kopia lustrzana https://github.com/Hamlib/Hamlib
467 wiersze
12 KiB
C
467 wiersze
12 KiB
C
/**
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* \file src/locator.c
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* \ingroup hamlib
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* \brief locator and bearing conversion interface
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* \author Stephane Fillod
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* \date 2000-2002
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*
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* Hamlib Interface - locator and bearing conversion calls
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*/
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/*
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* Hamlib Interface - locator and bearing conversion calls
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* Copyright (c) 2001-2002 by Stephane Fillod
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* Copyright (c) 2003 by Nate Bargmann
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*
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* $Id: locator.c,v 1.7 2003-08-19 23:41:08 n0nb Exp $
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*
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* Code to determine bearing and range was taken from the Great Circle,
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* by S. R. Sampson, N5OWK.
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* Ref: "Air Navigation", Air Force Manual 51-40, 1 February 1987
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* Ref: "ARRL Satellite Experimenters Handbook", August 1990
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*
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* Code to calculate distance and azimuth between two Maidenhead locators,
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* taken from wwl, by IK0ZSN Mirko Caserta.
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*
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*
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* This library is free software; you can redistribute it and/or modify
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* it under the terms of the GNU Library General Public License as
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* published by the Free Software Foundation; either version 2 of
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* the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Library General Public License for more details.
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*
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* You should have received a copy of the GNU Library General Public
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* License along with this library; if not, write to the Free Software
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* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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*
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*/
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/*! \page hamlib Hamlib general purpose API
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*
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* Here are grouped some often used functions, like locator conversion
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* routines.
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <ctype.h>
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#include <math.h>
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#include <hamlib/rotator.h>
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#ifndef DOC_HIDDEN
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#define RADIAN (180.0 / M_PI)
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/* arc length for 1 degree, 60 Nautical Miles */
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#define ARC_IN_KM 111.2
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#endif /* !DOC_HIDDEN */
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/**
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* \brief Convert DMS angle to decimal representation
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* \param degrees Degrees
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* \param minutes Minutes
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* \param seconds Seconds
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*
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* Convert degree/minute/second angle to a decimal representation.
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* Degrees >360, minutes > 60, and seconds > 60 are allowed, but
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* resulting angle won't be normalized.
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*
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* \return the decimal representation.
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*
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* \sa dec2dms()
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*/
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double dms2dec(int degrees, int minutes, int seconds)
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{
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if (degrees >= 0)
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return (double)degrees + (double)minutes/60. + (double)seconds/3600.;
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else
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return (double)degrees - (double)minutes/60. - (double)seconds/3600.;
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}
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/**
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* \brief Convert decimal angle into DMS representation
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* \param dec Decimal angle
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* \param degrees The location where to store the degrees
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* \param minutes The location where to store the minutes
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* \param seconds The location where to store the seconds
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*
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* Convert decimal angle into its degree/minute/second representation.
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*
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* When passed a value < -180 or > 180, the sign will be reversed
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* and the value constrained to => -180 and <= 180 before conversion.
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*
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* Upon return dec2dms guarantees -180<=degrees<180,
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* 0<=minutes<60, and 0<=seconds<60.
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*
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* \sa dms2dec()
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*/
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void dec2dms(double dec, int *degrees, int *minutes, int *seconds)
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{
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int deg, min, sec, is_neg = 0;
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double st;
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if (!degrees || !minutes || !seconds)
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return;
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/* reverse the sign if dec has a magnitude greater
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* than 180 and factor out multiples of 360.
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* e.g. when passed 270 st will be set to -90
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* and when passed -270 st will be set to 90. If
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* passed 361 st will be set to -1, etc. If passed
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* a value > -180 || < 180, value will be unchanged.
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*/
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if (dec >= 0.0)
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st = fmod(dec + 180, 360) - 180;
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else
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st = fmod(dec - 180, 360) + 180;
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/* if after all of that st is negative, we want deg
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* to be negative as well. Treat -180 as a special
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* case, not returning its sign so longitudes will
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* be returned from -179.999 to 180.0.
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*/
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if (st < 0.0 && st != -180.)
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is_neg = 1;
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/* work on st as a positive value to remove a
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* bug introduced by the effect of floor() when
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* passed a negative value. e.g. when passed
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* -96.8333 floor() returns -95! Also avoids
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* a rounding error introduced on negative values.
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*/
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st = fabs(st);
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deg = (int)floor(st);
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st = 60. * (st-(double)deg);
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min = (int)floor(st);
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st = 60. * (st-(double)min);
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sec = (int)floor(st);
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/* round fractional seconds up if greater than sec.5
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* round up min and deg if warranted.
