, &omega0[0]);
    if (m_body1) {
        NewtonBodyGetOmega(m_body1, &omega1[0]);
    }

    // calculate the desired acceleration
    dVector relOmega(omega0 - omega1);
    m_jointOmega_0 = relOmega % matrix0.m_front;
    m_jointOmega_1 = relOmega % matrix1.m_up;

    // check is the joint limit are enable
    if (m_limit_0_On) {
        if (angle0 < m_minAngle_0) {
            dFloat relAngle = angle0 - m_minAngle_0;

            // tell joint error will minimize the exceeded angle error
            NewtonUserJointAddAngularRow(m_joint, relAngle, &matrix0.m_front[0]);

            // need high stiffeners here
            NewtonUserJointSetRowStiffness(m_joint, 1.0f);

            // allow the joint to move back freely
            NewtonUserJointSetRowMaximumFriction(m_joint, 0.0f);

        } else if (angle0 > m_maxAngle_0) {
            dFloat relAngle = angle0 - m_maxAngle_0;

            // tell joint error will minimize the exceeded angle error
            NewtonUserJointAddAngularRow(m_joint, relAngle, &matrix0.m_front[0]);

            // need high stiffness here
            NewtonUserJointSetRowStiffness(m_joint, 1.0f);

            // allow the joint to move back freely
            NewtonUserJointSetRowMinimumFriction(m_joint, 0.0f);
        }

        // check is the joint limit motor is enable
    } else if (m_angularMotor_0_On) {
        // calculate the desired acceleration
        //         dFloat relOmega = (omega0 - omega1) % matrix0.m_front;
        dFloat relAccel = m_angularAccel_0 - m_angularDamp_0 * m_jointOmega_0;

        // add and angular constraint row to that will set the relative acceleration to zero
        NewtonUserJointAddAngularRow(m_joint, 0.0f, &matrix0.m_front[0]);

        // override the joint acceleration.
        NewtonUserJointSetRowAcceleration(m_joint, relAccel);
    }

    // if limit are enable ...
    if (m_limit_1_On) {
        if (angle1 < m_minAngle_1) {
            dFloat relAngle = angle1 - m_minAngle_1;

            // tell joint error will minimize the exceeded angle error
            NewtonUserJointAddAngularRow(m_joint, relAngle, &matrix1.m_up[0]);

            // need high stiffeners here
            NewtonUserJointSetRowStiffness(m_joint, 1.0f);

            // allow the joint to move back freely
            NewtonUserJointSetRowMaximumFriction(m_joint, 0.0f);

        } else if (angle1 > m_maxAngle_1) {
            dFloat relAngle = angle1 - m_maxAngle_1;

            // tell joint error will minimize the exceeded angle error
            NewtonUserJointAddAngularRow(m_joint, relAngle, &matrix1.m_up[0]);

            // need high stiffness here
            NewtonUserJointSetRowStiffness(m_joint, 1.0f);

            // allow the joint to move back freely
            NewtonUserJointSetRowMinimumFriction(m_joint, 0.0f);
        }
    } else if (m_angularMotor_1_On) {
        // calculate the desired acceleration
        dFloat relAccel = m_angularAccel_1 - m_angularDamp_1 * m_jointOmega_1;

        // add and angular constraint row to that will set the relative acceleration to zero
        NewtonUserJointAddAngularRow(m_joint, 0.0f, &matrix1.m_up[0]);

        // override the joint acceleration.
        NewtonUserJointSetRowAcceleration(m_joint, relAccel);
    }
}