Google Coral USB Edge TPU Implementation Guide
1. Installation and Troubleshooting
1.1 Hardware Requirements
- Google Coral USB Accelerator
- USB 3.0 port (for best performance)
- Linux host system (Ubuntu, Debian, etc.)
1.2 Installation Steps
# 1. Add the Coral package repository
echo "deb https://packages.cloud.google.com/apt coral-edgetpu-stable main" | sudo tee /etc/apt/sources.list.d/coral-edgetpu.list
# 2. Add the package key
curl https://packages.cloud.google.com/apt/doc/apt-key.gpg | sudo apt-key add -
# 3. Update package lists
sudo apt-get update
# 4. Install the Edge TPU runtime
sudo apt-get install libedgetpu1-std
# 5. Create a conda environment with Python 3.9
conda create -n coral_env python=3.9
conda activate coral_env
# 6. Install necessary packages
pip install numpy pillow opencv-python
# 7. Install PyCoral from Google's repository
pip install --extra-index-url https://google-coral.github.io/py-repo/ pycoral
1.3 Common Issues and Solutions
1.3.1 "Failed to load delegate from libedgetpu.so.1" Error
This is a common error that occurs when the Edge TPU library doesn't have executable permissions or when the user doesn't have the right permissions to access the device.
Solution:
# Add executable permission to the library
sudo chmod +x /usr/lib/x86_64-linux-gnu/libedgetpu.so.1.0
# Add your user to the plugdev group
sudo usermod -aG plugdev $USER
# Create proper udev rules
sudo bash -c 'cat > /etc/udev/rules.d/99-edgetpu.rules << EOF
SUBSYSTEM=="usb", ATTRS{idVendor}=="1a6e", ATTRS{idProduct}=="089a", MODE="0664", GROUP="plugdev"
EOF'
# Reload udev rules
sudo udevadm control --reload-rules && sudo udevadm trigger
# Unplug and replug your device
1.3.2 Verifying Installation
Create a simple Python script to check if the Edge TPU is detected:
# check_coral.py
from pycoral.utils import edgetpu
print("Testing Edge TPU...")
devices = edgetpu.list_edge_tpus()
print(f"Available Edge TPUs: {devices}")
if devices:
print("Edge TPU is working correctly!")
else:
print("No Edge TPU detected.")
Run with:
2. Edge TPU Inference with YOLOv10/YOLOv11
2.1 Complete Implementation
import time
import cv2
import numpy as np
import os
import sys
from PIL import Image
from pycoral.utils import edgetpu
from pycoral.adapters import common
class YOLOv10EdgeTPU:
def __init__(self, path, conf_thres=0.3, iou_thres=0.5, input_size=(640, 640)):
self.conf_threshold = conf_thres
self.iou_threshold = iou_thres
# Set default input size
self.default_input_height, self.default_input_width = input_size
# Initialize model
self.initialize_model(path)
def __call__(self, image):
return self.detect_objects(image)
def initialize_model(self, path):
# Load Edge TPU model
self.interpreter = edgetpu.make_interpreter(path)
self.interpreter.allocate_tensors()
# Get model info
self.get_input_details()
self.get_output_details()
def detect_objects(self, image):
input_tensor = self.prepare_input(image)
# Perform inference on the image
outputs = self.inference(input_tensor)
# Process outputs
self.boxes, self.scores, self.class_ids = self.process_output(outputs)
# Ensure boxes, scores, and class_ids have the same length
if len(self.boxes) != len(self.scores) or len(self.boxes) != len(self.class_ids):
return []
detections = []
for i in range(len(self.boxes)):
detection = {
'box': self.boxes[i].tolist(), # Convert numpy array to Python list
'score': self.scores[i],
'class_id': self.class_ids[i]
}
detections.append(detection)
return detections
def prepare_input(self, image):
self.img_height, self.img_width = image.shape[:2]
# Convert to RGB (OpenCV loads as BGR)
input_img = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
# Use the model's input dimensions
input_width = self.input_width
input_height = self.input_height
# Resize input image
input_img = cv2.resize(input_img, (input_width, input_height))
# Scale input pixel values to 0 to 1
input_img = input_img.astype(np.float32) / 255.0
# Add batch dimension
input_tensor = np.expand_dims(input_img, axis=0)
return input_tensor
def inference(self, input_tensor):
start = time.perf_counter()
# Set input tensor
common.set_input(self.interpreter, input_tensor)
# Run inference
self.interpreter.invoke()
# Get all output tensors
outputs = []
for i in range(len(self.output_details)):
outputs.append(self.interpreter.get_tensor(self.output_details[i]['index']))
infer_time = (time.perf_counter() - start) * 1000
print(f"Inference time: {infer_time:.2f} ms")
return outputs
def process_output(self, outputs):
"""Process output for YOLOv10/YOLOv11 TFLite model with shape [1, 5, 8400]"""
# Get the first output tensor
predictions = outputs[0] # Shape [1, 5, 8400]
