In my current project I ran into trouble regarding the quaternion provided by Core Motion's CMAttitude. I put the iPhone 5 (iOS 6.0.1) at a well defined start position. Then I start to move the device quickly around like in a fast pacing game. When I return to the start position after 10-30 seconds the reported yaw angle differ from the start position for 10-20 degrees (most of the time ≈11°).
I used the old (and sadly no longer available) Core Motion Teapot sample to validate the effect. The Euler Angles for logging are read directly from CMAttitude:
NSLog(@"pitch: %f, roll: %f, yaw: %f", attitude.pitch * 180 / M_PI, attitude.roll * 180 / M_PI, attitude.yaw * 180 / M_PI);
I found this on two different iPhone 5 devices manufactured at different times in different factories. But really weird is that my iPhone 4, running iOS 5.1.1, is working as expected. It seems to me an iOS bug and I filed a bug report already, but on the other hand I can hardly imagine that nobody had yet stumbled upon it. I suspect it might has to do with the redesigned Core Motion API. Starting with version 5 the magnetometer (compass) is considered for sensor fusion as well. Console shows that bias estimations from locationd are provided to CoreMotion:
locationd <Notice>: GYTT inserted: bias,-0.196419,1.749323,-1.828088,variance,0.002644,0.004651,0.002527,temperature,31.554688
My question(s): Is there chance to block magnetometer readings when using Device Motion? I tried deactivating location services but it doesn't affect Core Motion. If not possible, what is the alternative / workaround, Accelerometer based gravity estimation?
PS: As we are dealing with quaternion based models this is not related to Gimbal Lock
After doing some more measurements it seems clear that only yaw is affected. Pitch and roll show deviations within tolerance (<= 1°) while yaw is drifting regardless of the starting position.
CMDeviceMotion.gravity appears to be clean too.
EDIT (2): I could reproduce the problem with the MotionGraphs sample attached to recent XCode versions. The yaw graph is reproducibly drifting away from origin.