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My research team is struggling the GMM part in your paper, "Factor Graph based 3D Multi-Object Tracking in Point Clouds".
I believe the $w_j$ is the weights from GMM based on measurements.
Here is my question.
There are 5 lidar measurements, the number of $w_j$ is 5. When the number of components for the GMM is equal to the number of measurements, the $w_j$ will be uniform.
In addition to that, the information matrix representing the detector's accuracy but it is fixed.
If then, $c_j$ must be even.
In addition to that, if $c_j$ is even, the upper error term in the detection factor is going to be always zero because $c_j$ is equal to $r_m$.
I would like to understand this part, so could you help with this?
Sincerely,
Hojun Son
The text was updated successfully, but these errors were encountered:
Hi Tim.
My research team is struggling the GMM part in your paper, "Factor Graph based 3D Multi-Object Tracking in Point Clouds".
I believe the$w_j$ is the weights from GMM based on measurements.$w_j$ is 5. When the number of components for the GMM is equal to the number of measurements, the $w_j$ will be uniform.$c_j$ must be even.
Here is my question.
There are 5 lidar measurements, the number of
In addition to that, the information matrix representing the detector's accuracy but it is fixed.
If then,
In addition to that, if$c_j$ is even, the upper error term in the detection factor is going to be always zero because $c_j$ is equal to $r_m$ .
I would like to understand this part, so could you help with this?
Sincerely,
Hojun Son
The text was updated successfully, but these errors were encountered: