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Bregman dynamics, contact transformations and convex optimization
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Bregman dynamics, contact transformations and convex optimization
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Recent research on accelerated gradient methods of use in optimization has demonstrated that these methods can be derived as discretizations of dynamical systems. This, in turn, has provided a basis for more systematic investigations, especially into the geometric structure of those dynamical systems and their structure--preserving discretizations. In this work, we introduce dynamical systems defined through a contact geometry which are not only naturally suited to the optimization goal but also subsume all previous methods based on geometric dynamical systems. As a consequence, all the deterministic flows used in optimization share an extremely interesting geometric property: they are invariant under contact transformations. In our main result, we exploit this observation to show that the celebrated Bregman Hamiltonian system can always be transformed into an equivalent but separable Hamiltonian by means of a contact transformation. This in turn enables the development of fast and robust discretizations through geometric contact splitting integrators. As an illustration, we propose the Relativistic Bregman algorithm, and show in some paradigmatic examples that it compares favorably with respect to standard optimization algorithms such as classical momentum and Nesterov's accelerated gradient.
Forward citations
Cited by 2 Pith papers
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Optimization Geometrodynamics: A Framework for Dynamic Geometric Optimization
Dynamic geometric complexity of reducing condition number under full SPD metric control equals the affine-invariant distance from the relative log-spectrum to a low-width set.
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Geometric--Nongeometric Optimizer Calculus: A Modular Language for Reachable Gradient Methods
A modular calculus decomposes optimizer updates into geometric preconditioning plus structured nongeometric mechanisms, with a direction-expressivity theorem showing full SPD geometry captures exactly strict descent d...
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