Moving frames method

The equivalence moving frames method was introduced by E. Cartan to solve the equivalence problems on submanifolds under the action of a transformation group. In 1974, P. A. Griffiths has paid to the uniqueness and existence problem on geometric differential equations by using the Cartan method of Lie groups and moving frames.[1] Later on, in the 1990s, Fels and Peter J. Olver have presented the moving co-frame method as a new formulation of the classical Cartan's method for finite-dimensional Lie group actions on manifolds.[2][3] In the last two decades, the moving frames method has been developed in the general algorithmic and equivariant framework which gives several new powerful tools for finding and classifying the equivalence and symmetry properties of submanifolds, differential invariants, and their syzygies.[4]

Moving frames method in applied on a wide variety of problems, including solving the basic symmetry and equivalence problems of polynomials that form the foundation of classical invariant theory,[5] classifying the differential invariants for Lie group actions on functions,[6] analyzing the algebraic structure of differential invariants of PDEs,[7] geometry of curves and surfaces in homogeneous spaces.[8]

Lectures on Moving Frames

References

  1. ^ Griffiths, P. A. (1974). "On Cartan's method of Lie groups and moving frames as applied to uniqueness and existence questions in differential geometry". Duke Math. J. 41 (4): 775–814. doi:10.1215/S0012-7094-74-04180-5.
  2. ^ M. Fels and P. J. Olver (1998). "Moving coframes-I: A practical algorithm". Acta Appl. Math. 51 (2): 161–213. doi:10.1023/A:1005878210297.
  3. ^ M. Fels and P. J. Olver (1999). "Moving coframes-II: Regularization and theoretical foundations". Acta Appl. Math. 55 (2): 127–208. doi:10.1023/A:1006195823000.
  4. ^ Olver P. J. (2003). "Moving frames". J. Symb. Comput. 36 (3): 501–512. doi:10.1016/S0747-7171(03)00092-0.
  5. ^ Kogan, I.A. (2001). "Inductive construction of moving frames". Journal of Symbolic Computation. 285: 157–170. doi:10.1016/S0747-7171(03)00092-0.
  6. ^ Olver, Peter J. (2023). "Projective invariants of images". European Journal of Applied Mathematics. 34 (5): 936–946. doi:10.1017/S0956792522000298.
  7. ^ G Haghighatdoost, M Bazghandi, F Pashaie (2025). "Differential Invariants of Coupled Hirota-Satsuma KdV Equations". Kragujevac Journal of Mathematics. 49 (5): 793–805. doi:10.46793/KgJMat2505.793H.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  8. ^ Mar´ı Beffa, G., Sanders, J.A., and Wang, J.P (2003). "Relative and absolute differential invariants for conformal curves". J. Lie Theory. 13: 213–245.{{cite journal}}: CS1 maint: multiple names: authors list (link)

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