Robust Immersive Bilateral Teleoperation of Dissimilar Systems with Enhanced Transparency and Sense of Embodiment

In human-in-the-loop systems such as teleoperation, especially those involving heavy-duty manipulators, achieving high task performance requires both robust control and strong human engagement. This paper presents a bilateral teleoperation framework that enhances the operator's Sense of Embodiment (SoE), specifically, the senses of agency and self-location, through an immersive virtual reality interface and distributed haptic feedback via an exoskeleton. To support this embodiment and stablish high level of motion and force transparency, we develop a force-sensorless, robust control architecture that tackles input nonlinearities, master-slave asymmetries, unknown uncertainties, and arbitrary time delays. A human-robot augmented dynamic model is integrated into the control loop to enhance human-adaptability of the controller. Theoretical analysis confirms semi-global uniform ultimate boundedness of the closed-loop system. Extensive real-world experiments demonstrate high accuracy tracking under up to 1:13 motion scaling and 1:1000 force scaling, showcasing the significance of the results. Additionally, the stability-transparency tradeoff for motion tracking and force reflection-tracking is establish up to 150 ms of one-way fix and time-varying communication delay. The results of user study with 10 participants (9 male and 1 female) demonstrated that the system can imply a good level of SoE (76.4%), at the same time is very user friendly with no gender limitation. These results are significant given the scale and weight of the heavy-duty manipulators.

@article{hejrati2025_2505.14486,
  title={ Robust Immersive Bilateral Teleoperation of Dissimilar Systems with Enhanced Transparency and Sense of Embodiment },
  author={ Mahdi Hejrati and Jouni Mattila },
  journal={arXiv preprint arXiv:2505.14486},
  year={ 2025 }
}