I looked at a bunch of similar questions, and I cannot seem to find one that particularly answers my question. I am coding a simple 3d game, and I am trying to allow the player to pick up and move entities around my map. I essentially want to get a velocity vector that will "push" the physics object a distance from the player's eyes, wherever they are looking. Here's an example of this being done in another game (the player is holding a chair entity in front of his eyes).
To do this, I find out the player's eye angles, then get the forward vector from the angles, then calculate the velocity of the object. Here is my working code:
void Player::PickupOtherEntity( Entity& HoldingEntity )
{
QAngle eyeAngles = this->GetPlayerEyeAngles();
Vector3 vecPos = this->GetEyePosition();
Vector3 vecDir = eyeAngles.Forward();
Vector3 holdingEntPos = HoldingEntity.GetLocation();
// update object by holding it a distance away
vecPos.x += vecDir.x * DISTANCE_TO_HOLD;
vecPos.y += vecDir.y * DISTANCE_TO_HOLD;
vecPos.z += vecDir.z * DISTANCE_TO_HOLD;
Vector3 vecVel = vecPos - holdingEntPos;
vecVel = vecVel.Scale(OBJECT_SPEED_TO_MOVE);
// set the entity's velocity as to "push" it to be in front of the player's eyes
// at a distance of DISTANCE_TO_HOLD away
HoldingEntity.SetVelocity(vecVel);
}
All that is great, but I want to convert my math so that I can apply an impulse. Instead of setting a completely new velocity to the object, I want to "add" some velocity to its existing velocity. So supposing I have its current velocity, what kind of math do I need to "add" velocity? This is essentially a game physics question. Thank you!
A very simple implementation could be like this:
velocity(t+delta) = velocity(t) + delta * acceleration(t)
acceleration(t) = force(t) / mass of the object
velocity, acceleration and force are vectors. t, delta and mass scalars.
This only works reasonably well for small and equally spaced deltas. What you are essentially trying to achieve with this is a simulation of bodies using classical mechanics.
An Impulse is technically F∆t for a constant F. Here we might want to assume a∆t instead because mass is irrelevant. If you want to animate an impulse you have to decide what the change in velocity should be and how long it needs to take. It gets complicated real fast.
To be honest an impulse isn't the correct thing to do. Instead it would be preferable to set a constant pick_up_velocity (people don't tend to pick things up using an impulse), and refresh the position each time the object rises up velocity.y, until it reaches the correct level:
while(entPos.y < holdingEntPos.y)
{
entPos.y += pickupVel.y;
//some sort of short delay
}
And as for floating in front of the player's eyes, set an EyeMovementEvent of some sort that also sends the correct change in position to any entity the player is holding.
And if I missed something and that's what you are already doing, remember that when humans apply an impulse, it is generally really high acceleration for a really short time, much less than a frame. You wouldn't see it in-game anyways.
basic Newtonian/D'Alembert physics dictate:
derivate(position)=velocity
derivate(velocity)=acceleration
and also backwards:
integrate(acceleration)=velocity
integrate(velocity)=position
so for your engine you can use:
rectangle summation instead of integration (numerical solution of integral). Define time constant dt [seconds] which is the interval between updates (timer or 1/fps). So the update code (must be periodically called every dt:
vx+=ax*dt;
vy+=ay*dt;
vz+=az*dt;
x+=vx*dt;
y+=vy*dt;
z+=vz*dt;
where:
a{x,y,z} [m/s^2] is actual acceleration (in your case direction vector scaled to a=Force/mass)
v{x,y,z} [m/s] is actual velocity
x,y,z [m] is actual position
These values have to be initialized a,v to zero and x,y,z to init position
all objects/players... have their own variables
full stop is done by v=0; a=0;
driving of objects is done only by change of a
in case of collision mirror v vector by collision normal
and maybe multiply by some k<1.0 (0.95 for example) to account energy loss on impact
You can add gravity or any other force field by adding g vector:
vx+=ax*dt+gx*dt;
vy+=ay*dt+gy*dt;
vz+=az*dt+gz*dt;
also You can add friction and anything else you need
PS. the same goes for angles just use angle/omega/epsilon/I instead of x/a/v/m
to be clear by angles I mean rotation (pitch,yaw,roll) around mass center
I'm having difficulty getting the Chipmunk physics engine to do what I want. The only solution that appears to work requires some heavy vector math. Before diving into that rabbit hole for the other components of my game, I was hoping someone could fill me in on a better way to go about this. The desired gameplay is as follows:
A character moves around a finite space in a top-down view
Movement is always a constant velocity in whatever direction the character faces
The player taps on the screen, which causes the character to 'turn' towards the touched location
The basic idea is like driving a car. You cannot immediately turn around, but instead must first perform a u-turn. That car must also maintain a constant speed. How might I do this? Bonus question: how can you override whatever method chipmunk calls to update a body's position, and is this a good idea?
