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EventEMin

License: CC BY-NC-SA 4.0

Code for the following papers:

The authors provide this code in the hope it will be useful for understanding the proposed method, as well as for reproducibility of the results.

For more information and more open-source software please visit the Personal Robotic Lab's website: https://www.imperial.ac.uk/personal-robotics/.

Requirements

This code was tested on Ubuntu 16.04, 18.04 and 20.04 distros.

Dependencies

sudo apt install cmake cmake-curses-gui
git clone https://gitlab.com/libeigen/eigen.git
cd eigen
mkdir build && cd build
cmake ..
sudo make install

or

sudo apt install libeigen3-dev

This repo was originally developed using Eigen 3.3.7. Currently, there are some compilation issues between Eigen 3.4.0 and the AutoDiff module. So, you should compile this repo with at most Eigen 3.3.9.

git clone https://github.com/ampl/gsl.git
cd gsl
./configure
sudo make install
sudo apt install libomp-dev

General

git clone https://github.com/ImperialCollegeLondon/EventEMin.git
cd EventEMin
mkdir build && cd build
cmake .. <cmake arguments>

The cmake arguments can be set as follows:

-DEventEMin_BATCH_MODE=ON/OFF
                            Build batch mode.
                            (default: OFF)
-DEventEMin_INCREMENTAL_MODE=ON/OFF
                            Build incremental mode.
                            (default: OFF)
-DEventEMin_FAST_EXP=ON/OFF
                            Use fast exponentiation.
                            (default: ON)
-DEventEMin_USE_OPENMP=ON/OFF
                            Uses the OpenMP library for parallelization.
                            (default: ON)

Lastly, ensure all environment path variables are well set, and compile everything:

make

ROS

A ROS package for real-time incremental estimation can be found on the following repository: https://github.com/ImperialCollegeLondon/event_emin_ros.

Datasets

We provide samples in the dataset folder, corresponding to some results obtained in the paper. Most of the examples provided work with these samples, so you are not required to download any dataset.

Examples

The source files are located in the test directory and the binary files will be located in the bin directory. We provide estimation examples per model, and the dispersion measure to be used can be chosen on the corresponding source file. Please note that the exact entropy-based measures have quadratic complexity with the number of events and the respective examples are expected to take longer (especially if you do not use OpenMP).

Batch Mode

For each example, two images should be seen, corresponding to the original events and the transformed events, according to the estimated parameters, accumulated on the image plane. The status of the optimisation procedure should be displayed in the following format:

iteration, restart iteration: score, gradient magnitude
gradient
parameters

In the end, the estimated parameters are also displayed.

2D Translation Estimation

To run the example, on a terminal type:

./example_translation2d

Rotation Estimation

To run the example, on a terminal type:

./example_rotation

Motion Estimation in Planar Scenes

To run the example, on a terminal type:

./example_homography

6-DOF in 3D

To run the example, on a terminal type:

./example_6dof

Incremental Mode

For each example, two images should be seen, corresponding to the original events and the transformed events, according to the estimated parameters, accumulated on the image plane. The timestamp and corresponding estimates should be displayed in the following format:

ts: timestamp, v: motion parameter estimates

In the end, the estimated parameters are also displayed.

2D Translation Estimation

To run the example, on a terminal type:

./example_incremental_translation2d

Rotation Estimation

To run the example, on a terminal type:

./example_incremental_rotation

6-DOF in 3D

To run the example, on a terminal type:

./example_incremental_6dof

Test Sequences

To run the sequences test, you need to download at least one sequence of the dataset provided in http://rpg.ifi.uzh.ch/davis_data.html.

Batch Mode

2D

To run the test, on a terminal type:

./example_test_sequence <path-to-events-dir> <batch-size> <path-to-estimates-saving-dir> <estimates-file-name>

The executable arguments are as follows:

  • path-to-events-dir: Path to the events' directory, following the format proposed in http://rpg.ifi.uzh.ch/davis_data.html, e.g. /poster_rotation. The events' directory must contain two files, namely, events.txt (list of events) and calib.txt (camera parameters). Please check the folders under dataset for examples.
  • batch-size: Number of events of each batch, e.g. 20000.
  • path-to-estimates-saving-dir: Path to where the estimates are to be stored, e.g. /poster_rotation/estimates.
  • estimates-file-name: File name of the estimates, e.g. approx_tsallis_2.

For example, if you downloaded the poster_rotation sequence and stored it under foo directory, by running

./example_test_sequence /foo/poster_rotation 20000 /foo/poster_rotation/estimates approx_tsallis_2

a file containig the estimates using the Approx. Tsallis measure should be created under the /foo/poster_rotation/estimates directory (/estimates directory should be created before running the command).

3D

To run the test, on a terminal type:

./example_test_sequence_3d <path-to-events-dir> <batch-size> <minimum-depth> <maximum-depth> <path-to-estimates-saving-dir> <estimates-file-name>

The additional executable arguments are as follows:

  • minimum-depth: Minimum depth of the depth-augmented events.
  • maximum-depth: Maximum depth of the depth-augmented events.

The rest of the arguments are the same as previously. The events should already be undistorted and augmented with depth. See indoor_flying1 for an example.

Incremental Mode

2D

To run the test, on a terminal type:

./example_incremental_test_sequence <path-to-events-dir> <number-events> <path-to-estimates-saving-dir> <estimates-file-name>

The executable arguments are as follows:

  • path-to-events-dir: Path to the events' directory, following the format proposed in http://rpg.ifi.uzh.ch/davis_data.html, e.g. /poster_rotation. The events' directory must contain two files, namely, events.txt (list of events) and calib.txt (camera parameters). Please check the folders under dataset for examples.
  • number-events: Number of the most recent events to maintain, e.g. 10000.
  • path-to-estimates-saving-dir: Path to where the estimates are to be stored, e.g. /poster_rotation/estimates.
  • estimates-file-name: File name of the estimates, e.g. incremental_potential.

For example, if you downloaded the poster_rotation sequence and stored it under foo directory, by running

./example_incremental_test_sequence /foo/poster_rotation 10000 /foo/poster_rotation/estimates incremental_potential

a file containig the estimates using the Incremental Potential measure should be created under the /foo/poster_rotation/estimates directory (/estimates directory should be created before running the command).

3D

To run the test, on a terminal type:

./example_incremental_test_sequence_3d <path-to-events-dir> <number-events> <minimum-depth> <depth-scale> <path-to-estimates-saving-dir> <estimates-file-name>

The additional executable arguments are as follows:

  • minimum-depth: Minimum depth of the depth-augmented events.
  • depth-scale: Depth scaling factor.

The rest of the arguments are the same as previously. The events should already be undistorted and augmented with depth. See indoor_flying1 for an example.

Compute Errors

To compute the errors for rotational motion estimation, run the MATLAB script sequence_error.m.

License

The EventEMin code is licensed under CC BY-NC-SA 4.0. Commercial usage is not permitted.