Immense Fidelity Enhancement of Encoded Quantum Bell Pairs at Short and Long-distance Communication along with Generalized Design of Circuit (2303.07425v1)

Abstract: Quantum entanglement is a unique criterion of the quantum realm and an essential tool to secure quantum communication. Ensuring high-fidelity entanglement has always been a challenging task owing to interaction with the hostile channel environment created due to quantum noise and decoherence. Though several methods have been proposed, achieving almost 100% error correction is still a gigantic task. As one of the main contributions of this work, a new model for large distance communication has been introduced, which can correct all bit flip errors or other errors quite extensively if proper encoding is used. To achieve this purpose, at the very first step, the idea of differentiating the long and short-distance applications has been introduced. Short-distance is determined by the maximum range of applying unitary control gates by the qubit technology. As far as we know, there is no previous work that distinguishes long and short distance applications. At the beginning, we have applied stabilizer formalism and Repetition Code for decoding to distinguish the error correcting ability in long and short distance communication. Particularly for short distance communication, it has been demonstrated that a properly encoded bell state can identify all the bit flip, or phase flip errors with 100% accuracy theoretically. In contrast, if the bell states are used in long distance communication, the error-detecting and correcting ability reduces at huge amounts. To increase the fidelity significantly and correct the errors quite extensively for long-distance communication, a new model based on classical communication protocol has been proposed. All the required circuits in these processes have been generalized during encoding. Proposed analytical results have also been verified with the Simulation results of IBM QISKIT QASM.