There is this tutorial on how to do top down controls using specially configure joints:
http://chipmunk-physics.net/tutorials/ChipmunkTileDemo/
It's based on Chipmunk Pro, but the stuff about controlling the character is easily adapted to vanilla Chipmunk. The "Tank" demo that comes with the non-Pro Chipmunk source implements pretty much the same thing if you want to see some C code for it.
You basically want to rotate the orientation of the player more gradual. You could do this at a constant rate, so when you tap the screen it will start rotating at a constant rate until it has reached the right orientation. This would give a circular turn circle. This will however affect your position, so you would have to keep turning until you would be on a collision course with the position you tapped.
The path you would travel would be similar to that of the game Achtung die kurve.
So you would have to save the location and orientation of the player (x, y and phi coordinates). And to determine whether to stop turning you could do something like this:
dx = playerx - tapx;
dy = playery - tapy;
targetAngle = atan2(dy,dx);
if (phi > targetAngle)
{
if (phi - targetAngle > PI) omega = rotate;
else omega = -rotate;
}
else if (phi < targetAngle)
{
if (targetAngle - phi > PI) omega = -rotate;
else omega = rotate;
}
else omega = 0;
For the past days, I've been trying to make a ping pong like game. I have 2 paddles and a ball. All dynamic sprites. Everything's been working well except for one issue I'm having. The ball tends to bounce on the same angle at some point. So there would be times when the player can simply move the paddle on a specific part and the game can go on for a while or might be forever, since the ball doesn't change its angular velocity regardless of which part of the paddle it hits. I'm using a combination of linear and angular velocity to keep the ball moving like so:
if(_isPaused == FALSE)
{
_world->Step(dt, 10, 10);
for(b2Body *b = _world->GetBodyList(); b; b=b->GetNext()) {
if (b->GetUserData() != NULL) {
CCSprite *sprite = (CCSprite *)b->GetUserData();
if(sprite.tag == 2)
{
b2Vec2 dir = b->GetLinearVelocity();
dir.Normalize();
float currentSpeed = dir.Length();
int maxSpeed = 60;
float accelerate = vel;
if(currentSpeed <= maxSpeed)
{
b->SetLinearVelocity(accelerate * dir);
}
sprite.position = ccp(b->GetPosition().x * PTM_RATIO,
b->GetPosition().y * PTM_RATIO);
sprite.rotation = -1 * CC_RADIANS_TO_DEGREES(b->GetAngle());
//Keep sprite from bouncing in a straight angle
b->SetAngularVelocity(_body->GetAngle());
}}}
So my question is, how can I manipulate the angular velocity to keep the ball bouncing on different angles everytime it collides with my paddle? I'm thinking something like getting the current angular velocity then multiplying it with some value but I'm not sure if that's the right way to approach the issue I'm having. Any suggestions or ideas would be greatly appreciated. Thanks in advanced.
The way I see it, you have two options:
Check the location of a collision. If it's close to the top/bottom edge of the paddle, deflect the outgoing velocity by an angular amount proportional to the surface "curvature" at that point. Of course, this is cheating, but if the artwork and code are in agreement, it looks correct. And graphics is "the art of cheating without getting caught".
You could take into account the current velocity of the paddle as well as that of the ball. Eg: if the ball is moving downwards and to the right, and the paddle is moving down, then you can compute the outgoing direction using conservation of linear momentum. Just make sure you restrict the paddle's change in momentum along the horizontal axis to be zero.
Finally, you could combine the above techniques, but now you'd have to use accurate collision detection (not the hack I described in (1) above).
Hope that helps!
A few pointers, you should use SetLinearVelocity() and SetAngularVelocity() rarely. Each alters a property of the body definition, which could make you run into problems later on when things get more complex. It would be better to use ApplyForceToCenter() or ApplyLinearImpulse() in the place of SetLinearVelocity() as these two are much more versatile functions and are a bit more coder-friendly. In my opinion, I don't think you should use b->SetAngularVelocity(_body->GetAngle()); If you wanted to change the angular velocity each time it collided, you could, in your beginContact method, write that every time the body collides with the paddle body, a random angular impulse is applied to the ball, using ApplyAngularImpulse().Hope that helps.
