Biorobotics 7
State machine
Dependencies: mbed Adafruit_GFX BioroboticsMotorControl MODSERIAL BioroboticsEMGFilter
inverse_kinematics.h
- Committer:
- MAHCSnijders
- Date:
- 2018-11-05
- Revision:
- 51:e0e4d7e3de93
- Parent:
- 50:5d2176b93a65
File content as of revision 51:e0e4d7e3de93:
#pragma once
#include "mbed.h"
#include "constants.h"
// Pass the two values that you want the target angle outputs in, as 3rd and 4th arguments.
void inverse_kinematics(double Pe_x, double Pe_y, double &dest_main_angle, double &dest_sec_angle)
{
// Calculation of the position of joint 3 in frame 0
float n = sqrt(pow((L6-Pe_x),2) + pow(Pe_y,2)); // Radius between motor 1 and endeffector [meter]
float omega = acos(-(pow(n,2) - pow(L4,2) - pow(L5,2))/(2*L4*L5)); // Angle between L4 and L5 [rad]
float q4 = PI - omega; // Angle of joint 3 between L3 and L4
float theta = acos( -(pow(L5,2) - pow(n,2) - pow(L4,2))/(2*n*L4) ); // Angle between n and L4
float lambda_pre_value = Pe_y/(L6-Pe_x);
float lambda = PI - atan(lambda_pre_value); // Entire angle between L0 and n
dest_main_angle = lambda - theta;
float J3x_0 = L6 + L4*cos(dest_main_angle); // x-coordinate of joint 3 in frame 0
float J3y_0 = L4*sin(dest_main_angle); // y-coordinate of joint 3 in frame 0
// Calculation of the position of joint 2 in frame 0
float S = J3y_0 - Pe_y; // Distance between height endeffector and joint 3
float kappa = asin(S/L5); // Angle of L5
float J2x_0 = (L3+L5)*cos(kappa) + Pe_x; // x-coordinate of joint 2 in frame 0
float J2y_0 = (L3+L5)*sin(kappa) + Pe_y; // y-coordinate of joint 2 in frame 0
// Calculation of the position of joint 1 in frame 0
float J2x_1 = J2x_0 - L0 - L6; // x-coordinate of joint 2 in frame 1
float J2y_1 = J2y_0; // y-coordinate of joint 2 in frame 1
float r = sqrt(pow(J2x_1,2) + pow(J2y_1,2)); // Radius between origin frame 1 and J2
float alfa = acos( -(pow(r,2) - pow(L1,2) - pow(L2,2))/(2*L1*L2) ); // Angle opposite of radius r
float q2 = PI - alfa; // Angle between L1 and L2
// Delta < 175 graden SAFETY LIMITATION
if (r > max_r_length) // If delta is larger than 175 degrees then r is this
{
r = max_r_length;
}
// Calculation of motor_angle2
float beta = acos(- (pow(L2,2) - pow(r,2) - pow(L1,2))/(2*L1*r)); // Angle between r and L1
float zeta = acos(J2x_1/r); // Angle between r and x-axis of frame 1
dest_sec_angle = zeta - beta;
// Determining angle delta for safety (not necessary for calculation, for debugging purposes)
float J1x_0 = L0 + L6 + L1*cos(dest_sec_angle); // x-coordinate of joint 1 in frame 0
float J1y_0 = L1*sin(dest_sec_angle); // y-coordinate of joint 1 in frame 0
float m = sqrt(pow((J1x_0 - J3x_0),2) + pow((J3y_0 - J1y_0),2)); // Radius between Joint 1 and Joint 3
float delta = acos(- (pow(m,2) - pow(L2,2) - pow(L3,2))/(2*L2*L3)); // Angle between L2 and L3
// Implementing stops for safety
// 45 < Motor_angle1 < 160 graden
if (dest_main_angle < main_arm_min_angle) // If motor_angle is smaller than 45 degrees
{
dest_main_angle = main_arm_min_angle;
}
else if (dest_main_angle > main_arm_max_angle) // If motor_angle is larger than 70 degrees
{
dest_main_angle = main_arm_max_angle;
}
// -42 < Motor_angle2 < 85 graden
if (dest_sec_angle < sec_arm_min_angle) // If motor_angle is smaller than -42 degrees
{
dest_sec_angle = sec_arm_min_angle;
}
else if (dest_sec_angle > sec_arm_max_angle) // If motor_angle is larger than 85 degrees
{
dest_sec_angle = sec_arm_max_angle;
}
}