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https://github.com/gnss-sdr/gnss-sdr
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Merge branch 'next' of https://github.com/gnss-sdr/gnss-sdr into next
This commit is contained in:
commit
ff626ebdc5
@ -24,10 +24,10 @@
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|||||||
# also defined, but not for general use are
|
# also defined, but not for general use are
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||||||
# GPSTK_LIBRARY, where to find the GPSTK library.
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# GPSTK_LIBRARY, where to find the GPSTK library.
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||||||
|
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||||||
FIND_PATH(GPSTK_INCLUDE_DIR Rinex3ObsBase.hpp
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FIND_PATH(GPSTK_INCLUDE_DIR gpstk/Rinex3ObsBase.hpp
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HINTS /usr/include/gpstk
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HINTS /usr/include
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||||||
/usr/local/include/gpstk
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/usr/local/include
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||||||
/opt/local/include/gpstk )
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/opt/local/include )
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||||||
|
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||||||
SET(GPSTK_NAMES ${GPSTK_NAMES} gpstk libgpstk)
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SET(GPSTK_NAMES ${GPSTK_NAMES} gpstk libgpstk)
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||||||
FIND_LIBRARY(GPSTK_LIBRARY NAMES ${GPSTK_NAMES}
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FIND_LIBRARY(GPSTK_LIBRARY NAMES ${GPSTK_NAMES}
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|
@ -28,11 +28,10 @@
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*
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*
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||||||
* -------------------------------------------------------------------------
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* -------------------------------------------------------------------------
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*/
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*/
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#include "geofunctions.h"
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#include <iomanip>
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const double STRP_G_SI = 9.80665;
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#include "geofunctions.h"
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const double STRP_PI = 3.1415926535898; //!< Pi as defined in IS-GPS-200E
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const double STRP_PI = 3.1415926535898; // Pi as defined in IS-GPS-200E
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arma::mat Skew_symmetric(const arma::vec &a)
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arma::mat Skew_symmetric(const arma::vec &a)
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{
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{
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@ -206,7 +205,7 @@ int togeod(double *dphi, double *dlambda, double *h, double a, double finv, doub
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cosphi = cos(*dphi);
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cosphi = cos(*dphi);
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|
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// compute radius of curvature in prime vertical direction
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// compute radius of curvature in prime vertical direction
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N_phi = a / sqrt(1 - esq * sinphi * sinphi);
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N_phi = a / sqrt(1.0 - esq * sinphi * sinphi);
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|
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// compute residuals in P and Z
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// compute residuals in P and Z
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dP = P - (N_phi + (*h)) * cosphi;
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dP = P - (N_phi + (*h)) * cosphi;
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@ -234,7 +233,7 @@ int togeod(double *dphi, double *dlambda, double *h, double a, double finv, doub
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arma::mat Gravity_ECEF(const arma::vec &r_eb_e)
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arma::mat Gravity_ECEF(const arma::vec &r_eb_e)
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{
|
{
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// Parameters
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// Parameters
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const double R_0 = 6378137; // WGS84 Equatorial radius in meters
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const double R_0 = 6378137.0; // WGS84 Equatorial radius in meters
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const double mu = 3.986004418E14; // WGS84 Earth gravitational constant (m^3 s^-2)
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const double mu = 3.986004418E14; // WGS84 Earth gravitational constant (m^3 s^-2)
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const double J_2 = 1.082627E-3; // WGS84 Earth's second gravitational constant
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const double J_2 = 1.082627E-3; // WGS84 Earth's second gravitational constant
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const double omega_ie = 7.292115E-5; // Earth rotation rate (rad/s)
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const double omega_ie = 7.292115E-5; // Earth rotation rate (rad/s)
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@ -260,12 +259,14 @@ arma::mat Gravity_ECEF(const arma::vec &r_eb_e)
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}
|
}