I am implementing a 3D engine for spatial visualisation, and am writing a camera with the following navigation features:
Rotate the camera (ie, analogous to rotating your head)
Rotate around an arbitrary 3D point (a point in space, which is probably not in the center of the screen; the camera needs to rotate around this keeping the same relative look direction, ie the look direction changes too. This does not look directly at the chosen rotation point)
Pan in the camera's plane (so move up/down or left/right in the plane orthogonal to the camera's look vector)
The camera is not supposed to roll - that is, 'up' remains up. Because of this I represent the camera with a location and two angles, rotations around the X and Y axes (Z would be roll.) The view matrix is then recalculated using the camera location and these two angles. This works great for pan and rotating the eye, but not for rotating around an arbitrary point. Instead I get the following behaviour:
The eye itself apparently moving further up or down than it should
The eye not moving up or down at all when m_dRotationX is 0 or pi. (Gimbal lock? How can I avoid this?)
The eye's rotation being inverted (changing the rotation makes it look further up when it should look further down, down when it should look further up) when m_dRotationX is between pi and 2pi.
(a) What is causing this 'drift' in rotation?
This may be gimbal lock. If so, the standard answer to this is 'use quaternions to represent rotation', said many times here on SO (1, 2, 3 for example), but unfortunately without concrete details (example. This is the best answer I've found so far; it's rare.) I've struggled to implemented a camera using quaternions combining the above two types of rotations. I am, in fact, building a quaternion using the two rotations, but a commenter below said there was no reason - it's fine to immediately build the matrix.
This occurs when changing the X and Y rotations (which represent the camera look direction) when rotating around a point, but does not occur simply when directly changing the rotations, i.e. rotating the camera around itself. To me, this doesn't make sense. It's the same values.
(b) Would a different approach (quaternions, for example) be better for this camera? If so, how do I implement all three camera navigation features above?
If a different approach would be better, then please consider providing a concrete implemented example of that approach. (I am using DirectX9 and C++, and the D3DX* library the SDK provides.) In this second case, I will add and award a bounty in a couple of days when I can add one to the question. This might sound like I'm jumping the gun, but I'm low on time and need to implement or solve this quickly (this is a commercial project with a tight deadline.) A detailed answer will also improve the SO archives, because most camera answers I've read so far are light on code.
Thanks for your help :)
Some clarifications
Thanks for the comments and answer so far! I'll try to clarify a few things about the problem:
The view matrix is recalculated from the camera position and the two angles whenever one of those things changes. The matrix itself is never accumulated (i.e. updated) - it is recalculated afresh. However, the camera position and the two angle variables are accumulated (whenever the mouse moves, for example, one or both of the angles will have a small amount added or subtracted, based on the number of pixels the mouse moved up-down and/or left-right onscreen.)
Commenter JCooper states I'm suffering from gimbal lock, and I need to:
add another rotation onto your transform that rotates the eyePos to be
completely in the y-z plane before you apply the transformation, and
then another rotation that moves it back afterward. Rotate around the
y axis by the following angle immediately before and after applying
the yaw-pitch-roll matrix (one of the angles will need to be negated;
trying it out is the fastest way to decide which).
double fixAngle = atan2(oEyeTranslated.z,oEyeTranslated.x);
Unfortunately, when implementing this as described, my eye shoots off above the scene at a very fast rate due to one of the rotations. I'm sure my code is simply a bad implementation of this description, but I still need something more concrete. In general, I find unspecific text descriptions of algorithms are less useful than commented, explained implementations. I am adding a bounty for a concrete, working example that integrates with the code below (i.e. with the other navigation methods, too.) This is because I would like to understand the solution, as well as have something that works, and because I need to implement something that works quickly since I am on a tight deadline.
Please, if you answer with a text description of the algorithm, make sure it is detailed enough to implement ('Rotate around Y, then transform, then rotate back' may make sense to you but lacks the details to know what you mean. Good answers are clear, signposted, will allow others to understand even with a different basis, are 'solid weatherproof information boards.')
In turn, I have tried to be clear describing the problem, and if I can make it clearer please let me know.
