Development and implementation of a universal quantum simulator using the Qiskit platform

Development and implementation of a universal quantum simulator using the Qiskit platform

Quantum Computers are of great interest for understanding quantum systems due to their advantages in tackling problems that classical computers could not because of their computational differences. Thus, one of the most promising research lines within this field is quantum simulation. In this thesis...

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Tác giả chính: Cofre Caiza, Gabriel Alexander (author)
Định dạng: bachelorThesis
Ngôn ngữ:eng
Được phát hành: 2022
Những chủ đề:
Computación cuántica
Simulación cuántica
Fidelidad
Funciones de Walsh
Simulador Cuántico Universal
Quantum computing
Quantum simulation
Fidelity
Walsh functions
Universal Quantum Simulator
Truy cập trực tuyến:http://repositorio.yachaytech.edu.ec/handle/123456789/540
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Tóm tắt:Quantum Computers are of great interest for understanding quantum systems due to their advantages in tackling problems that classical computers could not because of their computational differences. Thus, one of the most promising research lines within this field is quantum simulation. In this thesis work, we develop and implement a Universal Quantum Simulator (UQS) in the Qiskit platform capable of implementing the quantum circuit of any physical system, which is represented as a sum of local contribution potentials. To test the feasibility of the UQS, we have implemented two well-studied physical systems: Quantum Harmonic Oscillator and the Double Well Potential; and compared their final circuit implementation, state evolution, and circuit depth with previous research work. All these systems were executed by the state vector simulator, noiseless simulator, and then run by real quantum computers: ibmq-quito and ibmq-lima, provided by IBM-Q. The experimental state positions obtained from real quantum chips were compared with the noiseless simulator to verify the states' fidelities using the classical definition. As a result, we obtained that due to the Walsh Functions approximation, Trotterization process, and experimental coherence time of each gate, there exists a considerable amount of noise that does not allow us to notice the system evolution as in the noiseless simulator.

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