User:Jheald/sandbox/Bivector

Bivectors as antisymmetric tensors[edit]

A bivector B can be represented by an anti-symmetric matrix B_ij (in fact, an antisymmetric tensor) when used in a contraction with two vectors to produce a scalar. This is often how bivectors are introduced or defined, especially in older works.^[1]

u_{i}\mathbf {e} _{i}\cdot \mathbf {B} \cdot \mathbf {e} _{j}v_{j}=u_{i}\,\langle \mathbf {e} _{i}\mathbf {B} \mathbf {e} _{j}\rangle _{0}\,v_{j}=u_{i}B_{ij}v_{j}

Anti-symmetry is established by noting that, as a scalar, $\scriptstyle {\langle \mathbf {e} _{i}\mathbf {B} \mathbf {e} _{j}\rangle _{0}}$ is invariant under the geometric algebra reversal operation, so

B_{ij}=\langle \mathbf {e} _{j}{\tilde {\mathbf {B} }}\mathbf {e} _{i}\rangle _{0}

But for a bivector $\scriptstyle {{\tilde {\mathbf {B} }}=-\mathbf {B} }$ , and therefore

B_{ij}=-\langle \mathbf {e} _{j}\mathbf {B} \mathbf {e} _{i}\rangle _{0}=-B_{ji}

The tensor property follows from the fact that the map $\scriptstyle {T:V^{*}\times V\rightarrow \mathbf {R} }$ from two vectors to a scalar defined in this way is co-ordinate free, transforming appropriately and continuing to hold under rotations and other transformations.

Electromagnetic tensor[edit]

Is it worth reflecting the explicit form given in the Electromagnetic tensor article to make the connection more direct:

F^{\mu \nu }={\begin{bmatrix}0&-E_{x}/c&-E_{y}/c&-E_{z}/c\\E_{x}/c&0&-B_{z}&B_{y}\\E_{y}/c&B_{z}&0&-B_{x}\\E_{z}/c&-B_{y}&B_{x}&0\end{bmatrix}}\;\leftrightarrow \;\mathbf {F}

(Q: raised indices or lowered indices?

Should it not be one up and one down, with reversal turning it into the other choice?)

where

\mathbf {F} ={\frac {1}{c}}{\overline {E}}\mathbf {e} _{4}+{\overline {B}}\mathbf {e} _{123},

Note (1): 1/c corresponds to the convention in the matrix above, whereas E + i c B from the mathematical descriptions article (cf below) does not

Note (2): This formulation has the potential to be a bit confusing at first sight, because the untrained eye sees e₄ and e₁₂₃ it may not think "bivector". This is a bivector formula, because

\scriptstyle {\overline {E}}

and

\scriptstyle {\overline {B}}

are vectors, so multiplying them by e₄ and e₁₂₃ gives bivectors, but that may need to be emphasised.

Note (3): It might be worth changing to e₀ rather than e₄ for the time-like unit vector, if we were going to want to make the closest connection with the matrix up above.

c.f. from Mathematical_descriptions_of_the_electromagnetic_field#Geometric_algebra_formulations

$F=\mathbf {E} +ic\mathbf {B} =E^{k}\gamma _{k}\gamma _{0}-c(B^{1}\gamma _{2}\gamma _{3}+B^{2}\gamma _{3}\gamma _{1}+B^{3}\gamma _{1}\gamma _{2}),$

Q1. why the raised indices ? -- I guess perhaps to show summation, but is this really standard notation in GA -- relation to tensor notation too confusing?

Q2. apparent difference in sign - minus for the magnetic field part, rather than plus

Q3. this is c times the other F -- which is more standard/appropriate ?

The different conventions give rise to slightly different forms of Maxwell's equations.

From here:

$\partial \mathbf {F} =\mathbf {J} .$

whereas there

$\nabla F=\mu _{0}cJ$

Limitations of representing bivectors as anti-symmetic matrices[edit]

Is it worth adding a section on the limitations of representing bivectors as anti-symmetic matrices?

eg:

* representing B e_i u_i as B_ij u_j loses the trivector component B ∧ e_i u_i

* and it doesn't let you represent B u B^-1 (even though we do have a section on the exponentiation of anti-symmetric matrices)

Because of its group structure, there is a faithful matrix representation of the elements of a GA that reproduces the algebra; but in this representation, to get over issues like the above, vectors (in the sense of spatial vectors) also are represented by matrices -- eg the Pauli matrices, or the Gamma matrices -- and no longer by a column of numbers.

In that sort of representation, bivectors (are still represented by anti-symmetric matrices??), but not of the same form B_ij.

References[edit]

^ eg Cartan

[1] Cartan

[1]