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Autor principal:	Pavlov, Mikhail
Formato:	Recurso digital
Lenguaje:	ruso
Publicado:	Zenodo 2026
Materias:	Quantum computing; variational quantum algorithms; VQAs; ansatz; variational forms; parameterized circuits; reference states; hybrid quantum-classical algorithms; optimization trade-offs; Qiskit; NISQ devices; quantum algorithm workflow; IBM Q; practical quantum computing.
Acceso en línea:	https://doi.org/10.5281/zenodo.18862014
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<h2>Abstract</h2> This practical guide explores the construction and application of ansätze and variational forms in variational quantum algorithms (VQAs), based on IBM Q learning resources. The exercises were performed by the author on May 1, 2024, using IBM Q cloud resources. Ansatz-based methods form the core of all variational algorithms, enabling the systematic exploration of parameterized quantum states to optimize a given objective function. In this lesson, participants first learn how to construct parameterized quantum circuits manually, defining the variational form that generates a family of quantum states suitable for optimization. These parameterized circuits are then applied to a previously prepared reference state, forming the ansatz that serves as the foundation for the variational algorithm. The guide emphasizes practical strategies for balancing computational speed and solution accuracy when exploring the parameter space, highlighting the trade-offs involved in designing efficient variational circuits. Through hands-on exercises in Qiskit, participants gain experience in circuit parameterization, application of ansätze to reference states, and iterative optimization. This approach demonstrates how variational forms enable flexible and scalable representations of quantum states, facilitating practical implementation of hybrid quantum-classical algorithms on noisy intermediate-scale quantum (NISQ) devices. The lesson provides foundational skills for constructing effective variational algorithms in quantum chemistry, combinatorial optimization, and machine learning applications, while reinforcing the conceptual understanding of parameterized quantum state spaces.

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