How to Detect Head Turn with Face Landmarks

Peter Xie
6 min readDec 9, 2023

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Source photo by 🇸🇮 Janko Ferlič and Prince Akachi on Unsplash

TLDR: When turned left, the right chin is bigger than the left one, and vice versa. Use the distance between the right / left chin top and the nose top to measure the right / left chin size.

I have been using bank and payment app face authentication for years where you will be asked to open your mouth, turn your head, etc. to authenticate you don’t hack with a static photo. I figured out how to detect mouth open years ago, but how to detect head turn had puzzled me for years until recently the idea came to my mind all of a sudden and it is that simple, as shown above, once you know it. Depending on the face landmarks detection library you use, you can also use this method: When turned left, you show your right ear and hide the left one, and vice versa.

To start with, we will be using two Python libraries, namely dlib and face_recognition, to help detect face landmarks and analyze them to infer head orientation.

Setting Up the Environment

Before you can detect the head turn, you’ll need to have the necessary libraries installed. You’ll need dlib, an open-source toolkit in C++ for making real-world machine learning and data analysis applications including face detection and recognition, and face_recognition, a dlib wrapper library that simplifies facial recognition processes and helps you download the model file automatically and group face landmarks into facial features like eyes, nose, mouth, and chin, etc.

Install them using pip:

pip3 install dlib 
pip3 install face_recognition
pip3 install Pillow

Notes:

  1. dlib installation will take 10–15 minutes as it will build the C++ library in real-time. On Windows, you need to install Visual Studio with C++ App Development selected first.
  2. dlib python package provides a Python interface as well, so you don’t have to use face_recognition for production deployment. Refer to this dlib only example for face landmarks detection.
  3. We also install Pillow for image drawing, not required for production deployment.

Understanding the Code

Photo on Quotefancy
#!/usr/bin/env python
from PIL import Image, ImageDraw, ImageFont
import face_recognition
import argparse
import math

argparser = argparse.ArgumentParser(description="Detect head turn")
argparser.add_argument(
"image_file",
help="Image file to detect head turn",
)
args = argparser.parse_args()

image_file = args.image_file

# Load the image file into a numpy array
image = face_recognition.load_image_file(image_file)

# Find face landmarks of all the faces in the image
face_landmarks_list = face_recognition.face_landmarks(image)
num_faces = len(face_landmarks_list)
print(f"Found {num_faces} face(s) in this photograph.")
# Get locations of all the faces in the image
face_locations = face_recognition.face_locations(image)

pil_image = Image.fromarray(image)
d = ImageDraw.Draw(pil_image)

facial_features = [
"chin",
"left_eyebrow",
"right_eyebrow",
"nose_bridge",
"nose_tip",
"left_eye",
"right_eye",
"top_lip",
"bottom_lip",
]

# get landmarks of 1st face, assume there is only one face in the image
face_landmarks = face_landmarks_list[0]
# Let's trace out each facial feature with a line!
for facial_feature in facial_features:
# print(f"{facial_feature} has {len(face_landmarks[facial_feature])} points: {face_landmarks[facial_feature]}")
d.line(face_landmarks[facial_feature], width=5)

# draw left chin to nose top in green
d.line(face_landmarks["chin"][-1:] + face_landmarks["nose_bridge"][:1], width=5, fill=(0, 255, 0))
# draw right chin to nose top in red
d.line(face_landmarks["chin"][:1] + face_landmarks["nose_bridge"][:1], width=5, fill=(255, 0, 0))

def point_distance(p1, p2):
"""get distance of two points"""
return math.sqrt( (p1[0] - p2[0])**2 + (p1[1] - p2[1])**2 )

# right / left chin ratio
left_chin_green = point_distance(face_landmarks["chin"][-1], face_landmarks["nose_bridge"][0])
right_chin_red = point_distance(face_landmarks["chin"][0], face_landmarks["nose_bridge"][0])
right_to_left_ratio = right_chin_red / left_chin_green
left_to_right_ratio = left_chin_green / right_chin_red

