Efficient Two-stream Model for Anomaly Detection with SAM Guidance

The proposed SAM-guided Two-stream Lightweight Model for anomaly detection introduces a novel approach that aligns with the practical requirements of model efficiency and mobile-friendliness in industrial applications. Compared to traditional anomaly detection methods, this model leverages the robust generalization capabilities of Segment Anything (SAM) to effectively localize unseen anomalies and diverse real-world patterns. By employing two lightweight image encoders guided by SAM's knowledge, the model can generate discriminative and general feature representations in both normal and anomalous regions. This approach enhances the differentiation of features when facing anomalous regions, leading to competitive performance on benchmark datasets like MVTec AD.

Using a knowledge distillation framework in anomaly detection models has significant implications for enhancing performance and addressing challenges related to unseen anomalies. In this study, the knowledge distillation process involves transferring comprehensive knowledge from a fixed SAM teacher network to two student streams within the Two-stream Lightweight Model. The plain student stream is trained to generate generalized feature representations relevant to anomaly detection tasks, while the denoising student stream focuses on reconstructing normal features accurately. This framework helps overcome limitations related to architectural similarities between networks and shared data flows, enabling more precise representation of anomalies during inference.

The findings from this study have several implications for real-world industrial applications beyond benchmark datasets: Efficient Anomaly Detection: The SAM-guided Two-stream Lightweight Model offers an efficient solution for detecting anomalies in various domains such as industrial quality control, medical diagnoses, and video surveillance. Generalizability: The robust generalization capabilities demonstrated by this model make it suitable for handling diverse types of anomalies encountered in practical scenarios. Model Efficiency: With about 16M parameters and fast inference times (20ms), this model proves effective while being resource-efficient—a crucial factor for deployment in real-world settings. Practical Implementation: By showcasing competitive results on challenging datasets like VisA and DAGM, the model demonstrates its effectiveness across different domains beyond standard benchmarks. Enhanced Localization: The ability of the FA module within STLM to precisely locate anomalies can be invaluable in industries where accurate defect localization is critical. These implications highlight how advancements in anomaly detection models can translate into tangible benefits for real-world applications requiring reliable anomaly identification and localization capabilities with minimal computational resources required at scale.