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This is the real HEAD of the APM_Camera branch. Seams that lots of changes got lost in the SVN to GIT port

This commit is contained in:
Amilcar Lucas 2011-09-09 16:02:22 +02:00
parent ec398505a6
commit f40c85a601
5 changed files with 126 additions and 552 deletions
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210
ArduPlane/Cam_move.pde
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@ -1,210 +0,0 @@
/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
#if CAMERA == ENABLED
void init_camera()
{
g.rc_camera_pitch.set_angle(4500); // throw of servo?
g.rc_camera_pitch.radio_min = 1000; // lowest radio input
g.rc_camera_pitch.radio_trim = 1500; // middle radio input
g.rc_camera_pitch.radio_max = 2000; // highest radio input
g.rc_camera_roll.set_angle(4500);
g.rc_camera_roll.radio_min = 1000;
g.rc_camera_roll.radio_trim = 1500;
g.rc_camera_roll.radio_max = 2000;
//use test target for now
camera_target = home;
}
void camera()
{
//decide what happens to camera depending on camera mode
switch(camera_mode)
{
case 0:
//do nothing, i.e lock camera in place
break;
case 1:
//stabilize
target_vector.x=0; //east to west gives +tive value (i.e. longitude)
target_vector.y=0; //south to north gives +tive value (i.e. latitude)
target_vector.z=100; //downwards is +tive
camera_move();
break;
case 2:
//track target
if(g_gps->fix)
{
target_vector=get_location_vector(&current_loc,&camera_target);
camera_move();
}
break;
}
}
void camera_move()
{
Matrix3f m = dcm.get_dcm_transposed();
Vector3<float> targ = m*target_vector; //to do: find out notion of x y convention
switch(gimbal_mode)
{
case 0: // pitch & roll
cam_pitch = degrees(atan2(-targ.x, targ.z)); //pitch
cam_roll = degrees(atan2(targ.y, targ.z)); //roll
// check_limits(pitch);
// check_limits(roll);
// camera_out();
break;
case 1: // pitch and yaw
cam_tilt = atan2((sqrt(sq(targ.y) + sq(targ.x)) * .01113195), targ.z) * -1;
cam_pan = 9000 + atan2(-targ.y, targ.x) * 5729.57795;
if (cam_pan < 0) cam_pan += 36000;
// check_limits(pitch);
// check_limits(yaw);
// camera_out();
break;
/* case 2: // pitch, roll & yaw - not started
float cam_ritch = 100;
float cam_yoll = 100;
float cam_paw = 100;
break; */
}
}
/* void check_limits(axis,variable) // Use servo definitions to calculate for all servo throws - TO DO
{
// find limits of servo range in deg
track_pan_right = PAN_CENTER + (PAN_RANGE/2);
track_pan_left = track_pan_right + (360 - PAN_RANGE);
if (track_pan_left > 360){
track_pan_left = track_pan_left - 360;
}
// check track_bearing is "safe" - not outside pan servo limits
// if the bearing lies in the servo dead zone change bearing to closet edge
if (track_bearing < track_pan_left && track_bearing > track_pan_right){
track_oor_l = abs(track_bearing - track_pan_left);
track_oor_r = abs(track_bearing - track_pan_right);
if (track_oor_r > track_oor_l){
track_bearing = track_pan_right;
}
if (track_oor_l > track_oor_r){
track_bearing = track_pan_left;
}
}
// center bearing to cam_servo center
track_pan_deg = track_bearing - PAN_CENTER;
// make negative is left rotation
if (track_pan_deg > 180){
track_pan_deg = (180 - (track_pan_deg - 180)) * -1;
}
} */
void camera_out()
{
switch(gimbal_mode)
{
case 0: // pitch & roll
