Study of the light energy harvesting capacity in indoor environments

Costa, Mathias Scroccaro; Manera, Leandro Tiago; Moreira, Hugo Soeiro

doi:10.1109/inscit.2019.8868516

Cited by 9 publications

(4 citation statements)

References 9 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Nevertheless, in recent years, the increasing diffusion of pervasive low-power applications, mainly driven by the pivotal paradigms of IoT and IoE, are driving research advancements around miniaturization of light-based EHs [169]- [171]. Given such a context, indoor application scenarios are attracting particular interest [172].…”

Section: ) Energy Harvestersmentioning

confidence: 99%

Review and Perspectives of Micro/Nano Technologies as Key-Enablers of 6G

Iannacci

Poor

2022

IEEE Access

View full text Add to dashboard Cite

show abstract

Section: ) Energy Harvestersmentioning

confidence: 99%

Review and Perspectives of Micro/Nano Technologies as Key-Enablers of 6G

Iannacci

Poor

2022

IEEE Access

View full text Add to dashboard Cite

show abstract

“…In general, indoor light energy harvesting results in a strongly formance of the solar cells. In [22], this issue is shown for a cell wi for IoT devices (1.9 cm × 5.0 cm). The power density for four differen varies in the range of 10-30 µW/cm 2 at the maximum power poin solar illumination is present, this value increases by the factor of the problem of the low light situation indoors.…”

Section: 21 X For Peer Reviewmentioning

confidence: 99%

“…Hamadani and Campanell ber in [25] for testing reference cells with varying spectra of the LED In general, indoor light energy harvesting results in a strongly reduced output performance of the solar cells. In [22], this issue is shown for a cell with typical dimensions for IoT devices (1.9 cm × 5.0 cm). The power density for four different application positions varies in the range of 10-30 µW/cm 2 at the maximum power point.…”

Section: 21 X For Peer Reviewmentioning

confidence: 99%

Prospects of Wireless Energy-Aware Sensors for Smart Factories in the Industry 4.0 Era

et al. 2021

View full text Add to dashboard Cite

Advanced sensors are becoming essential for modern factories, as they contribute by gathering comprehensive data about machines, processes, and human-machine interaction. They play an important role in improving manufacturing performance, in-factory logistics, predictive maintenance, supply chains, and digitalization in general. Wireless sensors and wireless sensor networks (WSNs) provide, in this context, significant advantages as they are flexible and easily deployable. They have reduced installation and maintenance costs and contributed by reducing cables and preinstalled infrastructure, leading to improved reliability. WSNs can be retrofitted in machines to provide direct information from inside the processes. Recent developments have revealed exciting possibilities to enhance energy harvesting (EH) and wireless energy transmission, enabling a reliable use of wireless sensors in smart factories. This review provides an overview of the potential of energy aware WSNs for industrial applications and shows relevant techniques for realizing a sustainable energy supply based on energy harvesting and energy transfer. The focus is on high-performance converter solutions and improvement of frequency, bandwidth, hybridization of the converters, and the newest trends towards flexible converters. We report on possibilities to reduce the energy consumption in wireless communication on the node level and on the network level, enabling boosting network efficiency and operability. Based on the existing technologies, energy aware WSNs can nowadays be realized for many applications in smart factories. It can be expected that they will play a great role in the future as an enabler for digitalization in this decisive economic sector.

show abstract

“…Energy harvesting is the collection of ambient energy from various renewable sources, such as solar [6], wind, and thermal (heat) [7], to power commercial wireless devices. Mechanical energy, vibration [8], movement, sound (acoustic) [9], light [10], electromagnetic energy, natural energy, human body energy, and others are examples of energy harvesting sources.…”

Section: Introductionmentioning

confidence: 99%

Rectenna for Radio Frequency Energy Harvesting: A Review

AB RASHID,

B. H. Ahmad,

M. Z. A. Abd Aziz

et al. 2024

Elektrika

View full text Add to dashboard Cite

The emergence of wireless charging technology is also a topic of debate among consumers, fabricators, researchers, and academics. This paper focuses on the literature review of several works on the previous enhancement technique that effect the performance of antenna design with rectifying circuit (rectenna) for energy transfer system technology. Several techniques are applied on this microstrip antenna design work to enhance the antenna performance such as slot, parasitic element, fractal, antenna arrays and others. The parameters that are considered in this work are return loss, resonant frequency with bandwidth, gain and the antenna dimension.

show abstract

Study of the light energy harvesting capacity in indoor environments

Cited by 9 publications

References 9 publications

Review and Perspectives of Micro/Nano Technologies as Key-Enablers of 6G

Review and Perspectives of Micro/Nano Technologies as Key-Enablers of 6G

Prospects of Wireless Energy-Aware Sensors for Smart Factories in the Industry 4.0 Era

Rectenna for Radio Frequency Energy Harvesting: A Review

Contact Info

Product

Resources

About