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YOLOv8 Crowd Detection Module - Enhanced for Small Objects
Implements REQ-1, REQ-2, REQ-3: Person detection with bounding boxes and counting
"""
import cv2
import numpy as np
from ultralytics import YOLO
import time
from typing import List, Tuple, Dict
import logging
logger = logging.getLogger(__name__)
class CrowdDetector:
"""
Main crowd detection class using YOLOv8 - Enhanced for small objects
Satisfies SRS Requirements:
- REQ-1: Detect individuals in video frames using pre-trained model
- REQ-2: Display bounding boxes around detected individuals
- REQ-3: Update count continuously as frames are processed
"""
def __init__(self, config: Dict):
"""
Initialize the YOLOv8 detector
Args:
config: Configuration dictionary from config.yaml
"""
self.config = config
self.model_name = config['model']['name']
self.confidence_threshold = config['model']['confidence_threshold']
self.iou_threshold = config['model']['iou_threshold']
self.device = config['model']['device']
self.class_filter = config['model']['class_filter']
self.min_size = config['crowd']['min_detection_size']
# Optimization parameters
self.small_object_mode = config['model'].get('small_object_mode', True)
self.imgsz = 416 # Lower resolution for faster TensorRT inference
# Dynamic mode parameters (can be updated via API)
self.max_det = 300 # Default max detections
self.second_pass_conf = 0.05 # Default second pass confidence
self.duplicate_threshold = 30 # Default duplicate detection threshold
self.min_box_size = 5 # Default minimum box size
# Performance tracking
from collections import deque
self.frame_times = deque(maxlen=30) # Keep last 30 frame times
self.detection_count = 0
self.frame_count = 0 # Track frames for logging throttle
logger.info(f"Initializing YOLOv8 Detector with model: {self.model_name}")
logger.info(f"Device: {self.device}, Confidence: {self.confidence_threshold}")
logger.info(f"Small object mode: {self.small_object_mode}")
# Check for TensorRT optimized model first
tensorrt_model = self.model_name.replace('.pt', '.engine')
use_tensorrt = False
try:
import os
if os.path.exists(tensorrt_model):
logger.info(f"Loading TensorRT optimized model: {tensorrt_model}")
self.model = YOLO(tensorrt_model)
use_tensorrt = True
else:
logger.info(f"Loading PyTorch model: {self.model_name}")
logger.info(f"TIP: Export to TensorRT for 2-3x speedup: yolo export model={self.model_name} format=engine half=True device=0")
self.model = YOLO(self.model_name)
self.model.to(self.device)
use_tensorrt = False
logger.info("YOLOv8 model loaded successfully")
logger.info(f"*** USING {'TensorRT ENGINE' if use_tensorrt else 'PyTorch FP16'} for inference ***")
# GPU Warmup - run dummy inference to compile CUDA kernels
logger.info("Warming up GPU (this may take a few seconds)...")
