I'm guessing you're working with matrices of the form

```
[ side_x up_x forward_x position_x ]
[ side_y up_y forward_y position_y ]
[ side_z up_z forward_z position_z ]
[ 0 0 0 1 ]
```

So to rotate around the local up vector `a`

radians, multiply the local transformation matrix by a rotation matrix that rotates around the Y-vector, i.e.

```
[ side_x up_x forward_x position_x ] [ cos(a) 0 -sin(a) 0 ]
[ side_y up_y forward_y position_y ] *= [ 0 1 0 0 ]
[ side_z up_z forward_z position_z ] [ sin(a) 0 cos(a) 0 ]
[ 0 0 0 1 ] [ 0 0 0 1 ]
```

Let me know how that turns out.

# BIG EDIT

Here's some more information.

### Definition (Frame)

A *frame* F is a collection of four homogeneous coordinates x_F, y_F, z_F, o_F such that the fourth coordinates of x_F, y_F, z_F are zero and the fourth coordinate of o_F is one, and x_F, y_F, z_F are pairwise orthogonal (orthogonality is not *really* necessary, but I just define it like this here). o_F is called the origin of the frame. A collection of vertices is said to be *relative to frame F* if their coordinates are expressed with respect to F.

### Example 1

A mesh made in Blender or Maya has its vertices expressed relative to the model's frame.

### Definition (Frame transformation matrix)

Given two frames F and G, a *frame transformation matrix* M is a 4x4 matrix M such that

- M * x_F = x_G
- M * y_F = y_G
- M * z_F = z_G
- M * o_F = o_G

Written differently, we can express this as M * [x_F, y_F, z_F, o_F] = [x_G, y_G, z_G, o_G], where [ ... ] means the matrix spanned by the columns respectively. Again written differently, and assuming invertibility is of no concern, we may write

```
M = [x_G y_G z_G o_G] * [x_F y_F z_F o_F]^{-1}
```

### Example 2

Suppose we need to transform from world space to view (or eye) space. We assume that world space coordinates are just the standard basis vectors, and we assume that our camera in view space is centered at o_V with some rotation applied to it such that we get the vectors x_V, y_V and z_V. Then M is simply equal to

```
M = [x_V y_V z_V o_V] * I^{-1} = [x_V y_V z_V o_V]
```

### Example 3

Suppose now that we have a batch over vertices from a model and the vertices' coordinates are expressed in model space. The model is located somewhere in world space with some orientation. The model thus has an origin o_M and some rotation x_M, y_m, z_M. The matrix that transforms the vertices from model space to world space is then equal to

```
M = I * [x_M y_M z_M o_M]^{-1} = [x_M y_M z_M o_M]^{-1}
```

Observe that one must be aware that the matrix must be inverted.

### Example 4

Suppose now that we want to go directly from model space to view space. This is now easy, since we already deduced the matrices for model -> world and world -> view. Hence

```
M = [x_V y_V z_V o_V] * [x_M y_M z_M o_M]^{-1}
```

### Who cares?

A frame is a useful tool to implement the effects that you want. Suppose the objects in our world all have a `position`

, a `forward`

and an `up`

vector. Our camera through which we look at is also an object in the world. Hence it also has a `position`

, a `forward`

and an `up`

vector. A first version of a `Frame`

class could be

```
struct Frame { // version 1
vec3 position;
vec3 forward;
vec3 up;
};
```

However we'd like to make our `Frame`

do useful things. So we could add member functions.

```
struct Frame { // version 2
vec3 position;
vec3 forward;
vec3 up;
mat4 getLocalToWorldTransform() const;
mat4 getWorldToLocalTransform() const;
}
```

The `mat4 Frame::getWorldToLocalTransform() const`

member functions could look something like this:

```
mat4 Frame::getWorldToLocalTransform() const {
vec3 side = crossProduct(forward, up);
// [x_F y_F z_F o_F ] (!!)
return mat4(side, up, -forward, position); // +forward or -forward depending on the graphics API
}
```

If you notice though there could be a problem. Who guarantees that `up`

and `forward`

are always orthogonal? You'll have to take care of that yourself. For example, you could force yourself to only rotate the `forward`

direction around the `up`

vector so that they always remain orthogonal.
I'll leave the implementation details of `mat4 Frame::getLocalToWorldTransform() const`

to you.

Now we'd like our `Frame`

to be able to move about in the world. We could add more member functions

```
struct Frame { // version 3
vec3 position;
vec3 forward;
vec3 up;
mat4 getLocalToWorldTransform() const;
mat4 getWorldToLocalTransform() const;
void moveForward(const float steps);
void moveBackward(const float steps);
void rotateClockwiseAroundUp(const float radians);
void rotateCounterClockwiseAroundUp(const float radians);
}
```

The implementation of `void Frame::rotateCounterClockwiseAroundUp(const float radians)`

could look something like this:

```
void Frame::rotateCounterClockwiseAroundUp(const float radians) {
direction = mat3::rotationFromAngleAndAxis(radians, up) * direction;
}
```

So, your camera should maintain its own `Frame`

class. To rotate the camera, use the member functions `rotateCounterClockwiseAroundUp`

and `rotateClockwiseAroundUp`

. To move the camera backwards and forwards, use the member functions `moveForward`

and `moveBackward`

. To get the transformation matrix, use the member function `getWorldToLocalTransform`

, because we need to go from world -> view space.

`_13`

represent? I dunno and guessing as to what is meant is a waste of time. Please consider clarifying your question. I think that is also what @Yakk was subtly trying to elude to. – Adrian Jun 14 '13 at 2:06