Carmen Bisogni , Vincenzo Loia , Michele Nappi , Chiara Pero
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引用次数: 0
Abstract
The rapid evolution of synthetic voice generation and audio manipulation technologies poses significant challenges, raising societal and security concerns due to the risks of impersonation and the proliferation of audio deepfakes. This study introduces a lightweight machine learning (ML)-based framework designed to effectively distinguish between genuine and spoofed audio recordings. Departing from conventional deep learning (DL) approaches, which mainly rely on image-based spectrogram features or learning-based audio features, the proposed method utilizes a diverse set of hand-crafted audio features – such as spectral, temporal, chroma, and frequency-domain features – to enhance the accuracy of deepfake audio content detection. Through extensive evaluation and experiments on three well-known datasets, ASVSpoof2019, FakeAVCelebV2, and an In-The-Wild database, the proposed solution demonstrates robust performance and a high degree of generalization compared to state-of-the-art methods. In particular, our method achieved 89% accuracy on ASVSpoof2019, 94.5% on FakeAVCelebV2, and 94.67% on the In-The-Wild database. Additionally, the experiments performed on explainability techniques clarify the decision-making processes within ML models, enhancing transparency and identifying crucial features essential for audio deepfake detection.
期刊介绍:
The central focus of this journal is the computer analysis of pictorial information. Computer Vision and Image Understanding publishes papers covering all aspects of image analysis from the low-level, iconic processes of early vision to the high-level, symbolic processes of recognition and interpretation. A wide range of topics in the image understanding area is covered, including papers offering insights that differ from predominant views.
Research Areas Include:
• Theory
• Early vision
• Data structures and representations
• Shape
• Range
• Motion
• Matching and recognition
• Architecture and languages
• Vision systems