Abstract
Hybrid quantum-classical variational algorithms are one of the most propitious implementations of quantum computing on near-term devices, offering classical machine-learning support to quantum scale solution spaces. However, numerous studies have demonstrated that the rate at which this space grows in qubit number could preclude learning in deep quantum circuits, a phenomenon known as barren plateaus. In this work, we implicate random entanglement, i.e., entanglement that is formed due to state evolution with random unitaries, as a source of barren plateaus and characterize them in terms of many-body entanglement dynamics, detailing their formation as a function of system size, circuit depth, and circuit connectivity. Using this comprehension of entanglement, we propose and demonstrate a number of barren plateau ameliorating techniques, including initial partitioning of cost function and non-cost function registers, meta-learning of low-entanglement circuit initializations, selective inter-register interaction, entanglement regularization, the addition of Langevin noise, and rotation into preferred cost function eigenbases. We find that entanglement limiting, both automatic and engineered, is a hallmark of high-accuracy training and emphasize that, because learning is an iterative organization process whereas barren plateaus are a consequence of randomization, they are not necessarily unavoidable or inescapable. Our work forms both a theoretical characterization and a practical toolbox; first defining barren plateaus in terms of random entanglement and then employing this expertise to strategically combat them.
Highlights
The rapid development of noisy quantum devices [1] has led to great interest in hybrid quantum-classical variational algorithms, through which classical machine-learning techniques are employed to prepare, sample, and optimize states on noisy quantum hardware [2,3,4,5,6]
Of particular interest are quantum neural networks (QNNs) [8], in which quantum input states are transformed into output states by a parametrized quantum circuit (PQC)
Before characterizing the relationship between entanglement and barren plateaus, we provide a brief overview of hybrid quantum-classical variational algorithms in onedimensional (1D) circuits
Summary
The rapid development of noisy quantum devices [1] has led to great interest in hybrid quantum-classical variational algorithms, through which classical machine-learning techniques are employed to prepare, sample, and optimize states on noisy quantum hardware [2,3,4,5,6] Do these algorithms show potential for a variety of near-term applications [7], they are inherently robust against certain coherent errors and are free to minimize decoherence effects through the exploration of unconventional gate sequences. As our findings quantify barrenness via the entanglement of specific qubit subsets, we develop partitioning methods that initially or continuously restrict such entanglement This generates nonbarren cost function landscapes and improves circuit learning. We draw a parallel between entanglement dynamics and the improved performance of QNNs in certain measurement bases
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