Victor Bélanger-Garnier scite author profile

The ability to integrate multiple materials into miniaturized fiber structures enables the realization of novel biomedical textile devices with higher-level functionalities and minimally-invasive attributes. In this work, we present novel textile fabrics integrating unobtrusive multi-material fibers that communicate through 2.4 GHz wireless networks with excellent signal quality. The conductor elements of the textiles are embedded within the fibers themselves, providing electrical and chemical shielding against the environment, while preserving the mechanical and cosmetic properties of the garments. These multi-material fibers combine insulating and conducting materials into a well-defined geometry, and represent a cost-effective and minimally-invasive approach to sensor fabrics and bio-sensing textiles connected in real time to mobile communications infrastructures, suitable for a variety of health and life science applications.

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Virtual image determination for mirrored surfaces

Radel¹,

Bélanger-Garnier²,

Hegedüs³

2018

Opt. Express

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An object viewed via reflection from a mirrored surface is often perceived by the observer to be located behind the mirror's surface. The image of this object behind the mirror is known as its virtual image. Conventional methods for determining the location and shape of a virtual image for non-planar mirrors are complex and impractical unless both the observer and object are near the optical axis. We have developed a technique designed to be simple and practical for determining the location of a virtual image in a non-planar mirror far from the optical axis. Results using this technique were compared with known results from geometric optics for an object point on the optical axis of a parabola and for an object point imaged off the optical axis of a spherical mirror. These results were also in agreement with experimental measurements for a hemispherical mirror viewed at large angles with respect to its optical axis. This technique has applications for display devices or imaging tools utilizing curved, mirrored surfaces.

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Novel multi-material fibers for wireless communication textile devices

Bélanger-Garnier

Gorgutsa

Ung

et al. 2014

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Abstract-Miniaturized, multi-material fibers represent a novel promising approach to integration of higher-level functionalities into textile mediums. In this work, we present novel 'smart textile' fabrics featuring multi-material fiber antennas compatible with existing 2.4GHz wireless communication networks. A submillimeter leaky coaxial cable fiber antenna is shown to be fully compatible with a textile weaving process, and exhibits an isotropic radiation pattern in the H-plane and multiple radiation lobes in the E-plane, in accordance with theory and simulations.

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Novel Wearable RF Textile-Integrated Antennas Made from Multi-Material Fibers

Gorgutsa

Khalil

Bélanger-Garnier

et al. 2015

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