* 背景 *
1、 目前人脸识别已经广泛运用,即使在视频流里面也能流畅识别出来,无论是对安防还是其他体验类产品都有很大的影响。研究完人脸识别后,对于年龄的预测,性别的判断以及根据面部动作识别表情也开始实现,以后可能还会学习颜值预测和是否带眼睛戴帽子什么的。面部表情识别技术主要的应用领域包括人机交互、智能控制、安全、医疗、通信等领域。颜值预测可以运用于未来的虚拟化妆,客户可以看见化妆后的自己,满意后再实际化妆出来的效果最能让客户开心。
实现
在哪里实现?
第一,在视频流里实时识别,人脸识别的人脸对齐过程实现,人脸检测完之后将检测结果传参给预测模型。
第二、直接给图片先检测再预测
代码实现
demo.py
import os
import cv2
import time
import numpy as np
import argparse
import dlib
from contextlib import contextmanager
from wide_resnet import WideResNet
from keras.utils.data_utils import get_file
from keras.models import model_from_json
pretrained_model = "https://github.com/yu4u/age-gender-estimation/releases/download/v0.5/weights.18-4.06.hdf5"
modhash = '89f56a39a78454e96379348bddd78c0d'
emotion_labels = ['angry', 'fear', 'happy', 'sad', 'surprise', 'neutral']
# load json and create model arch
json_file = open('model.json','r')
loaded_model_json = json_file.read()
json_file.close()
#将json重构为model结构
model = model_from_json(loaded_model_json)
# load weights into new model
model.load_weights('model.h5')
def predict_emotion(face_image_gray): # a single cropped face
resized_img = cv2.resize(face_image_gray, (48,48), interpolation = cv2.INTER_AREA)
image = resized_img.reshape(1, 1, 48, 48)
im = cv2.resize(resized_img,(90,100))
cv2.imwrite('face.bmp', im)
list_of_list = model.predict(image, batch_size=1, verbose=1)
angry, fear, happy, sad, surprise, neutral = [prob for lst in list_of_list for prob in lst]
return [angry, fear, happy, sad, surprise, neutral]
def get_args():
parser = argparse.ArgumentParser(description="This script detects faces from web cam input, "
"and estimates age and gender for the detected faces.",
formatter_class=argparse.ArgumentDefaultsHelpFormatter)
#改成自己的地址
parser.add_argument("--weight_file", type=str, default="./pretrained_models/weights.18-4.06.hdf5",
help="path to weight file (e.g. weights.18-4.06.hdf5)")
parser.add_argument("--depth", type=int, default=16,
help="depth of network")
parser.add_argument("--width", type=int, default=8,
help="width of network")
args = parser.parse_args()
return args
def draw_label(image, point, label, font=cv2.FONT_HERSHEY_SIMPLEX,
font_scale=1, thickness=2):
size = cv2.getTextSize(label, font, font_scale, thickness)[0]
x, y = point
cv2.rectangle(image, (x, y - size[1]), (x + size[0], y), (255, 0, 0), cv2.FILLED)
cv2.putText(image, label, point, font, font_scale, (255, 255, 255), thickness)
@contextmanager
def video_capture(*args, **kwargs):
cap = cv2.VideoCapture(*args, **kwargs)
try:
yield cap
finally:
cap.release()
def yield_images():
# capture video
with video_capture(0) as cap:
cap.set(cv2.CAP_PROP_FRAME_WIDTH, 640)
cap.set(cv2.CAP_PROP_FRAME_HEIGHT, 480)
while True:
# get video frame
ret, img = cap.read()
if not ret:
raise RuntimeError("Failed to capture image")
yield img
def main():
biaoqing = ""
args = get_args()
depth = args.depth
k = args.width
weight_file = args.weight_file
print(weight_file)
#第一次运行时会自动从给的网址下载weights.18-4.06.hdf5模型(190M左右)
if not weight_file:
weight_file = get_file("weights.18-4.06.hdf5", pretrained_model, cache_subdir="pretrained_models",
file_hash=modhash, cache_dir=os.path.dirname(os.path.abspath(__file__)))
# for face detection
detector = dlib.get_frontal_face_detector()
# load model and weights
img_size = 64
model = WideResNet(img_size, depth=depth, k=k)()
model.load_weights(weight_file)
for img in yield_images():
#img = cv2.imread("1.jpg")
input_img = cv2.cvtColor(img, cv2.COLOR_BGR2RGB)
img_gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
img_h, img_w, _ = np.shape(input_img)
#print("h w ",img_h,img_w)
emotions = []
# Draw a rectangle around the faces
# detect faces using dlib detector
detected = detector(img_gray, 0)
faces = np.empty((len(detected), img_size, img_size, 3))
