kusano kiyoshige
ライブラリ化を行った後
Dependencies: QEI accelerator bit_test cyclic_io cyclic_var cylinder event_var limit mbed mecanum motor_drive pid pid_encoder rs422_put sbdbt servo
Fork of
17robo_Practice1
by 
kusano kiyoshige
main.cpp
- Committer:
- echo_piyo
- Date:
- 2017-09-13
- Revision:
- 50:e4e1f38d1bd5
- Parent:
- 49:b041c815c063
- Child:
- 51:70d45b959d6b
File content as of revision 50:e4e1f38d1bd5:
#include "mbed.h"
#include "math.h"
#include "bit_test.h"
#include "RS422_put.h"
#include "sbdbt.h"
#include "mecanum.h"
#include "bno055_lib.h"
#include "bno055_use.h"
#include "pid.h"
#include "limit.h"
#include "accelerator.h"
#include "encorder.h"
#include "cyclic.h"
#include "cyclic_IO.h"
#include "cylinder.h"
#include "varEvent.h"
#define pc_baud 460800
#define sbdbt_tx p13
#define sbdbt_rx p14
#define sbdbt_baud 115200
#define rs422_tx p28
#define rs422_rx p27
#define rs422_baud 115200
#define output_period 0.015
#define nucleo_num 6
#define pi 3.141592
#define n1_id 3
#define n2_id 4
#define n3_id 5
#define n4_id 6
#define n5_id 7
#define n6_id 8
#define yaw_Kp 0.01
#define yaw_Ki 0.01
#define yaw_Kd 0.01
#define acceleration 20 //25
#define pin_cylinder_on p17
#define pin_cylinder_off p18
#define pin_interrupt_cylinder_min p23
#define encoder_A p25
#define encoder_B p26
#define enc_Kp 0.0400
#define enc_Ki 0.0001
#define enc_Kd 0.0003
#define mecanum_power 1.0
#define sword_power 0.8
#define sholder_power 0.8
#define pin_interrupt_sholderright_max p19 //p21
#define pin_interrupt_sholderright_min p20 //p22
#define pin_interrupt_sholderleft_max p7
#define pin_interrupt_sholderleft_min p8
#define pin_servo p21
#define servo_reload_time 1.0
#define pin_cylinder_reload p15
#define pin_sbdbt_pairing p12
#define pin_sbdbt_indicator p11
DigitalOut led1(LED1);
DigitalOut led2(LED2);
DigitalOut led3(LED3);
DigitalOut led4(LED4);
DigitalIn interrupt_cylinder_min(pin_interrupt_cylinder_min);
Serial pc(USBTX,USBRX);
RS422 rs422(rs422_tx, rs422_rx);
Sbdbt sbdbt(sbdbt_tx, sbdbt_rx, pin_sbdbt_pairing);
Ticker output_timer;
Mecanum mecanum;
Bno055 bno055;
Position_pid yaw_pid;
Accel v1;
Accel v2;
Accel v3;
Accel v4;
Cylinder cylinder(pin_cylinder_on,pin_cylinder_off);
Cyclic sword;
Cyclic cyclic_cylinder_position;
DigitalIn interrupt_sholderright_min(pin_interrupt_sholderright_min);
DigitalIn interrupt_sholderright_max(pin_interrupt_sholderright_max);
DigitalIn interrupt_sholderleft_min(pin_interrupt_sholderleft_min);
DigitalIn interrupt_sholderleft_max(pin_interrupt_sholderleft_max);
Encoder enc_cylinder(encoder_A,encoder_B);
Cyclic cyclic_servo;
Cyclic_IO cylinder_reload(pin_cylinder_reload);
PwmOut servo(pin_servo);
DigitalOut sbdbt_indigator(pin_sbdbt_indicator);
varEvent event;
void setup();
void output();
void motor_cal();
void cylinder_cal();
void boost();
void cylinder_origin();
void cylinder_origin_first();
void sword_cal();
void servo_origin();
float shoulder_right_cal();
float shoulder_left_cal();
//output
float yaw, target_yaw;
//cylinder_origin
int cylinder_origin_flag = 0;
//cylinder
float cylinder_pwm;
int cylinder_pos_num = 0;
float cylinder_pos[3] = {0.0,90.0,325.0};
//riseEventそのうちClassにしたい
short state;
int riseEvent(int input)
{
state = ((state<<1)|input)&3;
if(state == 1) {
return 1;
} else {
return 0;
}
}
int main()
{
setup();
while(1) {
led1 = interrupt_sholderleft_max;
led2 = interrupt_sholderleft_min;
led3 = interrupt_sholderright_max;
led4 = interrupt_sholderright_min;
event.input(sbdbt.left);
pc.printf("riseState %d : fallState %d\r\n",event.getRiseState(),event.getFallState());
}
}
void setup()
{
wait(2.0);
bno055.begin();
wait(1.0);
bno055.firstRead();
pc.baud(pc_baud);
sbdbt.begin(sbdbt_baud);
rs422.begin(rs422_baud);
cylinder_origin_first();
cylinder_pos_num = 2; //セットアップタイムでの初期装填のため
output_timer.attach(&output, output_period);
yaw_pid.setup(yaw_Kp, yaw_Ki, yaw_Kd);
mecanum.setupdeg(bno055.getYawRad()); //基盤が前後逆の場合+180
