Two-point tensor: Difference between revisions
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'''Two-point |
'''Two-point tensors''', or '''double vectors''', are [[tensor]]-like quantities which transform as [[Euclidean vector]]s with respect to each of their indices. They are used in [[continuum mechanics]] to transform between reference ("material") and present ("configuration") coordinates.<ref>Humphrey, Jay D. Cardiovascular solid mechanics: cells, tissues, and organs. Springer Verlag, 2002.</ref> Examples include the [[deformation gradient]] and the first [[Piola–Kirchhoff stress tensor]]. |
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As with many applications of tensors, [[Einstein summation notation]] is frequently used. To clarify this notation, capital indices are often used to indicate reference coordinates and lowercase for present coordinates. Thus, a two-point tensor will have one capital and one lower-case index; for example, ''A<sub>jM</sub>''. |
As with many applications of tensors, [[Einstein summation notation]] is frequently used. To clarify this notation, capital indices are often used to indicate reference coordinates and lowercase for present coordinates. Thus, a two-point tensor will have one capital and one lower-case index; for example, ''A<sub>jM</sub>''. |
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== |
==Continuum mechanics== |
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A conventional tensor can be viewed as a transformation of vectors in one coordinate system to other vectors in the same coordinate system. In contrast, a two-point tensor transforms vectors from one coordinate system to another. That is, a conventional tensor, |
A conventional tensor can be viewed as a transformation of vectors in one coordinate system to other vectors in the same coordinate system. In contrast, a two-point tensor transforms vectors from one coordinate system to another. That is, a conventional tensor, |
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: <math> |
: <math>\mathbf{Q} = Q_{pq}(\mathbf{e}_p\otimes \mathbf{e}_q)</math>, |
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transforms a vector ''u'' to a vector ''v'' such that |
[[active transformation|actively transforms]] a vector '''u''' to a vector '''v''' such that |
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:<math>v= |
:<math>\mathbf{v}=\mathbf{Q}\mathbf{u}</math> |
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where ''v'' and ''u'' are measured in the same |
where '''v''' and '''u''' are measured in the same space and their coordinates representation is with respect to the same basis (denoted by the "''e''"). |
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In contrast, a two-point tensor, '''G''' will be written as |
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Suppose we have two coordinate systems one primed and another unprimed and a vectors' components transform between them as |
Suppose we have two coordinate systems one primed and another unprimed and a vectors' components transform between them as |
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:<math>v'_p=Q_{pq}v_q</math>. |
:<math>v'_p = Q_{pq}v_q</math>. |
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For tensors suppose we then have |
For tensors suppose we then have |
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:<math>T_{pq}(e_p \otimes e_q)</math>. |
:<math>T_{pq}(e_p \otimes e_q)</math>. |
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: <math>T'_{pq}(e'_p \otimes e'_q)</math>. |
: <math>T'_{pq}(e'_p \otimes e'_q)</math>. |
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We can say |
We can say |
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:<math>T'_{ij}=Q_{ip} Q_{jr} T_{pr}</math>. |
:<math>T'_{ij} = Q_{ip} Q_{jr} T_{pr}</math>. |
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Then |
Then |
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:<math>T'=QTQ^T</math> |
:<math>T' = QTQ^\mathsf{T}</math> |
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is the routine tensor transformation. But a two-point tensor between these systems is just |
is the routine tensor transformation. But a two-point tensor between these systems is just |
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: <math>F_{pq}(e'_p \otimes e_q)</math> |
: <math>F_{pq}(e'_p \otimes e_q)</math> |
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which transforms as |
which transforms as |
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: <math>F'=QF</math>. |
: <math>F' = QF</math>. |
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==Simple example== |
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The most mundane example of a two-point tensor is the transformation tensor, the ''Q'' in the above discussion. Note that |
The most mundane example of a two-point tensor is the transformation tensor, the ''Q'' in the above discussion. Note that |
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: <math>v'_p=Q_{pq}u_q</math>. |
