AC dipoles in accelerators are used to excite coherent betatron oscillations at a drive frequency close to the tune. These beam oscillations may last arbitrarily long and, in principle, there is no significant emittance growth if the AC dipole is adiabatically turned on and off. Therefore the AC dipole seems to be an adequate tool for non–linear diagnostics provided the particle motion is well described in presence of the AC dipole and non–linearities. Normal Forms and Lie algebra are powerful tools to study the non–linear content of an accelerator lattice. In this article a way to obtain the Normal Form of the Hamiltonian of an accelerator with an AC dipole is described. The particle motion to first order in the non– linearities is derived using Lie algebra techniques. The dependence of the Hamiltonian terms on the longitudinal coordinate is studied showing that they vary differently depending on the AC dipole parameters. The relation is given between the lines of the Fourier spectrum of the turn–by–turn motion and the Hamiltonian terms.
[1]
F. Schmidt,et al.
Measurement of Driving Terms
,
2001
.
[2]
J. W. Humberston.
Classical mechanics
,
1980,
Nature.
[3]
É. Forest.
A Hamiltonian-Free Description of Single Particle Dynamics for Hopelessly Complex Periodic Systems
,
1990
.
[4]
F. Schmidt,et al.
Normal form via tracking or beam data
,
1997
.
[5]
E. Karantzoulis,et al.
Calculation of beam envelopes in storage rings and transport systems in the presence of transverse space charge effects and coupling
,
1988
.
[6]
Ezio Todesco,et al.
A normal form approach to the theory of nonlinear betatronic motion
,
1994
.