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stmbl/sim/sim.h

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#include <iostream>
#include <cstdlib>
#include <cmath>
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#include <vector>
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using namespace std;
#define ABS(a) (((a) < 0) ? -(a) : (a))
#define CLAMP(x, low, high) (((x) > (high)) ? (high) : (((x) < (low)) ? (low) : (x)))
#define MIN(a, b) (((a) < (b)) ? (a) : (b))
#define MAX(a, b) (((a) > (b)) ? (a) : (b))
#define DEG(a) ((a)*M_PI/180.0)
#define RAD(a) ((a)*180.0/M_PI)
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#define RAD(a) ((a)*180.0/M_PI)
#define SIGN(a) (((a) < 0) ? (-1) : (((a) > 0) ? (1) : (0)))
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double grand(){
double ret = 0;
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for(int i = 0; i < 12; i++){
ret += (float)rand() / RAND_MAX;
}
return(ret - 6.0);
}
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double prand(){
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return(rand() * 2 * M_PI / RAND_MAX - M_PI);
}
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// double mod(double pos){
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// return(fmod(pos + M_PI, 2 * M_PI) - M_PI);
// }
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double mod(double a){
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while(a < -M_PI){
a += 2.0 * M_PI;
}
while(a > M_PI){
a -= 2.0 * M_PI;
}
return(a);
}
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double minus_(double a, double b){
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if(ABS(a - b) < M_PI){
return(a - b);
}
else if(a > b){
return(a - b - 2.0 * M_PI);
}
else{
return(a - b + 2.0 * M_PI);
}
}
class mot_c{
public:
struct {
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double pos;
double vel;
double acc;
double u;
double v;
double w;
double t;
double cur;
double volt;
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double ind;
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double torq;
int res_polarity;
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} state;
struct feedback_s{
enum{
ENC,
RES,
NONE
} type;
int count;
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double res_offset;
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int enc_offset;
} feedback;
struct {
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double max_i;
double i;
double r;
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double l;
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double nm_a;
double v_rps;
double slip;
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} elec_spec;
struct mech_spec_s{
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double t2; // term. time const
double max_rps;
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int pole_count;
enum{
AC_SYNC,
AC_ASYNC,
DC
} mot_type;
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double friction;
double damping;
double inertia; // inertia
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} mech_spec;
struct{
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double var;
double sin_offset;
double sin_scale;
double cos_offset;
double cos_scale;
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} noise;
struct {
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double friction; // friction (torque)
double load; // asym. torque
double damping; // damping (torque / vel)
double inertia; // inertia (torque / acc)
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} load;
void reset();
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void step(double periode);
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int get_enc();
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double get_sin();
double get_cos();
int get_polarity();
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void set_volt(double u, double v, double w);
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};
void mot_c::reset(){
state.pos = 0.0;//prand();
state.vel = 0.0;
state.acc = 0.0;
state.u = 0.0;
state.v = 0.0;
state.w = 0.0;
state.t = 20.0;
state.cur = 0.0;
state.volt = 0.0;
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state.ind = 0.0;
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state.res_polarity = 1.0;
feedback.enc_offset = state.pos;
}
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void mot_c::step(double periode){
double d;
double q;
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state.res_polarity *= -1;
switch(mech_spec.mot_type){
case mech_spec_s::AC_SYNC:
d = 2/3 * (cos(state.pos * mech_spec.pole_count) * state.u + cos(state.pos * mech_spec.pole_count - 2/3 * M_PI) * state.v + cos(state.pos * mech_spec.pole_count + 2/3 * M_PI) * state.w);
q = 2/3 * (-sin(state.pos * mech_spec.pole_count) * state.u - sin(state.pos * mech_spec.pole_count - 2/3 * M_PI) * state.v - sin(state.pos * mech_spec.pole_count + 2/3 * M_PI) * state.w);
state.volt = q;
break;
case mech_spec_s::AC_ASYNC:
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state.volt = 0.0;
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break;
case mech_spec_s::DC:
state.volt = state.u - state.v;
break;
}
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state.ind = state.vel * elec_spec.v_rps;
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state.cur += (state.volt - state.ind - state.cur * elec_spec.r) / elec_spec.l * periode;
