Differences

This shows you the differences between two versions of the page.

--- thinkgeo.mapsuite.silverlightcore.multipointshape [2015/09/21 03:22]
admin
+++ thinkgeo.mapsuite.silverlightcore.multipointshape [2017/03/16 21:59] (current)
@@ Line 1: / Line 1: @@
 ====== ThinkGeo.MapSuite.SilverlightCore.MultipointShape ======
+{{section>upgrade_map_suite_to_10.0}}
 This class represents one or more point shapes.
 ===== Inheritance Hierarchy =====
@@ Line 10: / Line 13: @@
 ** {{wiki:PublicMethod.gif|}} MultipointShape() **
-This constructor creates a MultipointShape.
+  * //This constructor creates a MultipointShape.//
 == Remarks ==
-None
+  * //None//
 == Parameters ==
 <div newline></div>
 ** {{wiki:PublicMethod.gif|}} MultipointShape(IEnumerable<PointShape>) **
-This constructor creates a MultipointShape by passing in predefined points.
+  * //This constructor creates a MultipointShape by passing in predefined points.//
 == Remarks ==
-None
+  * //None//
 == Parameters ==
   * //points//
@@ Line 28: / Line 31: @@
 ** {{wiki:PublicMethod.gif|}} MultipointShape(IEnumerable<Feature>) **
-This constructor creates a MultipointShape by passing in predefined point features.
+  * //This constructor creates a MultipointShape by passing in predefined point features.//
 == Remarks ==
-None
+  * //None//
 == Parameters ==
   * //pointFeatures//
@@ Line 39: / Line 42: @@
 ** {{wiki:PublicMethod.gif|}} MultipointShape(Feature) **
-This constructor creates a MultipointShape by passing in a Multipoint type Feature.
+  * //This constructor creates a MultipointShape by passing in a Multipoint type Feature.//
 == Remarks ==
-N/A
+  * //N/A//
 == Parameters ==
   * //multipointFeature//
@@ Line 50: / Line 53: @@
 ** {{wiki:PublicMethod.gif|}} MultipointShape(String) **
-This constructor creates the MultipointShape.
+  * //This constructor creates the MultipointShape.//
 == Remarks ==
-None
+  * //None//
 == Parameters ==
   * //wellKnownText//
@@ Line 61: / Line 64: @@
 ** {{wiki:PublicMethod.gif|}} MultipointShape(Byte[]) **
-This constructor creates the LineShape.
+  * //This constructor creates the LineShape.//
 == Remarks ==
-None
+  * //None//
 == Parameters ==
   * //wellKnownBinary//
@@ Line 74: / Line 77: @@
 ** {{wiki:PublicMethod.gif|}} ScaleUp(Double) **
-This method increases the size of the shape by the percentage given in the percentage parameter.
+  * //This method increases the size of the shape by the percentage given in the percentage parameter.//
 == Remarks ==
-This method is useful when you would like to increase the size of the shape. Note that a larger percentage will scale the shape up faster, as you are applying the operation multiple times. There is also a ScaleDown method that will shrink the shape.
+  * //This method is useful when you would like to increase the size of the shape. Note that a larger percentage will scale the shape up faster, as you are applying the operation multiple times. There is also a ScaleDown method that will shrink the shape.//
 == Return Value ==
@@ Line 90: / Line 93: @@
 ** {{wiki:PublicMethod.gif|}} ScaleDown(Double) **
-This method decreases the size of the shape by the percentage given in the percentage parameter.
+  * //This method decreases the size of the shape by the percentage given in the percentage parameter.//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 106: / Line 109: @@
 ** {{wiki:PublicMethod.gif|}} ConvexHull() **
-This method returns the convex hull of the shape (defined as the smallest convex ring that contains all the points in the shape).
+  * //This method returns the convex hull of the shape (defined as the smallest convex ring that contains all the points in the shape).//
 == Remarks ==
-This method is useful when you want to create a perimeter around the shape. For example, if you had a MultiPolygon which represented buildings on a campus, you could easily get the convex hull of the buildings and determine the perimeter of all of the buildings together. This also works with MultiPoint shapes, where each point may represent a certain type of person you are doing statistics on. With convex hull, you can get an idea of the regions those points are located in.
