PFUSRC-010-A and PFUSRC-010-B have demonstrated respectively from experimental data and fundamental theory that quantum measurement uncertainty originates from violent topological anchoring of target quantum subsystem by measuring apparatus. Large anchoring disturbance difference A drives the ontological field ₁ to perform intrinsic active risk avoidance for topological stability, making quantum information concealed within the low-probability topological domain Pₗow. This paper proposes the conception of Flow Platform, a novel measurement interface designed to suppress ₁ risk avoidance and realize lossless non-destructive quantum readout. The Flow Platform is defined by four core features: global full-system sensing, asymptotically vanishing measurement disturbance (A 0), weak resonant coupling and measurement construction constrained by topological invariants. Derived from the intrinsic framework of PFUSRC, this work provides practical engineering control schemes for A, the exponential relation Tcoh e^- A between quantum coherence and disturbance as well as the 12/11 parity statistical verification criterion. All theoretical deductions are cross-referenced against cutting-edge experiments including quantum capacitance probing, superconducting junction readout and Majorana topological qubit protection. Three feasible falsifiable experimental proposals are put forward to validate the whole theoretical framework.
Zhenmin Wang (Wed,) studied this question.
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