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arma::vec LLH_to_deg(arma::vec &LLH)
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arma::vec LLH_to_deg(const arma::vec &LLH)
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||||||
{
|
{
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const double rtd = 180.0 / STRP_PI;
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const double rtd = 180.0 / STRP_PI;
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LLH(0) = LLH(0) * rtd;
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arma::vec deg = arma::zeros(3, 1);
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LLH(1) = LLH(1) * rtd;
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deg(0) = LLH(0) * rtd;
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return LLH;
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deg(1) = LLH(1) * rtd;
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|
deg(2) = LLH(2);
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|
return deg;
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}
|
}
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@ -297,15 +298,16 @@ double mstokph(double MetersPerSeconds)
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}
|
}
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arma::vec CTM_to_Euler(arma::mat &C)
|
arma::vec CTM_to_Euler(const arma::mat &C)
|
||||||
{
|
{
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||||||
// Calculate Euler angles using (2.23)
|
// Calculate Euler angles using (2.23)
|
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|
arma::mat CTM = C;
|
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arma::vec eul = arma::zeros(3, 1);
|
arma::vec eul = arma::zeros(3, 1);
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||||||
eul(0) = atan2(C(1, 2), C(2, 2)); // roll
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eul(0) = atan2(CTM(1, 2), CTM(2, 2)); // roll
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if (C(0, 2) < -1.0) C(0, 2) = -1.0;
|
if (CTM(0, 2) < -1.0) CTM(0, 2) = -1.0;
|
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if (C(0, 2) > 1.0) C(0, 2) = 1.0;
|
if (CTM(0, 2) > 1.0) CTM(0, 2) = 1.0;
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eul(1) = -asin(C(0, 2)); // pitch
|
eul(1) = -asin(CTM(0, 2)); // pitch
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eul(2) = atan2(C(0, 1), C(0, 0)); // yaw
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eul(2) = atan2(CTM(0, 1), CTM(0, 0)); // yaw
|
||||||
return eul;
|
return eul;
|
||||||
}
|
}
|
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|
|
||||||
@ -354,7 +356,7 @@ arma::vec cart2geo(const arma::vec &XYZ, int elipsoid_selection)
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do
|
do
|
||||||
{
|
{
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oldh = h;
|
oldh = h;
|
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N = c / sqrt(1 + ex2 * (cos(phi) * cos(phi)));
|
N = c / sqrt(1.0 + ex2 * (cos(phi) * cos(phi)));
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phi = atan(XYZ[2] / ((sqrt(XYZ[0] * XYZ[0] + XYZ[1] * XYZ[1]) * (1.0 - (2.0 - f[elipsoid_selection]) * f[elipsoid_selection] * N / (N + h)))));
|
phi = atan(XYZ[2] / ((sqrt(XYZ[0] * XYZ[0] + XYZ[1] * XYZ[1]) * (1.0 - (2.0 - f[elipsoid_selection]) * f[elipsoid_selection] * N / (N + h)))));
|
||||||
h = sqrt(XYZ[0] * XYZ[0] + XYZ[1] * XYZ[1]) / cos(phi) - N;
|
h = sqrt(XYZ[0] * XYZ[0] + XYZ[1] * XYZ[1]) / cos(phi) - N;
|
||||||
iterations = iterations + 1;
|
iterations = iterations + 1;
|
||||||
@ -399,11 +401,11 @@ void ECEF_to_Geo(const arma::vec &r_eb_e, const arma::vec &v_eb_e, const arma::m
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void Geo_to_ECEF(const arma::vec &LLH, const arma::vec &v_eb_n, const arma::mat &C_b_n, arma::vec &r_eb_e, arma::vec &v_eb_e, arma::mat &C_b_e)
|
void Geo_to_ECEF(const arma::vec &LLH, const arma::vec &v_eb_n, const arma::mat &C_b_n, arma::vec &r_eb_e, arma::vec &v_eb_e, arma::mat &C_b_e)
|
||||||
{
|
{
|
||||||
// Parameters
|
// Parameters
|
||||||
double R_0 = 6378137; // WGS84 Equatorial radius in meters
|
double R_0 = 6378137.0; // WGS84 Equatorial radius in meters
|
||||||
double e = 0.0818191908425; // WGS84 eccentricity
|
double e = 0.0818191908425; // WGS84 eccentricity
|
||||||
|
|
||||||
// Calculate transverse radius of curvature using (2.105)
|
// Calculate transverse radius of curvature using (2.105)
|
||||||
double R_E = R_0 / sqrt(1 - (e * sin(LLH(0))) * (e * sin(LLH(0))));
|
double R_E = R_0 / sqrt(1.0 - (e * sin(LLH(0))) * (e * sin(LLH(0))));
|
||||||
|
|
||||||
// Convert position using (2.112)
|
// Convert position using (2.112)
|
||||||
double cos_lat = cos(LLH(0));
|
double cos_lat = cos(LLH(0));
|
||||||
@ -435,7 +437,7 @@ void Geo_to_ECEF(const arma::vec &LLH, const arma::vec &v_eb_n, const arma::mat
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void pv_Geo_to_ECEF(double L_b, double lambda_b, double h_b, const arma::vec &v_eb_n, arma::vec &r_eb_e, arma::vec &v_eb_e)
|
void pv_Geo_to_ECEF(double L_b, double lambda_b, double h_b, const arma::vec &v_eb_n, arma::vec &r_eb_e, arma::vec &v_eb_e)
|
||||||
{
|
{
|
||||||
// Parameters
|
// Parameters
|
||||||
const double R_0 = 6378137; // WGS84 Equatorial radius in meters
|
const double R_0 = 6378137.0; // WGS84 Equatorial radius in meters
|
||||||
const double e = 0.0818191908425; // WGS84 eccentricity
|
const double e = 0.0818191908425; // WGS84 eccentricity
|
||||||
|
|
||||||
// Calculate transverse radius of curvature using (2.105)
|
// Calculate transverse radius of curvature using (2.105)
|
||||||
@ -460,6 +462,7 @@ void pv_Geo_to_ECEF(double L_b, double lambda_b, double h_b, const arma::vec &v_
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v_eb_e = C_e_n.t() * v_eb_n;
|
v_eb_e = C_e_n.t() * v_eb_n;
|
||||||
}
|
}
|
||||||
|
|
||||||
|
|
||||||
double great_circle_distance(double lat1, double lon1, double lat2, double lon2)
|
double great_circle_distance(double lat1, double lon1, double lat2, double lon2)
|
||||||
{
|
{
|
||||||
// The Haversine formula determines the great-circle distance between two points on a sphere given their longitudes and latitudes.
