In this article, the classic dynamic of Paul trap problem is investigated. We give a complete description of the topological structure of Hamiltonian flows on the real phase space. Using the surgery’s theory of Fomenko Liouville tori, all generic bifurcations of the common level sets of the first integrals were described theoretically. We give also an explicit periodic solution for singular values of the first integrals. Numerical investigations are carried out for all generic bifurcations and we observe order-chaos transition when the critical value of a control parameter is varied.
In recent years, the study of dynamic systems has been undertaken in a wide range of fields, which are located at the crossroads of differential geometry, algebraic geometry, number theory, Lie algebra, Intellectual and material means.
A considerable renewed interest appeared for Hamiltonian dynamic systems with two degrees of freedom, one of which is the study of the topological properties of the flow of these systems, their integrability, their chaotic behavior, the study of Periodic solutions and their bifurcation.
A first fundamental task in this field was the search for integrable systems which give rise to non chaotic behavior. For a Hamiltonian system with n degrees of freedom, the most general definition is that of Liouville. In addition to direct analytical methods, various criteria are developed to determine candidates for integrability, namely the Painlevé criterion, the Ziglin criterion and the Poincaré sections.
Integrability is clearly a central issue in understanding the origins and implications of the behaviour of the dynamical systems. Physically interesting integrable systems are rare, and consequently, it stirs up considerable excitement when one is discovered. Moreover, the Painlevé analysis as described in [
Most integrable problems characterizing the motion of a rigid body around a fixed point were collected in [
We examine here an integrable mechanical system which exhibits a great richness of behavior. The proposed system is the system of Paul trap, the Hamiltonian flows are generated by the Hamiltonian:
H ( q , p , λ ) = 1 2 ( P x 2 + P y 2 + P z 2 ) + 1 r + 1 2 ( x 2 + y 2 + λ 2 z 2 ) (1)
where λ is a constant, and r = x 2 + y 2 + z 2 , is known to be integrable in the following three cases [
The plan of the paper is as follows: In Section 2 we give a detailed description of the real phase space topology of the system (1) in the integrable λ = ± 1 case, for doing that, we separate the Hamiltonian system from two canonical transformations. This separability implies a description of the topology of the common-level sets of the first integrals (invariant level sets) however, in our study we consider the common-level sets M ℝ of the first integrals:
M ℝ = { ( x , y , z , P x , P y , P z ) ∈ ℝ 6 ; H = h , F = f } (2)
where H and F are respectively the Hamiltonian and the second invariant of the system.
According to the classical Liouville theorem, for noncritical values of the first integrals h and f, the regular level sets M ℝ of a completely integrable Hamiltonian system consists of tori. All generic bifurcations of these tori, corresponding to these critical values will be described by using Fomenko theorem [
In the Hamiltonian (1) there is a singularity at r = 0 , which necessitates an infinitesimally small step size for numerical integration of the corresponding equation of motion. So, one has to introduce appropriate coordinate transformation to remove this singularity. For this purpose, you can use two canonical transformations, the first is:
{ x = ρ cos ( φ ) , P x = P ρ cos ( φ ) − P φ sin ( φ ) ρ y = ρ sin ( φ ) , P y = P ρ sin ( φ ) + P φ cos ( φ ) ρ z = z , P z = P z (3)
here P ρ , P φ and P z are the canonical momenta conjugate to the coordinates ρ , φ and z respectively.
Then, Equation (1) Can be rewritten as for λ = ± 1
H = 1 2 ( P ρ 2 + P z 2 ) + 1 2 ( ρ 2 + z 2 ) + 1 r + P φ 2 2 ρ 2 , r = ρ 2 + z 2 (4)
Equation (4) is a three degrees of freedom Hamiltonian system in which φ is a cyclic variable, and so the corresponding canonically conjugate momenta P φ is conserved, or P φ = m = const .
