Optimization of Transfers linking Ballistic Captures to Earth-Moon Periodic Orbit Families

The design of transfers to periodic orbits in the Earth--Moon system has regained prominence with NASA's Artemis and CNSA's Chang'e programs. This work addresses the problem of linking ballistic capture trajectories - exploiting multi-body dynamics for temporary lunar orbit insertion - with bounded periodic motion described in the circular restricted three-body problem (CR3BP). A unified framework is developed for optimizing bi-impulsive transfers to families of periodic orbits via a high-order polynomial expansion of the CR3BP dynamics. That same expansion underlies a continuous 'abacus' parameterization of orbit families, enabling rapid targeting and analytic sensitivity. Transfers to planar periodic-orbit families (Lyapunov L1 and L2, and distant retrograde orbits) are addressed first, followed by extension to spatial families, such as butterfly and halo L1/L2 orbits, with an emphasis towards Near-Rectilinear Halo Orbits (NRHOs). Numerical results demonstrate low-cost solutions and validate the method's adaptability for the design of lunar missions. The optimized trajectories can inform an established low-energy transfer database, enriching it with detailed cost profiles that reflect both transfer feasibility and underlying dynamical relationships to specific periodic-orbit families. Finally, the proposed transfers provide reliable initial guesses for rapid refinement, readily adaptable for further optimization across mission-specific needs.