+  * //This method is useful when you want to create a perimeter around the shape. For example, if you had a MultiPolygon which represented buildings on a campus, you could easily get the convex hull of the buildings and determine the perimeter of all of the buildings together. This also works with MultiPoint shapes, where each point may represent a certain type of person you are doing statistics on. With convex hull, you can get an idea of the regions those points are located in.//
 == Return Value ==
@@ Line 118: / Line 121: @@
 ** {{wiki:PublicMethod.gif|}} RemoveVertex(Vertex) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 134: / Line 137: @@
 ** {{wiki:PublicMethod.gif|}} LoadFromWellKnownData(String) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 150: / Line 153: @@
 ** {{wiki:PublicMethod.gif|}} GetWellKnownText() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 162: / Line 165: @@
 ** {{wiki:PublicMethod.gif|}} LoadFromWellKnownData(Byte[]) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 178: / Line 181: @@
 ** {{wiki:PublicMethod.gif|}} GetWellKnownBinary() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 190: / Line 193: @@
 ** {{wiki:PublicMethod.gif|}} GetWellKnownBinary(WkbByteOrder) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 206: / Line 209: @@
 ** {{wiki:PublicMethod.gif|}} GetBoundingBox() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 218: / Line 221: @@
 ** {{wiki:PublicMethod.gif|}} GetWellKnownType() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 230: / Line 233: @@
 ** {{wiki:PublicMethod.gif|}} CloneDeep() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 242: / Line 245: @@
 ** {{wiki:PublicMethod.gif|}} TranslateByOffset(Double,Double,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 270: / Line 273: @@
 ** {{wiki:PublicMethod.gif|}} TranslateByOffset(Double,Double) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 290: / Line 293: @@
 ** {{wiki:PublicMethod.gif|}} TranslateByDegree(Double,Double,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 318: / Line 321: @@
 ** {{wiki:PublicMethod.gif|}} TranslateByDegree(Double,Double) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 338: / Line 341: @@
 ** {{wiki:PublicMethod.gif|}} Rotate(PointShape,Single) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 358: / Line 361: @@
 ** {{wiki:PublicMethod.gif|}} GetShortestLineTo(BaseShape,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 378: / Line 381: @@
 ** {{wiki:PublicMethod.gif|}} GetShortestLineTo(Feature,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 398: / Line 401: @@
 ** {{wiki:PublicMethod.gif|}} GetClosestPointTo(BaseShape,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 418: / Line 421: @@
 ** {{wiki:PublicMethod.gif|}} GetClosestPointTo(Feature,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 438: / Line 441: @@
 ** {{wiki:PublicMethod.gif|}} GetCenterPoint() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 450: / Line 453: @@
 ** {{wiki:PublicMethod.gif|}} Buffer(Double,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 474: / Line 477: @@
 ** {{wiki:PublicMethod.gif|}} Buffer(Double,Int32,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 502: / Line 505: @@
 ** {{wiki:PublicMethod.gif|}} Buffer(Double,Int32,BufferCapType,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 534: / Line 537: @@
 ** {{wiki:PublicMethod.gif|}} GetDistanceTo(BaseShape,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 558: / Line 561: @@
 ** {{wiki:PublicMethod.gif|}} GetDistanceTo(Feature,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 582: / Line 585: @@
 ** {{wiki:PublicMethod.gif|}} Register(PointShape,PointShape,DistanceUnit,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 610: / Line 613: @@
 ** {{wiki:PublicMethod.gif|}} Register(Feature,Feature,DistanceUnit,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 638: / Line 641: @@
 ** {{wiki:PublicMethod.gif|}} Validate(ShapeValidationMode) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 654: / Line 657: @@
 ** {{wiki:PublicMethod.gif|}} IsDisjointed(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 670: / Line 673: @@
 ** {{wiki:PublicMethod.gif|}} IsDisjointed(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 686: / Line 689: @@
 ** {{wiki:PublicMethod.gif|}} Intersects(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 702: / Line 705: @@
 ** {{wiki:PublicMethod.gif|}} Intersects(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 