Services d'informatique quantique/en: Difference between revisions

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== Summary ==
== Summary ==


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Our team of quantum computing analysts provides expertise, support and training on quantum computing and hybrid classical-quantum computing. As of the end of fall 2024, Calcul Québec will offer access to a 24 qubit superconducting quantum computer called [[MonarQ/en|MonarQ]], coupled with the [[Narval/en|Narval]] cluster.
Our team of quantum computing analysts provides expertise, support and training on quantum computing and hybrid classical-quantum computing. As of the fall of 2024, Calcul Québec will offer access to a 24-qubit superconducting quantum computer called [https://docs.alliancecan.ca/wiki/MonarQ MonarQ], coupled with the Narval cluster.
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<b>What is quantum computing?</b> A quantum computer takes advantage of the characteristics of quantum particles (<i>qubits</i>), including superposition of states, constructive and destructive interference, and entanglement. With these properties, a new computational paradigm is in place and promises greater parallelization for solving complex problems that cannot be managed by classical computing systems.
<b>What is quantum computing?</b> A quantum computer takes advantage of the characteristics of quantum particles (<i>qubits</i>), including superposition of states, constructive and destructive interference, and entanglement. With these properties, a new computational paradigm promises greater parallelization to solve complex problems that cannot be managed by classical computing systems.


== Applications ==
== Applications ==
Optimization of complex problems is one of the most promising areas for quantum computing in several research areas:
Optimization of complex problems is one of the most promising areas for quantum computing in several research areas:
* Machine learning: quantum computing can reduce training and processing times;
* Machine learning: quantum computing could reduce training and processing times.
* Finance: quantum computing can speed up portfolio risk assessment and fraud detection;
* Finance: quantum computing could speed up portfolio risk assessment and fraud detection.
* Molecular modeling: quantum computing can simulate more complex chemical systems and simulate reactions in real time;
* Molecular modelling: quantum computing could simulate more complex chemical systems and simulate reactions in real time.
* Meteorology: quantum computing can increase the number of variables for weather forecasting;
* Meteorology: quantum computing could increase the number of variables for weather forecasting.
* Logistics: quantum computing can optimize logistics and workflow planning associated with supply chain management.
* Logistics: quantum computing could optimize logistics and workflow planning associated with supply chain management.


== Software ==
== Software ==


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There are several specialized software libraries for performing quantum computing and developing quantum algorithms. You can use these libraries to build circuits that are run on simulators mimicking the performance and results obtained on a quantum computer. These libraries can be used on all of our clusters.   
Il existe plusieurs bibliothèques logicielles spécialisées pour faire du calcul quantique et pour développer des algorithmes quantiques. Ces bibliothèques permettent de construire des circuits qui sont exécutés sur des simulateurs qui imitent la performance et les résultats obtenus sur un ordinateur quantique. Elles peuvent être utilisées sur toutes les grappes de l’Alliance.
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* [[PennyLane/en|PennyLane]], Python library
* [[PennyLane]], bibliothèque de commandes en Python  
* [[Snowflurry/en|Snowflurry]], Julia library
* [[Snowflurry]], bibliothèque de commandes en Julia
* [[Qiskit/fr|Qiskit]], Python library
* [[Qiskit]], bibliothèque de commandes en Python
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== Technical support ==
== Soutien technique ==
If you have questions on our quantum computing services, please write to [mailto:support@calculquebec.ca support@calculquebec.ca].
Pour des questions sur nos services quantiques, écrivez à [mailto:support@calculquebec.ca support@calculquebec.ca].
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Latest revision as of 16:14, 16 October 2024

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Summary

Our team of quantum computing analysts provides expertise, support and training on quantum computing and hybrid classical-quantum computing. As of the end of fall 2024, Calcul Québec will offer access to a 24 qubit superconducting quantum computer called MonarQ, coupled with the Narval cluster.

What is quantum computing? A quantum computer takes advantage of the characteristics of quantum particles (qubits), including superposition of states, constructive and destructive interference, and entanglement. With these properties, a new computational paradigm promises greater parallelization to solve complex problems that cannot be managed by classical computing systems.

Applications

Optimization of complex problems is one of the most promising areas for quantum computing in several research areas:

  • Machine learning: quantum computing could reduce training and processing times.
  • Finance: quantum computing could speed up portfolio risk assessment and fraud detection.
  • Molecular modelling: quantum computing could simulate more complex chemical systems and simulate reactions in real time.
  • Meteorology: quantum computing could increase the number of variables for weather forecasting.
  • Logistics: quantum computing could optimize logistics and workflow planning associated with supply chain management.

Software

There are several specialized software libraries for performing quantum computing and developing quantum algorithms. You can use these libraries to build circuits that are run on simulators mimicking the performance and results obtained on a quantum computer. These libraries can be used on all of our clusters.

Technical support

If you have questions on our quantum computing services, please write to support@calculquebec.ca.