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state.cur = CLAMP(state.cur, -elec_spec.max_i, elec_spec.max_i);
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//state.cur = (state.volt - state.ind) / elec_spec.r;
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state.torq = state.cur * elec_spec.nm_a - (mech_spec.damping + load.damping) * state.vel + load.load;
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if(abs(state.torq) < mech_spec.friction + load.friction){
state.torq = 0.0;
}
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else{
state.torq = state.torq - SIGN(state.torq) * (mech_spec.friction + load.friction);
}
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state.acc = state.torq / (mech_spec.inertia + load.inertia);
state.vel += state.acc * periode;
state.pos += state.vel * periode;
state.pos = mod(state.pos);
if(state.cur > elec_spec.max_i){
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cerr << "MOT: cur > max_i: " << state.cur << endl;
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}
if(state.vel > mech_spec.max_rps){
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cerr << "MOT: vel > max_v: " << state.vel << endl;
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}
}
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void mot_c::set_volt(double u, double v, double w){
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state.u = u;
state.v = v;
state.w = w;
}
int mot_c::get_enc(){
return((int)((state.pos - feedback.enc_offset + 2 * M_PI) * feedback.count / 2 / M_PI) % feedback.count);
}
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double mot_c::get_sin(){
return(sin((state.pos + feedback.res_offset) * feedback.count) * noise.sin_scale * state.res_polarity + noise.sin_offset + grand() * noise.var);
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}
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double mot_c::get_cos(){
return(cos((state.pos + feedback.res_offset) * feedback.count) * noise.cos_scale * state.res_polarity + noise.cos_offset + grand() * noise.var);
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}
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int mot_c::get_polarity(){
return(state.res_polarity);
}
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class cmd_c{
public:
struct {
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double time;
double pos;
double vel;
double acc;
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} state;
enum{
POS,
POS_VEL,
POS_VEL_ACC,
VEL,
VEL_ACC
} type;
enum{
SINE,
SQUARE,
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RAMP,
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CONST
} wave;
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double periode;
double amplitude;
double max_vel;
double max_acc;
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double pos_res;
double vel_res;
double acc_res;
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void reset();
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void step(double periode);
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double get_pos();
double get_vel();
double get_acc();
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};
void cmd_c::reset(){
state.time = 0.0;
state.pos = 0.0;
state.vel = 0.0;
state.acc = 0.0;
}
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void cmd_c::step(double s){
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state.time += s;
switch(wave){
case SINE:
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state.pos = mod(sin(state.time / periode * 2 * M_PI) * amplitude);
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state.vel = cos(state.time / periode * 2 * M_PI) * amplitude;
state.acc = -sin(state.time / periode * 2 * M_PI) * amplitude;
break;
case SQUARE:
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state.pos = mod(((int)(state.time / periode * 2) % 2) * amplitude);
state.vel = 0;
state.acc = 0;
break;
case RAMP:
state.pos = mod(state.time * amplitude);
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state.vel = 0;
state.acc = 0;
break;
case CONST:
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state.pos = mod(amplitude);
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state.vel = 0;
state.acc = 0;
break;
}
}
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double cmd_c::get_pos(){
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return((int)(state.pos / pos_res) * pos_res);
}
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double cmd_c::get_vel(){
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return((int)(state.vel / vel_res) * vel_res);
}
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double cmd_c::get_acc(){
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return((int)(state.acc / acc_res) * acc_res);
}
class drive_c{
public:
struct cmd_s{
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double pos;
double vel;
double acc;
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} cmd;
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double dc;
double pwm_scale;
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int pwm_res;
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double pid_periode;
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struct {
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double offset;
double sin_scale;
