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/*
* Location . cpp
*/
# include "Location.h"
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# ifndef HAL_BOOTLOADER_BUILD
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# include <AP_AHRS/AP_AHRS.h>
# include <AP_Terrain/AP_Terrain.h>
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const Location definitely_zero { } ;
bool Location : : is_zero ( void ) const
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{
return ! memcmp ( this , & definitely_zero , sizeof ( * this ) ) ;
}
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void Location : : zero ( void )
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{
memset ( this , 0 , sizeof ( * this ) ) ;
}
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// Construct location using position (NEU) from ekf_origin for the given altitude frame
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Location : : Location ( int32_t latitude , int32_t longitude , int32_t alt_in_cm , AltFrame frame )
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{
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// make sure we know what size the Location object is:
ASSERT_STORAGE_SIZE ( Location , 16 ) ;
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zero ( ) ;
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lat = latitude ;
lng = longitude ;
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set_alt_cm ( alt_in_cm , frame ) ;
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}
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# if AP_AHRS_ENABLED
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Location : : Location ( const Vector3f & ekf_offset_neu , AltFrame frame )
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{
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zero ( ) ;
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// store alt and alt frame
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set_alt_cm ( ekf_offset_neu . z , frame ) ;
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// calculate lat, lon
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Location ekf_origin ;
if ( AP : : ahrs ( ) . get_origin ( ekf_origin ) ) {
lat = ekf_origin . lat ;
lng = ekf_origin . lng ;
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offset ( ekf_offset_neu . x * 0.01 , ekf_offset_neu . y * 0.01 ) ;
}
}
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# endif // AP_AHRS_ENABLED
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void Location : : set_alt_cm ( int32_t alt_cm , AltFrame frame )
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{
alt = alt_cm ;
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relative_alt = false ;
terrain_alt = false ;
origin_alt = false ;
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switch ( frame ) {
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case AltFrame : : ABSOLUTE :
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// do nothing
break ;
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case AltFrame : : ABOVE_HOME :
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relative_alt = true ;
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break ;
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case AltFrame : : ABOVE_ORIGIN :
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origin_alt = true ;
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break ;
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case AltFrame : : ABOVE_TERRAIN :
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// we mark it as a relative altitude, as it doesn't have
// home alt added
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relative_alt = true ;
terrain_alt = true ;
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break ;
}
}
// converts altitude to new frame
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bool Location : : change_alt_frame ( AltFrame desired_frame )
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{
int32_t new_alt_cm ;
if ( ! get_alt_cm ( desired_frame , new_alt_cm ) ) {
return false ;
}
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set_alt_cm ( new_alt_cm , desired_frame ) ;
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return true ;
}
// get altitude frame
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Location : : AltFrame Location : : get_alt_frame ( ) const
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{
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if ( terrain_alt ) {
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return AltFrame : : ABOVE_TERRAIN ;
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}
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if ( origin_alt ) {
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return AltFrame : : ABOVE_ORIGIN ;
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}
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if ( relative_alt ) {
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return AltFrame : : ABOVE_HOME ;
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}
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return AltFrame : : ABSOLUTE ;
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}
/// get altitude in desired frame
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bool Location : : get_alt_cm ( AltFrame desired_frame , int32_t & ret_alt_cm ) const
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{
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# if CONFIG_HAL_BOARD == HAL_BOARD_SITL
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if ( ! initialised ( ) ) {
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AP_HAL : : panic ( " Should not be called on invalid location: Location cannot be (0, 0, 0) " ) ;
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}
# endif
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Location : : AltFrame frame = get_alt_frame ( ) ;
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// shortcut if desired and underlying frame are the same
if ( desired_frame = = frame ) {
ret_alt_cm = alt ;
return true ;
}
// check for terrain altitude
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float alt_terr_cm = 0 ;
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if ( frame = = AltFrame : : ABOVE_TERRAIN | | desired_frame = = AltFrame : : ABOVE_TERRAIN ) {
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# if AP_TERRAIN_AVAILABLE
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AP_Terrain * terrain = AP : : terrain ( ) ;
if ( terrain = = nullptr ) {
return false ;
}
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if ( ! terrain - > height_amsl ( * this , alt_terr_cm ) ) {
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return false ;
}
// convert terrain alt to cm
alt_terr_cm * = 100.0f ;
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# else
return false ;
# endif
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}
// convert alt to absolute
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int32_t alt_abs = 0 ;
