 |
| 0 degrees from up vector. Good. yaw 0, pitch 0, roll 0 |
2:24 PM
One of the hardest things to do is to keep going each day when you're feeling doubt and time pressures.
I tried comparing the angle between two quaternions and no luck. Quaternions could work differently to vectors in this way.
Nope. I think, I'm messing up defining an up quaternion.
4:28 PM
I hate quaternions. So much.
5:10 PM
Calculating the angle between an up vector and a direction vector only works in when I rotate in some directions.
5:30 PM
I can rotate objects as much as I like but I can't get the current rotation level back to check whether an object has rotated too far.
6:17 PM
Looking at the direction vector doesn't help. Perhaps, I can look
6:26 PM
GOT IT!
1) Create two up vectors (0, 1, 0). Call them Alpha and Bravo.
2) Rotate Bravo by the robot's orientation.
3) Calculate the angle between Alpha and Bravo.
 |
| 45 degrees from up vector. Good. yaw 0, pitch -45, roll 0 |
 |
| 45 degrees from up vector. Good. yaw -45, pitch -90, roll 90 |
 |
| 45 degrees from up vector. Good. yaw 0, pitch, 135, roll -180 |
 |
| 45 degrees from up vector. Good. yaw 45, -90, 90 |
 |
| 45 degrees from up vector. Good. yaw 0, pitch 45, roll 0 |
YES! YES! YES!
I don't know why this doesn't work when Bravo is (0, 0, -1) and I don't know how to do this with quaternions.
More screen shots to illustrate why using pitch and yaw to detect the extent of tipping over was difficult.
 | |
| 45 degrees from up vector. Good yaw 0, pitch 0, roll -45 |
Up till now we could use the rule that a robot has tipped too far when either absolute pitch or absolute roll has exceeded 45 degrees.
 |
| 46 degrees from up vector. Good. yaw -34, pitch -18, roll -34 |
However, there are situations like this which makes using such a rule difficult.
Some code fragments to illustrate what I'm doing.
void Robot::Rotate( const Direction& dir ) {
const float increment = 5.0f;
float yaw = 0.0f;
float pitch = 0.0f;
float roll = 0.0f;
switch( dir ) {
case ROTATE_DOWN:
pitch = Ogre::Degree( -increment ).valueRadians();
break;
case ROTATE_UP:
pitch = Ogre::Degree( increment ).valueRadians();
break;
case ROTATE_LEFT:
yaw = Ogre::Degree( increment ).valueRadians();
break;
case ROTATE_RIGHT:
yaw = Ogre::Degree( -increment ).valueRadians();
break;
case ROLL_LEFT:
roll = Ogre::Degree( -increment ).valueRadians();
break;
case ROLL_RIGHT:
roll = Ogre::Degree( increment ).valueRadians();
break;
default:
break;
}
// get transform
btTransform transform;
transform.setIdentity();
transform = rigidBody->getCenterOfMassTransform();
// modify transform
btMatrix3x3 matrix3x3;
matrix3x3.setEulerYPR( roll, yaw, pitch );
transform.getBasis() *= matrix3x3;
// apply transform
rigidBody->setCenterOfMassTransform( transform );
// debug
transform.getBasis().getEulerYPR( roll, yaw, pitch );
cout << "yaw : " << nint( Ogre::Radian( yaw ).valueDegrees() )
<< endl;
cout << "pitch : " << nint( Ogre::Radian( pitch ).valueDegrees() )
<< endl;
cout << "roll : " << nint( Ogre::Radian( roll ).valueDegrees() )
<< endl;
// WORKS!
const btVector3 upVec( 0.0f, 1.0f, 0.0f );
const btQuaternion rotQua = transform.getRotation();
btVector3 rotVec( 0.0f, 1.0f, 0.0f );
rotVec = transform.getBasis() * rotVec;
const float angle = upVec.angle( rotVec );
// ARGH!
//const btQuaternion upQua( btVector3( 1.0f, 0.0f, 0.0f ), 90.0f ); // up
//const btQuaternion upQua( btVector3( 0.0f, 0.0f, 1.0f ), 0.0f ); // up
//const btQuaternion upQua( btVector3( 0.0f, 1.0f, 0.0f ), 0.0f ); // up
//btQuaternion rotQua( upQua );
//rotQua = rotQua * transform.getRotation();
//const float angle = upQua.angle( rotQua );
cout << "angle: " << Ogre::Radian( angle ).valueDegrees() << endl;
}
Pomodoros
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RELATED
Hmm. What set of values is OGRE using to render the orientation of your object?
ReplyDeleteHi Anonymous,
ReplyDeleteI took a vector representing position and a quaternion representing orientation from Bullet and then used them in Ogre. I'll post up the actual pitch, yaw, and roll values for each of the screen-shots in a few hours.
Hi Anonymous,
ReplyDeleteI've added a few screen shots, yaw, pitch, and roll values, and some code to clarify the difficulties I had and the approach that I found.
The function allows me to manually rotate a robot depending on the input direction.
Line 36 and 43 where I call setEulerYPR() and getEulerYPR() look a bit funny because either they don't work as they should so I had to modify how I used them or I'm way off.
The key part of this is Bullet code with a few convenience fragments from Ogre.