Cross-Platform Optimization Scheme for Quantum Processors Based on κ-Qubit Network Topological Stability

This paper proposes a topological stability optimization scheme for quantum processors based on the quantum gravity framework constructed with the physicalized Woodin cardinal κ (κ = 118±25). The core innovations include: establishing a κ-bit network topological fidelity model, designing a cross-platform configuration mapping protocol that maps quantum gates to particle topological configurations via K-theory, and conducting experimental validation. Experiments on IBMQ and Xanadu platforms show that this scheme can improve quantum fidelity by 7-13% and reduce compi lation time by 65%. This work addresses the essential problem of environmental noise sensitivity in current quantum computing and provides a theoretical-experimental bridge for fault-tolerant quan tum computers.