Then, Equation (4) can be rewritten as
H = 1 2 ( P ρ 2 + P z 2 ) + 1 2 ( ρ 2 + z 2 ) + 1 r + m 2 2 ρ 2 (5)
the second canonical transformation is:
{ ρ = r cos ( θ ) , P ρ = P r cos ( θ ) − P θ sin ( θ ) r z = r sin ( θ ) , P z = P r sin ( θ ) + P θ cos ( θ ) r (6)
Then, Equation (5) can be rewritten as
H = 1 2 P r 2 + 1 2 r 2 P θ 2 + 1 2 m 2 r 2 ( cos ( θ ) ) 2 + 1 2 r 2 + 1 r (7)
and the Hamilton’s equations of motion of (7) start as
{ d r d t = r ˙ = P r , d P r d t = P ˙ r = P θ 2 r 3 − r + 1 r 2 d θ d t = θ ˙ = P θ r 2 , d P θ d t = P ˙ θ = 0 (8)
which is obtained by making P φ = m = 0 .
In the integrable λ = ± 1 case, we recall the Hamilton-Jacobi equation corresponding to the system (8) that separates into r , θ coordinates defined by
ρ = r cos ( θ ) , z = r sin ( θ ) and φ = const (9)
It is easy to check that P r and P θ can be expressed in terms of r and θ characteristic polynomials in the following way:
{ P r = ± 1 r G ( r ) P θ = ± Q ( θ ) = ± 2 F = const where #Math_34# (10)
And F denotes the second integral of motion:
F = r 2 h − 1 2 r 2 P r 2 − 1 2 r 4 − r = 1 2 P θ 2 (11)
F = f = 1 2 ( ρ P z − z P ρ ) 2 = const (12)
With the rescaled time variable: d t = d τ r .
Therefore, the differential equations satisfied by r and θ are:
{ d r G ( r ) = d τ d θ Q ( θ ) = d t (13)
In order to give a complete description of the topology of M ℝ , we find first the bifurcation diagram B in the ( h , f ) -plane, i.e. the set of the critical values of the energy-momentum mapping
( ρ , z , P ρ , P z ) → ( H , F ) (14)
Definition. The bifurcation diagram of an integrable system is defined to be the region of possible motion depicted on the plane of first integrals ( h , f ) [
It turns out (like in the Hénon-Heils [
B = { ( h , f ) ∈ ℝ 2 : discriminant ( G ( r ) ) = 0 } (15)
where
B = { ( h , f ) ∈ ℝ 2 : 128 h 3 − 432 + 512 h 4 f − 2048 h 2 f 2 − 2304 h f + 2048 f 3 = 0 , f = 1 2 P θ 2 ≥ 0 }
The set M ℝ \ B consists of three connected components (as it is shown in
As θ is acyclical variable ⇒ θ ∈ [ 0 , 2 π ] .
Theorem. The set M ℝ \ B consists of three connected and nonintersecting with each other domains. The topological type of M ℝ is a disjoint union of two-dimensional two-tori 2T, two-dimensional tori T and the empty set ϕ .
Proof. Consider the complexified system
M ⊄ = { ( X , P ) ∈ ⊄ 4 ; H = h , F = f } (16)
consider also the elliptic curves
Γ 1 : { ω 1 2 = G ( r ) } and Γ 2 : { ω 2 2 = Q ( θ ) } (17)
and the corresponding Riemann surfaces R 1 and R 2 of the same genus. We obtain the explicit solutions of the initial problem (13) by solving the Jacobi inversion problem [
Define the natural projection
π : M ⊄ → Γ 1 ⊗ Γ 2 (18)
(where Ä is the symmetric product), and the complex conjugation on M ⊄
ξ : ( ρ , z , P ρ , P z ) → ( ρ ¯ , z ¯ , P ¯ ρ , P ¯ z ) (19)
Consider also the natural projection η on the Riemann surface R = R 1 ⊗ R 2 given in ( r , θ ) coordinates by η : ( r , θ ) → ( r ¯ , θ ¯ ) .
It induces an involution on the Jacobi variety and hence on M ⊄ by the natural projection π . By Equations (10) and (13) imply that this involution η coincides with the complex conjugation (19) on M ⊄ . The upshot is that in order to describe M ℝ it is enough to study the projection:
π : M ⊄ → J a c ( R ) = Γ 1 ⊗ Γ 2 (20)
Definition. A connected component of the set of fixed points of τ on the curve Γ 1 and Γ 2 is called an oval.
