Public Member Functions | Protected Member Functions | Private Member Functions | Private Attributes | Static Private Attributes | List of all members
net.sf.geographiclib.GeodesicLine Class Reference

Public Member Functions

double Arc ()
 
GeodesicData ArcPosition (double a12)
 
GeodesicData ArcPosition (double a12, int outmask)
 
double Azimuth ()
 
Pair AzimuthCosines ()
 
int Capabilities ()
 
boolean Capabilities (int testcaps)
 
double Distance ()
 
double EquatorialArc ()
 
double EquatorialAzimuth ()
 
Pair EquatorialAzimuthCosines ()
 
double Flattening ()
 
double GenDistance (boolean arcmode)
 
void GenSetDistance (boolean arcmode, double s13_a13)
 
 GeodesicLine (Geodesic g, double lat1, double lon1, double azi1)
 
 GeodesicLine (Geodesic g, double lat1, double lon1, double azi1, int caps)
 
double Latitude ()
 
double Longitude ()
 
double MajorRadius ()
 
GeodesicData Position (boolean arcmode, double s12_a12, int outmask)
 
GeodesicData Position (double s12)
 
GeodesicData Position (double s12, int outmask)
 
void SetDistance (double s13)
 

Protected Member Functions

 GeodesicLine (Geodesic g, double lat1, double lon1, double azi1, double salp1, double calp1, int caps, boolean arcmode, double s13_a13)
 

Private Member Functions

 GeodesicLine ()
 
boolean Init ()
 
void LineInit (Geodesic g, double lat1, double lon1, double azi1, double salp1, double calp1, int caps)
 

Private Attributes

double _a
 
double _a13
 
double _C1a []
 
int _caps
 
double _lat1
 

Static Private Attributes

static final int nC1_ = Geodesic.nC1_
 
static final int nC1p_ = Geodesic.nC1p_
 
static final int nC2_ = Geodesic.nC2_
 
static final int nC3_ = Geodesic.nC3_
 
static final int nC4_ = Geodesic.nC4_
 

Detailed Description

A geodesic line.

GeodesicLine facilitates the determination of a series of points on a single geodesic. The starting point (lat1, lon1) and the azimuth azi1 are specified in the constructor; alternatively, the {Geodesic.Line} method can be used to create a GeodesicLine. #Position Position} returns the location of point 2 a distance s12 along the geodesic. Alternatively #ArcPosition ArcPosition} gives the position of point 2 an arc length a12 along the geodesic. You can register the position of a reference point 3 a distance (arc length), s13 (a13) along the geodesic with the SetDistance (SetArc) functions. Points a fractional distance along the line can be found by providing, for example, 0.5 * Distance as an argument to Position. The Geodesic.InverseLine or Geodesic.DirectLine methods return GeodesicLine objects with point 3 set to the point 2 of the corresponding geodesic problem. GeodesicLine objects created with the public constructor or with Geodesic.Line have s13 and a13 set to NaNs.

The calculations are accurate to better than 15 nm (15 nanometers). See Sec. 9 of arXiv:1102.1215v1 for details. The algorithms used by this class are based on series expansions using the flattening f as a small parameter. These are only accurate for |f| < 0.02; however reasonably accurate results will be obtained for |f| < 0.2.

The algorithms are described in

Here's an example of using this class

import net.sf.geographiclib.*;
public class GeodesicLineTest {
public static void main(String[] args) {
// Print waypoints between JFK and SIN
Geodesic geod = Geodesic.WGS84;
double
lat1 = 40.640, lon1 = -73.779, // JFK
lat2 = 1.359, lon2 = 103.989; // SIN
GeodesicLine line = geod.InverseLine(lat1, lon1, lat2, lon2,
GeodesicMask.DISTANCE_IN |
GeodesicMask.LATITUDE |
GeodesicMask.LONGITUDE);
double ds0 = 500e3; // Nominal distance between points = 500 km
// The number of intervals
int num = (int)(Math.ceil(line.Distance() / ds0));
{
// Use intervals of equal length
double ds = line.Distance() / num;
for (int i = 0; i <= num; ++i) {
GeodesicData g = line.Position(i * ds,
GeodesicMask.LATITUDE |
GeodesicMask.LONGITUDE);
System.out.println(i + " " + g.lat2 + " " + g.lon2);
}
}
{
// Slightly faster, use intervals of equal arc length
double da = line.Arc() / num;
for (int i = 0; i <= num; ++i) {
GeodesicData g = line.ArcPosition(i * da,
GeodesicMask.LATITUDE |
GeodesicMask.LONGITUDE);
System.out.println(i + " " + g.lat2 + " " + g.lon2);
}
}
}
}

Definition at line 93 of file GeodesicLine.java.

