Edge Sharpness Analysis
Depth-of-Field Consistency
Analyzes sharpness distribution across the image and validates depth-of-field consistency. AI often produces unnaturally uniform sharpness.
Frequently Asked Questions
What is edge sharpness distribution?
Real photos have varying sharpness based on focus distance - objects at the focal plane are sharp while others are blurred. AI often produces uniformly sharp images throughout.
How is depth-of-field analyzed?
The detector measures sharpness at different estimated depths. Real DoF follows optical laws with smooth blur transitions; AI blur often has abrupt changes.
Why do AI images have uniform sharpness?
AI models don't simulate lens optics. They generate all details equally unless specifically prompted for bokeh, resulting in flat sharpness profiles.
Can AI-generated bokeh be detected?
Yes, AI-generated blur patterns often have unrealistic characteristics like uniform blur circles, incorrect bokeh shapes, or blur that doesn't correlate with depth.
What about photos with f/16 aperture?
Deep depth-of-field photos still have subtle sharpness variations and proper lens characteristics like diffraction softening. AI doesn't replicate these optical properties.
How does this detect upscaled images?
AI upscaling often adds sharpness uniformly. This creates unnaturally consistent edge profiles that differ from optically captured detail.
What is the sharpness coefficient of variation?
This measures how much sharpness varies across the image. Real photos have high variation (0.3-0.8); AI images often have low variation (0.1-0.3).
Are motion blur and DoF blur different?
Yes, motion blur is directional while DoF blur is uniform. AI often confuses these, creating motion-style blur when DoF is intended.
Does sharpening affect detection?
Post-processing sharpening can affect results, but it creates distinctive halo artifacts that the detector also identifies as non-natural patterns.
Why is this weighted at 6%?
Sharpness analysis provides useful signals but can be affected by post-processing and display scaling. It complements other methods rather than serving as a primary detector.
相关方法
机器学习检测
我们的机器学习检测使用最先进的Transformer模型,在数百万张图像上训练,以区分真实照片和AI生成内容。
PRNU分析
光响应非均匀性(PRNU)检测来自制造缺陷的独特相机传感器指纹。AI图像无法复制这些真实的传感器签名。
频率分析
频域分析检查图像中高频和低频分量的分布。AI生成的图像通常缺乏真实照片中存在的自然高频噪声。
梯度分析
使用Sobel、Canny和Laplacian算子分析边缘模式和纹理特征。AI图像通常具有不自然平滑或均匀的梯度。
噪声模式
真实照片包含来自相机传感器的独特噪声模式,这些模式在图像中有所不同。AI生成的图像具有不自然的均匀噪声分布。
元数据分析
图像元数据包含关于其来源的重要线索。我们分析EXIF数据、软件签名和其他嵌入信息以识别AI生成工具。
GAN指纹
检测GAN特有的伪影,如棋盘格图案、色带和生成对抗网络特有的频谱异常。
纹理分析
局部二值模式分析用于检测AI生成图像中常见的纹理异常。测量均匀性、熵和同质性。
人体解剖检测
AI图像生成器经常创建人类立即识别为错误的解剖错误。我们使用计算机视觉来检测这些明显的错误。
C2PA验证
C2PA是通过加密签名跟踪数字内容来源和历史的行业标准。
Semantic Inconsistency Detection
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Human Biometric Analysis
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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.
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.