Design of an efficiency‐enhanced Greinacher rectifier operating in the GSM 1800 band by using rat‐race coupler for RF energy harvesting applications

Gözel, Mahmut Ahmet; Kahriman, Mesud; Kasar, Ömer

doi:10.1002/mmce.21621

Cited by 22 publications

(9 citation statements)

References 26 publications

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“…As a result, they achieved an efficiency of 81.65% for 0 dBm input at 868 MHz. A different approach of designing a rectifier in a rectenna is presented in [51,52]. In both works, the authors manufactured a modified Greinacher rectifier that receives input from a rat-race coupler, that was used to divide the input RF signal into two signals with equal power and a 180 • phase shift.…”

Section: Rectifiermentioning

confidence: 99%

State-of-the-Art Techniques in RF Energy Harvesting Circuits

Bougas

Papadopoulou

Boursianis

et al. 2021

Telecom

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The exigency for continuous use of electrical devices has created greater demands for electricity along with more efficient transmission techniques. Energy from natural resources can be solar, thermal, vibration, friction, or Radio Frequencies (RF) signals. This state-of-the-art work provides a summary of RF energy harvesting techniques and can be used as a guide for the manufacture of RF energy scavenging modules. The use of Radio Frequency (RF) Energy Harvesting (EH) technique contributes to the development of autonomous energy devices and sensors. A rectenna system includes three main units: the receiving antenna, the impedance matching network, and the rectifier. We thoroughly analyze how to design a rectenna system with special emphasis given on the design of the rectifier. At the same time many works of the last 10 years are presented. This review article categorizes the used topologies depending on the type of antennas, IMNs, and rectifiers and comparatively presents their advantages and disadvantages.

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Section: Rectifiermentioning

confidence: 99%

State-of-the-Art Techniques in RF Energy Harvesting Circuits

Bougas

Papadopoulou

Boursianis

et al. 2021

Telecom

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“…For the rectifier, the shunt mounted (packaged SOT 323) HSMS‐285C Schottky diodes are used here because of their low threshold voltages. In order to achieve high efficiency, the standard symmetrical full‐wave Greinacher topology of the rectifier is adopted here as the basic configuration . The Greinacher topology is used in the present work because of the several advantages mentioned as: (a) the use of the Greinacher voltage multiplier increases the power handling capacity due to doubling the number of diodes.…”

Section: Rectifying Circuit Designmentioning

confidence: 99%

“…In order to achieve high efficiency, the standard symmetrical full-wave Greinacher topology of the rectifier is adopted here as the basic configuration. [22][23][24] The Greinacher topology is used in the present work because of the several advantages mentioned as: (a) the use of the Greinacher voltage multiplier increases the power handling capacity due to doubling the number of diodes. (b) As the number of rectifiers is doubled in the Greinacher voltage multiplier configuration, the optimal resistance value for the maximum conversion efficiency increases.…”

Section: Rectifying Circuit Designmentioning

confidence: 99%

An efficient dual‐band rectenna using symmetrical rectifying circuit and slotted monopole antenna array

Chandravanshi

Akhtar

2020

Int J RF Microw Comput Aided Eng

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In this article, an efficient dual‐band rectenna making use of the newly proposed symmetrical rectifying circuit working at the frequency of 1.8 and 2.45 GHz, is proposed. The proposed dual‐band rectifying circuit is combined with an array of compact wideband planar monopole modified circular slot antenna in order to facilitate the efficient rectenna design. The rectifying circuit employs symmetrical matching network in addition to the symmetrical rectifier thereby facilitating the suppression of the odd order harmonics. This eventually results into the higher output voltage as compared to the conventional rectifier circuits. Moreover, the dual‐band topology of the proposed rectenna increases the overall voltage by harvesting energy from two independent RF sources. The measured results of the fabricated structure show that the maximum RF to dc conversion efficiency of the proposed rectifier circuit reaches up to 70% at 9 dBm input RF power. From application point of view, the proposed rectenna circuit is tested to extract the RF energy from 1.8 GHz cellular and 2.45 GHz Wi‐Fi bands to energize a low‐power LED. The overall rectenna structure is reasonably compact providing good performance, which can potentially be employed for efficient wireless power transmission system.

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“…One of the most widely known RF rectifier circuits is the Dickson rectifier . The circuit, which can basically respond to low current and voltage, provides achieving high power conversion efficiency and high DC voltage over the output load . In addition to being practical and simple, Dickson rectifier circuits are widely preferred because they are suitable for being developed .…”

Section: Introductionmentioning

confidence: 99%

“…7,8 The circuit, which can basically respond to low current and voltage, provides achieving high power conversion efficiency and high DC voltage over the output load. 9,10 In addition to being practical and simple, Dickson rectifier circuits are widely preferred because they are suitable for being developed. 7,11,12 Another advantage of the energy harvesting process with Dickson circuits is that it creates a staged-structure by adding the same rectifier circuit one after the other.…”

Section: Introductionmentioning

confidence: 99%

Analysis of rectifier stage number and load resistance in an RF energy harvesting circuit

Kasar

Gözel

Kahriman

2019

Micro & Optical Tech Letters

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In this study, a single‐stage and three‐stage Dickson rectifier circuits that would be able to perform RF energy harvesting were proposed. Operating frequency was selected as 1 GHz. The highest efficiency value was obtained at 7 dBm input power. The load resistance values for the input power were parametrically analyzed and the power conversion efficiency and output voltage were calculated. In the cases where the best performance was obtained, while a maximum power conversion efficiency of 70.5% was obtained in the single‐stage Dickson circuit, maximum 77% efficiency was obtained in the three‐stage circuit. In addition, in the cases where the highest efficiency was observed, the load resistance values were calculated as 5590 and 14 610 Ω at the single stage and three stages, respectively. The load resistance value used to obtain higher efficiency values in the three‐stage circuit is increasing. Moreover, it was observed that as the number of stages increased, the output voltage also increased linearly. The maximum output voltage which was 1.8 V in the single‐stage was measured as ~5.16 V in three‐stages.

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Design of an efficiency‐enhanced Greinacher rectifier operating in the GSM 1800 band by using rat‐race coupler for RF energy harvesting applications

Cited by 22 publications

References 26 publications

State-of-the-Art Techniques in RF Energy Harvesting Circuits

State-of-the-Art Techniques in RF Energy Harvesting Circuits

An efficient dual‐band rectenna using symmetrical rectifying circuit and slotted monopole antenna array

Analysis of rectifier stage number and load resistance in an RF energy harvesting circuit

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