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Quantum machine learning: Small-scale photonic quantum processor can already outperform classical counterparts

Quantum computers boost machine learning algorithms
Classification of data points can be performed through a photonic quantum computer, boosting the accuracy of conventional methods. Credit: Iris Agresti

One of the current hot research topics is the combination of two of the most recent technological breakthroughs: machine learning and quantum computing.

An experimental study shows that already small-scale quantum computers can boost the performance of algorithms.

This was demonstrated on a photonic quantum processor by an international team of researchers at the University of Vienna. The work, in Nature Photonics, shows promising for optical quantum computers.

Recent scientific breakthroughs have reshaped the development of future technologies. On the one hand, machine learning and have already revolutionized our lives from everyday tasks to . On the other hand, has emerged as a new paradigm of computation.

From the combination of these promising two fields, a new research line has opened up: Quantum Machine Learning. This field aims at finding potential enhancements in the speed, efficiency or accuracy of algorithms when they run on quantum platforms. It is, however, still an open challenge to achieve such an advantage on current technology quantum computers.

This is where an international team of researchers took the next step and designed a novel experiment carried out by scientists from the University of Vienna.

The set-up features a quantum photonic circuit built at the Politecnico di Milano (Italy), which runs a machine learning first proposed by researchers working at Quantinuum (United Kingdom). The goal was to classify data points using a photonic quantum computer and single out the contribution of quantum effects, to understand the advantage with respect to classical computers.

The experiment showed that already small-sized quantum processors can perform better than conventional algorithms.

"We found that for specific tasks our algorithm commits fewer errors than its classical counterpart," explains Philip Walther from the University of Vienna, lead of the project.

"This implies that existing quantum computers can show good performances without necessarily going beyond the state-of-the-art technology," adds Zhenghao Yin, first author of the publication in Nature Photonics.

Another interesting aspect of the new research is that photonic platforms can consume less energy with respect to standard computers. "This could prove crucial in the future, given that machine learning algorithms are becoming infeasible, due to the too high energy demands," emphasizes co-author Iris Agresti.

The result of the researchers has an impact both on quantum computation, since it identifies tasks that benefit from quantum effects, as well as on standard computing.

Indeed, new algorithms, inspired by quantum architectures, could be designed, reaching better performances and reducing energy consumption.

More information: Zhenghao Yin et al, Experimental quantum-enhanced kernel-based machine learning on a photonic processor, Nature Photonics (2025).

Journal information: Nature Photonics

Provided by University of Vienna

Citation: Quantum machine learning: Small-scale photonic quantum processor can already outperform classical counterparts (2025, June 9) retrieved 10 June 2025 from /news/2025-06-quantum-machine-small-scale-photonic.html
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