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switch ( frame ) {
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case AltFrame : : ABSOLUTE :
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alt_abs = alt ;
break ;
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case AltFrame : : ABOVE_HOME :
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# if AP_AHRS_ENABLED
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if ( ! AP : : ahrs ( ) . home_is_set ( ) ) {
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return false ;
}
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alt_abs = alt + AP : : ahrs ( ) . get_home ( ) . alt ;
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# else
return false ;
# endif // AP_AHRS_ENABLED
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break ;
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case AltFrame : : ABOVE_ORIGIN :
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# if AP_AHRS_ENABLED
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{
// fail if we cannot get ekf origin
Location ekf_origin ;
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if ( ! AP : : ahrs ( ) . get_origin ( ekf_origin ) ) {
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return false ;
}
alt_abs = alt + ekf_origin . alt ;
}
break ;
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# else
return false ;
# endif // AP_AHRS_ENABLED
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case AltFrame : : ABOVE_TERRAIN :
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alt_abs = alt + alt_terr_cm ;
break ;
}
// convert absolute to desired frame
switch ( desired_frame ) {
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case AltFrame : : ABSOLUTE :
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ret_alt_cm = alt_abs ;
return true ;
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case AltFrame : : ABOVE_HOME :
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# if AP_AHRS_ENABLED
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if ( ! AP : : ahrs ( ) . home_is_set ( ) ) {
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return false ;
}
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ret_alt_cm = alt_abs - AP : : ahrs ( ) . get_home ( ) . alt ;
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# else
return false ;
# endif // AP_AHRS_ENABLED
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return true ;
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case AltFrame : : ABOVE_ORIGIN :
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# if AP_AHRS_ENABLED
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{
// fail if we cannot get ekf origin
Location ekf_origin ;
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if ( ! AP : : ahrs ( ) . get_origin ( ekf_origin ) ) {
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return false ;
}
ret_alt_cm = alt_abs - ekf_origin . alt ;
return true ;
}
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# else
return false ;
# endif // AP_AHRS_ENABLED
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case AltFrame : : ABOVE_TERRAIN :
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ret_alt_cm = alt_abs - alt_terr_cm ;
return true ;
}
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return false ; // LCOV_EXCL_LINE - not reachable
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}
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bool Location : : get_alt_m ( AltFrame desired_frame , float & ret_alt ) const
{
int32_t ret_alt_cm ;
if ( ! get_alt_cm ( desired_frame , ret_alt_cm ) ) {
return false ;
}
ret_alt = ret_alt_cm * 0.01 ;
return true ;
}
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# if AP_AHRS_ENABLED
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// converts location to a vector from origin; if this method returns
// false then vec_ne is unmodified
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template < typename T >
bool Location : : get_vector_xy_from_origin_NE ( T & vec_ne ) const
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{
Location ekf_origin ;
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if ( ! AP : : ahrs ( ) . get_origin ( ekf_origin ) ) {
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return false ;
}
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vec_ne . x = ( lat - ekf_origin . lat ) * LATLON_TO_CM ;
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vec_ne . y = diff_longitude ( lng , ekf_origin . lng ) * LATLON_TO_CM * longitude_scale ( ( lat + ekf_origin . lat ) / 2 ) ;
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return true ;
}
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// define for float and position vectors
template bool Location : : get_vector_xy_from_origin_NE < Vector2f > ( Vector2f & vec_ne ) const ;
# if HAL_WITH_POSTYPE_DOUBLE
template bool Location : : get_vector_xy_from_origin_NE < Vector2p > ( Vector2p & vec_ne ) const ;
# endif
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// converts location to a vector from origin; if this method returns
// false then vec_neu is unmodified
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template < typename T >
bool Location : : get_vector_from_origin_NEU ( T & vec_neu ) const
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{
// convert altitude
int32_t alt_above_origin_cm = 0 ;
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if ( ! get_alt_cm ( AltFrame : : ABOVE_ORIGIN , alt_above_origin_cm ) ) {
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return false ;
}
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// convert lat, lon
if ( ! get_vector_xy_from_origin_NE ( vec_neu . xy ( ) ) ) {
return false ;
}
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vec_neu . z = alt_above_origin_cm ;
return true ;
}
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// define for float and position vectors
template bool Location : : get_vector_from_origin_NEU < Vector3f > ( Vector3f & vec_neu ) const ;
# if HAL_WITH_POSTYPE_DOUBLE
template bool Location : : get_vector_from_origin_NEU < Vector3p > ( Vector3p & vec_neu ) const ;
# endif
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# endif // AP_AHRS_ENABLED
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// return horizontal distance in meters between two locations
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ftype Location : : get_distance ( const Location & loc2 ) const
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{
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ftype dlat = ( ftype ) ( loc2 . lat - lat ) ;
ftype dlng = ( ( ftype ) diff_longitude ( loc2 . lng , lng ) ) * longitude_scale ( ( lat + loc2 . lat ) / 2 ) ;
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return norm ( dlat , dlng ) * LOCATION_SCALING_FACTOR ;
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}
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// return the altitude difference in meters taking into account alt frame.