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*/
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if (fmod(st, sec) >= 0.5) {
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sec++;
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if (sec == 60) {
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sec = 0;
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min++;
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if (min == 60) {
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min = 0;
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deg++;
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}
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}
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}
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/* set *degrees to original sign passed to dec */
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(is_neg == 1) ? (*degrees = deg * -1) : (*degrees = deg);
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*minutes = min;
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*seconds = sec;
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}
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/**
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* \brief Convert Maidenhead grid locator to longitude/latitude
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* \param longitude The location where to store longitude, decimal
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* \param latitude The location where to store latitude, decimal
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* \param locator The locator--four or six char nul terminated string
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*
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* Convert Maidenhead grid locator to longitude/latitude (decimal).
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* The locator be either in 4 or 6 chars long format. locator2longlat
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* is case insensitive, however it checks for locator validity.
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*
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* Decimal long/lat is computed to center of grid square, i.e. given
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* EM19 will return coordinates equivalent to the southwest corner
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* of EM19mm. Given a six character locator, computed values will
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* in the center of the given subsquare, i.e. 2' 30" from west boundary
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* and 1' 15" from south boundary.
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*
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* \todo Support for greater accuracy as proposed by Dave Hines to
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* six pairs of grid designators.
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*
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* \return RIG_OK to indicate conversion went ok, -RIG_EINVAL if locator
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* exceeds RR99xx or is malformed (not of 4 or 6 character format).
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*
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* \sa longlat2locator()
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*/
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int locator2longlat(double *longitude, double *latitude, const char *locator)
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{
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char loc[6];
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int length;
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if (locator[4] != '\0' && locator[6] != '\0')
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return -RIG_EINVAL;
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loc[0] = toupper(locator[0]);
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loc[1] = toupper(locator[1]);
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loc[2] = locator[2];
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loc[3] = locator[3];
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if (locator[4] != '\0') {
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loc[4] = toupper(locator[4]);
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loc[5] = toupper(locator[5]);
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length = 6;
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} else {
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/* center of 4 character grid */
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loc[4] = 'M';
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loc[5] = 'M';
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length = 4;
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}
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if (loc[0] < 'A' || loc[0] > 'R' ||
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loc[1] < 'A' || loc[1] > 'R' ||
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loc[2] < '0' || loc[2] > '9' ||
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loc[3] < '0' || loc[3] > '9' ||
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loc[4] < 'A' || loc[4] > 'X' ||
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loc[5] < 'A' || loc[5] > 'X' ) {
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return -RIG_EINVAL;
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}
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*longitude = 20.0 * (loc[0]-'A') - 180.0 + 2.0 * (loc[2]-'0') +
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(loc[4]-'A')/12.0;
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/* move east to center of subsquare */
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if (length == 6)
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*longitude += 0.04166666;
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*latitude = 10.0 * (loc[1]-'A') - 90.0 + (loc[3]-'0') +
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(loc[5]-'A')/24.0;
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/* move north to center of subsquare */
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if (length == 6)
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*latitude += 0.020833333;
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return RIG_OK;
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}
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/**
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* \brief Convert longitude/latitude to Maidenhead grid locator
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* \param longitude The longitude, decimal
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* \param latitude The latitude, decimal
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* \param locator The location where to store the locator
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*
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* Convert longitude/latitude (decimal) to Maidenhead grid locator.
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* \a locator must point to an array at least 6 char long.
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*
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* \todo Support for greater accuracy as proposed by Dave Hines to
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* six pairs of grid designators.
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*
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* \sa locator2longlat()
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*/
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void longlat2locator(double longitude, double latitude, char *locator)
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{
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double tmp, min_sec;
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tmp = longitude;
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/* Ideally, the input should be constrained to
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* >= -180. && < 179.9999999999999
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*/
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if (tmp == 180.)
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tmp = -tmp;
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/* with input of -180 to 179 this expression will evaluate
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* to 1 to 359 or degrees east of -180 degrees longitude.
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*/
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tmp = fmod(tmp, 360) + 180.;
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/* determine west side of the field. Fields always start at
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* a longitude that is a multiple of 20. Fields advance
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* eastward from -180 deg West longitude.
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*/
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locator[0] = 'A' + (int)floor(tmp/20.);
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tmp = fmod(tmp, 20.);
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/* at this point tmp = degrees east of west boundary
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* of the field.
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*/
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locator[2] = '0' + (int)floor(tmp/2.);
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min_sec = 12. * fabs(floor(longitude)-longitude);
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/* When tmp is an odd value, then we must be sure that
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* the subsquare is referenced to 'm' as the longitude
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* subsquare range spans 2 degrees.
