Optimization of Spring Constant of a Pneumatic Artificial Muscle-Spring Driven Antagonistic Structure

Zhou, Zhongchao; Kokubu, Shota; Wang, Yuanyuan; Lu, Yuxi; Tortos, Pablo; Yu, Wenwei

doi:10.1109/lra.2022.3162021

Cited by 5 publications

(3 citation statements)

References 26 publications

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“…Soft robots, characterized by low stiffness, lightweight, infinite degrees of freedom, and the ability to withstand high-energy impacts, possess many superior comprehensive performance features, such as good safety, high flexibility, and applicability in various scenarios [2]. So far, soft robots have become a research hotspot in the field of robotics and have been widely applied in areas such as biomimetic robots [3]- [8], healthcare [9]- [11], and industry [12]- [15], among other [16]- [21]. In recent years, scholars both domestically and internationally have conducted extensive research on various soft robots.…”

Section: Introductionmentioning

confidence: 99%

Multi-Structure Parameter Optimization Analysis of Soft Actuator Based on Numerical Calculation

Songtao,

Yimeng,

Shiyu

et al. 2024

IEEE Access

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To optimize the performance of the soft actuator, numerical experiments and regression analysis of the multi-structure parameter are presented based on the numerical calculation method. Firstly, numerical experiments and regression analysis were performed on the parameters of different driving channel shapes, including equilateral triangle, square, regular pentagon, regular hexagon, and circle, to determine the driving performance under different channel cross-sections. Secondly, numerical experiments and regression analysis were conducted on the parameters of fiber winding diameter and winding angle of the soft actuator, and qualitative analysis was performed on the failure states of the numerical calculations. Lastly, numerical experiments and regression analysis were carried out on the parameters of wall thickness and driving channel length of the soft actuator to determine the influence of these parameters on the driving performance. Through the numerical experiments and regression analysis, this study provides a necessary theoretical foundation for the optimization design of soft actuator, effectively improving the development efficiency and dynamic performance of soft actuators.

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Section: Introductionmentioning

confidence: 99%

Multi-Structure Parameter Optimization Analysis of Soft Actuator Based on Numerical Calculation

Songtao,

Yimeng,

Shiyu

et al. 2024

IEEE Access

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“…As an application of the ImbalSim2Real scheme, we focus on the finger joint stiffness sensing problem, taken as a prime imbalanced sim2real problem in the soft robot-assisted rehabilitation scenario. Soft Frontiers in Bioengineering and Biotechnology frontiersin.org actuators have been applied in various healthcare fields, such as rehabilitation (Wang et al, 2021), surgery (Lu et al, 2023), and assistance (Zhou et al, 2022). In particular, Heung et al analyzed the relationship between finger joint stiffness, soft actuator's angle, and air pressure, and hence developed an accurate analytic angle-pressurefinger joint stiffness model (Heung et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Addressing data imbalance in Sim2Real: ImbalSim2Real scheme and its application in finger joint stiffness self-sensing for soft robot-assisted rehabilitation

Zhou,

Lu,

Tortós

et al. 2024

Front. Bioeng. Biotechnol.

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The simulation-to-reality (sim2real) problem is a common issue when deploying simulation-trained models to real-world scenarios, especially given the extremely high imbalance between simulation and real-world data (scarce real-world data). Although the cycle-consistent generative adversarial network (CycleGAN) has demonstrated promise in addressing some sim2real issues, it encounters limitations in situations of data imbalance due to the lower capacity of the discriminator and the indeterminacy of learned sim2real mapping. To overcome such problems, we proposed the imbalanced Sim2Real scheme (ImbalSim2Real). Differing from CycleGAN, the ImbalSim2Real scheme segments the dataset into paired and unpaired data for two-fold training. The unpaired data incorporated discriminator-enhanced samples to further squash the solution space of the discriminator, for enhancing the discriminator’s ability. For paired data, a term targeted regression loss was integrated to ensure specific and quantitative mapping and further minimize the solution space of the generator. The ImbalSim2Real scheme was validated through numerical experiments, demonstrating its superiority over conventional sim2real methods. In addition, as an application of the proposed ImbalSim2Real scheme, we designed a finger joint stiffness self-sensing framework, where the validation loss for estimating real-world finger joint stiffness was reduced by roughly 41% compared to the supervised learning method that was trained with scarce real-world data and by 56% relative to the CycleGAN trained with the imbalanced dataset. Our proposed scheme and framework have potential applicability to bio-signal estimation when facing an imbalanced sim2real problem.

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“…Soft actuators can self-adjust their stiffness and are ideal for dealing with unstructured environments or interacting with humans because their softness allows them to deform around their surroundings. Soft actuators are also commonly employed in different fields, such as rehabilitation [ 8 , 9 , 10 , 11 , 12 , 13 ] and MIS instruments [ 14 , 15 ]. In numerous applications, a pneumatic soft actuator is expected to have a small size, low hardness, large bidirectional bending angle and low stiffness, hence, minimizing the damage of surgical instruments to the surrounding tissues.…”

Section: Introductionmentioning

confidence: 99%

Neural Network-Based Active Load-Sensing Scheme and Stiffness Adjustment for Pneumatic Soft Actuators for Minimally Invasive Surgery Support

Zhou

Kokubu

et al. 2023

Sensors

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To provide a stable surgical view in Minimally Invasive Surgery (MIS), it is necessary for a flexible endoscope applied in MIS to have adjustable stiffness to resist different external loads from surrounding organs and tissues. Pneumatic soft actuators are expected to fulfill this role, since they could feed the endoscope with an internal access channel and adjust their stiffness via an antagonistic mechanism. For that purpose, it is essential to estimate the external load. In this study, we proposed a neural network (NN)-based active load-sensing scheme and stiffness adjustment for a soft actuator for MIS support with antagonistic chambers for three degrees of freedom (DoFs) of control. To deal with the influence of the nonlinearity of the soft actuating system and uncertainty of the interaction between the soft actuator and its environment, an environment exploration strategy was studied for improving the robustness of sensing. Moreover, a NN-based inverse dynamics model for controlling the stiffness of the soft actuator with different flexible endoscopes was proposed too. The results showed that the exploration strategy with different sequence lengths improved the estimation accuracy of external loads in different conditions. The proposed method for external load exploration and inverse dynamics model could be used for in-depth studies of stiffness control of soft actuators for MIS support.

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Optimization of Spring Constant of a Pneumatic Artificial Muscle-Spring Driven Antagonistic Structure

Cited by 5 publications

References 26 publications

Multi-Structure Parameter Optimization Analysis of Soft Actuator Based on Numerical Calculation

Multi-Structure Parameter Optimization Analysis of Soft Actuator Based on Numerical Calculation

Addressing data imbalance in Sim2Real: ImbalSim2Real scheme and its application in finger joint stiffness self-sensing for soft robot-assisted rehabilitation

Neural Network-Based Active Load-Sensing Scheme and Stiffness Adjustment for Pneumatic Soft Actuators for Minimally Invasive Surgery Support

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