Constructor & Destructor Documentation

◆ GeodesicLine() [1/4]

net.sf.geographiclib.GeodesicLine.GeodesicLine ( Geodesic  g,
double  lat1,
double  lon1,
double  azi1 
)
inline

Constructor for a geodesic line staring at latitude lat1, longitude lon1, and azimuth azi1 (all in degrees).

Parameters
gA Geodesic object used to compute the necessary information about the GeodesicLine.
lat1latitude of point 1 (degrees).
lon1longitude of point 1 (degrees).
azi1azimuth at point 1 (degrees).

lat1 should be in the range [−90°, 90°].

If the point is at a pole, the azimuth is defined by keeping lon1 fixed, writing lat1 = ±(90° − ε), and taking the limit ε → 0+.

Definition at line 127 of file GeodesicLine.java.

◆ GeodesicLine() [2/4]

net.sf.geographiclib.GeodesicLine.GeodesicLine ( Geodesic  g,
double  lat1,
double  lon1,
double  azi1,
int  caps 
)
inline

Constructor for a geodesic line staring at latitude lat1, longitude lon1, and azimuth azi1 (all in degrees) with a subset of the capabilities included.

Parameters
gA Geodesic object used to compute the necessary information about the GeodesicLine.
lat1latitude of point 1 (degrees).
lon1longitude of point 1 (degrees).
azi1azimuth at point 1 (degrees).
capsbitor'ed combination of GeodesicMask values specifying the capabilities the GeodesicLine object should possess, i.e., which quantities can be returned in calls to Position.

The GeodesicMask values are

Definition at line 177 of file GeodesicLine.java.

◆ GeodesicLine() [3/4]

net.sf.geographiclib.GeodesicLine.GeodesicLine ( Geodesic  g,
double  lat1,
double  lon1,
double  azi1,
double  salp1,
double  calp1,
int  caps,
boolean  arcmode,
double  s13_a13 
)
inlineprotected

Definition at line 276 of file GeodesicLine.java.

◆ GeodesicLine() [4/4]

net.sf.geographiclib.GeodesicLine.GeodesicLine ( )
inlineprivate

A default constructor. If GeodesicLine.Position is called on the resulting object, it returns immediately (without doing any calculations). The object can be set with a call to Geodesic.Line. Use {} to test whether object is still in this uninitialized state. (This constructor was useful in C++, e.g., to allow vectors of GeodesicLine objects. It may not be needed in Java, so make it private.)

Definition at line 292 of file GeodesicLine.java.

Member Function Documentation

◆ Arc()

double net.sf.geographiclib.GeodesicLine.Arc ( )
inline
Returns
a13, the arc length to point 3 (degrees).

Definition at line 744 of file GeodesicLine.java.

◆ ArcPosition() [1/2]

GeodesicData net.sf.geographiclib.GeodesicLine.ArcPosition ( double  a12)
inline

Compute the position of point 2 which is an arc length a12 (degrees) from point 1.

Parameters
a12arc length from point 1 to point 2 (degrees); it can be negative.
Returns
a GeodesicData object with the following fields: lat1, lon1, azi1, lat2, lon2, azi2, s12, a12. Some of these results may be missing if the GeodesicLine did not include the relevant capability.

The values of lon2 and azi2 returned are in the range [−180°, 180°].

The GeodesicLine object must have been constructed with caps |= GeodesicMask#DISTANCE_IN; otherwise no parameters are set.

Definition at line 355 of file GeodesicLine.java.

◆ ArcPosition() [2/2]

GeodesicData net.sf.geographiclib.GeodesicLine.ArcPosition ( double  a12,
int  outmask 
)
inline

Compute the position of point 2 which is an arc length a12 (degrees) from point 1 and with a subset of the geodesic results returned.

Parameters
a12arc length from point 1 to point 2 (degrees); it can be negative.
outmaska bitor'ed combination of GeodesicMask values specifying which results should be returned.
Returns
a GeodesicData object giving lat1, lon2, azi2, and a12.

Requesting a value which the GeodesicLine object is not capable of computing is not an error (no parameters will be set). The value of lon2 returned is in the range [−180°, 180°], unless the outmask includes the GeodesicMask#LONG_UNROLL flag.

Definition at line 374 of file GeodesicLine.java.

◆ Azimuth()

double net.sf.geographiclib.GeodesicLine.Azimuth ( )
inline
Returns
azi1 the azimuth (degrees) of the geodesic line at point 1.

Definition at line 657 of file GeodesicLine.java.

◆ AzimuthCosines()

Pair net.sf.geographiclib.GeodesicLine.AzimuthCosines ( )
inline
Returns
pair of sine and cosine of azi1 the azimuth (degrees) of the geodesic line at point 1.

