flightgear/utils/GPSsmooth/GPSsmooth.cxx

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2022-10-20 20:29:11 +08:00
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <simgear/compiler.h>
#include <iostream>
#include <simgear/constants.h>
#include <simgear/io/iostreams/sgstream.hxx>
#include <simgear/misc/strutils.hxx>
#include <simgear/misc/sg_path.hxx>
#include "GPSsmooth.hxx"
using std::cout;
using std::endl;
GPSTrack::GPSTrack() {};
GPSTrack::~GPSTrack() {};
// load the specified file, return the number of records loaded
int GPSTrack::load( const std::string &file ) {
int count = 0;
data.clear();
// openg the file
sg_gzifstream in( SGPath::fromLocal8Bit(file.c_str()) );
if ( !in.is_open() ) {
cout << "Cannot open file: " << file << endl;
return 0;
}
std::vector <std::string> tokens;
GPSPoint p;
while ( ! in.eof() ) {
char tmp[2049];
in.getline(tmp, 2048);
tokens.clear();
tokens = simgear::strutils::split(tmp, ",");
int dd;
double raw, min;
if ( tokens[0] == "$GPRMC" && tokens.size() == 13 ) {
double raw_time = atof(tokens[1].c_str());
GPSTime gps_time = GPSTime( raw_time );
if ( (gps_time.get_time() > p.gps_time.get_time()) &&
(p.gps_time.get_time() > 1.0) )
{
// new data cycle store last data before continuing
data.push_back( p );
count++;
}
p.gps_time = gps_time;
raw = atof( tokens[3].c_str() );
dd = (int)(raw / 100.00);
min = raw - dd * 100.0;
p.lat_deg = dd + min / 60.0;
if ( tokens[4] == "S" ) {
p.lat_deg = -p.lat_deg;
}
raw = atof( tokens[5].c_str() );
dd = (int)(raw / 100.00);
min = raw - dd * 100.0;
p.lon_deg = dd + min / 60.0;
if ( tokens[6] == "W" ) {
p.lon_deg = -p.lon_deg;
}
static double max_speed = 0.0;
p.speed_kts = atof( tokens[7].c_str() );
if ( p.speed_kts > max_speed ) {
max_speed = p.speed_kts;
cout << "max speed = " << max_speed << endl;
}
p.course_true = atof( tokens[8].c_str() ) * SGD_DEGREES_TO_RADIANS;
} else if ( tokens[0] == "$GPGGA" && tokens.size() == 15 ) {
double raw_time = atof(tokens[1].c_str());
GPSTime gps_time = GPSTime( raw_time );
if ( fabs(gps_time.get_time() - p.gps_time.get_time()) > 0.0001 &&
(p.gps_time.get_time() > 1.0) ) {
// new data cycle store last data before continuing
data.push_back( p );
count++;
}
p.gps_time = gps_time;
raw = atof( tokens[2].c_str() );
dd = (int)(raw / 100.00);
min = raw - dd * 100.0;
p.lat_deg = dd + min / 60.0;
if ( tokens[3] == "S" ) {
p.lat_deg = -p.lat_deg;
}
raw = atof( tokens[4].c_str() );
dd = (int)(raw / 100.00);
min = raw - dd * 100.0;
p.lon_deg = dd + min / 60.0;
if ( tokens[5] == "W" ) {
p.lon_deg = -p.lon_deg;
}
p.fix_quality = atoi( tokens[6].c_str() );
p.num_satellites = atoi( tokens[7].c_str() );
p.hdop = atof( tokens[8].c_str() );
static double max_alt = 0.0;
double alt = atof( tokens[9].c_str() );
if ( alt > max_alt ) {
max_alt = alt;
cout << "max alt = " << max_alt << endl;
}
if ( tokens[10] == "F" || tokens[10] == "f" ) {
alt *= SG_FEET_TO_METER;
}
p.altitude_msl = alt;
}
}
return count;
}
static double interp( double a, double b, double p, bool rotational = false ) {
double diff = b - a;
if ( rotational ) {
// special handling of rotational data
if ( diff > SGD_PI ) {
diff -= SGD_2PI;
} else if ( diff < -SGD_PI ) {
diff += SGD_2PI;
}
}
return a + diff * p;
}
GPSPoint GPSInterpolate( const GPSPoint A, const GPSPoint B,
const double percent ) {
GPSPoint p;
p.gps_time = GPSTime((int)interp(A.gps_time.get_time(),
B.gps_time.get_time(),
percent));
p.lat_deg = interp(A.lat_deg, B.lat_deg, percent);
p.lon_deg = interp(A.lon_deg, B.lon_deg, percent);
p.fix_quality = (int)interp(A.fix_quality, B.fix_quality, percent);
p.num_satellites = (int)interp(A.num_satellites, B.num_satellites, percent);
p.hdop = interp(A.hdop, B.hdop, percent);
p.altitude_msl = interp(A.altitude_msl, B.altitude_msl, percent);
p.speed_kts = interp(A.speed_kts, B.speed_kts, percent);
p.course_true = interp(A.course_true, B.course_true, percent, true);
return p;
}