dummy_frame = np.zeros((416, 416, 3), dtype=np.uint8)
for _ in range(5): # Run 5 warmup passes for better optimization
self.model(dummy_frame, conf=0.5, verbose=False, device=self.device, half=(self.device != "cpu"), imgsz=self.imgsz)
logger.info("GPU warmup complete - ready for fast inference")
except Exception as e:
logger.error(f"Failed to load YOLOv8 model: {e}")
raise
def preprocess_frame(self, frame: np.ndarray) -> np.ndarray:
"""
Light preprocessing - only applied if needed
Returns frame as-is for speed (YOLO handles normalization)
"""
return frame # Skip preprocessing for speed
def detect_additional_pass(self, frame: np.ndarray, existing_detections: List[Dict]) -> List[Dict]:
"""
Additional detection pass with very low confidence for missed small objects
"""
try:
# Second pass with lower confidence threshold for small/distant objects
results = self.model(
frame,
conf=self.second_pass_conf, # Use dynamic second pass confidence
iou=self.iou_threshold,
classes=self.class_filter,
verbose=False,
imgsz=self.imgsz,
device=self.device,
half=(self.device != "cpu")
)
additional_detections = []
existing_centers = [(d['center'][0], d['center'][1]) for d in existing_detections]
for result in results:
boxes = result.boxes
for box in boxes:
x1, y1, x2, y2 = box.xyxy[0].cpu().numpy()
confidence = float(box.conf[0].cpu().numpy())
class_id = int(box.cls[0].cpu().numpy())
width = x2 - x1
height = y2 - y1
center_x = int((x1 + x2) / 2)
center_y = int((y1 + y2) / 2)
# Filter out very small noise using dynamic min_box_size
if width < self.min_box_size or height < self.min_box_size:
continue
# Check if this is a duplicate (near existing detection)
is_duplicate = False
for ex, ey in existing_centers:
distance = ((center_x - ex)**2 + (center_y - ey)**2)**0.5
if distance < self.duplicate_threshold: # Use dynamic threshold
is_duplicate = True
break
if not is_duplicate:
detection = {
'bbox': [int(x1), int(y1), int(x2), int(y2)],
'confidence': confidence,
'class_id': class_id,
'class_name': 'person',
'center': [center_x, center_y],
'size': 'tiny' if (width < 10 or height < 10) else ('small' if (width < 50 or height < 50) else 'normal')
}
additional_detections.append(detection)
return additional_detections
except Exception as e:
logger.error(f"Additional detection pass error: {e}")
return []
def detect(self, frame: np.ndarray, resize_factor: float = 1.0,
confidence_threshold: float = None) -> Tuple[List[Dict], int, float]:
"""
Detect people in the frame using YOLOv8 with TensorRT
Args:
frame: Input frame (BGR format from OpenCV)
resize_factor: Ignored - always uses full resolution for best accuracy
confidence_threshold: Optional override for detection threshold
Returns:
detections: List of all detected people (primary + second pass)
count: Total number of people detected
processing_time: Time taken for detection
"""
start_time = time.time()
detections = []
if confidence_threshold is None:
confidence_threshold = self.confidence_threshold
try:
# Primary detection with CUDA using configured device
results = self.model(
frame,
conf=confidence_threshold,
iou=self.iou_threshold,
classes=self.class_filter,
verbose=False,
imgsz=self.imgsz,
device=self.device,
half=(self.device != "cpu"), # FP16 inference for 2x speedup on RTX 3050
max_det=self.max_det, # Use dynamic max detections
agnostic_nms=False,
retina_masks=False # Disable for speed
)
# Extract primary detections
for result in results:
boxes = result.boxes
for box in boxes:
x1, y1, x2, y2 = box.xyxy[0].cpu().numpy()
confidence = float(box.conf[0].cpu().numpy())
class_id = int(box.cls[0].cpu().numpy())
width = x2 - x1
height = y2 - y1
# Filter by minimum size to remove noise
if width >= self.min_size and height >= self.min_size:
detection = {
'bbox': [int(x1), int(y1), int(x2), int(y2)],
'confidence': confidence,
'class_id': class_id,
'class_name': 'person',
'center': [int((x1 + x2) / 2), int((y1 + y2) / 2)],
'size': 'tiny' if (width < 10 or height < 10) else ('small' if (width < 50 or height < 50) else 'normal')
}
detections.append(detection)