g.rc_camera_pitch.servo_out = cam_pitch;
g.rc_camera_pitch.calc_pwm();
g.rc_camera_roll.servo_out = cam_roll;
g.rc_camera_roll.calc_pwm();
break;
case 1: // pitch and yaw
g.rc_camera_pitch.servo_out = cam_tilt;
g.rc_camera_pitch.calc_pwm();
g.rc_camera_roll.servo_out = cam_pan; // borrowing roll servo output for pan/yaw
g.rc_camera_roll.calc_pwm();
break;
/*case 2: // pitch, roll & yaw
g.rc_camera_pitch.servo_out = cam_ritch;
g.rc_camera_pitch.calc_pwm();
g.rc_camera_roll.servo_out = cam_yoll;
g.rc_camera_roll.calc_pwm();
g.rc_camera_yaw.servo_out = cam_paw; // camera_yaw doesn't exist it should unless we use another channel
g.rc_camera_yaw.calc_pwm();
break; */
}
#if defined PITCH_SERVO
APM_RC.OutputCh(PITCH_SERVO, g.rc_camera_pitch.radio_out);
#endif
#if defined ROLL_SERVO
APM_RC.OutputCh(ROLL_SERVO, g.rc_camera_roll.radio_out);
#endif
/*#if defined YAW_SERVO
APM_RC.OutputCh(YAW_SERVO, g.rc_camera_yaw.radio_out);
#endif */
#if CAM_DEBUG == ENABLED
//for debugging purposes
Serial.println();
Serial.print("current_loc: lat: ");
Serial.print(current_loc.lat);
Serial.print(", lng: ");
Serial.print(current_loc.lng);
Serial.print(", alt: ");
Serial.print(current_loc.alt);
Serial.println();
Serial.print("target_loc: lat: ");
Serial.print(camera_target.lat);
Serial.print(", lng: ");
Serial.print(camera_target.lng);
Serial.print(", alt: ");
Serial.print(camera_target.alt);
Serial.print(", distance: ");
Serial.print(get_distance(&current_loc,&camera_target));
Serial.print(", bearing: ");
Serial.print(get_bearing(&current_loc,&camera_target));
Serial.println();
Serial.print("dcm_angles: roll: ");
Serial.print(degrees(dcm.roll));
Serial.print(", pitch: ");
Serial.print(degrees(dcm.pitch));
Serial.print(", yaw: ");
Serial.print(degrees(dcm.yaw));
Serial.println();
Serial.print("target_vector: x: ");
Serial.print(target_vector.x,2);
Serial.print(", y: ");
Serial.print(target_vector.y,2);
Serial.print(", z: ");
Serial.print(target_vector.z,2);
Serial.println();
Serial.print("rotated_target_vector: x: ");
Serial.print(targ.x,2);
Serial.print(", y: ");
Serial.print(targ.y,2);
Serial.print(", z: ");
Serial.print(targ.z,2);
Serial.println();
Serial.print("gimbal type 0: roll: ");
Serial.print(roll);
Serial.print(", pitch: ");
Serial.print(pitch);
Serial.println();
/* Serial.print("gimbal type 1: pitch: ");
Serial.print(pan);
Serial.print(", roll: ");
Serial.print(tilt);
Serial.println(); */
/* Serial.print("gimbal type 2: pitch: ");
Serial.print(ritch);
Serial.print(", roll: ");
Serial.print(yoll);
Serial.print(", yaw: ");
Serial.print(paw);
Serial.println(); */
#endif
}
#endif

41
ArduPlane/Cam_trigger.pde
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@ -1,41 +0,0 @@
void servo_pic() // Servo operated camera
{
APM_RC.OutputCh(CAM_SERVO,1500 + (333)); // Camera click, not enough - add more, wring way - put a minus before bracket number (-300)
delay(250); // delay
APM_RC.OutputCh(CAM_SERVO,1500); // Return servo to mid position
}
void relay_picture() // basic relay activation
{
relay_on();
delay(250); // 0.25 seconds delay
relay_off();
}
void throttle_pic() // pictures blurry? use this trigger. Turns off the throttle until for # of cycles of medium loop then takes the picture and re-enables the throttle.
