Real-Time Deterministic QECC Architecture for Supercritical Quantum Register Control Modern superconducting Quantum Processing Units (QPUs) are trapped in an architectural dilemma: software-level error correction (QECC). Relying on stochastic syndrome measurements and probabilistic surface codes means your system consumes up to 99% of its available qubit footprint simply to maintain active coherence. Under sudden electromagnetic interference (EMI) strikes, these probabilistic computation loops generate immense accumulation delays, causing mathematical finite-element solvers to freeze via NaN overflows. The Toosibashi Multi-Vector Telemetry & Sensor Console resolves this problem directly at the physical hardware-register layer. Industrial Value Complete Reclamation of Processing Capacity: By eliminating the software-level QECC overhead, 100% of your physical qubits are reclaimed for actualexecution algorithms. A 50-qubit processor suddenly delivers the raw output of aconventional 5,000-qubit matrix. Fail-Safe Real-Time Sensor Processing: Designed for supercriticalinfrastructures (such as autonomous smart grids, aerospace guidance systems,and high-frequency communication networks), processing millions of high-dimensional vectors completely deterministically without statistical lag. Total NaN-Immunity under Critical EMI Stress: Eliminates filter divergence andsystem freezes under severe transient voltage peaks by safely regularizingelectrical noise into non-dissipative geometric tracks.
Abolfazl Toosibashi (Mon,) studied this question.