Definition at line 664 of file GeodesicLine.java.

◆ Capabilities() [1/2]

int net.sf.geographiclib.GeodesicLine.Capabilities ( )
inline
Returns
caps the computational capabilities that this object was constructed with. LATITUDE and AZIMUTH are always included.

Definition at line 714 of file GeodesicLine.java.

◆ Capabilities() [2/2]

boolean net.sf.geographiclib.GeodesicLine.Capabilities ( int  testcaps)
inline
Parameters
testcapsa set of bitor'ed GeodesicMask values.
Returns
true if the GeodesicLine object has all these capabilities.

Definition at line 720 of file GeodesicLine.java.

◆ Distance()

double net.sf.geographiclib.GeodesicLine.Distance ( )
inline
Returns
s13, the distance to point 3 (meters).

Definition at line 739 of file GeodesicLine.java.

◆ EquatorialArc()

double net.sf.geographiclib.GeodesicLine.EquatorialArc ( )
inline
Returns
a1 the arc length (degrees) between the northward equatorial crossing and point 1.

Definition at line 691 of file GeodesicLine.java.

◆ EquatorialAzimuth()

double net.sf.geographiclib.GeodesicLine.EquatorialAzimuth ( )
inline
Returns
azi0 the azimuth (degrees) of the geodesic line as it crosses the equator in a northward direction.

Definition at line 673 of file GeodesicLine.java.

◆ EquatorialAzimuthCosines()

Pair net.sf.geographiclib.GeodesicLine.EquatorialAzimuthCosines ( )
inline
Returns
pair of sine and cosine of azi0 the azimuth of the geodesic line as it crosses the equator in a northward direction.

Definition at line 682 of file GeodesicLine.java.

◆ Flattening()

double net.sf.geographiclib.GeodesicLine.Flattening ( )
inline
Returns
f the flattening of the ellipsoid. This is the value inherited from the Geodesic object used in the constructor.

Definition at line 707 of file GeodesicLine.java.

◆ GenDistance()

double net.sf.geographiclib.GeodesicLine.GenDistance ( boolean  arcmode)
inline

The distance or arc length to point 3.

Parameters
arcmodeboolean flag determining the meaning of returned value.
Returns
s13 if arcmode is false; a13 if arcmode is true.

Definition at line 733 of file GeodesicLine.java.

◆ GenSetDistance()

void net.sf.geographiclib.GeodesicLine.GenSetDistance ( boolean  arcmode,
double  s13_a13 
)
inline

Specify position of point 3 in terms of either distance or arc length.

Parameters
arcmodeboolean flag determining the meaning of the second parameter; if arcmode is false, then the GeodesicLine object must have been constructed with caps |= GeodesicMask#DISTANCE_IN.
s13_a13if arcmode is false, this is the distance from point 1 to point 3 (meters); otherwise it is the arc length from point 1 to point 3 (degrees); it can be negative.

Definition at line 630 of file GeodesicLine.java.

◆ Init()

boolean net.sf.geographiclib.GeodesicLine.Init ( )
inlineprivate
Returns
true if the object has been initialized.

Definition at line 640 of file GeodesicLine.java.

◆ Latitude()

double net.sf.geographiclib.GeodesicLine.Latitude ( )
inline
Returns
lat1 the latitude of point 1 (degrees).

Definition at line 645 of file GeodesicLine.java.

◆ LineInit()

void net.sf.geographiclib.GeodesicLine.LineInit ( Geodesic  g,
double  lat1,
double  lon1,
double  azi1,
double  salp1,
double  calp1,
int  caps 
)
inlineprivate

Definition at line 188 of file GeodesicLine.java.

◆ Longitude()

double net.sf.geographiclib.GeodesicLine.Longitude ( )
inline
Returns
lon1 the longitude of point 1 (degrees).

Definition at line 651 of file GeodesicLine.java.

◆ MajorRadius()

double net.sf.geographiclib.GeodesicLine.MajorRadius ( )
inline
Returns
a the equatorial radius of the ellipsoid (meters). This is the value inherited from the Geodesic object used in the constructor.

Definition at line 700 of file GeodesicLine.java.

◆ Position() [1/3]

GeodesicData net.sf.geographiclib.GeodesicLine.Position ( boolean  arcmode,
double  s12_a12,
int  outmask 
)
inline

The general position function. Position and ArcPosition are defined in terms of this function.

Parameters
arcmodeboolean flag determining the meaning of the second parameter; if arcmode is false, then the GeodesicLine object must have been constructed with caps |= GeodesicMask#DISTANCE_IN.
s12_a12if arcmode is false, this is the distance between point 1 and point 2 (meters); otherwise it is the arc length between point 1 and point 2 (degrees); it can be negative.
outmaska bitor'ed combination of GeodesicMask values specifying which results should be returned.
Returns
a GeodesicData object with the requested results.

