Pinching sweaters on your phone – iShoogle : multi-gesture touchscreen fabric simulator using natural on-fabric gestures to communicate textile qualities

The inability to touch fabrics online frustrates consumers, who are used to evaluating physical textiles by engaging in complex, natural gestural interactions. When customers interact with physical fabrics, they combine cross-modal information about the fabric's look, sound and handle to build an impression of its physical qualities. But whenever an interaction with a fabric is limited (i.e. when watching clothes online) there is a perceptual gap between the fabric qualities perceived digitally and the actual fabric qualities that a person would perceive when interacting with the physical fabric. The goal of this thesis was to create a fabric simulator that minimized this perceptual gap, enabling accurate perception of the qualities of fabrics presented digitally. We designed iShoogle, a multi-gesture touch-screen sound-enabled fabric simulator that aimed to create an accurate representation of fabric qualities without the need for touching the physical fabric swatch. iShoogle uses on-screen gestures (inspired by natural on-fabric movements e.g. Crunching) to control pre-recorded videos and audio of fabrics being deformed (e.g. being Crunched). iShoogle creates an illusion of direct video manipulation and also direct manipulation of the displayed fabric. This thesis describes the results of nine studies leading towards the development and evaluation of iShoogle. In the first three studies, we combined expert and non-expert textile-descriptive words and grouped them into eight dimensions labelled with terms Crisp, Hard, Soft, Textured, Flexible, Furry, Rough and Smooth. These terms were used to rate fabric qualities throughout the thesis. We observed natural on-fabric gestures during a fabric handling study (Study 4) and used the results to design iShoogle's on-screen gestures. In Study 5 we examined iShoogle's performance and speed in a fabric handling task and in Study 6 we investigated users' preferences for sound playback interactivity. iShoogle's accuracy was then evaluated in the last three studies by comparing participants’ ratings of textile qualities when using iShoogle with ratings produced when handling physical swatches. We also described the recording and processing techniques for the video and audio content that iShoogle used. Finally, we described the iShoogle iPhone app that was released to the general public. Our evaluation studies showed that iShoogle significantly improved the accuracy of fabric perception in at least some cases. Further research could investigate which fabric qualities and which fabrics are particularly suited to be represented with iShoogle

Applying nanotechnology in easy-to-clean hydrophofic fabrics and its use in automobiles

Upholstery cleaning is one of the main problems regarding the inner maintenance of a vehicle. Finding solutions to the usual brewery spots, grease stains, sausage marks and their smells is complicated due to both the nature of the dirt and the tedious undo of seats. At the forefront of the nowadays use of carbon fluoride based products, we present here the development of a hydrophobic and stain-resistance fabrics by using nanotechnology. Hydrophobic fabrics are water-resistant, self-cleaning and guarantee a long lasting protection against dirt. The addition of nanoparticles into upholstery fabrics result in surfaces which keep the superficial tension of water or dirt drops. Although this method drastically reduces liquid-fabric contacts and enhances the stain-resistance of the upholstery, intrinsic properties of the fabric fibers do not changePostprint (published version

Monte Carlo method applied to the mechanical dating of the Turin Shroud

Alternative dating methods to radiocarbon have been recently developed to study the Turin Shroud (TS), the linen sheet that according to the tradition enveloped the dead body of Jesus Christ; among them, a mechanical one is based on the study of five mechanical parameters in reference to the breaking strength, the Young modulus and the loss factor. This method tests single TS linen fibers using a machine, built in for the purpose, capable to measure the stress-stain parameters during loading cycles. These parameters have been already shown to be dependent on the age of the linen under test, and a preliminary result has been obtained: the TS date is 400 A.D. \ub1400 years at 95% confidence level. A companion paper has combined this mechanical result with two chemical ones, coming from Raman and FT-IR spectra, and the combined result is 90 AD \ub1200 years at 95% confidence level, thus confirming the compatibility of the age of the TS with the period in which Jesus Crist lived in Palestine. As the evaluation of the uncertainty propagation is not simple in the case of the mechanical parameters, this paper tries to furnish a more reliable result applying the Monte Carlo method to the mechanical parameters directly measured. The obtained mechanical age of the TS of 279 A.D. \ub1216 years at 95% confidence level is compatible with the previous results, but with an uncertainty almost halved

