Uses of Class org.geotoolkit.referencing.operation.projection.ProjectionException (Referencing core 3.18-geoapi-3.0 API)

Packages that use ProjectionException
org.geotoolkit.referencing.operation.projection	Map projection implementations.

Methods in org.geotoolkit.referencing.operation.projection that throw ProjectionException
`Matrix`	`TransverseMercator.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`Orthographic.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`Mercator.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`LambertConformal.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`LambertAzimuthalEqualArea.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`EquatorialStereographic.derivative(Point2D point)` Gets the derivative of this transform at a point.
`Matrix`	`AlbersEqualArea.derivative(Point2D point)` Gets the derivative of this transform at a point.
`protected abstract void`	`UnitaryProjection.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Converts the coordinate in `srcPts` at the given offset and stores the result in `ptDst` at the given offset.
`protected void`	`TransverseMercator.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Stereographic.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Polyconic.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`PolarStereographic.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Orthographic.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`ObliqueStereographic.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`ObliqueMercator.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`NewZealandMapGrid.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Mercator.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`LambertConformal.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`LambertAzimuthalEqualArea.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Krovak.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`Equirectangular.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`CassiniSoldner.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected void`	`AlbersEqualArea.inverseTransform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`x`,`y`) coordinates and stores the result in `dstPts` (angles in radians).
`protected abstract void`	`UnitaryProjection.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Converts the coordinate in `srcPts` at the given offset and stores the result in `dstPts` at the given offset.
`protected void`	`TransverseMercator.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Stereographic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Polyconic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`PolarStereographic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Orthographic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`ObliqueStereographic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`ObliqueMercator.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`NewZealandMapGrid.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Mercator.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`LambertConformal.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`LambertAzimuthalEqualArea.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Krovak.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`Equirectangular.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`EquatorialStereographic.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`CassiniSoldner.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).
`protected void`	`AlbersEqualArea.transform(double[] srcPts, int srcOff, double[] dstPts, int dstOff)` Transforms the specified (`λ`,`φ`) coordinates (units in radians) and stores the result in `dstPts` (linear distance on a unit sphere).

Matrix

TransverseMercator.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

Orthographic.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

Mercator.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

LambertConformal.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

LambertAzimuthalEqualArea.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

EquatorialStereographic.derivative(Point2D point)
Gets the derivative of this transform at a point.

Matrix

AlbersEqualArea.derivative(Point2D point)
Gets the derivative of this transform at a point.

protected abstract void

UnitaryProjection.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Converts the coordinate in srcPts at the given offset and stores the result in ptDst at the given offset.

protected void

TransverseMercator.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Stereographic.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Polyconic.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

PolarStereographic.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Orthographic.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

ObliqueStereographic.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

ObliqueMercator.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

NewZealandMapGrid.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Mercator.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

LambertConformal.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

LambertAzimuthalEqualArea.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Krovak.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

Equirectangular.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

CassiniSoldner.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected void

AlbersEqualArea.inverseTransform(double[] srcPts,
                 int srcOff,
                 double[] dstPts,
                 int dstOff)

Transforms the specified (x,y) coordinates and stores the result in dstPts (angles in radians).

protected abstract void

UnitaryProjection.transform(double[] srcPts,
          int srcOff,
          double[] dstPts,
          int dstOff)

Converts the coordinate in srcPts at the given offset and stores the result in dstPts at the given offset.

protected void

TransverseMercator.transform(double[] srcPts,
          int srcOff,
          double[] dstPts,
          int dstOff)