However, this estimator (like multiple histogram techniques) requires reevaluation of the potential energy of the system at all other thermodynamic states under study. This can become a computationally unreasonable burden when there are many states, such as 3-dimensional potentials of mean force obtained through umbrella sampling or alchemical simulations with many intermediates, or in situations where the cost of obtaining the extra energy evaluations are high, such as when using polarizable force fields. This burden is especially unreasonable since many states with low overlap will contribute little to the corresponding free energy or ensemble averages. Methods such as Bennett's acceptance ratio [4,5] can be used to compute free energies between only neighboring, but this type of pairwise analysis ignores correlation between samples and is inappropriate when states overlap in phase space with many others.
To solve the problem of efficiently computing averages and free energies with large numbers of states, we derive a modification of the multistate minimum variance method that uses only states with sufficient mutual phase space overlap. For many cases of interest, this drastically decreases the number of states that must be considered with negligible loss of precision. We also present a number of test cases of this method, including free energy profiles for single molecule pulling experiments and the computation of small molecule partition coefficients.
[1] M. R. Shirts and J. D. Chodera, http://arxiv.org/abs/0801.1426 (2008)
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[3] S. Kumar, D. Bouzida, R. H. Swendsen, P. A. Kollman and J. M. J. Rosenberg, J. Comput. Chem., 13:1011-1021 (1992)
[4] C. H. Bennett, J. Comput. Phys. 22:245-268 (1976)
[5] M. K. Fenwick and F. A. Escobedo, J. Chem. Phys. 120:3066-3074 (2004)