SHENG-HEN HSIEH
By pOOPOO
Fork of
LSM9DS1_project_5_zerotorque
by 
Rong Syuan Lin
main.cpp
- Committer:
- open4416
- Date:
- 2018-11-05
- Revision:
- 10:6a9de32601b1
- Parent:
- 9:07de3af99031
File content as of revision 10:6a9de32601b1:
#define DEBUG_STDIO 1
#include "mbed.h" //不用gyro的data,只要輸出兩個imu的acce的xyz資料即可
#include "encoder.h"
//#include "Mx28.h"
//#include "PID.h"
#include "LSM9DS1.h"
//********************* Dynamxiel ******************************
#define SERVO_ID 0x01 // ID of which we will set Dynamixel too
#define SERVO_ControlPin A2 // Control pin of buffer chip, NOTE: this does not matter becasue we are not using a half to full contorl buffer.
#define SERVO_SET_Baudrate 1000000 // Baud rate speed which the Dynamixel will be set too (1Mbps)
#define TxPin A0
#define RxPin A1
#define CW_LIMIT_ANGLE 1 // lowest clockwise angle is 1, as when set to 0 it set servo to wheel mode
#define CCW_LIMIT_ANGLE 4095 // Highest anit-clockwise angle is 0XFFF, as when set to 0 it set servo to wheel mode
#define _PI 3.14159265f
//***************************************************************
Serial uart(USBTX, USBRX);
//Serial uart(D10,D2); // TX : D10 RX : D2 // bluetooth
DigitalOut LED(A4); // check if the code is running
DigitalOut led2(PA_5); // check if the code is running interrupt
AnalogIn EMG(PC_4); //
DigitalOut test(PC_8);
DigitalOut CS(PA_8);
uint8_t led2f; //測試用
//AnalogOut test2(PA_5);
/*IMU*******************************************************************/
LSM9DS1 imu(D14, D15); //SDA SCL
//LSM9DS1 imu2(PC_9,PA_8); //SDA SCL
void init_IMU();
int16_t Gyro_axis_data[6] = {0}; // X, Y, Z axis
int16_t Acce_axis_data[6] = {0}; // X, Y, Z axis
float Acce_axis_data_f[6] = {0}; //_f代表經過低通濾波的資料
float Acce_axis_data_f_old[6] = {0};
float Gyro_axis_data_f[6] = {0};
float Gyro_axis_data_f_old[6] = {0};
// Timer
Ticker timer1;
float ITR_time1 = 100.0; //timer interrupt unit:us 多少us計時一次 10毫秒
float Ts = ITR_time1/1000000; //控馬達的某個時間參數 不用理他
uint8_t flag;
// EMG
float lpf(float input, float output_old, float frequency); //low pass filter
float emg_value;
float emg_value_f;
float emg_value_f_old;
float Tf = ITR_time1/1000000; // 低通濾波的採樣週期
// uart_tx
union splitter { //將data切割為兩個byte
short j;
char C[2];
// C[0] is lowbyte of j, C[1] is highbyte of j
};
uint8_t T[16] = {255,255,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
// T[16]中的16是2+14,2為start btye 255 255,14為要傳7個參數到電腦,拆成high byte和low byte,所以是7*2=14
// 若要更改傳到電腦的參數個數,則改x*2=y,x為要傳的參數個數,y為char T[]裡面要有多少個0
int i = 0;
// function
void init_UART();
void init_TIMER();
void timer1_ITR();
void uart_tx(); // 傳data到電腦
/**************************************************************************/
int main()
{
// LED = 1; // darken
// wait_ms(500);
// initial sensor
// init_SPI_encoder();
// init_encoder();
init_UART();
init_IMU();
// initial uart
// wait_ms(500);
// led2 = 1;
// led2f = 0;
// LED = 0; // lighten
// init_TIMER();
while(1) {
// test = 1;
led2 = !led2;
// EMG
//emg_value = EMG.read();
// emg_value_f = lpf(emg_value,emg_value_f_old,15);
// emg_value_f_old = emg_value_f;
// IMU
imu.readAccel();
// imu.readGyro();
// imu2.readAccel();
// imu2.readGyro();
Acce_axis_data[0] = imu.ax*Acce_gain_x;
Acce_axis_data[1] = imu.ay*Acce_gain_y;
Acce_axis_data[2] = imu.az*Acce_gain_z;
// Acce_axis_data[3] = -imu2.ax*Acce_gain_x_2;
// Acce_axis_data[4] = imu2.az*Acce_gain_y_2;
// Acce_axis_data[5] = imu2.ay*Acce_gain_z_2;
Gyro_axis_data[0] = imu.gx*Gyro_gain_x;
Gyro_axis_data[1] = imu.gy*Gyro_gain_y;
Gyro_axis_data[2] = imu.gz*Gyro_gain_z;
// Gyro_axis_data[3] = -imu2.gx*Gyro_gain_x_2;
// Gyro_axis_data[4] = imu2.gz*Gyro_gain_y_2;
