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Main Authors: De Falco, Francesca, Ceschini, Andrea, Sebastianelli, Alessandro, Saux, Bertrand Le, Panella, Massimo
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.16147
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author De Falco, Francesca
Ceschini, Andrea
Sebastianelli, Alessandro
Saux, Bertrand Le
Panella, Massimo
author_facet De Falco, Francesca
Ceschini, Andrea
Sebastianelli, Alessandro
Saux, Bertrand Le
Panella, Massimo
contents In this paper, we propose a new methodology to design quantum hybrid diffusion models, derived from classical U-Nets with ResNet and Attention layers. Specifically, we propose two possible different hybridization schemes combining quantum computing's superior generalization with classical networks' modularity. In the first one, we acted at the vertex: ResNet convolutional layers are gradually replaced with variational circuits to create Quantum ResNet blocks. In the second proposed architecture, we extend the hybridization to the intermediate level of the encoder, due to its higher sensitivity in the feature extraction process. In order to conduct an in-depth analysis of the potential advantages stemming from the integration of quantum layers, images generated by quantum hybrid diffusion models are compared to those generated by classical models, and evaluated in terms of several quantitative metrics. The results demonstrate an advantage in using a hybrid quantum diffusion models, as they generally synthesize better-quality images and converges faster. Moreover, they show the additional advantage of having a lower number of parameters to train compared to the classical one, with a reduction that depends on the extent to which the vertex is hybridized.
format Preprint
id arxiv_https___arxiv_org_abs_2402_16147
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Towards Efficient Quantum Hybrid Diffusion Models
De Falco, Francesca
Ceschini, Andrea
Sebastianelli, Alessandro
Saux, Bertrand Le
Panella, Massimo
Quantum Physics
In this paper, we propose a new methodology to design quantum hybrid diffusion models, derived from classical U-Nets with ResNet and Attention layers. Specifically, we propose two possible different hybridization schemes combining quantum computing's superior generalization with classical networks' modularity. In the first one, we acted at the vertex: ResNet convolutional layers are gradually replaced with variational circuits to create Quantum ResNet blocks. In the second proposed architecture, we extend the hybridization to the intermediate level of the encoder, due to its higher sensitivity in the feature extraction process. In order to conduct an in-depth analysis of the potential advantages stemming from the integration of quantum layers, images generated by quantum hybrid diffusion models are compared to those generated by classical models, and evaluated in terms of several quantitative metrics. The results demonstrate an advantage in using a hybrid quantum diffusion models, as they generally synthesize better-quality images and converges faster. Moreover, they show the additional advantage of having a lower number of parameters to train compared to the classical one, with a reduction that depends on the extent to which the vertex is hybridized.
title Towards Efficient Quantum Hybrid Diffusion Models
topic Quantum Physics
url https://arxiv.org/abs/2402.16147