wifi-densepose/references/script_5.py

# WiFi DensePose Implementation - Fixed version
# Based on "DensePose From WiFi" by Carnegie Mellon University

import numpy as np
import math
from typing import Dict, List, Tuple, Optional
from collections import OrderedDict
import json

class CSIPhaseProcessor:
    """
    Processes raw CSI phase data through unwrapping, filtering, and linear fitting
    Based on the phase sanitization methodology from the paper
    """
    
    def __init__(self, num_subcarriers: int = 30):
        self.num_subcarriers = num_subcarriers
        print(f"Initialized CSI Phase Processor with {num_subcarriers} subcarriers")
    
    def unwrap_phase(self, phase_data: np.ndarray) -> np.ndarray:
        """
        Unwrap phase values to handle discontinuities
        Phase data shape: (freq_samples, ant_tx, ant_rx) = (150, 3, 3)
        """
        unwrapped = np.copy(phase_data)
        
        # Unwrap along frequency dimension (groups of 30 frequencies)
        for sample_group in range(5):  # 5 consecutive samples
            start_idx = sample_group * 30
            end_idx = start_idx + 30
            
            for tx in range(3):
                for rx in range(3):
                    for i in range(start_idx + 1, end_idx):
                        diff = unwrapped[i, tx, rx] - unwrapped[i-1, tx, rx]
                        
                        if diff > np.pi:
                            unwrapped[i, tx, rx] = unwrapped[i-1, tx, rx] + diff - 2*np.pi
                        elif diff < -np.pi:
                            unwrapped[i, tx, rx] = unwrapped[i-1, tx, rx] + diff + 2*np.pi
        
        return unwrapped
    
    def apply_filters(self, phase_data: np.ndarray) -> np.ndarray:
        """
        Apply median and uniform filters to eliminate outliers
        """
        filtered = np.copy(phase_data)
        
        # Apply smoothing in frequency dimension
        for i in range(1, phase_data.shape[0]-1):
            filtered[i] = (phase_data[i-1] + phase_data[i] + phase_data[i+1]) / 3
        
        return filtered
    
    def linear_fitting(self, phase_data: np.ndarray) -> np.ndarray:
        """
        Apply linear fitting to remove systematic phase drift
        """
        fitted_data = np.copy(phase_data)
        F = self.num_subcarriers
        
        # Process each sample group (5 consecutive samples)
        for sample_group in range(5):
            start_idx = sample_group * 30
            end_idx = start_idx + 30
            
            for tx in range(3):
                for rx in range(3):
                    phase_seq = phase_data[start_idx:end_idx, tx, rx]
                    
                    # Calculate linear coefficients
                    if len(phase_seq) > 1:
                        alpha1 = (phase_seq[-1] - phase_seq[0]) / (2 * np.pi * F)
                        alpha0 = np.mean(phase_seq)
                        
                        # Apply linear fitting
                        frequencies = np.arange(1, len(phase_seq) + 1)
                        linear_trend = alpha1 * frequencies + alpha0
                        fitted_data[start_idx:end_idx, tx, rx] = phase_seq - linear_trend
        
        return fitted_data
    
    def sanitize_phase(self, raw_phase: np.ndarray) -> np.ndarray:
        """
        Complete phase sanitization pipeline
        """
        print("Sanitizing CSI phase data...")
        print(f"Input shape: {raw_phase.shape}")
        
        # Step 1: Unwrap phase
        unwrapped = self.unwrap_phase(raw_phase)
        print("✓ Phase unwrapping completed")
        
        # Step 2: Apply filters
        filtered = self.apply_filters(unwrapped)
        print("✓ Filtering completed")
        
        # Step 3: Linear fitting
        sanitized = self.linear_fitting(filtered)
        print("✓ Linear fitting completed")
        
        return sanitized

class ModalityTranslationNetwork:
    """
    Simulates the modality translation network behavior
    Translates CSI domain features to spatial domain features
    """
    
    def __init__(self, input_shape=(150, 3, 3), output_shape=(3, 720, 1280)):
        self.input_shape = input_shape
        self.output_shape = output_shape
        self.hidden_dim = 512
        
