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What is the correct way to use CMAttitude:multiplyByInverseOfAttitude?

Assuming an iOS5 device laying flat on a table, after starting CMMotionManager with:

CMMotionManager *motionManager = [[CMMotionManager alloc]init];
[motionManager startDeviceMotionUpdatesUsingReferenceFrame:

Later, CMDeviceMotion objects are obtained:

CMDeviceMotion *deviceMotion = [motionManager deviceMotion];

I expect that [deviceMotion attitude] reflects the rotation of the device from True North.

By observation, [deviceMotion userAcceleration] reports acceleration in the device reference frame. That is, moving the device side to side (keeping it flat on the table) registers acceleration in the x-axis. Turning the device 90° (still flat) and moving the device side to side still reports x acceleration.

What is the correct way to transform [deviceMotion userAcceleration] to obtain North-South/East-West acceleration rather than left-right/forward-backward?

CMAttitude multiplyByInverseOfAttitude seems unnecessary since a reference frame has already been specified and it is unclear from the documentation how to apply the attitude to CMAcceleration.

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up vote 11 down vote accepted

The question would not have arisen if CMDeviceMotion had an accessor for the userAcceleration in coordinates of the reference frame. So, I used a category to add the required method:

In CMDeviceMotion+TransformToReferenceFrame.h:

#import <CoreMotion/CoreMotion.h>

@interface CMDeviceMotion (TransformToReferenceFrame)

and in CMDeviceMotion+TransformToReferenceFrame.m:

#import "CMDeviceMotion+TransformToReferenceFrame.h"

@implementation CMDeviceMotion (TransformToReferenceFrame)

    CMAcceleration acc = [self userAcceleration];
    CMRotationMatrix rot = [self attitude].rotationMatrix;

    CMAcceleration accRef;
    accRef.x = acc.x*rot.m11 + acc.y*rot.m12 + acc.z*rot.m13;
    accRef.y = acc.x*rot.m21 + acc.y*rot.m22 + acc.z*rot.m23;
    accRef.z = acc.x*rot.m31 + acc.y*rot.m32 + acc.z*rot.m33;

    return accRef;


Now, code that previously used [deviceMotion userAcceleration] can use [deviceMotion userAccelerationInReferenceFrame] instead.

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This is interesting, nice work. I assume you are using it in conjunction with the compass (CLHeading). What are you doing with the numbers you get from the acceleration? – Kevin_TA Jun 14 '12 at 17:55
In theory, initialising with CMAttitudeReferenceFrameXTrueNorthZVertical means that the compass heading is already considered. In general, there are many interesting uses for the world acceleration rather than device acceleration. – Zaq Jun 18 '12 at 7:36
Your answer is incorrect. In order to move a vector from reference frame A to reference frame B, when rotation matrix from B to A is given, the vector should be multiplied by inverse rotation matrix. Here is how you calculate the inverse matrix stackoverflow.com/a/984054/204533 – Vitaly Stakhov Mar 10 '13 at 10:27
@Vitaly, thanks for the feedback. The code is operational and working fine; have you tried it? Your link gives a method for inverting an arbitrary matrix but "the inverse of a rotation matrix is simply its transpose" (mathpages.com/home/kmath593/kmath593.htm). It's subtle, but the code transposes the rotation matrix in the calculation. – Zaq Mar 11 '13 at 8:03
@Zaq, I'm taking my words back, you're right. Took a look at my rotation matrix inversion code, which is an arbitrary matrix inversion code, and it produces the transposed matrix. Apparently rotation matrix inverse is its transpose because of the two facts: a) determinant is always 1 as vectors don't scale when rotate and b) rotation matrix is an orthogonal matrix. – Vitaly Stakhov Mar 18 '13 at 18:56

i tried to implement a solution after reading the paper linked above.

Steps are the follows:

  • take the attitude rotation matrix every update time.
  • comput the inverse matrix.
  • multiplying the inverse matrix for the UserAcceleration vector.

the resultant vector will be the projection of the vector.