Literature Reviews on Modeling Internal Geometry of Textile Composites and Rate-Independent Continuum Damage

Textile composite materials have good potential for constructing composite structures where the effects of three-dimensional stresses are critical or geometric complexity is a manufacturing concern. There is a recent interest in advancing competence within Langley Research Center for modeling the degradation of mechanical properties of textile composites. In an initial effort, two critical areas are identified to pursue: (1) Construction of internal geometry of textile composites, and (2) Rate-independent continuum damage mechanics. This report documents reviews on the two subjects. Various reviewed approaches are categorized, their assumptions, methods, and progress are briefed, and then critiques are presented. Each review ends with recommended research

Pebbles Is a Girl That Doesn\u27t Know Anything

I am not quite sure how to be a woman. It’s complicated, contradictory and highly surveilled. I make videos, sculptures and wearable objects that attempt to rationalize my female identity. The body is a sustained fixture in my work: as an armature, as an absent actor for constructed environments, as fragment and as the literal inclusion of my image. It is through these various modes of dis/embodiment that I negotiate the complexities of gendered existence. Crumbling ceramic and paper objects, pieced fabric forms, videos, beauty products, and delicate flowers reference splintered narratives and unwieldy terrains. I consider the idea of pink, not exclusively as color but as a framework for the perpetual performance of the body and the negotiation of contradictions within constructed identity

Dichroism in helicoidal crystals

Accounting for the interactions of light with heterogeneous, anisotropic, absorbing, optically active media is part of the characterization of complex, transparent materials. Stained biological structures in thin tissue sections share many of these features, but systematic optical analyses beyond the employ of the simple petrographic microscopes have not be established. Here, this accounting is made for polycrystalline, spherulitic bundles of twisted d-mannitol lamellae grown from melts containing light-absorbing molecules. It has long been known that a significant percentage of molecular crystals readily grow as helicoidal ribbons with mesoscale pitches, but a general appreciation of the commonality of these non-classical crystal forms has been lost. Helicoidal crystal twisting was typically assayed by analyzing refractivity modulation in the petrographic microscope. However, by growing twisted crystals from melts in the presence of dissolved, light-absorbing molecules, crystal twisting can be assayed by analyzing the dichroism, both linear and circular. The term "helicoidal dichroism" is used here to describe the optical consequences of anisotropic absorbers precessing around radii of twisted crystalline fibrils or lamellae. d-Mannitol twists in two polymorphic forms, α and δ. The two polymorphs, when grown from supercooled melts in the presence of a variety of histochemical stains and textile dyes, are strongly dichroic in linearly polarized white light. The bis-azo dye Chicago sky blue is modeled because it is most absorbing when parallel and perpendicular to the radial axes in the respective spherulitic polymorphs. Optical properties were measured using Mueller matrix imaging polarimetry and simulated by taking into account the microstructure of the lamellae. The optical analysis of the dyed, patterned polycrystals clarifies aspects of the mesostructure that can be difficult to extract from bundles of tightly packed fibrils

Durability of Wearable Antennas Based on Nonwoven Conductive Fabrics: Experimental Study on Resistance to Washing and Ironing

Adhesive nonwoven conductive fabrics are appealing materials for fabricating fully textile antennas for wearable wireless systems. Wearable antennas should be flexible, lightweight, and mechanically resistant. Additionally, the antenna performance should be robust to activities related to daily use of garments, such as washing and ironing. Accordingly, in this work, the results of several washing tests performed on fully textile antennas fabricated by exploiting three different adhesive nonwoven conductive fabrics are reported