Integrable - crowlogic/arb4j GitHub Wiki

In the context of dynamical systems and classical mechanics, a system is considered integrable if it possesses as many independent conserved quantities (or constants of motion) as the number of degrees of freedom. These conserved quantities help simplify the analysis and understanding of the system's behavior. Integrable systems exhibit regular, predictable motion and can often be solved exactly or reduced to simpler problems.

Here are some key aspects of integrable systems:

  1. Degrees of freedom: The number of degrees of freedom in a system is the minimum number of independent parameters needed to describe its state or configuration. In classical mechanics, this typically corresponds to the number of generalized coordinates required to specify the position of all particles in the system.

  2. Conserved quantities: Conserved quantities, or constants of motion, are quantities that remain constant over time as the system evolves. They are often associated with symmetries in the system. Examples include energy, linear momentum, and angular momentum.

  3. Liouville's theorem: For a Hamiltonian system to be integrable, it must satisfy Liouville's theorem, which states that there exists a set of canonical transformations that can transform the Hamiltonian equations of motion into a set of independent, uncoupled, first-order differential equations. This simplifies the analysis of the system's dynamics and makes it possible to solve the equations of motion.

  4. Separation of variables: Integrable systems often exhibit separation of variables, which means that their Hamilton-Jacobi equations can be separated into a set of independent ordinary differential equations. This separation simplifies the problem and makes it easier to find exact solutions.

  5. Invariant tori and quasi-periodic motion: In phase space, the trajectories of integrable systems are typically confined to invariant tori, which are closed, torus-shaped surfaces. The motion on these invariant tori is typically quasi-periodic, meaning it is regular and predictable but not strictly periodic.

  6. Examples: Some examples of integrable systems include the simple harmonic oscillator, the Kepler problem (two-body problem in celestial mechanics), and the motion of a charged particle in a uniform magnetic field.

Integrable systems play an important role in the study of dynamical systems and classical mechanics because they can be solved exactly or reduced to simpler problems. Their regular, predictable behavior provides valuable insights into the properties and behavior of more complex, non-integrable systems.