Lecture Notes on the General Theory of Relativity

- Newton's law of universal gravitation
- The force law of gravitation
- Newton's law of gravitation in local form
- Tidal forces
- The principle of equivalence
- The general principle of relativity
- The covariance principle
- Mach's principle
- The special theory of relativity
- Coordinate systems and Minkowski diagrams
- Synchronization of clocks
- The Doppler effect
- Relativistic time-dilation
- The relativity of simultaneity
- The Lorentz contraction
- The Lorentz transformation
- The Lorentz invariant interval
- The twin paradox
- Hyperbolic motion
- Energy and mass
- Relativistic increase of mass
- Tachyons
- Magnetism as a relativistic second order effect
- Vectors, tensors and forms
- Vectors
- Four-vectors
- Tangent vector fields and coordinate vectors
- Coordinate transformations
- Structure coefficients
- Tensors
- Transformation of tensor components
- Transformation of basis 1-forms
- The metric tensor
- Forms
- Rotating and accelerated reference frames
- Rotating reference frames
- The spatial metric tensor
- Angular acceleration of the rotating frame
- Gravitational time dilation
- Path of photons emitted from the axis in a rotating frame
- The Sagnac effect
- Uniformly accelerated reference frames
- Covariant differentiation
- Differentiation of forms
- Exterior differentiation
- Covariant derivative
- The Christoffel symbols
- Geodetic curves
- The covariant Euler-Lagrange equations
- Application of the Lagrange formalism to free particles
- Equation of motion from Lagrange's equations
- Geodesic worldliness in spacetime
- Gravitational Doppler effect
- The Koszul connection
- Connection coefficients and structure coefficients in a Riemannian (torsion free) space
- Covariant differentiation of vectors, forms and tensors
- Covariant differentiation of a vector field in an arbitrary basis
- Covariant differentiation of forms
- Generalization for tensors of higher rank
- The Cartan

From the reviews:"The textbook is self-contained and designed for master students. The book provides an introduction to abstract notations for tensor calculus and differential geometry, in particular the calculus of differential forms." (Vladimir Dzhunushaliev, Zentralblatt MATH, Vol. 1192, 2010)"This book collects the lecture notes of a course on general relativity ... . The text is enriched by a collection of interesting and stimulating exercises, which both allow a working knowledge of the theory and provide further insight into the theory itself and its applications as well. Together with the personal didactical approach taken by the author in his book, these exercises may represent useful hints for a teacher wishing to introduce new ideas in a standard introductory course on general relativity." (Giovanni Preti, Mathematical Reviews, Issue 2011 k)

From the reviews:

"The textbook is self-contained and designed for master students. The book provides an introduction to abstract notations for tensor calculus and differential geometry, in particular the calculus of differential forms." (Vladimir Dzhunushaliev, Zentralblatt MATH, Vol. 1192, 2010)

"This book collects the lecture notes of a course on general relativity ... . The text is enriched by a collection of interesting and stimulating exercises, which both allow a working knowledge of the theory and provide further insight into the theory itself and its applications as well. Together with the personal didactical approach taken by the author in his book, these exercises may represent useful hints for a teacher wishing to introduce new ideas in a standard introductory course on general relativity." (Giovanni Preti, Mathematical Reviews, Issue 2011 k)