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Warning! This version of documentation is OUTDATED, as it describes an older SDK version! Please switch to the documentation for the latest SDK version.
Warning! This version of documentation describes an old SDK version which is no longer supported! Please upgrade to the latest SDK version.

Unigine.Ellipsoid Class

Warning
The functionality described in this article is not available in the Community SDK edition.
You should upgrade to Engineering / Sim SDK edition to use it.

The Ellipsoid class handles the geodetic transformations:

  • Specifies the Ellipsoid settings: semimajor axis, flattening coefficient
  • Performs systems coordinates (ECF, ENU, NED, Geodetic) conversion
  • Solves direct and inverse geodetic problems with different calculation mode (Great Circle and Vincenty algorithms)

This class is used to create an Ellipsoid instance to the GeodeticPivot class.

Here is a code snippet of the Ellipsoid class usage:

Source code (C#)
// define the geodetic origin
dvec3 tomsk_origin = new dvec3(58.49771, 84.97437, 117.0);

// create a new GeodeticPivot object
GeodeticPivot pivot = new GeodeticPivot();

// create a new ellipsoid and specify its settings
Ellipsoid ellipsoid = pivot.getEllipsoid();
ellipsoid.setSemimajorAxis(80000.0f);
ellipsoid.setMode(Ellipsoid.MODE_FAST);

// set the ellipsoid to the pivot
pivot.setOrigin(tomsk_origin);
pivot.setEllipsoid(ellipsoid);

Ellipsoid Class

Properties

double SemiminorEccentricitySqr#

The squared eccentricity calculated along the semiminor axis.

double SemimajorEccentricitySqr#

The squared eccentricity calculated along the semimajor axis.

double MeanRadius#

The mean radius of the ellipsoid.

double SemiminorAxis#

The Semiminor axis of the ellipsoid in units.

int Mode#

The calculation mode int value: 1 if the mode is MODE_ACCURATE, 0 if the mode is MODE_FAST.

double Flattening#

The Flattening coefficient of the ellipsoid.

double SemimajorAxis#

The Semimajor axis length of the ellipsoid in units.

Members


Ellipsoid ( double semimajor_axis, double flattening ) #

Constructor. Creates a new Ellipsoid class instance with given flattening and semimajor axis.

Arguments

  • double semimajor_axis - Semimajor axis.
  • double flattening - Flattening coefficient.

Ellipsoid ( ) #

Constructor. Creates a new Ellipsoid class instance (WGS84 Ellipsoid).

dvec3 GetENUSurfacePoint ( dvec3 geodetic_origin, dvec3 tangent_point ) #

Returns surface point by using tangent point coordinates.
Notice
The Up-axis (Z+) direction in ENU points upward along the ellipsoid normal, while in UNIGINE implementation of ENU it goes from the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 tangent_point - Tangent point coordinates to converted (curved) to surface coordinates (offset related to point of junction).

Return value

Surface point coordinates.

dvec3 GetENUTangentPoint ( dvec3 geodetic_origin, dvec3 surface_point ) #

Returns tangent point ENU coordinates based on the geographical coordinates.
Notice
The Up-axis (Z+) direction in ENU points upward along the ellipsoid normal, while in UNIGINE implementation of ENU it goes from the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 surface_point - Surface point coordinates to be converted (flatten) to tangent point (offset related to point of junction).

Return value

Tangent point coordinates.

quat GetENUWorldRotation ( dvec3 geodetic_origin ) #

Returns the world rotation quaternion in ENU coordinates.
Notice
The Up-axis (Z+) direction in ENU points upward along the ellipsoid normal, while in UNIGINE implementation of ENU it goes from the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).

Return value

World rotation in ENU coordinates.

dmat4 GetENUWorldTransform ( dvec3 geodetic_origin ) #

Returns the world transformation matrix in ENU coordinates.
Notice
The Up-axis (Z+) direction in ENU points upward along the ellipsoid normal, while in UNIGINE implementation of ENU it goes from the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).

Return value

World transformation matrix in ENU coordinates.

int IsSupported ( ) #

Returns a value indicating if the geodetics feature is enabled.

