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Calculus/Points, paths, surfaces, and volumes

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This chapter will provide an intuitive interpretation of vector calculus using simple concepts such as multi-points, multi-paths, multi-surfaces, and multi-volumes. Scalar fields will not be simply treated as a function that returns a number given an input point, and vector fields will not be simply treated as a function that returns a vector given an input point.


Basic structures

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The basic structures are multi-points, multi-paths, multi-surfaces, and multi-volumes.

Multi-points

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A point is an arbitrary position. A "multi-point" is a set of point/weight pairs: where is the "weight" that is assigned to point . Given two point/weight pairs and that cover the same point , the weights add up to get which replaces and . Any pair is removed. can consist of infinitely many points, and each point may have an infinitesimal weight.

An arbitrary point can be described by the scalar field . This is the "Dirac delta function" centered on point . The is the inverse of an infinitely small volume that wraps point . To further explain this, let be a tiny volume with volume that wraps point . can be approximated by . A mass of 1 is being crammed into yielding an infinitely high density. Since is essentially a density function, it brings with it the units .

Multi-point can be described by the scalar field . If consists of infinitely many points with each point having infinitesimal weight, then is a density function.

In the image below, the multi-point in the left panel is converted to the scalar field in the center panel by averaging the point weight over each cell. The volume of each cell should be infinitesimal. The multi-point in the right panel corresponds to the same scalar field, and is in a more canonical form where oppositely weighted points have cancelled out.

The multi-point (a collection of weighted points) on the left can be denoted by the scalar field in the middle. On the right is a more canonical multi-point with the same scalar field, where nearby points of opposite sign have cancelled out.

The image below shows how a continuous scalar field can be generated as a collection of points. Consider position and the infinitesimal volume with volume . The total point weight contained by is . This weight of is then split up over an arbitrarily large number of points that are scattered over the volume .

A single point of weight 1 can be "smeared out" over the volume that it sits in. The point is divided into an increasing number of points with fractional weights. After an infinite number of steps, there is an infinite number of points that fill the volume and each point has an infinitesimal weight.

In summary, a multi-point is denoted by a scalar field that quantifies the density at each point, and any scalar field that quantifies density at each point is best interpreted as a multi-point.

Multi-paths

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A simple path (also called a simple curve) is an oriented continuous curve that extends from a starting point to an ending point . Intermediate points are indexed by and are denoted by . A simple path should be continuous (no breaks), and may intersect or retrace itself. A "multi-path" is a set of simple-path/weight pairs: where is the weight that is assigned to path . Given two path/weight pairs and that cover the same path , the weights add up to get which replaces and . Any pair is removed. In addition given two path/weight pairs and with the same weight and , then and can be linked end-to-end to get the pair which replaces and . Assigning a path a negative weight effectively reverses its orientation: if denotes path with the opposite orientation, then is equivalent to . can consist of infinitely many paths, and each path may have an infinitesimal weight.

This image depicts the Dirac delta function of a simple path. Unlike the Dirac delta function for a point which is a scalar field, the Dirac delta function for a path is a vector field.

An arbitrary curve can be described by the vector field . This is the "Dirac delta function" for the curve . is the unit length tangent vector to path at point . if . If there are multiple tangent vectors due to intersecting itself, then is the sum of these tangent vectors. The is the inverse of the cross-sectional area of an infinitely thin tube that encloses . To further explain this, let be a thin tube with cross-sectional area that encloses . can be approximated by . is the generalization of to the tube . A path weight of 1 is being crammed into the cross-sectional area of yielding an infinitely high path density. Since is essentially a density over area, it brings with it the units .

The image to the right gives a depiction of the Dirac delta function for a simple curve. The vector field is everywhere outside of an infinitely thin tube that encloses the path. Inside the tube, the vectors are parallel to the path, and have a magnitude equal to the inverse of the cross-sectional area. The Dirac delta function is the limit as the tube becomes infinitely thin.

Multi-path can be described by the vector field . If consists of infinitely many paths with each path having infinitesimal weight, then is a flow density function.

In the image below, the multi-path in the left panel is converted to the vector field in the center panel by computing the total displacement in each cell and averaging over the volume. The volume of each cell should be infinitesimal. The multi-path in the right panel corresponds to the same vector field, and is in a more canonical form where the individual paths do not cross each other.

The multi-path (a collection of weighted paths) on the left can be denoted by the vector field in the middle (in generating the vector field, each path was approximated to enter each cell through the middle of an edge). On the right is a more canonical multi-path with the same vector field, where nearby path segments with opposite orientations have cancelled out, and the individual paths do not cross each other.

In summary, a multi-path is denoted by a vector field that quantifies the path/flow density at each point, and any vector field that quantifies a flow density at each point (such as current density) is best interpreted as a multi-path. (Flow density is a vector that points in the net direction of a flow, and has a length equal to the flow rate per unit area through a surface that is perpendicular to the net flow.)

Multi-surfaces

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A simple surface is an oriented continuous surface. A simple surface may intersect or fold back on itself. A "multi-surface" is a set of simple-surface/weight pairs: where is the weight that is assigned to surface . Given two surface/weight pairs and that cover the same surface , the weights add up to get which replaces and . Any pair is removed. In addition given two surface/weight pairs and with the same weight , then and can be combined to get the pair which replaces and . Assigning a surface a negative weight effectively reverses its orientation: if denotes surface with the opposite orientation, then is equivalent to . can consist of infinitely many surfaces, and each surface may have an infinitesimal weight.

An arbitrary surface can be described by the vector field . This is the "Dirac delta function" for the surface . is the unit length normal vector to surface at point . if . If there are multiple normal vectors due to intersecting itself, then is the sum of these normal vectors. The is the inverse of the thickness of an infinitely thin membrane that encloses . To further explain this, let be a thin membrane with thickness that encloses . can be approximated by . is the generalization of to the membrane . A surface weight of 1 is being sandwiched into the thickness of yielding an infinitely high surface density. Since is essentially a density over length, it brings with it the units .

Multi-surface can be described by the vector field . If consists of infinitely many surfaces with each surface having infinitesimal weight, then is a rate-of-gain function.

In the image below, the multi-surface in the left panel is converted to the vector field in the center panel by computing the total surface in each cell and averaging over the volume. The volume of each cell should be infinitesimal. The multi-surface in the right panel corresponds to the same vector field, and is in a more canonical form where the individual surfaces do not intersect each other.