#print("dector",detected)
if len(detected) > 0:
for i, d in enumerate(detected):
#print("i,d =",i,d)
x1, y1, x2, y2, w, h = d.left(), d.top(), d.right() + 1, d.bottom() + 1, d.width(), d.height()
#print("w h =",w,h)
xw1 = max(int(x1 - 0.4 * w), 0)
yw1 = max(int(y1 - 0.4 * h), 0)
xw2 = min(int(x2 + 0.4 * w), img_w - 1)
yw2 = min(int(y2 + 0.4 * h), img_h - 1)
cv2.rectangle(img, (x1, y1), (x2, y2), (255, 0, 0), 2)
#cv2.rectangle(img, (xw1, yw1), (xw2, yw2), (255, 0, 0), 2)
faces[i, :, :, :] = cv2.resize(img[yw1:yw2 + 1, xw1:xw2 + 1, :], (img_size, img_size))
#print("faces ",faces)
face_image_gray = img_gray[y1:y1 + y2, x1:x1 + x2]
angry, fear, happy, sad, surprise, neutral = predict_emotion(face_image_gray)
emotions = [angry, fear, happy, sad, surprise, neutral]
m = emotions.index(max(emotions))
for index, val in enumerate(emotion_labels):
if (m == index):
biaoqing = val
# predict ages and genders of the detected faces
results = model.predict(faces)
predicted_genders = results[0]
ages = np.arange(0, 101).reshape(101, 1)
predicted_ages = results[1].dot(ages).flatten()
# draw results
for i, d in enumerate(detected):
#print("表情",biaoqing)
label = "{}, {},{}".format(int(predicted_ages[i]),
"F" if predicted_genders[i][0] > 0.5 else "M" ,biaoqing)
draw_label(img, (d.left(), d.top()), label)
cv2.imshow("result", img)
#等待3ms
key = cv2.waitKey(3)
if key == 27:
break
if __name__ == '__main__':
main()
wide_resnet.py
# This code is imported from the following project: https://github.com/asmith26/wide_resnets_keras
import logging
import sys
import numpy as np
from keras.models import Model
from keras.layers import Input, Activation, add, Dense, Flatten, Dropout
from keras.layers.convolutional import Conv2D, AveragePooling2D
from keras.layers.normalization import BatchNormalization
from keras.regularizers import l2
from keras import backend as K
sys.setrecursionlimit(2 ** 20)
np.random.seed(2 ** 10)
class WideResNet:
def __init__(self, image_size, depth=16, k=8):
self._depth = depth
self._k = k
self._dropout_probability = 0
self._weight_decay = 0.0005
self._use_bias = False
self._weight_init = "he_normal"
if K.image_dim_ordering() == "th":
logging.debug("image_dim_ordering = 'th'")
self._channel_axis = 1
self._input_shape = (3, image_size, image_size)
else:
logging.debug("image_dim_ordering = 'tf'")
self._channel_axis = -1
self._input_shape = (image_size, image_size, 3)
# Wide residual network http://arxiv.org/abs/1605.07146
def _wide_basic(self, n_input_plane, n_output_plane, stride):
def f(net):
# format of conv_params:
# [ [kernel_size=("kernel width", "kernel height"),
# strides="(stride_vertical,stride_horizontal)",
# padding="same" or "valid"] ]
# B(3,3): orignal <<basic>> block
conv_params = [[3, 3, stride, "same"],
[3, 3, (1, 1), "same"]]
n_bottleneck_plane = n_output_plane
# Residual block
for i, v in enumerate(conv_params):
if i == 0:
if n_input_plane != n_output_plane:
net = BatchNormalization(axis=self._channel_axis)(net)
net = Activation("relu")(net)
convs = net
else:
convs = BatchNormalization(axis=self._channel_axis)(net)
convs = Activation("relu")(convs)
convs = Conv2D(n_bottleneck_plane, kernel_size=(v[0], v[1]),
strides=v[2],
padding=v[3],
kernel_initializer=self._weight_init,
kernel_regularizer=l2(self._weight_decay),
use_bias=self._use_bias)(convs)
else:
convs = BatchNormalization(axis=self._channel_axis)(convs)
convs = Activation("relu")(convs)
if self._dropout_probability > 0:
convs = Dropout(self._dropout_probability)(convs)
convs = Conv2D(n_bottleneck_plane, kernel_size=(v[0], v[1]),
strides=v[2],
padding=v[3],
kernel_initializer=self._weight_init,
kernel_regularizer=l2(self._weight_decay),
use_bias=self._use_bias)(convs)