|
// The Haversine formula determines the great-circle distance between two points on a sphere given their longitudes and latitudes.
|
||||||
@ -475,53 +478,49 @@ double great_circle_distance(double lat1, double lon1, double lat2, double lon2)
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return d * 1000.0; // meters
|
return d * 1000.0; // meters
|
||||||
}
|
}
|
||||||
|
|
||||||
void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu)
|
|
||||||
|
void cart2utm(const arma::vec &r_eb_e, int zone, arma::vec &r_enu)
|
||||||
{
|
{
|
||||||
//%CART2UTM Transformation of (X,Y,Z) to (E,N,U) in UTM, zone 'zone'.
|
// Transformation of (X,Y,Z) to (E,N,U) in UTM, zone 'zone'
|
||||||
//%
|
|
||||||
//%[E, N, U] = cart2utm(X, Y, Z, zone);
|
|
||||||
//%
|
|
||||||
//% Inputs:
|
|
||||||
//% X,Y,Z - Cartesian coordinates. Coordinates are referenced
|
|
||||||
//% with respect to the International Terrestrial Reference
|
|
||||||
//% Frame 1996 (ITRF96)
|
|
||||||
//% zone - UTM zone of the given position
|
|
||||||
//%
|
|
||||||
//% Outputs:
|
|
||||||
//% E, N, U - UTM coordinates (Easting, Northing, Uping)
|
|
||||||
//
|
//
|
||||||
//%Kai Borre -11-1994
|
// Inputs:
|
||||||
//%Copyright (c) by Kai Borre
|
// r_eb_e - Cartesian coordinates. Coordinates are referenced
|
||||||
//%
|
// with respect to the International Terrestrial Reference
|
||||||
//% CVS record:
|
// Frame 1996 (ITRF96)
|
||||||
//% $Id: cart2utm.m,v 1.1.1.1.2.6 2007/01/30 09:45:12 dpl Exp $
|
// zone - UTM zone of the given position
|
||||||
//
|
//
|
||||||
//%This implementation is based upon
|
// Outputs:
|
||||||
//%O. Andersson & K. Poder (1981) Koordinattransformationer
|
// r_enu - UTM coordinates (Easting, Northing, Uping)
|
||||||
//% ved Geod\ae{}tisk Institut. Landinspekt\oe{}ren
|
|
||||||
//% Vol. 30: 552--571 and Vol. 31: 76
|
|
||||||
//%
|
|
||||||
//%An excellent, general reference (KW) is
|
|
||||||
//%R. Koenig & K.H. Weise (1951) Mathematische Grundlagen der
|
|
||||||
//% h\"oheren Geod\"asie und Kartographie.
|
|
||||||
//% Erster Band, Springer Verlag
|
|
||||||
//
|
//
|
||||||
//% Explanation of variables used:
|
// Originally written in Matlab by Kai Borre, Nov. 1994
|
||||||
//% f flattening of ellipsoid
|
// Implemented in C++ by J.Arribas
|
||||||
//% a semi major axis in m
|
|
||||||
//% m0 1 - scale at central meridian; for UTM 0.0004
|
|
||||||
//% Q_n normalized meridian quadrant
|
|
||||||
//% E0 Easting of central meridian
|
|
||||||
//% L0 Longitude of central meridian
|
|
||||||
//% bg constants for ellipsoidal geogr. to spherical geogr.
|
|
||||||
//% gb constants for spherical geogr. to ellipsoidal geogr.
|
|
||||||
//% gtu constants for ellipsoidal N, E to spherical N, E
|
|
||||||
//% utg constants for spherical N, E to ellipoidal N, E
|
|
||||||
//% tolutm tolerance for utm, 1.2E-10*meridian quadrant
|
|
||||||
//% tolgeo tolerance for geographical, 0.00040 second of arc
|
|
||||||
//
|
//
|
||||||
//% B, L refer to latitude and longitude. Southern latitude is negative
|
// This implementation is based upon
|
||||||
//% International ellipsoid of 1924, valid for ED50
|
// O. Andersson & K. Poder (1981) Koordinattransformationer
|
||||||
|
// ved Geod\ae{}tisk Institut. Landinspekt\oe{}ren
|
||||||
|
// Vol. 30: 552--571 and Vol. 31: 76
|
||||||
|
//
|
||||||
|
// An excellent, general reference (KW) is
|
||||||
|
// R. Koenig & K.H. Weise (1951) Mathematische Grundlagen der
|
||||||
|
// h\"oheren Geod\"asie und Kartographie.
|
||||||
|
// Erster Band, Springer Verlag
|
||||||
|
//
|
||||||
|
// Explanation of variables used:
|
||||||
|
// f flattening of ellipsoid
|
||||||
|
// a semi major axis in m
|
||||||
|
// m0 1 - scale at central meridian; for UTM 0.0004
|
||||||
|
// Q_n normalized meridian quadrant
|
||||||
|
// E0 Easting of central meridian
|
||||||
|
// L0 Longitude of central meridian
|
||||||
|
// bg constants for ellipsoidal geogr. to spherical geogr.