: <math>v'_p=Q_{pq}u_q</math>. |
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:<math>u=u_q e_q</math> |
:<math>u=u_q e_q</math> |
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and also |
and also |
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:<math>v=v'_p |
:<math>v=v'_p e'_p</math>. |
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This then requires ''Q'' to be of the form |
This then requires ''Q'' to be of the form |
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: <math>Q_{pq}(e'_p \otimes e_q)</math>. |
: <math>Q_{pq}(e'_p \otimes e_q)</math>. |
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By definition of [[tensor product]], |
By definition of [[tensor product]], |
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: <math>(e'_p\otimes e_q)e_q=(e_q.e_q) e'_p = e'_p |
{{NumBlk|:| <math>(e'_p\otimes e_q)e_q=(e_q.e_q) e'_p =3 e'_p</math>|{{EquationRef|1}}}} |
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So we can write |
So we can write |
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: <math>u_p e_p = (Q_{pq}(e'_p \otimes e_q))(v_q e_q)</math> |
: <math>u_p e_p = (Q_{pq}(e'_p \otimes e_q))(v_q e_q)</math> |
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Thus |
Thus |
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: <math>u_p e_p = Q_{pq} v_q(e'_p \otimes e_q) e_q</math> |
: <math>u_p e_p = Q_{pq} v_q(e'_p \otimes e_q) e_q</math> |
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Incorporating (1), we have |
Incorporating ({{EquationNote|1}}), we have |
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:<math>u_p e_p = Q_{pq} v_q e_p</math>. |
:<math>u_p e_p = Q_{pq} v_q e_p</math>. |
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==See also== |
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* [[Mixed tensor]] |
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* [[Covariance and contravariance of vectors]] |
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==References== |
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{{engineering-stub}} |
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{{Reflist}} |
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==External links== |
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* [https://books.google.com/books?id=RjzhDL5rLSoC&dq=two-point+tensor&pg=PA71 Mathematical foundations of elasticity By Jerrold E. Marsden, Thomas J. R. Hughes] |
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* [http://www.imechanica.org/node/7131 Two-point Tensors at iMechanica] |
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{{DEFAULTSORT:Two-Point Tensor}} |
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[[Category:Euclidean geometry]] |
Latest revision as of 17:37, 17 March 2023
This article needs additional citations for verification. (December 2013) |
Two-point tensors, or double vectors, are tensor-like quantities which transform as Euclidean vectors with respect to each of their indices. They are used in continuum mechanics to transform between reference ("material") and present ("configuration") coordinates.[1] Examples include the deformation gradient and the first Piola–Kirchhoff stress tensor.
As with many applications of tensors, Einstein summation notation is frequently used. To clarify this notation, capital indices are often used to indicate reference coordinates and lowercase for present coordinates. Thus, a two-point tensor will have one capital and one lower-case index; for example, AjM.
Continuum mechanics
[edit]A conventional tensor can be viewed as a transformation of vectors in one coordinate system to other vectors in the same coordinate system. In contrast, a two-point tensor transforms vectors from one coordinate system to another. That is, a conventional tensor,
- ,
actively transforms a vector u to a vector v such that
where v and u are measured in the same space and their coordinates representation is with respect to the same basis (denoted by the "e").
In contrast, a two-point tensor, G will be written as
and will transform a vector, U, in E system to a vector, v, in the e system as
- .
The transformation law for two-point tensor
[edit]Suppose we have two coordinate systems one primed and another unprimed and a vectors' components transform between them as
- .
For tensors suppose we then have
- .
A tensor in the system . In another system, let the same tensor be given by
- .
We can say
- .
Then
is the routine tensor transformation. But a two-point tensor between these systems is just
which transforms as
- .
Simple example
[edit]The most mundane example of a two-point tensor is the transformation tensor, the Q in the above discussion. Note that
- .
Now, writing out in full,
and also
- .
This then requires Q to be of the form
- .
By definition of tensor product,
(1) |
So we can write
Thus
Incorporating (1), we have
- .
See also
[edit]References
[edit]- ^ Humphrey, Jay D. Cardiovascular solid mechanics: cells, tissues, and organs. Springer Verlag, 2002.