Erina Yamaguchi
/
jumping_leg_clicky
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Dependencies: ExperimentServer MotorShield QEI_pmw
main.cpp
- Committer:
- erinay
- Date:
- 2022-11-20
- Revision:
- 28:925794e4178b
- Parent:
- 27:9f2dad72971f
- Child:
- 29:dc2556b300a6
File content as of revision 28:925794e4178b:
#include "mbed.h"
#include "rtos.h"
#include "EthernetInterface.h"
#include "ExperimentServer.h"
#include "QEI.h"
#include "BezierCurve.h"
#include "MotorShield.h"
#include "HardwareSetup.h"
//#define BEZIER_ORDER_FOOT 7
#define NUM_INPUTS 12
#define NUM_OUTPUTS 6
#define PULSE_TO_RAD (2.0f*3.14159f / 1200.0f)
// Initializations
Serial pc(USBTX, USBRX); // USB Serial Terminal
ExperimentServer server; // Object that lets us communicate with MATLAB
Timer t; // Timer to measure elapsed time of experiment
Timer hold; // Timer to measure how long to hold clicked position
DigitalIn clicker(PB_8);
QEI encoderA(PE_9,PE_11, NC, 1200, QEI::X4_ENCODING); // MOTOR A ENCODER (no index, 1200 counts/rev, Quadrature encoding)
QEI encoderB(PA_5, PB_3, NC, 1200, QEI::X4_ENCODING); // MOTOR B ENCODER (no index, 1200 counts/rev, Quadrature encoding)
QEI encoderC(PC_6, PC_7, NC, 1200, QEI::X4_ENCODING); // MOTOR C ENCODER (no index, 1200 counts/rev, Quadrature encoding)
QEI encoderD(PD_12, PD_13, NC, 1200, QEI::X4_ENCODING);// MOTOR D ENCODER (no index, 1200 counts/rev, Quadrature encoding)
MotorShield motorShield(24000); //initialize the motor shield with a period of 24000 ticks or ~10kHZ
Ticker currentLoop;
// Variables for q1
float current1;
float current_des1 = 0;
float prev_current_des1 = 0;
float current_int1 = 0;
float angle1;
float angle1_des;
float velocity1;
float duty_cycle1;
float angle1_init;
// Fixed kinematic parameters
const float l_1=.25;
const float l_OB=.5;
// Timing parameters
float current_control_period_us = 200.0f; // 5kHz current control loop
float impedance_control_period_us = 1000.0f; // 1kHz impedance control loop
float start_period, traj_period, end_period;
// Control parameters
float current_Kp = 4.0f;
float current_Ki = 0.4f;
float current_int_max = 3.0f;
float duty_max;
float K_xx;
float K_yy;
float K_xy;
float D_xx;
float D_xy;
float D_yy;
// Model parameters
float supply_voltage = 12; // motor supply voltage
float R = 2.0f; // motor resistance
float k_t = 0.18f; // motor torque constant
float nu = 0.0005; // motor viscous friction
// Current control interrupt function
void CurrentLoop()
{
// This loop sets the motor voltage commands using PI current controllers with feedforward terms.
//use the motor shield as follows:
//motorShield.motorAWrite(DUTY CYCLE, DIRECTION), DIRECTION = 0 is forward, DIRECTION =1 is backwards.
