advanced_tools:exterior_product
Differences
This shows you the differences between two versions of the page.
| Both sides previous revision Previous revision Next revision | Previous revision | ||
|
advanced_tools:exterior_product [2022/11/27 21:13] 100.35.170.34 |
advanced_tools:exterior_product [2023/03/19 21:33] (current) edi [Concrete] |
||
|---|---|---|---|
| Line 3: | Line 3: | ||
| <tabbox Intuitive> | <tabbox Intuitive> | ||
| - | The exterior product of two vectors represents the (oriented) area of the parallelogram enclosed by the vectors. The exterior product of three vectors represents the (oriented) volume of the parallelepiped enclosed by the three vectors. | + | The exterior product of two vectors can be pictured as the (oriented) area of the parallelogram enclosed by the two vectors. Similarly, the exterior product of three vectors can be pictured as the (oriented) volume of the parallelepiped enclosed by the three vectors. |
| - | The exterior product generalizes the cross product and (scalar) triple product in such a way that we can calculate with area and volume elements in higher dimensional spaces. | + | The exterior product generalizes the cross product and (scalar) triple product from 3-dimensional space to spaces with any number of dimensions. |
| - | The exterior product is also known as Grassmann product or wedge product. | + | The exterior product is also known as the Grassmann product or wedge product. |
| | | ||
| <tabbox Concrete> | <tabbox Concrete> | ||
| - | The exterior product is calculated by taking the tensor product and antisymmetrizing the result. The picture below shows how to do that for (a) two 3D vectors, (b) three 3D vectors, and (c) a 3D vector and an antisymmetric tensor. The relationship to (a) the cross product, (b) the (scalar) triple product, and (c) the dot product is shown in red. | + | The exterior product is obtained by first taking the tensor product and then antisymmetrizing the result. The picture below shows how to do that for two 3D vectors (top), three 3D vectors (center), and a 3D vector and an antisymmetric tensor (bottom). |
| - | + | The exterior product of two 3D vectors is a rank-2 tensor with three independent components (shown in red), which match those of the cross product. The exterior product of three 3D vectors is a rank-3 tensor with only one independent component (shown in red), which matches the (scalar) triple product. The exterior product of a 3D vector and an antisymmetric tensor is again a rank-3 tensor with only one independent component (shown in red), which is related to the scalar product. | |
| + | |||
| + | For a more detailed explanation of this picture see [[https://esackinger.wordpress.com/blog/lie-groups-and-their-representations/#exterior_prod|Fun with Symmetry]]. | ||
| + | |||
| + | [{{ :advanced_tools:exterior_prod.jpg?nolink }}] | ||
| <tabbox Abstract> | <tabbox Abstract> | ||
advanced_tools/exterior_product.1669580006.txt.gz · Last modified: 2022/11/27 21:13 by 100.35.170.34
Page Tools
Except where otherwise noted, content on this wiki is licensed under the following license: CC Attribution-Share Alike 4.0 International