v1.setup(acceleration,output_period);
v2.setup(acceleration,output_period);
v3.setup(acceleration,output_period);
v4.setup(acceleration,output_period);
enc_cylinder.setup(100);
enc_cylinder.set_parameter(enc_Kp,enc_Ki,enc_Kd);
servo.period(0.020);
}
//Sword
float shoulder_right_cal()
{
if(interrupt_sholderright_max==0&&sbdbt.sankaku==1) {
return 0.0;
}
if(interrupt_sholderright_min==0&&sbdbt.batu==1) {
return 0.0;
}
return (-sbdbt.sankaku*0.8+sbdbt.batu*0.8);
}
float shoulder_left_cal()
{
if(interrupt_sholderleft_max==0&&sbdbt.sankaku==1) {
return 0.0;
}
if(interrupt_sholderleft_min==0&&sbdbt.batu==1) {
return 0.0;
}
return (-sbdbt.sankaku*0.8+sbdbt.batu*0.8);
}
void sword_cal()
{
sword.cyclic(sbdbt.maru);
}
//cylinder
void cylinder_origin_first()
{
while(interrupt_cylinder_min == 1){
rs422.put(5, -0.4, 0.0);
}
rs422.put(5, 0.0, 0.0);
enc_cylinder.origin();
}
//cylinder_origin_flagを1にすることで動作する
void cylinder_origin()
{
if(interrupt_cylinder_min == 0&&cylinder_origin_flag == 1) {
cylinder_origin_flag = 0;
enc_cylinder.origin();
cylinder_pos_num = 0;
} else if(cylinder_origin_flag == 1) {
rs422.put(5, -0.8, 0.0);
}
}
void cylinder_cal()
{
cylinder.cyclic(sbdbt.shikaku); //cylinder ON/OFF
if(riseEvent(sbdbt.right)) { //cylinder degset
cylinder_pos_num++;
if(cylinder_pos_num >= 3) {
//cylinder_pos_num = 0;
cylinder_origin_flag=1;
}
}
enc_cylinder.cal((float)cylinder_pos[cylinder_pos_num],output_period); //set cylinder_tergetPos
//pc.printf("terget\t%f\tnow_deg\t%f\tnow_pulse\t%d\tpwm\t%f\r\n",cylinder_pos[cylinder_pos_num],enc_cylinder.deg(),enc_cylinder.pulse(),enc_cylinder.duty());
}
void servo_max()
{
servo.pulsewidth(0.0022);
}
void servo_min()
{
servo.pulsewidth(0.0010);
}
void servo_out()
{
cyclic_servo.cyclic(sbdbt.down); //setServoControl
if(cyclic_servo.getState()==0) {
servo_min();
} else if(cyclic_servo.getState()==1) {
servo_max();
}
}
//boost
void boost()
{
if(sbdbt.r2) {
mecanum.boost_forward();
}
if(sbdbt.l2) {
mecanum.boost_back();
}
/*
if(sbdbt.shikaku) {
mecanum.boost_left();
}
if(sbdbt.maru) {
mecanum.boost_right();
}
*/
}
//mecanum
void motor_cal()
{
yaw = bno055.getYawRad();
target_yaw = yaw;
yaw_pid.cal(target_yaw, yaw, output_period);
mecanum.sbdbt_cal(sbdbt.left_x, sbdbt.left_y, sbdbt.l1, sbdbt.r1, yaw_pid.duty(), bno055.getYawRad());
// pc.printf("%f\t data %f\t %f\t %f\t %f\t\r\n", bno055.getYawRad(), sbdbt.left_x, sbdbt.left_y, mecanum.VX(), mecanum.VY());
}
void output()
{
motor_cal();
cylinder_cal();
sword_cal();
servo_out();
cylinder_origin();
//boost();
//led1 = sbdbt.get_pairingState();
sbdbt_indigator = sbdbt.get_pairingState();
if(sbdbt.up)cylinder_origin_flag = 1;
if(sbdbt.left)bno055.yaw_origin();
cylinder_reload.cyclic(sbdbt.down);
static int counter;
int id[nucleo_num] = {n1_id, n2_id, n3_id, n4_id, n5_id, n6_id};
//sbdbtがpairingしている場合のみ動作
if(sbdbt.get_pairingState()) {
switch (counter) {
case 0:
rs422.put(id[counter], v1.duty((mecanum.v1()*mecanum_power)+(sbdbt.right_y*0.5)), v3.duty((mecanum.v3()*mecanum_power)+(sbdbt.right_y*0.5)));
counter++;
break;
case 1:
//.duty(<cal>*<powerControle>+(<boost>*0.5))
rs422.put(id[counter], v2.duty((mecanum.v2()*mecanum_power)-(sbdbt.right_y*0.5)), v4.duty((mecanum.v4()*mecanum_power)-(sbdbt.right_y*0.5)));
counter ++;
break;
case 2:
rs422.put(id[counter], -1*enc_cylinder.duty_enableWidth(-.0,5.0), 0.0);
counter ++;
break;
case 3:
rs422.put(id[counter], -1*shoulder_right_cal()*sholder_power,shoulder_left_cal()*sholder_power);
counter ++;
break;
case 4:
rs422.put(id[counter], ((float)sword.getState()*sword_power),0.0);
counter = 0;
break;
default:
break;
}
}else{
switch (counter) {
case 0:
rs422.put(id[counter],0.0,0.0);
counter++;
break;
case 1:
rs422.put(id[counter],0.0,0.0);
counter ++;
break;
case 2:
rs422.put(id[counter],0.0,0.0);
counter ++;
break;
case 3:
rs422.put(id[counter],0.0,0.0);
counter ++;
break;
case 4:
rs422.put(id[counter],0.0,0.0);
counter = 0;
break;
default:
break;
}
}
}