Overcoming Fourier Locking in Quantum Data Re-uploading Classifiers via Spectral Homotopy
Abstract
Data re-uploading parameterized quantum circuits (DRU-PQCs) are universal function approximators, yet their expressivity produces oscillatory, non-convex loss landscapes that resist gradient-based optimization. We show that the primary optimization bottleneck in DRU-PQCs is not insufficient capacity but a structural failure mode we term Fourier locking (FL): because encoding weights and entangling layers are nonlinearly coupled, random initialization on high-frequency targets collapses the encoding parameters into spurious local minima. Two Fisher diagnostics characterize FL. The input-space quantum Fisher information Fx measures the effective frequency content of the encoded state; the Fisher discriminant ratio of the measured features measures their alignment with the class labels. In two independent 50-seed experiments, the locking is literal: trapped circuits hold Fx frozen for the entire run, while escaping circuits migrate their frequency content (direct training: rpb = -0.48; curriculum: d = 1.34; both p < 0.001). The replicated signature is this spectral mobility, not any endpoint value of Fx, and trapped circuits retain a fully non-degenerate parameter-space QFIM (rpb ≈ 0): the failure is spectral misalignment of a responsive state, not a loss of geometric sensitivity. A frequency-staged homotopy protocol that paces the target frequency (f: 1.0 3.0) convexifies the early loss landscape; escaping circuits raise Fx in step with the curriculum, and the escape rate triples (18% vs. 6%). Fourier locking is a frequency-alignment problem, and its remedy is frequency pacing.
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