|
||||||
|
// gb constants for spherical geogr. to ellipsoidal geogr.
|
||||||
|
// gtu constants for ellipsoidal N, E to spherical N, E
|
||||||
|
// utg constants for spherical N, E to ellipoidal N, E
|
||||||
|
// tolutm tolerance for utm, 1.2E-10*meridian quadrant
|
||||||
|
// tolgeo tolerance for geographical, 0.00040 second of arc
|
||||||
|
//
|
||||||
|
// B, L refer to latitude and longitude. Southern latitude is negative
|
||||||
|
// International ellipsoid of 1924, valid for ED50
|
||||||
|
|
||||||
double a = 6378388.0;
|
double a = 6378388.0;
|
||||||
double f = 1.0 / 297.0;
|
double f = 1.0 / 297.0;
|
||||||
@ -535,10 +534,10 @@ void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu)
|
|||||||
double scale = 0.9999988;
|
double scale = 0.9999988;
|
||||||
arma::vec v = scale * R * vec + trans; // coordinate vector in ED50
|
arma::vec v = scale * R * vec + trans; // coordinate vector in ED50
|
||||||
double L = atan2(v(1), v(0));
|
double L = atan2(v(1), v(0));
|
||||||
double N1 = 6395000; // preliminary value
|
double N1 = 6395000.0; // preliminary value
|
||||||
double B = atan2(v(2) / ((1 - f) * (1 - f) * N1), arma::norm(v.subvec(0, 1)) / N1); // preliminary value
|
double B = atan2(v(2) / ((1.0 - f) * (1.0 - f) * N1), arma::norm(v.subvec(0, 1)) / N1); // preliminary value
|
||||||
double U = 0.1;
|
double U = 0.1;
|
||||||
double oldU = 0;
|
double oldU = 0.0;
|
||||||
int iterations = 0;
|
int iterations = 0;
|
||||||
while (fabs(U - oldU) > 1.0E-4)
|
while (fabs(U - oldU) > 1.0E-4)
|
||||||
{
|
{
|
||||||
@ -553,44 +552,44 @@ void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu)
|
|||||||
break;
|
break;
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
//%Normalized meridian quadrant, KW p. 50 (96), p. 19 (38b), p. 5 (21)
|
// Normalized meridian quadrant, KW p. 50 (96), p. 19 (38b), p. 5 (21)
|
||||||
double m0 = 0.0004;
|
double m0 = 0.0004;
|
||||||
double n = f / (2.0 - f);
|
double n = f / (2.0 - f);
|
||||||
double m = n * n * (1 / 4 + n * n / 64);
|
double m = n * n * (1.0 / 4.0 + n * n / 64.0);
|
||||||
double w = (a * (-n - m0 + m * (1 - m0))) / (1 + n);
|
double w = (a * (-n - m0 + m * (1.0 - m0))) / (1.0 + n);
|
||||||
double Q_n = a + w;
|
double Q_n = a + w;
|
||||||
|
|
||||||
//%Easting and longitude of central meridian
|
// Easting and longitude of central meridian
|
||||||
double E0 = 500000;
|
double E0 = 500000.0;
|
||||||
double L0 = (zone - 30.0) * 6.0 - 3.0;
|
double L0 = (zone - 30) * 6.0 - 3.0;
|
||||||
|
|
||||||
//%Check tolerance for reverse transformation
|
// Check tolerance for reverse transformation
|
||||||
// double tolutm = STRP_PI / 2.0 * 1.2e-10 * Q_n;
|
// double tolutm = STRP_PI / 2.0 * 1.2e-10 * Q_n;
|
||||||
// double tolgeo = 0.000040;
|
// double tolgeo = 0.000040;
|
||||||
// % Coefficients of trigonometric series
|
// Coefficients of trigonometric series
|
||||||
|
|
||||||
// % ellipsoidal to spherical geographical, KW p .186 --187, (51) - (52)
|
|
||||||
// % bg[1] = n * (-2 + n * (2 / 3 + n * (4 / 3 + n * (-82 / 45))));
|
|
||||||
// % bg[2] = n ^ 2 * (5 / 3 + n * (-16 / 15 + n * (-13 / 9)));
|
|
||||||
// % bg[3] = n ^ 3 * (-26 / 15 + n * 34 / 21);
|
|
||||||
// % bg[4] = n ^ 4 * 1237 / 630;
|
|
||||||
//
|
//
|
||||||
// % spherical to ellipsoidal geographical, KW p.190 --191, (61) - (62) % gb[1] = n * (2 + n * (-2 / 3 + n * (-2 + n * 116 / 45)));
|
// ellipsoidal to spherical geographical, KW p .186 --187, (51) - (52)
|
||||||
// % gb[2] = n ^ 2 * (7 / 3 + n * (-8 / 5 + n * (-227 / 45)));
|
// bg[1] = n * (-2 + n * (2 / 3 + n * (4 / 3 + n * (-82 / 45))));
|
||||||
// % gb[3] = n ^ 3 * (56 / 15 + n * (-136 / 35));
|
// bg[2] = n ^ 2 * (5 / 3 + n * (-16 / 15 + n * (-13 / 9)));
|