# Determine head turn!
threshold = 1.3 # customise your preference here
if left_to_right_ratio > threshold:
turned = "turned right"
print(f"green / red = {left_to_right_ratio:.1f}, {turned}")
elif right_to_left_ratio > threshold:
turned = "turned left"
print(f"red / green = {right_to_left_ratio:.1f}, {turned}")
else:
turned = "facing straight"
print(f"red / green = {right_to_left_ratio:.1f}, {turned}")

# Add text to the image for head turn orientation
top, right, bottom, left = face_locations[0]
position = (left, top) # write text from face location top left
font_size = (right - left) // 6 # relative to face size
font = ImageFont.truetype("arial.ttf", size=font_size)
text_color = (0, 0, 255) # RGB color
d.text(position, turned, fill=text_color, font=font)

# Save drawn image
out_file = "out_" + image_file
print("saved to " + out_file)
pil_image.save(out_file)

The provided Python code describes a simple yet effective algorithm based on facial landmarks to detect head orientation. It implies drawing lines from the top of the chin on both sides to the top of the nose and comparing their lengths to determine which direction the head is turned.

Notes: arial.ttf is a Microsoft Windows font. If you run this script on Linux like Ubuntu, install the font as follows:

sudo apt install ttf-mscorefonts-installer
sudo fc-cache -f

# After that, check with:
fc-match Arial

# out:
Arial.ttf: "Arial" "Regular"

Detailed Walkthrough

  1. Parse Command-Line Arguments: Use argparse to provide the script with the path to the input image containing the face you want to analyze.
  2. Load and Process the Image: Utilize the face_recognition library to load the image and detect the face location and landmarks grouped by facial features like chin, nose, etc.
  3. Calculate Distances: Implement a function to calculate the Euclidean distance between two points. Use this to find the distances from the points at the top of the right and left chin to the top of the nose.

Given: Two points (x1, y1) and (x2, y2)

Formula: Distance = sqrt((x2 - x1)² + (y2 - y1)²)

4. Compare Distances: If the distance on one side is significantly larger than on the other, conclude that the head is turned towards the shorter distance. For example, if the right chin distance is greater than the left one, the head is turned left.

5. Displaying the Result: Use Pillow (PIL fork) library to draw on the image, highlighting relevant landmarks. Add text to label the detected head orientation (turned right, turned left, facing straight).

Some tricks are used here to set label font size relative to the face size and write from the face location top left.

6. Save the Result: Save the modified image to the disk for review.

Running the Script

Run the script by passing the image file as an argument:

python detect_head_turn.py your_image_file.jpg

This command will generate an output image with the facial landmarks highlighted and the inferred head orientation labeled on the image.

Sample 1: Turn Left

python detect_head_turn.py left.jpg

Out:
ound 1 face(s) in this photograph.
red / green = 2.9, turned left
saved to out_left.jpg

Source Image:

Photo by 🇸🇮 Janko Ferlič on Unsplash

Output Image:

Sample 2: Face Straight

python detect_head_turn.py straight.jpg

Out:
Found 1 face(s) in this photograph.
red / green = 1.0, facing straight
saved to out_straight.jpg

Output Image:

Source photo by Joseph Gonzalez on Unsplash

Left-right flip on Mobile Selfie

Note that if you take a selfie with a mobile front camera, it is very likely the left and right are flipped. When you look at the selfie image you have taken, the left side of the image is your left. While you take a picture with a main camera, e.g. back camera of a mobile, the left side of the image is your right.

Conclusion

Facial landmark detection serves as a powerful tool for understanding more about an individual’s head orientation at a given moment. By analyzing the relative sizes of the chin regions, we can accurately predict the direction of a person’s head turn. Utilizing a combination of dlib and face_recognition libraries simplifies the process, allowing us to build intelligent systems in a few lines of code.

Citation

If you’re using this article in your research or applications, please cite using this BibTeX:

@article{xie2023detectheadturn,
title={How to Detect Head Turn with Face Landmarks},
author={Xie, Peter Jiping},
year={2023},
contact={peter.jp.xie@gmail.com}
}

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