The multi-surface (a collection of weighted surfaces) on the left can be denoted by the vector field in the middle (in generating the vector field, each surface was approximated to intersect the edge of each square in the middle). On the right is a more canonical multi-surface with the same vector field, where nearby surface segments with opposite orientations have cancelled out, and the individual surfaces do not intersect.

In summary, a multi-surface is denoted by a vector field that quantifies the rate of gain at each point. To describe the rate-of-gain, imagine that passing through a surface in the preferred direction gives "energy". The rate of gain is a vector that points in the direction that yields the greatest rate of energy increase per unit length, and has a length equal to the maximum rate of energy increase per unit length. Any vector field that quantifies a rate of gain at each point (such as a force field) is best interpreted as a multi-surface.

Multi-volumes

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A volume is an arbitrary region of space. A "multi-volume" is a set of volume/weight pairs: where is the "weight" that is assigned to volume . Given two volume/weight pairs and that cover the same volume , the weights add up to get which replaces and . Any pair is removed. In addition given two volume/weight pairs and with the same weight and , then and can be combined to get the pair which replaces and . can consist of infinitely many volumes, and each volume may have an infinitesimal weight.

An arbitrary volume can be described by the scalar field . This is the "Dirac delta function" analog for volumes, and is essentially an indicator function that indicates whether or not a position is contained by or not, 1 being yes and 0 being no. Since is simply an indicator function, it brings with it no units (it is dimensionless).

Multi-volume can be described by the scalar field . If consists of infinitely many volumes with each volume having infinitesimal weight, then is a potential function.

In the image below, the multi-volume in the left panel is converted to the scalar field in the center panel by averaging the volume weight in each cell. The volume of each cell should be infinitesimal. The multi-volume in the right panel corresponds to the same scalar field, and is in a more canonical form where oppositely weighted volumes have cancelled out, and the remaining volume has diffused to fill each cell.

The multi-volume (a collection of weighted volumes) on the left can be denoted by the scalar field in the middle (in generating the scalar field, the beveled corners of each volume where ignored). On the right is a more canonical multi-volume with the same scalar field, where volumes of opposite sign have cancelled out, and the remaining volume is smeared out to fill each cell.

In summary, a multi-volume is denoted by a scalar field that quantifies a potential at each point, and any scalar field that quantifies a potential at each point is best interpreted as a multi-volume.

At infinity

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An important requirement is that all multi-points, multi-paths, multi-surfaces, and multi-volumes not extend to infinity. All structures can extend to an arbitrarily large range, as long as this range is not unbounded. Allowing the structures to extend to infinity will cause problems in the later discussions.

Paths that extend to infinity are generally not allowed for most theorems related to vector calculus.
Surfaces that extend to infinity are generally not allowed for most theorems related to vector calculus.
Volumes that extend to infinity are generally not allowed for most theorems related to vector calculus.

Totals

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These sections will describe the total weight of multi-points, the total displacement of multi-paths, the total surface of multi-surfaces, and the total volumes of multi-volumes.

Total point weight

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Given a multi-point , the total point weight is clearly . Given a scalar field that denotes a multi-point, the total weight of is . Given a simple point , the total weight is 1 so .

Total displacement

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The displacement between two points is independent of the path that connects them.

Given a simple path that starts at point and ends at point , the total displacement generated by is . This displacement is solely dependent on the endpoints as indicated by the top image to the right.

The displacement generated by a closed loop is .

Given a multi-path , the total displacement generated by is .

Given a vector field that denotes a multi-path, the total displacement generated by is . Since the displacement generated by a simple path is , it is the case that .

A path integral can be converted to a volume integral be replacing the displacement differential dq with the shown expression that is proportional to the volume differential dV. As is shown, the path is diffused to fill a thin tube. The integrand of the volume integral at all points outside of this thin tube is 0.

One important observation from is that given a path integral over path , the differential is equal to in a volume integral: provided that function is linear in the second parameter. In the lower image to the right, the displacement differential is equated to the volume differential by diffusing the path over an infintely thin cross-sectional area . The integrand at points outside of the infinitely thin tube is 0: for all points , .

Total surface vector

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A flat surface with area "A", a counter-clockwise boundary denoted by the arrows, and an orientation out of the plane is depicted by this image. Normal vector "n" has a length of 1, is perpendicular to the surface, and is oriented out of the plane as shown. The surface itself can be described by the vector "A n". The length is the area, and the direction is the orientation.

Given an arbitrary oriented surface , its "counter-clockwise boundary", denoted by , is the boundary of whose orientation is determined in the following manner: Looking at so that the preferred direction through is oriented towards the viewer, the boundary wraps in a counter-clockwise direction.

Given a flat surface as shown in the image to the right, this surface can be quantified by the "surface vector" which is a vector that is perpendicular (normal) to the surface in the preferred orientation, and has a length equal to the area of the surface. In the image to the right, a flat surface has an area of and is oriented to be perpendicular to unit-length normal vector . The "surface vector" of this surface is .

Given a non-flat surface , the total surface vector of is computed by summing the surface vectors of each infinitesimal portion of . The total surface vector is .

In a manner similar to how the total displacement of a path is solely a function of the endpoints, the total surface vector of a surface is solely a function of its counter-clockwise boundary. This is not intuitive, and will be explained in greater detail below using two approaches:

Two different surfaces are shown. Both surfaces have identical counter-clockwise boundaries, and because of this, the "total surface vector" for each surface are the same. Similar to how the total displacement along a path is purely a function of its endpoints, the total surface vector of a surface is purely a function of its boundary.

Generalizing from surfaces in 2D space

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Below are shown two images related to surface vectors in 2D space. The image to the left shows surface vectors in 2D space. In 2 dimensions, surfaces are called 1D surfaces and are similar to paths. The boundary of a 1D surface consists of 2 points. The surface vector of a 1D surface segment is a 90 degree rotation of the segment and is oriented in the direction of the surface's orientation. The total surface vector of a 1D surface is the sum of all of the surface vectors of the individual components. For each component of the surface, the surface vector is a 90 degree rotation of the displacement that traverses the component, so the total surface vector is a 90 degree rotation of the displacement between the points that form the boundary of the surface. This proves that in two dimensions, the total surface vector depends only on the boundary of the 1D surface.