My current code
To implement the above three navigation features, in a mouse move event moving based on the pixels the cursor has moved:
// Adjust this to change rotation speed when dragging (units are radians per pixel mouse moves)
// This is both rotating the eye, and rotating around a point
static const double dRotatePixelScale = 0.001;
// Adjust this to change pan speed (units are meters per pixel mouse moves)
static const double dPanPixelScale = 0.15;
switch (m_eCurrentNavigation) {
case ENavigation::eRotatePoint: {
// Rotating around m_oRotateAroundPos
const double dX = (double)(m_oLastMousePos.x - roMousePos.x) * dRotatePixelScale * D3DX_PI;
const double dY = (double)(m_oLastMousePos.y - roMousePos.y) * dRotatePixelScale * D3DX_PI;
// To rotate around the point, translate so the point is at (0,0,0) (this makes the point
// the origin so the eye rotates around the origin), rotate, translate back
// However, the camera is represented as an eye plus two (X and Y) rotation angles
// This needs to keep the same relative rotation.
// Rotate the eye around the point
const D3DXVECTOR3 oEyeTranslated = m_oEyePos - m_oRotateAroundPos;
D3DXMATRIX oRotationMatrix;
D3DXMatrixRotationYawPitchRoll(&oRotationMatrix, dX, dY, 0.0);
D3DXVECTOR4 oEyeRotated;
D3DXVec3Transform(&oEyeRotated, &oEyeTranslated, &oRotationMatrix);
m_oEyePos = D3DXVECTOR3(oEyeRotated.x, oEyeRotated.y, oEyeRotated.z) + m_oRotateAroundPos;
// Increment rotation to keep the same relative look angles
RotateXAxis(dX);
RotateYAxis(dY);
break;
}
case ENavigation::ePanPlane: {
const double dX = (double)(m_oLastMousePos.x - roMousePos.x) * dPanPixelScale;
const double dY = (double)(m_oLastMousePos.y - roMousePos.y) * dPanPixelScale;
m_oEyePos += GetXAxis() * dX; // GetX/YAxis reads from the view matrix, so increments correctly
m_oEyePos += GetYAxis() * -dY; // Inverted compared to screen coords
break;
}
case ENavigation::eRotateEye: {
// Rotate in radians around local (camera not scene space) X and Y axes
const double dX = (double)(m_oLastMousePos.x - roMousePos.x) * dRotatePixelScale * D3DX_PI;
const double dY = (double)(m_oLastMousePos.y - roMousePos.y) * dRotatePixelScale * D3DX_PI;
RotateXAxis(dX);
RotateYAxis(dY);
break;
}
The RotateXAxis and RotateYAxis methods are very simple:
void Camera::RotateXAxis(const double dRadians) {
m_dRotationX += dRadians;
m_dRotationX = fmod(m_dRotationX, 2 * D3DX_PI); // Keep in valid circular range
}
void Camera::RotateYAxis(const double dRadians) {
m_dRotationY += dRadians;
// Limit it so you don't rotate around when looking up and down
m_dRotationY = std::min(m_dRotationY, D3DX_PI * 0.49); // Almost fully up
m_dRotationY = std::max(m_dRotationY, D3DX_PI * -0.49); // Almost fully down
}
And to generate the view matrix from this:
void Camera::UpdateView() const {
const D3DXVECTOR3 oEyePos(GetEyePos());
const D3DXVECTOR3 oUpVector(0.0f, 1.0f, 0.0f); // Keep up "up", always.
// Generate a rotation matrix via a quaternion
D3DXQUATERNION oRotationQuat;
D3DXQuaternionRotationYawPitchRoll(&oRotationQuat, m_dRotationX, m_dRotationY, 0.0);
D3DXMATRIX oRotationMatrix;
D3DXMatrixRotationQuaternion(&oRotationMatrix, &oRotationQuat);
// Generate view matrix by looking at a point 1 unit ahead of the eye (transformed by the above
// rotation)
D3DXVECTOR3 oForward(0.0, 0.0, 1.0);
D3DXVECTOR4 oForward4;
D3DXVec3Transform(&oForward4, &oForward, &oRotationMatrix);
D3DXVECTOR3 oTarget = oEyePos + D3DXVECTOR3(oForward4.x, oForward4.y, oForward4.z); // eye pos + look vector = look target position
D3DXMatrixLookAtLH(&m_oViewMatrix, &oEyePos, &oTarget, &oUpVector);
}
It seems to me that "Roll" shouldn't be possible given the way you form your view matrix. Regardless of all the other code (some of which does look a little funny), the call D3DXMatrixLookAtLH(&m_oViewMatrix, &oEyePos, &oTarget, &oUpVector); should create a matrix without roll when given [0,1,0] as an 'Up' vector unless oTarget-oEyePos happens to be parallel to the up vector. This doesn't seem to be the case since you're restricting m_dRotationY to be within (-.49pi,+.49pi).
