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The purpose of this paper is to develop an illuminated polymeric optical fibre (POF) garment – the LUMI jacket – with accessibility and wearability improvements. This paper demonstrates how wearable technology can be seamlessly integrated into daily life.

An interdisciplinary approach involving design and technological techniques was adopted. Both garment design approaches and textile technologies were used to optimise the performance of a POF jacket. A group of tactile sensors was developed to create an easy-to-access interactive function. A POF fabric sample and garment were washed and examined to prove that a POF garment could be made part of a domestic laundry routine.

As a result, an illuminated POF garment – the LUMI jacket with textile-based switches – was created. Compared with current POF garments, the LUMI jacket’s wearability and accessibility were highly improved.

This project explored an unobstructive POF-illuminated garment to address the functional and wearable barriers to adoption. The interaction between wearer and garment is accessible. Electronics and textile touch sensors were seamlessly integrated into garment. Washability of POF garment was proved. This research explores how e-textiles can fit into everyday life.

This paper aims to investigate how different knitted structures affect the illuminative effect of polymeric optical fibres (POFs).

Knit prototypes were constructed using a 7-gauge industrial hand flat knitting machine. The textile prototype swatches developed in this study tested POF illumination in three types of knitting structures: intervallic knit and float stitch structures; POF inlaid into double plain and full cardigan structures; and double plain and partial knitting structures. The illuminative effects of the POFs in seven prototype swatches were analysed and compared.

It is possible to use an industrial hand flat knitting machine to knit POFs. Longer floats expose more POFs, which boosts illumination but limits the textile’s horizontal stretchability. The openness of the full cardigan structure maximises POF exposure and contributes to even illumination. The partial knitting in different sections achieves the most complete physical integration of POFs into the knitted textiles but constrains the horizontal stretchability of the textiles.

The integration of POFs into knitted textiles provides a functional illuminative effect. Applications include but are not limited to fashion, architecture and interior design.

This study is novel, as it investigates new POF knitted textiles with different loop structures. This study examines how knit stitches affect POFs in intervallic knit and float stitch, inlaid POF double knit, double plain and partial knit and the illuminative effects of the knitted textile.

The purpose of this paper is to investigate how electronic components can be utilized and integrated into polymeric optical fibre (POF) textiles to refine the design aesthetic, tactile quality and initiate the interaction of textiles with the users; and to study the design process of interactive products by using a novel design process model.

Fashion and textile design methods, textile technology are used in combination with modern technologies such as laser engraving, sensing, short-distance communication technology, throughout the entire process of development of interactive photonics creations.

The results of evaluation indicate that the engineered prototypes can enhance the interactive function of interior furnishing. The usability of interactive POF cushions is optimized by innovative design methods considering both design and technology.

This research explores to combine knowledge from different disciplines, including textile, electronics, sensor and laser to create interactive soft furnishings. The inter-disciplinary research provides a new perspective on how POF fabric can be utilized as a new media to change the way people interact with their living surroundings. The interior soft furnishings are no longer unresponsive to people, but can react to them, adapt to their behaviors, change color according to their preferences and therefore merge into our daily life. The developed prototypes reshape interior soft furnishing, and therefore have both theoretical and practical significance.

The purpose of this article is to develop a smart illuminated polymeric optical fibre (POF) chameleonic garment, using a wearable device technology for camouflage or safety warnings based on user needs.

This study integrates the theory of the optical foundation, control system, wireless communication, program development and apparel design into a chameleonic garment, displaying some vests, bags and shoes.

After selecting a pixel in the photo taken by the smart phone, the four modes of the application developed in this study are used to change the POF colour of the garment.

This study develops four modes of smart phone application; picked mode: picks a pixel colour on a smart phone canvas, contrastive mode: transfers to contrastive colour of the picked pixel, customized mode – gives input colour number manual and random mode – it based on a system random number. When users have different functional requirements, the four modes provide various choices.

It is important to monitor wrist four direction movements (flexion, extension, adduction and abduction) for hand healthcare, wrist rehabilitation and upper limb exercise, and so on. The purpose of this study is to develop a quadri-directional optical bending sensor that integrated wearable device technology in a smart glove to detect wrist four direction movements.