The image to the right extrudes the 1D surfaces in two dimensional space into 2D "ribbons" in 3 dimensional space. At the top a closed "ribbon" is shown. This "ribbon" is a surface that is always parallel to the vertical dimension, and whose boundary forms two identical loops that are vertically displaced from each other. The boundary loops are also perpendicular to the vertical dimension. The ribbon itself is partitioned into tiny rectangles whose height is equal to that of the ribbon. To the bottom left, a view of the same ribbon from the top down is shown. It can be seen that the length of the each surface vector is proportional to the length of the corresponding rectangular segment, since the heights are all uniform. To the bottom right, by rotating the surface vectors 90 degrees around the vertical dimension, the surface vectors now sum to , so the sum of the unrotated surface vectors is also .

This image depicts how in 2 dimensions, the total surface vector of a 1D surface is a 90 degree rotation of the displacement between the two endpoints (the boundary of a 1D surface), and is therefore purely a function of the endpoints. In the left panel, a 1D surface is a sequence of black line segments, and the surface vectors of each segment are denoted by the dashed red arrows. Each surface vector is a 90 degree rotation of the displacement along the surface. The long grey line is the net displacement between the endpoints of the surface, and the dashed pink arrow is a 90 degree rotation of this net displacement. In the right panel, the pink arrow is shown as the sum of the dashed red arrow vectors, hence the "total surface" is purely a function of the 1D surface's endpoints.
This image demonstrates that the total surface vector of a surface that is a closed ribbon is 0. The top image shows a surface that is a closed ribbon where the width of the ribbon is constant, the width is always parallel to the vertical dimension, and the edge is always perpendicular to the vertical dimension. The surface is sub-divided into tiny rectangular portions, the surface vectors of which are shown. The lower-left image shows the same surface from a top down perspective. In the lower-right image, the surface vectors are all rotated 90 degrees counter-clockwise around the vertical dimension and clearly sum to 0.

The fact that the total surface vector of a closed ribbon is means that if relief is added to a surface without changing its boundaries, the total surface vector is conserved. The two left images below give examples of distorting the interior of a surface by hammering in relief. The vertical surfaces introduced by the relief are ribbons which contribute to the total surface vector, while the horizontal surfaces are simply displaced vertically be the relief. The rightmost image below shows how the total surface vector is preserved if the "texture" of the surface at infinitesimal scales is converted from "steps" (a union of horizontal and vertical surfaces) to "smooth slopes" and vice versa. The surface formed from the red and green planes is a step, while the surface formed from the blue plane is a slope. These two surfaces can be seen to have equal total surface vectors from the right-angled triangle at the right side of the image.

Adding elevation (depression in this image) or relief to a surface does not change the total surface vector. The red colored horizontal surfaces are clearly conserved, albeit at different elevations. The green colored vertical surfaces sum to 0 at each tier/elevation.
Adding elevation (depression in this image) or relief to a surface does not change the total surface vector. The horizontal surfaces are clearly conserved, albeit at different elevations. The green colored vertical surfaces sum to their initial value above the lower red surface, and sum to 0 beneath the lower red surface.
In this image there are two surfaces. The first surface is the union of the red and green planes, and the counter-clockwise boundary is shown by the thick black line. The second surface is the blue plane and the counter-clockwise boundary is shown by the dashed blue line. The surface vectors of the red, green, and blue planes are shown. The total surface vector of the first surface is the sum of the surface vectors of the red and green planes, and is equal to the surface vector of the blue plane. This all implies that the total surface vector of a sloped flat surface is unchanged by replacing the surface with its horizontal and vertical components (projections).

Generalizing from displacement vectors

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The total displacement along a simple oriented curve can be used to compute the net displacement in a specific direction. Given a simple oriented curve and an oriented straight line with the direction indicated by normal vector , the total displacement along can be used to compute the net displacement in the direction indicated by the line. This displacement is , and depends only on the endpoints of the curve.

In a direct analogy, given a simple oriented surface with counter-clockwise boundary , and an oriented flat plane whose surface normal is , a quantity of interest is the total signed area of perpendicularly projected onto the plane. The signed area that is projected by a flat infinitesimal portion of with surface vector is , and the total signed area is where is the total surface vector of .

The total signed projected area onto the plane is purely a function of the boundary , and does not depend on how fills its boundary . This is much more obvious and clearer than the claim that the total surface vector is only a function of : the area enclosed by a boundary in 2D space is purely a function of that boundary. Since the projected area is signed, "upside down" surfaces project negative area, and folds and overhangs cancel each other out.

Since is purely a function of for all choices of plane orientation , then the total surface vector is purely a function of .

Given an arbitrary oriented path, the total displacement covered by the perpendicularly projected path onto an oriented straight line does not depend on the placement of the interior points of the path. The displacement only depends on the endpoints. Since this is true no matter the choice of straight line, the total 3D displacement vector generated by an oriented curve is purely a function of its endpoints, and does not change if the interior points are moved.
The total signed area of the projection of an oriented surface onto an oriented flat plane depends only on the boundary and not on any of the interior points. The "shadow" does not change if the interior points are moved around. If the surface is deformed so that there is an "overhang" where some projected points fall outside of the projected boundary, such as in the example of the right, these points cancel out with the points on the opposite side (top or bottom) of the overhang. An upside down surface projects negative area, and in the example on the right, all negative projected area is cancelled out with the positive area projected by the upright surface on top of the overhang.
Computing the signed projected area of a flat surface onto a flat plane is equivalent to computing the signed projected length of the surface vector onto the line that is perpendicular to the plane.

Summary

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The total surface vector generated by a closed surface is .

Given a multi-surface the total surface vector generated by is .

Given a vector field that denotes a multi-surface, the total surface vector generated by is . Since the surface vector generated by simple surface is , it is the case that . One important observation is that given a surface integral over , the differential is equal to in a volume integral: provided that function is a linear in the second parameter.

Total volume

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Consider a multi-volume , where the volumes of are respectively , then the total volume of is . Each volume can be computed by . The total volume of is .

If a multi-volume can be denoted by scalar field , then the volume of is .

Given an arbitrary volume , a volume integral over can be converted to a volume integral over by replacing the differential with :

provided that is linear in the second parameter.

Intersections

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The union of two multi-points denoted by scalar fields and is simply , and the same is true for the union of two multi-paths, the union of two multi-surfaces, and the union of two multi-volumes. The union of two structures with different types, such as a multi-point with a multi-path, is forbidden however.

