Removed all calls to legacy trim_radio(). Handled by radio setup.

Added AP_Var Fingerprint checker. Will not let users fly with OOD firmware.
Tweaked Yaw to give better response. Let me know how it goes. It looks fine, but I've not flown it.


git-svn-id: https://arducopter.googlecode.com/svn/trunk@1878 f9c3cf11-9bcb-44bc-f272-b75c42450872
This commit is contained in:
jasonshort 2011-04-14 05:56:39 +00:00
parent 21980216b9
commit f6783454d7
7 changed files with 38 additions and 49 deletions

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@ -43,7 +43,7 @@ version 2.1 of the License, or (at your option) any later version.
#define MAVLINK_COMM_NUM_BUFFERS 2 #define MAVLINK_COMM_NUM_BUFFERS 2
#include <GCS_MAVLink.h> // MAVLink GCS definitions #include <GCS_MAVLink.h> // MAVLink GCS definitions
//#include <GCS_SIMPLE.h>
// Configuration // Configuration
@ -178,6 +178,7 @@ GPS *g_gps;
GCS_Class gcs; GCS_Class gcs;
#endif #endif
//#include <GCS_SIMPLE.h>
//GCS_SIMPLE gcs_simple(&Serial); //GCS_SIMPLE gcs_simple(&Serial);
AP_RangeFinder_MaxsonarXL sonar; AP_RangeFinder_MaxsonarXL sonar;

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@ -139,13 +139,6 @@ output_yaw_with_hold(boolean hold)
// Apply PID and save the new angle back to RC_Channel // Apply PID and save the new angle back to RC_Channel
g.rc_4.servo_out = g.pid_yaw.get_pid(yaw_error, delta_ms_fast_loop, 1.0); // .5 * 6000 = 3000 g.rc_4.servo_out = g.pid_yaw.get_pid(yaw_error, delta_ms_fast_loop, 1.0); // .5 * 6000 = 3000
// We adjust the output by the rate of rotation
long rate = degrees(omega.z) * 100.0; // 3rad = 17188 , 6rad = 34377
int dampener = (float)rate * g.hold_yaw_dampener; // 18000 * .17 = 3000
// Limit dampening to be equal to propotional term for symmetry
g.rc_4.servo_out -= constrain(dampener, -max_yaw_dampener, max_yaw_dampener); // -3000
}else{ }else{
// rate control // rate control
@ -155,33 +148,29 @@ output_yaw_with_hold(boolean hold)
// -error = CCW, +error = CW // -error = CCW, +error = CW
if(g.rc_4.control_in == 0){ if(g.rc_4.control_in == 0){
// we are breaking; // we are breaking;
g.rc_4.servo_out = (omega.z > 0) ? -1800 : 1800; //g.rc_4.servo_out = (omega.z > 0) ? -600 : 600;
g.rc_4.servo_out = (int)((float)g.rc_4.servo_out * (omega.z / 6.0));
//g.rc_4.servo_out = (int)((float)g.rc_4.servo_out * (omega.z / 6.0));
//switch comments to get old behavior.
//g.rc_4.servo_out = g.pid_acro_rate_yaw.get_pid(error, delta_ms_fast_loop, 1.0);// kP .07 * 36000 = 2520
}else{ }else{
g.rc_4.servo_out = g.pid_acro_rate_yaw.get_pid(error, delta_ms_fast_loop, 1.0); // kP .07 * 36000 = 2520 g.rc_4.servo_out = g.pid_acro_rate_yaw.get_pid(error, delta_ms_fast_loop, 1.0); // kP .07 * 36000 = 2520
}
}
// We adjust the output by the rate of rotation // We adjust the output by the rate of rotation
//long rate = degrees(omega.z) * 100.0; // 3rad = 17188 , 6rad = 34377 long rate = degrees(omega.z) * 100.0; // 3rad = 17188 , 6rad = 34377
//int dampener = (float)rate * g.hold_yaw_dampener; // 18000 * .17 = 3000 int dampener = (float)rate * g.hold_yaw_dampener; // 18000 * .17 = 3000
// Limit dampening to be equal to propotional term for symmetry // Limit dampening to be equal to propotional term for symmetry
//g.rc_4.servo_out -= constrain(dampener, -max_yaw_dampener, max_yaw_dampener); // -3000 g.rc_4.servo_out -= constrain(dampener, -max_yaw_dampener, max_yaw_dampener); // -3000
g.rc_4.servo_out = constrain(g.rc_4.servo_out, -1800, 1800); // limit to 24°
}
} // Limit Output
g.rc_4.servo_out = constrain(g.rc_4.servo_out, -1800, 1800); // limit to 24°
//Serial.printf("%d\n",g.rc_4.servo_out); //Serial.printf("%d\n",g.rc_4.servo_out);
} }
// slight left rudder gives right roll.
void void
output_rate_roll() output_rate_roll()
{ {

