/usr/include/angles/angles.h is in libangles-dev 1.9.11-1.
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#ifndef GEOMETRY_ANGLES_UTILS_H
#define GEOMETRY_ANGLES_UTILS_H
#include <algorithm>
#include <cmath>
namespace angles
{
/*!
* \brief Convert degrees to radians
*/
static inline double from_degrees(double degrees)
{
return degrees * M_PI / 180.0;
}
/*!
* \brief Convert radians to degrees
*/
static inline double to_degrees(double radians)
{
return radians * 180.0 / M_PI;
}
/*!
* \brief normalize_angle_positive
*
* Normalizes the angle to be 0 to 2*M_PI
* It takes and returns radians.
*/
static inline double normalize_angle_positive(double angle)
{
return fmod(fmod(angle, 2.0*M_PI) + 2.0*M_PI, 2.0*M_PI);
}
/*!
* \brief normalize
*
* Normalizes the angle to be -M_PI circle to +M_PI circle
* It takes and returns radians.
*
*/
static inline double normalize_angle(double angle)
{
double a = normalize_angle_positive(angle);
if (a > M_PI)
a -= 2.0 *M_PI;
return a;
}
/*!
* \function
* \brief shortest_angular_distance
*
* Given 2 angles, this returns the shortest angular
* difference. The inputs and ouputs are of course radians.
*
* The result
* would always be -pi <= result <= pi. Adding the result
* to "from" will always get you an equivelent angle to "to".
*/
static inline double shortest_angular_distance(double from, double to)
{
return normalize_angle(to-from);
}
/*!
* \function
*
* \brief returns the angle in [-2*M_PI, 2*M_PI] going the other way along the unit circle.
* \param angle The angle to which you want to turn in the range [-2*M_PI, 2*M_PI]
* E.g. two_pi_complement(-M_PI/4) returns 7_M_PI/4
* two_pi_complement(M_PI/4) returns -7*M_PI/4
*
*/
static inline double two_pi_complement(double angle)
{
//check input conditions
if (angle > 2*M_PI || angle < -2.0*M_PI)
angle = fmod(angle, 2.0*M_PI);
if(angle < 0)
return (2*M_PI+angle);
else if (angle > 0)
return (-2*M_PI+angle);
return(2*M_PI);
}
/*!
* \function
*
* \brief This function is only intended for internal use and not intended for external use. If you do use it, read the documentation very carefully. Returns the min and max amount (in radians) that can be moved from "from" angle to "left_limit" and "right_limit".
* \return returns false if "from" angle does not lie in the interval [left_limit,right_limit]
* \param from - "from" angle - must lie in [-M_PI, M_PI)
* \param left_limit - left limit of valid interval for angular position - must lie in [-M_PI, M_PI], left and right limits are specified on the unit circle w.r.t to a reference pointing inwards
* \param right_limit - right limit of valid interval for angular position - must lie in [-M_PI, M_PI], left and right limits are specified on the unit circle w.r.t to a reference pointing inwards
* \param result_min_delta - minimum (delta) angle (in radians) that can be moved from "from" position before hitting the joint stop
* \param result_max_delta - maximum (delta) angle (in radians) that can be movedd from "from" position before hitting the joint stop
*/
static bool find_min_max_delta(double from, double left_limit, double right_limit, double &result_min_delta, double &result_max_delta)
{
double delta[4];
delta[0] = shortest_angular_distance(from,left_limit);
delta[1] = shortest_angular_distance(from,right_limit);
delta[2] = two_pi_complement(delta[0]);
delta[3] = two_pi_complement(delta[1]);
if(delta[0] == 0)
{
result_min_delta = delta[0];
result_max_delta = std::max<double>(delta[1],delta[3]);
return true;
}
if(delta[1] == 0)
{
result_max_delta = delta[1];
result_min_delta = std::min<double>(delta[0],delta[2]);
return true;
}
double delta_min = delta[0];
double delta_min_2pi = delta[2];
if(delta[2] < delta_min)
{
delta_min = delta[2];
delta_min_2pi = delta[0];
}
double delta_max = delta[1];
double delta_max_2pi = delta[3];
if(delta[3] > delta_max)
{
delta_max = delta[3];
delta_max_2pi = delta[1];
}
// printf("%f %f %f %f\n",delta_min,delta_min_2pi,delta_max,delta_max_2pi);
if((delta_min <= delta_max_2pi) || (delta_max >= delta_min_2pi))
{
result_min_delta = delta_max_2pi;
result_max_delta = delta_min_2pi;
if(left_limit == -M_PI && right_limit == M_PI)
return true;
else
return false;
}
result_min_delta = delta_min;
result_max_delta = delta_max;
return true;
}
/*!
