Characterization of nested Walsh parity-check filters in a single-photon eight-mode register on a cloud photonic processor

Abstract

We characterize two nested Walsh parity-check filters implemented on Quandela's Belenos cloud photonic processor in a single-photon eight-mode spatial register. The modes are indexed by the vertices of the cube Q3. The filters realize the classical [8,7,2] single-parity-check code, the zero-sum neutral subspace N and the [8,4,4] extended Hamming code, the parity-checked subspace S⊂N with one DC and three face-parity syndrome channels. These are first-quantized path/mode encodings of classical codes: the experiment verifies leakage suppression and syndrome routing, not error correction or protection against photon loss, and all probabilities are conditional on postselected single-photon detections. Across more than 340,000 detections, neutral inputs show residual DC-port leakage of 0.02\%-1.1\% (mean 0.6\%), corresponding to ≈21× suppression relative to the ideal 0.125 DC-capture baseline and 31.6× relative to the measured non-neutral control. Injected DC contamination gives a monotonic soft error signal, and the three face-parity syndrome channels route to their predicted ports with 94-99\% selectivity. A sector-preserving unitary core keeps leakage far below non-neutral controls over one to three applications, with differences dominated by calibration and compilation systematics rather than gate-cycle physics. We quantify these limits, including fixed-pattern separator bias, 0.02 calibration offsets, and compilation scatter near the 10-3 leakage level, and report a Hong-Ou-Mandel degradation episode in which suppression vanished and recovered after recalibration.