PRNU Analysis
Sensor Fingerprint Detection
Photo Response Non-Uniformity (PRNU) analysis detects unique camera sensor fingerprints that are impossible for AI to replicate. Real cameras have manufacturing imperfections that create consistent noise patterns - AI images lack these authentic signatures.
How PRNU Analysis Works
Every camera sensor has unique imperfections from the manufacturing process. These create a consistent "fingerprint" pattern in all photos taken by that camera. AI generators cannot replicate this authentic sensor noise, making PRNU one of the most reliable detection methods.
Extract
Isolate noise residual
Variance
Measure PRNU variance
Correlation
Check spatial patterns
Verify
Block consistency
Key Metrics
PRNU Variance
Measures the variation in sensor noise patterns. Real cameras have distinctive variance patterns, while AI images have uniform synthetic noise.
Spatial Correlation
Real sensor noise has spatial correlation patterns from physical sensor layout. AI lacks these authentic correlations.
Why PRNU is Highly Effective
- ● Unique Fingerprint: Every camera sensor has a unique PRNU pattern that cannot be replicated
- ● Physical Origin: Comes from manufacturing imperfections in silicon wafers
- ● Robust to Editing: PRNU patterns persist through most image processing
- ● Cross-Generator: Works against all AI generators equally well
Frequently Asked Questions
What is PRNU analysis?
PRNU (Photo Response Non-Uniformity) analysis examines unique sensor noise patterns that act like a fingerprint for real cameras. AI-generated images lack these authentic sensor patterns.
Why is PRNU reliable for AI detection?
Every camera sensor has manufacturing imperfections creating unique noise patterns. AI generators cannot replicate these authentic hardware signatures, making their absence a strong indicator of synthetic content.
How is PRNU extracted from images?
We use wavelet denoising to separate the image content from the noise layer. The noise residual is then analyzed for statistical properties characteristic of real sensor noise.
Does PRNU work on compressed images?
Yes, PRNU patterns persist through moderate JPEG compression (quality 50+). Heavy compression or multiple re-compressions can degrade the signal but rarely eliminate it completely.
Can AI images fake PRNU patterns?
Current AI generators do not replicate authentic PRNU. Even if synthetic noise is added, it lacks the statistical properties and spatial correlations of real sensor noise.
What is the noise variance threshold?
Real photos typically have noise variance between 0.001-0.01. AI images often show unnaturally low variance (<0.0005) or synthetic uniform noise patterns.
Does image editing affect PRNU?
Light editing preserves PRNU. Heavy filtering, resizing, or noise reduction can weaken it. This is why we use PRNU alongside other detection methods in our ensemble.
How accurate is PRNU analysis alone?
PRNU analysis achieves 75-85% accuracy as a standalone method. Its value increases significantly when combined with other detection techniques in our ensemble approach.
What about smartphone photos?
Smartphone cameras have distinct PRNU patterns. Computational photography may alter these patterns somewhat, but genuine sensor noise characteristics typically remain detectable.
Why is PRNU weighted at 15%?
PRNU provides strong evidence of camera origin but can be affected by post-processing. The 15% weight balances its reliability with methods less sensitive to image modifications.
Métodos relacionados
Detección ML
Nuestra detección ML usa modelos Transformer entrenados en millones de imágenes.
Análisis de Frecuencia
El análisis del dominio de frecuencia examina la distribución de componentes de alta y baja frecuencia en una imagen. Las imágenes generadas por IA típicamente carecen del ruido natural de alta frecuencia presente en fotografías reales.
Análisis de gradiente
Analyzes edge patterns and texture characteristics using Sobel, Canny, and Laplacian operators. AI images often have unnaturally smooth or uniform gradients.
Patrón de ruido
Las fotografías reales contienen patrones de ruido únicos de los sensores de cámara que varían a través de la imagen. Las imágenes generadas por IA tienen una distribución de ruido anormalmente uniforme.
Análisis de metadatos
Los metadatos de imagen contienen pistas valiosas sobre su origen. Analizamos datos EXIF, firmas de software y otra información incrustada para identificar herramientas de generación de IA.
Huella GAN
Detecta artefactos específicos de GAN como patrones de tablero de ajedrez y bandas de color.
Análisis de textura
Análisis Local Binary Pattern para anomalías de textura en imágenes IA.
Detección Anatómica
Los generadores de imágenes de IA a menudo crean errores anatómicos que los humanos reconocen inmediatamente como incorrectos. Usamos visión por computadora para detectar estos errores reveladores.
Verificación C2PA
C2PA (Coalition for Content Provenance and Authenticity) es un estándar de la industria para rastrear el origen y la historia del contenido digital a través de firmas criptográficas.
Semantic Inconsistency Detection
Detects logical inconsistencies like incorrect shadows, impossible perspectives, distorted reflections, and violations of physical laws that AI often produces.
Human Biometric Analysis
Uses MediaPipe to analyze human anatomy for incorrect finger counts, asymmetric eyes, unnatural skin texture, and other anatomical anomalies common in AI-generated faces.
Lighting Physics Validation
Validates light source consistency, shadow direction physics, specular highlight accuracy, and color temperature uniformity across the image.
Compression Artifact Analysis
Analyzes JPEG compression artifacts to estimate quality levels and detect re-compression patterns that indicate image manipulation or AI generation.
Edge Sharpness Analysis
Analyzes sharpness distribution across the image and validates depth-of-field consistency. AI often produces unnaturally uniform sharpness.
Statistical Pattern Analysis
Analyzes statistical properties including Shannon entropy, histogram patterns, and Benford's Law compliance to detect synthetic image characteristics.
Chromatic Aberration Analysis
Detects the absence of chromatic aberration (color fringing) that real camera lenses produce. AI images lack these optical artifacts.
Micro-Texture Analysis
Analyzes microscopic texture patterns for repetition, uniformity, and unnatural randomness that AI generators often exhibit.
Color Palette Analysis
Analyzes color distribution including saturation levels, color diversity, and white balance consistency. AI images often have oversaturated colors.
Verificar Tu Imagen
Todos los métodos se combinan usando puntuación ponderada para producir un veredicto final con nivel de confianza.
Probar Ahora