Edge-Aware Normalized Attention for Efficient and Detail-Preserving Single Image Super-Resolution

Single-image super-resolution (SISR) remains highly ill-posed because recovering structurally faithful high-frequency content from a single low-resolution observation is ambiguous. Existing edge-aware methods often attach edge priors or attention branches onto increasingly complex backbones, yet ad hoc fusion frequently introduces redundancy, unstable optimization, or limited structural gains. We address this gap with an edge-guided attention mechanism that derives an adaptive modulation map from jointly encoded edge features and intermediate feature activations, then applies it to normalize and reweight responses, selectively amplifying structurally salient regions while suppressing spurious textures. In parallel, we integrate this mechanism into a lightweight residual design trained under a composite objective combining pixel-wise, perceptual, and adversarial terms to balance fidelity, perceptual realism, and training stability. Extensive experiments on standard SISR benchmarks demonstrate consistent improvements in structural sharpness and perceptual quality over SRGAN, ESRGAN, and prior edge-attention baselines at comparable model complexity. The proposed formulation provides (i) a parameter-efficient path to inject edge priors, (ii) stabilized adversarial refinement through a tailored multiterm loss, and (iii) enhanced edge fidelity without resorting to deeper or heavily overparameterized architectures. These results highlight the effectiveness of principled edge-conditioned modulation for advancing perceptual super-resolution.