论可微量子程序设计语言的原理

Shaopeng Zhu, S. Hung, Shouvanik Chakrabarti, Xiaodi Wu
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引用次数: 6

摘要

变分量子电路(vqc),或所谓的量子神经网络,被预测为近期最重要的量子应用之一,不仅因为它们与经典神经网络的前景相似,而且还因为它们在近期有噪声的中型量子(NISQ)机器上的可行性。在VQC应用的训练过程中对梯度信息的需求刺激了量子电路自分化技术的发展。我们提出了这种技术的第一个形式化,不仅在量子电路的背景下,而且在命令式量子程序(例如,带有控制)中,受到经典机器学习中可微编程语言成功的启发。特别是,我们克服了由奇异量子特征(如量子不可克隆)引起的一些独特困难,并提供了适用于有界循环令状量子程序的微分的严格公式,其代码转换规则,以及一个合理的逻辑来推理它们的正确性。此外,我们已经在OCaml中实现了我们的代码转换,并从分析和经验两方面证明了我们的方案的资源效率。我们还进行了一个带有控制的VQC实例的训练案例研究,这表明我们的方案相对于没有控制的量子电路的现有自分化具有优势。
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On the principles of differentiable quantum programming languages
Variational Quantum Circuits (VQCs), or the so-called quantum neural-networks, are predicted to be one of the most important near-term quantum applications, not only because of their similar promises as classical neural-networks, but also because of their feasibility on near-term noisy intermediate-size quantum (NISQ) machines. The need for gradient information in the training procedure of VQC applications has stimulated the development of auto-differentiation techniques for quantum circuits. We propose the first formalization of this technique, not only in the context of quantum circuits but also for imperative quantum programs (e.g., with controls), inspired by the success of differentiable programming languages in classical machine learning. In particular, we overcome a few unique difficulties caused by exotic quantum features (such as quantum no-cloning) and provide a rigorous formulation of differentiation applied to bounded-loop imperative quantum programs, its code-transformation rules, as well as a sound logic to reason about their correctness. Moreover, we have implemented our code transformation in OCaml and demonstrated the resource-efficiency of our scheme both analytically and empirically. We also conduct a case study of training a VQC instance with controls, which shows the advantage of our scheme over existing auto-differentiation for quantum circuits without controls.
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