# Tag Info

12

Yes, it is normal. There are 2 ways to represent the same rotation with Euler angles. I personally don't like Euler angles, they mess up the stability of your app. I would avoid them. Plus, they are not very handy either.

10

transform.rotation retrieves a Quaternion. Try transform.rotation.eulerAngles.y instead.

9

Multiplying quaternions is going to suffer from accumulation of floating-point roundoff issues (even simple angles like 45 degrees won't be exact). It's a great way to composite rotations, but the precision of each of your quaternion components is going to drop-off over time. The bleed-through is one side-effect, a visually worse one though is your ...

7

You would need to convert the axis angle rotation to Euler angles. Here is a link explaining this process in some detail with code: http://www.euclideanspace.com/maths/geometry/rotations/conversions/angleToEuler/index.htm From the article: yaw = atan2(y * sin(angle)- x * z * (1 - cos(angle)) , 1 - (y2 + z2 ) * (1 - cos(angle))) ...

7

Firstly, should: sinP = -matrix.M32 EDIT: Full solution follows My derivation: Rx(P)=| 1 0 0 | | 0 cos P -sin P | | 0 sin P cos P | Ry(H)=| cos H 0 sin H | | 0 1 0 | | -sin H 0 cos H | Rz(B)=| cos B -sin B 0 | | sin B cos B 0 | | 0 0 1 | Multiplied with your ...

7

Have a look at this page. It has everything you need (even some code samples!) for dealing with 3D transformations. Quaternion to Euler Angles Euler Angles to Quaternion All rotation conversions

6

This looks like a classic case of old technology being overlooked - I managed to dig out a copy of Graphics Gems IV from the garage and it looks like Ken Shoemake has not only an algorithm for converting from Euler angles of arbitrary rotation order, but also answers most of my other questions on the subject. Hooray for books. If only I could vote up Mr. ...

6

I do not think there is a built in Matlab function to perform what you want. However, there is a function in the Mathworks user community which I believe is what you are looking for. spinCalc This will convert between the various rotation types DCM, Euler angles, Euler vectors, and Quaternions. Please note this comment from the above post regarding ...

6

You have probably figured this out by now... but What eulerAngle sequence does the function: glm::vec3 euler = glm::eulerAngles(q) * 3.14159f / 180.f; return? If it does not return explicitly an 'YXZ' sequence, you will not be able to use the next function properly: glm::mat4 transform1 = glm::eulerAngleYXZ(euler.y, euler.x, euler.z); Your variable ...

5

In a right-handed Cartesian coordinate system with Z axis pointing up, do this: struct Quaternion { double w, x, y, z; }; void GetEulerAngles(Quaternion q, double& yaw, double& pitch, double& roll) { const double w2 = q.w*q.w; const double x2 = q.x*q.x; const double y2 = q.y*q.y; const double z2 = q.z*q.z; const double ...

5

Here are my working assumptions: The coordinate system (x,y,z) is such that positive x is to the right, positive y is down, and z is the remaining direction. In particular, y=0 is the ground plane. An object at (0,0,0) currently facing towards (0,0,1) is being turned to face towards (x,y,z). In order to accomplish this, there will be a rotation about the ...

5

Rich Seller's answer shows you how to rotate a point from one 3-D coordinate system to another system, given a set of Euler angles describing the rotation between the two coordinate systems. But it sounds like you're asking for something different: You have: 3-D coordinates of a single point You want: a set of Euler angles If that's what you're asking ...

5

First, you can calculate the axis and amount of rotation (assuming an arbitrary axis): Vector3 axis = Vector3.Cross(normal1, normal2); axis.Normalize(); double angle = Math.Acos(Vector3.Dot(normal1, normal2) / normal1.Length() / normal2.Length()); If the normals are normalized, then the calculation of the angle reduces to double angle = ...

5

We can get euler angles from rotation matrix using following formula. Given a 3×3 rotation matrix The 3 Euler angles are Here atan2 is the same arc tangent function, with quadrant checking, you typically find in C or Matlab. Note: Care must be taken if the angle around the y-axis is exactly +/-90°. In that case all elements in the first column ...