# Second pass for better small object detection
if self.small_object_mode:
additional = self.detect_additional_pass(frame, detections)
detections.extend(additional)
processing_time = time.time() - start_time
self.frame_times.append(processing_time)
self.detection_count += len(detections)
self.frame_count += 1
count = len(detections)
# Log detection count occasionally (every 30 frames) to avoid log spam
if self.frame_count % 30 == 0 or count > 0:
logger.debug(f"Detected {count} people in {processing_time:.3f}s (frame {self.frame_count})")
return detections, count, processing_time
except Exception as e:
logger.error(f"Detection error: {e}")
import traceback
logger.error(traceback.format_exc())
return [], 0, 0.0
def _calculate_iou(self, box1: List[int], box2: List[int]) -> float:
"""
Calculate Intersection over Union for two bounding boxes with edge case handling
Args:
box1: [x1, y1, x2, y2]
box2: [x1, y1, x2, y2]
Returns:
IoU value between 0.0 and 1.0
"""
# Calculate intersection area
x1_inter = max(box1[0], box2[0])
y1_inter = max(box1[1], box2[1])
x2_inter = min(box1[2], box2[2])
y2_inter = min(box1[3], box2[3])
inter_area = max(0, x2_inter - x1_inter) * max(0, y2_inter - y1_inter)
# Calculate union area
box1_area = (box1[2] - box1[0]) * (box1[3] - box1[1])
box2_area = (box2[2] - box2[0]) * (box2[3] - box2[1])
# Handle edge cases
if box1_area <= 0 or box2_area <= 0:
return 0.0
union_area = box1_area + box2_area - inter_area
# Avoid division by zero
if union_area <= 0:
return 0.0
return inter_area / union_area
def draw_detections(self, frame: np.ndarray, detections: List[Dict],
show_confidence: bool = True) -> np.ndarray:
"""
Draw bounding boxes with high visibility for crowd detection
Color-coded by confidence level
Args:
frame: Input frame
detections: List of detections
show_confidence: Whether to display confidence scores
Returns:
frame: Frame with drawn bounding boxes
"""
frame_copy = frame.copy()
for i, det in enumerate(detections):
x1, y1, x2, y2 = det['bbox']
confidence = det['confidence']
is_small = det.get('size') == 'small'
# Color by confidence: Green (high) -> Yellow (medium) -> Orange (low)
if confidence >= 0.5:
color = (0, 255, 0) # Green - high confidence
elif confidence >= 0.25:
color = (0, 255, 255) # Yellow - medium
elif confidence >= 0.15:
color = (0, 165, 255) # Orange - lower
else:
color = (0, 128, 255) # Light orange - very low
thickness = 1 if is_small else 2
# Draw bounding box
cv2.rectangle(frame_copy, (x1, y1), (x2, y2), color, thickness)
# Draw center dot for all detections
center_x, center_y = det['center']
cv2.circle(frame_copy, (center_x, center_y), 2, color, -1)
# Draw prominent count display in top-left corner
count = len(detections)
count_text = f"PEOPLE: {count}"
# Background box for count
(text_w, text_h), _ = cv2.getTextSize(count_text, cv2.FONT_HERSHEY_SIMPLEX, 1.0, 2)
cv2.rectangle(frame_copy, (5, 5), (text_w + 15, text_h + 15), (0, 0, 0), -1)
cv2.rectangle(frame_copy, (5, 5), (text_w + 15, text_h + 15), (0, 255, 0), 2)
# Count text
cv2.putText(frame_copy, count_text, (10, text_h + 8),
cv2.FONT_HERSHEY_SIMPLEX, 1.0, (0, 255, 0), 2)
return frame_copy
def get_statistics(self) -> Dict:
"""
Get detection statistics
Returns:
stats: Dictionary with performance metrics
"""
if not self.frame_times:
return {
'avg_processing_time': 0.0,
'fps': 0.0,
'total_detections': 0,
'frames_processed': 0
}
avg_time = np.mean(self.frame_times[-100:]) # Last 100 frames
fps = 1.0 / avg_time if avg_time > 0 else 0.0
return {
'avg_processing_time': avg_time,
'fps': fps,
'total_detections': self.detection_count,
'frames_processed': len(self.frame_times),
'max_processing_time': max(self.frame_times) if self.frame_times else 0.0,
'min_processing_time': min(self.frame_times) if self.frame_times else 0.0
}
def reset_statistics(self):
"""Reset detection statistics"""
from collections import deque
self.frame_times = deque(maxlen=30)
self.detection_count = 0
self.frame_count = 0
logger.info("Detection statistics reset")
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