Development of a novel paediatric surgical assist robot for tissue manipulation in a narrow workspace

Liu, Quanquan; Shi, Chaoyang; Zhang, Bo; Duan, Li; Sun, Tongyang; Zhang, Xin; Li, Weiguang; Wu, Zhengzhi; Fujie, Masakatsu G.

doi:10.1108/aa-12-2016-162

Cited by 10 publications

(9 citation statements)

References 22 publications

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“…Several groups citing the Raven system have developed complete or nearly complete surgical robotic systems [6][7][8][9][10][11][12]. These systems often address new surgical procedures (such as pediatric cases or needle guidance) [6,9,10] novel delivery modes [8] or integration of industrial manipulators into surgery [12] Numerous groups have developed new hardware influenced by the Raven design [12][13][14][15][16][17][18][19][20][21][22] or focused on numerical optimization of mechansims [23]. Key aspects of these designs are minimally invasive character, often making a contribution such as novel mechanisms for decoupling motion at the laparoscopic entry port [13], decoupling drive axes [16], or reducing weight and size [19].…”

Section: Research Citing Raven But Not Using Ravenmentioning

confidence: 99%

The Raven Open Surgical Robotic Platforms: A Review and Prospect

2019

APH

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The Raven I and the Raven II surgical robots, as open research platforms, have been serving the robotic surgery research community for ten years. The paper 1) briefly presents the Raven I and the Raven II robots, 2) reviews the recent publications that are built upon the Raven robots, aim to be applied to the Raven robots, or are directly compared with the Raven robots, and 3) uses the Raven robots as a case study to discuss the popular research problems in the research community and the trend of robotic surgery study. Instead of being a thorough literature review, this work only reviews the works formally published in the past three years and uses these recent publications to analyze the research interests, the popular open research problems, and opportunities in the topic of robotic surgery.

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Section: Research Citing Raven But Not Using Ravenmentioning

confidence: 99%

The Raven Open Surgical Robotic Platforms: A Review and Prospect

2019

APH

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“…A novel reconfigurable tracked robot based on four-link mechanism was proposed in Luo’s paper (Luo et al , 2013), which is composed of one suspension and one pair of symmetrical deployed reconfigurable track modules. In addition, many tracked robots have been specially developed for fire-fighting and disaster relief (Yan et al , 2016; He et al ,2016; Yang et al , 2017; Yang et al , 2018b; Yoneda et al , 2001; Martin et al , 2017; Faisal et al , 2017; Wu et al ,2016; Frost et al , 2002; Murphy, 2004; Ji et al , 2015; Yu et al , 2018; Yu et al , 2016; Liu et al , 2017; Qu et al , 2018).…”

Section: Introductionmentioning

confidence: 99%

An angle-changeable tracked robot with human-robot interaction in unstructured environments

Zong

et al. 2020

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Purpose The purpose of this paper is to study the adaptability of the tracked robot in complex working environment. It proposes an angle-changeable tracked robot with human–robot interaction in unstructured environment. The study aims to present the mechanical structure and human–robot interaction control system of the tracked robot and analyze the static stability of the robot working in three terrains, i.e. rugged terrain, sloped terrain and stairs. Design/methodology/approach The paper presents the mechanical structure and human–robot interaction control system of the tracked robot. To prevent the detachment of the tracks during obstacle navigation, a new type of passively adaptive device based on the relationship between the track’s variable angle and the forces is presented. Then three types of rough terrain are chosen to analyze the static stability of the tracked robot, i.e. rugged terrain, sloped terrain and stairs. Findings This paper provides the design method of the tracked robot. Owing to its appropriate dimensions, good mass distribution and limited velocity, the tracked robot remains stable on the complex terrains. The experimental results verify the effectiveness of the design method. Originality/value The theoretical analysis of this paper provides basic reference for the structural design of tracked robots.

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“…In the early literature of human-robot shared control, a leader-follower model is usually adopted wherein the robot is assigned a follower's role (Hogan, 1985;Liu et al, 2017). This is mainly because most of current robots are still behind humans in the sense of intelligence.…”

Section: Introductionmentioning

confidence: 99%

Reinforcement learning for human-robot shared control

Tee

Yan

et al. 2019

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Purpose This paper aims to propose a general framework of shared control for human–robot interaction. Design/methodology/approach Human dynamics are considered in analysis of the coupled human–robot system. Motion intentions of both human and robot are taken into account in the control objective of the robot. Reinforcement learning is developed to achieve the control objective subject to unknown dynamics of human and robot. The closed-loop system performance is discussed through a rigorous proof. Findings Simulations are conducted to demonstrate the learning capability of the proposed method and its feasibility in handling various situations. Originality/value Compared to existing works, the proposed framework combines motion intentions of both human and robot in a human–robot shared control system, without the requirement of the knowledge of human’s and robot’s dynamics.

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Development of a novel paediatric surgical assist robot for tissue manipulation in a narrow workspace

Cited by 10 publications

References 22 publications

The Raven Open Surgical Robotic Platforms: A Review and Prospect

The Raven Open Surgical Robotic Platforms: A Review and Prospect

An angle-changeable tracked robot with human-robot interaction in unstructured environments

Reinforcement learning for human-robot shared control

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