Perhaps you can clarify how you know that 'roll' is happening. Do you have a ground plane and the horizon line of that ground plane is departing from horizontal?
As an aside, in UpdateView, the D3DXQuaternionRotationYawPitchRoll seems completely unnecessary since you immediately turn around and change it into a matrix. Just use D3DXMatrixRotationYawPitchRoll as you did in the mouse event. Quaternions are used in cameras because they're a convenient way to accumulate rotations happening in eye coordinates. Since you're only using two axes of rotation in a strict order, your way of accumulating angles should be fine. The vector transformation of (0,0,1) isn't really necessary either. The oRotationMatrix should already have those values in the (_31,_32,_33) entries.
Update
Given that it's not roll, here's the problem: you create a rotation matrix to move the eye in world coordinates, but you want the pitch to happen in camera coordinates. Since roll isn't allowed and yaw is performed last, yaw is always the same in both the world and camera frames of reference. Consider the images below:
Your code works fine for local pitch and yaw because those are accomplished in camera coordinates.
But when you rotate around a reference point, you are creating a rotation matrix that is in world coordinates and using that to rotate the camera center. This works okay if the camera's coordinate system happens to line up with the world's. However, if you don't check to see if you're up against the pitch limit before you rotate the camera position, you will get crazy behavior when you hit that limit. The camera will suddenly start to skate around the world--still 'rotating' around the reference point, but no longer changing orientation.
If the camera's axes don't line up with the world's, strange things will happen. In the extreme case, the camera won't move at all because you're trying to make it roll.
The above is what would normally happen, but since you handle the camera orientation separately, the camera doesn't actually roll.
Instead, it stays upright, but you get strange translation going on.
One way to handle this would be to (1)always put the camera into a canonical position and orientation relative to the reference point, (2)make your rotation, and then (3)put it back when you're done (e.g., similar to the way that you translate the reference point to the origin, apply the Yaw-Pitch rotation, and then translate back). Thinking more about it, however, this probably isn't the best way to go.
Update 2
I think that Generic Human's answer is probably the best. The question remains as to how much pitch should be applied if the rotation is off-axis, but for now, we'll ignore that. Maybe it'll give you acceptable results.
The essence of the answer is this: Before mouse movement, your camera is at c1 = m_oEyePos and being oriented by M1 = D3DXMatrixRotationYawPitchRoll(&M_1,m_dRotationX,m_dRotationY,0). Consider the reference point a = m_oRotateAroundPos. From the point of view of the camera, this point is a'=M1(a-c1).
You want to change the orientation of the camera to M2 = D3DXMatrixRotationYawPitchRoll(&M_2,m_dRotationX+dX,m_dRotationY+dY,0). [Important: Since you won't allow m_dRotationY to fall outside of a specific range, you should make sure that dY doesn't violate that constraint.] As the camera changes orientation, you also want its position to rotate around a to a new point c2. This means that a won't change from the perspective of the camera. I.e., M1(a-c1)==M2(a-c2).
So we solve for c2 (remember that the transpose of a rotation matrix is the same as the inverse):
M2TM1(a-c1)==(a-c2) =>
-M2TM1(a-c1)+a==c2
Now if we look at this as a transformation being applied to c1, then we can see that it is first negated, then translated by a, then rotated by M1, then rotated by M2T, negated again, and then translated by a again. These are transformations that graphics libraries are good at and they can all be squished into a single transformation matrix.
#Generic Human deserves credit for the answer, but here's code for it. Of course, you need to implement the function to validate a change in pitch before it's applied, but that's simple. This code probably has a couple typos since I haven't tried to compile:
case ENavigation::eRotatePoint: {
const double dX = (double)(m_oLastMousePos.x - roMousePos.x) * dRotatePixelScale * D3DX_PI;
double dY = (double)(m_oLastMousePos.y - roMousePos.y) * dRotatePixelScale * D3DX_PI;
dY = validatePitch(dY); // dY needs to be kept within bounds so that m_dRotationY is within bounds
D3DXMATRIX oRotationMatrix1; // The camera orientation before mouse-change
D3DXMatrixRotationYawPitchRoll(&oRotationMatrix1, m_dRotationX, m_dRotationY, 0.0);
D3DXMATRIX oRotationMatrix2; // The camera orientation after mouse-change
D3DXMatrixRotationYawPitchRoll(&oRotationMatrix2, m_dRotationX + dX, m_dRotationY + dY, 0.0);
D3DXMATRIX oRotationMatrix2Inv; // The inverse of the orientation
D3DXMatrixTranspose(&oRotationMatrix2Inv,&oRotationMatrix2); // Transpose is the same in this case
D3DXMATRIX oScaleMatrix; // Negative scaling matrix for negating the translation
D3DXMatrixScaling(&oScaleMatrix,-1,-1,-1);
D3DXMATRIX oTranslationMatrix; // Translation by the reference point
D3DXMatrixTranslation(&oTranslationMatrix,
m_oRotateAroundPos.x,m_oRotateAroundPos.y,m_oRotateAroundPos.z);
D3DXMATRIX oTransformMatrix; // The full transform for the eyePos.