Unions
structure multi-point multi-path multi-surface multi-volume
multi-point multi-point n/a n/a n/a
multi-path n/a multi-path n/a n/a
multi-surface n/a n/a multi-surface n/a
multi-volume n/a n/a n/a multi-volume

The intersection on the other hand, is less trivial and can occur between structures of different types.

Point-Volume intersections

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When a point with weight intersects a volume with weight , then the intersection is point with weight . Given a multi-point and a multi-volume, the intersection is the sum of the pair-wise intersections of each simple point with each simple volume. The image below gives an example of the intersection of a multi-point with a multi-volume.

The left panel depicts both a multi-point and a multi-volume. The right panel depicts the intersection between the multi-point and the multi-volume, which is itself a multi-point. Note that points that intersect a volume with weight -1 have their weights flipped to their negative.

Given a multi-point with scalar field , and a multi-volume with scalar field , then the intersection is a multi-point with scalar field .

The total intersection between a multi-point and a multi-volume is .

If denotes a simple point , then the total intersection is .

If denotes a simple volume , then the total intersection is .

Path-Surface intersections

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When a path with weight intersects a surface with weight at point , then the intersection is point with weight . The weight is if passes through in the direction in which is oriented. The weight is if passes through opposite the direction in which is oriented. Given a multi-path and a multi-surface, the intersection is the sum of the pair-wise intersections of each simple path with each simple surface. The images below give examples of the intersections of a multi-path with a multi-surface.

A 2D image showing the intersection of a multi-path (dark blue dashed curves) with a multi-surface (dark red solid curves). Positive intersection points (red circles) occur when a path intersects a surface in the preferred direction. Negative intersection points (teal circles) occur when a path intersects a surface in the opposite direction. The intersection is effectively a multi-point.
A 3D image showing the intersection of a simple path (red curve) with a simple surface (green surface with the counter-clockwise boundary highlighted). The positive intersection points are denoted by red "+" signs, and the negative intersection points are denoted by blue "-" signs.
The intersection between a multi-path shown as a blue tube with a multi-surface shown as layers of red sheets. Vector F is the flow density through the blue tube. Vector G is the surface density in the red sheets. The green parallelogram is a 2D projection of the volume of the intersection. The intersection points become more dilute as the angle theta increases, so the intersection point density is the dot product of F and G.

In the image above to the far right, the multi-path is denoted by a vector field which has the value inside the blue tube, and is everywhere else. The multi-surface is denoted by a vector field which has the value among the red sheets, and is everywhere else. The total path weight in the blue tube is . The total surface weight in the red sheets is . The total weight of all the intersection points is . The volume that the intersection points are evenly spread out in is . The intersection point density is .

Given a multi-path with vector field , and a multi-surface with vector field , then the intersection is a multi-point with scalar field .

The total intersection between a multi-path and a multi-surface is .

If is a simple path , then the total intersection is .

If is a simple surface , then the total intersection is .

Path-Volume intersections

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When a path with weight intersects a volume with weight , then the intersection is path with weight . Given a multi-path and a multi-volume, the intersection is the sum of the pair-wise intersections of each simple path with each simple volume. The image below gives an example of the intersection of a multi-path with a multi-volume.

The left panel depicts both a multi-path and a multi-volume. The right panel depicts the intersection between the multi-path and the multi-volume, which is itself a multi-path. Note that the path's orientation is reversed in the negatively weighted volumes. In addition, the path segment in the weight 2 volume region in the middle has a weight of 2 as indicated by the thicker line.

Given a multi-path with vector field , and a multi-volume with scalar field , then the intersection is a multi-path with vector field .

The total intersection between a multi-path and a multi-volume is .

If denotes a simple path , then the total intersection is .

If denotes a simple volume , then the total intersection is .

Surface-Surface intersections

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When a surface with weight intersects a surface with weight , then the intersection is the path with weight . The orientation given to path is defined as follows: viewing the intersection where the surface normal vectors of and are oriented towards the viewer, the intersection path has to its right, and to its left. Put another way, the intersection path is oriented according to the "right-hand rule" where the surface normals of are the "x" direction, and the surface normals of are the "y" direction. The images below give examples of the intersections of a multi-surface with a multi-surface.

A 3D image that shows the intersection of 2 surfaces. Surface 1 is blue and the normal vectors are oriented upwards. Surface 2 is red and the normal vectors are oriented to the right. The intersection is the black curve. The orientation of the intersection curve is determined via the right-hand rule with the surface normals of surface 1 as the "x" direction, and the surface normals of surface 2 as the "y" direction.
The intersection between two multi-surfaces. The first multi-surface is the layered blue sheets, and the second multi-surface is the layered red sheets. Vector F is the surface density in the blue sheets. Vector G is the surface density in the red sheets. The green parallelogram is a 2D cross-section of the prism that forms the intersection. The intersection paths become more dilute the further angle theta deviates from 90 degrees, so the intersection path density is the cross product of F and G. The intersection paths are also oriented out of the screen in this example.

In the image above to the right, the first multi-surface is denoted by a vector field that has the value among the blue sheets, and is everywhere else. The second multi-surface is denoted by a vector field that has the value among the red sheets, and is everywhere else. The total surface weight in the blue sheets is , and the total surface weight in the red sheets is . The total weight of all the intersection paths is . The cross-sectional area that the intersection paths are evenly spread out over is . The intersection path density is . Lastly, it should be noted that the intersection paths are oriented out of the screen as per the right-hand rule.

Given a multi-surface with vector field , and a multi-surface with vector field , then the intersection is the multi-path with vector field .

The total intersection between multi-surface and multi-surface is .

If denotes a simple surface , then the total intersection is .

Surface-Volume intersections

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When a surface with weight intersects a volume with weight , then the intersection is surface with weight . Given a multi-surface and a multi-volume, the intersection is the sum of the pair-wise intersections of each simple surface with each simple volume. The image below gives an example of the intersection of a multi-surface with a multi-volume.

The left panel depicts both a multi-surface and a multi-volume. The right panel depicts the intersection between the multi-surface and the multi-volume, which is itself a multi-surface. Note that the surface's orientation is reversed in the negatively weighted volume. In addition, the surface segment in the weight 2 volume region in the upper-left has a weight of 2 as indicated by the thicker line.

Given a multi-surface with vector field , and a multi-volume with scalar field , then the intersection is a multi-surface with vector field .

The total intersection between a multi-surface and a multi-volume is .

If denotes a simple surface , then the total intersection is .

If denotes a simple volume , then the total intersection is .

