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2

Your matrix: matrix (a,b,c): a : 0.707107 0.000000 0.707107 b : 0.000000 -1.000000 0.000000 c : -0.707107 0.000000 0.707107 is orthogonal but it is not a rotation matrix. A rotation matrix has determinant 1; your matrix has determinant -1 and is thus an improper rotation. I think your code is likely correct and the issue is in your data. Try it with ...


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You have two options. You can still use the XMQuaternionToAxisAngle() function, and it'll use an axis other than the cardinal axes. Any rotation can be represented as a single angle rotating around a given axis. On the other hand, if you really need to get it as Euler angles, there's no good function to do this for you. The formulas are readily available ...


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Your code XMVECTOR quaternion = XMVectorSet(random_x, random_y, 0); is not creating a valid quaternion. First, if you did not set the w component to 1, then the 4-vector quaternion doesn't actually represent a 3D rotation. Second, a quaternion's vector components are not Euler angles. You want to use XMQuaternionRotationRollPitchYaw which constructs a ...


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I finally solved this problem!! Obviously Unity has a precision problem with Quaternions. First of all the Quaternion == Quaternion comparision I made wasn't really safe and just an approximation (they even wrote it in the docs!). So I found out that both were actually different at a very very insignificant digit. I guess Unity doesn't properly normalize ...


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The most perfect answer has come to me after a lot of googling and experimentation: Disregard original ideas, acquire matrices! B.Matrix * Invert(A.Matrix) is stored as a relative marker, And then to restore, simply replace B's matrix with relative * A.MATRIX. This perfectly adjusts both rotation and position in one all-mighty swoop. I have no idea how to ...


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You want to implement the algorithm described here. You need to rotate B about an arbitrary axis - the same axis that you are rotating A about. I'm assuming you have an axis that you are rotating A about. If not, you can calculate one using the center point of A and a line parallel to the rotation normal.


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Use RotateAround. // Rotate around world y. transform.RotateAround(transform.position, Vector3.up, angle); // Rotate around local y. transform.RotateAround(transform.position, transform.up, angle); You may found other useful stuff in Transform documentation anyway.


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transform.eulerAngles = new Vector3(90, 0, 0); Rotates your gameobject to 90 degrees in x axis. Or you can rotate smoothly with Vector3 destination = new Vector3(90,0,0); transform.eulerAngles = Vector3.Lerp(transform.rotation.eulerAngles, destination, Time.deltaTime);


-1

vec_res = (inverse(VM) * conversion_to_matrix(q) * VM) * vec_input Is perfectly valid. The problem is... inverse(VM) * conversion_to_matrix(q) * VM is NOT equal to conversion_to_matrix(q) Therefore you have to keep the original equation in its entirety.


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Note that multiplying your vector with inverse(VM) * conversion_to_matrix(q) * VM is not the same as multiplying it with conversion_to_matrix(q) since matrix multiplication is not commutative. So you really have to compute the entire matrix given in the first formula above.


2

You can apply a Kalman filter to accelerometer data, it's a powerful technique though and there are lots of ways to do it wrong. If your goal is to learn about the filter then go for it - the discussion here might be helpful. If you just want to smooth the data and get on with the next problem then you might want to start with a moving average filter, or ...


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well, quaternions represent rotation around an axis, so the rotation is in the plane orthogonal to this axis, no ?


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I think it's possible to do what you want very quickly and efficiently. First thing, you should complete each orthonormal pair of vectors into an orthonormal basis. The obvious way to do so is by taking the cross product of the first two vectors. Order matters: if you want u0 to map to v0 and u1 to map to v1, then form the orthonormal basis {u0,u1,u2} where ...


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There is an exact correspondence between 3x3 rotation matrices and unit quarternions, up to a sign change in the quarternion (the sign is irrelevant when in comes to performing rotation on 3D vectors). This means that given two quarternions, q1, q2, and their corresponding matrices, m1, m2, the action of the quarternions on a vector v is the same as the ...


0

You are right Since quaternions are already a measure of rotation, should I just add (or multiply) another quaternion representing the desired rotation to q? You should multiply current rotation quaternion with desired rotation quaternion. Depending on, local frame "Y" or global frame "Y" you should multiply from left to right or right to left.


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There's a reason why all those tutorials point to rotational matrices: in 3D you can't perform simultaneous rotations one by one, you need to perform them at once. Since JavaFX only uses one angle and one axis, you have to provide the way to convert three rotations over three axes in just one angle and one axis. A while ago I went to all the math behind ...


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At the end of the day, I want my object (Polygon in SharpGL terms) to rotate about its own axes (or about the "world" axes, but be consistent). I think this answer you put in your question is somehow explaining the situation. In order to perform rotation around object axis: 1. Perform Translation/Rotation to your object and make the object axis ...



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