Abstract
Computing the equilibrium properties of complex systems, such as free energy differences, is often hampered by rare events in the dynamics. Enhanced sampling methods may be used in order to speed up sampling by, for example, using high temperatures, as in parallel tempering, or simulating with a biasing potential such as in the case of umbrella sampling. The equilibrium properties of the thermodynamic state of interest (e.g., lowest temperature or unbiased potential) can be computed using reweighting estimators such as the weighted histogram analysis method or the multistate Bennett acceptance ratio (MBAR). weighted histogram analysis method and MBAR produce unbiased estimates, the simulation samples from the global equilibria at their respective thermodynamic state--a requirement that can be prohibitively expensive for some simulations such as a large parallel tempering ensemble of an explicitly solvated biomolecule. Here, we introduce the transition-based reweighting analysis method (TRAM)--a class of estimators that exploit ideas from Markov modeling and only require the simulation data to be in local equilibrium within subsets of the configuration space. We formulate the expanded TRAM (xTRAM) estimator that is shown to be asymptotically unbiased and a generalization of MBAR. Using four exemplary systems of varying complexity, we demonstrate the improved convergence (ranging from a twofold improvement to several orders of magnitude) of xTRAM in comparison to a direct counting estimator and MBAR, with respect to the invested simulation effort. Lastly, we introduce a random-swapping simulation protocol that can be used with xTRAM, gaining orders-of-magnitude advantages over simulation protocols that require the constraint of sampling from a global equilibrium.
Highlights
The successful prediction of equilibrium behavior of complex systems is of critical importance in computational physics
We compare three different estimators, which are the newly proposed xTRAM estimator, multistate Bennett acceptance ratio (MBAR), and histogram counting, each applied to the same sets of data
Expanded transition-based reweighting analysis method (TRAM) can be used to obtain estimates of equilibrium properties from any set of simulations that were conducted at different thermodynamic states, such as multiple temperatures, Hamiltonians, or bias potentials, which we demonstrated here for multiple temperature simulations
Summary
The successful prediction of equilibrium behavior of complex systems is of critical importance in computational physics. Rare events in the system’s dynamics make such estimates through direct simulations impractical. For this reason, the past 20 years have seen vast progress in computational techniques used for efficient sampling of rare-event systems with complex energy landscapes. The past 20 years have seen vast progress in computational techniques used for efficient sampling of rare-event systems with complex energy landscapes These developments were, in particular, driven by the study of systems such as spin glasses [1,2], quantum frustrated spin systems [3,4], QCD [5,6,7], and molecular dynamics (MD) of biomolecules [8,9].
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