Relativistic Equation of Motion

Related lectures (32)

Page 2 of 4

Introduces special and general relativity, Einstein equations, and gravitational dynamics.

Covers tensors, Lorentz transformations, and electrodynamics in relativistic notation.

Explains the principles of special relativity, including time dilation, length contraction, and the Lorentz transformations.

Explores Lorentz invariance, tensors in vector spaces, and electromagnetic potentials.

Explores Lorentz transformations, covariant tensors, rotational invariance, and linear transformations in vector spaces.

Explores Lorentz transformations, boosts, and symmetries in Newtonian mechanics.

Covers the equation of motion for a relativistic charged particle and Lorentz transformations, along with tensors and electrodynamics.

Covers the formulation of gravitational field equations and the motion of particles in gravitational fields.

Explores the consequences of Lorentz transformations in 1+1 dimensions for two observers and the implications on time and distance measurements.

Covers EM Field and Discrete Symmetries, emphasizing the importance of symmetries in quantum field theory.