Jürgen Struckmeier & Walter Greiner 
EXTEND LAGRANGE & HAMILTON FORMAL FOR POINT MECH & COVARI .. [EPUB ebook] 

This book presents the extended Lagrange and Hamilton formalisms of point mechanics and field theory in the usual tensor language of standard textbooks on classical dynamics. The notion ‘extended’ signifies that the physical time of point dynamics as well as the space-time in field theories are treated as dynamical variables. It thus elaborates on some important questions including: How do we convert the canonical formalisms of Lagrange and Hamilton that are built upon Newton’s concept of an absolute time into the appropriate form of the post-Einstein era? How do we devise a Hamiltonian field theory with space-time as a dynamical variable in order to also cover General Relativity?

In this book, the authors demonstrate how the canonical transformation formalism enables us to systematically devise gauge theories. With the extended canonical transformation formalism that allows to map the space-time geometry, it is possible to formulate a generalized theory of gauge transformations. For a system that is form-invariant under both a local gauge transformation of the fields and under local variations of the space-time geometry, we will find a formulation of General Relativity to emerge naturally from basic principles rather than being postulated.

Contents:

• Conventional Lagrange and Hamilton Formalism for Point Mechanics:
  
  
  
  • Conventional Lagrange Formalism
  
  
  • Conventional Hamilton Formalism
  
  
  • Canonical Transformation Theory
  
  


• Extended Lagrange and Hamilton Formalisms for Point Mechanics:
  
  
  
  • Extended Lagrange Formalism
  
  
  • The Extended Hamiltonian in Point Mechanics
  
  
  • Theory of Extended Canonical Transformations
  
  


• Covariant Hamilton Field Theory under Fixed Spacetime:
  
  
  
  • Covariant Canonical Field Equations
  
  
  • Canonical Transformations in Covariant Hamiltonian Field Theory
  
  
  • Examples of Hamiltonians in Covariant Field Theory
  
  
  • Examples of Canonical Transformations in Covariant Hamiltonian Field Theory
  
  
  • U(1) and SU(N) Gauge Theories in the Hamiltonian Formulation
  
  


• Covariant Hamilton Field Theory with Spacetime as a Dynamical Variable:
  
  
  
  • General Spacetime Transformation of Systems of Scalar, Vector, and Tensor Fields
  
  
  • Gauge Theory of Gravity for Real Scalar and Vector Fields
  
  
  • Applications of the Gauge Theory of Gravity
  
  
  • SU(N) x SO(3, 1) x Diff(M) Gauge Theory
  
  

Readership: Graduate students and researchers in relativistic point mechanics and field theories.