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Simple "hello world" style program for X-NUCLEO-IKS01A1 MEMS Inertial
Dependencies: GraphicsDisplay X_NUCLEO_IKS01A1 HelloWorld_IKS01A1 mbed-src mbed
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HelloWorld_IKS01A1
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main.cpp
- Committer:
- istheworldreal
- Date:
- 2016-05-18
- Revision:
- 7:dc9ba99b1928
- Parent:
- 4:b1526d074d83
File content as of revision 7:dc9ba99b1928:
/* Includes */
#include "mbed.h"
#include "x_nucleo_iks01a1.h"
/* Instantiate the expansion board */
static X_NUCLEO_IKS01A1 *mems_expansion_board = X_NUCLEO_IKS01A1::Instance(D14, D15);
/* Retrieve the composing elements of the expansion board */
static GyroSensor *gyroscope = mems_expansion_board->GetGyroscope();
static MotionSensor *accelerometer = mems_expansion_board->GetAccelerometer();
static MagneticSensor *magnetometer = mems_expansion_board->magnetometer;
static HumiditySensor *humidity_sensor = mems_expansion_board->ht_sensor;
static PressureSensor *pressure_sensor = mems_expansion_board->pt_sensor;
static TempSensor *temp_sensor1 = mems_expansion_board->ht_sensor;
static TempSensor *temp_sensor2 = mems_expansion_board->pt_sensor;
/* Helper function for printing floats & doubles */
static char *printDouble(char* str, double v, int decimalDigits=2)
{
int i = 1;
int intPart, fractPart;
int len;
char *ptr;
/* prepare decimal digits multiplicator */
for (;decimalDigits!=0; i*=10, decimalDigits--);
/* calculate integer & fractinal parts */
intPart = (int)v;
fractPart = (int)((v-(double)(int)v)*i);
/* fill in integer part */
sprintf(str, "%i.", intPart);
/* prepare fill in of fractional part */
len = strlen(str);
ptr = &str[len];
/* fill in leading fractional zeros */
for (i/=10;i>1; i/=10, ptr++) {
if(fractPart >= i) break;
*ptr = '0';
}
/* fill in (rest of) fractional part */
sprintf(ptr, "%i", fractPart);
return str;
}
/* Simple main function */
int main() {
uint8_t id;
float value1, value2;
char buffer1[32], buffer2[32];
int32_t axes[3];
int32_t m[3];
int32_t n[3];
int32_t r;
int32_t i;
int32_t lock_unlock=0;
printf("\r\n--- Starting new run ---\r\n");
humidity_sensor->ReadID(&id);
printf("HTS221 humidity & temperature = 0x%X\r\n", id);
//pressure_sensor->ReadID(&id);
// printf("LPS25H pressure & temperature = 0x%X\r\n", id);
//magnetometer->ReadID(&id);
//printf("LIS3MDL magnetometer = 0x%X\r\n", id);
gyroscope->ReadID(&id);
printf("LSM6DS0 accelerometer & gyroscope = 0x%X\r\n", id);
DigitalOut myled(LED1);
DigitalIn mybutton(USER_BUTTON);
wait(3);
while(1) {
wait(1);
printf("\r\n");
temp_sensor1->GetTemperature(&value1);
humidity_sensor->GetHumidity(&value2);
if ((value1>27) && (value2>70))
{
myled=1;
wait(1);
myled=0;
printf("Excessive Temperature & Excessive Humidity\r\n");
}
if ((value1>27) && (value2<=70))
{
myled=1;
wait(0.3);
myled=0;
printf("Excessive Temperature\r\n");
}
if ((value1<=27) && (value2>70))
{
myled=1;
wait(0.6);
myled=0;
printf("Excessive Humidity\r\n");
}
printf("HTS221: [temp] %7s°C, [hum] %s%%\r\n", printDouble(buffer1, value1), printDouble(buffer2, value2));
temp_sensor2->GetFahrenheit(&value1);
//pressure_sensor->GetPressure(&value2);
//printf("LPS25H: [temp] %7s°F, [press] %smbar\r\n", printDouble(buffer1, value1), printDouble(buffer2, value2));
if(mybutton == 0)
{
lock_unlock =! lock_unlock;
myled=1;
wait(0.2);
myled=0;
wait(0.2);
myled=1;
wait(0.2);
myled=0;
}
if (lock_unlock == 0)
{
printf("SecuritySystemON\r\n");
accelerometer->Get_X_Axes(axes);
for (i=0;i<3;i++)
{
m[i]=axes[i];
}
wait(0.2);
accelerometer->Get_X_Axes(axes);
for (i=0;i<3;i++)
{
n[i]=axes[i];
}
r=(m[0]-n[0])*(m[0]-n[0])+(m[1]-n[1])*(m[1]-n[1])+(m[2]-n[2])*(m[2]-n[2]);
if(r>70)
{
myled=1;
printf("Security Alert\r\n");
}
printf("LSM6DS0 [acc/mg]:%6ld, %6ld, %6ld\r\n", axes[0], axes[1], axes[2]);
}
if (lock_unlock != 0)
{
printf("UNLOCKED\r\n");
printf("SecuritySystemOFF\r\n");
}
wait(1.5);
}
}