double sin_avg;
double cos_scale;
double cos_avg;
double res_var;
double pos;
double vel;
double acc;
double cur;
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double friction;
double load;
double damping;
double inertia;
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double p;
double v;
double a;
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} est;
struct {
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double mag_pos;
double mag_vel;
double ctr;
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} state;
mot_c* mot;
cmd_c* in;
void reset();
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void step(double periode);
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void (*input_cmd)(drive_c* drv, double periode);
void (*input_feedback)(drive_c* drv, double periode);
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void (*pid)(drive_c* drv, double periode);
void (*output)(drive_c* drv, double periode);
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void set_pos(double pos);
void set_pos_vel(double pos, double vel);
void set_pos_vel_acc(double pos, double vel, double acc);
void set_vel(double pos);
void set_vel_acc(double pos, double acc);
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};
void drive_c::reset(){
cmd.pos = 0.0;
cmd.vel = 0.0;
cmd.acc = 0.0;
est.offset = 0.0;
est.sin_scale = 1.0;
est.cos_scale = 1.0;
est.sin_avg = 0.0;
est.cos_avg = 0.0;
est.res_var = 0.0;
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est.friction = mot->mech_spec.friction;
est.load = 0.0;
est.damping = mot->mech_spec.damping;
est.inertia = mot->mech_spec.inertia;
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est.pos = 0.0;
est.vel = 0.0;
est.acc = 0.0;
est.cur = 0.0;
state.mag_pos = 0.0;
state.mag_vel = 0.0;
state.ctr = 0.0;
}
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void drive_c::step(double periode){
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input_cmd(this, periode);
input_feedback(this, periode);
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pid(this, periode);
output(this, periode);
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}
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void input_cmd(drive_c* drv, double periode){
double tp, tv;
tp = drv->cmd.pos;
tv = drv->cmd.vel;
switch(drv->in->type){
case cmd_c::POS:
drv->cmd.pos = drv->in->get_pos();
drv->cmd.vel = (drv->cmd.pos - tp) / periode;
drv->cmd.acc = (drv->cmd.vel - tv) / periode;
break;
case cmd_c::POS_VEL:
drv->cmd.pos = drv->in->get_pos();
drv->cmd.vel = drv->in->get_vel();;
drv->cmd.acc = (drv->cmd.vel - tv) / periode;
break;
case cmd_c::POS_VEL_ACC:
drv->cmd.pos = drv->in->get_pos();
drv->cmd.vel = drv->in->get_vel();;
drv->cmd.acc = drv->in->get_acc();
break;
case cmd_c::VEL:
drv->cmd.pos = drv->cmd.pos + drv->cmd.vel * periode;
drv->cmd.vel = drv->in->get_vel();;
drv->cmd.acc = (drv->cmd.vel - tv) / periode;
break;
case cmd_c::VEL_ACC:
drv->cmd.pos = drv->cmd.pos + drv->cmd.vel * periode;
drv->cmd.vel = drv->in->get_vel();;
drv->cmd.acc = drv->in->get_acc();
break;
}
}
void input_feedback(drive_c* drv, double periode){
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double t1, t2;
static double sin_avg_amp = 1.0;
static double cos_avg_amp = 1.0;
static double r = 1.0;
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double dpos = 0.0;
double v = 0.0;
static double i_sum;
double p = 0.05;
double i = 1 * periode;
double vlo = 0.0 * periode;
static int point = 0;
const int hist_size = 10;
static double pos_hist[hist_size];
static double vel_hist[hist_size];
static double acc_hist[hist_size];
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t1 = drv->est.pos;
switch(drv->mot->feedback.type){
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case mot_c::feedback_s::ENC:
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drv->est.pos = mod(drv->mot->get_enc() * 2 * M_PI / drv->mot->feedback.count - drv->est.offset);
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break;
case mot_c::feedback_s::RES:
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drv->est.sin_avg = 0.995 * drv->est.sin_avg + 0.005 * drv->mot->get_sin();
drv->est.cos_avg = 0.995 * drv->est.cos_avg + 0.005 * drv->mot->get_cos();
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// sin_avg_amp = 0.5 * sin_avg_amp + 0.5 * (drv->mot->get_sin() - drv->est.sin_avg) / drv->est.sin_scale * drv->mot->get_polarity();
// cos_avg_amp = 0.5 * cos_avg_amp + 0.5 * (drv->mot->get_cos() - drv->est.cos_avg) / drv->est.cos_scale * drv->mot->get_polarity();
//
// r = 0.99 * r + 0.01 * (sin_avg_amp * sin_avg_amp + cos_avg_amp * cos_avg_amp);
//
// if(ABS(sin_avg_amp) < 0.01){
// drv->est.cos_scale -= 0.001 * SIGN(1 - cos_avg_amp);
// }
//
// if(ABS(cos_avg_amp) < 0.01){
// drv->est.sin_scale -= 0.001 * SIGN(1 - sin_avg_amp);
// }
//
// if(ABS(r - 1.0) > 0.6){
// //cerr << "res error r: " << r << endl;
// }
dpos = (drv->mot->get_sin() - drv->est.sin_avg) / drv->est.sin_scale * drv->mot->get_polarity() * cos(drv->est.pos + drv->est.offset) - (drv->mot->get_cos() - drv->est.cos_avg) / drv->est.cos_scale * drv->mot->get_polarity() * sin(drv->est.pos + drv->est.offset);
i_sum += dpos * i + vlo * (drv->state.ctr * drv->dc - drv->est.vel * drv->mot->elec_spec.v_rps) / drv->mot->elec_spec.r * drv->mot->elec_spec.nm_a * periode;
dpos = p * dpos + i_sum;
drv->est.pos += dpos;
drv->est.pos = mod(drv->est.pos);
