Tensor Analysis - Request for opinion

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Discussion Overview

The discussion revolves around the concept of invariance in the context of tensors and vectors, particularly focusing on differing interpretations of the term "invariant" as it relates to coordinate transformations. Participants explore theoretical implications and definitions, referencing specific sources and examples.

Discussion Character

  • Debate/contested
  • Conceptual clarification
  • Technical explanation

Main Points Raised

  • Some participants propose that "invariant" refers to geometric quantities like tensors and vectors, which retain meaning independent of coordinate systems, while others argue that this usage is unconventional.
  • One participant asserts that tensor equations are invariant under coordinate transformations, but general tensors are not, suggesting a distinction between the two concepts.
  • Another participant clarifies that constant tensors can be considered invariant, but the transformation of tensors can lead to different representations depending on the coordinate system used.
  • There is a discussion about the implications of changing coordinate systems and how it relates to the presence or absence of gravitational fields, referencing Einstein's work and the role of Christoffel symbols.
  • Some participants express confusion over the terminology and usage of "invariant," indicating a need for clearer definitions and understanding among those discussing the topic.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the definitions and implications of invariance in relation to tensors and vectors. Multiple competing views remain, with some agreeing on the distinction between invariant quantities and invariant equations, while others challenge these interpretations.

Contextual Notes

Limitations include varying interpretations of the term "invariant," dependence on specific definitions of tensors and coordinate transformations, and unresolved nuances regarding the implications of changing coordinate systems on tensor properties.

pmb
[SOLVED] Tensor Analysis - Request for opinion

Seems that a few people refer to things like vectors and tensors as quantities which are invariant. For example

Dr. Bertschinger (Cosmologist at MIT) has online notes at http://arcturus.mit.edu/8.962/notes/gr1.pdf
"Introduction to Tensor Calculus for General Relativity,"

In it he writes

"Scalars and vectors are invariant under coordinate transformations;
vector components are not."

this meaning that the vector is a geometric quantity which has a coordinate independent meaning. Call this Meaning Number 1

This is an unusual use of the term "invariant" since that term usually is synonymous with scalar = tensor of rank zero. Call this Meaning Number 2

My question is this - How many go by #1 and how many go by #2 and how many dirive the meaning from context?

Thank you for your opinion.

Pete
 
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Most people do not "go by" either one. Most people understand the difference between "invariant" and "invariant under coordinate transformations".
 
Originally posted by HallsofIvy
Most people do not "go by" either one. Most people understand the difference between "invariant" and "invariant under coordinate transformations".

So I take it that you argree that an invariant is a tensor of rank zero? I also take it that you understand that there is a difference between something being "an" invariant and something having the property of "being" invariant (under a coordinate transformation as you say).

The reason I posted this question was due to a few people who didn't understand that what you just said is true. I was curious as to how many people think that.

Thank you for your opinion.

Pmb
 
But tensors are not "invariant under coordinate transformations". Tensor equations are. Which means that constant tensors T_mu,nu = k are invariant, but not general tensors (a vector is a tensor of rank 1). You can "transform tensors away" by changing coordinates. This is how you can eliminate (local) gravity in a free falling frame of reference.
 
Originally posted by selfAdjoint
But tensors are not "invariant under coordinate transformations". Tensor equations are. Which means that constant tensors T_mu,nu = k are invariant, but not general tensors (a vector is a tensor of rank 1). You can "transform tensors away" by changing coordinates. This is how you can eliminate (local) gravity in a free falling frame of reference.

There is a sense in which tensors are invariant. See Bertschinger's notes above for an explanation/description.

A tensor is a geometrical object which has a meaning independent of the coordinate system. If I change coodinate systems I don't change the tensor. That is what Bertschinger means when he says that a vector remains invariant under a coordinate transformation.

For example: The vector R points North East and has a magnitude of a. If I change coordinates then R remains unchanged.

Personally I find that usage confusing and I try to avoid it. But some relativists use the term in that way.

However the statement "You can 'transform tensors away' by changing coordinates." needs some clarification.

If the components of a tensor vanish in one coordinate system then they vanish in all coordinate systems. The meaning of Einstein's statement that a gravitational field can be transformed away means something different than going from a non-vanishing tensor to a vanishing one (since that is impossible).

Note that the "gravitational field" tensor is the metric.

If, in Minkowski coordinates (t,x,y,z), the metric is not the Minkowski metric g_uv = diag(1,-1,-1,-1) then it is said that there is a gravitational field at that point. If the metric is the Minkowski metric then it is said that there is no a gravitaional field at that point.

What you can transform away are the components of the gravitational field which Einstein defined to be the Christoffel symbols. If, in Minkowski coordinates, the Christoffel symbols don't vanish at a point then there is a gravitational field at that point. But the Christoffel symbols are not parts of a tensor.

This is all explained in Einstein's 1916 paper which, I believe, is available online. See - http://www.Alberteinstein.info/


Pete
 
Okay, it would be better to say that Tensor EQUATIONS are "invariant under coordinate transformations". That is, if A= B (A and B tensors) is true in one coordiante system then it is true in any coordinate system (which is basically the definition of "tensor").
 
Originally posted by HallsofIvy
Okay, it would be better to say that Tensor EQUATIONS are "invariant under coordinate transformations". That is, if A= B (A and B tensors) is true in one coordiante system then it is true in any coordinate system (which is basically the definition of "tensor").

Thank you for your input/opinion. Much appreciated!

Pete
 

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