A soft pneumatic bistable reinforced actuator bioinspired by Venus Flytrap with enhanced grasping capability

Wang, Xing; Khara, Aarjav; Chen, Chao

doi:10.1088/1748-3190/aba091

Cited by 54 publications

(30 citation statements)

References 35 publications

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“…The manipulator helps perform the path planning together with the end-effector. Our end-effector adopted the design principle of the soft robotic grippers that have been explored significantly for robotic grasping application recently [ 45 , 46 ]. The proposed end-effector combines the compliant mechanism and the safe contact as a result of the fin-ray design and low elastic modulus material m4601, respectively.…”

Section: Methodsmentioning

confidence: 99%

Real-Time Fruit Recognition and Grasping Estimation for Robotic Apple Harvesting

Kang

Zhou

Wang

et al. 2020

Sensors

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135

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Robotic harvesting shows a promising aspect in future development of agricultural industry. However, there are many challenges which are still presented in the development of a fully functional robotic harvesting system. Vision is one of the most important keys among these challenges. Traditional vision methods always suffer from defects in accuracy, robustness, and efficiency in real implementation environments. In this work, a fully deep learning-based vision method for autonomous apple harvesting is developed and evaluated. The developed method includes a light-weight one-stage detection and segmentation network for fruit recognition and a PointNet to process the point clouds and estimate a proper approach pose for each fruit before grasping. Fruit recognition network takes raw inputs from RGB-D camera and performs fruit detection and instance segmentation on RGB images. The PointNet grasping network combines depth information and results from the fruit recognition as input and outputs the approach pose of each fruit for robotic arm execution. The developed vision method is evaluated on RGB-D image data which are collected from both laboratory and orchard environments. Robotic harvesting experiments in both indoor and outdoor conditions are also included to validate the performance of the developed harvesting system. Experimental results show that the developed vision method can perform highly efficient and accurate to guide robotic harvesting. Overall, the developed robotic harvesting system achieves 0.8 on harvesting success rate and cycle time is 6.5 s.

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Section: Methodsmentioning

confidence: 99%

Real-Time Fruit Recognition and Grasping Estimation for Robotic Apple Harvesting

Kang

Zhou

Wang

et al. 2020

Sensors

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135

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“…Amongst other systems, these were driven by photo-thermally produced heat (Dong et al, 2020;Lim et al, 2017) or via joule heating (Kim et al, 2014;Lim et al, 2017) (Figure 6b). Furthermore, AVFT systems exist, in which the "trap" closure movements are actuated via magnetism (Esser et al, 2019;Schmied et al, 2017;Zhang et al, 2016) (Figure 6c), electricity (Shahinpoor, 2011;Shahinpoor and Thompson, 1995), pressurized air (Esser et al, 2019;Pal et al, 2020;Temirel et al, 2016;Wang et al, 2020) (Figure 6d), temperature changes (Esser et al, 2019;Riley et al, 2020) (Figure 6b), or hydrogel swelling or shrinking activated via enzymes (Athas et al, 2016) or moisture (Esser et al,. 2019;Fan et al, 2019;Lee et al, 2010;Zhu et al, 2020) (Figure 6e).…”

Section: Fourth Example: the Venus Flytrap As Concept Generator For Plant-inspired Soft Robots (Avft: Artificial Venus Flytrap)mentioning

confidence: 99%

Bio-inspired life-like motile materials systems: Changing the boundaries between living and technical systems in the Anthropocene

Speck

Poppinga

Speck

et al. 2021

The Anthropocene Review

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A current trend observed in the Anthropocene is the search for bioinspired solutions. Since it became possible to change the quality of the boundary between living and technical systems, more and more life-like technical products have been developed in recent years. Using five plant-inspired developments of motile technical systems for architecture and soft-robotics, we show how the boundary between living and technical systems undulates, shifts, perforates, blurs, or dissolves with increasing life-likeness. We discuss what causes theses changes in the boundary and how this contributes to the overall aim to achieve higher resilience, robustness, and improved esthetics of plant-inspired products. Inspiration from living systems that make efficient and economic use of materials and energy and are fully recyclable after “service time” may additionally contribute to sustainable material use, one of the major challenges in the Anthropocene.

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“…Leaf thinning or leaf removal through manual or mechanical means has been a common practice in modern viticulture to increase ventilation and sunlight exposure and thus improve fruit quality and production (Zhuang et al 2014;Bogicevic 2015). Researchers have explored mechanical approaches to clear leaves temporarily for fruit extraction (Lee and Rosa 2006), However, As the soft robotic gripper becomes signi cantly popular for autonomous grasping application (Crooks et al 2016;Wang et al 2020), Zhou in (Kang et al 2020a) developed an adaptive gripper that can reach through the canopy through the canopy and pushing away the leaves around the target fruit without damaging the canopy structure.…”

Section: Fruit and Leaf Thinningmentioning

confidence: 99%

Intelligent Robots for Fruit Harvesting: Recent Developments and Future Challenges

Zhou

Wang

et al. 2021

Preprint

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Intelligent robots for fruit harvesting have been actively developed over the past decades to bridge the increasing gap between feeding a rapidly growing population and limited labour resources. Despite significant advancements in this field, widespread use of harvesting robots in orchards is yet to be seen. To identify the challenges and formulate future research and development directions, this work reviews the state-of-the-art of intelligent fruit harvesting robots by comparing their system architectures, visual perception approaches, fruit detachment methods and system performances. The potential reasons behind the inadequate performance of existing harvesting robots are analysed and a novel map of challenges and potential research directions is created, considering both environmental factors and user requirements.

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A soft pneumatic bistable reinforced actuator bioinspired by Venus Flytrap with enhanced grasping capability

Cited by 54 publications

References 35 publications

Real-Time Fruit Recognition and Grasping Estimation for Robotic Apple Harvesting

Real-Time Fruit Recognition and Grasping Estimation for Robotic Apple Harvesting

Bio-inspired life-like motile materials systems: Changing the boundaries between living and technical systems in the Anthropocene

Intelligent Robots for Fruit Harvesting: Recent Developments and Future Challenges

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