General relativity (GR) is an advanced topic within the department of Astrophysics and requires a high level of knowledge in calculus, algebra and physics in general. Tensor fields are a critical part of general relativity.

• Topic:Special relativity (SR) - the spacetimes of GR have the spacetime of SR as a limiting case at a point in spacetime, so you must first understand SR
• Topic:Differential geometry - you need to understand tensors, tensor fields and differential geometry in general in order to understand GR; elements of these are frequently taught within a GR course as an alternative to a full differential geometry course

• Special relativity and steps towards general relativity (shortcut: SRepsilonGR)
  • this course includes a few elements towards elementary general relativity
• Cosmology
  • twentieth/twenty-first cosmology is one of the main applications of general relativity

• General relativity
• Introduction to general relativity
• Inveiling the breakdown of Euclidean geometry in linearized general relativity

See: Learning Projects and the Wikiversity:Learning model.

Learning materials and learning projects can be used by multiple departments. Cooperate with other departments that use the same learning resource.

• Tensors
• Tensors Differential Forms and Variational Principles
• Tidal Forces
• ...

Relevant topics: Covariance, Vectors/ Fields, Tensor Calculus, Euler-Lagrange equations, Equivalence principle, Curvature, Riemann Tensor, Gravitational Waves

• Tensors Differential Forms and Variational Principles

• The website for a GR class taught at Caltech by Kip Thorne and Lee Lindblom. Contains problems, solutions and some lecture notes. [1]
• The first of a sequence of videos of lectures of an "Introduction to General Relativity" class taught by Kip Thorne. [2]
• "Lecture Notes on General Relativity" by Sean Carroll. Coincidentally the basis for his book. [3]
• The General Relativity Tutorial, John Baez: online tutorials and reading list.

• Exact solutions in general relativity category
• Deriving the Schwarzschild solution