# Shortcut Connection: identity function or 1x1 convolutional
# (depends on difference between input & output shape - this
# corresponds to whether we are using the first block in each
# group; see _layer() ).
if n_input_plane != n_output_plane:
shortcut = Conv2D(n_output_plane, kernel_size=(1, 1),
strides=stride,
padding="same",
kernel_initializer=self._weight_init,
kernel_regularizer=l2(self._weight_decay),
use_bias=self._use_bias)(net)
else:
shortcut = net
return add([convs, shortcut])
return f
# "Stacking Residual Units on the same stage"
def _layer(self, block, n_input_plane, n_output_plane, count, stride):
def f(net):
net = block(n_input_plane, n_output_plane, stride)(net)
for i in range(2, int(count + 1)):
net = block(n_output_plane, n_output_plane, stride=(1, 1))(net)
return net
return f
# def create_model(self):
def __call__(self):
logging.debug("Creating model...")
assert ((self._depth - 4) % 6 == 0)
n = (self._depth - 4) / 6
inputs = Input(shape=self._input_shape)
n_stages = [16, 16 * self._k, 32 * self._k, 64 * self._k]
conv1 = Conv2D(filters=n_stages[0], kernel_size=(3, 3),
strides=(1, 1),
padding="same",
kernel_initializer=self._weight_init,
kernel_regularizer=l2(self._weight_decay),
use_bias=self._use_bias)(inputs) # "One conv at the beginning (spatial size: 32x32)"
# Add wide residual blocks
block_fn = self._wide_basic
conv2 = self._layer(block_fn, n_input_plane=n_stages[0], n_output_plane=n_stages[1], count=n, stride=(1, 1))(conv1)
conv3 = self._layer(block_fn, n_input_plane=n_stages[1], n_output_plane=n_stages[2], count=n, stride=(2, 2))(conv2)
conv4 = self._layer(block_fn, n_input_plane=n_stages[2], n_output_plane=n_stages[3], count=n, stride=(2, 2))(conv3)
batch_norm = BatchNormalization(axis=self._channel_axis)(conv4)
relu = Activation("relu")(batch_norm)
# Classifier block
pool = AveragePooling2D(pool_size=(8, 8), strides=(1, 1), padding="same")(relu)
flatten = Flatten()(pool)
predictions_g = Dense(units=2, kernel_initializer=self._weight_init, use_bias=self._use_bias,
kernel_regularizer=l2(self._weight_decay), activation="softmax",
name="pred_gender")(flatten)
predictions_a = Dense(units=101, kernel_initializer=self._weight_init, use_bias=self._use_bias,
kernel_regularizer=l2(self._weight_decay), activation="softmax",
name="pred_age")(flatten)
model = Model(inputs=inputs, outputs=[predictions_g, predictions_a])
return model
def main():
model = WideResNet(64)()
model.summary()
if __name__ == '__main__':
main()
准备工作
环境:python3 TensorFlow-gpu numpy keras dlib
模型:model.h5(表情预测模型) model.json(表情预测模型的json类型) weights.18-4.06.hdf5(性别年龄预测模型)
[模型下载](https://download.csdn.net/download/hpymiss/10490349)
运行
python demo.py
效果
处理一帧一秒以内,视频流里能流畅运行
不足之处:模型的精度还不够,需要进行微调,如何改进还待研究
硬件
- GPU:
name: GeForce GTX 960M major: 5 minor: 0 memoryClockRate(GHz): 1.176
pciBusID: 0000:02:00.0
totalMemory: 4.00GiB freeMemory: 3.34GiB - 处理器 (i7)
学习参考
keras官方文档
参考代码以及model.h5下载
年龄性别预测
彻底理解Python中的yield
Keras 实现的性别年龄检测 (已并入颜值服务)
keras系列︱人脸表情分类与识别:opencv人脸检测+Keras情绪分类(四)