718: / Line 721: @@
 ** {{wiki:PublicMethod.gif|}} Touches(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 734: / Line 737: @@
 ** {{wiki:PublicMethod.gif|}} Touches(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 750: / Line 753: @@
 ** {{wiki:PublicMethod.gif|}} Crosses(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 766: / Line 769: @@
 ** {{wiki:PublicMethod.gif|}} Crosses(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 782: / Line 785: @@
 ** {{wiki:PublicMethod.gif|}} IsWithin(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 798: / Line 801: @@
 ** {{wiki:PublicMethod.gif|}} IsWithin(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 814: / Line 817: @@
 ** {{wiki:PublicMethod.gif|}} Contains(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 830: / Line 833: @@
 ** {{wiki:PublicMethod.gif|}} Contains(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 846: / Line 849: @@
 ** {{wiki:PublicMethod.gif|}} Overlaps(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 862: / Line 865: @@
 ** {{wiki:PublicMethod.gif|}} Overlaps(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 878: / Line 881: @@
 ** {{wiki:PublicMethod.gif|}} IsTopologicallyEqual(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 894: / Line 897: @@
 ** {{wiki:PublicMethod.gif|}} IsTopologicallyEqual(Feature) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 910: / Line 913: @@
 ** {{wiki:PublicMethod.gif|}} GetFeature() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 922: / Line 925: @@
 ** {{wiki:PublicMethod.gif|}} GetFeature(IDictionary<String,String>) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 938: / Line 941: @@
 ** {{wiki:PublicMethod.gif|}} GetCrossing(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 954: / Line 957: @@
 ** {{wiki:PublicMethod.gif|}} ScaleTo(Double) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 970: / Line 973: @@
 ** {{wiki:PublicMethod.gif|}} ToString() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 982: / Line 985: @@
 ** {{wiki:PublicMethod.gif|}} Equals(Object) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 998: / Line 1001: @@
 ** {{wiki:PublicMethod.gif|}} GetHashCode() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1010: / Line 1013: @@
 ** {{wiki:PublicMethod.gif|}} GetType() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1022: / Line 1025: @@
 ** {{wiki:PublicMethod.gif|}}{{wiki:Static.gif|}} RemoveVertex(Vertex,MultipointShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1043: / Line 1046: @@
 ** {{wiki:ProtectedMethod.gif|}} CloneDeepCore() **
-This method returns a complete copy of the shape without any references in common.
+  * //This method returns a complete copy of the shape without any references in common.//
 == Remarks ==
-When you override this method, you need to ensure that there are no references in common between the original and the copy.
+  * //When you override this method, you need to ensure that there are no references in common between the original and the copy.//
 == Return Value ==
@@ Line 1055: / Line 1058: @@
 ** {{wiki:ProtectedMethod.gif|}} ScaleUpCore(Double) **
-This method increases the size of the shape by the percentage given in the percentage parameter.
+  * //This method increases the size of the shape by the percentage given in the percentage parameter.//
 == Remarks ==
-This method is useful when you would like to increase the size of the shape. Note that a larger percentage will scale the shape up faster, as you are applying the operation multiple times. There is also a ScaleDown method that will shrink the shape.
+  * //This method is useful when you would like to increase the size of the shape. Note that a larger percentage will scale the shape up faster, as you are applying the operation multiple times. There is also a ScaleDown method that will shrink the shape.//
 == Return Value ==
@@ Line 1071: / Line 1074: @@
 ** {{wiki:ProtectedMethod.gif|}} ScaleDownCore(Double) **
-This method decreases the size of the shape by the percentage given in the percentage parameter.
+  * //This method decreases the size of the shape by the percentage given in the percentage parameter.//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1087: / Line 1090: @@
 ** {{wiki:ProtectedMethod.gif|}} ConvexHullCore() **
-This method returns the convex hull of the shape (defined as the smallest convex ring that contains all the points in the shape).