// We assume the matrix multiply protects against variable aliasing
D3DXMatrixMultiply(&oTransformMatrix,&oScaleMatrix,&oTranslationMatrix);
D3DXMatrixMultiply(&oTransformMatrix,&oTransformMatrix,&oRotationMatrix1);
D3DXMatrixMultiply(&oTransformMatrix,&oTransformMatrix,&oRotationMatrix2Inv);
D3DXMatrixMultiply(&oTransformMatrix,&oTransformMatrix,&oScaleMatrix);
D3DXMatrixMultiply(&oTransformMatrix,&oTransformMatrix,&oTranslationMatrix);
D3DXVECTOR4 oEyeFinal;
D3DXVec3Transform(&oEyeFinal, &m_oEyePos, &oTransformMatrix);
m_oEyePos = D3DXVECTOR3(oEyeFinal.x, oEyeFinal.y, oEyeFinal.z)
// Increment rotation to keep the same relative look angles
RotateXAxis(dX);
RotateYAxis(dY);
break;
}
I think there is a much simpler solution that lets you sidestep all rotation issues.
Notation: A is the point we want to rotate around, C is the original camera location, M is the original camera rotation matrix that maps global coordinates to the camera's local viewport.
Make a note of the local coordinates of A, which are equal to A' = M × (A - C).
Rotate the camera like you would in normal "eye rotation" mode. Update the view matrix M so that it is modified to M2 and C remains unchanged.
Now we would like to find C2 such that A' = M2 × (A - C2).
This is easily done by the equation C2 = A - M2-1 × A'.
Voilà, the camera has been rotated and because the local coordinates of A are unchanged, A remains at the same location and the same scale and distance.
As an added bonus, the rotation behavior is now consistent between "eye rotation" and "point rotation" mode.
You rotate around the point by repeatedly applying small rotation matrices, this probably cause the drift (small precision errors add up) and I bet you will not really do a perfect circle after some time. Since the angles for the view use simple 1-dimension double, they have much less drift.
A possible fix would be to store a dedicated yaw/pitch and relative position from the point when you enter that view mode, and using those to do the math. This requires a bit more bookkeeping, since you need to update those when moving the camera. Note that it will also make the camera move if the point move, which I think is an improvement.
If I understand correctly, you are satisfied with the rotation component in the final matrix (save for inverted rotation controls in the problem #3), but not with the translation part, is that so?
The problem seems to come from the fact that you treating them differently: you are recalculating the rotation part from scratch every time, but accumulate the translation part (m_oEyePos). Other comments mention precision problems, but it's actually more significant than just FP precision: accumulating rotations from small yaw/pitch values is simply not the same---mathematically---as making one big rotation from the accumulated yaw/pitch. Hence the rotation/translation discrepancy. To fix this, try recalculating eye position from scratch simultaneously with the rotation part, similarly to how you find "oTarget = oEyePos + ...":
oEyePos = m_oRotateAroundPos - dist * D3DXVECTOR3(oForward4.x, oForward4.y, oForward4.z)
dist can be fixed or calculated from the old eye position. That will keep the rotation point in the screen center; in the more general case (which you are interested in), -dist * oForward here should be replaced by the old/initial m_oEyePos - m_oRotateAroundPos multiplied by the old/initial camera rotation to bring it to the camera space (finding a constant offset vector in camera's coordinate system), then multiplied by the inverted new camera rotation to get the new direction in the world.
This will, of course, be subject to gimbal lock when the pitch is straight up or down. You'll need to define precisely what behavior you expect in these cases to solve this part. On the other hand, locking at m_dRotationX=0 or =pi is rather strange (this is yaw, not pitch, right?) and might be related to the above.