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Related Concept Videos

Elasticity01:12

Elasticity

3.4K
Elasticity is the ability of an object to withstand the effects of distortion and to return to its original size and shape once the forces causing deformation are removed. When an elastic material deforms under the action of an external force, it experiences internal resistance to the deformation. However, if no external force is applied, it returns to its original state.
The elasticity of an object can be described by a stress-strain curve, which represents the relationship between stress...
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Elastic Potential Energy01:01

Elastic Potential Energy

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Elastic potential energy is the energy stored as a result of the deformation of an elastic object, such as the stretching of a spring. An object is elastic if it returns to its original shape and size after being deformed. 
Potential energy is also associated with the elastic force exerted by an ideal spring. The work done by this force can be represented as a change in the elastic potential energy of the spring. Thus, the work done by a perfectly elastic spring, in one dimension, depends...
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Elasticity in Concrete01:20

Elasticity in Concrete

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Upon subjecting concrete to moderate or high uniaxial compressive or tensile stresses, the strain response is non-linear relative to the stress applied. As the stress is removed, the resulting stress-strain curve deviates from the original path traced during loading, creating a hysteresis loop, indicative of the concrete's non-linear and non-elastic properties. Typically, a material's modulus of elasticity, which is a measure of the material's stiffness, is inferred from the linear...
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Elastic Curve from the Load Distribution01:16

Elastic Curve from the Load Distribution

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The structural behavior of beams under distributed loads is critical for engineering analysis, which focuses on predicting how beams bend and react under such conditions. Different types of beams (e.g., cantilever, supported, or overhanging) behave differently under distributed load conditions.
For all beams, the analysis of the beam's reaction to distributed loads begins by understanding the relationship between a beam's load and the resulting shear forces and bending moments.
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Members Made of Elastoplastic Material01:19

Members Made of Elastoplastic Material

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The behavior of elastoplastic materials under bending stresses, particularly in structural members with rectangular cross-sections, is crucial for predicting material responses and understanding failure modes. Initially, when a bending moment is applied, the stress distribution across the section follows Hooke's Law and is linear and elastic. This distribution means the stress increases from the neutral axis to the maximum at the outer fibers, up to the elastic limit.
As the bending moment...
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Elastic Collisions: Introduction01:00

Elastic Collisions: Introduction

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An elastic collision is one that conserves both internal kinetic energy and momentum. Internal kinetic energy is the sum of the kinetic energies of the objects in a system. Truly elastic collisions can only be achieved with subatomic particles, such as electrons striking nuclei. Macroscopic collisions can be very nearly, but not quite, elastic, as some kinetic energy is always converted into other forms of energy such as heat transfer due to friction and sound. An example of a nearly...
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Related Experiment Video

Updated: May 24, 2025

Quantification of Strain in a Porcine Model of Skin Expansion Using Multi-View Stereo and Isogeometric Kinematics
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Quantification of Strain in a Porcine Model of Skin Expansion Using Multi-View Stereo and Isogeometric Kinematics

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Squishicalization: Exploring Elastic Volume Physicalization.

Daniel Pahr, Michal Piovarci, Hsiang-Yun Wu

    IEEE Transactions on Visualization and Computer Graphics
    |March 3, 2025
    PubMed
    Summary
    This summary is machine-generated.

    Squishicalization transforms volumetric data into tactile sculptures by encoding scalar information into material elasticity. This novel pipeline enables direct physical interaction with complex data through 3D-printed, sponge-like structures.

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    Area of Science:

    • Data Visualization
    • Human-Computer Interaction
    • Material Science

    Background:

    • Data physicalization increasingly explores multisensory encoding for enhanced interactivity.
    • Leveraging the tactile dimension offers a unique pathway for direct data interaction.

    Purpose of the Study:

    • Introduce Squishicalization, a pipeline for generating physicalizations of volumetric data.
    • Encode scalar information into physical characteristics, specifically local elasticity or "squishiness".

    Main Methods:

    • Adapt volume rendering transfer functions to map scalar values to elasticity levels.
    • Utilize weighted sampling of scalar fields and Voronoi tessellation for structure generation.
    • Employ consumer-grade 3D printing with readily available filament for fabrication.

    Main Results:

    • Successfully generated physicalizations (squishicalizations) encoding scalar data through elasticity.
    • Validated the pipeline through computational, mechanical, and perceptual evaluations.
    • Identified potential application scenarios through expert interviews.

    Conclusions:

    • Squishicalization offers a novel method for tangible data representation and interaction.
    • The pipeline is accessible, utilizing standard 3D printing technology.
    • Future research can explore diverse applications and material properties for enhanced data physicalization.