MoveNet:超快且准确的姿态检测模型

在 TensorFlow.org上查看 在 Google Colab 中运行 在 GitHub 上查看源代码 下载笔记本 查看 TF Hub 模型

MoveNet 是一个超快且准确的模型,可检测身体的 17 个关键点。该模型在 TF Hub 上提供两种变体,分别为 Lightning 和 Thunder。Lightning 用于延迟关键型应用,而 Thunder 用于需要高准确性的应用。在大多数现代台式机、笔记本电脑和手机上,这两种模型的运行速度都快于实时 (30+ FPS),这对于实时的健身、健康和保健应用至关重要。

drawing

*图像下载自 Pexels (https://www.pexels.com/)

本 Colab 将详细介绍如何加载 MoveNet,并对下面的输入图像和视频运行推断。

注:请查看实时演示以了解该模型的工作原理!

使用 MoveNet 进行人体姿态估计

可视化库和导入

pip install -q imageio
pip install -q opencv-python
pip install -q git+https://github.com/tensorflow/docs
import tensorflow as tf
import tensorflow_hub as hub
from tensorflow_docs.vis import embed
import numpy as np
import cv2

# Import matplotlib libraries
from matplotlib import pyplot as plt
from matplotlib.collections import LineCollection
import matplotlib.patches as patches

# Some modules to display an animation using imageio.
import imageio
from IPython.display import HTML, display
2022-12-14 21:01:05.561349: W tensorflow/compiler/xla/stream_executor/platform/default/dso_loader.cc:64] Could not load dynamic library 'libnvinfer.so.7'; dlerror: libnvinfer.so.7: cannot open shared object file: No such file or directory
2022-12-14 21:01:05.561447: W tensorflow/compiler/xla/stream_executor/platform/default/dso_loader.cc:64] Could not load dynamic library 'libnvinfer_plugin.so.7'; dlerror: libnvinfer_plugin.so.7: cannot open shared object file: No such file or directory
2022-12-14 21:01:05.561458: W tensorflow/compiler/tf2tensorrt/utils/py_utils.cc:38] TF-TRT Warning: Cannot dlopen some TensorRT libraries. If you would like to use Nvidia GPU with TensorRT, please make sure the missing libraries mentioned above are installed properly.

Helper functions for visualization

从 TF hub 加载模型

model_name = "movenet_lightning"

if "tflite" in model_name:
  if "movenet_lightning_f16" in model_name:
    !wget -q -O model.tflite https://tfhub.dev/google/lite-model/movenet/singlepose/lightning/tflite/float16/4?lite-format=tflite
    input_size = 192
  elif "movenet_thunder_f16" in model_name:
    !wget -q -O model.tflite https://tfhub.dev/google/lite-model/movenet/singlepose/thunder/tflite/float16/4?lite-format=tflite
    input_size = 256
  elif "movenet_lightning_int8" in model_name:
    !wget -q -O model.tflite https://tfhub.dev/google/lite-model/movenet/singlepose/lightning/tflite/int8/4?lite-format=tflite
    input_size = 192
  elif "movenet_thunder_int8" in model_name:
    !wget -q -O model.tflite https://tfhub.dev/google/lite-model/movenet/singlepose/thunder/tflite/int8/4?lite-format=tflite
    input_size = 256
  else:
    raise ValueError("Unsupported model name: %s" % model_name)

  # Initialize the TFLite interpreter
  interpreter = tf.lite.Interpreter(model_path="model.tflite")
  interpreter.allocate_tensors()

  def movenet(input_image):
    """Runs detection on an input image.

    Args:
      input_image: A [1, height, width, 3] tensor represents the input image
        pixels. Note that the height/width should already be resized and match the
        expected input resolution of the model before passing into this function.