Volume-Volume intersections

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When a volume with weight intersects a volume with weight , then the intersection is the volume with weight . Given two multi-volumes, the intersection is the sum of the pair-wise intersections of each simple volume from the first multi-volume with each simple volume from the second multi-volume. The image below gives an example of the intersection between two multi-volumes.

The left two panels each depict a multi-volume, and the rightmost panel depicts the intersection of the two multi-volumes. The weight of the intersection of two simple volumes is the product of the weight of the two volumes.

Given a multi-volume with scalar field , and a multi-volume with scalar field , then the intersection is a multi-volume with scalar field .

The total intersection between multi-volume and multi-volume is .

If denotes a simple volume , then the total intersection is .

Other intersections

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Other types of intersections, such as Point-Point intersections, Point-Path intersections, Point-Surface intersections, and Path-Path intersections, are not considered since these kinds of intersections can occur only by design. For example, the probability that two randomly chosen points will intersect each other is 0, but if a point and a volume are randomly chosen, then the probability of the point landing in the volume is nonzero. Given two unrelated points, these two points will never land on each other, since a prior relationship has to exist for the points to coincide. Below is summarized the various types of intersections:

Intersections
structure multi-point multi-path multi-surface multi-volume
multi-point n/a n/a n/a multi-point
multi-path n/a n/a multi-point multi-path
multi-surface n/a multi-point multi-path multi-surface
multi-volume multi-point multi-path multi-surface multi-volume

Boundaries

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The endpoints of paths

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Given a simple path that starts at point and ends at point , the "endpoints" of is the multi-point that consists of the starting point with a weight of +1, and the final point with a weight of -1. While is denoted by the vector field , the endpoints are denoted by the scalar field . The image below gives several examples of simple paths and their associated endpoints.

A series of panels, each depicting a directed path and its endpoints. The endpoints of a path consists of a positively weighted point at the start and a negatively weighted point at the end.

Given a multi-path , the endpoints of is the multi-point .

Given a vector field that denotes a multi-path, the multi-point that denotes the endpoints of is denoted by scalar field . The scalar field evaluated at point is denoted by , or .

The requirement that no path extends to infinity means that every starting point is paired with a final point, and therefore the total weight of all of the endpoints together is 0: .

The path endpoints are the intersections of the path with the "surface of reality".

The similarity of the notation to the intersection of multi-path with multi-surface , denoted by , makes sense if is interpreted as the "surface of reality". A starting point forms when a path pokes into reality, and a final point forms when a path pokes out of reality.

In the image to the right, a depiction of the "surface of reality" interpretation of is shown. On the right is a simple path , along with its endpoints . On the left is an extension of that is behind the "veil" of surface . pokes out of and into at points consistent with the endpoints of : i.e. .

The counter-clockwise oriented boundaries of surfaces

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Given an oriented surface , the "counter-clockwise oriented boundary" of is a path that traces the boundary of in a counter-clockwise direction. The counter-clockwise direction is better described as follows: While located on the boundary, the counter-clockwise direction is the "forwards" direction when the surface normal vectors point "up" and the surface itself is on the "left". The image below gives several examples of oriented surfaces and their counter-clockwise boundaries. Note in particular the 4th panel that shows that the orientation around a hole in the surface appears to be clockwise.

A series of panels, each depicting an oriented surface and its counterclockwise oriented boundary. The surface normal vectors are depicted by the red arrows.

Given a multi-surface , the counter-clockwise boundary of is the multi-path .

Given a vector field that denotes a multi-surface, the multi-path that denotes the counter-clockwise boundary of is denoted by vector field . The vector field evaluated at point is denoted by , , or .

The requirement that no surface weight extends to infinity means that all counter-clockwise boundaries form closed loops, and therefore the total displacement of the total counter-clockwise boundary is : .

It is also important to note that the counter-clockwise boundary has no endpoints: .

The boundary of a surface is analogous to the intersection of the surface with the "surface of reality".

The similarity of the notation to the intersection of multi-surface with multi-surface , denoted by , again makes sense if is interpreted as the "surface of reality". An edge is formed when a surface "slices" into reality.

In the image to the right, a depiction of the "surface of reality" interpretation of is shown. On the right is a simple surface , along with its counter-clockwise boundary . On the left is an extension of that is behind the "veil" of surface . slices into at curves consistent with the boundary of : i.e. .

The inwards-oriented surfaces of volumes

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Given a volume , the "inwards oriented surface" of is a surface that wraps the volume with the surface normals pointing inwards. The image below gives several examples of volumes and their inwards oriented surfaces.

A series of panels, each depicting a volume and its inwards oriented surface. The inwards orientation of the surface is indicated by the red arrows pointing inwards.

Given a multi-volume , the inwards oriented surface of is the multi-surface .

Given a scalar field that denotes a multi-volume, the multi-surface that denotes the inwards oriented surface of is denoted by vector field . The vector field evaluated at point is denoted by , , or .

The requirement that no volume weight extends to infinity means that all inwards oriented surfaces form closed surfaces, and therefore the total surface vector of the total inwards oriented surface is : .

It is also important to note that the inwards oriented surface has no boundary: .

In this 2D cross-section, the surface of a volume is analogous to the intersection of the volume with the "surface of reality".

The similarity of the notation to the intersection of multi-surface with multi-volume , denoted by , again makes sense if is interpreted as the "surface of reality". A surface is formed from the surface of reality when the volume "pushes" into reality.

In the image to the right, a depiction of the "surface of reality" interpretation of is shown. The image is a 2D cross-section for simplicity. On the right is a simple volume , along with its inwards oriented surface . On the left is an extension of that is behind the "veil" of surface . pushes through at surfaces consistent with the surface of : i.e. .

Closed loops and closed surfaces

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A simple path is "closed" or a "loop" if its starting and final points are the same, so the total endpoints is 0 since the weights of the starting and final points cancel out. More generally, a multi-path is "closed" or a "multi-loop" if . As previously noted, the counter-clockwise boundary of a surface is closed.

A simple surface is "closed" or a "bubble" if it has no boundary. More generally, a multi-surface is "closed" or a "multi-bubble" if . As previously noted, the inwards oriented surface of a volume is closed.

It is clear that the total displacement present in a closed multi-path is : , and it is also clear that the total surface vector of a closed multi-surface is also : .

Given a simple loop and simple bubble, the number of times that the loop enters the bubble is equal to the number of times that the loop leaves the bubble.