print(f"Output 0 shape: {predictions.shape}")
# Transpose the predictions from [1, 5, 8400] to [8400, 5]
predictions = predictions[0].T # Now shape is [8400, 5]
print(f"Transposed predictions shape: {predictions.shape}")
# Extract confidence scores
objectness_scores = predictions[:, 4] # Last column is confidence
# Filter by confidence threshold
valid_indices = np.where(objectness_scores > self.conf_threshold)[0]
if len(valid_indices) == 0:
return [], [], []
valid_boxes = predictions[valid_indices, :4] # First 4 values are bbox coords
valid_scores = predictions[valid_indices, 4] # 5th value is confidence
# For single-class model, all class IDs are 0
valid_class_ids = np.zeros(len(valid_scores), dtype=np.int32)
# Convert normalized coordinates to pixel coordinates
# For YOLO, the output is in normalized format (0-1)
valid_boxes[:, 0] *= self.img_width # x
valid_boxes[:, 1] *= self.img_height # y
valid_boxes[:, 2] *= self.img_width # width
valid_boxes[:, 3] *= self.img_height # height
# Convert from [cx, cy, width, height] to [x1, y1, x2, y2]
boxes_xyxy = self.cxcywh_to_xyxy(valid_boxes)
# Apply non-maximum suppression
indices = self.nms(boxes_xyxy, valid_scores)
print(f"After NMS: {len(indices)} detections")
return boxes_xyxy[indices], valid_scores[indices], valid_class_ids[indices]
def cxcywh_to_xyxy(self, boxes):
"""Convert boxes from center_x, center_y, width, height to x1, y1, x2, y2 format"""
xyxy = np.zeros_like(boxes)
xyxy[:, 0] = boxes[:, 0] - boxes[:, 2] / 2 # x1 = cx - w/2
xyxy[:, 1] = boxes[:, 1] - boxes[:, 3] / 2 # y1 = cy - h/2
xyxy[:, 2] = boxes[:, 0] + boxes[:, 2] / 2 # x2 = cx + w/2
xyxy[:, 3] = boxes[:, 1] + boxes[:, 3] / 2 # y2 = cy + h/2
return xyxy
def nms(self, boxes, scores):
"""Apply non-maximum suppression"""
# Get indices of boxes sorted by scores in descending order
indices = np.argsort(scores)[::-1]
keep = []
while indices.size > 0:
# Pick the box with highest score
current = indices[0]
keep.append(current)
# If only one box left, break
if indices.size == 1:
break
# Compute IoU of the picked box with the rest
ious = self.box_iou(boxes[current:current+1], boxes[indices[1:]])
# Remove boxes with IoU over threshold
mask = ious < self.iou_threshold
indices = indices[1:][mask]
return keep
def box_iou(self, box1, box2):
"""
Calculate IoU between box1 and box2
box1, box2: [x1, y1, x2, y2]
"""
# Calculate intersection area
x1 = np.maximum(box1[0, 0], box2[:, 0])
y1 = np.maximum(box1[0, 1], box2[:, 1])
x2 = np.minimum(box1[0, 2], box2[:, 2])
y2 = np.minimum(box1[0, 3], box2[:, 3])
intersection = np.maximum(0, x2 - x1) * np.maximum(0, y2 - y1)
# Calculate union area
box1_area = (box1[0, 2] - box1[0, 0]) * (box1[0, 3] - box1[0, 1])
box2_area = (box2[:, 2] - box2[:, 0]) * (box2[:, 3] - box2[:, 1])
union = box1_area + box2_area - intersection
# Calculate IoU
iou = intersection / union
return iou
def draw_detections(self, image, draw_scores=True, mask_alpha=0.4):
"""Draw detection boxes on image with scores if requested"""
img_copy = image.copy()
for i, box in enumerate(self.boxes):
x1, y1, x2, y2 = [int(val) for val in box]
# Draw box with thicker lines for visibility
cv2.rectangle(img_copy, (x1, y1), (x2, y2), (0, 255, 0), 3)
# Draw score if requested
if draw_scores and i < len(self.scores):
score = self.scores[i]
class_id = self.class_ids[i] if i < len(self.class_ids) else 0
# For your license plate detector
label = f"License Plate: {score:.2f}"
# Calculate text size and position
text_size = cv2.getTextSize(label, cv2.FONT_HERSHEY_SIMPLEX, 0.7, 2)[0]
# Draw text background
cv2.rectangle(img_copy, (x1, y1 - text_size[1] - 5), (x1 + text_size[0], y1), (0, 255, 0), -1)
# Draw text
cv2.putText(img_copy, label, (x1, y1 - 5), cv2.FONT_HERSHEY_SIMPLEX, 0.7, (0, 0, 0), 2)
return img_copy
def get_input_details(self):
input_details = self.interpreter.get_input_details()
self.input_details = input_details
# Print input details for debugging
print(f"Input details: {input_details}")
# Get input shape
self.input_shape = input_details[0]['shape']
print(f"Input shape: {self.input_shape}")
# Get input dimensions
if len(self.input_shape) == 4:
_, self.input_height, self.input_width, _ = self.input_shape
else:
self.input_height = self.default_input_height
self.input_width = self.default_input_width
print(f"Input dimensions: {self.input_width}x{self.input_height}")
def get_output_details(self):
self.output_details = self.interpreter.get_output_details()
print(f"Output details: {self.output_details}")
def run_benchmark(detector, img, num_runs=10):
"""Run inference multiple times to benchmark performance"""
print(f"\nRunning benchmark with {num_runs} iterations...")