The GeodesicMask values possible for outmask are

Requesting a value which the GeodesicLine object is not capable of computing is not an error; Double.NaN is returned instead.

Definition at line 423 of file GeodesicLine.java.

◆ Position() [2/3]

GeodesicData net.sf.geographiclib.GeodesicLine.Position ( double  s12)
inline

Compute the position of point 2 which is a distance s12 (meters) from point 1.

Parameters
s12distance from point 1 to point 2 (meters); it can be negative.
Returns
a GeodesicData object with the following fields: lat1, lon1, azi1, lat2, lon2, azi2, s12, a12. Some of these results may be missing if the GeodesicLine did not include the relevant capability.

The values of lon2 and azi2 returned are in the range [−180°, 180°].

The GeodesicLine object must have been constructed with caps |= GeodesicMask#DISTANCE_IN; otherwise no parameters are set.

Definition at line 311 of file GeodesicLine.java.

◆ Position() [3/3]

GeodesicData net.sf.geographiclib.GeodesicLine.Position ( double  s12,
int  outmask 
)
inline

Compute the position of point 2 which is a distance s12 (meters) from point 1 and with a subset of the geodesic results returned.

Parameters
s12distance from point 1 to point 2 (meters); it can be negative.
outmaska bitor'ed combination of GeodesicMask values specifying which results should be returned.
Returns
a GeodesicData object including the requested results.

The GeodesicLine object must have been constructed with caps |= GeodesicMask#DISTANCE_IN; otherwise no parameters are set. Requesting a value which the GeodesicLine object is not capable of computing is not an error (no parameters will be set). The value of lon2 returned is normally in the range [−180°, 180°]; however if the outmask includes the GeodesicMask#LONG_UNROLL flag, the longitude is "unrolled" so that the quantity lon2lon1 indicates how many times and in what sense the geodesic encircles the ellipsoid.

Definition at line 334 of file GeodesicLine.java.

◆ SetDistance()

void net.sf.geographiclib.GeodesicLine.SetDistance ( double  s13)
inline

Specify position of point 3 in terms of distance.

Parameters
s13the distance from point 1 to point 3 (meters); it can be negative.

This is only useful if the GeodesicLine object has been constructed with caps |= GeodesicMask#DISTANCE_IN.

Definition at line 598 of file GeodesicLine.java.

Member Data Documentation

◆ _a

double net.sf.geographiclib.GeodesicLine._a
private

Definition at line 102 of file GeodesicLine.java.

◆ _a13

double net.sf.geographiclib.GeodesicLine._a13
private

Definition at line 105 of file GeodesicLine.java.

◆ _C1a

double net.sf.geographiclib.GeodesicLine._C1a[]
private

Definition at line 107 of file GeodesicLine.java.

◆ _caps

int net.sf.geographiclib.GeodesicLine._caps
private

Definition at line 109 of file GeodesicLine.java.

◆ _lat1

double net.sf.geographiclib.GeodesicLine._lat1
private

Definition at line 101 of file GeodesicLine.java.

◆ nC1_

final int net.sf.geographiclib.GeodesicLine.nC1_ = Geodesic.nC1_
staticprivate

Definition at line 95 of file GeodesicLine.java.

◆ nC1p_

final int net.sf.geographiclib.GeodesicLine.nC1p_ = Geodesic.nC1p_
staticprivate

Definition at line 96 of file GeodesicLine.java.

◆ nC2_

final int net.sf.geographiclib.GeodesicLine.nC2_ = Geodesic.nC2_
staticprivate

Definition at line 97 of file GeodesicLine.java.

◆ nC3_

final int net.sf.geographiclib.GeodesicLine.nC3_ = Geodesic.nC3_
staticprivate

Definition at line 98 of file GeodesicLine.java.

◆ nC4_

final int net.sf.geographiclib.GeodesicLine.nC4_ = Geodesic.nC4_
staticprivate

Definition at line 99 of file GeodesicLine.java.


The documentation for this class was generated from the following file:
gtsam.examples.DogLegOptimizerExample.int
int
Definition: DogLegOptimizerExample.py:111
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int main(int argc, char **argv)
Definition: cmake/example_cmake_find_gtsam/main.cpp:63
net
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GeodesicLine()
Definition: GeodesicLine.java:292
net.sf.geographiclib
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Definition: testBTree.cpp:41
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Definition: BiCGSTAB_step_by_step.cpp:9


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autogenerated on Sat Nov 16 2024 04:16:46