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[[Category:MA271Fall2020Walther]]
 
[[Category:MA271Fall2020Walther]]
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==Vector Laplacian==
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The Laplace operator is originally an operation where you input a scalar function and it returns a scalar function. However, there is an alternate version of the Laplace operator that can be performed on vector fields.
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The vector Laplacian is defined as:
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<math>\Delta F = \nabla^2 F = \nabla (\nabla \cdot F) - \nabla \times (\nabla \times F) \\</math>
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where F is a vector field. In Cartesian coordinates, the vector Laplacian simplifies to the following:
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<math>
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\Delta F =
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\left[\begin{array} {1}
  
 
[[Walther_MA271_Fall2020_topic9|Back to main page]]
 
[[Walther_MA271_Fall2020_topic9|Back to main page]]

Revision as of 23:03, 6 December 2020

Vector Laplacian

The Laplace operator is originally an operation where you input a scalar function and it returns a scalar function. However, there is an alternate version of the Laplace operator that can be performed on vector fields.

The vector Laplacian is defined as:

$ \Delta F = \nabla^2 F = \nabla (\nabla \cdot F) - \nabla \times (\nabla \times F) \\ $

where F is a vector field. In Cartesian coordinates, the vector Laplacian simplifies to the following:

$ \Delta F = \left[\begin{array} {1} [[Walther_MA271_Fall2020_topic9|Back to main page]] $

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