Quantum Gradient-Based Approach for Edge and Corner Detection Using Sobel Kernels

TL;DR

This paper presents a quantum implementation of Sobel and Harris corner detection methods using two quantum image encoding schemes, demonstrating functional results with potential for future hardware adaptation.

Contribution

It introduces a quantum gradient computation scheme and compares two encoding methods, showing the feasibility of quantum edge and corner detection.

Findings

QPIE encoding yields more stable results than FRQI.

Quantum circuits produce outputs consistent with classical operators.

Overall cost is dominated by state preparation and measurement.

Abstract

Edge detection refers to identifying points in a digital image where intensity changes sharply, indicating object boundaries or structural features. Corners are locations where gray-level intensity changes abruptly in multiple directions and are widely used in feature extraction, object tracking, and 3D modeling. In this study, we present a quantum implementation of Sobel-based edge detection and Harris-style corner detection. Two quantum image encoding methods - Flexible Representation of Quantum Images (FRQI) and Quantum Probability Image Encoding (QPIE) - are used to encode the input data and are comparatively analyzed. The proposed approach introduces a quantum gradient computation scheme based on lag-2 differences, enabling the evaluation of gradient-like features in superposition. To improve detection quality and reduce false positives, a classical post-processing step is applied to candidate corner points identified by the quantum circuit. Results show that the proposed quantum circuits produce outputs consistent with classical Sobel and Harris operators. Furthermore, the QPIE-based configuration yields more stable and coherent results than FRQI, especially under limited measurement shots. While gradient computation can be performed efficiently at the circuit level, the overall cost remains dominated by state preparation, measurement, and classical post-processing. All experiments are conducted under noiseless simulation, and performance on NISQ hardware may be affected by noise and measurement limitations. Therefore, this work demonstrates a functional and scalable quantum realization of classical edge and corner detection methods rather than an end-to-end speedup.