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*/
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if ((int)tmp % 2)
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locator[4] = 'm' + (int)floor(min_sec);
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else
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locator[4] = 'a' + (int)floor(min_sec);
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/* input should be constrained to >= -90. && < 90. */
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tmp = fmod(latitude, 360) + 90.;
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locator[1] = 'A' + (int)floor(tmp/10.);
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tmp = fmod(tmp, 10.);
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locator[3] = '0' + (int)floor(tmp);
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tmp = 24. * fabs(floor(latitude)-latitude);
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locator[5] = 'a' + (int)floor(tmp);
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}
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/**
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* \brief Calculate the distance and bearing between two points.
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* \param lon1 The local longitude, decimal degrees
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* \param lat1 The local latitude, decimal degrees
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* \param lon2 The remote longitude, decimal degrees
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* \param lat2 The remote latitude, decimal degrees
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* \param distance The location where to store the distance
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* \param azimuth The location where to store the bearing
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*
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* Calculate the QRB between \a lat1,\a lat1 and \a lon2,\a lat2.
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*
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* This version also takes into consideration the two points
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* being close enough to be in the near-field, and the antipodal points,
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* which are easily calculated.
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*
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* \return the distance in kilometers and azimuth in decimal degrees
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* for the short path.
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*
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* \sa distance_long_path(), azimuth_long_path()
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*/
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int qrb(double lon1, double lat1, double lon2, double lat2,
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double *distance, double *azimuth)
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{
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double delta_long, tmp, arc, cosaz, az;
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if (!distance || !azimuth)
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return -1;
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if ((lat1 > 90.0 || lat1 < -90.0) || (lat2 > 90.0 || lat2 < -90.0))
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return -1;
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if ((lon1 > 180.0 || lon1 < -180.0) || (lon2 > 180.0 || lon2 < -180.0))
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return -1;
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/* Prevent ACOS() Domain Error */
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if (lat1 == 90.0)
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lat1 = 89.99;
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else if (lat1 == -90.0)
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lat1 = -89.99;
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if (lat2 == 90.0)
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lat2 = 89.99;
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else if (lat2 == -90.0)
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lat2 = -89.99;
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/*
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* Convert variables to Radians
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*/
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lat1 /= RADIAN;
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lon1 /= RADIAN;
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lat2 /= RADIAN;
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lon2 /= RADIAN;
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delta_long = lon2 - lon1;
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tmp = sin(lat1) * sin(lat2) + cos(lat1) * cos(lat2) * cos(delta_long);
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if (tmp > .999999) {
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/* Station points coincide, use an Omni! */
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*distance = 0.0;
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*azimuth = 0.0;
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return 0;
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}
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if (tmp < -.999999) {
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/*
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* points are antipodal, it's straight down.
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* Station is equal distance in all Azimuths.
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* So take 180 Degrees of arc times 60 nm,
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* and you get 10800 nm, or whatever units...
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*/
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*distance = 180.0 * ARC_IN_KM;
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*azimuth = 0.0;
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return 0;
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}
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arc = acos(tmp);
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/*
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* One degree of arc is 60 Nautical miles
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* at the surface of the earth, 111.2 km, or 69.1 sm
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* This method is easier than the one in the handbook
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*/
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/* Short Path */
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*distance = ARC_IN_KM * RADIAN * arc;
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/*
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* Long Path
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*
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* distlp = (ARC_IN_KM * 360.0) - distsp;
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*/
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cosaz = (sin(lat2) - (sin(lat1) * cos(arc))) /
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(sin(arc) * cos(lat1));
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if (cosaz > .999999)
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az = 0.0;
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else if (cosaz < -.999999)
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az = 180.0;
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else
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az = acos(cosaz) * RADIAN;
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/*
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* Handbook had the test ">= 0.0" which looks backwards??
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* must've been frontwards since the numbers seem to make sense
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* now. ;-) -N0NB
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*/
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// if (sin(delta_long) < 0.0) {
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if (sin(delta_long) >= 0.0) {
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*azimuth = az;
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} else {
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*azimuth = 360.0 - az;
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}
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if (*azimuth == 360.0)
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*azimuth = 0;
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return 0;
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}
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/**
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* \brief Calculate the long path distance between two points.
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* \param distance The distance
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*
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* Calculate the long path (resp. short path) of a given distance.
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*
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* \return the distance in kilometers for the opposite path.
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*
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* \sa qrb()
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*/
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double distance_long_path(double distance)
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{
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return (ARC_IN_KM * 360.0) - distance;
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}
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/**
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* \brief Calculate the long path bearing between two points.
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* \param azimuth The bearing
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*
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* Calculate the long path (resp. short path) of a given bearing.
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*
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* \return the azimuth in decimal degrees for the opposite path.
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*
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* \sa qrb()
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*/
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double azimuth_long_path(double azimuth)
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{
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return 360.0 - azimuth;
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}
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