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bool Location : : get_alt_distance ( const Location & loc2 , ftype & distance ) const
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{
int32_t alt1 , alt2 ;
if ( ! get_alt_cm ( AltFrame : : ABSOLUTE , alt1 ) | | ! loc2 . get_alt_cm ( AltFrame : : ABSOLUTE , alt2 ) ) {
return false ;
}
distance = ( alt1 - alt2 ) * 0.01 ;
return true ;
}
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/*
return the distance in meters in North / East plane as a N / E vector
from loc1 to loc2
*/
Vector2f Location : : get_distance_NE ( const Location & loc2 ) const
{
return Vector2f ( ( loc2 . lat - lat ) * LOCATION_SCALING_FACTOR ,
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diff_longitude ( loc2 . lng , lng ) * LOCATION_SCALING_FACTOR * longitude_scale ( ( loc2 . lat + lat ) / 2 ) ) ;
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}
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// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2, NOT CONSIDERING ALT FRAME!
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Vector3f Location : : get_distance_NED ( const Location & loc2 ) const
{
return Vector3f ( ( loc2 . lat - lat ) * LOCATION_SCALING_FACTOR ,
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diff_longitude ( loc2 . lng , lng ) * LOCATION_SCALING_FACTOR * longitude_scale ( ( lat + loc2 . lat ) / 2 ) ,
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( alt - loc2 . alt ) * 0.01 ) ;
}
// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2
Vector3d Location : : get_distance_NED_double ( const Location & loc2 ) const
{
return Vector3d ( ( loc2 . lat - lat ) * double ( LOCATION_SCALING_FACTOR ) ,
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diff_longitude ( loc2 . lng , lng ) * LOCATION_SCALING_FACTOR * longitude_scale ( ( lat + loc2 . lat ) / 2 ) ,
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( alt - loc2 . alt ) * 0.01 ) ;
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}
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// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2 considering alt frame, if altitude cannot be resolved down distance is 0
Vector3f Location : : get_distance_NED_alt_frame ( const Location & loc2 ) const
{
int32_t alt1 , alt2 = 0 ;
if ( ! get_alt_cm ( AltFrame : : ABSOLUTE , alt1 ) | | ! loc2 . get_alt_cm ( AltFrame : : ABSOLUTE , alt2 ) ) {
// one or both of the altitudes are invalid, don't do alt distance calc
alt1 = 0 , alt2 = 0 ;
}
return Vector3f ( ( loc2 . lat - lat ) * LOCATION_SCALING_FACTOR ,
diff_longitude ( loc2 . lng , lng ) * LOCATION_SCALING_FACTOR * longitude_scale ( ( loc2 . lat + lat ) / 2 ) ,
( alt1 - alt2 ) * 0.01 ) ;
}
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Vector2d Location : : get_distance_NE_double ( const Location & loc2 ) const
{
return Vector2d ( ( loc2 . lat - lat ) * double ( LOCATION_SCALING_FACTOR ) ,
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diff_longitude ( loc2 . lng , lng ) * double ( LOCATION_SCALING_FACTOR ) * longitude_scale ( ( lat + loc2 . lat ) / 2 ) ) ;
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}
Vector2F Location : : get_distance_NE_ftype ( const Location & loc2 ) const
{
return Vector2F ( ( loc2 . lat - lat ) * ftype ( LOCATION_SCALING_FACTOR ) ,
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diff_longitude ( loc2 . lng , lng ) * ftype ( LOCATION_SCALING_FACTOR ) * longitude_scale ( ( lat + loc2 . lat ) / 2 ) ) ;
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}
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// extrapolate latitude/longitude given distances (in meters) north and east
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void Location : : offset_latlng ( int32_t & lat , int32_t & lng , ftype ofs_north , ftype ofs_east )
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{
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const int32_t dlat = ofs_north * LOCATION_SCALING_FACTOR_INV ;
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const int64_t dlng = ( ofs_east * LOCATION_SCALING_FACTOR_INV ) / longitude_scale ( lat + dlat / 2 ) ;
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lat + = dlat ;
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lat = limit_lattitude ( lat ) ;
lng = wrap_longitude ( dlng + lng ) ;
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}
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// extrapolate latitude/longitude given distances (in meters) north and east
void Location : : offset ( ftype ofs_north , ftype ofs_east )
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{
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offset_latlng ( lat , lng , ofs_north , ofs_east ) ;
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}
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// extrapolate latitude/longitude given distances (in meters) north
// and east. Note that this is metres, *even for the altitude*.