    Returns:
      A [1, 1, 17, 3] float numpy array representing the predicted keypoint
      coordinates and scores.
    """
    # TF Lite format expects tensor type of uint8.
    input_image = tf.cast(input_image, dtype=tf.uint8)
    input_details = interpreter.get_input_details()
    output_details = interpreter.get_output_details()
    interpreter.set_tensor(input_details[0]['index'], input_image.numpy())
    # Invoke inference.
    interpreter.invoke()
    # Get the model prediction.
    keypoints_with_scores = interpreter.get_tensor(output_details[0]['index'])
    return keypoints_with_scores

else:
  if "movenet_lightning" in model_name:
    module = hub.load("https://tfhub.dev/google/movenet/singlepose/lightning/4")
    input_size = 192
  elif "movenet_thunder" in model_name:
    module = hub.load("https://tfhub.dev/google/movenet/singlepose/thunder/4")
    input_size = 256
  else:
    raise ValueError("Unsupported model name: %s" % model_name)

  def movenet(input_image):
    """Runs detection on an input image.

    Args:
      input_image: A [1, height, width, 3] tensor represents the input image
        pixels. Note that the height/width should already be resized and match the
        expected input resolution of the model before passing into this function.

    Returns:
      A [1, 1, 17, 3] float numpy array representing the predicted keypoint
      coordinates and scores.
    """
    model = module.signatures['serving_default']

    # SavedModel format expects tensor type of int32.
    input_image = tf.cast(input_image, dtype=tf.int32)
    # Run model inference.
    outputs = model(input_image)
    # Output is a [1, 1, 17, 3] tensor.
    keypoints_with_scores = outputs['output_0'].numpy()
    return keypoints_with_scores

单个图像示例

本节演示对单个图像运行模型以预测 17 个人体关键点的最小工作示例。

加载输入图像

curl -o input_image.jpeg https://images.pexels.com/photos/4384679/pexels-photo-4384679.jpeg --silent
# Load the input image.
image_path = 'input_image.jpeg'
image = tf.io.read_file(image_path)
image = tf.image.decode_jpeg(image)

运行推断

# Resize and pad the image to keep the aspect ratio and fit the expected size.
input_image = tf.expand_dims(image, axis=0)
input_image = tf.image.resize_with_pad(input_image, input_size, input_size)

# Run model inference.
keypoints_with_scores = movenet(input_image)

# Visualize the predictions with image.
display_image = tf.expand_dims(image, axis=0)
display_image = tf.cast(tf.image.resize_with_pad(
    display_image, 1280, 1280), dtype=tf.int32)
output_overlay = draw_prediction_on_image(
    np.squeeze(display_image.numpy(), axis=0), keypoints_with_scores)

plt.figure(figsize=(5, 5))
plt.imshow(output_overlay)
_ = plt.axis('off')

png

视频(图像序列)示例

本节演示当输入为帧序列时,如何根据前一帧的检测结果应用智能裁剪。这样模型可以将注意力和资源投入到主要主题上,从而在不牺牲速度的情况下获得更好的预测质量。

Cropping Algorithm

加载输入图像序列

wget -q -O dance.gif https://github.com/tensorflow/tfjs-models/raw/master/pose-detection/assets/dance_input.gif
# Load the input image.
image_path = 'dance.gif'
image = tf.io.read_file(image_path)
image = tf.image.decode_gif(image)

使用裁剪算法运行推断

# Load the input image.
num_frames, image_height, image_width, _ = image.shape
crop_region = init_crop_region(image_height, image_width)

output_images = []
bar = display(progress(0, num_frames-1), display_id=True)
for frame_idx in range(num_frames):
  keypoints_with_scores = run_inference(
      movenet, image[frame_idx, :, :, :], crop_region,
      crop_size=[input_size, input_size])
  output_images.append(draw_prediction_on_image(
      image[frame_idx, :, :, :].numpy().astype(np.int32),
      keypoints_with_scores, crop_region=None,
      close_figure=True, output_image_height=300))
  crop_region = determine_crop_region(
      keypoints_with_scores, image_height, image_width)
  bar.update(progress(frame_idx, num_frames-1))

# Prepare gif visualization.
output = np.stack(output_images, axis=0)
to_gif(output, fps=10)

gif