{
g.channel_throttle.radio_out = g.throttle_min;
if (thr_pic = 10){
servo_pic(); // triggering method
thr_pic = 0;
g.channel_throttle.radio_out = g.throttle_cruise;
}
thr_pic++;
}
void distance_pic() // pictures blurry? use this trigger. Turns off the throttle until closer to waypoint then takes the picture and re-enables the throttle.
{
g.channel_throttle.radio_out = g.throttle_min;
if (wp_distance < 3){
servo_pic(); // triggering method
g.channel_throttle.radio_out = g.throttle_cruise;
}
}
void NPN_trigger() // hacked the circuit to run a transistor? use this trigger to send output.
{
// To Do: Assign pin spare pin for output
digitalWrite(camtrig, HIGH);
delay(50);
digitalWrite(camtrig, LOW);
}

116
libraries/AP_Camera/AP_Camera.cpp Normal file
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@ -0,0 +1,116 @@
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*-
#include <AP_Camera.h>
#include <RC_Channel.h>
extern RC_Channel_aux* g_rc_function[RC_Channel_aux::k_nr_aux_servo_functions]; // the aux. servo ch. assigned to each function
extern long wp_distance;
extern "C" {
void relay_on();
void relay_off();
}
void
AP_Camera::servo_pic() // Servo operated camera
{
if (g_rc_function[RC_Channel_aux::k_cam_trigger])
{
g_rc_function[RC_Channel_aux::k_cam_trigger]->radio_out = g_rc_function[RC_Channel_aux::k_cam_trigger]->radio_max;
keep_cam_trigg_active_cycles = 2; // leave a message that it should be active for two event loop cycles
}
}
void
AP_Camera::relay_pic() // basic relay activation
{
relay_on();
keep_cam_trigg_active_cycles = 2; // leave a message that it should be active for two event loop cycles
}
void
AP_Camera::throttle_pic() // pictures blurry? use this trigger. Turns off the throttle until for # of cycles of medium loop then takes the picture and re-enables the throttle.
{
// TODO find a way to do this without using the global parameter g
// g.channel_throttle.radio_out = g.throttle_min;
if (thr_pic == 10){
servo_pic(); // triggering method
thr_pic = 0;
// g.channel_throttle.radio_out = g.throttle_cruise;
}
thr_pic++;
}
void
AP_Camera::distance_pic() // pictures blurry? use this trigger. Turns off the throttle until closer to waypoint then takes the picture and re-enables the throttle.
{
// TODO find a way to do this without using the global parameter g
// g.channel_throttle.radio_out = g.throttle_min;
if (wp_distance < 3){
servo_pic(); // triggering method
// g.channel_throttle.radio_out = g.throttle_cruise;
}
}
void
AP_Camera::NPN_pic() // hacked the circuit to run a transistor? use this trigger to send output.
{
// TODO: Assign pin spare pin for output
digitalWrite(camtrig, HIGH);
keep_cam_trigg_active_cycles = 1; // leave a message that it should be active for two event loop cycles
}
// single entry point to take pictures
void
AP_Camera::trigger_pic()
{
switch (trigger_type)
{
case 0:
servo_pic(); // Servo operated camera
break;
case 1:
relay_pic(); // basic relay activation
break;
case 2:
throttle_pic(); // pictures blurry? use this trigger. Turns off the throttle until for # of cycles of medium loop then takes the picture and re-enables the throttle.
break;
case 3:
distance_pic(); // pictures blurry? use this trigger. Turns off the throttle until closer to waypoint then takes the picture and re-enables the throttle.
break;
case 4:
NPN_pic(); // hacked the circuit to run a transistor? use this trigger to send output.
break;
}
}
// de-activate the trigger after some delay, but without using a delay() function
void
AP_Camera::trigger_pic_cleanup()
{
if (keep_cam_trigg_active_cycles)
{
keep_cam_trigg_active_cycles --;
}
else
{
switch (trigger_type)
{
case 0:
case 2:
case 3:
if (g_rc_function[RC_Channel_aux::k_cam_trigger])
{
g_rc_function[RC_Channel_aux::k_cam_trigger]->radio_out = g_rc_function[RC_Channel_aux::k_cam_trigger]->radio_min;
}
break;
case 1:
// TODO for some strange reason the function call bellow gives a linker error
//relay_off();
PORTL &= ~B00000100; // hardcoded version of relay_off(). Replace with a proper function call later.
