# Tag Info

6

Since your title does not really match your questions, I'm trying to answer as much as I can. Gyroscopes don't give an absolute orientation (as the ROTATION_VECTOR) but only rotational velocities around those axis they are built to 'rotate' around. This is due to the design and construction of a gyroscope. Imagine the construction below. The golden thing is ...

4

A direction vector is not a defined rotation, it still has an infinite number of possible solutions. See there is no information for how to rotate around the axis. Two, vectors is possible as is a vector and a rotation (with a meaningful center) and in fact a fully defined matrix. Because in your case the rotation is rather meaningless, just use the up ...

4

You can totally avoid having to implement momentum physics by making use of the UIScrollView class in UIKit. You can position a UIScrollView that doesn't actually draw any content over your OpenGL view and configure it to have the contentSize (scrollable area) and scrolling properties that you want. You can then make one of your classes conform to ...

4

I finally managed to solve the problem, To achieve this I used a sample code using augmented reality available on Apple developer ressources: pARk The idea was first to convert the sun's spherical coordinates to cartesian coordinates in order to get its position in the sky as a simple vector: {x, y, z}. The formula is available on Wikipedia : Spherical ...

3

As said before, you're probably best off using a library that already does the math for you. The problem here is that you've swapped signs for w_x on matrix[6] and matrix[9]. The relevant lines should read thusly: matrix[1] = 2*(x_y+w_z); matrix[5] = 1-2*(x_x+z_z); matrix[9] = 2*(y_z-w_x); matrix[13] = 0; matrix[2] = 2*(x_z-w_y); matrix[6] ...

3

I found out how to properly rotate a quaternion on my own. The key was to find vectors for the axis I want to rotate around. Those are used to create quaternions from axis and angle, when angle is the amount to rotate around the actual axis. The following code shows what I ended up with. It also allows to roll the camera, which might be useful some time. ...

3

Contrary to popular belief, quaternions are not magical "solve the Gimbal lock" devices, such that any uses of quaternions make Euler angles somehow not Euler angles. Your RotateTo3 function takes 3 Euler angles and converts them into a rotation matrix. It doesn't matter how you perform this process; whether you use 3 matrices, 3 quaternions or ...

3

The maths behind the rotation You are using quaternions when defining points and rotations. A quaternion q = a + bi + cj + dk would in your code be represented as: q.x = b; q.y = c; q.z = d; q.w = a; Your array p consists of quaternions that represent points in space. The coordinates (x, y, z) are written as xi + yj + zk, or in your code as: p[i].x = x; ...

3

M3 to M4 The answere is already there, given by Rob and Najzero. In most cases, it will be sufficient to construct the matrix as follows: m3: |a00|a01|a02| |a10|a11|a12| |a20|a21|a22| to m4: |a00|a01|a02| 0 | |a10|a11|a12| 0 | |a20|a21|a22| 0 | | 0 | 0 | 0 | 1 | The 4x4 matrix does not only allow to rotate a vector, but also to shift(translate) and ...

3

You need to rotate the accelerometer reading by the quaternion into the Earth frame of reference (into the coordinate system of the room if you like), then subtract gravity. The remaining acceleration is the acceleration of the sensor in the Earth frame of reference often referred to as linear acceleration or user acceleration. In pseudo-code, something ...

3

Never mind. If I compile the code with gcc -msse3 -O1 -S instead, I get the following: .text .align 4,0x90 .globl __Z13_mm_cross4_psU8__vectorfS_ __Z13_mm_cross4_psU8__vectorfS_: LFB644: movaps %xmm0, %xmm5 movaps %xmm1, %xmm3 movaps %xmm0, %xmm2 shufps \$27, %xmm0, %xmm5 movaps %xmm5, %xmm4 shufps \$17, %xmm1, %xmm3 ...

3

You need to maintain a separate variable for the interpolation and update that every frame. Otherwise your Time.deltaTime * rotationSpeed will keep going up forever past the 0-1 range. private float _RawLerp; private float _Lerp; public float _Speed; public transform _Source; public transform _Target; private transform _TransformCache; // the transform for ...

3

Convert the quaternion to a 3x3 rotation matrix and apply this rotation to your vector. For a unit (w, x, y, z) quaternion, this matrix is: ( 1 - 2 * ( y * y + z * z ) 2 * ( x * y - z * w ) 2 * (x * z + y * w ) ) R = ( 2 * ( x * y + z * w ) 1 - 2 * ( x * x + z * z ) 2 * (y * z - x * w ) ) ( 2 * ( x * z - y * w ) 2 ...

2

So here is the answer! @Stemkoski, thanks for the direction. I took a similar approach for a final solution that came to light yesterday. It is a bit a costly in computational power due to inverting a matrix, but it works well. First, create a new matrix as follows: var m = new THREE.Matrix4().getInverse(parent.matrix).multiply(target.matrix); This ...