pos_hist[point] = drv->est.pos;
vel_hist[point] = minus_(pos_hist[(point) % hist_size], pos_hist[(point + hist_size - 2) % hist_size]) / (2 * periode);
acc_hist[point] = minus_(vel_hist[(point) % hist_size], vel_hist[(point + hist_size - 2) % hist_size]) / (2 * periode);
point++;
point %= hist_size;
//drv->est.vel = i_sum / periode;
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drv->est.pos = mod(atan2((drv->mot->get_sin() - drv->est.sin_avg) / drv->est.sin_scale * drv->mot->get_polarity(), (drv->mot->get_cos() - drv->est.cos_avg) / drv->est.cos_scale * drv->mot->get_polarity()) - drv->est.offset);
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break;
case mot_c::feedback_s::NONE:
break;
}
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double a = 0.0;
v = 0.0;
p = 0.0;
double x = 0.0;
for(int j = 0; j < hist_size; j++){
a += acc_hist[(point + j) % hist_size];
}
a /= hist_size;
a *= 0.5;
for(int j = 0; j < hist_size; j++){
x = (j - hist_size / 2.0) * periode;
v += vel_hist[(point + j) % hist_size] - (2 * a * x);
}
v /= hist_size;
for(int j = 0; j < hist_size; j++){
x = (j - hist_size / 2.0) * periode;
p += pos_hist[(point + j) % hist_size] - (a * x * x + v * x);
}
p /= hist_size;
x = hist_size / 2.0 * periode;
drv->est.p = (a * x * x + v * x + p);
drv->est.v = (2 * a * x + v);
drv->est.a = (2 * a);
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drv->est.pos = drv->mot->state.pos;
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//drv->est.pos = drv->est.p;
// t2 = drv->est.vel;
// drv->est.vel = (drv->est.pos - t1) / periode;
// drv->est.acc = (drv->est.vel - t2) / periode;
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}
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void input_feedback_real(drive_c* drv, double periode){
drv->est.pos = drv->mot->state.pos;
drv->est.vel = drv->mot->state.vel;
drv->est.acc = drv->mot->state.acc;
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}
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void pid(drive_c* drv, double periode){
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double p = 1000; // kp
double i = 10000 * periode; // ki
double d = 0.6 / periode; // kd
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double dd = 0.0 / periode; // rel. vel. kd
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double in = 0.0; // ind. kp
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double dc_scale = 1.0 / drv->dc; // dc voltage scale
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double ind = drv->mot->state.vel * drv->mot->elec_spec.v_rps / drv->dc;
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double e = minus_(drv->cmd.pos, drv->est.pos);
static double e_old = 0;
static double i_sum = 0;
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i_sum += e;
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//i_sum -=
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drv->state.ctr = p * e;
drv->state.ctr += i * i_sum;
drv->state.ctr += d * (e - e_old);
if(abs(e) > 0.01){
drv->state.ctr += dd * (e - e_old) / e;
}
drv->state.ctr *= dc_scale;
drv->state.ctr += in * ind;
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drv->state.ctr = CLAMP(drv->state.ctr, -1, 1);
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// if(ABS(drv->est.vel) >= drv->mot->mech_spec.max_rps * 0.7){
// drv->state.ctr = 0.0;
// }
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if(abs(drv->state.ctr) >= 0.99){
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i_sum -= e;
}
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i_sum = CLAMP(i_sum, -1/i, 1/i);
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e_old = e;
}
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void pid2(drive_c* drv, double periode){
double ind = drv->est.vel * drv->mot->elec_spec.v_rps;
double max_volt_pos = drv->dc * drv->pwm_scale - ind;
double max_cur_pos = max_volt_pos / drv->mot->elec_spec.r;
double max_torq_pos = max_cur_pos * drv->mot->elec_spec.nm_a;
max_torq_pos -= drv->est.friction;
max_torq_pos -= drv->est.load;
max_torq_pos -= drv->est.damping * drv->est.vel;
double max_acc_pos = max_torq_pos / drv->est.inertia;
double max_dvel_pos = max_acc_pos * periode;
double max_volt_neg = -drv->dc * drv->pwm_scale - ind;
double max_cur_neg = max_volt_neg / drv->mot->elec_spec.r;
double max_torq_neg = max_cur_neg * drv->mot->elec_spec.nm_a;
max_torq_neg -= drv->est.friction;
max_torq_neg += drv->est.load;
max_torq_neg -= drv->est.damping * drv->est.vel;
double max_acc_neg = max_torq_neg / drv->est.inertia;
double max_dvel_neg = max_acc_neg * periode;
drv->state.ctr = 0.0;
}
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void output(drive_c* drv, double periode){
double u, v, w;
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switch(drv->mot->mech_spec.mot_type){
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case mot_c::mech_spec_s::AC_SYNC:
case mot_c::mech_spec_s::AC_ASYNC:
case mot_c::mech_spec_s::DC:
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u = ((int)((drv->state.ctr * drv->pwm_scale + 1) / 2.0 * drv->pwm_res)) * drv->dc / drv->pwm_res;
v = ((int)((drv->state.ctr * drv->pwm_scale * (-1) + 1) / 2.0 * drv->pwm_res)) * drv->dc / drv->pwm_res;
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w = 0;
break;
}
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drv->mot->set_volt(u, v, w);
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}