Abstract

In quantum computing, the variational quantum algorithms (VQAs) are well suited for finding optimal combinations of things in specific applications ranging from chemistry all the way to finance. The training of VQAs with gradient descent optimization algorithm has shown a good convergence. At an early stage, the simulation of variational quantum circuits on noisy intermediate-scale quantum (NISQ) devices suffers from noisy outputs. Just like classical deep learning, it also suffers from vanishing gradient problems. It is a realistic goal to study the topology of loss landscape, to visualize the curvature information and trainability of these circuits in the existence of vanishing gradients. In this paper, we calculate the Hessian and visualize the loss landscape of variational quantum classifiers at different points in parameter space. The curvature information of variational quantum classifiers (VQC) is interpreted and the loss function’s convergence is shown. It helps us better understand the behavior of variational quantum circuits to tackle optimization problems efficiently. We investigated the variational quantum classifiers via Hessian on quantum computers, starting with a simple 4-bit parity problem to gain insight into the practical behavior of Hessian, then thoroughly analyzed the behavior of Hessian’s eigenvalues on training the variational quantum classifier for the Diabetes dataset. Finally, we show how the adaptive Hessian learning rate can influence the convergence while training the variational circuits.

Highlights

  • Introduction & motivationIn recent years, the enhancement of machine learning algorithms by noisy intermediate-scale quantum (NISQ) technology and mainly the variational quantum circuits have garnered significant attention among academic and research communities [1]

  • The major downside of variational quantum circuits is the occurrence of a barren plateau, which vanishes the gradients of cost function exponentially with the increase in the number of qubits [25, 26]

  • The curvature information of the loss landscape of variational quantum classifiers has been visualized via the lens of Hessian eigenvalues

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Summary

Variational quantum classifiers through the lens of the Hessian

Pinaki SenID1, Amandeep Singh BhatiaID2*, Kamalpreet Singh Bhangu, Ahmed Elbeltagi. OPEN ACCESS Citation: Sen P, Bhatia AS, Bhangu KS, Elbeltagi A (2022) Variational quantum classifiers through the lens of the Hessian. The training of VQAs with gradient descent optimization algorithm has shown a good convergence. It is a realistic goal to study the topology of loss landscape, to visualize the curvature information and trainability of these circuits in the existence of vanishing gradients. We calculate the Hessian and visualize the loss landscape of variational quantum classifiers at different points in parameter space. The curvature information of variational quantum classifiers (VQC) is interpreted and the loss function’s convergence is shown. It helps us better understand the behavior of variational quantum circuits to tackle optimization problems efficiently.

Introduction & motivation
Hessian computation of VQC
Experiment settings
Classification of diabetes
Convergence via adaptive Hessian learning rate
Conclusion
Author Contributions

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