Online Trajectory Planning in Dynamic Environments for Surgical Task Automation

Osa, Takayuki; Sugita, Naohiko; Mitsuishi, Mamoru

doi:10.15607/rss.2014.x.011

Cited by 43 publications

(38 citation statements)

References 18 publications

(27 reference statements)

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“…The framework called ProMP models the distribution of the trajectories in the parameter space [10] while the method in [11] modeled the distribution of the demonstrated trajectories at each time step using Gaussian Processes. These studies showed that the demonstrated behaviors can be generalized to new situation by modeling the distribution of the demonstrated trajectories.…”

Section: Related Workmentioning

confidence: 99%

“…We assume that the demonstrations are available under various contexts s i . In this case, we can model the conditional distribution of the demonstrated trajectories given the context in order to generalize the demonstrated trajectories to new situations [11], [24], [25]. Here, we use Locally Weighted Regression (LWR) to model this distribution [26], [27].…”

Section: Modelling Demonstrated Trajectory Distributionsmentioning

confidence: 99%

“…In LfD methods, the distribution of the demonstrated trajectories is often modeled, and the learned distribution is leveraged for generalizing the demonstrated behaviors [10], [11]. Recent work on LfD showed that the variance of the demonstrated trajectories can be used to adaptively control the robot behaviors [12].…”

Section: Introductionmentioning

confidence: 99%

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A learning-based shared control architecture for interactive task execution

Abi-Farraj

Osa

Peters

et al. 2017

2017 IEEE International Conference on Robotics and Automation (ICRA)

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Abstract-Shared control is a key technology for various robotic applications in which a robotic system and a human operator are meant to collaborate efficiently. In order to achieve efficient task execution in shared control, it is essential to predict the desired behavior for a given situation or context to simplify the control task for the human operator. To do this prediction, we use Learning from Demonstration (LfD), which is a popular approach for transferring human skills to robots. We encode the demonstrated behavior as trajectory distributions and generalize the learned distributions to new situations. The goal of this paper is to present a shared control framework that uses learned expert distributions to gain more autonomy. Our approach controls the balance between the controller's autonomy and the human preference based on the distributions of the demonstrated trajectories. Moreover, the learned distributions are autonomously refined from collaborative task executions, resulting in a master-slave system with increasing autonomy that requires less user input with an increasing number of task executions. We experimentally validated that our shared control approach enables efficient task executions. Moreover, the conducted experiments demonstrated that the developed system improves its performances through interactive task executions with our shared control.

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Section: Related Workmentioning

confidence: 99%

Section: Modelling Demonstrated Trajectory Distributionsmentioning

confidence: 99%

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A learning-based shared control architecture for interactive task execution

Abi-Farraj

Osa

Peters

et al. 2017

2017 IEEE International Conference on Robotics and Automation (ICRA)

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“…Van den Berg et al [34] proposed an iterative technique to learn a reference trajectory and execute it at higher than demonstration speeds for suture knot tying. This work was recently extended by Osa et al [25] to deal with dynamic changes in the environment, but with an industrial manipulator. Mayer et al [20] use principles of fluid dynamics and Schulman et al [31] use non-rigid registration techniques to generalize human demonstrations to similar, yet previously unseen, initial conditions.…”

Section: Related Workmentioning

confidence: 99%

Learning by observation for surgical subtasks: Multilateral cutting of 3D viscoelastic and 2D Orthotropic Tissue Phantoms

Murali

Sen

Kehoe

et al. 2015

2015 IEEE International Conference on Robotics and Automation (ICRA)

161

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Abstract-Automating repetitive surgical subtasks such as suturing, cutting and debridement can reduce surgeon fatigue and procedure times and facilitate supervised tele-surgery. Programming is difficult because human tissue is deformable and highly specular. Using the da Vinci Research Kit (DVRK) robotic surgical assistant, we explore a "Learning By Observation" (LBO) approach where we identify, segment, and parameterize sub-trajectories ("surgemes") and sensor conditions to build a finite state machine (FSM) for each subtask. The robot then executes the FSM repeatedly to tune parameters and if necessary update the FSM structure. We evaluate the approach on two surgical subtasks: debridement of 3D Viscoelastic Tissue Phantoms (3d-DVTP), in which small target fragments are removed from a 3D viscoelastic tissue phantom, and Pattern Cutting of 2D Orthotropic Tissue Phantoms (2d-PCOTP), a step in the standard Fundamentals of Laparoscopic Surgery training suite, in which a specified circular area must be cut from a sheet of orthotropic tissue phantom. We describe the approach and physical experiments, which yielded a success rate of 96% for 50 trials of the 3d-DVTP subtask and 70% for 20 trials of the 2d-PCOTP subtask.

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“…These studies include complete automation of time-consuming and repetitive tasks [5], as well as collaborative surgery in which the control is shared back and forth between the operator and the robot [6]. Recent studies have looked into generalizing learned demonstrations to previously unseen initial conditions [7], as well as an adaptive trajectory planning to deal with dynamic changes in the environment [8]. In the field of endovascular intervention these learning-based techniques have been used for automation of motion trajectories from expert demonstrations for the same catheterization task, by a robotic driver, demonstrating potential improvements over manual catheterization [9].…”

Section: Introductionmentioning

confidence: 99%

A learning based training and skill assessment platform with haptic guidance for endovascular catheterization

Chi

Rafii-Tari

Liu

et al. 2017

2017 IEEE International Conference on Robotics and Automation (ICRA)

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Abstract-This paper improves a semi-automatic robotic catheterization platform based on previous works [9] by proposing a method to address subject variability. It incorporates anatomical information in the process of catheter trajectories optimization, hence can adapt to the scale and orientation differences among subjects. Statistical modeling is implemented to encode the catheter motions of both proximal and distal sites from demonstrations of one vascular model. Non-rigid registration is applied to find a warping function to map catheter tip trajectories onto other anatomically-similar but shape/scale/orientation different models. Such function can finally generate a robot trajectory to conduct a collaborative catheratization task. Experiments investigate the proposed method in different vascular phantoms. The success rate for semi-automatic cannulation is high, which suggest the method can be potentially applied to different endovascular tasks and vasculature. The proposed robotic approach also show significant improvements in the quality of catheterization over manual approach by achieving smoother and safer catheter paths and reducing contact forces. This work provides insights into catheter task planning and an improved design of handson, ergonomic catheter navigation robots.

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Online Trajectory Planning in Dynamic Environments for Surgical Task Automation

Cited by 43 publications

References 18 publications

A learning-based shared control architecture for interactive task execution

A learning-based shared control architecture for interactive task execution

Learning by observation for surgical subtasks: Multilateral cutting of 3D viscoelastic and 2D Orthotropic Tissue Phantoms

A learning based training and skill assessment platform with haptic guidance for endovascular catheterization

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