* \function
*
* \brief Returns the delta from "from_angle" to "to_angle" making sure it does not violate limits specified by left_limit and right_limit.
* The valid interval of angular positions is [left_limit,right_limit]. E.g., [-0.25,0.25] is a 0.5 radians wide interval that contains 0.
* But [0.25,-0.25] is a 2*M_PI-0.5 wide interval that contains M_PI (but not 0).
* The value of shortest_angle is the angular difference between "from" and "to" that lies within the defined valid interval.
* E.g. shortest_angular_distance_with_limits(-0.5,0.5,0.25,-0.25,ss) evaluates ss to 2*M_PI-1.0 and returns true while
* shortest_angular_distance_with_limits(-0.5,0.5,-0.25,0.25,ss) returns false since -0.5 and 0.5 do not lie in the interval [-0.25,0.25]
*
* \return true if "from" and "to" positions are within the limit interval, false otherwise
* \param from - "from" angle
* \param to - "to" angle
* \param left_limit - left limit of valid interval for angular position, left and right limits are specified on the unit circle w.r.t to a reference pointing inwards
* \param right_limit - right limit of valid interval for angular position, left and right limits are specified on the unit circle w.r.t to a reference pointing inwards
* \param shortest_angle - result of the shortest angle calculation
*/
static inline bool shortest_angular_distance_with_limits(double from, double to, double left_limit, double right_limit, double &shortest_angle)
{
double min_delta = -2*M_PI;
double max_delta = 2*M_PI;
double min_delta_to = -2*M_PI;
double max_delta_to = 2*M_PI;
bool flag = find_min_max_delta(from,left_limit,right_limit,min_delta,max_delta);
double delta = shortest_angular_distance(from,to);
double delta_mod_2pi = two_pi_complement(delta);
if(flag)//from position is within the limits
{
if(delta >= min_delta && delta <= max_delta)
{
shortest_angle = delta;
return true;
}
else if(delta_mod_2pi >= min_delta && delta_mod_2pi <= max_delta)
{
shortest_angle = delta_mod_2pi;
return true;
}
else //to position is outside the limits
{
find_min_max_delta(to,left_limit,right_limit,min_delta_to,max_delta_to);
if(fabs(min_delta_to) < fabs(max_delta_to))
shortest_angle = std::max<double>(delta,delta_mod_2pi);
else if(fabs(min_delta_to) > fabs(max_delta_to))
shortest_angle = std::min<double>(delta,delta_mod_2pi);
else
{
if (fabs(delta) < fabs(delta_mod_2pi))
shortest_angle = delta;
else
shortest_angle = delta_mod_2pi;
}
return false;
}
}
else // from position is outside the limits
{
find_min_max_delta(to,left_limit,right_limit,min_delta_to,max_delta_to);
if(fabs(min_delta) < fabs(max_delta))
shortest_angle = std::min<double>(delta,delta_mod_2pi);
else if (fabs(min_delta) > fabs(max_delta))
shortest_angle = std::max<double>(delta,delta_mod_2pi);
else
{
if (fabs(delta) < fabs(delta_mod_2pi))
shortest_angle = delta;
else
shortest_angle = delta_mod_2pi;
}
return false;
}
shortest_angle = delta;
return false;
}
}
#endif
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