Prediction of Harvestable Energy for Self-Powered Wearable Healthcare Devices: Filling a Gap

Wahba, Maram A.; Ashour, Amira S.; Ghannam, Rami

doi:10.1109/access.2020.3024167

Cited by 32 publications

(17 citation statements)

References 95 publications

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“…According to previous studies, there are multiple alternative energy source in smart contact lens design. Moreover, there is interest in using machine learning techniques to predict the amount of harvestable energy from these sources [79], [80]. Table III contains publications about different energy sources and the maximum power.…”

Section: B Energymentioning

confidence: 99%

State-of-the-Art in Smart Contact Lenses for Human–Machine Interaction

Xia

Khamis

Fernández

et al. 2023

IEEE Trans. Human-Mach. Syst.

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Contact lenses have traditionally been used for vision correction applications. Recent advances in microelectronics and nanofabrication on flexible substrates have now enabled sensors, circuits and other essential components to be integrated on a small contact lens platform. This has opened up the possibility of using contact lenses for a range of humanmachine interaction applications including vision assistance, eye tracking, displays and healthcare. In this article, we systematically review the range of smart contact lens materials, device architectures and components that facilitate this interaction for different applications. In fact, evidence from our systematic review demonstrates that these lenses can be used to display information, detect eye movements, restore vision and detect certain biomarkers in tear fluid. Consequently, whereas previous state-of the-art reviews in contact lenses focused exclusively on biosensing, our systematic review covers a wider range of smart contact lens applications in HMI. Moreover, we present a new method of classifying the literature on smart contact lenses according to their six constituent building blocks, which are the sensing, energy management, driver electronics, communications, substrate and the I/O interfacing modules. Based on recent developments in each of these categories, we speculate the challenges and opportunities of smart contact lenses for humanmachine interaction. Moreover, based on our analysis of the state-of-the-art we develop guidelines for the future design of a self-powered smart contact lens concept with integrated energy harvesters, sensors and communications modules. Therefore, our review is a critical evaluation of current data and is presented with the aim of guiding researchers to new research directions in smart contact lenses.

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Section: B Energymentioning

confidence: 99%

State-of-the-Art in Smart Contact Lenses for Human–Machine Interaction

Xia

Khamis

Fernández

et al. 2023

IEEE Trans. Human-Mach. Syst.

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“…Consequently, various prototypes and commercial products have been designed and developed by research facilities and industrial companies. The market momentum is expected to reach nearly $140 billion by 2026 [ 10 ]. The most significant merit of healthcare monitoring is to provide real-time feedback information about health status, either to the individuals or to healthcare workers or professional personnel at a medical centre to take action before the happening of possible imminent health threats.…”

Section: Introductionmentioning

confidence: 99%

Healthcare Monitoring Using Low-Cost Sensors to Supplement and Replace Human Sensation: Does It Have Potential to Increase Independent Living and Prevent Disease?

Liu

Cascioli

McCarthy

2023

Sensors

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Continuous monitoring of health status has the potential to enhance the quality of life and life expectancy of people suffering from chronic illness and of the elderly. However, such systems can only come into widespread use if the cost of manufacturing is low. Advancements in material science and engineering technology have led to a significant decrease in the expense of developing healthcare monitoring devices. This review aims to investigate the progress of the use of low-cost sensors in healthcare monitoring and discusses the challenges faced when accomplishing continuous and real-time monitoring tasks. The major findings include (1) only a small number of publications (N = 50) have addressed the issue of healthcare monitoring applications using low-cost sensors over the past two decades; (2) the top three algorithms used to process sensor data include SA (Statistical Analysis, 30%), SVM (Support Vector Machine, 18%), and KNN (K-Nearest Neighbour, 12%); and (3) wireless communication techniques (Zigbee, Bluetooth, Wi-Fi, and RF) serve as the major data transmission tools (77%) followed by cable connection (13%) and SD card data storage (10%). Due to the small fraction (N = 50) of low-cost sensor-based studies among thousands of published articles about healthcare monitoring, this review not only summarises the progress of related research but calls for researchers to devote more effort to the consideration of cost reduction as well as the size of these components.

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“…[ 22 ] Despite current interests in predicting the amount of harvestable energy from intermittent sources such as the sun, photovoltaic energy harvesting is strongly dependent on the incoming light intensity. [ 23,24 ] Solar cells can provide high and stable energy densities when exposed to outdoor sunlight (around 15 mW cm −2 ). However, this power density immediately drops to below 10 µW cm −2 at indoor conditions, which may not sufficiently meet the needs of modern wearable devices.…”

Section: Introductionmentioning

confidence: 99%

Piezoelectric energy harvesting for self‐powered wearable upper limb applications

et al. 2021

Self Cite

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Wearable devices can be used for monitoring vital physical and physiological signs remotely, as well as for interacting with computers. Widespread adoption of wearables is somewhat hindered by the duration time they can be used without re‐recharging. To ensure uninterrupted operation, these devices need a constant and battery‐less energy supply. Scavenging energy from the wearable's surroundings is, therefore, an essential step towards achieving genuinely autonomous and self‐powered devices. While energy harvesting technologies may not completely eliminate the battery storage unit, they can ensure a maximum duration of use. Piezoelectric energy harvesting is a promising and efficient technique to generate electricity for powering wearable devices in response to body movements. Consequently, we systematically survey the range of technologies used for scavenging energy from the human body, with a particular focus on the upper‐limb area. According to our review and in comparison to other upper limb locations, highest power densities can be achieved from piezoelectric transducers located on the wrist. For short and fast battery charging needs, we therefore review the range of materials, architectures and devices used to scavenge energy from these upper‐limb areas. We provide comparisons as well as recommendations and possible future directions for harvesting energy using this promising technique.

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Prediction of Harvestable Energy for Self-Powered Wearable Healthcare Devices: Filling a Gap

Cited by 32 publications

References 95 publications

State-of-the-Art in Smart Contact Lenses for Human–Machine Interaction

State-of-the-Art in Smart Contact Lenses for Human–Machine Interaction

Healthcare Monitoring Using Low-Cost Sensors to Supplement and Replace Human Sensation: Does It Have Potential to Increase Independent Living and Prevent Disease?

Piezoelectric energy harvesting for self‐powered wearable upper limb applications

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