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Quantum Algorithms
Modeling Sequences with Quantum States: A Look Under the Hood
arXiv
Authors: Tai-Danae Bradley, E. Miles Stoudenmire, John Terilla
Year
2019
Paper ID
7173
Status
Preprint
Abstract Read
~2 min
Abstract Words
156
Citations
N/A
Abstract
Classical probability distributions on sets of sequences can be modeled using quantum states. Here, we do so with a quantum state that is pure and entangled. Because it is entangled, the reduced densities that describe subsystems also carry information about the complementary subsystem. This is in contrast to the classical marginal distributions on a subsystem in which information about the complementary system has been integrated out and lost. A training algorithm based on the density matrix renormalization group (DMRG) procedure uses the extra information contained in the reduced densities and organizes it into a tensor network model. An understanding of the extra information contained in the reduced densities allow us to examine the mechanics of this DMRG algorithm and study the generalization error of the resulting model. As an illustration, we work with the even-parity dataset and produce an estimate for the generalization error as a function of the fraction of the dataset used in training.
Why This Paper Matters
- It adds a 2019 reference point for readers tracking recent quantum research.
- Classical probability distributions on sets of sequences can be modeled using quantum states.
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