ardupilot/ArduCopter/sensors.pde

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// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
// Sensors are not available in HIL_MODE_ATTITUDE
#if HIL_MODE != HIL_MODE_ATTITUDE
static void ReadSCP1000(void) {}
#if CONFIG_SONAR == ENABLED
static void init_sonar(void)
{
#if CONFIG_SONAR_SOURCE == SONAR_SOURCE_ADC
sonar.calculate_scaler(g.sonar_type, 3.3);
#else
sonar.calculate_scaler(g.sonar_type, 5.0);
#endif
}
#endif
static void init_barometer(void)
{
#if HIL_MODE == HIL_MODE_SENSORS
gcs_update(); // look for inbound hil packets for initialization
#endif
ground_temperature = barometer.get_temperature();
int i;
// We take some readings...
for(i = 0; i < 60; i++){
delay(20);
// get new data from absolute pressure sensor
barometer.read();
//Serial.printf("init %ld, %d, -, %ld, %ld\n", barometer.RawTemp, barometer.Temp, barometer.RawPress, barometer.Press);
}
for(i = 0; i < 20; i++){
delay(20);
#if HIL_MODE == HIL_MODE_SENSORS
gcs_update(); // look for inbound hil packets
#endif
// Get initial data from absolute pressure sensor
barometer.read();
ground_pressure = barometer.get_pressure();
ground_temperature = (ground_temperature * 7 + barometer.get_temperature()) / 8;
//Serial.printf("init %ld, %d, -, %ld, %ld, -, %d, %ld\n", barometer.RawTemp, barometer.Temp, barometer.RawPress, barometer.Press, ground_temperature, ground_pressure);
}
}
static void reset_baro(void)
{
ground_pressure = barometer.get_pressure();
ground_temperature = barometer.get_temperature();
}
static int32_t read_barometer(void)
{
float x, scaling, temp;
barometer.read();
float abs_pressure = barometer.get_pressure();
//Serial.printf("%ld, %ld, %ld, %ld\n", barometer.RawTemp, barometer.RawPress, barometer.Press, abs_pressure);
scaling = (float)ground_pressure / abs_pressure;
temp = ((float)ground_temperature / 10.0f) + 273.15f;
x = log(scaling) * temp * 29271.267f;
return (x / 10);
}
#endif // HIL_MODE != HIL_MODE_ATTITUDE
static void init_compass()
{
compass.set_orientation(MAG_ORIENTATION); // set compass's orientation on aircraft
dcm.set_compass(&compass);
compass.init();
compass.get_offsets(); // load offsets to account for airframe magnetic interference
Bug fix for compass. This is a fix for an interesting bug when a DCM matrix reset was added to the ground start. This bug only showed up if (A) a ground start were performed after an air start or due to use of the "Calibrate Gryo" action, (B) if the current orientation were sufficiently different from 0/0/0, and (C.) if the particular magnetometer had sufficiently large offsets. Why did resetting the DCM matrix to 0/0/0 pitch/roll/yaw at ground start cause a bug? The magnetometer offset nulling determines the proper offsets for the magnetometer by comparing the observed change in the magnetic field vector with the expected change due to rotation as calculated from the rotation in the DCM matrix. This comparison is made at 10Hz, and then filtered with a weight based on the amount of rotation to estimate the offsets. Normally it would take considerable time at normal in-flight rotation rates for the offset estimate to converge. If a DCM matrix reset occurs when the offset nulling algorithm is up and running, the algorithm sees the DCM reset as a instantaneous rotation, however the magnetic field vector did not change at all. Under certain conditions the algorithm would interpret this as indicating that the offset(s) should be very large. Since the "rotation" could also have been large the filter weighting would be large and it was possible for a large erroneous estimate of the offset(s) to be made based on this single (bad) data point. To fix this bug methods were added to the compass object to start and stop the offset nulling algorithm. Further, when the algorithm is started, it is set up to get fresh samples. The DCM matrix reset method now calls these new methods to stop the offset nulling before resetting the matrix, and resume after the matrix has been reset.
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compass.null_offsets_enable();
}
static void init_optflow()
{
#ifdef OPTFLOW_ENABLED
if( optflow.init(false) == false ) {
g.optflow_enabled = false;
SendDebug("\nFailed to Init OptFlow ");
}
optflow.set_orientation(OPTFLOW_ORIENTATION); // set optical flow sensor's orientation on aircraft
optflow.set_field_of_view(OPTFLOW_FOV); // set optical flow sensor's field of view
// setup timed read of sensor
//timer_scheduler.register_process(&AP_OpticalFlow::read);
#endif
}
static void read_battery(void)
{
if(g.battery_monitoring == 0){
battery_voltage1 = 0;
return;
}
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if(g.battery_monitoring == 3 || g.battery_monitoring == 4)
battery_voltage1 = BATTERY_VOLTAGE(analogRead(BATTERY_PIN_1)) * .1 + battery_voltage1 * .9;
if(g.battery_monitoring == 4) {
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current_amps1 = CURRENT_AMPS(analogRead(CURRENT_PIN_1)) * .1 + current_amps1 * .9; //reads power sensor current pin
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current_total1 += current_amps1 * 0.02778; // called at 100ms on average, .0002778 is 1/3600 (conversion to hours)
}
#if BATTERY_EVENT == 1
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//if(battery_voltage < g.low_voltage)
// low_battery_event();
if((battery_voltage1 < g.low_voltage) || (g.battery_monitoring == 4 && current_total1 > g.pack_capacity)){
low_battery_event();
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#if PIEZO_LOW_VOLTAGE == 1
// Only Activate if a battery is connected to avoid alarm on USB only
if (battery_voltage1 > 1){
piezo_on();
}else{
piezo_off();
}
#endif
}else{
#if PIEZO_LOW_VOLTAGE == 1
piezo_off();
#endif
}
#endif
}
//v: 10.9453, a: 17.4023, mah: 8.2