Analysis and Maximizing Energy Harvesting from RF Signals using T-Shaped Microstrip Patch Antenna

Iqbal, Muhammad Salman; Khanzada, Tariq Jamil Saifullah; Dahri, Faisal Ahmed; Ali, Asif; Ali, M.M.; Khokhar, Abdul Wahab

doi:10.14569/ijacsa.2019.0100141

Cited by 6 publications

(1 citation statement)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Since this study will only employ the simulation, the function generator will assist the antenna role as the input source to the circuit. This method has been employed by [7] and [9] in their previous study. Same to the antenna, a rectifier is one of the indispensable components in a rectenna.…”

Section: Components In Rectennamentioning

confidence: 99%

Design of Power Over Wi-Fi Rectifier Circuit for IoT Based Sensor Application through Simulation

Azman¹,

Ramli²

2020

IJETS

View full text Add to dashboard Cite

Energy harvesting has been a phenomena throughout the year as it produces renewable clean energy which not only benefit to the user but also to the environment. Radio frequency energy is among the possible choice that can be harvested for low power usage application. By doing so, low power application such as IoT based sensors can eliminate usage of input power from battery which has limited supply over time or restrained from limited cable length. The objectives of this study are to design a power over Wi-Fi rectifier circuit for IoT based sensor application, analyze the effect of different type of diodes to the power over Wi-Fi rectifier circuit, and determine of minimum voltage required to power an IoT sensor. Cockcroft Walton voltage multiplier configuration was chosen as the rectifier circuit to be employed in the simulation by using Multisim software. With two different Schottky diodes, the output were recorded, and analyzed. Both diode has achieved the minimum required voltage of 3.3V and above for IoT sensors at stage 3. Among the diodes, BAT68 has recorded better output with 4.145V compare to diode BAT17 with 4.090V. Output of diode BAT68 also has reach its stable condition fast than diode BAT17. This configuration can be used and applied in prototype for future study. Even though there are many other factors that need to be considered, radio frequency energy harvesting should be explored more as it promotes clean energy and longevity lifespan as the world are moving wireless in many tasks.

show abstract

Section: Components In Rectennamentioning

confidence: 99%

Design of Power Over Wi-Fi Rectifier Circuit for IoT Based Sensor Application through Simulation

Azman¹,

Ramli²

2020

IJETS

View full text Add to dashboard Cite

show abstract

Design of Circularly Polarized Koch Snowflake Fractal Antenna With Schottky Band Diode Rectifiers for RF Energy Harvesting Applications

Sathiyapriya,

Sudhakar

2024

Int J Communication

View full text Add to dashboard Cite

Radio frequency (RF) energy harvesting has recently become an effective way of powering wireless devices, reducing the requirement of batteries along with their related storage as well as lifespan restrictions. One of the main obstacles to RF energy harvesting is the limited quantity of energy that can be obtained from wireless sources due to weak signal strength, low efficiency, and poor gain. To address these shortcomings, the proposed method is designed based on the circularly polarized Koch snowflake fractal antenna with the Jerusalem cross (JC)–based frequency‐selective surface (FSS) and Schottky diode–based rectifiers for RF energy harvesting applications at the resonance frequency of 5.8 GHz. The electromagnetic energy from the environment can effectively captured using a proposed wide band and high gain antenna designed using a Koch snowflake array based on FSSs. Flame Retardant‐4 (FR‐4) material has good dielectric qualities for electronics, and it is employed as the dielectric substrate in this model; copper serves as the ground plane. The squid game optimizer (SGO) determines the ideal outer snowflake dimensions by maximizing the resonance frequency in order to achieve high gain. The optimally selected outer snowflake length and width are 40 and 23.09 mm. The designed antenna model uses a rectifier based on Schottky diodes for RF energy harvesting applications, which involves converting electromagnetic waves into direct current. The fractal antenna model and RF energy harvesting are designed and simulated using the ANSYS HFSS and Matlab RF toolbox. The model is used to evaluate the antenna's performance by concentrating on gain radiation patterns, S11, and voltage standing wave ratio (VSWR). The Koch snowflake fractal antenna, which uses a JC–based FSS, has been measured for performance at 5.8‐GHz frequency; the values obtained for impedance bandwidth, gain, S11, and VSWR are 7.61%, 9.962 dB, −33 dB, and 1.01, respectively. The analysis of the experimental data demonstrates that the Koch snowflake fractal antenna, which is being proposed for energy harvesting applications, outperforms several other existing designs in terms of effectiveness.

show abstract

Far Field Analysis of Defected Ground Structured Wideband Antenna for RF Energy Harvesting Applications

Pandey

Shankhwar

Singh

2020

Lecture Notes in Electrical Engineering

View full text Add to dashboard Cite

Analysis and Maximizing Energy Harvesting from RF Signals using T-Shaped Microstrip Patch Antenna

Cited by 6 publications

References 11 publications

Design of Power Over Wi-Fi Rectifier Circuit for IoT Based Sensor Application through Simulation

Design of Power Over Wi-Fi Rectifier Circuit for IoT Based Sensor Application through Simulation

Design of Circularly Polarized Koch Snowflake Fractal Antenna With Schottky Band Diode Rectifiers for RF Energy Harvesting Applications

Far Field Analysis of Defected Ground Structured Wideband Antenna for RF Energy Harvesting Applications

Contact Info

Product

Resources

About