-x north, +x south

-y east, +y weast

my code it's not perfect yet, i'm working on it.

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Can i do this for pitch and roll also >? – Nil Jul 21 '15 at 11:01
can you share the code? or explain the above steps.. All I got is Store the attitude which you want to create as a reference, compute the inverse of the current attitude – Nil Jul 27 '15 at 9:45

The reference frame is related to the attitude value, look the value of attitude of yaw angle; If you don't use a reference frame, when you start your app, this value is always zero, instead if you use the reference frame CMAttitudeReferenceFrameXTrueNorthZVertical the yaw value indicates the angle between the x-axis and true north. with this information you can identify the attitude of phone in the coordinates of the earth and therefore the position of axes of the accelerometer with respect to the cardinal points.

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Thanks @batti, I understand the geometry, the question is about coding. The API doesn't seem to support a simple approach to applying the transform. In CMAttitude, the euler angles, the quaternion representation and the rotation matrix are all easily accessed, but there's no obvious way to apply these to the CMAcceleration. Worse still, CMAcceleration is read-only, so I can't transform it myself and update the object before sending it on. – Zaq Nov 1 '11 at 3:11
the problem is that le axis of accelerometer are fixed with the device, so the accelerometer can measure the acceleration in the device frame. If the sensors were not so noisy, you should just find the horizontal plane of acceleration, the plane perpendicular to the vector of gravity, look the vector on this plane and calculate the angle between the vector and the north to know the direction of the acceleration in the cardinals cordinates. What does your app do? – Batti Nov 2 '11 at 10:01
this should be helpful, section 3.A link – Batti Nov 2 '11 at 11:03

According to Apple's Documentation, CMAttitude refers to the orientation of a body relative to a given frame of reference. And either userAcceleration or gravity is the value of the device's frame. So in order to get the value of reference frame. We should do as @Batti said

  1. take the attitude rotation matrix every update time.
  2. comput the inverse matrix.
  3. multiplying the inverse matrix for the UserAcceleration vector.

Here's the Swift version

import CoreMotion
import GLKit

extension CMDeviceMotion {

    func userAccelerationInReferenceFrame() -> CMAcceleration {

        let origin = userAcceleration
        let rotation = attitude.rotationMatrix
        let matrix = rotation.inverse()

        var result = CMAcceleration()
        result.x = origin.x * matrix.m11 + origin.y * matrix.m12 + origin.z * matrix.m13;
        result.y = origin.x * matrix.m21 + origin.y * matrix.m22 + origin.z * matrix.m23;
        result.z = origin.x * matrix.m31 + origin.y * matrix.m32 + origin.z * matrix.m33;

        return result

    func gravityInReferenceFrame() -> CMAcceleration {

        let origin = self.gravity
        let rotation = attitude.rotationMatrix
        let matrix = rotation.inverse()

        var result = CMAcceleration()
        result.x = origin.x * matrix.m11 + origin.y * matrix.m12 + origin.z * matrix.m13;
        result.y = origin.x * matrix.m21 + origin.y * matrix.m22 + origin.z * matrix.m23;
        result.z = origin.x * matrix.m31 + origin.y * matrix.m32 + origin.z * matrix.m33;

        return result

extension CMRotationMatrix {

    func inverse() -> CMRotationMatrix {

        let matrix = GLKMatrix3Make(Float(m11), Float(m12), Float(m13), Float(m21), Float(m22), Float(m23), Float(m31), Float(m32), Float(m33))
        let invert = GLKMatrix3Invert(matrix, nil)

        return CMRotationMatrix(m11: Double(invert.m00), m12: Double(invert.m01), m13: Double(invert.m02),
                            m21: Double(invert.m10), m22: Double(invert.m11), m23: Double(invert.m12),
                            m31: Double(invert.m20), m32: Double(invert.m21), m33: Double(invert.m22))



Hope it helps a little bit

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