Abstract
Sensory feedback is essential for the control of soft robotic systems and to enable deployment in a variety of different tasks. Proprioception refers to sensing the robot’s own state and is of crucial importance in order to deploy soft robotic systems outside of laboratory environments, i.e. where no external sensing, such as motion capture systems, is available. A vision-based sensing approach for a soft robotic arm made from fabric is presented, leveraging the high-resolution sensory feedback provided by cameras. No mechanical interaction between the sensor and the soft structure is required and consequently the compliance of the soft system is preserved. The integration of a camera into an inflatable, fabric-based bellow actuator is discussed. Three actuators, each featuring an integrated camera, are used to control the spherical robotic arm and simultaneously provide sensory feedback of the two rotational degrees of freedom. A convolutional neural network architecture predicts the two angles describing the robot’s orientation from the camera images. Ground truth data is provided by a motion capture system during the training phase of the supervised learning approach and its evaluation thereafter. The camera-based sensing approach is able to provide estimates of the orientation in real-time with an accuracy of about one degree. The reliability of the sensing approach is demonstrated by using the sensory feedback to control the orientation of the robotic arm in closed-loop.
Highlights
Soft robots show promise to overcome challenges encountered with rigid robots due to the versatility resulting from the soft materials employed (Polygerinos et al, 2017)
While camera-based sensing approaches have been demonstrated for a soft plush robot, soft fingers and a compliant link, we demonstrate a vision-based sensing approach for a fabric-based bellow actuator used in a soft robotic arm
The results indicate that the actual tracking errors achievable with the visionbased sensing approach, are slightly higher compared to the case when relying on ground truth sensory feedback
Summary
Soft robots show promise to overcome challenges encountered with rigid robots due to the versatility resulting from the soft materials employed (Polygerinos et al, 2017). Their intrinsic mechanical properties are beneficial in terms of safety, allowing for close human-robot collaboration (Abidi and Cianchetti, 2017). The potential benefits of soft robots come with several challenges, such as the complex dynamics that are difficult to model and limit the application of open-loop control (Rus and Tolley, 2015). Vision-based approaches relying on internal cameras to observe the deformation of soft materials are promising because the sensor provides a high resolution and is not required to mechanically interact with the soft material that is observed
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