VENUS: A geometrical representation for quantum state visualization
Visualizations have played a crucial role in helping quantum computing users explore quantum states in various quantum computing applications. Among them, Bloch Sphere is the widely-used visualization for showing quantum states, which leverages angles to represent quantum amplitudes. However, it can...
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Institutional Knowledge at Singapore Management University
2023
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sg-smu-ink.sis_research-96002024-01-25T08:31:43Z VENUS: A geometrical representation for quantum state visualization RUAN, Shaolun YUAN, Ribo GUAN, Qiang LIN, Yanna MAO, Ying JIANG, Weiwen WANG, Zhepeng XU, Wei Yong WANG, Visualizations have played a crucial role in helping quantum computing users explore quantum states in various quantum computing applications. Among them, Bloch Sphere is the widely-used visualization for showing quantum states, which leverages angles to represent quantum amplitudes. However, it cannot support the visualization of quantum entanglement and superposition, the two essential properties of quantum computing. To address this issue, we propose VENUS, a novel visualization for quantum state representation. By explicitly correlating 2D geometric shapes based on the math foundation of quantum computing characteristics, VENUS effectively represents quantum amplitudes of both the single qubit and two qubits for quantum entanglement. Also, we use multiple coordinated semicircles to naturally encode probability distribution, making the quantum superposition intuitive to analyze. We conducted two well-designed case studies and an in-depth expert interview to evaluate the usefulness and effectiveness of VENUS. The result shows that VENUS can effectively facilitate the exploration of quantum states for the single qubit and two qubits. 2023-06-01T07:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/8597 info:doi/10.1111/cgf.14827 https://ink.library.smu.edu.sg/context/sis_research/article/9600/viewcontent/2303.08366.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University Quantum computing data visualization quantum state Artificial Intelligence and Robotics Graphics and Human Computer Interfaces |
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Quantum computing data visualization quantum state Artificial Intelligence and Robotics Graphics and Human Computer Interfaces RUAN, Shaolun YUAN, Ribo GUAN, Qiang LIN, Yanna MAO, Ying JIANG, Weiwen WANG, Zhepeng XU, Wei Yong WANG, VENUS: A geometrical representation for quantum state visualization |
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Visualizations have played a crucial role in helping quantum computing users explore quantum states in various quantum computing applications. Among them, Bloch Sphere is the widely-used visualization for showing quantum states, which leverages angles to represent quantum amplitudes. However, it cannot support the visualization of quantum entanglement and superposition, the two essential properties of quantum computing. To address this issue, we propose VENUS, a novel visualization for quantum state representation. By explicitly correlating 2D geometric shapes based on the math foundation of quantum computing characteristics, VENUS effectively represents quantum amplitudes of both the single qubit and two qubits for quantum entanglement. Also, we use multiple coordinated semicircles to naturally encode probability distribution, making the quantum superposition intuitive to analyze. We conducted two well-designed case studies and an in-depth expert interview to evaluate the usefulness and effectiveness of VENUS. The result shows that VENUS can effectively facilitate the exploration of quantum states for the single qubit and two qubits. |
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text |
| author |
RUAN, Shaolun YUAN, Ribo GUAN, Qiang LIN, Yanna MAO, Ying JIANG, Weiwen WANG, Zhepeng XU, Wei Yong WANG, |
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RUAN, Shaolun YUAN, Ribo GUAN, Qiang LIN, Yanna MAO, Ying JIANG, Weiwen WANG, Zhepeng XU, Wei Yong WANG, |
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RUAN, Shaolun |
| title |
VENUS: A geometrical representation for quantum state visualization |
| title_short |
VENUS: A geometrical representation for quantum state visualization |
| title_full |
VENUS: A geometrical representation for quantum state visualization |
| title_fullStr |
VENUS: A geometrical representation for quantum state visualization |
| title_full_unstemmed |
VENUS: A geometrical representation for quantum state visualization |
| title_sort |
venus: a geometrical representation for quantum state visualization |
| publisher |
Institutional Knowledge at Singapore Management University |
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2023 |
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https://ink.library.smu.edu.sg/sis_research/8597 https://ink.library.smu.edu.sg/context/sis_research/article/9600/viewcontent/2303.08366.pdf |
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