break;
case 4:
digitalWrite(camtrig, LOW);
break;
}
}
}

34
libraries/AP_Camera/Camera.h → libraries/AP_Camera/AP_Camera.h
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@ -1,16 +1,16 @@
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*-
/// @file Camera.h
/// @file AP_Camera.h
/// @brief Photo or video camera manager, with EEPROM-backed storage of constants.
#ifndef CAMERA_H
#define CAMERA_H
#ifndef AP_CAMERA_H
#define AP_CAMERA_H
#include <AP_Common.h>
/// @class Camera
/// @brief Object managing a Photo or video camera
class Camera{
class AP_Camera{
protected:
AP_Var_group _group; // must be before all vars to keep ctor init order correct
@ -20,45 +20,31 @@ public:
/// @param key EEPROM storage key for the camera configuration parameters.
/// @param name Optional name for the group.
///
Camera(AP_Var::Key key, const prog_char_t *name) :
AP_Camera(AP_Var::Key key, const prog_char_t *name) :
_group(key, name),
mode (&_group, 0, 0, name ? PSTR("MODE") : 0), // suppress name if group has no name
trigger_type(&_group, 1, 0, name ? PSTR("TRIGGER_MODE") : 0),
trigger_type(&_group, 0, 0, name ? PSTR("TRIGG_TYPE") : 0),
picture_time (0), // waypoint trigger variable
thr_pic (0), // timer variable for throttle_pic
camtrig (83), // PK6 chosen as it not near anything so safer for soldering
// camera_target (home), // use test target for now
gimbal_type (1),
keep_cam_trigg_active_cycles (0)
keep_cam_trigg_active_cycles (0),
wp_distance_min (10)
{}
// move the camera depending on the camera mode
void move();
// single entry point to take pictures
void trigger_pic();
// de-activate the trigger after some delay, but without using a delay() function
void trigger_pic_cleanup();
// call this from time to time to make sure the correct gimbal type gets choosen
void update_camera_gimbal_type();
// set camera orientation target
void set_target(struct Location target);
int picture_time; // waypoint trigger variable
long wp_distance_min; // take picture if distance to WP is smaller than this
private:
uint8_t keep_cam_trigg_active_cycles; // event loop cycles to keep trigger active
struct Location camera_target; // point of interest for the camera to track
// struct Location GPS_mark; // GPS POI for position based triggering
int thr_pic; // timer variable for throttle_pic
int camtrig; // PK6 chosen as it not near anything so safer for soldering
AP_Int8 mode; // 0=do nothing, 1=stabilize, 2=track target, 3=manual, 4=simple stabilize test
AP_Int8 trigger_type; // 0=Servo, 1=relay, 2=throttle_off time, 3=throttle_off waypoint 4=transistor
uint8_t gimbal_type; // 0=pitch & roll (tilt & roll), 1=yaw & pitch(pan & tilt), 2=pitch, roll & yaw (to be added)
void servo_pic(); // Servo operated camera
void relay_pic(); // basic relay activation
@ -68,4 +54,4 @@ private:
};
#endif /* CAMERA_H */
#endif /* AP_CAMERA_H */

277
libraries/AP_Camera/Camera.cpp
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@ -1,277 +0,0 @@
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*-
#include "Camera.h"
#include "../RC_Channel/RC_Channel.h"
void
Camera::move()
{
Vector3<float> target_vector(0,0,1); // x, y, z to target before rotating to planes axis, values are in meters
//decide what happens to camera depending on camera mode
switch(mode)
{
case 0:
//do nothing, i.e lock camera in place
return;
break;
case 1:
//stabilize
