It is well known that rotation matrix can be represented by quaternion. This page explains how to calculate the quaternions when the rotation matrix is given.
Quaternion q=(q0,q1,q2,q3) where |q|=1
Quaternion to rotation matrix.
Rotation matrix to quaternion. rij=aij
is rotation matrix. 
Therefore,
By solving this,
Now let's calculate the sign. q and -q represent same rotation, thus,
Other sign will be as follows.
Another choice is to do as follows.
or
or
Source code: Convert rotation matrix to quaternion.
inline float
SIGN(float
x) {return
(x >= 0.0f) ? +1.0f : -1.0f;}
inline float
NORM(float
a, float
b, float
c, float
d) {return
sqrt(a * a + b * b + c * c + d * d);}
q0 = ( r11 + r22 + r33 + 1.0f) / 4.0f;
q1 = ( r11 - r22 - r33 + 1.0f) / 4.0f;
q2 = (-r11 + r22 - r33 + 1.0f) / 4.0f;
q3 = (-r11 - r22 + r33 + 1.0f) / 4.0f;
if(q0 <
0.0f) q0 = 0.0f;
if(q1 <
0.0f) q1 = 0.0f;
if(q2 <
0.0f) q2 = 0.0f;
if(q3 <
0.0f) q3 = 0.0f;
q0 = sqrt(q0);
q1 = sqrt(q1);
q2 = sqrt(q2);
q3 = sqrt(q3);
if(q0
>= q1 && q0 >= q2 && q0 >= q3) {
q0 *= +1.0f;
q1 *= SIGN(r32 - r23);
q2 *= SIGN(r13 - r31);
q3 *= SIGN(r21 - r12);
} else if(q1 >= q0
&& q1 >= q2 && q1 >= q3) {
q0 *= SIGN(r32 - r23);
q1 *= +1.0f;
q2 *= SIGN(r21 + r12);
q3 *= SIGN(r13 + r31);
} else if(q2 >= q0
&& q2 >= q1 && q2 >= q3) {
q0 *= SIGN(r13 - r31);
q1 *= SIGN(r21 + r12);
q2 *= +1.0f;
q3 *= SIGN(r32 + r23);
} else if(q3 >= q0
&& q3 >= q1 && q3 >= q2) {
q0 *= SIGN(r21 - r12);
q1 *= SIGN(r31 + r13);
q2 *= SIGN(r32 + r23);
q3 *= +1.0f;
} else {
printf("coding
error\n");
}
r = NORM(q0, q1, q2, q3);
q0 /= r;
q1 /= r;
q2 /= r;
q3 /= r;