RAIvSVScGx (explore)

RAIvSVScGx

Full identifier: https://w3id.org/np/RAIvSVScGx3gdwGiNP-SZA6hewBf0v5NQZ3kHgXRLUg-A

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Status

Nanopublication

RAIvSVScGx RoCrate comment approve/disapprove edit as derived nanopublication

""_:FOR/020603"" .

""_:FOR/080110"" .

""_:contact/elija.t.perrier@student.uts.edu.au"" .

"./" .

"2022-03-28T04:39:03.553Z" .

"The QDataSet comprises 52 datasets based on simulations of one- and two-qubit systems evolving in the presence and/or absence of noise subject to a variety of controls. It has been developed to provide a large-scale set of datasets for the training, benchmarking and competitive development of classical and quantum algorithms for common tasks in quantum sciences, including quantum control, quantum tomography and noise spectroscopy. It has been generated using customised code drawing upon base-level Python packages in order to facilitate interoperability and portability across common machine learning and quantum programming platforms. Each dataset consists of 10,000 samples which in turn comprise a range of data relevant to the training of machine learning algorithms for solving optimisation problems. The data includes a range of information (stored in list, matrix or tensor format) regarding quantum systems and their evolution, such as: quantum state vectors, drift and control Hamiltonians and unitaries, Pauli measurement distributions, time series data, pulse sequence data for square and Gaussian pulses and noise and distortion data. The total compressed size of the QDataSet (using Pickle and zip formats) is around 14TB (uncompressed, around 100TB). Researchers can use the QDataSet in a variety of ways to design algorithms for solving problems in quantum control, quantum tomography and quantum circuit synthesis, together with algorithms focused on classifying or simulating such data. We also provide working examples of how to use the QDataSet in practice and its use in benchmarking certain algorithms. The associated paper provides in-depth detail on the QDataSet for researchers who may be unfamiliar with quantum computing, together with specifications for domain experts within quantum engineering, quantum computation and quantum machine learning. The dataset details are set out in the link to raw files. " .

"" .

"[70967290a59911eca9a84993133e6628, {"@id":"_:local-id:public_ocfl:70967290a59911eca9a84993133e6628","@type":"PropertyValue","value":"70967290a59911eca9a84993133e6628","name":"public_ocfl"}]" .

"machine learning" .

"quantum" .

""_:license/http://creativecommons.org/licenses/by/3.0/au"" .

"QDataSet: Quantum Datasets for Machine Learning" .

"2021-01-01/2021-01-01" .

"2022" .

"This is the UTS Research Data Portal. For any questions, please get in touch with us at eResearch-it@uts.edu.au" .

"UTS Research Data Portal" .

"Oni ocfl tools" .

"git+https://github.com/Arkisto-Platform/oni-ocfl.git" .

(xsd:dateTime) .

0009-0008-3635-347X, 18 Jul 2025, 12:01:34 UTC

References

Raw

TriG(txt), JSON-LD(txt), N-Quads(txt), XML(txt)