To determine the ovals of Γ 1 and Γ 2 it suffices to study the real roots of the polynomial G ( r ) for different values of h and f as shown in
1) M ℝ is a two-dimensional two-tori 2T in domain 3.
2) M ℝ is a two-dimensional tori T in domain 2.
3) M ℝ is the empty set in domain 1.
Suppose now that the constants h and f are changed in such a way that ( h , f ) passes through the bifurcation diagram B. Then the topological type of M ℝ may change and the bifurcation of Liouville tori takes place. In order to describe all generic bifurcations of Liouville tori, we use Fomenko’s theorem of bifurcation for Liouville tori. We can have in our case two types of bifurcation (see
To prove that, it suffices to look at the bifurcations of roots of the polynomial G ( r ) , the correspondence between bifurcation of roots and Liouville tori is shown in
Domain | Real roots of |
---|---|
1 | 0 |
2 | |
3 |
Domain | Topological type of | ||
---|---|---|---|
1 | |||
2 | T | ||
3 | 2T |
When the bifurcation of Liouville tori takes place, the level set M ℝ becomes completely degenerate. Then we can have exceptional families of periodic solutions. It is seen from
Then we obtain from (9) and (10) the following parameterization of fixed periodic solution:
{ ρ = k cos θ , P ρ = − sin θ k Q ( θ ) z = k sin θ , P z = cos θ k P θ (21)
Knowing that
Q ( θ ) = P θ 2 = 2 f (22)
The expression of P ρ can put in the form:
P ρ = − sin ( θ ) k 2 f (23)
Using the differential equations of Hamilton
d t = d θ Q ( θ ) = d θ 2 f ⇒ θ = 2 f t (24)
It is easy to deduce solution
z ( t ) = k sin ( 2 f t ) (25)
and the period associated is given by
T θ = 2 π 2 f (26)
Using a surface of the section map, we give numerical illustrations of the topological analysis studied in Section 2.
For fixed values of energy h and f varies, the Liouville tori contained in the level set H = h and F = f change their topological type. The surfaces of section map shown in
Curve | Topological type of | ||
---|---|---|---|
S |
of Liouville tori and the order-chaos transition when one of the system parameters is varied. This map is constructed using a clever method introduced by Poincaré and extended by Hénon [
The Figures 3(a)-(e) represent the sections for five values of the second invariant f = 3.345 , 4.493 , 5.023 , 5.156 , 5.377 and h = 3.016 . These values correspond to five points of domain 2 on the bifurcation diagram B where M ℝ is a two-dimensional tori T. Moreover, the
The fixed points in
The
The
For critical values of a control parameter λ = 1.16 , 1.35 , 1.18 , we observe a fairly random distribution of points which correspond to a dramatic change in the Poincarésections indicating the order-chaos transition, as it is shown respectively on the
In this study we have treated the classical dynamics of an integrable Hamiltonian system with two degrees of freedom. The system is characterized by a polynomial dependent on the invariants of the motion H and F. The different results obtained show the capacity of the method used to provide precise information on this Hamiltonian system. We have shown how this system can be converted by canonical transformations to easily exploitable Hamiltonians.
The very important question that we have studied is the topological analysis of the real invariant manifolds of the system. Fomenko’s theory on surgery and bifurcations of the Liouville tori has been combined with that of the algebraic structure to give a rigorous and detailed description of the topology of the invariant manifolds. For noncritical values of H and F, the variety contains torus or is empty.
In the same way we have shown how the periodic orbits can be found for singular values of first integrals, how the period of solutions is determined, and how explicit formulas can be established.
We have also highlighted numerically the topology of the invariant manifolds, the bifurcations of the Liouville tori and the order-chaos transition when the system control parameter varies.
Kharbach, J., Benkhali, M., Benmalek, M., Sali1, A., Rezzouk, A. and Ouazzani-Jamil, M. (2017) The Study on the Phase Structure of the Paul Trap System. Applied Mathematics, 8, 525-536. https://doi.org/10.4236/am.2017.84042