||||||
// % gb[4] = n ^ 4 * 4279 / 630;
|
// bg[3] = n ^ 3 * (-26 / 15 + n * 34 / 21);
|
||||||
|
// bg[4] = n ^ 4 * 1237 / 630;
|
||||||
//
|
//
|
||||||
// % spherical to ellipsoidal N, E, KW p.196, (69) % gtu[1] = n * (1 / 2 + n * (-2 / 3 + n * (5 / 16 + n * 41 / 180)));
|
// spherical to ellipsoidal geographical, KW p.190 --191, (61) - (62) % gb[1] = n * (2 + n * (-2 / 3 + n * (-2 + n * 116 / 45)));
|
||||||
// % gtu[2] = n ^ 2 * (13 / 48 + n * (-3 / 5 + n * 557 / 1440));
|
// gb[2] = n ^ 2 * (7 / 3 + n * (-8 / 5 + n * (-227 / 45)));
|
||||||
// % gtu[3] = n ^ 3 * (61 / 240 + n * (-103 / 140));
|
// gb[3] = n ^ 3 * (56 / 15 + n * (-136 / 35));
|
||||||
// % gtu[4] = n ^ 4 * 49561 / 161280;
|
// gb[4] = n ^ 4 * 4279 / 630;
|
||||||
//
|
//
|
||||||
// % ellipsoidal to spherical N, E, KW p.194, (65) % utg[1] = n * (-1 / 2 + n * (2 / 3 + n * (-37 / 96 + n * 1 / 360)));
|
// spherical to ellipsoidal N, E, KW p.196, (69) % gtu[1] = n * (1 / 2 + n * (-2 / 3 + n * (5 / 16 + n * 41 / 180)));
|
||||||
// % utg[2] = n ^ 2 * (-1 / 48 + n * (-1 / 15 + n * 437 / 1440));
|
// gtu[2] = n ^ 2 * (13 / 48 + n * (-3 / 5 + n * 557 / 1440));
|
||||||
// % utg[3] = n ^ 3 * (-17 / 480 + n * 37 / 840);
|
// gtu[3] = n ^ 3 * (61 / 240 + n * (-103 / 140));
|
||||||
// % utg[4] = n ^ 4 * (-4397 / 161280);
|
// gtu[4] = n ^ 4 * 49561 / 161280;
|
||||||
|
//
|
||||||
// % With f = 1 / 297 we get
|
// ellipsoidal to spherical N, E, KW p.194, (65) % utg[1] = n * (-1 / 2 + n * (2 / 3 + n * (-37 / 96 + n * 1 / 360)));
|
||||||
|
// utg[2] = n ^ 2 * (-1 / 48 + n * (-1 / 15 + n * 437 / 1440));
|
||||||
|
// utg[3] = n ^ 3 * (-17 / 480 + n * 37 / 840);
|
||||||
|
// utg[4] = n ^ 4 * (-4397 / 161280);
|
||||||
|
//
|
||||||
|
// With f = 1 / 297 we get
|
||||||
|
|
||||||
arma::colvec bg = {-3.37077907e-3,
|
arma::colvec bg = {-3.37077907e-3,
|
||||||
4.73444769e-6,
|
4.73444769e-6,
|
||||||
@ -612,23 +611,23 @@ void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu)
|
|||||||
-1.69485209e-10,
|
-1.69485209e-10,
|
||||||
-2.20473896e-13};
|
-2.20473896e-13};
|
||||||
|
|
||||||
// % Ellipsoidal latitude, longitude to spherical latitude, longitude
|
// Ellipsoidal latitude, longitude to spherical latitude, longitude
|
||||||
bool neg_geo = false;
|
bool neg_geo = false;
|
||||||
|
|
||||||
if (B < 0) neg_geo = true;
|
if (B < 0.0) neg_geo = true;
|
||||||
|
|
||||||
double Bg_r = fabs(B);
|
double Bg_r = fabs(B);
|
||||||
double res_clensin = clsin(bg, 4, 2 * Bg_r);
|
double res_clensin = clsin(bg, 4, 2.0 * Bg_r);
|
||||||
Bg_r = Bg_r + res_clensin;
|
Bg_r = Bg_r + res_clensin;
|
||||||
L0 = L0 * STRP_PI / 180.0;
|
L0 = L0 * STRP_PI / 180.0;
|
||||||
double Lg_r = L - L0;
|
double Lg_r = L - L0;
|
||||||
|
|
||||||
// % Spherical latitude, longitude to complementary spherical latitude % i.e.spherical N, E
|
// Spherical latitude, longitude to complementary spherical latitude % i.e.spherical N, E
|
||||||
double cos_BN = cos(Bg_r);
|
double cos_BN = cos(Bg_r);
|
||||||
double Np = atan2(sin(Bg_r), cos(Lg_r) * cos_BN);
|
double Np = atan2(sin(Bg_r), cos(Lg_r) * cos_BN);
|
||||||
double Ep = atanh(sin(Lg_r) * cos_BN);
|
double Ep = atanh(sin(Lg_r) * cos_BN);
|
||||||
|
|
||||||
// % Spherical normalized N, E to ellipsoidal N, E
|
// Spherical normalized N, E to ellipsoidal N, E
|
||||||
Np = 2.0 * Np;
|
Np = 2.0 * Np;
|
||||||
Ep = 2.0 * Ep;
|
Ep = 2.0 * Ep;
|
||||||
|
|
||||||
@ -651,24 +650,18 @@ void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu)
|
|||||||
}
|
}
|
||||||
|
|
||||||
|
|
||||||
double clsin(arma::colvec ar, int degree, double argument)
|
double clsin(const arma::colvec &ar, int degree, double argument)
|
||||||
{
|
{
|
||||||
//%Clenshaw summation of sinus of argument.
