What sort of vector is this?

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What sort of "vector" is this?

A contravariant transforms as [tex]A^\rho \rightarrow {\Lambda^\rho}_\sigma A^\sigma[/tex].

A covariant vector [tex]A_\mu[/tex] can be built from [tex]A^\rho[/tex] by [tex]A_\mu=\eta_{\mu\rho}A^\rho[/tex]. Then it transforms according to

[tex]A_\mu\rightarrow\eta_{\mu\rho}{\Lambda^\rho}_\sigma A^\sigma=\Lambda_{\mu\sigma}A^\sigma={\Lambda_\mu}^\sigma A_\sigma[/tex].

(Indeed, [tex]{\Lambda_\mu}^\sigma {\Lambda^\rho}_\sigma=\delta^\rho_\mu[/tex] can be considered the definition of a Lorentz transformation, that is, one which leaves [tex]A^\mu A_\mu[/tex] invariant.)

But are there (covariant?) vectors whose components transform according to

[tex]B_\sigma \rightarrow {\Lambda^\rho}_\sigma B_\rho[/tex]

?

What sort of a "vector" is B? It is not dual to a contravariant vector in the ordinary sense. And (why I put this in relativity forum and not a math forum) what does this type of vector signify within relativity theory? Are there any physical quantities which transform like this?Edit:
Ok. I think I get it. B is a covariant vector and the transformation being questioned represents transforming it by the inverse of the given Lorentz transform.

But please correct if I am wrong. Thanks!
 
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Just in case you haven't noticed it:

pellman said:
A covariant vector [tex]A_\mu[/tex] ... transforms according to

[tex]A_\mu\rightarrow {\Lambda_\mu}^\sigma A_\sigma[/tex].

are there (covariant?) vectors whose components transform according to

[tex]B_\sigma \rightarrow {\Lambda^\rho}_\sigma B_\rho[/tex]
Those two expressions are the same expression, just with different variable names.
 


pellman said:
A contravariant transforms as [tex]A^\rho \rightarrow {\Lambda^\rho}_\sigma A^\sigma[/tex].

A covariant vector [tex]A_\mu[/tex] can be built from [tex]A^\rho[/tex] by [tex]A_\mu=\eta_{\mu\rho}A^\rho[/tex]. Then it transforms according to

[tex]A_\mu\rightarrow\eta_{\mu\rho}{\Lambda^\rho}_\sigma A^\sigma=\Lambda_{\mu\sigma}A^\sigma={\Lambda_\mu}^\sigma A_\sigma[/tex].

(Indeed, [tex]{\Lambda_\mu}^\sigma {\Lambda^\rho}_\sigma=\delta^\rho_\mu[/tex] can be considered the definition of a Lorentz transformation, that is, one which leaves [tex]A^\mu A_\mu[/tex] invariant.)

But are there (covariant?) vectors whose components transform according to

[tex]B_\sigma \rightarrow {\Lambda^\rho}_\sigma B_\rho[/tex]

?

What sort of a "vector" is B? It is not dual to a contravariant vector in the ordinary sense.
Well, yes, it is. Just as you can construct a covariant vector that is dual to a contravariant vector (some texts would say "covariant" and "contravariant" components of the same vector), you can construct a covariant vector that is dual to a contravariant vector (that is basically what "dual" means- it works both ways). The dual to [tex]B_\sigma[/itex] is [tex]B^\gamma= \nu^{\gamma\sigma}B_\sigma[/tex].<br /> Assuming that your [itex]\nu_{\mu\rho}[/itex] is the metric tensor, [itex]\mu^{\gamma\sigma}[/itex] is the tensor such that [itex]\nu_{\mu\rho}\nu^{\mu\gamma}= \nu^{\mu\gamma}\nu_{\mu\rho}= \delta^\gamma_\rho[/itex]. Algebraically, [itex]\nu^{\gamma\sigma}[/itex] is represented by the matrix that is the inverse to [itex]\nu_{\gamma\sigma}[/itex].<br /> <br /> <blockquote data-attributes="" data-quote="" data-source="" class="bbCodeBlock bbCodeBlock--expandable bbCodeBlock--quote js-expandWatch"> <div class="bbCodeBlock-content"> <div class="bbCodeBlock-expandContent js-expandContent "> And (why I put this in relativity forum and not a math forum) what does this type of vector signify within relativity theory? Are there any physical quantities which transform like this?<br /> <br /> <br /> Edit:<br /> Ok. I think I get it. B is a covariant vector and the transformation being questioned represents transforming it by the inverse of the given Lorentz transform. <br /> <br /> But please correct if I am wrong. Thanks! </div> </div> </blockquote> Yes, your edit is correct.[/tex]
 


Covariant transformation from (say) frame S to frame S':

[tex]A'_\mu=\Lambda_\mu{}^\nu A_\nu[/tex]

Multiply by [itex]\Lambda^\mu{}_\rho[/tex].<br /> <br /> [tex]\Lambda^\mu{}_\rho A'_\mu=\Lambda^\mu{}_\rho\Lambda_\mu{}^\nu A_\nu=\Lambda^\mu{}_\rho(\Lambda^{-1})^\nu{}_\mu A_\nu=\delta^\nu_\rho A_\nu=A_\rho[/tex]<br /> <br /> This is clearly just a covariant transformation from S' to S.[/itex]