File content as of revision 46:adcd57a5e402:

////////////////////////////////////////////////////////////////////////////////
// Motion control unit
////////////////////////////////////////////////////////////////////////////////
// Takes current state of the robot and target waypoint,
// calculates desired forward and angular velocities and requests those from the motor control layer.
////////////////////////////////////////////////////////////////////////////////

#include "motion.h"

namespace motion
{

Mutex waypoint_flag_mutex;

Waypoint *current_waypoint = NULL; 

bool waypoint_reached = false; // is current waypoint reached
bool d_reached = false;
bool a_reached = false;

void motionlayer(void const *dummy)
{    
    // save target waypoint
    Waypoint target_waypoint = *current_waypoint;
    
    // get current state from Kalman
    State current_state = Kalman::getState();
    
    float delta_x = target_waypoint.x - current_state.x;
    float delta_y = target_waypoint.y - current_state.y;
    
    //printf("motion sees deltax: %f deltay %f\r\n", delta_x, delta_y);
    
    float distance_err = hypot(delta_x, delta_y);
    
    float angle_err = constrainAngle(atan2(delta_y, delta_x) - current_state.theta);
    
    // is the waypoint reached
    waypoint_flag_mutex.lock();
    if (distance_err < ((d_reached) ? target_waypoint.pos_threshold+0.02 : target_waypoint.pos_threshold))
    {
        d_reached = true;
        distance_err = 0;
        
        angle_err = 0.5*constrainAngle(target_waypoint.theta - current_state.theta);
        
        if (abs(angle_err) < target_waypoint.angle_threshold)
        {
            a_reached = true;
            //angle_err = 0;
        }
    } 
    waypoint_flag_mutex.unlock();
        
    waypoint_flag_mutex.lock(); // proper way would be to construct a function to evaluate the condition and pass the function pointer to a conditional setter function for reached flag
    if (d_reached && a_reached)
    {
        setWaypointReached();
    }
    waypoint_flag_mutex.unlock();
    
    // angular velocity controller
    const float p_gain_av = 0.5; //TODO: tune
    
    const float max_av = 0.5*PI; // radians per sec //TODO: tune
    
    // angle error [-pi, pi]
    float angular_v = p_gain_av * angle_err;
    
    // constrain range
    if (angular_v > max_av)
        angular_v = max_av;
    else if (angular_v < -max_av)
        angular_v = -max_av;
    
    
    // forward velocity controller
    const float p_gain_fv = 0.5; //TODO: tune
    
    float max_fv = 0.2; // meters per sec //TODO: tune
    const float angle_envelope_exponent = 8.0; //TODO: tune
    
    // control, distance_err in meters
    float forward_v = p_gain_fv * distance_err;
    
    // control the forward velocity envelope based on angular error
    max_fv = max_fv * pow(cos(angle_err/2), angle_envelope_exponent);
    
    // constrain range
    if (forward_v > max_fv)
        forward_v = max_fv;
    else if (forward_v < -max_fv)
        forward_v = -max_fv;
        
    //printf("fwd: %f, omega: %f\r\n", forward_v, angular_v);
    
    // pass values to the motor control
    MotorControl::set_fwdcmd(forward_v);
    MotorControl::set_omegacmd(angular_v);
}

void setNewWaypoint(Waypoint *new_wp)
{
    current_waypoint = new_wp;
}

void setWaypointReached()
{
    waypoint_reached = true;
}

void clearWaypointReached()
{
    waypoint_reached = false;
    d_reached = false;
    a_reached = false;
}

bool checkWaypointStatus()
{
    return waypoint_reached;
}

} //namespace