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Trainability of Dissipative Perceptron-Based Quantum Neural Networks

Kunal Sharma, M. Cerezo, Łukasz Cincio, Patrick J. Coles

2022Physical Review Letters170 citationsDOIOpen Access PDF

Abstract

Several architectures have been proposed for quantum neural networks (QNNs), with the goal of efficiently performing machine learning tasks on quantum data. Rigorous scaling results are urgently needed for specific QNN constructions to understand which, if any, will be trainable at a large scale. Here, we analyze the gradient scaling (and hence the trainability) for a recently proposed architecture that we call dissipative QNNs (DQNNs), where the input qubits of each layer are discarded at the layer's output. We find that DQNNs can exhibit barren plateaus, i.e., gradients that vanish exponentially in the number of qubits. Moreover, we provide quantitative bounds on the scaling of the gradient for DQNNs under different conditions, such as different cost functions and circuit depths, and show that trainability is not always guaranteed. Our work represents the first rigorous analysis of the scalability of a perceptron-based QNN.

Topics & Concepts

PerceptronScalingScalabilityDissipative systemComputer scienceQubitArtificial neural networkQuantumQuantum computerStatistical physicsArtificial intelligenceMultilayer perceptronTheoretical computer scienceAlgorithmPhysicsMathematicsQuantum mechanicsDatabaseGeometryQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomenaAdvanced Memory and Neural Computing
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