Given both a simple loop and a simple bubble, the total point weight of all intersection points is 0: every time the loop enters the bubble, it must also leave the bubble, and the weights of these two intersection points cancel out. More generally, given a closed multi-path and a closed multi-surface , then the total intersection point weight is 0: .

The above identity gives rise to the following observations:

  • The total intersection point weight of a multi-loop and a multi-surface is purely a function of the multi-loop and the multi-surface's counter-clockwise boundary: the interior of the multi-surface does not matter. If and , then .
  • The total intersection point weight of a multi-path and a multi-bubble is purely a function of the multi-bubble and the multi-path's endpoints: the interior of the multi-path does not matter. If and , then .

The inwards oriented surface of a volume is closed. Conversely, given a closed surface, there exists a volume that "fills" the surface. More generally, given a multi-bubble , there exists a multi-volume for which is the inwards oriented multi-surface of : . This multi-volume is referred to as the "scalar potential" of . The requirement that volumes cannot extend to infinity means that is unique.

The counter-clockwise oriented boundary of a surface is closed. Conversely, given a loop, there exists a surface that "fills" the loop. More generally, given a multi-loop , there exists a multi-surface for which is the counter-clockwise boundary of : . This multi-surface is referred to as the "vector potential" of . Even with the requirement that surfaces cannot extend to infinity, is not unique without additional restrictions.

Coordinate Systems

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This image depicts a generalized coordinate lattice at the top. At the bottom of the image is a single volume element with the basis displacement (contravariant) vectors, alongside the basis surface (covariant) vectors.

This section will describe how to compute various quantities such as intersections, endpoints, boundaries, and surfaces given a curvilinear coordinate system.

Let the curvilinear coordinate system be arbitrary. Let the 3 coordinates that index all points be . Coordinates will be denoted by the triple .

The following notation will be used in the following discussions:

  • Given an arbitrary expression that assigns a real number to each index , then will denote the triple .
  • Given index variables , the expression equals 1 if and 0 if otherwise.
  • Given an arbitrary expression that assigns a real number to each index , then will denote the sum .
  • Given an index variable , will rotate forwards by 1, and will rotate forwards by 2. In essence, and .

Start with an arbitrary coordinate and infinitesimal differences , , and . The following 3 paths, 3 surfaces, and volume will be associated with point :

  • For each there exists an infinitely short path starting from point and ending on point along the curve defined by , and . The displacement covered by is approximately where is a unit length vector that is parallel to the displacement between points and , and is the length of the displacement. Note that the length of the displacement is proportional to , with being the constant of proportionality. The set of vectors is the set of displacement basis vectors.
  • For each there exists an infinitely small surface that is defined by the following: , , and . The orientation of is in the direction of increasing . The surface vector of is approximately where is a unit length vector that is perpendicular to , and is the area of . Note that the area of is proportional to , with being the constant of proportionality. The set of vectors is the set of surface basis vectors.
  • There is an infinitely small volume defined by , , and . has a shape that is approximately that of a parallelepiped. The volume of is approximately . Note that the volume of is proportional to , with being the constant of proportionality.

It is important to note that:

  • if and only if , , and (note the strictness of the upper bounds).
  • For all , if and only if , , and (note the strictness of the upper bounds).
  • For all , if and only if (note the strictness of the upper bound), , and .

Converting between multi-points, multi-paths, multi-surfaces, and multi-volumes and their respective scalar fields and vector fields proceeds as follows:

This conversion is performed by subdividing space into discrete volumes or cells. Infinitesimal differences , , and are chosen, and a lattice consisting of the points where is an arbitrary triple of integers is generated. The cell indexed by consists of the point , the paths for each , the surfaces for each , and the volume . All points where for all "belong" to the cell indexed by (note that the upper bounds are excluded). Given an arbitrary point , the cell that contains is indexed by . The point is the vertex that the cell is associated with.

A multi-point, multi-path, multi-surface, or multi-volume is converted to a scalar field or vector field by computing the total point weight, displacement, surface vector, or volume contained by each cell and then averaging over the cell's volume.

A scalar-field is converted to a multi-point by doing the following for each cell . First compute the total point weight contained inside the cell: . Next assign this weight to the point .

A vector-field is converted to a multi-path by doing the following for each cell . First compute the total displacement contained inside the cell: . Next separate this total displacement into components according to the basis , , and : for each the coefficient of is . Next for each , divide the coefficient of by the length of , which results in approximately , and assign this weight to .

A vector-field is converted to a multi-surface by doing the following for each cell . First compute the total surface vector contained inside the cell: . Next separate this total surface vector into components according to the basis , , and : for each the coefficient of is . Next for each , divide the coefficient of by the area of , which results in approximately , and assign this weight to .

A scalar-field is converted to a multi-volume by doing the following for each cell . First compute the total volume contained inside the cell: . Next divide this weight by the volume of , which results in approximately , and assign this weight to .

Computing various intersections

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Computing the intersection of any structure with a multi-volume is trivial matter: Simply multiply the scalar of vector field by the scalar field that denotes the multi-volume. When both structures are denoted by vector fields however, computing the intersection is far less trivial.

Computing path-surface intersections

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To save space, the notation and will be omitted from the various terms.

Given a multi-path denoted by vector field , and a multi-surface denoted by vector field , the scalar field that denotes the intersection can be computed as follows:

The following computations applies to each cell:

For each , the weight assigned to by is computed as follows: is the component of the total displacement contained by the current cell. Computing the weight assigned to requires that this displacement be spread over the length of : .

For each , the weight assigned to by is computed as follows: is the component of the total surface vector contained by the current cell. Computing the weight assigned to requires that this surface vector be spread over the area of : .

The intersection between and is the current lattice point with weight .

Aside from the intersections between and for each cell and , no other intersections occur. The total weight of the intersection at the vertex of the current cell is .

The value of at the current cell is approximately . The coefficient of exists to spread the point weight over the current cell.

Therefore . Note that is expressed using the displacement basis vectors, while is expressed using the surface basis vectors.

Computing surface-surface intersections

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To save space, the notation and will be omitted from the various terms.

Given a multi-surface denoted by vector field , and a multi-surface denoted by vector field , the vector field that denotes the intersection can be computed as follows:

The following computations applies to each cell:

For each , the weight assigned to by is computed as follows: is the component of the total surface vector contained by the current cell. Computing the weight assigned to requires that this surface vector be spread over the area of : . Similarly, the weight assigned to by is .