|
// Clenshaw summation of sinus of argument.
|
||||||
//%
|
|
||||||
//%result = clsin(ar, degree, argument);
|
|
||||||
//
|
//
|
||||||
//% Written by Kai Borre
|
// result = clsin(ar, degree, argument);
|
||||||
//% December 20, 1995
|
//
|
||||||
//%
|
// Originally written in Matlab by Kai Borre
|
||||||
//% See also WGS2UTM or CART2UTM
|
// Implemented in C++ by J.Arribas
|
||||||
//%
|
|
||||||
//% CVS record:
|
|
||||||
//% $Id: clsin.m,v 1.1.1.1.2.4 2006/08/22 13:45:59 dpl Exp $
|
|
||||||
//%==========================================================================
|
|
||||||
|
|
||||||
double cos_arg = 2.0 * cos(argument);
|
double cos_arg = 2.0 * cos(argument);
|
||||||
double hr1 = 0;
|
double hr1 = 0.0;
|
||||||
double hr = 0;
|
double hr = 0.0;
|
||||||
double hr2;
|
double hr2;
|
||||||
for (int t = degree; t > 0; t--)
|
for (int t = degree; t > 0; t--)
|
||||||
{
|
{
|
||||||
@ -681,32 +674,26 @@ double clsin(arma::colvec ar, int degree, double argument)
|
|||||||
}
|
}
|
||||||
|
|
||||||
|
|
||||||
void clksin(arma::colvec ar, int degree, double arg_real, double arg_imag, double *re, double *im)
|
void clksin(const arma::colvec &ar, int degree, double arg_real, double arg_imag, double *re, double *im)
|
||||||
{
|
{
|
||||||
//%Clenshaw summation of sinus with complex argument
|
// Clenshaw summation of sinus with complex argument
|
||||||
//%[re, im] = clksin(ar, degree, arg_real, arg_imag);
|
// [re, im] = clksin(ar, degree, arg_real, arg_imag);
|
||||||
//
|
//
|
||||||
//% Written by Kai Borre
|
// Originally written in Matlab by Kai Borre
|
||||||
//% December 20, 1995
|
// Implemented in C++ by J.Arribas
|
||||||
//%
|
|
||||||
//% See also WGS2UTM or CART2UTM
|
|
||||||
//%
|
|
||||||
//% CVS record:
|
|
||||||
//% $Id: clksin.m,v 1.1.1.1.2.4 2006/08/22 13:45:59 dpl Exp $
|
|
||||||
//%==========================================================================
|
|
||||||
|
|
||||||
double sin_arg_r = sin(arg_real);
|
double sin_arg_r = sin(arg_real);
|
||||||
double cos_arg_r = cos(arg_real);
|
double cos_arg_r = cos(arg_real);
|
||||||
double sinh_arg_i = sinh(arg_imag);
|
double sinh_arg_i = sinh(arg_imag);
|
||||||
double cosh_arg_i = cosh(arg_imag);
|
double cosh_arg_i = cosh(arg_imag);
|
||||||
|
|
||||||
double r = 2 * cos_arg_r * cosh_arg_i;
|
double r = 2.0 * cos_arg_r * cosh_arg_i;
|
||||||
double i = -2 * sin_arg_r * sinh_arg_i;
|
double i = -2.0 * sin_arg_r * sinh_arg_i;
|
||||||
|
|
||||||
double hr1 = 0;
|
double hr1 = 0.0;
|
||||||
double hr = 0;
|
double hr = 0.0;
|
||||||
double hi1 = 0;
|
double hi1 = 0.0;
|
||||||
double hi = 0;
|
double hi = 0.0;
|
||||||
double hi2;
|
double hi2;
|
||||||
double hr2;
|
double hr2;
|
||||||
for (int t = degree; t > 0; t--)
|
for (int t = degree; t > 0; t--)
|
||||||
@ -727,86 +714,61 @@ void clksin(arma::colvec ar, int degree, double arg_real, double arg_imag, doubl
|
|||||||
*im = r * hi + i * hr;
|
*im = r * hi + i * hr;
|
||||||
}
|
}
|
||||||
|
|
||||||
|
|
||||||
int findUtmZone(double latitude_deg, double longitude_deg)
|
int findUtmZone(double latitude_deg, double longitude_deg)
|
||||||
{
|
{
|
||||||
//%Function finds the UTM zone number for given longitude and latitude.