        # Initialize simulated weights
        np.random.seed(42)
        self.amp_weights = np.random.normal(0, 0.1, (np.prod(input_shape), self.hidden_dim//4))
        self.phase_weights = np.random.normal(0, 0.1, (np.prod(input_shape), self.hidden_dim//4))
        self.fusion_weights = np.random.normal(0, 0.1, (self.hidden_dim//2, 24*24))
        
        print(f"Initialized Modality Translation Network:")
        print(f"  Input: {input_shape} -> Output: {output_shape}")
    
    def encode_features(self, amplitude_data, phase_data):
        """
        Simulate feature encoding from amplitude and phase data
        """
        # Flatten inputs
        amp_flat = amplitude_data.flatten()
        phase_flat = phase_data.flatten()
        
        # Simple linear transformation (simulating MLP)
        amp_features = np.tanh(np.dot(amp_flat, self.amp_weights))
        phase_features = np.tanh(np.dot(phase_flat, self.phase_weights))
        
        return amp_features, phase_features
    
    def fuse_and_translate(self, amp_features, phase_features):
        """
        Fuse features and translate to spatial domain
        """
        # Concatenate features
        fused = np.concatenate([amp_features, phase_features])
        
        # Apply fusion transformation
        spatial_features = np.tanh(np.dot(fused, self.fusion_weights))
        
        # Reshape to spatial map
        spatial_map = spatial_features.reshape(24, 24)
        
        # Simulate upsampling to target resolution
        # Using simple bilinear interpolation simulation
        from scipy.ndimage import zoom
        upsampled = zoom(spatial_map, 
                        (self.output_shape[1]/24, self.output_shape[2]/24), 
                        order=1)
        
        # Create 3-channel output
        output = np.stack([upsampled, upsampled * 0.8, upsampled * 0.6])
        
        return output
    
    def forward(self, amplitude_data, phase_data):
        """
        Complete forward pass
        """
        # Encode features
        amp_features, phase_features = self.encode_features(amplitude_data, phase_data)
        
        # Translate to spatial domain
        spatial_output = self.fuse_and_translate(amp_features, phase_features)
        
        return spatial_output

class WiFiDensePoseSystem:
    """
    Complete WiFi DensePose system
    """
    
    def __init__(self):
        self.config = WiFiDensePoseConfig()
        self.phase_processor = CSIPhaseProcessor(self.config.num_subcarriers)
        self.modality_network = ModalityTranslationNetwork()
        
        print("WiFi DensePose System initialized!")
    
    def process_csi_data(self, amplitude_data, phase_data):
        """
        Process raw CSI data through the complete pipeline
        """
        # Step 1: Phase sanitization
        sanitized_phase = self.phase_processor.sanitize_phase(phase_data)
        
        # Step 2: Modality translation
        spatial_features = self.modality_network.forward(amplitude_data, sanitized_phase)
        
        # Step 3: Simulate DensePose prediction
        pose_prediction = self.simulate_densepose_prediction(spatial_features)
        
        return {
            'sanitized_phase': sanitized_phase,
            'spatial_features': spatial_features,
            'pose_prediction': pose_prediction
        }
    
    def simulate_densepose_prediction(self, spatial_features):
        """
        Simulate DensePose-RCNN prediction
        """
        # Simulate person detection
        num_detected = np.random.randint(1, 4)  # 1-3 people
        
        predictions = []
        for i in range(num_detected):
            # Simulate bounding box
            x = np.random.uniform(50, spatial_features.shape[1] - 150)
            y = np.random.uniform(50, spatial_features.shape[2] - 300)
            w = np.random.uniform(80, 150)
            h = np.random.uniform(200, 300)
            
            # Simulate confidence
            confidence = np.random.uniform(0.7, 0.95)
            
            # Simulate keypoints
            keypoints = []
            for kp in range(17):
                kp_x = x + np.random.uniform(-w/4, w/4)
                kp_y = y + np.random.uniform(-h/4, h/4)
                kp_conf = np.random.uniform(0.6, 0.9)
                keypoints.extend([kp_x, kp_y, kp_conf])
            
            # Simulate UV map (simplified)
            uv_map = np.random.uniform(0, 1, (24, 112, 112))
            
            predictions.append({
                'bbox': [x, y, w, h],
                'confidence': confidence,
                'keypoints': keypoints,
                'uv_map': uv_map
            })
        
        return predictions

# Configuration and utility classes
class WiFiDensePoseConfig:
    """Configuration class for WiFi DensePose system"""
    def __init__(self):
        # Hardware configuration
        self.num_transmitters = 3
        self.num_receivers = 3
        self.num_subcarriers = 30
        self.sampling_rate = 100  # Hz
        self.consecutive_samples = 5
        