target_vector.x=0; //east to west gives +tive value (i.e. longitude)
target_vector.y=0; //south to north gives +tive value (i.e. latitude)
target_vector.z=100; //downwards is +tive
break;
case 2:
//track target
if(g_gps->fix)
{
target_vector=get_location_vector(&current_loc,&camera_target);
}
break;
case 3: // radio manual control
case 4: // test (level the camera and point north)
break; // see code 25 lines bellow
}
Matrix3f m = dcm.get_dcm_transposed();
Vector3<float> targ = m*target_vector; //to do: find out notion of x y convention
switch(gimbal_type)
{
case 0: // pitch & roll (tilt & roll)
cam_pitch = degrees(atan2(-targ.x, targ.z)); //pitch
cam_roll = degrees(atan2(targ.y, targ.z)); //roll
break;
case 1: // yaw & pitch (pan & tilt)
cam_pitch = atan2((sqrt(sq(targ.y) + sq(targ.x)) * .01113195), targ.z) * -1;
cam_yaw = 9000 + atan2(-targ.y, targ.x) * 5729.57795;
break;
/* case 2: // pitch, roll & yaw - not started
cam_ritch = 0;
cam_yoll = 0;
cam_paw = 0;
break; */
}
//some camera modes overwrite the gimbal_type calculations
switch(mode)
{
case 3: // radio manual control
if (rc_function[CAM_PITCH])
cam_pitch = map(rc_function[CAM_PITCH]->radio_in,
rc_function[CAM_PITCH]->radio_min,
rc_function[CAM_PITCH]->radio_max,
rc_function[CAM_PITCH]->angle_min,
rc_function[CAM_PITCH]->radio_max);
if (rc_function[CAM_ROLL])
cam_roll = map(rc_function[CAM_ROLL]->radio_in,
rc_function[CAM_ROLL]->radio_min,
rc_function[CAM_ROLL]->radio_max,
rc_function[CAM_ROLL]->angle_min,
rc_function[CAM_ROLL]->radio_max);
if (rc_function[CAM_YAW])
cam_yaw = map(rc_function[CAM_YAW]->radio_in,
rc_function[CAM_YAW]->radio_min,
rc_function[CAM_YAW]->radio_max,
rc_function[CAM_YAW]->angle_min,
rc_function[CAM_YAW]->radio_max);
break;
case 4: // test (level the camera and point north)
cam_pitch = -dcm.pitch_sensor;
cam_yaw = dcm.yaw_sensor; // do not invert because the servo is mounted upside-down on my system
// TODO: the "trunk" code can invert using parameters, but this branch still can't
cam_roll = -dcm.roll_sensor;
break;
}
#if CAM_DEBUG == ENABLED
//for debugging purposes
Serial.println();
Serial.print("current_loc: lat: ");
Serial.print(current_loc.lat);
Serial.print(", lng: ");
Serial.print(current_loc.lng);
Serial.print(", alt: ");
Serial.print(current_loc.alt);
Serial.println();
Serial.print("target_loc: lat: ");
Serial.print(camera_target.lat);
Serial.print(", lng: ");
Serial.print(camera_target.lng);
Serial.print(", alt: ");
Serial.print(camera_target.alt);
Serial.print(", distance: ");
Serial.print(get_distance(&current_loc,&camera_target));
Serial.print(", bearing: ");
Serial.print(get_bearing(&current_loc,&camera_target));
Serial.println();
Serial.print("dcm_angles: roll: ");
Serial.print(degrees(dcm.roll));
Serial.print(", pitch: ");
Serial.print(degrees(dcm.pitch));
Serial.print(", yaw: ");
Serial.print(degrees(dcm.yaw));
Serial.println();
Serial.print("target_vector: x: ");
Serial.print(target_vector.x,2);
Serial.print(", y: ");
Serial.print(target_vector.y,2);
Serial.print(", z: ");
Serial.print(target_vector.z,2);
Serial.println();
Serial.print("rotated_target_vector: x: ");
Serial.print(targ.x,2);
Serial.print(", y: ");
Serial.print(targ.y,2);
Serial.print(", z: ");
Serial.print(targ.z,2);
Serial.println();
Serial.print("gimbal type 0: roll: ");
Serial.print(roll);
Serial.print(", pitch: ");
Serial.print(pitch);