void Location : : offset ( const Vector3p & ofs_ned )
{
offset_latlng ( lat , lng , ofs_ned . x , ofs_ned . y ) ;
alt + = - ofs_ned . z * 100 ; // m -> cm
}
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/*
* extrapolate latitude / longitude given bearing and distance
* Note that this function is accurate to about 1 mm at a distance of
* 100 m . This function has the advantage that it works in relative
* positions , so it keeps the accuracy even when dealing with small
* distances and floating point numbers
*/
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void Location : : offset_bearing ( ftype bearing_deg , ftype distance )
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{
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const ftype ofs_north = cosF ( radians ( bearing_deg ) ) * distance ;
const ftype ofs_east = sinF ( radians ( bearing_deg ) ) * distance ;
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offset ( ofs_north , ofs_east ) ;
}
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// extrapolate latitude/longitude given bearing, pitch and distance
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void Location : : offset_bearing_and_pitch ( ftype bearing_deg , ftype pitch_deg , ftype distance )
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{
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const ftype ofs_north = cosF ( radians ( pitch_deg ) ) * cosF ( radians ( bearing_deg ) ) * distance ;
const ftype ofs_east = cosF ( radians ( pitch_deg ) ) * sinF ( radians ( bearing_deg ) ) * distance ;
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offset ( ofs_north , ofs_east ) ;
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const int32_t dalt = sinF ( radians ( pitch_deg ) ) * distance * 100.0f ;
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alt + = dalt ;
}
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ftype Location : : longitude_scale ( int32_t lat )
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{
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ftype scale = cosF ( lat * ( 1.0e-7 * DEG_TO_RAD ) ) ;
return MAX ( scale , 0.01 ) ;
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}
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/*
* convert invalid waypoint with useful data . return true if location changed
*/
bool Location : : sanitize ( const Location & defaultLoc )
{
bool has_changed = false ;
// convert lat/lng=0 to mean current point
if ( lat = = 0 & & lng = = 0 ) {
lat = defaultLoc . lat ;
lng = defaultLoc . lng ;
has_changed = true ;
}
// convert relative alt=0 to mean current alt
if ( alt = = 0 & & relative_alt ) {
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int32_t defaultLoc_alt ;
if ( defaultLoc . get_alt_cm ( get_alt_frame ( ) , defaultLoc_alt ) ) {
alt = defaultLoc_alt ;
has_changed = true ;
}
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}
// limit lat/lng to appropriate ranges
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if ( ! check_latlng ( ) ) {
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lat = defaultLoc . lat ;
lng = defaultLoc . lng ;
has_changed = true ;
}
return has_changed ;
}
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// return bearing in radians from location to loc2, return is 0 to 2*Pi
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ftype Location : : get_bearing ( const Location & loc2 ) const
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{
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const int32_t off_x = diff_longitude ( loc2 . lng , lng ) ;
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const int32_t off_y = ( loc2 . lat - lat ) / loc2 . longitude_scale ( ( lat + loc2 . lat ) / 2 ) ;
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ftype bearing = ( M_PI * 0.5 ) + atan2F ( - off_y , off_x ) ;
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if ( bearing < 0 ) {
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bearing + = 2 * M_PI ;
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}
return bearing ;
}
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/*
return true if lat and lng match . Ignores altitude and options
*/
bool Location : : same_latlon_as ( const Location & loc2 ) const
{
return ( lat = = loc2 . lat ) & & ( lng = = loc2 . lng ) ;
}
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bool Location : : same_alt_as ( const Location & loc2 ) const
{
// fast path if the altitude frame is the same
if ( this - > get_alt_frame ( ) = = loc2 . get_alt_frame ( ) ) {
return this - > alt = = loc2 . alt ;
}
ftype alt_diff ;
bool have_diff = this - > get_alt_distance ( loc2 , alt_diff ) ;
const ftype tolerance = FLT_EPSILON ;
return have_diff & & ( fabsF ( alt_diff ) < tolerance ) ;
}
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// return true when lat and lng are within range
bool Location : : check_latlng ( ) const
{
return check_lat ( lat ) & & check_lng ( lng ) ;
}
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// see if location is past a line perpendicular to
// the line between point1 and point2 and passing through point2.