2

Apparently there are a lot of different definitions of the Euler angles, and your two libraries use different conventions. From GLM's source they use Pitch, Yaw, Roll : template <typename T> GLM_FUNC_QUALIFIER detail::tvec3<T> eulerAngles ( detail::tquat<T> const & x ) { return detail::tvec3<T>(pitch(x), yaw(x), ...

2

note: copied from my answer here. All you have done is effectively implement Euler angles with quaternions. That's not helping. The problem with Euler angles is that, when you compute the matrices, each angle is relative to the rotation of the matrix that came before it. What you want is to take an object's current orientation, and apply a rotation along ...

2

You're doing the multiplications in the wrong order. For two rotations q1 and q2, if q2 is to follow q1 (since rotations are generally non-communitive) you multiply q2*q1. In a gimbal style system such as controls for a FPS, the priority order is always yaw, pitch, roll. This would suggest the following math: roll * pitch * yaw As a java point, I would ...

2

First, find the relative position vector dPT from vehicle to target: worldspace target vector dPT = T - P Since vehicle position P and target position T are in world coordinates, the resulting vector dPT will also be represented in world coordinates. So, you must use the vehicle orientation quaternion to rotate dPT from world coordinates to vehicle ...

2

The conjugate of a quaternion x + i y + j z + k w is defined as x - i y - j z - k w. There aren't three separate conjugates. Also, don't try putting norm, invx, invy, invz, conjx, etc. into your quaternion structure. Just write: typedef struct { double x; double y; double z; double w; } quaternion; and then write functions that take ...

2

glRotatef doesn't expect a quaternion, but an axis and angle (in degrees). Have a look at: http://www.euclideanspace.com/maths/geometry/rotations/conversions/matrixToAngle/index.htm

2

You can get the inverse of a matrix in XNA and then use it by doing this: Matrix inverseMatrix = Matrix.Inverse(myMatrix); Vector3 result = Vector3.Transform(myVector, inverseMatrix); From my understanding, though, you want to ignore the translation when getting the inverse. So you've got a direction only (basically this accounts for rotation, scale, ...

2

Solution: Change the order of your transformations. Quaternion result = PitchRotationQuaternion * oldTransform * YawRotationQuaternion; Explanation: You have an object with a local reference frame. I'll say that +x_o is toward the object's right, -z_o is "forward" and +y_o is "up" with respect to the object. The object exists in the world's ...

2

Quaternions have many advantages over Euler angles and are often preferable for 3D rotations: Easier (and well-defined) interpolation between quaternions (or: orientations): the resulting movement has constant angular velocity around a single axis, which is often aesthetically more pleasing. This process is called "slerp" and critical for ...

2

I think where you got confused here is that ((i)%4) evaluates to TRUE when i is not a multiple of 4, so you get an _mm_shuffle_ps for non-multiples of 4, otherwise you just get the original vector (since a rotate by a multiple of 4 is a no-op). Some background which may be useful: The vec_XXX macros indicate that this code was originally ported from ...

2

The order of rotation is relevant, and this might be what causes your confusion. Imagine a point on the x-axis at (1, 0, 0). When we now do a rotation of 90° around the x axis, nothing happens. Then we do a rotation of 90° around the y axis, which makes the point lie on the positive z-axis. If we change the order of rotation, the point will end on the y ...

2

I don't really get what you want to do with the x member of the quaternion. If anything you are comparing the x-coordinate of different rotation axes. However if I get the question right, you are looking for the difference of rotation angles around the x-axis. In this case http://en.wikipedia.org/wiki/Conversion_between_quaternions_and_Euler_angles explains ...

2

I can't reproduce it with the data you've provided. But it seems you're tweening on startV3DV while using a currentV3D Vector, which is not mentioned in your example code. It could contain invalid data such as 0 axis or 0 scale. Furthermore, this is not how quaternions are supposed to be used for tweening. What you seem to be trying to do here is tween ...

2

The dot product for quaternions is simply the standard Euclidean dot product in 4D: dot = left.x * right.x + left.y * right.y + left.z * right.z + left.w * right.w Then the angle your are looking for is the arccos of the dot product (note that the dot product is not the angle): acos(dot). However, if you are looking for the relative rotation between two ...

2

The constructors from an AngleAxis or Matrix are explicit meaning you have to write the conversion as follow: Matrix3f mat; Quaternionf q(mat); or Quaternionf q; q = mat; Same for AngleAxis.

2

If you want to find a quaternion diff such that diff * q1 == q2, then you need to use the multiplicative inverse: diff * q1 = q2 ---> diff = q2 * inverse(q1) where: inverse(q1) = conjugate(q1) / abs(q1) and: conjugate( quaternion(re, i, j, k) ) = quaternion(re, -i, -j, -k) If your quaternions are rotation quaternions, they should all be unit ...

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