Serial.println();
/* Serial.print("gimbal type 1: pitch: ");
Serial.print(pan);
Serial.print(", roll: ");
Serial.print(tilt);
Serial.println(); */
/* Serial.print("gimbal type 2: pitch: ");
Serial.print(ritch);
Serial.print(", roll: ");
Serial.print(yoll);
Serial.print(", yaw: ");
Serial.print(paw);
Serial.println(); */
#endif
}
void
Camera::set_target(struct Location target)
{
camera_target = target;
}
void
Camera::update_camera_gimbal_type()
{
// Auto detect the camera gimbal type depending on the functions assigned to the servos
if ((rc_function[CAM_YAW] == NULL) && (rc_function[CAM_PITCH] != NULL) && (rc_function[CAM_ROLL] != NULL))
{
gimbal_type = 0;
}
if ((rc_function[CAM_YAW] != NULL) && (rc_function[CAM_PITCH] != NULL) && (rc_function[CAM_ROLL] == NULL))
{
gimbal_type = 1;
}
if ((rc_function[CAM_YAW] != NULL) && (rc_function[CAM_PITCH] != NULL) && (rc_function[CAM_ROLL] != NULL))
{
gimbal_type = 2;
}
}
void
Camera::servo_pic() // Servo operated camera
{
if (rc_function[CAM_TRIGGER])
{
cam_trigger = rc_function[CAM_TRIGGER]->radio_max;
keep_cam_trigg_active_cycles = 2; // leave a message that it should be active for two event loop cycles
}
}
void
Camera::relay_pic() // basic relay activation
{
relay_on();
keep_cam_trigg_active_cycles = 2; // leave a message that it should be active for two event loop cycles
}
void
Camera::throttle_pic() // pictures blurry? use this trigger. Turns off the throttle until for # of cycles of medium loop then takes the picture and re-enables the throttle.
{
g.channel_throttle.radio_out = g.throttle_min;
if (thr_pic == 10){
servo_pic(); // triggering method
thr_pic = 0;
g.channel_throttle.radio_out = g.throttle_cruise;
}
thr_pic++;
}
void
Camera::distance_pic() // pictures blurry? use this trigger. Turns off the throttle until closer to waypoint then takes the picture and re-enables the throttle.
{
g.channel_throttle.radio_out = g.throttle_min;
if (wp_distance < 3){
servo_pic(); // triggering method
g.channel_throttle.radio_out = g.throttle_cruise;
}
}
void
Camera::NPN_pic() // hacked the circuit to run a transistor? use this trigger to send output.
{
// To Do: Assign pin spare pin for output
digitalWrite(camtrig, HIGH);
keep_cam_trigg_active_cycles = 1; // leave a message that it should be active for two event loop cycles
}
// single entry point to take pictures
void
Camera::trigger_pic()
{
switch (trigger_type)
{
case 0:
servo_pic(); // Servo operated camera
break;
case 1:
relay_pic(); // basic relay activation
break;
case 2:
throttle_pic(); // pictures blurry? use this trigger. Turns off the throttle until for # of cycles of medium loop then takes the picture and re-enables the throttle.
break;
case 3:
distance_pic(); // pictures blurry? use this trigger. Turns off the throttle until closer to waypoint then takes the picture and re-enables the throttle.
break;
case 4:
NPN_pic(); // hacked the circuit to run a transistor? use this trigger to send output.
break;
}
}
// de-activate the trigger after some delay, but without using a delay() function
void
Camera::trigger_pic_cleanup()
{
if (keep_cam_trigg_active_cycles)
{
keep_cam_trigg_active_cycles --;
}
else
{
switch (trigger_type)
{
case 0:
case 2:
case 3:
if (rc_function[CAM_TRIGGER])
{
cam_trigger = rc_function[CAM_TRIGGER]->radio_min;
}
break;
case 1:
relay_off();
break;
case 4:
digitalWrite(camtrig, LOW);
break;
}
}
}