5

I'm using the following Python function to convert quaternions to Euler angles:

import math

def quaternion_to_euler_angle(w, x, y, z):
    ysqr = y * y

    t0 = +2.0 * (w * x + y * z)
    t1 = +1.0 - 2.0 * (x * x + ysqr)
    X = math.degrees(math.atan2(t0, t1))

    t2 = +2.0 * (w * y - z * x)
    t2 = +1.0 if t2 > +1.0 else t2
    t2 = -1.0 if t2 < -1.0 else t2
    Y = math.degrees(math.asin(t2))

    t3 = +2.0 * (w * z + x * y)
    t4 = +1.0 - 2.0 * (ysqr + z * z)
    Z = math.degrees(math.atan2(t3, t4))

    return X, Y, Z

I would like to transform a Pandas DataFrame, which has columns "w", "quat_x", "quat_y" and "quat_z", to Eueler angles. Currently, I'm iterating over each row of the DataFrame using a for loop and call the quaternion_to_euler_angle() function on each row. This is very slow because I have more than 400'000 rows.

Is there a more efficient way to do it? For example, I could pass the DataFrame (or inidividual Series) to quaternion_to_euler_angle() but then the problem is to change quaternion_to_euler_angle() so that it can handle DataFrames instead of integers.

1
  • Can you add some sample data, 5 rows?
    – jezrael
    May 19, 2019 at 11:46

2 Answers 2

10

A more compact way is to use Rotation from scipy.spatial.transform:

import pandas as pd
from scipy.spatial.transform import Rotation

rot = Rotation.from_quat(quat_df)
rot_euler = rot.as_euler('xyz', degrees=True)
euler_df = pd.DataFrame(data=rot_euler, columns=['x', 'y', 'z'])
1
  • 1
    Just keep in mind that Scipy uses real last format for quaternions. There are also no flags or parameters to set the order of the quaternions. You have to make your own shim.
    – ZachS
    Nov 30, 2023 at 20:59
7

We could leverage vectorized NumPy ufuncs instead of their math module counterparts that work on entire array data and still have minimal change(s) -

import numpy as np

def quaternion_to_euler_angle_vectorized1(w, x, y, z):
    ysqr = y * y

    t0 = +2.0 * (w * x + y * z)
    t1 = +1.0 - 2.0 * (x * x + ysqr)
    X = np.degrees(np.arctan2(t0, t1))

    t2 = +2.0 * (w * y - z * x)
    t2 = np.where(t2>+1.0,+1.0,t2)
    #t2 = +1.0 if t2 > +1.0 else t2

    t2 = np.where(t2<-1.0, -1.0, t2)
    #t2 = -1.0 if t2 < -1.0 else t2
    Y = np.degrees(np.arcsin(t2))

    t3 = +2.0 * (w * z + x * y)
    t4 = +1.0 - 2.0 * (ysqr + z * z)
    Z = np.degrees(np.arctan2(t3, t4))

    return X, Y, Z 

So, the only replacements were :

math.degrees <-> np.degrees
math.atan2   <-> np.arctan2
math.asin    <-> np.arcsin

And np.where for vectorized checks and assignments.

Hence, we get our vectorized solution like so -

# For df.columns = ['w', 'quat_x', 'quat_y', 'quat_z']
X,Y,Z = quaternion_to_euler_angle_vectorized1(*df.values.T)

# If needed as a dataframe output 
df_out = pd.DataFrame({'X':X,'Y':Y,'Z':Z})

Timings on 400,000 rows -

In [55]: np.random.seed(0)
    ...: a = np.random.rand(400000,4)
    ...: df = pd.DataFrame(a)
    ...: df.columns = ["w", "quat_x", "quat_y" , "quat_z"]

In [56]: %timeit quaternion_to_euler_angle_vectorized1(*df.values.T)
1 loops, best of 3: 70.6 ms per loop

Optimization #1

Use np.clip to replace double np.where -

def quaternion_to_euler_angle_vectorized2(w, x, y, z):
    ysqr = y * y

    t0 = +2.0 * (w * x + y * z)
    t1 = +1.0 - 2.0 * (x * x + ysqr)
    X = np.degrees(np.arctan2(t0, t1))

    t2 = +2.0 * (w * y - z * x)

    t2 = np.clip(t2, a_min=-1.0, a_max=1.0)
    Y = np.degrees(np.arcsin(t2))

    t3 = +2.0 * (w * z + x * y)
    t4 = +1.0 - 2.0 * (ysqr + z * z)
    Z = np.degrees(np.arctan2(t3, t4))

    return X, Y, Z

Timings on same data -

In [70]: %timeit quaternion_to_euler_angle_vectorized2(*df.values.T)
10 loops, best of 3: 65.2 ms per loop

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