+  * //This method returns the convex hull of the shape (defined as the smallest convex ring that contains all the points in the shape).//
 == Remarks ==
-This method is useful when you want to create a perimeter around the shape. For example, if you had a MultiPolygon which represented buildings on a campus, you could easily get the convex hull of the buildings and determine the perimeter of all of the buildings together. This also works with MultiPoint shapes, where each point may represent a certain type of person you are doing statistics on. With convex hull, you can get an idea of the regions those points are located in.
+  * //This method is useful when you want to create a perimeter around the shape. For example, if you had a MultiPolygon which represented buildings on a campus, you could easily get the convex hull of the buildings and determine the perimeter of all of the buildings together. This also works with MultiPoint shapes, where each point may represent a certain type of person you are doing statistics on. With convex hull, you can get an idea of the regions those points are located in.//
 == Return Value ==
@@ Line 1099: / Line 1102: @@
 ** {{wiki:ProtectedMethod.gif|}} RegisterCore(PointShape,PointShape,DistanceUnit,GeographyUnit) **
-This method returns a BaseShape which has been registered from its original coordinate system to another based on two anchor PointShapes.
+  * //This method returns a BaseShape which has been registered from its original coordinate system to another based on two anchor PointShapes.//
 == Remarks ==
-Registering allows you to take a geometric shape generated in a planar system and attach it to the ground in a Geographic Unit.A common scenario is integrating geometric shapes from external programs (such as CAD software or a modeling system) and placing them onto a map. You may have the schematics of a building in a CAD system and the relationship between all the points of the building are in feet. You want to then take the CAD image and attach it to where it really exists on a map. You would use the register method to do this.Registering is also useful for scientific modeling, where software models things such as a plume of hazardous materials or the fallout from a volcano. The modeling software typically generates these models in a fictitious planar system. You would then use the register to take the abstract model and attach it to a map with real coordinates.
+  * //Registering allows you to take a geometric shape generated in a planar system and attach it to the ground in a Geographic Unit.A common scenario is integrating geometric shapes from external programs (such as CAD software or a modeling system) and placing them onto a map. You may have the schematics of a building in a CAD system and the relationship between all the points of the building are in feet. You want to then take the CAD image and attach it to where it really exists on a map. You would use the register method to do this.Registering is also useful for scientific modeling, where software models things such as a plume of hazardous materials or the fallout from a volcano. The modeling software typically generates these models in a fictitious planar system. You would then use the register to take the abstract model and attach it to a map with real coordinates.//
 == Return Value ==
@@ Line 1127: / Line 1130: @@
 ** {{wiki:ProtectedMethod.gif|}} TranslateByOffsetCore(Double,Double,GeographyUnit,DistanceUnit) **
-This method moves the base shape from one location to another based on an X and Y offset distance.
+  * //This method moves the base shape from one location to another based on an X and Y offset distance.//
 == Remarks ==
-This method moves the base shape from one location to another based on an X and Y offset distance. It is important to note that with this overload the X and Y offset units are based off of the distanceUnit parameter. For example if your shape is in decimal degrees and you call this method with an X offset of one and a Y offset of one and you're going to move this shape one unit of the distanceUnit in the horizontal direction and one unit of the distanceUnit in the vertical direction. In this way you can easily move a shape in decimal degrees five miles to on the X axis and 3 miles on the Y axis.
+  * //This method moves the base shape from one location to another based on an X and Y offset distance. It is important to note that with this overload the X and Y offset units are based off of the distanceUnit parameter. For example if your shape is in decimal degrees and you call this method with an X offset of one and a Y offset of one and you're going to move this shape one unit of the distanceUnit in the horizontal direction and one unit of the distanceUnit in the vertical direction. In this way you can easily move a shape in decimal degrees five miles to on the X axis and 3 miles on the Y axis.//
 == Return Value ==
@@ Line 1155: / Line 1158: @@
 ** {{wiki:ProtectedMethod.gif|}} TranslateByDegreeCore(Double,Double,GeographyUnit,DistanceUnit) **
-This method moves the shape from one location to another based on a direction in degrees and distance.
