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Implementation For RC Scale Car #41
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Hello mbrossar, I find this repository very interesting and thank you for making this open source. I tested this with the KITTI test dataset as guided in the page and I got perfectly same set of results as expected in this page. Great set of instructions!! Thanks Now I am trying to implement this real time for the turtle-bot which has GPS and IMU. when I had the glance at the code, it is not straight forward to implement with own data. As mentioned above in the post Please can you suggest where to begin with and some suggestions would be really grateful. Best Regards, |
Hello Sharish, I recognize that invariant Kalman theory is not straightforward. My best suggestion for reading are: A. Barrau and S. Bonnabel, “Invariant Kalman Filtering,” Annual Review of Control, Robotics, and Autonomous Systems, vol. 1, no. 1, pp. 237–257, 2018. A. Barrau and S. Bonnabel, “The Invariant Extended Kalman Filter as a Stable An example of well application is What you need to understand is that the error is NOT but defined in equations (22) to (25). I think the question you search to answer is: What is the Jacobian for GPS measurement ? To obtain it, I start by linearizing the error (22) for rotation and position (we do not need velocity here) Now, we write the residual of the measurement From (*), we have The Jacobian is thus for the part of as in a stantard Kalman filter, plus a new part of the Jacobian for orientation, i.e. Do you need more clarifications ? Best regards, Martin |
Hi Martin, Thank you very much for your response on my query. I will look into those papers for better understanding. Best Regards, |
Hi,
I can suggest you to start as simple as possible. If it is only a rosbag, you can manually correct for imu biaises and imu misalignment. You thus have only a filter with a state space of size 9. Then, without training anything, tune the filter parameters to obtain good initial guess. And then you can start training, adding biaises,...
Best regards,
Martin
Le 12 mars 2020 à 16:20, à 16:20, sharish33 <notifications@github.com> a écrit:
…Hi Martin,
Thank you very much for your response on my query. I will look into
those papers for better understanding.
May be I misleaded you with my question. I have a ros bag file recorded
from real time turtlebot having IMU data. Now I am planning to apply
this algorithm to my bag file and willing to get the results how the
algorithm behaves to my real data.Please can you give some suggestions
for where to start if I wanted to modify the code to work with my bag
file I have, to train the neural network and then test the algorithm
and to get the results as like with KITTI test data.
Best Regards,
Harish
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#41 (comment)
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Hi Martin, Thank you for your inputs. I am trying to implement the algorithm with real time imu data. I will let here posted with further results in my implementation. Thank you for your support !! Best Regards, |
Hi Martin, I started reading the code and understanding the algorithm. But with the existing algorithm I am bit lost to implement for real time IMU data set. please could you elaborate the steps mentioned above to implement for real time data, that would be great and helpful. Also please let know if you have tested the algorithm for real time data and this is feasible to implement. Best Regards, |
Hi Sagi, Could you be please describe precisely where you meet difficulties ? Is it for understanding the filter, implementing it in e.g. ros, ... ? All the best, Martin |
Hi Martin, Thanks for your replies. At least for me, the training of the neural network is the difficult part. It seems to rely on your dataset class derived from KITTI. However, I have a csv file where I have saved the data from a gps (for ground truth) and IMU. So the question is how should I format my data to work with train_torch_filter.py or make a compatible dataset.py? I think this may also be what Harish was asking. On another note, I am also not completely sure I understand the loss function. Could you explain it? Thanks again, |
Hi Martin, Thank you very much for your time, help and inputs here in the implementation.
When comes to neural network,
Your suggestions and inputs on these queries would be great and very much helpful. Also if created, Please could you share the github repository for real time implementation of algorithm, that would be really helpful and solve my other thousand questions. Best Regards, |
Hello. I recently read your paper and I am interested in implementing your dead reckoning algorithm on an RC car equipped with a raspberry pi, GPS, and IMU. I was wondering if you had any suggestions for where to start if I wanted to modify the code to work with data I record from the car to train the neural network and then test the algorithm in real time. From glancing through the code, my intuition is that I need to change the datasets.py class and it would be nearly plug and play, but I thought that I would get your insight first.
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