Noise analysis for the Sorkin and Peres tests performed on a quantum computer

We use quantum computers to test the foundations of quantum mechanics through quantum algorithms that implement some of the experimental tests as the basis of the theory's postulates. These algorithms can be used as a test of the physical theory under the premise of perfect hardware or as a test of the hardware under the premise that quantum theory is correct. In this work, we show how the algorithms can be used to test the efficacy of a quantum computer in obeying the postulates of quantum mechanics. We study the effect of different types of noise on the results of experimental tests of the postulates. A salient feature of this noise analysis is that it is deeply rooted in the fundamentals of quantum mechanics as it highlights how systematic errors affect the quantumness of the quantum computer.

Automated summary

We use quantum computers to test the foundations of quantum mechanics through implementing quantum algorithms that serve as experimental tests for the theory's postulates. These algorithms can be used to test the efficacy of a quantum computer in obeying the postulates, assuming perfect hardware, or to test the hardware under the assumption that quantum theory is correct. This work demonstrates how algorithms can be utilized to examine the impact of different types of noise on experimental tests of the postulates, revealing how systematic errors affect the quantumness of the quantum computer.