The paper investigates methods to optimize the simulation of the BioTac tactile sensor, a commonly used sensor that enables robots to perceive and respond to physical tactile stimuli. The authors first revisit the work by Ruppel et al., which uses a neural network to predict the sensor outputs based on temperature, force, and contact point positions.
The authors identify two key areas for improvement:
The authors then implement three alternative approaches without using temperature as input:
The authors thoroughly investigate the impact of different input window sizes on the performance of these models. Their results show that the XGBoost regressor and transformer encoder outperform the feed-forward neural network, achieving statistically significant improvements in normalized mean absolute error (MAE) of up to 7.8% over the baseline.
The authors also analyze the limitations of the dataset, noting that it is unbalanced and only includes a single indenter type. They suggest that the non-linear dynamics of the sensor, caused by its non-radial symmetry and non-uniform fluid volume, also contribute to the errors.
As future work, the authors propose to extend the dataset to include different BioTac sensors, varied surrounding temperatures, and several indenter shapes to enhance the model's robustness and generalizability. They also suggest training an ensemble of transformer networks to better deal with the non-linear dynamics of the sensor.
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