// If point1 is our previous waypoint and point2 is our target waypoint
// then this function returns true if we have flown past
// the target waypoint
bool Location : : past_interval_finish_line ( const Location & point1 , const Location & point2 ) const
{
return this - > line_path_proportion ( point1 , point2 ) > = 1.0f ;
}
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/*
return the proportion we are along the path from point1 to
point2 , along a line parallel to point1 < - > point2 .
This will be more than 1 if we have passed point2
*/
float Location : : line_path_proportion ( const Location & point1 , const Location & point2 ) const
{
const Vector2f vec1 = point1 . get_distance_NE ( point2 ) ;
const Vector2f vec2 = point1 . get_distance_NE ( * this ) ;
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const ftype dsquared = sq ( vec1 . x ) + sq ( vec1 . y ) ;
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if ( dsquared < 0.001f ) {
// the two points are very close together
return 1.0f ;
}
return ( vec1 * vec2 ) / dsquared ;
}
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/*
wrap longitude for - 180e7 to 180e7
*/
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int32_t Location : : wrap_longitude ( int64_t lon )
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{
if ( lon > 1800000000L ) {
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lon = int32_t ( lon - 3600000000LL ) ;
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} else if ( lon < - 1800000000L ) {
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lon = int32_t ( lon + 3600000000LL ) ;
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}
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return int32_t ( lon ) ;
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}
/*
get lon1 - lon2 , wrapping at - 180e7 to 180e7
*/
int32_t Location : : diff_longitude ( int32_t lon1 , int32_t lon2 )
{
if ( ( lon1 & 0x80000000 ) = = ( lon2 & 0x80000000 ) ) {
// common case of same sign
return lon1 - lon2 ;
}
int64_t dlon = int64_t ( lon1 ) - int64_t ( lon2 ) ;
if ( dlon > 1800000000LL ) {
dlon - = 3600000000LL ;
} else if ( dlon < - 1800000000LL ) {
dlon + = 3600000000LL ;
}
return int32_t ( dlon ) ;
}
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/*
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limit latitude to - 90e7 to 90e7
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*/
int32_t Location : : limit_lattitude ( int32_t lat )
{
if ( lat > 900000000L ) {
lat = 1800000000LL - lat ;
} else if ( lat < - 900000000L ) {
lat = - ( 1800000000LL + lat ) ;
}
return lat ;
}
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// update altitude and alt-frame base on this location's horizontal position between point1 and point2
// this location's lat,lon is used to calculate the alt of the closest point on the line between point1 and point2
// origin and destination's altitude frames must be the same
// this alt-frame will be updated to match the destination alt frame
void Location : : linearly_interpolate_alt ( const Location & point1 , const Location & point2 )
{
// new target's distance along the original track and then linear interpolate between the original origin and destination altitudes
set_alt_cm ( point1 . alt + ( point2 . alt - point1 . alt ) * constrain_float ( line_path_proportion ( point1 , point2 ) , 0.0f , 1.0f ) , point2 . get_alt_frame ( ) ) ;
}
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# endif // HAL_BOOTLOADER_BUILD