| """ |
| branches/diffusion_branch.py |
| ----------------------------- |
| Branch 5: Diffusion Residual Analysis Branch |
| STATUS: COMPLETE β no training required (signal processing) |
| |
| Detects denoising traces and residual noise patterns left by diffusion models |
| (e.g. Stable Diffusion, DALL-E, Midjourney). |
| |
| Technique: |
| - Residual noise map : image β gaussian_blur(image) |
| - High-pass filtering : captures fine-grained noise structure |
| - Noise statistics : kurtosis, variance, power spectral density |
| - Local noise uniformity : AI images have suspiciously uniform noise |
| |
| Research background: |
| Corvi et al. (2023) demonstrated that diffusion models leave detectable |
| denoising artifacts in the residual noise domain. Unlike real cameras |
| (photon shot noise, sensor noise), diffusion residuals show elevated |
| uniformity and dampened high-frequency kurtosis. |
| |
| Output: |
| { |
| "prob_fake" : float in [0, 1], |
| "confidence" : float in [0, 1], |
| "noise_map" : np.ndarray (H, W) β residual noise for visualization |
| } |
| """ |
|
|
| import numpy as np |
| import cv2 |
| from scipy.stats import kurtosis, skew |
| from scipy.signal import welch |
| from utils.image_utils import to_grayscale |
|
|
|
|
| |
| |
| |
|
|
| def _compute_residual_noise(gray: np.ndarray, sigma: int = 3) -> np.ndarray: |
| """ |
| Residual noise map = image β Gaussian-smoothed image. |
| Real camera noise is random; diffusion noise shows structured patterns. |
| Returns residual (H, W) float32, can have negative values. |
| """ |
| gray_u8 = (np.clip(gray, 0, 1) * 255).astype(np.uint8) |
| kernel_size = sigma * 6 + 1 |
| blurred = cv2.GaussianBlur(gray_u8, (kernel_size, kernel_size), sigma) |
| residual = gray_u8.astype(np.float32) - blurred.astype(np.float32) |
| return residual |
|
|
|
|
| def _noise_kurtosis_score(residual: np.ndarray) -> float: |
| """ |
| Real camera noise follows near-Gaussian distribution (kurtosis β 3). |
| Diffusion model residuals are flatter (lower kurtosis) or spikier. |
| Returns score in [0, 1]. |
| """ |
| flat = residual.flatten() |
| kurt = float(kurtosis(flat, fisher=False)) |
| |
| |
| if kurt < 2.5: |
| score = np.clip((2.5 - kurt) / 2.5, 0.0, 1.0) |
| elif kurt > 6.0: |
| score = np.clip((kurt - 6.0) / 10.0, 0.0, 1.0) |
| else: |
| score = 0.0 |
| return float(score) |
|
|
|
|
| def _noise_variance_score(residual: np.ndarray) -> float: |
| """ |
| Very low residual variance: AI image may have been denoised too aggressively. |
| Very high variance: fake noise injection. |
| Returns score in [0, 1]. |
| """ |
| var = float(np.var(residual)) |
| |
| if var < 1.5: |
| score = np.clip((1.5 - var) / 1.5, 0.0, 1.0) |
| elif var > 30.0: |
| score = np.clip((var - 30.0) / 50.0, 0.0, 1.0) |
| else: |
| score = 0.0 |
| return float(score) |
|
|
|
|
| def _noise_uniformity_score(residual: np.ndarray) -> float: |
| """ |
| Local noise variance uniformity across image patches. |
| Real cameras: noise varies by region (ISO, lighting). |
| Diffusion models: noise is spatially uniform. |
| Returns score in [0, 1] β higher = more uniform = more likely fake. |
| """ |
| H, W = residual.shape |
| patch_size = 32 |
| local_vars = [] |
|
|
| for r in range(0, H - patch_size, patch_size): |
| for c in range(0, W - patch_size, patch_size): |
| patch = residual[r:r+patch_size, c:c+patch_size] |
| local_vars.append(float(np.var(patch))) |
|
|
| if len(local_vars) < 4: |
| return 0.5 |
|
|
| cv_of_var = float(np.std(local_vars) / (np.mean(local_vars) + 1e-8)) |
| |
| |
| score = np.clip((0.5 - cv_of_var) / 0.5, 0.0, 1.0) |
| return float(score) |
|
|
|
|
| def _high_pass_psd_score(residual: np.ndarray) -> float: |
| """ |
| Power Spectral Density (PSD) via Welch's method on residual. |
| Examines high-frequency content in the noise. |
| Diffusion models tend to suppress certain frequency bands. |
| Returns score in [0, 1]. |
| """ |
| flat = residual.flatten().astype(np.float64) |
| freqs, power = welch(flat, nperseg=256) |
|
|
| if len(power) < 10: |
| return 0.5 |
|
|
| |
| n = len(power) |
| low_power = float(np.mean(power[:n // 4])) |
| high_power = float(np.mean(power[3*n // 4:])) |
|
|
| if low_power < 1e-8: |
| return 0.5 |
|
|
| ratio = high_power / (low_power + 1e-8) |
| |
| |
| if ratio < 0.10: |
| score = np.clip((0.10 - ratio) / 0.10, 0.0, 1.0) |
| elif ratio > 0.60: |
| score = np.clip((ratio - 0.60) / 0.40, 0.0, 1.0) |
| else: |
| score = 0.0 |
| return float(score) |
|
|
|
|
| |
| |
| |
|
|
| def run_diffusion_branch(img: np.ndarray) -> dict: |
| """ |
| Run the complete Diffusion Residual Analysis Branch. |
| |
| Args: |
| img : float32 numpy array (H, W, 3) in [0, 1] β RGB image |
| |
| Returns: |
| dict with keys: |
| "prob_fake" : float β probability the image is AI-generated |
| "confidence" : float β certainty of this branch's estimate |
| "noise_map" : np.ndarray (H, W) float32 β residual noise (for viz) |
| """ |
| gray = to_grayscale(img) |
|
|
| |
| residual_fine = _compute_residual_noise(gray, sigma=1) |
| residual_coarse = _compute_residual_noise(gray, sigma=3) |
|
|
| |
| kurtosis_score = _noise_kurtosis_score(residual_fine) |
| variance_score = _noise_variance_score(residual_fine) |
| uniformity_score = _noise_uniformity_score(residual_fine) |
| psd_score = _high_pass_psd_score(residual_coarse) |
|
|
| |
| prob_fake = ( |
| 0.30 * kurtosis_score + |
| 0.20 * variance_score + |
| 0.35 * uniformity_score + |
| 0.15 * psd_score |
| ) |
| prob_fake = float(np.clip(prob_fake, 0.0, 1.0)) |
|
|
| |
| scores = [kurtosis_score, variance_score, uniformity_score, psd_score] |
| agreement = 1.0 - float(np.std(scores)) |
| confidence = float(np.clip(agreement * 0.88, 0.1, 0.90)) |
|
|
| |
| noise_vis = np.abs(residual_fine) |
| if noise_vis.max() > 0: |
| noise_vis /= noise_vis.max() |
|
|
| return { |
| "prob_fake": prob_fake, |
| "confidence": confidence, |
| "noise_map": noise_vis.astype(np.float32), |
| } |
|
|
