Kozai Lidov Cycles = Simple Pendulum
Abstract
The quadrupole Kozai mechanism, which describes the hierarchical three-body problem in the leading order, is shown to be equivalent to a simple pendulum where the change in the eccentricity squared equals the height of the pendulum from its lowest point: emax2-e2=h=l(1-θ). In particular, this results in useful expressions for the KLC period, and the maximal and minimal eccentricities in terms of orbital constants. We derive the equivalence using the vector coordinates α=j+e, β=j-e for the inner Keplerian orbit, where j is the normalized specific angular momentum, and e is the eccentricity vector. The equations of motion for α and β simplify to α=2∂α φ × α and β=2∂β φ × β, where φ is the normalized averaged interaction potential and are symmetric to replacing α and β for the KLC quadratic potential. Their constraints simplify to α2=β2=1, and they are distributed uniformly and independently on the unit sphere for a uniform distribution in phase space (with a fixed energy).
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