The intersection between and is path with weight . Conversely, the intersection between and is path with weight .

Aside from the intersections between and , and the intersections between and , for each cell and , no other intersections occur. For each , the total weight assigned to is .

The value of at the current cell is approximately . The coefficient of exists to spread the displacement of each path over the current cell.

Therefore . Note that both and are both expressed using the surface basis vectors, but is using the displacement basis vectors.

Computing the endpoints of paths

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To save space, the notation , , and will be omitted from the various terms. However, given a quantity and an arbitrary , the notation will denote the quantity in the adjacent cell by moving back one step along the dimension indexed by . This cell will be referred to as the neighbor of the current cell.

Given a multi-path denoted by vector field , the scalar field that denotes the endpoints can be computed as follows:

The following computations apply to each cell:

For each , the weight assigned to by is computed as follows: is the component of the total displacement contained by the current cell. Computing the weight assigned to requires that this displacement be spread over the length of : .

For each , path contributes a weight of to the lattice point of the current cell, and path contributes a weight of to the lattice point of the current cell.

The total weight assigned to the lattice point of the current cell is .

Spreading the weight assigned to the current lattice point over the volume of the current cell gives: .

Therefore: . Note that is expressed using the displacement basis vectors.

Computing the counter-clockwise boundaries of surfaces

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To save space, the notation , , and will be omitted from the various terms. However, given a quantity and an arbitrary , the notation will denote the quantity in the adjacent cell by moving back one step along the dimension indexed by . This cell will be referred to as the neighbor of the current cell.

Given a multi-surface denoted by vector field , the vector field that denotes the counter-clockwise boundary can be computed as follows:

The following computations apply to each cell:

For each , the weight assigned to by is computed as follows: is the component of the total surface vector contained by the current cell. Computing the weight assigned to requires that this surface vector be spread over the area of : .

For each , surfaces that contain path as part of their boundary include , , , and . receives a mass of from ; a mass of from ; a mass of from ; and a mass of from . The total mass assigned to is .

Spreading the displacement generated by each over the volume of the current cell gives: .

Therefore: . Note that is expressed using the surface basis vectors, but is using the displacement basis vectors.

Computing the inwards-oriented surfaces of volumes

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To save space, the notation , , and will be omitted from the various terms. However, given a quantity and an arbitrary , the notation will denote the quantity in the adjacent cell by moving back one step along the dimension indexed by . This cell will be referred to as the neighbor of the current cell.

Given a multi-volume denoted by scalar field , the vector field that denotes the inwards-oriented surface can be computed as follows:

The following computations apply to each cell:

The cell's volume has the weight .

For each , surface receives a weight of from the current cell, and a weight of from the neighbor of the current cell. The total weight is simply . Spreading the surface vector generated by each over the volume of the current cell gives: .

Therefore: . Note that uses the surface basis vectors.

Summary

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  • Given multi-path and multi-surface , the intersection of with is multi-point .
  • Given multi-surfaces and , the intersection of with is multi-path .
  • Given multi-path , the endpoints of is multi-point .
  • Given multi-surface , the counter-clockwise boundary of is multi-path .
  • Given multi-volume , the inwards-oriented surface of is multi-surface .

Orthogonal coordinate systems

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In the special case where the displacement basis vectors are all mutually orthogonal (perpendicular), then:

  • The surface basis vectors are identical to the displacement basis vectors: .
  • For each , .
  • .

The above formulas simplify to:

  • .
  • .
  • .
  • .
  • .

For Cartesian coordinates, , , , and , , , and , , . Therefore:

  • .
  • .
  • .
  • .
  • .

For cylindrical coordinates, , , , and , , , and , , . Therefore:

  • .
  • .
  • .
  • .
  • .

For spherical coordinates, , , , and , , , and , , . Therefore:

  • .
  • .
  • .
  • .
  • .

Intersection Boundaries

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The endpoints of intersections

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Many identities related to vector calculus can be derived from examining the endpoints of path-volume intersections and surface-surface intersections.

The endpoints of path-volume intersections

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There are two sources of endpoints for the intersection of a multi-path with a multi-volume: The endpoints of the multi-path that are already in the multi-volume plus the endpoints generated by the paths entering and leaving the volumes.

Start with a multi-path , denoted by vector field , and a multi-volume , denoted by scalar field . The intersection is denoted by vector field .

Any time a path with weight starts in a volume with weight , the intersection gains an endpoint at the starting point of with weight . Any time a path with weight finishes in a volume with weight , the intersection gains an endpoint at the finishing point of with weight . The endpoints for that are generated when paths from start or finish in volumes from is the intersection of the endpoints of with multi-volume . This contributes the term to .

Any time a path with weight enters a volume with weight , the intersection gains an endpoint at the point of entry with weight . Any time a path with weight leaves a volume with weight , the intersection gains an endpoint at the point of exit with weight . The endpoints for that are generated when paths from enter or exit volumes from is the intersection of multi-path with the inwards oriented multi-surface of . This contributes the term to .

The total endpoints of are: . In essence, the endpoints of are the endpoints of that are contained in , plus the points at which paths from enter or exit volumes from . This is depicted in the images on the right.

From the identity , counting the total point weight gives: . For the endpoints of a multi-path, every starting point must be paired with a finishing point so the total point weight of the endpoints of a multi-path is 0. so hence . The total intersection between the endpoints of multi-path and multi-volume is the negative of the total intersection between and the inwards oriented surface of .

If denotes a simple path that starts at point and ends at point , then the above integral identity becomes:

This is known as the gradient theorem.

If denotes a simple volume with a outwards oriented surface , then the integral identity becomes:

This is known as Gauss's divergence theorem.

In summary:

  • Given a multi-path denoted by vector field , and a multi-volume denoted by scalar field , then the endpoints of the intersection are: .
  • Given a multi-path denoted by vector field , and a multi-volume denoted by scalar field , then .
  • Given a simple path that starts at point and ends at point , and a multi-volume denoted by scalar field , then . This is the gradient theorem.
  • Given a multi-path denoted by vector field , and a simple volume with outwards oriented surface , then . This is Gauss's divergence theorem.

The endpoints of surface-surface intersections

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When the counter-clockwise boundary of the first surface (blue) intersects the second surface (orange), endpoints for the intersection path are created with the correct polarity. When the counter-clockwise boundary of the second surface intersects the first surface, endpoints for the intersection path are created with the opposite polarity.

