Prompt-Driven Visuomotor Grasping

We present a biologically inspired neural model for the robotic tasks of object identification, localization, and motor action regression. The model is designed for: 1) Enabling a robot to reach objects in a three-dimensional space as this is a required ability for many real-world robotic applications; 2) Addressing the influence of imbalances in the training data on possible biases in the model’s behavior; 3) Evaluating the model’s performance on the auxiliary tasks of object localization and identification. We examine the effect of training these auxiliary tasks, along with the main task of reaching for an object, to gain a better understanding of the model’s performance and observe possible synergetic effects of learning the three tasks simultaneously.

References

2022

Enhancing a Neurocognitive Shared Visuomotor Model for Object Identification, Localization, and Grasping With Learning From Auxiliary Tasks

Matthias Kerzel*, Fares Abawi*, Manfred Eppe, and 1 more author

IEEE Transactions on Cognitive and Developmental Systems, 2022

arXiv Bib HTML PDF Code

@article{kerzel2022enhancing,
  title = {Enhancing a Neurocognitive Shared Visuomotor Model for Object Identification, Localization, and Grasping With Learning From Auxiliary Tasks},
  author = {Kerzel*, Matthias and Abawi*, Fares and Eppe, Manfred and Wermter, Stefan},
  journal = {IEEE Transactions on Cognitive and Developmental Systems},
  volume = {14},
  number = {4},
  pages = {1331--1342},
  year = {2022},
  publisher = {IEEE},
  doi = {10.1109/TCDS.2020.3028460},
}

2020

Augmented Extended Train Robots [Dataset]

Fares Abawi

2020

Bib HTML

@misc{abawi2020augmented,
  title = {Augmented Extended Train Robots  [Dataset]},
  author = {Abawi, Fares},
  journal = {https://doi.org/10.34740/KAGGLE/DSV/1511904},
  year = {2020},
  doi = {10.34740/KAGGLE/DSV/1511904},
}