// Gyro_axis_data[5] = imu2.gy*Gyro_gain_z_2;
// for(i=0; i<6; i++) {
// Acce_axis_data_f[i] = lpf(Acce_axis_data[i],Acce_axis_data_f_old[i],15);
// Acce_axis_data_f_old[i] = Acce_axis_data_f[i];
// Gyro_axis_data_f[i] = lpf(Gyro_axis_data[i],Gyro_axis_data_f_old[i],15);
// Gyro_axis_data_f_old[i] = Gyro_axis_data_f[i];
// }
// int16_t shit2 = imu.ax_raw;
// uart.printf("%d\n\r", shit2);
uart.printf("x: %.2f, y: %.2f, z: %.2f\n\r",imu.ax, imu.ay, imu.az);
// uart_tx();
// flag = 0;
wait_ms(500);
// test = 0;
}
}
void init_IMU()
{
uint16_t shit;
shit = imu.begin(imu.G_SCALE_245DPS,imu.A_SCALE_2G,imu.M_SCALE_4GS,imu.G_ODR_238_BW_14,imu.A_ODR_119,imu.M_ODR_0625); //imu.G_SCALE_245DPS,imu.A_SCALE_2G,imu.M_SCALE_4GS,imu.G_ODR_238_BW_14,imu.A_ODR_119,imu.M_ODR_0625
// imu2.begin(imu.G_SCALE_500DPS,imu.A_SCALE_2G,imu.M_SCALE_4GS,imu.G_ODR_476_BW_21,imu.A_ODR_476,imu.M_ODR_0625);
if(shit != 0x683D) {
while(1) {
uart.printf("IMU error\n\r");
}
}
uart.printf("IMU init success\n\r");
// uart.printf("%d\n\r", shit);
}
void init_UART()
{
uart.baud(115200);
}
void init_TIMER()
{
timer1.attach_us(&timer1_ITR, ITR_time1);
}
void timer1_ITR() //開始讀取資料
{
// test = 1;
led2 = !led2;
// EMG
//emg_value = EMG.read();
// emg_value_f = lpf(emg_value,emg_value_f_old,15);
// emg_value_f_old = emg_value_f;
CS = 1;
// IMU
imu.readAccel();
// imu.readGyro();
// imu2.readAccel();
// imu2.readGyro();
//Acce_axis_data[0] = imu.ax*Acce_gain_x;
// Acce_axis_data[1] = imu.ay*Acce_gain_y;
// Acce_axis_data[2] = imu.az*Acce_gain_z;
// Acce_axis_data[3] = -imu2.ax*Acce_gain_x_2;
// Acce_axis_data[4] = imu2.az*Acce_gain_y_2;
// Acce_axis_data[5] = imu2.ay*Acce_gain_z_2;
//Gyro_axis_data[0] = imu.gx*Gyro_gain_x;
// Gyro_axis_data[1] = imu.gy*Gyro_gain_y;
// Gyro_axis_data[2] = imu.gz*Gyro_gain_z;
// Gyro_axis_data[3] = -imu2.gx*Gyro_gain_x_2;
// Gyro_axis_data[4] = imu2.gz*Gyro_gain_y_2;
// Gyro_axis_data[5] = imu2.gy*Gyro_gain_z_2;
//for(i=0; i<6; i++) {
// Acce_axis_data_f[i] = lpf(Acce_axis_data[i],Acce_axis_data_f_old[i],15);
// Acce_axis_data_f_old[i] = Acce_axis_data_f[i];
// Gyro_axis_data_f[i] = lpf(Gyro_axis_data[i],Gyro_axis_data_f_old[i],15);
// Gyro_axis_data_f_old[i] = Gyro_axis_data_f[i];
// }
// uart.printf("x: %7.4f, y: %7.4f, z: %7.4f\n\r",imu.ax, imu.ay, imu.az);
//uart_tx();
// flag = 0;
// wait_ms(1);
// test = 0;
}
void uart_tx() //分割資料
{
splitter s1;
splitter s2;
splitter s3;
splitter s4;
splitter s5;
splitter s6;
splitter s7;
// splitter s8;
s1.j = Acce_axis_data_f[0]; // 0x6161;//
s2.j = Acce_axis_data_f[1];
s3.j = Acce_axis_data_f[2];
s4.j = Acce_axis_data_f[3];
s5.j = Acce_axis_data_f[4];
s6.j = Acce_axis_data_f[5];
s7.j = emg_value_f;
// s8.j = 1; // 若要傳的參數不足8個,則隨意打一個常數即可
T[2] = Acce_axis_data[0]; //0x5A;
T[3] = Acce_axis_data[0] >>8;
T[4] = s2.C[0];
T[5] = s2.C[1];
T[6] = s3.C[0];
T[7] = s3.C[1];
T[8] = s4.C[0];
T[9] = s4.C[1];
T[10] = s5.C[0];
T[11] = s5.C[1];
T[12] = s6.C[0];
T[13] = s6.C[1];
T[14] = s7.C[0];
T[15] = s7.C[1];
// uart.putc(T[0]);
// uart.putc(T[1]);
// uart.putc(T[2]);
// uart.putc(T[3]);
// uart.putc(T[4]);
// uart.putc(T[5]);
// uart.putc(T[6]);
// uart.putc(T[7]);
// uart.putc(T[8]);
// uart.putc(T[9]);
// uart.putc(T[10]);
// uart.putc(T[11]);
// uart.putc(T[12]);
// uart.putc(T[13]);
// uart.putc(T[14]);
// uart.putc(T[15]);
// while(1) { //開始傳到USB
// if (uart.writeable() == 1) {
// uart.putc(T[i]);
// i++;
// }
// if (i >= sizeof(T)) {
// i = 0;
// break;
// }
// }
}
float lpf(float input, float output_old, float frequency)
{
float output = 0;
output = (output_old + frequency*Tf*input) / (1 + frequency*Tf);
return output;
}
//有估測器有delay,丟資料給機器學習時就不是及時動作,所以之後決定直接丟資料