Return value

1 if the geodetics feature is enabled; otherwise, 0.

dvec3 GetNEDSurfacePoint ( dvec3 geodetic_origin, dvec3 tangent_point ) #

Returns surface point by using tangent point coordinates.
Notice
The Down-axis direction in NED points downward along the ellipsoid normal, while in UNIGINE implementation of NED it goes through the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 tangent_point - Tangent point coordinates to converted (curved) to surface coordinates (offset related to point of junction).

Return value

Surface point coordinates.

dvec3 GetNEDTangentPoint ( dvec3 geodetic_origin, dvec3 surface_point ) #

Returns tangent point NED coordinates based on the geographical coordinates.
Notice
The Down-axis direction in NED points downward along the ellipsoid normal, while in UNIGINE implementation of NED it goes through the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 surface_point - Surface point coordinates to be converted (flatten) to tangent point (offset related to point of junction).

Return value

Tangent point coordinates.

quat GetNEDWorldRotation ( dvec3 geodetic_origin ) #

Returns the world rotation quaternion in NED coordinates.
Notice
The Down-axis direction in NED points downward along the ellipsoid normal, while in UNIGINE implementation of NED it goes through the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).

Return value

World rotation in NED coordinates.

dmat4 GetNEDWorldTransform ( dvec3 geodetic_origin ) #

Returns the world transformation matrix in NED coordinates.
Notice
The Down-axis direction in NED points downward along the ellipsoid normal, while in UNIGINE implementation of NED it goes through the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).

Return value

World transformation matrix in NED coordinates.

dvec3 SolveGeodeticDirect ( dvec3 geodetic_start, double bearing, double distance ) #

Solves the direct geodetic problem: calculates end point coordinates on the ellipsoid by using given start point, distance between points, and bearing value.

Arguments

  • dvec3 geodetic_start - Start point on the ellipsoid.
  • double bearing - Bearing value.
  • double distance - Distance between two points on the ellipsoid.

void SolveGeodeticInverse ( dvec3 geodetic_start, dvec3 geodetic_end, out double bearing, out double distance ) #

Solves the inverse geodetic problem: calculates distance and bearing values by using given start and end points on the ellipsoid.

Arguments

  • dvec3 geodetic_start - Start point on the ellipsoid.
  • dvec3 geodetic_end - End point on the ellipsoid.
  • out double bearing - Variable to save the calculated bearing value.
  • out double distance - Variable to save the calculated distance value.

dvec3 ToECF ( dvec3 geodetic_coords ) #

Converts geodetic coordinates to Cartesian (ECF).

Arguments

  • dvec3 geodetic_coords - Ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters)) to be converted to Cartesian.

Return value

Cartesian coordinates.

dvec3 ToENU ( dvec3 geodetic_origin, dvec3 geodetic_coords ) #

Converts geodetic coordinates to ENU (East, North, Up).
Notice
The Up-axis (Z+) direction in ENU points upward along the ellipsoid normal, while in UNIGINE implementation of ENU it goes from the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 geodetic_coords - Coordinates to be converted to ENU.

Return value

ENU coordinates.

dvec3 ToGeodetic ( dvec3 ecf_coords, int need_alt = 1 ) #

Converts Cartesian (ECF) coordinates to Ellipsoid.

Arguments

  • dvec3 ecf_coords - Cartesian ECF coordinates to be converted.
  • int need_alt - Flag indicating if altitude is to be calculated. 1 to calculate altitude, 0 - to skip altitude calculation.The default value is 1.

Return value

Ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters)

dvec3 ToNED ( dvec3 geodetic_origin, dvec3 geodetic_coords ) #

Converts geodetics coordinates to NED (North, East, Down).
Notice
The Down-axis direction in NED points downward along the ellipsoid normal, while in UNIGINE implementation of NED it goes through the Earth's center.

Arguments

  • dvec3 geodetic_origin - The origin in ellipsoid coordinates (latitude (degrees), longitude (degrees) and altitude (meters).
  • dvec3 geodetic_coords - Coordinates to be converted to NED.

Return value

NED coordinates.
Last update: 2022-12-14
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