Coordinate Transformations in GR

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SUMMARY

Coordinate transformations are fundamental in General Relativity (GR) due to the principle of relativity and the general covariance of its equations, which assert that the laws of physics remain consistent across different reference frames. This necessity arises from the nonlinearity of Maxwell's equations in GR, where gravitational mass affects the behavior of plane waves, leading to a lack of independent orthogonal coordinates. Additionally, GR emphasizes that no single coordinate system can adequately describe all events, necessitating the use of various coordinate transformations to represent different observers' measurements of the same events.

PREREQUISITES
  • Understanding of General Relativity principles
  • Familiarity with Maxwell's equations and their implications
  • Knowledge of coordinate systems and transformations
  • Basic grasp of Special Relativity and Lorentz Transformation
NEXT STEPS
  • Study the implications of general covariance in General Relativity
  • Explore the mathematical foundations of coordinate transformations in GR
  • Learn about the role of curvature in spacetime and its effects on measurements
  • Investigate the differences between Special Relativity and General Relativity regarding coordinate systems
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Students and researchers in physics, particularly those focusing on General Relativity, as well as anyone interested in the mathematical framework of coordinate transformations and their significance in understanding the nature of spacetime.

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As I try to understand GR, I find coordinate transformations just about everywhere. My question is simply: What is the reason coordinate transformations play such an important role in GR? Thanks.
 
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I'd say the reason is that one of the most important aspects of GR is the principle of relativity and the general covariance of its equations. Basically, that the laws of physics should be the same in any reference frame so naturally you'll want to perform coordinate trasnformations.
 
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That and also coordinate transformation is the simplest (read: best) way to visualize reference frames.
 
In special relativity, you can can use 3 spatially orthogonal plane wave solutions of Maxwell's "free space" equations as rulers for 3 orthogonal spatial axes. The 3 rulers won't interact with each other and Maxwell's equations are linear. In general relativity, each plane wave has energy or "gravitational mass" and should attract the other plane waves, so Maxwell's "free space" equations should become nonlinear indicating that you cannot get independent plane wave solutions. This will be true of any rulers you set up, so you will have no orthogonal coordinates, except very locally. The bending of your rulers and clocks or "metric" appears as spacetime curvature.
 
Another reason is that GR permits solutions in which it is mathematically impossible for a single choice of coordinates to fully suffice at every event.
 
I'm replying here to my own question, as a contribution to the Forum:

Even after having received the answers to my question, I continued to be concerned, and finally realized the answer is simple and obvious:

The name of the field is "Relativity" and the key is right there - we're talking about how different observers will measure the same events. Different observer's points of view are expressed as observations from different reference frames, and "reference frames" is simply another way of saying "coordinate systems," so of course coordinate transformations are found everywhere in General Relativity.

The second reason is that:
-For generations whe have dealt with coordinate translations, rotations, and moving coordinate systems without thinking much about it.
-In Special Relativity we add the Lorentz Transformation (and have to think a good bit about that).
-One of the basic lessons of General Relativity is that there are no preferred coordinate systems, so now we must deal with arbitrary coordinate systems and their transformations, and learning to do this is an essential part of GR.
 

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