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Related Experiment Videos

IoT-Oriented Security for Small Sensor Systems Using DnCNN Denoising and Multimodal Feature Fusion for Image Forgery

Nimra Nasir1, Syeda Sitara Waseem1, Muhammad Bilal2

  • 1Department of Computer Science & IT, The Govt. Sadiq College Women University, Bahawalpur 63100, Pakistan.

Sensors (Basel, Switzerland)
|February 27, 2026
PubMed
Summary
This summary is machine-generated.

MultiFusion enhances image forgery detection by combining multiple forensic cues, improving security for CCTV, sensors, and IoT devices. This advanced framework offers high accuracy and interpretability for authenticating sensor-generated content.

Keywords:
CCTV securityGANsIoT securitydeep learningdigital forensicsexplainable AIgenerative adversarial networksimage forgery detectionmedia authenticationmulti-cue fusionnoise residualssensor forensicssurveillance systemsvision transformer

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Area of Science:

  • Digital Forensics
  • Computer Vision
  • Artificial Intelligence

Background:

  • Increasing use of CCTV, miniature sensors, and IoT devices raises concerns about image authenticity.
  • Advanced editing tools and generative models create sophisticated forgeries undetectable by traditional methods.
  • Existing algorithms often rely on single forensic cues, limiting their robustness against diverse manipulations.

Purpose of the Study:

  • To develop a novel forgery detection framework, MultiFusion, for authenticating sensor-generated images.
  • To address the limitations of single-cue forensic methods by integrating complementary image characteristics.
  • To enhance the interpretability of forgery detection results.

Main Methods:

  • MultiFusion framework integrates SRM-based noise residuals, EfficientNet-B0 hierarchical texture features, and vision transformer global structural relationships.
  • A DnCNN denoising layer preprocesses images to suppress sensor noise and preserve tampering traces.
  • Explainable AI techniques, combining Grad-cam and transformer attention maps, generate interpretable heatmaps highlighting manipulated regions.

Main Results:

  • MultiFusion achieved high detection accuracy of 96.69% on the CASIA 2.0 dataset.
  • The framework demonstrated good generalization capabilities across different image types and manipulations.
  • Interpretable heatmaps effectively identified regions of image manipulation.

Conclusions:

  • The MultiFusion framework offers a robust and explainable solution for image forgery detection.
  • Its multimodal feature fusion and normalized denoising advance the authentication of CCTV, sensor, and IoT imagery.
  • The integration of explainable AI provides crucial insights into detected manipulations.