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1. A kirigami-enabled electrochromic wearable variable-emittance device for energy-efficient adaptive personal thermoregulation

   https://doi.org/10.1093/pnasnexus/pgad165  

   Chen, Ting-Hsuan; Hong, Yaoye; Fu, Ching-Tai; Nandi, Ankita; Xie, Wanrong; Yin, Jie; Hsu, Po-Chun (June 2023, PNAS Nexus)

   Derek Abbott (Ed.)

   For centuries, people have put effort to improve the thermal performance of clothing to adapt to varying temperatures. However, most clothing we wear today only offers a single-mode insulation. The adoption of active thermal management devices, such as resistive heaters, Peltier coolers, and water recirculation, is limited by their excessive energy consumption and form factor for long-term, continuous, and personalized thermal comfort. In this paper, we developed a wearable variable-emittance (WeaVE) device, enabling the tunable radiative heat transfer coefficient to fill the missing gap between thermoregulation energy efficiency and controllability. WeaVE is an electrically driven, kirigami-enabled electrochromic thin-film device that can effectively tune the midinfrared thermal radiation heat loss of the human body. The kirigami design provides stretchability and conformal deformation under various modes and exhibits excellent mechanical stability after 1,000 cycles. The electronic control enables programmable personalized thermoregulation. With less than 5.58 mJ/cm2 energy input per switching, WeaVE provides 4.9°C expansion of the thermal comfort zone, which is equivalent to a continuous power input of 33.9 W/m2. This nonvolatile characteristic substantially decreases the required energy while maintaining the on-demand controllability, thereby providing vast opportunities for the next generation of smart personal thermal managing fabrics and wearable technologies. 

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2. ECSkin: Tessellating Electrochromic Films for Reconfigurable On-skin Displays

   https://doi.org/10.1145/3659613  

   Ku, Pin-Sung; Jiang, Shuwen; Wang, Wei-Hsin; Kao, Hsin-Liu Cindy (May 2024, Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies)

   Emerging electrochromic (EC) materials have advanced the frontier of thin-film, low-power, and non-emissive display technologies. While suitable for wearable or textile-based applications, current EC display systems are manufactured in fixed, pre-designed patterns that hinder the potential of reconfigurable display technologies desired by on-skin interactions. To realize the customizable and scalable EC display for skin wear, this paper introduces ECSkin, a construction toolkit composed of modular EC films. Our approach enables reconfigurable designs that display customized patterns by arranging combinations of premade EC modules. An ECSkin device can pixelate patterns and expand the display area through tessellating congruent modules. We present the fabrication of flexible EC display modules with accessible materials and tools. We performed technical evaluations to characterize the electrochromic performance and conducted user evaluations to verify the toolkit's usability and feasibility. Two example applications demonstrate the adaptiveness of the modular display on different body locations and user scenarios. 

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3. A Soft Approach to Convey Vibrotactile Feedback in Wearables Through Mechanical Hysteresis

   https://doi.org/10.1109/RoboSoft55895.2023.10122072  

   Fino, Nathaniel; Zook, Zane A.; Jumet, Barclay; Preston, Daniel J.; O'Malley, Marcia K. (April 2023, 2023 IEEE International Conference on Soft Robotics (RoboSoft))

   Vibration is ubiquitous as a mode of haptic communication, and is used widely in handheld devices to convey events and notifications. The miniaturization of electromechanical actuators that are used to generate these vibrations has enabled designers to embed such actuators in wearable devices, conveying vibration at the wrist and other locations on the body. However, the rigid housings of these actuators mean that such wearables cannot be fully soft and compliant at the interface with the user. Fluidic textile-based wearables offer an alternative mechanism for haptic feedback in a fabric-like form factor. To our knowledge, fluidically driven vibrotactile feedback has not been demonstrated in a wearable device without the use of valves, which can only enable low-frequency vibration cues and detract from wearability due to their rigid structure. We introduce a soft vibrotactile wearable, made of textile and elastomer, capable of rendering high-frequency vibration. We describe our design and fabrication methods and the mechanism of vibration, which is realized by controlling inlet pressure and harnessing a mechanical hysteresis. We demonstrate that the frequency and amplitude of vibration produced by our device can be varied based on changes in the input pressure, with 0.3 to 1.4 bar producing vibrations that range between 160 and 260 Hz at 13 to 38 g, the acceleration due to gravity. Our design allows for controllable vibrotactile feedback that is comparable in frequency and outperforms in amplitude relative to electromechanical actuators, yet has the compliance and conformity of fully soft wearable devices. 

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4. Exploring the Design for Wearability of Wearable Devices: A Scoping Review

   https://doi.org/10.3390/computers13120326  

   Seo, Yeo Weon; La_Marca, Valentina; Tandon, Animesh; Chiao, Jung-Chih; Drummond, Colin K (December 2024, Computers)

   Wearable smart devices have become ubiquitous in modern society, extensively researched for their health monitoring capabilities and convenience features. However, the “wearability” of these devices remains a relatively understudied area, particularly in terms of design informed by clinical trials. Wearable devices possess significant potential to enhance daily life, yet their success depends on understanding and validating the design factors that influence comfort, usability, and seamless integration into everyday routines. This review aimed to evaluate the “wearability” of smart devices through a mixed-methods scoping literature review. By analyzing studies on comfort, usability, and daily integration, it sought to identify design improvements and research gaps to enhance user experience and system design. From an initial pool of 130 publications (1998–2024), 19 studies met the inclusion criteria. The review identified three significant outcomes: (1) a lack of standardized assessment methods, (2) the predominance of qualitative over quantitative assessments, and (3) limited utility of findings for informing design. Although qualitative studies provide valuable insights, the absence of quantitative research hampers the development of validated, generalizable design criteria. This underscores the urgent need for future studies to adopt robust quantitative methodologies to better assess wearability and inform evidence-based design strategies. 

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5. Characterizing Hybrid Active/Passive Heating Systems for Thermal Microclimate Control

   https://doi.org/10.1115/DMD2021-1065  

   Beaudette, Eric; Foo, Esther; Woelfle, Heidi; Molla, Md. Tahmidul; Dunne, Lucy (April 2021, Proceedings of the 2021 Design of Medical Devices Conference. 2021 Design of Medical Devices Conference)

   Abstract Heating devices offer particular benefits in cold climates and to those with thermoregulatory or vasospastic disorders, like Reynaud’s syndrome. Heating devices can be used to moderate a wearer’s microclimate to alleviate thermal discomfort and pain, especially in the distal extremities where thermal sensitivity is the highest. Applying insulation on top of wearables with heating components can reduce both heat lost to the environment, as well as power needs for maintaining thermal comfort. Here, we evaluated one stitched, heated textile garment with eight textile insulation materials to assess heat propagation (measured by five thermistors on a mannequin hand and one in the surrounding, enclosed environment) and wearability (measured from tests of fabric weight, thickness, flexural rigidity, and permeance). Results find energy conserved by all materials, but wearability drawbacks for some strong insulators. Thicker materials generally had higher insulative properties, and reduced heat propagation to the indirect heating regions, specifically the finger and thumb. Additionally, heat propagation through to the environment was stronger than to the finger and thumb. 

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