|
// Function finds the UTM zone number for given longitude and latitude.
|
||||||
//%The longitude value must be between -180 (180 degree West) and 180 (180
|
// The longitude value must be between -180 (180 degree West) and 180 (180
|
||||||
//%degree East) degree. The latitude must be within -80 (80 degree South) and
|
// degree East) degree. The latitude must be within -80 (80 degree South) and
|
||||||
//%84 (84 degree North).
|
// 84 (84 degree North).
|
||||||
//%
|
|
||||||
//%utmZone = findUtmZone(latitude, longitude);
|
|
||||||
//%
|
|
||||||
//%Latitude and longitude must be in decimal degrees (e.g. 15.5 degrees not
|
|
||||||
//%15 deg 30 min).
|
|
||||||
//
|
//
|
||||||
//%--------------------------------------------------------------------------
|
// utmZone = findUtmZone(latitude, longitude);
|
||||||
//% SoftGNSS v3.0
|
|
||||||
//%
|
|
||||||
//% Copyright (C) Darius Plausinaitis
|
|
||||||
//% Written by Darius Plausinaitis
|
|
||||||
//%--------------------------------------------------------------------------
|
|
||||||
//%This program is free software; you can redistribute it and/or
|
|
||||||
//%modify it under the terms of the GNU General Public License
|
|
||||||
//%as published by the Free Software Foundation; either version 2
|
|
||||||
//%of the License, or (at your option) any later version.
|
|
||||||
//%
|
|
||||||
//%This program is distributed in the hope that it will be useful,
|
|
||||||
//%but WITHOUT ANY WARRANTY; without even the implied warranty of
|
|
||||||
//%MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
|
|
||||||
//%GNU General Public License for more details.
|
|
||||||
//%
|
|
||||||
//%You should have received a copy of the GNU General Public License
|
|
||||||
//%along with this program; if not, write to the Free Software
|
|
||||||
//%Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
|
|
||||||
//%USA.
|
|
||||||
//%==========================================================================
|
|
||||||
//
|
//
|
||||||
//%CVS record:
|
// Latitude and longitude must be in decimal degrees (e.g. 15.5 degrees not
|
||||||
//%$Id: findUtmZone.m,v 1.1.2.2 2006/08/22 13:45:59 dpl Exp $
|
// 15 deg 30 min).
|
||||||
//
|
//
|
||||||
// % % Check value bounds == == == == == == == == == == == == == == == == == == == == == == == == == == =
|
// Originally written in Matlab by Darius Plausinaitis
|
||||||
|
// Implemented in C++ by J.Arribas
|
||||||
|
|
||||||
if ((longitude_deg > 180) || (longitude_deg < -180))
|
// Check value bounds
|
||||||
|
if ((longitude_deg > 180.0) || (longitude_deg < -180.0))
|
||||||
std::cout << "Longitude value exceeds limits (-180:180).\n";
|
std::cout << "Longitude value exceeds limits (-180:180).\n";
|
||||||
|
|
||||||
|
if ((latitude_deg > 84.0) || (latitude_deg < -80.0))
|
||||||
if ((latitude_deg > 84) || (latitude_deg < -80))
|
|
||||||
std::cout << "Latitude value exceeds limits (-80:84).\n";
|
std::cout << "Latitude value exceeds limits (-80:84).\n";
|
||||||
|
|
||||||
//
|
//
|
||||||
// % % Find zone ==
|
// Find zone
|
||||||
// == == == == == == == == == == == == == == == == == == == == == == == == == == == == == ==
|
//
|
||||||
|
|
||||||
// % Start at 180 deg west = -180 deg
|
|
||||||
|
|
||||||
|
// Start at 180 deg west = -180 deg
|
||||||
int utmZone = floor((180 + longitude_deg) / 6) + 1;
|
int utmZone = floor((180 + longitude_deg) / 6) + 1;
|
||||||
|
|
||||||
//%% Correct zone numbers for particular areas ==============================
|
// Correct zone numbers for particular areas
|
||||||
|
if (latitude_deg > 72.0)
|
||||||
if (latitude_deg > 72)
|
|
||||||
{
|
{
|
||||||
// % Corrections for zones 31 33 35 37
|
// Corrections for zones 31 33 35 37
|
||||||
if ((longitude_deg >= 0) && (longitude_deg < 9))
|
if ((longitude_deg >= 0.0) && (longitude_deg < 9.0))
|
||||||
{
|
{
|
||||||
utmZone = 31;
|
utmZone = 31;
|
||||||
}
|
}
|
||||||
else if ((longitude_deg >= 9) && (longitude_deg < 21))
|
else if ((longitude_deg >= 9.0) && (longitude_deg < 21.0))
|
||||||
{
|
{
|
||||||
utmZone = 33;
|
utmZone = 33;
|
||||||
}
|
}
|
||||||
else if ((longitude_deg >= 21) && (longitude_deg < 33))
|