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@ -29,7 +29,6 @@ void arm_motors()
}else{ }else{
arming_counter = 0; arming_counter = 0;
} }
}else{ }else{
arming_counter = 0; arming_counter = 0;
} }
@ -55,7 +54,7 @@ set_servos_4()
g.rc_3.servo_out = constrain(g.rc_3.servo_out, 0, 1000); g.rc_3.servo_out = constrain(g.rc_3.servo_out, 0, 1000);
if(g.rc_3.servo_out > 0) if(g.rc_3.servo_out > 0)
out_min = g.rc_3.radio_min + 50; out_min = g.rc_3.radio_min + 60;
//Serial.printf("out: %d %d %d %d\t\t", g.rc_1.servo_out, g.rc_2.servo_out, g.rc_3.servo_out, g.rc_4.servo_out); //Serial.printf("out: %d %d %d %d\t\t", g.rc_1.servo_out, g.rc_2.servo_out, g.rc_3.servo_out, g.rc_4.servo_out);
@ -65,6 +64,10 @@ set_servos_4()
g.rc_3.calc_pwm(); g.rc_3.calc_pwm();
g.rc_4.calc_pwm(); g.rc_4.calc_pwm();
// limit Yaw control so we don't clip and loose altitude
// this is only a partial solution.
g.rc_4.pwm_out = min(g.rc_4.pwm_out, (g.rc_3.radio_out - out_min));
//Serial.printf("out: %d %d %d %d\n", g.rc_1.radio_out, g.rc_2.radio_out, g.rc_3.radio_out, g.rc_4.radio_out); //Serial.printf("out: %d %d %d %d\n", g.rc_1.radio_out, g.rc_2.radio_out, g.rc_3.radio_out, g.rc_4.radio_out);
//Serial.printf("yaw: %d ", g.rc_4.radio_out); //Serial.printf("yaw: %d ", g.rc_4.radio_out);
@ -241,6 +244,7 @@ set_servos_4()
gcs_simple.write_int((int)nav_roll); gcs_simple.write_int((int)nav_roll);
gcs_simple.write_int((int)nav_pitch); gcs_simple.write_int((int)nav_pitch);
gcs_simple.write_long(current_loc.lat); //28 gcs_simple.write_long(current_loc.lat); //28
gcs_simple.write_long(current_loc.lng); //32 gcs_simple.write_long(current_loc.lng); //32
gcs_simple.write_int((int)current_loc.alt); //34 gcs_simple.write_int((int)current_loc.alt); //34

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@ -54,6 +54,7 @@ void calc_loiter_nav()
Becuase we are using lat and lon to do our distance errors here's a quick chart: Becuase we are using lat and lon to do our distance errors here's a quick chart:
100 = 1m 100 = 1m
1000 = 11m 1000 = 11m
1800 = 1980m = 60 feet
3000 = 33m 3000 = 33m
10000 = 111m 10000 = 111m
pitch_max = 22° (2200) pitch_max = 22° (2200)
@ -89,26 +90,21 @@ void calc_waypoint_nav()
//nav_lat = max(wp_distance, -DIST_ERROR_MAX); //nav_lat = max(wp_distance, -DIST_ERROR_MAX);
//nav_lat = min(wp_distance, DIST_ERROR_MAX); //nav_lat = min(wp_distance, DIST_ERROR_MAX);
//Serial.printf("nav_lat %ld, ", nav_lat);
// Scale response by kP // Scale response by kP
nav_lat *= g.pid_nav_lat.kP(); // 1800 * 2 = 3600 or 36° nav_lat *= g.pid_nav_lat.kP(); // 1800 * 2 = 3600 or 36°
//Serial.printf("%ld, ",nav_lat);
// get the sin and cos of the bearing error - rotated 90° // get the sin and cos of the bearing error - rotated 90°
sin_nav_y = sin(radians((float)(9000 - bearing_error) / 100)); sin_nav_y = sin(radians((float)(9000 - bearing_error) / 100));
cos_nav_x = cos(radians((float)(bearing_error - 9000) / 100)); cos_nav_x = cos(radians((float)(bearing_error - 9000) / 100));
//Serial.printf("X%2.4f, Y%2.4f ", cos_nav_x, sin_nav_y);
// rotate the vector // rotate the vector
nav_roll = (float)nav_lat * cos_nav_x; nav_roll = (float)nav_lat * cos_nav_x;
nav_pitch = -(float)nav_lat * sin_nav_y; nav_pitch = -(float)nav_lat * sin_nav_y;
//Serial.printf("R%ld, P%ld ", nav_roll, nav_pitch);
long pmax = g.pitch_max.get(); long pmax = g.pitch_max.get();
nav_roll = constrain(nav_roll, -pmax, pmax); nav_roll = constrain(nav_roll, -pmax, pmax);
nav_pitch = constrain(nav_pitch, -pmax, pmax); nav_pitch = constrain(nav_pitch, -pmax, pmax);
//Serial.printf("R%ld, P%ld \n", nav_roll, nav_pitch);
} }
void calc_bearing_error() void calc_bearing_error()

