Consider the following minimal working example:

```
#include <iostream>
#include <math.h>
#include <eigen3/Eigen/Dense>
int main() {
// Set the rotation matrices that give an example of the problem
Eigen::Matrix3d rotation_matrix_1, rotation_matrix_2;
rotation_matrix_1 << 0.15240781108708346, -0.98618841818279246, -0.064840288106743013,
-0.98826031445019891, -0.1527775600229907, 0.00075368177315370682,
-0.0106494132438156, 0.063964216524108775, -0.99789536976680049;
rotation_matrix_2 << -0.12448670851248633, -0.98805453458380521, -0.090836645094957508,
-0.99167686914182451, 0.12086367053038971, 0.044372968742129482,
-0.03286406263376359, 0.095604444636749664, -0.99487674792051639;
// Convert to Euler angles
Eigen::Vector3d euler_angles_1 = rotation_matrix_1.eulerAngles(2, 1, 0)*180.0f/M_PI;
Eigen::Vector3d euler_angles_2 = rotation_matrix_2.eulerAngles(2, 1, 0)*180.0f/M_PI;
// Convert to quaternion
Eigen::Quaternion<double> quaternion_1(rotation_matrix_1);
Eigen::Quaternion<double> quaternion_2(rotation_matrix_2);
// Print out results
std::cout << "Euler angles 1:\nyaw = " << euler_angles_1[0] << "\npitch = " << euler_angles_1[1] << "\nroll = " << euler_angles_1[2] << std::endl;
std::cout << "Quaternion 1:\nw = " << quaternion_1.w() << "\nx = " << quaternion_1.x() << "\ny = " << quaternion_1.y() << "\nz = " << quaternion_1.z() << std::endl;
std::cout << std::endl;
std::cout << "Euler angles 2:\nyaw = " << euler_angles_2[0] << "\npitch = " << euler_angles_2[1] << "\nroll = " << euler_angles_2[2] << std::endl;
std::cout << "Quaternion 2:\nw = " << quaternion_2.w() << "\nx = " << quaternion_2.x() << "\ny = " << quaternion_2.y() << "\nz = " << quaternion_2.z() << std::endl;
}
```

Whose output is:

```
Euler angles 1:
yaw = 98.767
pitch = 179.39
roll = -3.66759
Quaternion 1:
w = 0.020826
x = 0.758795
y = -0.650521
z = -0.0248716
Euler angles 2:
yaw = 82.845
pitch = 178.117
roll = -5.48908
Quaternion 2:
w = -0.0193663
x = -0.661348
y = 0.748369
z = 0.0467608
```

Both rotations are nearly identical (as given by the Euler angles). The expected behavior is that `quaternion_2`

will have values with same sign as `quaternion_1`

, i.e. for the output to be:

```
Quaternion 2:
w = 0.0193663
x = 0.661348
y = -0.748369
z = -0.0467608
```

However, Eigen appears to "flip" the quaternion. I am aware that q and -q represent the same rotation - however, it is visually not appealing, and frankly annoying, that the quaternion would flip sign in each of its values. How can this be rectified for the general case (i.e. that the quaternion always preserves its "handedness", rather than flipping sign for certain rotations)?