Start with multi-surface , denoted by vector field , and a second multi-surface , denoted by vector field . The intersection is denoted by vector field .

Consider a surface with weight from , and a surface with weight from . Let denote the counter-clockwise boundary of , and let denote the counter-clockwise boundary of . There are 4 scenarios regarding the endpoints of :

  • When the intersects in the preferred direction, the intersection point has a weight of , and an endpoint with weight (starting point) for forms at .
  • When the intersects in the opposite direction, the intersection point has a weight of , and an endpoint with weight (finishing point) for forms at .
  • When the intersects in the preferred direction, the intersection point has a weight of , and an endpoint with weight (finishing point) for forms at .
  • When the intersects in the opposite direction, the intersection point has a weight of , and an endpoint with weight (starting point) for forms at .

It can be seen that the intersection forms endpoints for with the correct polarity, and that the intersection forms endpoints for with the opposite polarity. This can be observed in the image of the right. This implies that the endpoints of are: .

Two surfaces, each with a counter-clockwise oriented boundary, are shown. The net number of times each boundary intersects the other surface is the same. The red boundary passes through the green surface in the preferred direction 2 times, and the green boundary passes through the red surface in the preferred direction 2 times.

From the identity , counting the total point weight gives: . For the endpoints of a multi-path, every starting point must be paired with a finishing point so the total point weight of the endpoints of a multi-path is 0. so hence . The total intersection of the counter-clockwise boundary of multi-surface with multi-surface is the total intersection of the counter-clockwise boundary of with . This is illustrated by the image on the right.

If denotes a simple surface with a counter-clockwise boundary , then the above integral identity becomes:

This is known as Stokes' theorem.

In summary:

  • Given two multi-surfaces denoted by vector fields and , then the endpoints of the intersection are: .
  • Given two multi-surfaces denoted by vector fields and , then .
  • Given a multi-surface denoted by vector field and a simple surface with counter-clockwise oriented boundary , then . This is Stokes' theorem.

The boundaries of intersections

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In addition to the identities derived from examining the endpoints of intersections, some more identities can be derived by examining the counter-clockwise boundaries of surfaces that result from intersections.

The counter-clockwise boundary of surface-volume intersections

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On the left is an oriented surface and a volume. The counter-clockwise boundary of the surface and the inwards oriented surface of the volume are shown. On the right is the surface that forms the intersection of the surface with the volume, and the counter-clockwise boundary of the intersection surface is also shown. The boundary of the intersection consists of two parts: the intersection of the boundary of the original surface with the volume, and the intersection of the the inwards oriented surface of the volume with the original surface.

Start with a multi-surface , denoted by vector field , and a multi-volume , denoted by scalar field . The intersection is denoted by vector field .

Consider a surface with weight from , and a volume with weight from . Let denote the counter-clockwise boundary of , and let denote the inwards oriented surface of . There are two sources for the counter-clockwise boundary of . Any time intersects , the intersection contributes to the boundary of . When leaves , the boundary of cannot follow, and instead must trace along the surface of while remaining in the surface as indicated in the image to the right. The boundary of the total intersection , denoted by , consists of two parts: the intersection of the boundary of with , denoted by , and the intersection of the inwards-oriented surface of with , denoted by . Therefore: .

From the identity , computing the total displacement gives: . The counter-clockwise boundary of a multi-surface is a closed multi-loop, and the total displacement generated by a loop is . so hence . The total intersection of a the boundary of multi-surface with multi-volume is the total intersection of with the surface of .

If denotes a simple surface with counter-clockwise boundary , then the above integral identity becomes:

If denotes a simple volume with outwards oriented surface , then the integral identity becomes:

In summary:

  • Given a multi-surface denoted by vector field , and a multi-volume denoted by scalar field , then the counter-clockwise boundary of the intersection is: .
  • Given a multi-surface denoted by vector field , and a multi-volume denoted by scalar field , then
  • Given a simple surface with counter-clockwise boundary , and a multi-volume denoted by scalar field , then .
  • Given a multi-surface denoted by vector field , and a simple volume with outwards oriented surface , then .

The surfaces of intersections

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Some more identities can be derived by examining the surfaces of volumes that result from intersections.

The inwards-oriented surface of volume-volume intersections

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The surface of a volume-volume intersection consists of two parts: the intersection of the surface of the second volume with the first volume, and the intersection of the surface of the first volume with the second volume.

Start with a multi-volume , denoted by scalar field , and a second multi-volume , denoted by scalar field . The intersection is denoted by the scalar field .

Consider a volume with weight from , and a volume with weight from . Let denote the inwards-oriented surface of , and let denote the inwards-oriented surface of . There are two parts to the inwards-oriented surface of the intersection , as shown in the image to the right. Part of the surface of consists of the portion of that is contained by , which contributes the term to . The other part of the surface of consists of the portion of that is contained by , which contributes the term to . Therefore the total surface of is .

From the identity , computing the total surface vector gives: . The inwards-oriented surface of a multi-volume is a closed multi-surface, and the total surface vector of a closed surface is . so hence . The total surface vector of the intersection of multi-volume with the inwards oriented surface of multi-volume is the opposite of the total surface vector of the intersection of the inwards oriented surface of with .

If denotes a simple volume with outwards oriented surface , then the above integral identity becomes:

In summary:

  • Given two multi-volumes denoted by scalar fields and , then the inwards-oriented surface of the intersection is: .
  • Given two multi-volumes denoted by scalar fields and , then .
  • Given a simple volume with outwards oriented surface and a multi-volume denoted by scalar field , then .

Summary

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The tables below summarizes the results of the previous sections:

The endpoints, boundaries, and surfaces of intersections
structure 1 structure 2 intersection endpoints, boundary, or surface
multi-path multi-volume multi-path multi-point
multi-surface multi-surface multi-path multi-point
multi-surface multi-volume multi-surface multi-path
multi-volume multi-volume multi-volume multi-surface
Integral identities
Simple structure Multi-structure Integral identity Identity name
simple path , with starting point and final point multi-volume the gradient theorem
simple volume , with outwards-oriented surface multi-path Gauss's divergence theorem
simple surface with counter-clockwise oriented boundary multi-surface Stokes' theorem
simple surface with counter-clockwise oriented boundary multi-volume unnamed
simple volume , with outwards-oriented surface multi-surface unnamed
simple volume , with outwards-oriented surface multi-volume unnamed

Multi-path and Multi-surface duality

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