        # Network configuration
        self.input_amplitude_shape = (150, 3, 3)  # 5 samples * 30 frequencies, 3x3 antennas
        self.input_phase_shape = (150, 3, 3)
        self.output_feature_shape = (3, 720, 1280)  # Image-like feature map
        
        # DensePose configuration
        self.num_body_parts = 24
        self.num_keypoints = 17
        self.keypoint_heatmap_size = (56, 56)
        self.uv_map_size = (112, 112)

class WiFiDataSimulator:
    """Simulates WiFi CSI data for demonstration purposes"""
    
    def __init__(self, config: WiFiDensePoseConfig):
        self.config = config
        np.random.seed(42)  # For reproducibility
    
    def generate_csi_sample(self, num_people: int = 1, movement_intensity: float = 1.0) -> Tuple[np.ndarray, np.ndarray]:
        """Generate simulated CSI amplitude and phase data"""
        # Base CSI signal (environment)
        amplitude = np.ones(self.config.input_amplitude_shape) * 50  # Base signal strength
        phase = np.zeros(self.config.input_phase_shape)
        
        # Add noise
        amplitude += np.random.normal(0, 5, self.config.input_amplitude_shape)
        phase += np.random.normal(0, 0.1, self.config.input_phase_shape)
        
        # Simulate human presence effects
        for person in range(num_people):
            # Random position effects
            pos_x = np.random.uniform(0.2, 0.8)
            pos_y = np.random.uniform(0.2, 0.8)
            
            # Create interference patterns
            for tx in range(3):
                for rx in range(3):
                    # Distance-based attenuation
                    distance = np.sqrt((tx/2 - pos_x)**2 + (rx/2 - pos_y)**2)
                    attenuation = movement_intensity * np.exp(-distance * 2)
                    
                    # Frequency-dependent effects
                    for freq in range(30):
                        freq_effect = np.sin(2 * np.pi * freq / 30 + person * np.pi/2)
                        
                        # Apply effects to all 5 samples for this frequency
                        for sample in range(5):
                            sample_idx = sample * 30 + freq
                            amplitude[sample_idx, tx, rx] *= (1 - attenuation * 0.3 * freq_effect)
                            phase[sample_idx, tx, rx] += attenuation * freq_effect * movement_intensity
        
        return amplitude, phase

# Install scipy for zoom function
try:
    from scipy.ndimage import zoom
except ImportError:
    print("Installing scipy...")
    import subprocess
    import sys
    subprocess.check_call([sys.executable, "-m", "pip", "install", "scipy"])
    from scipy.ndimage import zoom

# Initialize the complete system
print("="*60)
print("WIFI DENSEPOSE SYSTEM DEMONSTRATION")
print("="*60)

config = WiFiDensePoseConfig()
data_simulator = WiFiDataSimulator(config)
wifi_system = WiFiDensePoseSystem()

# Generate and process sample data
print("\n1. Generating sample CSI data...")
amplitude_data, phase_data = data_simulator.generate_csi_sample(num_people=2, movement_intensity=1.5)
print(f"   Generated CSI data shapes: Amplitude {amplitude_data.shape}, Phase {phase_data.shape}")

print("\n2. Processing through WiFi DensePose pipeline...")
results = wifi_system.process_csi_data(amplitude_data, phase_data)

print(f"\n3. Results:")
print(f"   Sanitized phase range: [{results['sanitized_phase'].min():.3f}, {results['sanitized_phase'].max():.3f}]")
print(f"   Spatial features shape: {results['spatial_features'].shape}")
print(f"   Detected {len(results['pose_prediction'])} people")

for i, pred in enumerate(results['pose_prediction']):
    bbox = pred['bbox']
    print(f"   Person {i+1}: bbox=[{bbox[0]:.1f}, {bbox[1]:.1f}, {bbox[2]:.1f}, {bbox[3]:.1f}], confidence={pred['confidence']:.3f}")

print("\nWiFi DensePose system demonstration completed successfully!")
print(f"System specifications:")
print(f"  - Hardware cost: ~$30 (2 TP-Link AC1750 routers)")
print(f"  - Frequency: 2.4GHz ± 20MHz")
print(f"  - Sampling rate: {config.sampling_rate}Hz")
print(f"  - Body parts detected: {config.num_body_parts}")
print(f"  - Keypoints tracked: {config.num_keypoints}")
print(f"  - Works through walls: ✓")
print(f"  - Privacy preserving: ✓")
print(f"  - Real-time capable: ✓")