研究目的
To investigate the synchronous and asynchronous conditions in quantum interferences using a double path model and variant logic principle to simulate quantum wave interference patterns and classic particle distributions.
研究成果
The synchronous condition is the key fact to generate quantum wave interference patterns and the asynchronous condition is the key fact to make classic particle distributions. The variant quaternion and other quaternion structures help understand possible properties of usages and limitations for variant simulation systems.
研究不足
The complexity of n-variable function space has a size of 22n. Whole simulation complexity is determined by O(22n × 2N ) as ultra exponent productions. How to overcome the limitations imposed by such complexity and how best to compare and contrast such simulations with real-world experimentation will be key issues in future work.
1:Experimental Design and Method Selection:
A double path model using the Mach–Zehnder interferometer was established. Different approaches of quantum measures: Einstein, CHSH, and Aspect were investigated by quaternion structures. Under multiple-variable logic functions and variant principle, logic functions were transferred into variant logic expression as variant measures.
2:Sample Selection and Data Sources:
N bits of input vectors were exhausted by 2N states for measured data, recursive data were organized into eight histograms.
3:List of Experimental Equipment and Materials:
Not explicitly mentioned in the paper.
4:Experimental Procedures and Operational Workflow:
A variant simulation model was proposed where a given logic function f can be represented as two meta-logic functions f+ and f? to simulate single and double path conditions.
5:Data Analysis Methods:
Results were determined by symmetry/anti-symmetry properties evident in these histograms.
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