String Actuated Curved Folded Surfaces

Kilian, Martin; Monszpart, Áron; Mitra, Niloy J.

doi:10.1145/3072959.3015460

Cited by 30 publications

(18 citation statements)

References 43 publications

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“…Although allowing concave components will increase the designing and folding labor, the labor might be alleviated if we can actuate a foldable model mechanically [KMM17]. Although allowing concave components will increase the designing and folding labor, the labor might be alleviated if we can actuate a foldable model mechanically [KMM17].…”

Section: Discussionmentioning

confidence: 99%

Semi‐Automatic Conversion of 3D Shape into Flat‐Foldable Polygonal Model

Miyamoto

Endo

Kanamori

et al. 2017

Computer Graphics Forum

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This paper presents a method that can convert a given 3D mesh into a flat-foldable model consisting of rigid panels. A previous work proposed a method to assist manual design of a single component of such flat-foldable model, consisting of verticallyconnected side panels as well as horizontal top and bottom panels. Our method semi-automatically generates a more complicated model that approximates the input mesh with multiple convex components. The user specifies the folding direction of each convex component and the fidelity of shape approximation. Given the user inputs, our method optimizes shapes and positions of panels of each convex component in order to make the whole model flat-foldable. The user can check a folding animation of the output model. We demonstrate the effectiveness of our method by fabricating physical paper prototypes of flat-foldable models.

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Section: Discussionmentioning

confidence: 99%

Semi‐Automatic Conversion of 3D Shape into Flat‐Foldable Polygonal Model

Miyamoto

Endo

Kanamori

et al. 2017

Computer Graphics Forum

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“…Taking time into account as an additional dimension, the process of printing structures that can transform in a pre‐programmed way in response to a stimulus is called 4D printing [Tib14]. Several recent works in computer graphics investigated the design of surfaces fabricated with pre‐stretched elastic materials that deploy into complex, 3D shapes [GMB17, POT17, KMM17]. Other methods optimize shapes to offer a pre‐defined elastic [CLMK17] or dynamic behaviour [UKSI14, BWBSH14].…”

Section: Methodsmentioning

confidence: 99%

“…Addressing this problem, Killian et al . [KMM17] introduced string‐actuated, curved folded surfaces that can be shaped by pulling a network of strings. The concept of foldable strips has been extended by Takezawa et al .…”

Section: Shapesmentioning

confidence: 99%

State of the Art on Stylized Fabrication

Bickel

Cignoni

Malomo

et al. 2018

Computer Graphics Forum

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Digital fabrication devices are powerful tools for creating tangible reproductions of 3D digital models. Most available printing technologies aim at producing an accurate copy of a tridimensional shape. However, fabrication technologies can also be used to create a stylistic representation of a digital shape. We refer to this class of methods as ‘stylized fabrication methods’. These methods abstract geometric and physical features of a given shape to create an unconventional representation, to produce an optical illusion or to devise a particular interaction with the fabricated model. In this state‐of‐the‐art report, we classify and overview this broad and emerging class of approaches and also propose possible directions for future research.

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“…The design of a curved folded surface is manual and time consuming and is usually done using an empirical trial and error approach [Demaine et al 2011a,c]. The known theory on curved folds is conned to a narrow set of folds, and contrary to classical origami, bending and folding instructions are hard to write down and multiple creases must be folded simultaneously [Kilian et al 2017]. Artists generally pre-crease the paper using a ball burnisher or a CNC plotter before carefully folding and bending, making the process of shape exploration even slower.…”

Section: Introductionmentioning

confidence: 99%

“…Although manual and slow, playing with paper is still the predominant approach for curved folded surface design. Existing works on modeling such surfaces are either limited to previously discovered surfaces [Kilian et al 2008[Kilian et al , 2017 or model a small, partial set of folded surfaces generated by re ections or rotational sweeps [Mitani 2009;Mitani and Igarashi 2011]. Modeling the folding process of novel forms remains a challenge [Demaine et al 2011c].…”

Section: Introductionmentioning

confidence: 99%

Modeling curved folding with freeform deformations

Rabinovich

Hoffmann²,

Sorkine‐Hornung

2019

ACM Trans. Graph.

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We present a computational framework for interactive design and exploration of curved folded surfaces. In current practice, such surfaces are typically created manually using physical paper, and hence our objective is to lay the foundations for the digitalization of curved folded surface design. Our main contribution is a discrete binary characterization for folds between discrete developable surfaces, accompanied by an algorithm to simultaneously fold creases and smoothly bend planar sheets. We complement our algorithm with essential building blocks for curved folding deformations: objectives to control dihedral angles and mountain-valley assignments. We apply our machinery to build the first interactive freeform editing tool capable of modeling bending and folding of complicated crease patterns.

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String Actuated Curved Folded Surfaces

Cited by 30 publications

References 43 publications

Semi‐Automatic Conversion of 3D Shape into Flat‐Foldable Polygonal Model

Semi‐Automatic Conversion of 3D Shape into Flat‐Foldable Polygonal Model

State of the Art on Stylized Fabrication

Modeling curved folding with freeform deformations

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