+  * //This method moves the shape from one location to another based on a direction in degrees and distance.//
 == Remarks ==
-This method moves the base shape from one location to another, based on an angleInDegrees and distance parameter. With this overload, it is important to note that the distance units are the same GeographicUnit as the shape. For example, if your shape is in decimal degrees and you call this method with a distance of 1, you're going to move this shape 1 decimal degree in direction of the angleInDegrees. In many cases it is more useful to specify the DistanceUnit of movement, such as in miles or yards, so for these scenarios there is another overload you may want to use instead.If you pass a distance of 0, then the operation is ignored.
+  * //This method moves the base shape from one location to another, based on an angleInDegrees and distance parameter. With this overload, it is important to note that the distance units are the same GeographicUnit as the shape. For example, if your shape is in decimal degrees and you call this method with a distance of 1, you're going to move this shape 1 decimal degree in direction of the angleInDegrees. In many cases it is more useful to specify the DistanceUnit of movement, such as in miles or yards, so for these scenarios there is another overload you may want to use instead.If you pass a distance of 0, then the operation is ignored.//
 == Return Value ==
@@ Line 1183: / Line 1186: @@
 ** {{wiki:ProtectedMethod.gif|}} RotateCore(PointShape,Single) **
-This method rotates the shape a number of degrees based on a pivot point.
+  * //This method rotates the shape a number of degrees based on a pivot point.//
 == Remarks ==
-This method rotates the shape a number of degrees based on a pivot point. By placing the pivot point in the center of the shape, you can achieve in-place rotation. By moving the pivot point outside of the center of the shape, you can translate the shape in a circular motion. Moving the pivot point further outside of the center will make the circular area larger.
+  * //This method rotates the shape a number of degrees based on a pivot point. By placing the pivot point in the center of the shape, you can achieve in-place rotation. By moving the pivot point outside of the center of the shape, you can translate the shape in a circular motion. Moving the pivot point further outside of the center will make the circular area larger.//
 == Return Value ==
@@ Line 1203: / Line 1206: @@
 ** {{wiki:ProtectedMethod.gif|}} GetClosestPointToCore(BaseShape,GeographyUnit) **
-This method returns the point of the current shape that is closest to the target shape.
+  * //This method returns the point of the current shape that is closest to the target shape.//
 == Remarks ==
-This method returns the point of the current shape that is closest to the target shape. It is often the case that the point returned is not a point of the object itself. An example would be a line with two points that are far apart from each other. If you set the targetShape to be a point midway between the points but a short distance away from the line, the method would return a point that is on the line but not either of the two points that make up the line.
+  * //This method returns the point of the current shape that is closest to the target shape. It is often the case that the point returned is not a point of the object itself. An example would be a line with two points that are far apart from each other. If you set the targetShape to be a point midway between the points but a short distance away from the line, the method would return a point that is on the line but not either of the two points that make up the line.//
 == Return Value ==
@@ Line 1223: / Line 1226: @@
 ** {{wiki:ProtectedMethod.gif|}} GetBoundingBoxCore() **
-This method calculates the smallest RectangleShape that encompasses the entire geometry.
+  * //This method calculates the smallest RectangleShape that encompasses the entire geometry.//
 == Remarks ==
-The GetBoundingBox method calculates the smallest RectangleShape that can encompass the entire geometry by examining each point in the geometry. Depending on the number of PointShapes and complexity of the geometry, this operation can take longer for larger objects. If the shape is a PointShape, then the bounding box’s upper left and lower right points will be equal. This will create a RectangleShape with no area. Overriding: Please ensure that you validate the parameters being passed in and raise the exceptions defined above.
+  * //The GetBoundingBox method calculates the smallest RectangleShape that can encompass the entire geometry by examining each point in the geometry. Depending on the number of PointShapes and complexity of the geometry, this operation can take longer for larger objects. If the shape is a PointShape, then the bounding box’s upper left and lower right points will be equal. This will create a RectangleShape with no area. Overriding: Please ensure that you validate the parameters being passed in and raise the exceptions defined above.//
 == Return Value ==
@@ Line 1235: / Line 1238: @@
 ** {{wiki:ProtectedMethod.gif|}} GetDistanceToCore(BaseShape,GeographyUnit,DistanceUnit) **
-This method computes the distance between the current shape and the targetShape.
