Incremental Machine Learning for Soft Pneumatic Actuators with Symmetrical Chambers

Kozhubaev, Yuriy; Ovchinnikova, Elena; Viacheslav, Ivanov; Krotova, Svetlana

doi:10.3390/sym15061206

Cited by 2 publications

(2 citation statements)

References 34 publications

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“…(4) The gas drive system has high flexibility and responsiveness and can quickly adjust and control the flow, pressure, and direction of the gas, so as to achieve precise motion control. This makes the gas drive perform well in applications that require a fast and precise response [28,29].…”

Section: Introductionmentioning

confidence: 99%

Symmetrical Modeling of Physical Properties of Flexible Structure of Silicone Materials for Control of Pneumatic Soft Actuators

Muratbakeev,

Kozhubaev,

Yiming

et al. 2024

Symmetry

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With the ongoing advancements in material technology, the domain of soft robotics has garnered increasing attention. Soft robots, in contrast to their rigid counterparts, offer superior adaptability to the environment, enhanced flexibility, and improved safety, rendering them highly suitable for complex application scenarios such as rescue operations and medical interventions. In this paper, a new type of pneumatic software actuator is proposed. The actuator adopts a combination of a soft structure and pneumatic control, which is highly flexible and versatile. By using the flow of gas inside the soft structure, high-precision and flexible motion control is realized. In the design process, the extensibility and adaptability of the structure are considered, so that the actuator can adapt to different working environments and task requirements. The experimental results show that the pneumatic soft actuator exhibits excellent performance in terms of accuracy, response speed, and controllability. This research provides new ideas and methods for the development of the field of pneumatic actuators and has wide application prospects. The main research content of this paper is as follows: first, the soft pneumatic actuator is modeled and simulated, the structure is optimized on the basis of simulation, and finally, the performance of the actuator is tested.

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Section: Introductionmentioning

confidence: 99%

Symmetrical Modeling of Physical Properties of Flexible Structure of Silicone Materials for Control of Pneumatic Soft Actuators

Muratbakeev,

Kozhubaev,

Yiming

et al. 2024

Symmetry

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“…It is a technique that is able to improve the speed of the adaptation under the Sparse Mechanism Assumption, which can have significant implications for real-world applications. For example, when a robot undergoes a change in a sensor or actuator [9], such a technique would improve how quickly it can accurately predict future observations again. It can also help in a biological context by improving the predictability of gene expressions in new pathways, where the Sparse Mechanism Shift assumption has shown to be useful for disentangling biological processes [10].…”

Section: Introductionmentioning

confidence: 99%

Causal Factor Disentanglement for Few-Shot Domain Adaptation in Video Prediction

Cornille,

Laenen,

Sun

et al. 2023

Entropy

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An important challenge in machine learning is performing with accuracy when few training samples are available from the target distribution. If a large number of training samples from a related distribution are available, transfer learning can be used to improve the performance. This paper investigates how to do transfer learning more effectively if the source and target distributions are related through a Sparse Mechanism Shift for the application of next-frame prediction. We create Sparse Mechanism Shift-TempoRal Intervened Sequences (SMS-TRIS), a benchmark to evaluate transfer learning for next-frame prediction derived from the TRIS datasets. We then propose to exploit the Sparse Mechanism Shift property of the distribution shift by disentangling the model parameters with regard to the true causal mechanisms underlying the data. We use the Causal Identifiability from TempoRal Intervened Sequences (CITRIS) model to achieve this disentanglement via causal representation learning. We show that encouraging disentanglement with the CITRIS extensions can improve performance, but their effectiveness varies depending on the dataset and backbone used. We find that it is effective only when encouraging disentanglement actually succeeds in increasing disentanglement. We also show that an alternative method designed for domain adaptation does not help, indicating the challenging nature of the SMS-TRIS benchmark.

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Incremental Machine Learning for Soft Pneumatic Actuators with Symmetrical Chambers

Cited by 2 publications

References 34 publications

Symmetrical Modeling of Physical Properties of Flexible Structure of Silicone Materials for Control of Pneumatic Soft Actuators

Symmetrical Modeling of Physical Properties of Flexible Structure of Silicone Materials for Control of Pneumatic Soft Actuators

Causal Factor Disentanglement for Few-Shot Domain Adaptation in Video Prediction

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