times = []
# Prepare input once
input_tensor = detector.prepare_input(img)
common.set_input(detector.interpreter, input_tensor)
for i in range(num_runs):
start = time.perf_counter()
detector.interpreter.invoke()
inference_time = (time.perf_counter() - start) * 1000
times.append(inference_time)
print(f"Run {i+1}: {inference_time:.2f} ms")
avg_time = sum(times) / len(times)
print(f"\nAverage inference time: {avg_time:.2f} ms")
print(f"Min: {min(times):.2f} ms, Max: {max(times):.2f} ms")
print(f"FPS: {1000/avg_time:.2f}")
return avg_time
if __name__ == '__main__':
# Get model path from command line or use default
model_path = "float32_edgetpu.tflite"
img_path = "cs1.png"
# Parse command line arguments
if len(sys.argv) > 1:
for i, arg in enumerate(sys.argv):
if arg == "--model" and i+1 < len(sys.argv):
model_path = sys.argv[i+1]
elif arg == "--image" and i+1 < len(sys.argv):
img_path = sys.argv[i+1]
# Check if files exist
if not os.path.exists(model_path):
print(f"Error: Model file not found at {model_path}")
sys.exit(1)
if not os.path.exists(img_path):
print(f"Error: Image file not found at {img_path}")
sys.exit(1)
# Initialize YOLOv10 EdgeTPU detector
detector = YOLOv10EdgeTPU(model_path, conf_thres=0.3, iou_thres=0.5, input_size=(640, 640))
# Load image
img = cv2.imread(img_path)
if img is None:
print(f"Failed to load image from path: {img_path}")
sys.exit(1)
print(f"Using image: {img_path}")
print(f"Image shape: {img.shape}")
# Detect Objects
detections = detector(img)
print(f"Found {len(detections)} detections")
# Log all detections
for i, det in enumerate(detections):
print(f"Detection {i+1}: box={det['box']}, score={det['score']:.4f}, class={det['class_id']}")
# Draw detections
output_img = detector.draw_detections(img, draw_scores=True)
output_path = "edgetpu_detections.jpg"
cv2.imwrite(output_path, output_img)
print(f"Output saved to {output_path}")
# Run benchmark if requested
if "--benchmark" in sys.argv:
run_benchmark(detector, img, num_runs=10)
2.2 Usage
# Basic inference
python edge_tpu_yolov10.py
# Specify custom model and image
python edge_tpu_yolov10.py --model /path/to/model_edgetpu.tflite --image /path/to/image.jpg
# Run benchmark
python edge_tpu_yolov10.py --benchmark
3. Comparison: Edge TPU vs GPU
The Edge TPU provides hardware acceleration for TensorFlow Lite models specifically compiled for it. Here's how it compares to GPU inference:
- Edge TPU: ~150 ms inference time (lower with benchmarking)
- GPU (NVIDIA): Can be much faster, depending on the GPU model
- Benefits of Edge TPU: Low power consumption, no need for a powerful GPU, portable
4. Tips and Best Practices
- Model Compilation:
- Use the Edge TPU Compiler to convert TFLite models for Edge TPU
- INT8 quantized models work best with Edge TPU
- Performance Optimization:
- Use USB 3.0 ports for faster data transfer
- Consider using the high-performance version (
libedgetpu1-max) if you need more speed and can manage the heat
- Troubleshooting:
- Always check permissions (
chmod +x on the library file) - Make sure your user is in the
plugdev group - Check the udev rules
- Hardware Limitations:
- Edge TPU has limited memory (8MB shared between all models)
- Not all operations are supported (mainly INT8 quantized operations)
This implementation provides a solid foundation for running YOLO object detection on the Google Coral Edge TPU with proper pre-processing and post-processing for optimal results.