+  * //This method computes the distance between the current shape and the targetShape.//
 == Remarks ==
-None
+  * //None//
 == Return Value ==
@@ Line 1259: / Line 1262: @@
 ** {{wiki:ProtectedMethod.gif|}} GetWellKnownTextCore() **
-This method returns the well-known text representation of this shape.
+  * //This method returns the well-known text representation of this shape.//
 == Remarks ==
-This method returns a string that represents the shape in well-known text. Well-known text allows you to describe a geometry as a string of text. Well-known text is useful when you want to save a geometry in a format such as a text file, or when you simply want to cut and paste the text between other applications. An alternative to well-known text is well-known binary, which is a binary representation of a geometry object. We have methods that work with well-known binary as well. Below are some samples of what well-known text might look like for various kinds of geometric shapes.POINT(5 17)LINESTRING(4 5,10 50,25 80)POLYGON((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3))MULTIPOINT(3.7 9.7,4.9 11.6)MULTILINESTRING((4 5,11 51,21 26),(-4 -7,-9 -7,-14 -3))MULTIPOLYGON(((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3)),((4 4,7 3,7 5,4 4)))
+  * //This method returns a string that represents the shape in well-known text. Well-known text allows you to describe a geometry as a string of text. Well-known text is useful when you want to save a geometry in a format such as a text file, or when you simply want to cut and paste the text between other applications. An alternative to well-known text is well-known binary, which is a binary representation of a geometry object. We have methods that work with well-known binary as well. Below are some samples of what well-known text might look like for various kinds of geometric shapes.POINT(5 17)LINESTRING(4 5,10 50,25 80)POLYGON((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3))MULTIPOINT(3.7 9.7,4.9 11.6)MULTILINESTRING((4 5,11 51,21 26),(-4 -7,-9 -7,-14 -3))MULTIPOLYGON(((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3)),((4 4,7 3,7 5,4 4)))//
 == Return Value ==
@@ Line 1271: / Line 1274: @@
 ** {{wiki:ProtectedMethod.gif|}} GetWellKnownTypeCore() **
-This method returns the well-known type for the shape.
+  * //This method returns the well-known type for the shape.//
 == Remarks ==
-None
+  * //None//
 == Return Value ==
@@ Line 1283: / Line 1286: @@
 ** {{wiki:ProtectedMethod.gif|}} GetWellKnownBinaryCore(WkbByteOrder) **
-This method returns a byte array that represents the shape in well-known binary.
+  * //This method returns a byte array that represents the shape in well-known binary.//
 == Remarks ==
-This method returns a byte array that represents the shape in well-known binary. Well-known binary allows you to describe a geometry as a binary array. Well-known binary is useful when you want to save a geometry in an efficient format using as little space as possible. An alternative to well-known binary is well-known text, which is a textual representation of a geometry object. We have methods that work with well-known text as well.
+  * //This method returns a byte array that represents the shape in well-known binary. Well-known binary allows you to describe a geometry as a binary array. Well-known binary is useful when you want to save a geometry in an efficient format using as little space as possible. An alternative to well-known binary is well-known text, which is a textual representation of a geometry object. We have methods that work with well-known text as well.//
 == Return Value ==
@@ Line 1299: / Line 1302: @@
 ** {{wiki:ProtectedMethod.gif|}} LoadFromWellKnownDataCore(String) **
-This method hydrates the current shape with its data from well-known text.
+  * //This method hydrates the current shape with its data from well-known text.//
 == Remarks ==
-None
+  * //None//
 == Return Value ==
@@ Line 1315: / Line 1318: @@
 ** {{wiki:ProtectedMethod.gif|}} LoadFromWellKnownDataCore(Byte[]) **
-This method hydrates the current shape with its data from well-known binary.
+  * //This method hydrates the current shape with its data from well-known binary.//
 == Remarks ==
-This is used when you want to hydrate a shape based on well-known binary. You can create the shape and then load the well-known binary using this method.
