KT-MFLD thins the particle system in mean-field Langevin dynamics to O(N^{3/2}) complexity with convergence guarantees matching standard MFLD up to logarithmic factors.
Scalable method for mean field control with kernel interactions via random Fourier features
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abstract
We develop a scalable algorithm for mean field control problems with kernel interactions by combining particle system simulations with random Fourier feature approximations. The method replaces the quadratic-cost kernel evaluations by linear-time estimates, enabling efficient stochastic gradient descent for training feedback controls in large populations. We provide theoretical complexity bounds and demonstrate through crowd motion and flocking examples that the approach preserves control performance while substantially reducing computational cost. The results indicate that random feature approximations offer an effective and practical tool for high dimensional and large scale mean field control.
years
2026 2verdicts
UNVERDICTED 2representative citing papers
Neural surrogates enable a four-stage alternating algorithm for nonlocal mean-field Schrödinger bridges with linear scaling and Gronwall stability bounds.
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Thinned Mean Field Langevin Dynamics
KT-MFLD thins the particle system in mean-field Langevin dynamics to O(N^{3/2}) complexity with convergence guarantees matching standard MFLD up to logarithmic factors.