Constrained DMPs for Feasible Skill Learning on Humanoid Robots

Duan, Anqing; Camoriano, Raffaello; Ferigo, Diego; Calandriello, Daniele; Rosasco, Lorenzo; Pucci, Daniele

doi:10.1109/humanoids.2018.8624934

Cited by 13 publications

(14 citation statements)

References 20 publications

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“…More widely applicable results could be obtained by further investigating these aspects. Also, to make robots safely operate in uncluttered environments, it can be considered to incorporate obstacle and joint limit avoidance [19]. Another interesting extension would be to learn the activation function profile π in response to the surrounding environment.…”

Section: Discussionmentioning

confidence: 99%

“…We need to transform Cartesian trajectories into joint space in order to control the robot. To do so, the Jacobian-based inverse kinematics techniqueẋ = J(q)q is employed, where J ∈ R 3×d is the robot Jacobian matrix [19]. In general, the corresponding discrete implementation incorporating nullspace exploration is given by…”

Section: B Transformation From Cartesian Space To Joint Spacementioning

confidence: 99%

See 1 more Smart Citation

Learning to Sequence Multiple Tasks with Competing Constraints

Duan

Camoriano

Ferigo

et al. 2019

2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Imitation learning offers a general framework where robots can efficiently acquire novel motor skills from demonstrations of a human teacher. While many promising achievements have been shown, the majority of them are only focused on single-stroke movements, without taking into account the problem of multi-tasks sequencing. Conceivably, sequencing different atomic tasks can further augment the robot's capabilities as well as avoid repetitive demonstrations. In this paper, we propose to address the issue of multi-tasks sequencing with emphasis on handling the so-called competing constraints, which emerge due to the existence of the concurrent constraints from Cartesian and joint trajectories. Specifically, we explore the null space of the robot from an informationtheoretic perspective in order to maintain imitation fidelity during transition between consecutive tasks. The effectiveness of the proposed method is validated through simulated and real experiments on the iCub humanoid robot.

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Section: Discussionmentioning

confidence: 99%

Section: B Transformation From Cartesian Space To Joint Spacementioning

confidence: 99%

Learning to Sequence Multiple Tasks with Competing Constraints

Duan

Camoriano

Ferigo

et al. 2019

2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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“…In view of high complexity of the multi-input multi-output system in addition to several constraints that could emerge, such as control bounds, joint limits, kinematic constraints etc., we consider to formulate our control problem from an optimization perspective. Compared with analytic control law design, optimization-based control strategies exhibit great potential for customization towards different requirements [24] and better at explicitly handling constraints [25]. Specifically, our control method akin to a feedback linearization method is composed of two loops similar to [20].…”

Section: Controller Designmentioning

confidence: 99%

Ultrasound-Guided Assistive Robots for Scoliosis Assessment with Optimization-based Control and Variable Impedance

Duan¹,

Victorova²,

Zhao³

et al. 2022

Preprint

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Assistive robots for healthcare have seen a growing demand due to the great potential of relieving medical practitioners from routine jobs. In this paper, we investigate the development of an optimization-based control framework for an ultrasound-guided assistive robot to perform scoliosis assessment. A conventional procedure for scoliosis assessment with ultrasound imaging typically requires a medical practitioner to slide an ultrasound probe along a patient's back. To automate this type of procedure, we need to consider multiple objectives, such as contact force, position, orientation, energy, posture, etc. To address the aforementioned components, we propose to formulate the control framework design as a quadratic programming problem with each objective weighed by its task priority subject to a set of equality and inequality constraints. In addition, as the robot needs to establish constant contact with the patient during spine scanning, we incorporate variable impedance regulation of the end-effector position and orientation in the control architecture to enhance safety and stability during the physical humanrobot interaction. Wherein, the variable impedance gains are retrieved by learning from the medical expert's demonstrations. The proposed methodology is evaluated by conducting real-world experiments of autonomous scoliosis assessment with a robot manipulator xArm. The effectiveness is verified by the obtained coronal spinal images of both a phantom and a human subject.

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“…Moreover, given that trajectories will be modified by the potential field unpredictably during obstacle avoidance, there are possibilities that joint trajectory evolution could exceed the allowable range. To address this issue, we employ Constrained Dynamic Movement Primitives (CDMPs), recently developed by Duan et al ( 2018 ) so as to ensure joint trajectories are always bounded within the specified range.…”

Section: Proposed Approachmentioning

confidence: 99%

“…It can be conceived that the modified trajectories are very susceptible to the strength of the potential field and a strong field could drive joint trajectories out of the allowable range. To cope with such issue, we will drive the robot's trajectories using our recently developed Constrained Dynamic Movement Primitives (CDMPs) (Duan et al, 2018 ). CDMPs are derived by parameterizing the original trajectory using the hyperbolic tangent function

.…”

Section: Proposed Approachmentioning

confidence: 99%

Learning to Avoid Obstacles With Minimal Intervention Control

et al. 2020

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Programming by demonstration has received much attention as it offers a general framework which allows robots to efficiently acquire novel motor skills from a human teacher. While traditional imitation learning that only focuses on either Cartesian or joint space might become inappropriate in situations where both spaces are equally important (e.g., writing or striking task), hybrid imitation learning of skills in both Cartesian and joint spaces simultaneously has been studied recently. However, an important issue which often arises in dynamical or unstructured environments is overlooked, namely how can a robot avoid obstacles? In this paper, we aim to address the problem of avoiding obstacles in the context of hybrid imitation learning. Specifically, we propose to tackle three subproblems: (i) designing a proper potential field so as to bypass obstacles, (ii) guaranteeing joint limits are respected when adjusting trajectories in the process of avoiding obstacles, and (iii) determining proper control commands for robots such that potential human-robot interaction is safe. By solving the aforementioned subproblems, the robot is capable of generalizing observed skills to new situations featuring obstacles in a feasible and safe manner. The effectiveness of the proposed method is validated through a toy example as well as a real transportation experiment on the iCub humanoid robot.

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Constrained DMPs for Feasible Skill Learning on Humanoid Robots

Cited by 13 publications

References 20 publications

Learning to Sequence Multiple Tasks with Competing Constraints

Learning to Sequence Multiple Tasks with Competing Constraints

Ultrasound-Guided Assistive Robots for Scoliosis Assessment with Optimization-based Control and Variable Impedance

Learning to Avoid Obstacles With Minimal Intervention Control

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