+  * //This is used when you want to hydrate a shape based on well-known binary. You can create the shape and then load the well-known binary using this method.//
 == Return Value ==
@@ Line 1331: / Line 1334: @@
 ** {{wiki:ProtectedMethod.gif|}} ValidateCore(ShapeValidationMode) **
-This method returns a ShapeValidationResult based on a series of tests.
+  * //This method returns a ShapeValidationResult based on a series of tests.//
 == Remarks ==
-We use this method, with the simple enumeration, internally before doing any kind of other methods on the shape. In this way, we are able to verify the integrity of the shape itself. If you wish to test things such as whether a polygon self-intersects, we invite you to call this method with the advanced ShapeValidationMode. One thing to consider is that for complex polygon shapes this operation could take some time, which is why we only run the basic, faster test. If you are dealing with polygon shapes that are suspect, we suggest you run the advanced test.
+  * //We use this method, with the simple enumeration, internally before doing any kind of other methods on the shape. In this way, we are able to verify the integrity of the shape itself. If you wish to test things such as whether a polygon self-intersects, we invite you to call this method with the advanced ShapeValidationMode. One thing to consider is that for complex polygon shapes this operation could take some time, which is why we only run the basic, faster test. If you are dealing with polygon shapes that are suspect, we suggest you run the advanced test.//
 == Return Value ==
@@ Line 1347: / Line 1350: @@
 ** {{wiki:ProtectedMethod.gif|}} GetCrossingCore(BaseShape) **
-This method returns the crossing points between the current shape and the passed-in target shape.
+  * //This method returns the crossing points between the current shape and the passed-in target shape.//
 == Remarks ==
-As this is a concrete public method that wraps a Core method, we reserve the right to add events and other logic to pre- or post-process data returned by the Core version of the method. In this way, we leave our framework open on our end, but also allow you the developer to extend our logic to suit your needs. If you have questions about this, please contact our support team as we would be happy to work with you on extending our framework.
+  * //As this is a concrete public method that wraps a Core method, we reserve the right to add events and other logic to pre- or post-process data returned by the Core version of the method. In this way, we leave our framework open on our end, but also allow you the developer to extend our logic to suit your needs. If you have questions about this, please contact our support team as we would be happy to work with you on extending our framework.//
 == Return Value ==
@@ Line 1363: / Line 1366: @@
 ** {{wiki:ProtectedMethod.gif|}} GetShortestLineToCore(BaseShape,GeographyUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1383: / Line 1386: @@
 ** {{wiki:ProtectedMethod.gif|}} GetCenterPointCore() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1395: / Line 1398: @@
 ** {{wiki:ProtectedMethod.gif|}} BufferCore(Double,Int32,BufferCapType,GeographyUnit,DistanceUnit) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1427: / Line 1430: @@
 ** {{wiki:ProtectedMethod.gif|}} IsDisjointedCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1443: / Line 1446: @@
 ** {{wiki:ProtectedMethod.gif|}} IntersectsCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1459: / Line 1462: @@
 ** {{wiki:ProtectedMethod.gif|}} TouchesCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1475: / Line 1478: @@
 ** {{wiki:ProtectedMethod.gif|}} CrossesCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1491: / Line 1494: @@
 ** {{wiki:ProtectedMethod.gif|}} IsWithinCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1507: / Line 1510: @@
 ** {{wiki:ProtectedMethod.gif|}} ContainsCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1523: / Line 1526: @@
 ** {{wiki:ProtectedMethod.gif|}} OverlapsCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1539: / Line 1542: @@
 ** {{wiki:ProtectedMethod.gif|}} IsTopologicallyEqualCore(BaseShape) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1555: / Line 1558: @@
 ** {{wiki:ProtectedMethod.gif|}} ScaleToCore(Double) **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1571: / Line 1574: @@
 ** {{wiki:ProtectedMethod.gif|}} Finalize() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==
@@ Line 1583: / Line 1586: @@
 ** {{wiki:ProtectedMethod.gif|}} MemberwiseClone() **
-N/A
+  * //N/A//
 == Remarks ==
-N/A
+  * //N/A//
 == Return Value ==

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