else if ((longitude_deg >= 21.0) && (longitude_deg < 33.0))
|
||||||
{
|
{
|
||||||
utmZone = 35;
|
utmZone = 35;
|
||||||
}
|
}
|
||||||
else if ((longitude_deg >= 33) && (longitude_deg < 42))
|
else if ((longitude_deg >= 33.0) && (longitude_deg < 42.0))
|
||||||
{
|
{
|
||||||
utmZone = 37;
|
utmZone = 37;
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
else if ((latitude_deg >= 56) && (latitude_deg < 64))
|
else if ((latitude_deg >= 56.0) && (latitude_deg < 64.0))
|
||||||
{
|
{
|
||||||
// % Correction for zone 32
|
// Correction for zone 32
|
||||||
if ((longitude_deg >= 3) && (longitude_deg < 12))
|
if ((longitude_deg >= 3.0) && (longitude_deg < 12.0))
|
||||||
utmZone = 32;
|
utmZone = 32;
|
||||||
}
|
}
|
||||||
return utmZone;
|
return utmZone;
|
||||||
|
@ -94,7 +94,7 @@ arma::mat Gravity_ECEF(const arma::vec &r_eb_e); //!< Calculates acceleration d
|
|||||||
*/
|
*/
|
||||||
arma::vec cart2geo(const arma::vec &XYZ, int elipsoid_selection);
|
arma::vec cart2geo(const arma::vec &XYZ, int elipsoid_selection);
|
||||||
|
|
||||||
arma::vec LLH_to_deg(arma::vec &LLH);
|
arma::vec LLH_to_deg(const arma::vec &LLH);
|
||||||
|
|
||||||
double degtorad(double angleInDegrees);
|
double degtorad(double angleInDegrees);
|
||||||
|
|
||||||
@ -104,7 +104,7 @@ double mstoknotsh(double MetersPerSeconds);
|
|||||||
|
|
||||||
double mstokph(double Kph);
|
double mstokph(double Kph);
|
||||||
|
|
||||||
arma::vec CTM_to_Euler(arma::mat &C);
|
arma::vec CTM_to_Euler(const arma::mat &C);
|
||||||
|
|
||||||
arma::mat Euler_to_CTM(const arma::vec &eul);
|
arma::mat Euler_to_CTM(const arma::vec &eul);
|
||||||
|
|
||||||
@ -151,35 +151,34 @@ void Geo_to_ECEF(const arma::vec &LLH, const arma::vec &v_eb_n, const arma::mat
|
|||||||
*/
|
*/
|
||||||
void pv_Geo_to_ECEF(double L_b, double lambda_b, double h_b, const arma::vec &v_eb_n, arma::vec &r_eb_e, arma::vec &v_eb_e);
|
void pv_Geo_to_ECEF(double L_b, double lambda_b, double h_b, const arma::vec &v_eb_n, arma::vec &r_eb_e, arma::vec &v_eb_e);
|
||||||
|
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
* \brief The Haversine formula determines the great-circle distance between two points on a sphere given their longitudes and latitudes.
|
* \brief The Haversine formula determines the great-circle distance between two points on a sphere given their longitudes and latitudes.
|
||||||
*/
|
*/
|
||||||
double great_circle_distance(double lat1, double lon1, double lat2, double lon2);
|
double great_circle_distance(double lat1, double lon1, double lat2, double lon2);
|
||||||
|
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
* \brief Transformation of ECEF (X,Y,Z) to (E,N,U) in UTM, zone 'zone'.
|
* \brief Transformation of ECEF (X,Y,Z) to (E,N,U) in UTM, zone 'zone'.
|
||||||
*/
|
*/
|
||||||
|
void cart2utm(const arma::vec &r_eb_e, int zone, arma::vec &r_enu);
|
||||||
|
|
||||||
void cart2utm(arma::vec r_eb_e, int zone, arma::vec &r_enu);
|
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
* \brief Function finds the UTM zone number for given longitude and latitude.
|
* \brief Function finds the UTM zone number for given longitude and latitude.
|
||||||
*/
|
*/
|
||||||
|
|
||||||
int findUtmZone(double latitude_deg, double longitude_deg);
|
int findUtmZone(double latitude_deg, double longitude_deg);
|
||||||
|
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
* \brief Clenshaw summation of sinus of argument.
|
* \brief Clenshaw summation of sinus of argument.
|
||||||
*/
|
*/
|
||||||
|
double clsin(const arma::colvec &ar, int degree, double argument);
|
||||||
double clsin(arma::colvec ar, int degree, double argument);
|
|
||||||
|
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
* \brief Clenshaw summation of sinus with complex argument.
|
* \brief Clenshaw summation of sinus with complex argument.
|
||||||
*/
|
*/
|
||||||
|
void clksin(const arma::colvec &ar, int degree, double arg_real, double arg_imag, double *re, double *im);
|
||||||
|
|
||||||
void clksin(arma::colvec ar, int degree, double arg_real, double arg_imag, double *re, double *im);
|
|
||||||
|
|
||||||
#endif
|
#endif
|
||||||
|
Loading…
Reference in New Issue
Block a user