Quantum Model Learning Agent: characterisation of quantum systems
through machine learning
- URL: http://arxiv.org/abs/2112.08409v1
- Date: Wed, 15 Dec 2021 19:01:53 GMT
- Title: Quantum Model Learning Agent: characterisation of quantum systems
through machine learning
- Authors: Brian Flynn, Antonio Andreas Gentile, Nathan Wiebe, Raffaele
Santagati, Anthony Laing
- Abstract summary: We report an algorithm -- the Quantum Model Learning Agent (QMLA) -- to reverse engineer Hamiltonian descriptions of a target system.
QMLA is shown to identify the true model in the majority of instances, when provided with limited a priori information.
We demonstrate QMLA operating on large model spaces by incorporating a genetic algorithm to formulate new hypothetical models.
- Score: 0.6474760227870044
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Accurate models of real quantum systems are important for investigating their
behaviour, yet are difficult to distill empirically. Here, we report an
algorithm -- the Quantum Model Learning Agent (QMLA) -- to reverse engineer
Hamiltonian descriptions of a target system. We test the performance of QMLA on
a number of simulated experiments, demonstrating several mechanisms for the
design of candidate Hamiltonian models and simultaneously entertaining numerous
hypotheses about the nature of the physical interactions governing the system
under study. QMLA is shown to identify the true model in the majority of
instances, when provided with limited a priori information, and control of the
experimental setup. Our protocol can explore Ising, Heisenberg and Hubbard
families of models in parallel, reliably identifying the family which best
describes the system dynamics. We demonstrate QMLA operating on large model
spaces by incorporating a genetic algorithm to formulate new hypothetical
models. The selection of models whose features propagate to the next generation
is based upon an objective function inspired by the Elo rating scheme,
typically used to rate competitors in games such as chess and football. In all
instances, our protocol finds models that exhibit $F_1$-score $\geq 0.88$ when
compared with the true model, and it precisely identifies the true model in 72%
of cases, whilst exploring a space of over $250,000$ potential models. By
testing which interactions actually occur in the target system, QMLA is a
viable tool for both the exploration of fundamental physics and the
characterisation and calibration of quantum devices.
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