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1. On the Accuracy of Network Synchronization Using Persistent Hourglass Clocks

   https://doi.org/10.1145/3362053.3363497  

   Çürük, Eren; Yıldırım, Kasim Sinan; Pawelczak, Przemyslaw; Hester, Josiah (January 2019, Proceedings of the 7th International Workshop on Energy Harvesting & Energy-Neutral Sensing Systems)

   Batteryless sensor nodes compute, sense, and communicate using only energy harvested from the ambient. These devices promise long maintenance free operation in hard to deploy scenarios, making them an attractive alternative to battery-powered wireless sensor networks. However, complications from frequent power failures due to unpredictable ambient energy stand in the way of robust network operation. Unlike continuously-powered systems, intermittently-powered batteryless nodes lose their time upon each reboot, along with all volatile memory, making synchronization and coordination difficult. In this paper, we consider the case where each batteryless sensor is equipped with a hourglass capacitor to estimate the elapsed time between power failures. Contrary to prior work that focused on providing a continuous notion of time for a single batteryless sensor, we consider a network of batteryless sensors and explore how to provide a network-wide, continuous, and synchronous notion of time. First, we build a mathematical model that represents the estimated time between power failures by using hourglass capacitors. This allowed us to simulate the local (and continuous) time of a single batteryless node. Second, we show--through simulations--the effect of hourglass capacitors and in turn the performance degradation of the state of the art synchronization protocol in wireless sensor networks in a network of batteryless devices. 

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2. Hapt-Aids: Self-Powered, On-Body Haptics for Activity Monitoring

   https://doi.org/10.1145/3749468  

   Shen, Vivian; Yang, Xiaoying; Harrison, Chris; Zhang, Yang (September 2025, Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies)

   Wearables are becoming increasingly useful, primarily due to their activity-monitoring features that enable various healthcare applications. Everyday devices like smartwatches, however, often have complex ecosystems and convoluted interfaces. These devices need constant charging and can be difficult to use, cumbersome for users interested in only simple applications. As an alternative, simpler everyday wearable, we present Hapt-Aids, self-powered on-body tags that passively monitor user activities and deliver haptic notifications. Our small-footprint devices 1) harvest energy from activity-specific sources, 2) use this energy as sensor information, and 3) convert this energy into haptic actuation using only analog hardware, without digital components or firmware. This structurally simple, triple-purpose design makes our system extremely low maintenance while being cost- and energy-efficient, leading to a friendly user experience. We present our proof-of-concept system design: a custom, unique architecture formed through theoretical modeling and evaluation studies, and we build four demo applications. Through in-lab benchmark testing and user studies, we demonstrate the potential of Hapt-Aids as alternative low-cost, easy-to-use wearables. 

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3. Logic-enabled textiles

   https://doi.org/10.1073/pnas.2202118119  

   Rajappan, Anoop; Jumet, Barclay; Shveda, Rachel A.; Decker, Colter J.; Liu, Zhen; Yap, Te Faye; Sanchez, Vanessa; Preston, Daniel J. (August 2022, Proceedings of the National Academy of Sciences)

   Textiles hold great promise as a soft yet durable material for building comfortable robotic wearables and assistive devices at low cost. Nevertheless, the development of smart wearables composed entirely of textiles has been hindered by the lack of a viable sheet-based logic architecture that can be implemented using conventional fabric materials and textile manufacturing processes. Here, we develop a fully textile platform for embedding pneumatic digital logic in wearable devices. Our logic-enabled textiles support combinational and sequential logic functions, onboard memory storage, user interaction, and direct interfacing with pneumatic actuators. In addition, they are designed to be lightweight, easily integrable into regular clothing, made using scalable fabrication techniques, and durable enough to withstand everyday use. We demonstrate a textile computer capable of input-driven digital logic for controlling untethered wearable robots that assist users with functional limitations. Our logic platform will facilitate the emergence of future wearables powered by embedded fluidic logic that fully leverage the innate advantages of their textile construction. 

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4. Workshop on AI integration with Renewable Energy harvesting sources

   Cooper, Geffen; Bhat, Ganapati (June 2025, https://bsn.embs.org/2024/program/workshops/)

   The potential of energy harvesting and batteryless sensing promises a future where IoT devices will become sustainable, long-lasting, and maintenance free. Given the significant challenges involved with building and programming such devices, it is reasonable to question whether energy harvesting based IoT can replace existing wearables (fitness trackers, smartwatches, or medical devices), while providing a reliable user experience. Hence, an important question arises: “What role can energy harvesting based sensing play in the age of AI and deep learning?” While energy harvesting based sensors can unlock new applications in wearables and personalized data analytics, the path towards integrating them into the modern deep learning landscape requires substantial intellectual innovation. This workshop aims to bridge multiple perspectives in wearable sensing and data analytics in the modern age of AI. 

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5. Greentooth: Robust and Energy Efficient Wireless Networking for Batteryless Devices

   https://doi.org/10.1145/3649221  

   Babatunde, Simeon; Alsubhi, Arwa; Hester, Josiah; Sorber, Jacob (May 2024, ACM Transactions on Sensor Networks)

   Communication presents a critical challenge for emerging intermittently powered batteryless sensors. Batteryless devices that operate entirely on harvested energy often experience frequent, unpredictable power outages and have trouble keeping time accurately. Consequently, effective communication using today’s low-power wireless network standards and protocols becomes difficult, particularly because existing standards are usually designed to support reliably powered devices with predictable node availability and accurate timekeeping capabilities for connection and congestion management. In this article, we present Greentooth, a robust and energy-efficient wireless communication protocol for intermittently powered sensor networks. It enables reliable communication between a receiver and multiple batteryless sensors using Time Division Multiple Access–style scheduling and low-power wake-up radios for synchronization. Greentooth employs lightweight and energy-efficient connections that are resilient to transient power outages, while significantly improving network reliability, throughput, and energy efficiency of both the battery-free sensor nodes and the receiver—which could be untethered and energy constrained. We evaluate Greentooth using a custom-built batteryless sensor prototype on synthetic and real-world energy traces recorded from different locations in a garden across different times of the day. Results show that Greentooth achieves 73% and 283% more throughput compared to Asynchronous Wake-up on Demand MAC and Receiver-Initiated Consecutive Packet Transmission Wake-up Radios, respectively, under intermittent ambient solar energy and over 2× longer receiver lifetime. 

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