current1 = -(((float(motorShield.readCurrentA())/65536.0f)*30.0f)-15.0f); // measure current
velocity1 = encoderA.getVelocity() * PULSE_TO_RAD; // measure velocity
float err_c1 = current_des1 - current1; // current errror
current_int1 += err_c1; // integrate error
current_int1 = fmaxf( fminf(current_int1, current_int_max), -current_int_max); // anti-windup
float ff1 = R*current_des1 + k_t*velocity1; // feedforward terms
duty_cycle1 = (ff1 + current_Kp*err_c1 + current_Ki*current_int1)/supply_voltage; // PI current controller
float absDuty1 = abs(duty_cycle1);
if (absDuty1 > duty_max) {
duty_cycle1 *= duty_max / absDuty1;
absDuty1 = duty_max;
}
if (duty_cycle1 < 0) { // backwards
motorShield.motorAWrite(absDuty1, 1);
} else { // forwards
motorShield.motorAWrite(absDuty1, 0);
}
prev_current_des1 = current_des1;
}
int main (void)
{
// Object for 7th order Cartesian foo//t trajectory
// BezierCurve rDesFoot_bez(2,BEZIER_ORDER_FOOT);
// Link the terminal with our server and start it up
server.attachTerminal(pc);
server.init();
// Continually get input from MATLAB and run experiments
float input_params[NUM_INPUTS];
pc.printf("%f",input_params[0]);
while(1) {
// If there are new inputs, this code will run
if (server.getParams(input_params,NUM_INPUTS)) {
// Get inputs from MATLAB
start_period = input_params[0]; // First buffer time, before trajectory
traj_period = input_params[1]; // Trajectory time/length
end_period = input_params[2]; // Second buffer time, after trajectory
angle1_init = input_params[3]; // Initial angle for q1 (rad)
angle1_des = input_params[4];
K_xx = input_params[5]; // Foot stiffness N/m
K_yy = input_params[6]; // Foot stiffness N/m
K_xy = input_params[7]; // Foot stiffness N/m
D_xx = input_params[8]; // Foot damping N/(m/s)
D_yy = input_params[9]; // Foot damping N/(m/s)
D_xy = input_params[10]; // Foot damping N/(m/s)
duty_max = input_params[11]; // Maximum duty factor
float th1_des = angle1_init;
// Get foot trajectory points
// float foot_pts[2*(BEZIER_ORDER_FOOT+1)];
// for(int i = 0; i<2*(BEZIER_ORDER_FOOT+1);i++) {
// foot_pts[i] = input_params[12+i];
// }
// rDesFoot_bez.setPoints(foot_pts);
// Attach current loop interrupt
currentLoop.attach_us(CurrentLoop,current_control_period_us);
// Setup experiment
t.reset();
t.start();
encoderA.reset();
encoderB.reset();
encoderC.reset();
encoderD.reset();
motorShield.motorAWrite(0, 0); //turn motor A off
// Run experiment
while( t.read() < start_period + traj_period + end_period) {
// Read encoders to get motor states
angle1 = encoderA.getPulses() *PULSE_TO_RAD + angle1_init;
velocity1 = encoderA.getVelocity() * PULSE_TO_RAD;
const float th1 = angle1;
const float dth1= velocity1;
// Calculate the Jacobian
// float Jx_th1 = l_AC*cos(th1+th2)+l_DE*cos(th1)+l_OB*cos(th1);
// float Jx_th2 = l_AC*cos(th1+th2);
// float Jy_th1 = l_AC*sin(th1+th2)+l_DE*sin(th1)+l_OB*sin(th1);
// float Jy_th2 = l_AC*sin(th1+th2);
// Calculate the forward kinematics (position and velocity)
// float xFoot = l_AC*sin(th1+th2)+l_DE*sin(th1)+l_OB*sin(th1);
// float yFoot = -l_AC*cos(th1+th2)-l_DE*cos(th1)-l_OB*cos(th1);
// float dxFoot = velocity1*(l_AC*cos(th1+th2)+l_DE*cos(th1)+l_OB*cos(th1))+velocity2*l_AC*cos(th1+th2);
// float dyFoot = velocity1*(l_AC*sin(th1+th2)+l_DE*sin(th1)+l_OB*sin(th1))+velocity2*l_AC*sin(th1+th2);
// Set gains based on buffer and traj times, then calculate desired x,y from Bezier trajectory at current time if necessary