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@ -202,10 +202,6 @@ setup_motors(uint8_t argc, const Menu::arg *argv)
init_rc_in(); init_rc_in();
// read the radio to set trims
// ---------------------------
trim_radio();
print_hit_enter(); print_hit_enter();
delay(1000); delay(1000);
@ -382,7 +378,6 @@ setup_flightmodes(uint8_t argc, const Menu::arg *argv)
Serial.printf_P(PSTR("\nMove RC toggle switch to each position to edit, move aileron stick to select modes.")); Serial.printf_P(PSTR("\nMove RC toggle switch to each position to edit, move aileron stick to select modes."));
print_hit_enter(); print_hit_enter();
trim_radio();
while(1){ while(1){
delay(20); delay(20);

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@ -107,7 +107,21 @@ void init_ardupilot()
// save the new format version // save the new format version
g.format_version.set_and_save(Parameters::k_format_version); g.format_version.set_and_save(Parameters::k_format_version);
//Serial.println_P(PSTR("done.")); Serial.printf_P(PSTR("Please Run Setup...\n"));
while (true) {
delay(100);
if(motor_light){
digitalWrite(A_LED_PIN, HIGH);
digitalWrite(B_LED_PIN, HIGH);
digitalWrite(C_LED_PIN, HIGH);
}else{
digitalWrite(A_LED_PIN, LOW);
digitalWrite(B_LED_PIN, LOW);
digitalWrite(C_LED_PIN, LOW);
}
motor_light = !motor_light;
}
}else{ }else{
unsigned long before = micros(); unsigned long before = micros();
// Load all auto-loaded EEPROM variables // Load all auto-loaded EEPROM variables
@ -245,7 +259,7 @@ void startup_ground(void)
// read the radio to set trims // read the radio to set trims
// --------------------------- // ---------------------------
trim_radio(); //trim_radio();
if (g.log_bitmask & MASK_LOG_CMD) if (g.log_bitmask & MASK_LOG_CMD)
Log_Write_Startup(TYPE_GROUNDSTART_MSG); Log_Write_Startup(TYPE_GROUNDSTART_MSG);

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@ -129,10 +129,6 @@ test_radio(uint8_t argc, const Menu::arg *argv)
print_hit_enter(); print_hit_enter();
delay(1000); delay(1000);
// read the radio to set trims
// ---------------------------
trim_radio();
while(1){ while(1){
delay(20); delay(20);
read_radio(); read_radio();
@ -183,10 +179,6 @@ test_failsafe(uint8_t argc, const Menu::arg *argv)
read_radio(); read_radio();
} }
// read the radio to set trims
// ---------------------------
trim_radio();
oldSwitchPosition = readSwitch(); oldSwitchPosition = readSwitch();
Serial.printf_P(PSTR("Unplug battery, throttle in neutral, turn off radio.\n")); Serial.printf_P(PSTR("Unplug battery, throttle in neutral, turn off radio.\n"));
@ -243,8 +235,6 @@ test_stabilize(uint8_t argc, const Menu::arg *argv)
Serial.printf_P(PSTR("g.pid_stabilize_roll.kP: %4.4f\n"), g.pid_stabilize_roll.kP()); Serial.printf_P(PSTR("g.pid_stabilize_roll.kP: %4.4f\n"), g.pid_stabilize_roll.kP());
Serial.printf_P(PSTR("max_stabilize_dampener:%d\n\n "), max_stabilize_dampener); Serial.printf_P(PSTR("max_stabilize_dampener:%d\n\n "), max_stabilize_dampener);
trim_radio();
motor_auto_safe = false; motor_auto_safe = false;
motor_armed = true; motor_armed = true;