An untethered miniature origami robot that self-folds, walks, swims, and degrades

Miyashita, Shuhei; Guitron, Steven; Ludersdorfer, Marvin; Sung, Cynthia; Rus, Daniela

doi:10.1109/icra.2015.7139386

Cited by 202 publications

(122 citation statements)

References 33 publications

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“…where n is the number of coils, R I i ∈ SO(3) and B i (p i ) ∈ R 3 represents the rotation matrix describing the orientation of the i th coil with respect to the inertial frame, Ψ I and the flux density in its associated local coordinates p [22]. The overall (global) magnetic flux density can be determined by the superposition of the contribution of the i th electromagnet as [21] B(p…”

Section: B Magnetic Control Inputmentioning

confidence: 99%

A robust controller for micro-sized agents: The prescribed performance approach

Denasi

Misra

2016

2016 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS)

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Abstract-Applications such as micromanipulation and minimally invasive surgery can be performed using micro-sized agents. For instance, drug-loaded magnetic micro-/nano-particles can enable targeted drug delivery. Their precise manipulation can be assured using a robust motion controller. In this paper, we design a closed-loop controller-observer pair for regulating the position of microagents. The prescribed performance technique is applied to control the microagents to follow desired motion trajectories. The position of the microagents are obtained using microscopic images and image processing. The velocities of the microagents are obtained using an iterative learning observer. The algorithm is tested experimentally on spherical magnetic microparticles that have an average diameter of 100 µm. The steady-state errors obtained by the algorithm are 20 µm. The errors converge to the steady-state in approximately 8 seconds.

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Section: B Magnetic Control Inputmentioning

confidence: 99%

A robust controller for micro-sized agents: The prescribed performance approach

Denasi

Misra

2016

2016 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS)

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“…Our previous work [1] has demonstrated a mobile origami robot that self-folds, is remotely controllable, and can be dissolved to be recycled. In this paper we design and control a new origami robot that can be swallowed and sent through the esophagus to the stomach (Fig.…”

Section: Introductionmentioning

confidence: 99%

Ingestible, controllable, and degradable origami robot for patching stomach wounds

Miyashita¹,

Guitron²,

Yoshida

et al. 2016

2016 IEEE International Conference on Robotics and Automation (ICRA)

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144

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Abstract-Developing miniature robots that can carry out versatile clinical procedures inside the body under the remote instructions of medical professionals has been a long time challenge. In this paper, we present origami-based robots that can be ingested into the stomach, locomote to a desired location, patch a wound, remove a foreign body, deliver drugs, and biodegrade. We designed and fabricated composite material sheets for a biocompatible and biodegradable robot that can be encapsulated in ice for delivery through the esophagus, embed a drug layer that is passively released to a wounded area, and be remotely controlled to carry out underwater maneuvers specific to the tasks using magnetic fields. The performances of the robots are demonstrated in a simulated physical environment consisting of an esophagus and stomach with properties similar to the biological organs.

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“…The microrobots made from stimuli-responsive materials can move, walk, or swim. These functions are especially useful in biomedical applications [16][17][18][19][20][21][22]. Magnetostrictive and multiferroic materials take a special place among the stimuli-responsive materials, because they couple magnetic, elastic, and electronic properties of the materials.…”

Section: Introduction To Origami and Micro-origamimentioning

confidence: 99%

Magnetic Micro-Origami

Małkiński¹,

Eskandari²

2016

Magnetic Materials

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Microscopic origami figures can be created from thin film patterns using surface tension of liquids or residual stresses in thin films. The curvature of the structures, direction of bending, twisting, and folding of the patterns can be controlled by their shape, thickness, and elastic properties and by the strength of the residual stresses. Magnetic materials used for micro-and nano-origami structures play an essential role in many applications. Magnetic force due to applied magnetic field can be used for remote actuation of microrobots. It can also be used in targeted drug delivery to direct cages loaded with drugs or microswimmers to transport drugs to specific organs. Magnetoelastic properties of free-standing micro-origami patterns can serve for stress or magnetic field sensing. Also, the stress-induced anisotropy and magnetic shape anisotropy provide a convenient method of tuning magnetic properties by designing a shape of the microorigami figures instead of varying the composition of the films. Micro-origami figures can also serve as building blocks for two-and three-dimensional meta-materials with unique properties such as negative index of refraction. Micro-origami techniques provide a powerful method of self-assembly of magnetic circuits and integrating them with microelectro-mechanical systems or other functional devices.

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An untethered miniature origami robot that self-folds, walks, swims, and degrades

Cited by 202 publications

References 33 publications

A robust controller for micro-sized agents: The prescribed performance approach

A robust controller for micro-sized agents: The prescribed performance approach

Ingestible, controllable, and degradable origami robot for patching stomach wounds

Magnetic Micro-Origami

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