5

Given a single image and no other information, there is no single solution for the angles. Consider the case of just Yaw. Projected onto the 2d plane, this is visible as a small change in the projected distance between eyes and the placement of the eyes with respect to the nose/mouth. This distance is not a constant from person to person, however. One ...

5

Let's see if I understand correctly. This is about the orientation of a rigid body in three dimensional space, like an air plane during flight. The nose of that airplane points towards the direction vector D=(XD,YD,ZD) . Towards the roof is the up vector U=(XU,YU,ZU) . Then heading H would be the direction vector D projected onto the earth surface: ...

4

Using CMDeviceMotion, you can get a CMAttitude object with "roll, pitch and yaw" - where for example, given a phone held in portrait mode "yaw" is "azimuth", "pitch" is the tilt of the phone with respect to ground, or zenith, and "roll" is about the vector pointing through the screen and not what you're interested in. Things get a bit tricky because ...

4

As others have already pointed out, your question should be revised. Let's call your vectors a and b. I assume that length(a)==length(b) > 0 otherwise I cannot answer the question. Calculate the cross product of your vectors v = a x b; v gives the axis of rotation. By computing the dot product, you can get the cosine of the angle you should rotate with ...

3

Maybe you could use "DummyCube" object as a parent. Then you can rotate first the cube inside dummy cube and then the DummyCube.

3

Here's some code I wrote to do something pretty similar, really only caring about the rotation of the device in the roll direction. Hope it helps! It just uses the accelerometer values to determine the pitch, no need to get orientation of the view. public void onSensorChanged(SensorEvent event) { float x = -1 * event.values[0] / ...

3

Here is a paper I wrote on converting a quaternion to Euler angles. Link 1 I have also put a number of documents at this location discussing various aspects of quaternions, Euler angles and rotation matrices (DCM). Link 2

3

Accumulation is an inexact process. Accumulating lots of incremental rotations will accumulate roundoff error whether you do it with quaternions or matrices. I imagine something like this: you got your code up and running, but noticed that after a certain amount of navigation your camera was heeling over annoyingly -- violating an invariant you hadn't ...

3

I have posted my paper titled "Quaternion to Euler Angle Conversion for Arbitrary Rotation Sequence Using Geometric Methods" on my website at noelhughes.net. I also have algorithms for converting any set of Euler angles to a quaternion and quaternion to/from direction cosine matrix which I will post this weekend. These are also on Martin Bakers website, ...

3

Transform Rotation is used for setting an angle, not turning an object, so you would need to get the rotation, add your change, and then set the new rotation. Try using transform.rotate instead. Check the Unity3d scripting reference here: http://unity3d.com/support/documentation/ScriptReference/Transform.Rotate.html

3

I don't think you're going to find an answer that's pure trig. Not an elegant one, anyway. Euler angles(Pitch/Yaw/Roll) are not the right tool for this job. Gimble-lock will be a problem, as well as the ambiguity of the order of operations. I suggest storing your objects' current rotational state in either a Matrix or a Quaternion. Only use Euler angles ...

3

So, this is what I ended up doing: I figured that unless you are actually dealing with 3D images, rectifying the perspective of a photo is a 2D operation. With this in mind, I replaced the z-axis values of the transformation matrix with zeros and ones, and applied a 2D Affine transformation to the image. Rotation of the initial image (see initial post) with ...

3

Maybe my answer is not correct due to my mis-understanding of the camera parameters, but I was wondering whether the Yaw/Pitch/Roll is relative to the position of your object. I used the formula of general rotations, and my code is below (the rotation functions R_x, R_y, and R_z were copied from yours, I didn't paste them here) close all ...

3

I assume you're referring to Euler Compass on the Android Play Store? The Accelerometer and Magnetic compass readings are very noisy. You would get better results if you also factor in the Gyroscope, maybe with a Kalman filter, or something similar. On windows tablets, most of the complex math is already done for you, but on Android and iPhone, you have to ...

2

Wikipedia shows how you can use the parts of the quaternion and calculate the euler angles.

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