Search

Your search keyword '"Wiedmann, Marco"' showing total 6 results
Start Over Author "Wiedmann, Marco"
6 results on '"Wiedmann, Marco"'

1. Fourier Analysis of Variational Quantum Circuits for Supervised Learning

Author

Wiedmann, Marco, Periyasamy, Maniraman, and Scherer, Daniel D.

Subjects
Computer Science - Machine Learning, Quantum Physics
Abstract

VQC can be understood through the lens of Fourier analysis. It is already well-known that the function space represented by any circuit architecture can be described through a truncated Fourier sum. We show that the spectrum available to that truncated Fourier sum is not entirely determined by the encoding gates of the circuit, since the variational part of the circuit can constrain certain coefficients to zero, effectively removing that frequency from the spectrum. To the best of our knowledge, we give the first description of the functional dependence of the Fourier coefficients on the variational parameters as trigonometric polynomials. This allows us to provide an algorithm which computes the exact spectrum of any given circuit and the corresponding Fourier coefficients. Finally, we demonstrate that by comparing the Fourier transform of the dataset to the available spectra, it is possible to predict which VQC out of a given list of choices will be able to best fit the data.

Published
2024

2. An Empirical Comparison of Optimizers for Quantum Machine Learning with SPSA-based Gradients

Author

Wiedmann, Marco, Hölle, Marc, Periyasamy, Maniraman, Meyer, Nico, Ufrecht, Christian, Scherer, Daniel D., Plinge, Axel, and Mutschler, Christopher

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

VQA have attracted a lot of attention from the quantum computing community for the last few years. Their hybrid quantum-classical nature with relatively shallow quantum circuits makes them a promising platform for demonstrating the capabilities of NISQ devices. Although the classical machine learning community focuses on gradient-based parameter optimization, finding near-exact gradients for VQC with the parameter-shift rule introduces a large sampling overhead. Therefore, gradient-free optimizers have gained popularity in quantum machine learning circles. Among the most promising candidates is the SPSA algorithm, due to its low computational cost and inherent noise resilience. We introduce a novel approach that uses the approximated gradient from SPSA in combination with state-of-the-art gradient-based classical optimizers. We demonstrate numerically that this outperforms both standard SPSA and the parameter-shift rule in terms of convergence rate and absolute error in simple regression tasks. The improvement of our novel approach over SPSA with stochastic gradient decent is even amplified when shot- and hardware-noise are taken into account. We also demonstrate that error mitigation does not significantly affect our results.

Published
2023
Full Text
View/download PDF

3. BCQQ: Batch-Constraint Quantum Q-Learning with Cyclic Data Re-uploading

Author

Periyasamy, Maniraman, Hölle, Marc, Wiedmann, Marco, Scherer, Daniel D., Plinge, Axel, and Mutschler, Christopher

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

Deep reinforcement learning (DRL) often requires a large number of data and environment interactions, making the training process time-consuming. This challenge is further exacerbated in the case of batch RL, where the agent is trained solely on a pre-collected dataset without environment interactions. Recent advancements in quantum computing suggest that quantum models might require less data for training compared to classical methods. In this paper, we investigate this potential advantage by proposing a batch RL algorithm that utilizes VQC as function approximators within the discrete batch-constraint deep Q-learning (BCQ) algorithm. Additionally, we introduce a novel data re-uploading scheme by cyclically shifting the order of input variables in the data encoding layers. We evaluate the efficiency of our algorithm on the OpenAI CartPole environment and compare its performance to the classical neural network-based discrete BCQ.

Published
2023

4. Batch Quantum Reinforcement Learning

Author

Periyasamy, Maniraman, Hölle, Marc, Wiedmann, Marco, Scherer, Daniel D., Plinge, Axel, and Mutschler, Christopher

Subjects
FOS: Computer and information sciences, Quantum Physics, Computer Science - Machine Learning, FOS: Physical sciences, Quantum Physics (quant-ph), Machine Learning (cs.LG)
Abstract

Training DRL agents is often a time-consuming process as a large number of samples and environment interactions is required. This effect is even amplified in the case of Batch RL, where the agent is trained without environment interactions solely based on a set of previously collected data. Novel approaches based on quantum computing suggest an advantage compared to classical approaches in terms of sample efficiency. To investigate this advantage, we propose a batch RL algorithm leveraging VQC as function approximators in the discrete BCQ algorithm. Additionally, we present a novel data re-uploading scheme based on cyclically shifting the input variables' order in the data encoding layers. We show the efficiency of our algorithm on the OpenAI CartPole environment and compare its performance to classical neural network-based discrete BCQ.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results