The quadri-directional optical bending sensor was designed with a microcontroller board, a Bluetooth wireless module, a side-emitting polymeric optical fibre (POF), an infrared light emitting diode and four phototransistors. A linear equation was deduced to calculate bending angle from detecting sensor value of Arduino microcontroller. The bending angle values could be seen by the smartphone screen, so the system has a good human–machine interface function.

The light emission by macro-bending of the side-emitting POFs that the transmittance of the outer side is greater than the inner. The bending POFs lateral emission phenomenon integrated with phototransistors on the edge is suitable for the development of bending sensors.

This study is to develop a novel quadri-directional optical bending sensor to replace two bi-direction sensors or four uni-direction sensors for wrist four direction movements monitoring.

The colors of traditional interior textiles cannot be changed. With the development of hi-tech textiles, interior textiles and furnishings with changeable colors are now possible with the integration of optical fibers. In this article, a study on the design of optical fiber integrated photonic interior furnishings is presented. First, the applications of polymeric optical fibers (POFs) in textiles are reviewed. It is observed that although there have been a wide variety in applications of POFs in textiles, research on the application of POFs in interior furnishing is rarely reported. The gap between technology and design handicaps the usability of photonic products. In order to design user-friendly photonic soft furnishings, a new design method is explored. Both technical and design aspects are considered in the development of photonic soft furnishings. A prototype of photonic fabrics and soft furnishings is successfully created. A usability test is undertaken to evaluate the performance of the prototype. The result of the usability test reveals that most of the subjects are satisfied with the overall performance of the prototype. They believe that photonic interior furnishings with changeable colors can enhance the environment. These usability test results are fed back to the design framework, and can provide a good source of reference for the improvement of photonic soft furnishing in the future.

The purpose of this study is to propose an extended reliability method for an industrial motor drive by integrating the physics of failure (PoF).

Industrial motor drive systems (IMDS) are currently expected to perform beyond the desired operating conditions to meet the demand. The PoF of the subsystem affects its reliability under such harsh operating circumstances. It is crucial to estimate reliability by integrating PoF, which helps in understanding its impact and to develop a fault-tolerant design, particularly in such an integrated drive system. An integrated PoF extended reliability method for industrial drive system is proposed to address this issue. In research, the numerical failure rate of each component of industrial drive is obtained first with the help of the MIL-HDBK-217 military handbook. Furthermore, the mathematically deduced proposed approach is modeled in the GoldSim Monte Carlo reliability workbench.

From the results, for a 15% rise in integrated PoF, the reliability and availability of the entire IMDS dropped by 23%, resulting in an impact on mean time to failure (MTTF).

The integrated PoF of the motor and motor controller affects industrial drive reliability, which falls to 0.18 with the least MTTF (2.27 years); whose overall reliability of industrial drive drops to 0.06 if it is additionally integrated with communication protocol.

Examines the fifteenth published year of the ITCRR. Runs the whole gamut of textile innovation, research and testing, some of which investigates hitherto untouched aspects. Subjects discussed include cotton fabric processing, asbestos substitutes, textile adjuncts to cardiovascular surgery, wet textile processes, hand evaluation, nanotechnology, thermoplastic composites, robotic ironing, protective clothing (agricultural and industrial), ecological aspects of fibre properties – to name but a few! There would appear to be no limit to the future potential for textile applications.

The main aim of this work is evaluation of side emitting plastic optical fibers (POF) illumination intensity changes in dependence on the distance from light source. Illumination intensity is measured along straight and bent fibers. The special devices for these measurements realization are described. The dependence of light intensity on the distance from light source for straight optical fibers is expressed by the exponential type model with two parameters, i.e. illumination intensity at the input into fiber and fiber attenuation factor. Preliminary results of measurement of light intensity in bent state are discussed. Influence of ratio between fiber diameter and bending cylinder diameter on the illumination intensity changes is presented.

This paper presents the defects that occur during the assembly and manufacturing of solder joints in single‐sided insertion‐mount printed wiring boards (PWBs). Each type of defect is discussed, with particular focus on how these defects are related to solderability issues, the mechanisms of failure due to defect‐induced failure accelerators, and the effect of the defect on solder joint reliability.