# Quaternion to Euler angles algorithm - How to convert to 'Y = Up' and between handedness?

I have an algorithm for converting between a Quaternion and Euler angles.

``````    public static Vector3 ToEulerAngles(this Quaternion q)
{
// Store the Euler angles in radians
Vector3 pitchYawRoll = new Vector3();

double sqw = q.W * q.W;
double sqx = q.X * q.X;
double sqy = q.Y * q.Y;
double sqz = q.Z * q.Z;

// If quaternion is normalised the unit is one, otherwise it is the correction factor
double unit = sqx + sqy + sqz + sqw;
double test = q.X * q.Y + q.Z * q.W;

if (test > 0.4999f * unit)                              // 0.4999f OR 0.5f - EPSILON
{
// Singularity at north pole
pitchYawRoll.Y = 2f * (float)Math.Atan2(q.X, q.W);  // Yaw
pitchYawRoll.X = PI * 0.5f;                         // Pitch
pitchYawRoll.Z = 0f;                                // Roll
return pitchYawRoll;
}
else if (test < -0.4999f * unit)                        // -0.4999f OR -0.5f + EPSILON
{
// Singularity at south pole
pitchYawRoll.Y = -2f * (float)Math.Atan2(q.X, q.W); // Yaw
pitchYawRoll.X = -PI * 0.5f;                        // Pitch
pitchYawRoll.Z = 0f;                                // Roll
return pitchYawRoll;
}
else
{
pitchYawRoll.Y = (float)Math.Atan2(2f * q.Y * q.W - 2f * q.X * q.Z, sqx - sqy - sqz + sqw);       // Yaw
pitchYawRoll.X = (float)Math.Asin(2f * test / unit);                                             // Pitch
pitchYawRoll.Z = (float)Math.Atan2(2f * q.X * q.W - 2f * q.Y * q.Z, -sqx + sqy - sqz + sqw);      // Roll
}

return pitchYawRoll;
}
``````

This method only works for a right-handed Cartesian coordinate system with the Z axis pointing up.

What would I change in order to make the Y axis point up instead of Z? (Would swapping X and Z work?)

How can I accommodate left handed coordinate systems?

EDIT:

``````public static Quaternion CreateFromYawPitchRoll(float yaw, float pitch, float roll)
{
float num = roll * 0.5f;
float num2 = (float)Math.Sin((double)num);
float num3 = (float)Math.Cos((double)num);
float num4 = pitch * 0.5f;
float num5 = (float)Math.Sin((double)num4);
float num6 = (float)Math.Cos((double)num4);
float num7 = yaw * 0.5f;
float num8 = (float)Math.Sin((double)num7);
float num9 = (float)Math.Cos((double)num7);
Quaternion result;
result.X = num9 * num5 * num3 + num8 * num6 * num2;
result.Y = num8 * num6 * num3 - num9 * num5 * num2;
result.Z = num9 * num6 * num2 - num8 * num5 * num3;
result.W = num9 * num6 * num3 + num8 * num5 * num2;
return result;
}
``````
-
Quaternions and euler angles are independent of the alignment of the coordinate system and of the headedness. Yaw, pitch and roll define rotations about the z, y and x axis respecitvely. It does not matter, how the axes are oriented. –  Nico Schertler Jul 15 '12 at 18:59
If I use this in combination with XNA's Quaternion.CreateFromYawPitchRoll then I do not get the original Quaternion though. msdn.microsoft.com/en-us/library/… –  user1423893 Jul 15 '12 at 23:24
Then the functions probably use different associations of yaw/pitch/roll to the axes. Swap the euler angles, so the definitions match . –  Nico Schertler Jul 16 '12 at 7:20
Could you please post an example based on the EDIT I have made which now includes the Quaternion.CreateFromYawPitchRoll? –  user1423893 Jul 16 '12 at 11:36

Here are changed methods that use the same definition of yaw, pitch, roll:

``````public static Quaternion CreateFromYawPitchRoll(float yaw, float pitch, float roll)
{
float rollOver2 = roll * 0.5f;
float sinRollOver2 = (float)Math.Sin((double)rollOver2);
float cosRollOver2 = (float)Math.Cos((double)rollOver2);
float pitchOver2 = pitch * 0.5f;
float sinPitchOver2 = (float)Math.Sin((double)pitchOver2);
float cosPitchOver2 = (float)Math.Cos((double)pitchOver2);
float yawOver2 = yaw * 0.5f;
float sinYawOver2 = (float)Math.Sin((double)yawOver2);
float cosYawOver2 = (float)Math.Cos((double)yawOver2);
Quaternion result;
result.X = cosYawOver2 * cosPitchOver2 * cosRollOver2 + sinYawOver2 * sinPitchOver2 * sinRollOver2;
result.Y = cosYawOver2 * cosPitchOver2 * sinRollOver2 - sinYawOver2 * sinPitchOver2 * cosRollOver2;
result.Z = cosYawOver2 * sinPitchOver2 * cosRollOver2 + sinYawOver2 * cosPitchOver2 * sinRollOver2;
result.W = sinYawOver2 * cosPitchOver2 * cosRollOver2 - cosYawOver2 * sinPitchOver2 * sinRollOver2;
return result;
}
``````

For `ToEulerAngles` (singularities ommitted):

``````pitchYawRoll.Y = (float)Math.Atan2(2f * q.X * q.W + 2f * q.Y * q.Z, 1 - 2f * (sqz  + sqw));     // Yaw
pitchYawRoll.X = (float)Math.Asin(2f * ( q.X * q.Z - q.W * q.Y ) );                             // Pitch
pitchYawRoll.Z = (float)Math.Atan2(2f * q.X * q.Y + 2f * q.Z * q.W, 1 - 2f * (sqy + sqz));      // Roll
``````

I performed the following test:

``````var q = CreateFromYawPitchRoll(0.2f, 0.3f, 0.7f);
var e = ToEulerAngles(q);
var q2 = CreateFromYawPitchRoll(e.Y, e.X, e.Z);
``````

with the following results;

``````e = (0.3, 0.2, 0.7) //pitch, yaw, roll
q2 = q
``````

Source: Wikipedia

-
Excellent answer, thanks. Are the singularities correct as originally written? –  user1423893 Jul 16 '12 at 13:29
`if (test > 0.4999f * unit) // 0.4999f OR 0.5f - EPSILON { // Singularity at north pole pitchYawRoll.Y = 2f * (float)Math.Atan2(q.Y, q.W); // Yaw pitchYawRoll.X = PI * 0.5f; // Pitch pitchYawRoll.Z = 0f; // Roll return pitchYawRoll; }` –  user1423893 Jul 16 '12 at 13:30
Just checked, PI does not produce the correct results. For example `FromYawPitchRoll((float)Math.PI, 0f, 0f)` –  user1423893 Jul 16 '12 at 13:43
`test` has to be `= q.X * q.Z - q.W * q.Y`. However, I am not absolutely sure, about the singularity values. You're best off trying it out. –  Nico Schertler Jul 16 '12 at 13:54
That equation for 'test' can't be correct. It produces a value of 0 for both (0, 0, 0) and (PI, 0, 0). –  user1423893 Jul 16 '12 at 14:30