float teff = 0;
float vMult = 0;
if( t < start_period) {
if (K_xx > 0 || K_yy > 0) {
K_xx = 50; // for joint space control, set this to 1; for Cartesian space control, set this to 50
K_yy = 50; // for joint space control, set this to 1; for Cartesian space control, set this to 50
D_xx = 2; // for joint space control, set this to 0.1; for Cartesian space control, set this to 2
D_yy = 2; // for joint space control, set this to 0.1; for Cartesian space control, set this to 2
K_xy = 0;
D_xy = 0;
}
teff = 0;
}
else if (t < start_period + traj_period)
{
K_xx = input_params[5]; // Foot stiffness N/m
K_yy = input_params[6]; // Foot stiffness N/m
K_xy = input_params[7]; // Foot stiffness N/m
D_xx = input_params[8]; // Foot damping N/(m/s)
D_yy = input_params[9]; // Foot damping N/(m/s)
D_xy = input_params[10]; // Foot damping N/(m/s)
teff = (t-start_period);
vMult = 1;
}
else
{
teff = traj_period;
vMult = 0;
}
// Get desired foot positions and velocities
// float rDesFoot[2] , vDesFoot[2];
// rDesFoot_bez.evaluate(teff/traj_period,rDesFoot);
// rDesFoot_bez.evaluateDerivative(teff/traj_period,vDesFoot);
// vDesFoot[0]/=traj_period;
// vDesFoot[1]/=traj_period;
// vDesFoot[0]*=vMult;
// vDesFoot[1]*=vMult;
//
// // Calculate the inverse kinematics (joint positions and velocities) for desired joint angles
// float xFoot_inv = -rDesFoot[0];
// float yFoot_inv = rDesFoot[1];
// float l_OE = sqrt( (pow(xFoot_inv,2) + pow(yFoot_inv,2)) );
// float alpha = abs(acos( (pow(l_OE,2) - pow(l_AC,2) - pow((l_OB+l_DE),2))/(-2.0f*l_AC*(l_OB+l_DE)) ));
// float th2_des = -(3.14159f - alpha);
// float th1_des = -((3.14159f/2.0f) + atan2(yFoot_inv,xFoot_inv) - abs(asin( (l_AC/l_OE)*sin(alpha) )));
// float dd = (Jx_th1*Jy_th2 - Jx_th2*Jy_th1);
// float dth1_des = (1.0f/dd) * ( Jy_th2*vDesFoot[0] - Jx_th2*vDesFoot[1] );
// float dth2_des = (1.0f/dd) * ( -Jy_th1*vDesFoot[0] + Jx_th1*vDesFoot[1] );
// Set desired currents
// current_des1 = (-K_xx*(angle1)-D_xx*(velocity1))/k_t;
// while (hold.read() == 0 | hold.read() > 2){
// if(clicker.read() == 0) {
// th1_des = angle1_init;
// }
// else {
// th1_des = angle1_des;
// hold.start();
// }
// }
th1_des = angle1_des;
// Joint impedance
// sub Kxx for K1, Dxx for D1, Kyy for K2, Dyy for D2
// Note: Be careful with signs now that you have non-zero desired angles!
// Your equations should be of the form i_d = K1*(q1_d - q1) + D1*(dq1_d - dq1)
current_des1 = (K_xx*(th1_des-angle1))/k_t;
// current_des1 = (K_xx*(th1_des-angle1)+D_xx*(dth1_des-velocity1))/k_t;
// Cartesian impedance
// Note: As with the joint space laws, be careful with signs!
// current_des1 = t1/k_t;
// Form output to send to MATLAB
float output_data[NUM_OUTPUTS];
// current time
output_data[0] = t.read();
// motor 1 state
output_data[1] = angle1;
output_data[2] = velocity1;
output_data[3] = current1;
output_data[4] = current_des1;
output_data[5] = duty_cycle1;
// foot state
// output_data[11] = xFoot;
// output_data[12] = yFoot;
// output_data[13] = dxFoot;
// output_data[14] = dyFoot;
// output_data[15] = rDesFoot[0];
// output_data[16] = rDesFoot[1];
// output_data[17] = vDesFoot[0];
// output_data[18] = vDesFoot[1];
// Send data to MATLAB
server.sendData(output_data,NUM_OUTPUTS);
wait_us(impedance_control_period_us);
}
// Cleanup after experiment
server.setExperimentComplete();
currentLoop.detach();
motorShield.motorAWrite(0, 0); //turn motor A off
} // end if
} // end while
} // end main