Services d'informatique quantique/en: Difference between revisions

Created page with "== Applications == 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; * Finance: quantum computing can speed up portfolio risk assessment and fraud detection; * Molecular modeling: quantum computing can simulate more complex chemical systems and simulate reactions in real time; * Meteorology: quantum computing can increase the..."
(Created page with "<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.")
(Created page with "== Applications == 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; * Finance: quantum computing can speed up portfolio risk assessment and fraud detection; * Molecular modeling: quantum computing can simulate more complex chemical systems and simulate reactions in real time; * Meteorology: quantum computing can increase the...")
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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 is in place and promises greater parallelization for solving complex problems that cannot be managed by classical computing systems.


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== Applications ==
== Applications ==
L'optimisation de problèmes complexes est l'un des domaines les plus prometteurs pour le calcul quantique qui peut s'appliquer à plusieurs domaines de recherche&nbsp;:
Optimization of complex problems is one of the most promising areas for quantum computing in several research areas:
* Apprentissage automatique : l’ordinateur quantique pourrait permettre de réduire les temps d’apprentissage et les délais de traitement;
* Machine learning: quantum computing can reduce training and processing times;
* Finances : l'ordinateur quantique pourrait accélérer l'évaluation de risques de portefolios et la détection de fraude;
* Finance: quantum computing can speed up portfolio risk assessment and fraud detection;
* Modélisation moléculaire : l'ordinateur quantique pourrait permettre de simuler des systèmes chimiques plus complexes et simuler des réactions en temps réel;
* Molecular modeling: quantum computing can simulate more complex chemical systems and simulate reactions in real time;
* Météorologie: l'ordinateur quantique pourrait permettre d'augmenter le nombre de variables pour les prévisions météorologiques;
* Meteorology: quantum computing can increase the number of variables for weather forecasting;
* Logistique: l'ordinateur quantique pourrait permettre d'optimiser la logistique et la planification des flux de travail associés à la gestion des chaînes d'approvisionnement.
* Logistics: quantum computing can optimize logistics and workflow planning associated with supply chain management.
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