Smartphone CanSat for Actualization of Real-time Streaming Video Calls Using Remote Screen Touch System with Shape Memory Alloy Actuator

Oh, Hyun-Ung; Kim, Hyein; Kim, Jeong-Ki; Choi, Jae-Seop; Kim, Su-Hyeon

doi:10.2322/tjsass.62.256

Cited by 5 publications

(3 citation statements)

References 16 publications

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“…As practice shows, this indirect and not always accessible way of solving problems (the transition from macroscale to microscale robotics and the introduction of non-standard interpretations despite the inconsistency with the high-budget mainstream) can help in obtaining non-standard results using spacecraft, as was the case decades ago [44][45][46]. A fibrillar manipulator cannot replace a macromanipulator, but for nanosatellites and picosatellites (such as "CanSat"), sets of cooperative fibrillar manipulators with the electron beam control may be the only possible means of achieving efficiency in many mechanical applications including pulsed one-time manipulations (such as opening a mirror or a solar battery) [47][48][49][50][51][52][53][54][55][56][57].…”

Section: Discussionmentioning

confidence: 99%

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics For Vacuum Conditions

Градов¹,

Gradova²,

Kholuiskaya³

et al. 2022

Preprint

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<p>The possibility of creating vacuum robotics based on the polymer structures irradiated by an electron beam, in particular, polymer fibers, which provide high functional flexibility and a variety of states, is discussed. The possibility of using polymer fibers as different types of MEMS-like electromechanical elements is demonstrated - from elastic cantilevers to springs that change their state under the electron beam. Experimentally proved the presence of different functional types of fibers, correlating with their thickness, as well as the phenomenon of the fiber break. A number of exotic forms of dynamics have been demonstrated and a method for their detection has been developed using 2D Fourier spectra, integral spatial characteristics, time rsolved correlograms and wavelet transforms (visualized as the scaleograms / scalograms). Access barcodes for the full video records of the corresponding experiments are provided.</p>

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Section: Discussionmentioning

confidence: 99%

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics For Vacuum Conditions

Градов¹,

Gradova²,

Kholuiskaya³

et al. 2022

Preprint

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“…Smart materials with shape memory properties are used in robotics to create self-deploying structures and adaptive robotic components [15]. Shape memory alloys can be integrated into consumer electronics, such as smartphones, to enable adaptable form factors or user interfaces [163]. Shape change materials can be employed in automotive applications, such as self-healing or adaptive panels [164,165].…”

Section: Shape Change Manipulation Using Laser Processingmentioning

confidence: 99%

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Murzin,

Stiglbrunner

2023

Applied Sciences

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Laser processing is a versatile tool that enhances smart materials for diverse industries, allowing precise changes in material properties and customization of surface characteristics. It drives the development of smart materials with adaptive properties through laser modification, utilizing photothermal reactions and functional additives for meticulous control. These laser-processed smart materials form the foundation of 4D printing that enables dynamic shape changes depending on external influences, with significant potential in the aerospace, robotics, health care, electronics, and automotive sectors, thus fostering innovation. Laser processing also advances photonics and optoelectronics, facilitating precise control over optical properties and promoting responsive device development for various applications. The application of computer-generated diffractive optical elements (DOEs) enhances laser precision, allowing for predetermined temperature distribution and showcasing substantial promise in enhancing smart material properties. This comprehensive overview explores the applications of laser technology and nanotechnology involving DOEs, underscoring their transformative potential in the realms of photonics and optoelectronics. The growing potential for further research and practical applications in this field suggests promising prospects in the near future.

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Section: Fig 2 Example Of the Broken Polymer Fibermentioning

confidence: 99%

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics for Vacuum Conditions

Градов

2022

Materials Research Proceedings

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Abstract. The possibility of creating vacuum robotics based on the polymer structures irradiated by an electron beam, in particular, polymer fibers, which provide high functional flexibility and a variety of states, is discussed. The possibility of using polymer fibers as different types of MEMS-like electromechanical elements is demonstrated - from elastic cantilevers to springs that change their state under the electron beam. Experimentally proved the presence of different functional types of fibers, correlating with their thickness, as well as the phenomenon of the fiber break. A number of exotic forms of dynamics have been demonstrated and a method for their detection has been developed using 2D Fourier spectra, integral spatial characteristics, time resolved correlograms and wavelet transforms (visualized as the scaleograms / scalograms). Access barcodes for the full video records of the corresponding experiments are provided.

show abstract

Smartphone CanSat for Actualization of Real-time Streaming Video Calls Using Remote Screen Touch System with Shape Memory Alloy Actuator

Cited by 5 publications

References 16 publications

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics For Vacuum Conditions

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics For Vacuum Conditions

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Towards Electron-Beam-Driven Soft / Polymer Fiber Microrobotics for Vacuum Conditions

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