Rectenna

A rectenna is a rectifying antenna — a special type of receiving antenna that is used for converting electromagnetic energy into direct current (DC) electricity. They are used in wireless power transmission systems that transmit power by radio waves. A simple rectenna element consists of a dipole antenna with an RF diode connected across the dipole elements. The diode rectifies the AC induced in the antenna by the microwaves, to produce DC power, which powers a load connected across the diode. Schottky diodes are usually used because they have the lowest voltage drop and highest speed and therefore have the lowest power losses due to conduction and switching.[1] Large rectennas consist of an array of many such dipole elements.

Rectennas for power beaming applications


The invention of the rectenna in the 1960s made long distance wireless power transmission feasible. The rectenna was invented in 1964 and patented in 1969[2] by US electrical engineer William C. Brown, who demonstrated it with a model helicopter powered by microwaves transmitted from the ground, received by an attached rectenna.[3] Since the 1970s, one of the major motivations for rectenna research has been to develop a receiving antenna for proposed solar power satellites, which would harvest energy from sunlight in space with solar cells and beam it down to Earth as microwaves to huge rectenna arrays.[4] A proposed military application is to power drone reconnaissance aircraft with microwaves beamed from the ground, allowing them to stay aloft for long periods.

In recent years, interest has turned to using rectennas as power sources for small wireless microelectronic devices. The largest current use of rectennas is in RFID tags, proximity cards and contactless smart cards, which contain an integrated circuit (IC) which is powered by a small rectenna element. When the device is brought near an electronic reader unit, radio waves from the reader are received by the rectenna, powering up the IC, which transmits its data back to the reader.

Radio frequency rectennas

Radio Frequency (RF) energy harvesting has experienced a rapid development in recent years due to the increasing number of RF transmitter sources producing an abundant ambient microwave energy waste. Furthermore, the development of wireless power transmission (WPT) technologies has triggered impetus for RF energy harvesting. Hence, RF energy scavenging is a promising solution as it has the potential to provide a sustainable energy source to meet upcoming demands. Efficient ambient RF energy scavenging is a very challenging issue, as it deals with the low RF power levels available in the environment. The scavengeable power levels are generally unknown and can vary unpredictably; therefore sparking research interest to develop highly sensitive RF energy scavengers to capture ambient RF signals over a range of low input power levels[5].[6][7] [8] [9]

The simplest crystal radio receiver, employing an antenna and a demodulating diode (rectifier), is actually a rectenna, although it discards the DC component before sending the signal to the headphones. People living near strong radio transmitters would occasionally discover that with a long receiving antenna, they could get enough electric power to light a light bulb.[10]

However, this example uses only one antenna having a limited capture area. A rectenna uses multiple antennas spread over a wide area to capture more energy.

Researchers are experimenting with the use of rectennas to power sensors in remote areas and distributed networks of sensors, especially for IoT applications.[11]

RF rectennas are used for several forms of wireless power transfer. In the microwave range, experimental devices have reached a power conversion efficiency of 85-90%.[12] The record conversion efficiency for a rectenna is 90.6% for 2.45 GHz,[13] with lower efficiency of about 82% achieved 5.82 GHz.[13]

Optical rectennas
Main article: Optical rectenna

In principle, similar devices, scaled down to the proportions used in nanotechnology, can be used to convert light directly into electricity. This type of device is called an optical rectenna (or "nantenna").[14][15] Theoretically, high efficiencies can be maintained as the device shrinks, but to date efficiency has been limited, and so far there has not been convincing evidence that rectification has been achieved at optical frequencies. The University of Missouri previously reported on work to develop low-cost, high-efficiency optical-frequency rectennas.[16] Other prototype devices were investigated in a collaboration between the University of Connecticut and Penn State Altoona using a grant from the National Science Foundation.[17] With the use of atomic layer deposition it has been suggested that conversion efficiencies of solar energy to electricity higher than 70% could eventually be achieved.

The creation of successful optical rectenna technology has two major complicating factors:

1. Fabricating an antenna small enough to couple optical wavelengths.

2. Creating an ultra-fast diode capable of rectifying the high frequency oscillations, at frequency of ~500 THz.

Below a are a few examples of potential paths to creating diodes that would be fast enough to rectify optical and near-optical radiation.

Geometric Diodes

A promising path towards creating these ultrafast diodes has been in the form of "geometric diodes".[18] Graphene geometric diodes have been reported to rectify terahertz radiation.[19] In April 2020 geometric diodes were reported in silicon nanowires.[20] The wires were shown experimentally to rectify up to 40 GHz, but that was instrument limited, and theoretically may be able to rectify signals in the THz region as well.

References
  1. Guler, Ulkuhan; Sendi, Mohammad S.E.; Ghovanloo, Maysam (2017). "A dual-mode passive rectifier for wide-range input power flow". 2017 IEEE 60th International Midwest Symposium on Circuits and Systems (MWSCAS). pp. 1376–1379. doi:10.1109/MWSCAS.2017.8053188. ISBN 978-1-5090-6389-5. S2CID 31003912.
  2. US 3434678 Microwave to DC Converter William C. Brown, et al, filed May 5, 1965, granted March 25, 1969
  3. "William C. Brown". Project #07-1726: Cutting the Cord. 2007-2008 Internet Science & Technology Fair, Mainland High School. 2012. Retrieved 2012-03-30.
  4. Torrey, Lee (Jul 10, 1980). "A trap to harness the sun". New Scientist. 87 (1209): 124–127. ISSN 0262-4079. Retrieved 2012-03-30.
  5. Shariati et al.,, Negin (2012). "RF Field Investigation and Maximum Available Power Analysis for Enhanced RF Energy Scavenging". 42nd European Microwave Conference (EuMC), IEEE: 329–332. doi:10.23919/EuMC.2012.6459223.CS1 maint: extra punctuation (link)
  6. Shariati et al.,, Negin (2014). "Highly Sensitive Rectifier for Efficient RF Energy Harvesting". 44th European Microwave Conference (EuMC), IEEE,Rome: 1190–1193. doi:10.1109/EuMC.2014.6986654.CS1 maint: extra punctuation (link)
  7. Shariati et al.,, Negin (2015). "Highly Sensitive FM Frequency Scavenger Integrated in Building Materials". 45th European Microwave Conference (EuMC), IEEE, Paris. doi:10.1109/EuMC.2015.7345701.CS1 maint: extra punctuation (link)
  8. Shariati et al.,, Negin (2015). "Multi- Service Highly Sensitive Rectifier for Enhanced RF Energy Scavenging". Nature Scientific Reports. 5. doi:10.1038/srep09655.CS1 maint: extra punctuation (link)
  9. Shariati et al.,, Negin (2018). "Multitone Excitation Analysis in RF Energy Harvesters—Considerations and Limitations". IEEE Internet of Things Journal: 2804–2816. doi:10.1109/JIOT.2018.2828978. hdl:10453/132255.CS1 maint: extra punctuation (link)
  10. "76.09 — Radio transmitter lights antenna bulb".
  11. "Over to you: Mythical electricity?". The Daily Telegraph. 2004-11-24. Retrieved 2009-06-25.
  12. Zhang, J (2000). Rectennas for RF wireless energy harvesting (PhD Thesis).
  13. McSpadden, J.O., Fan, L., and Kai Chang, “Design and Experiments of a High-Conversion-Efficiency 5.8-GHz Rectenna,” IEEE Trans. Microwave Theory and Technique, Vol 46, No. 12, Dec. 1998, pp. 2053-2060. http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.475.3488&rep=rep1&type=pdf
  14. Asha Sharma, Virendra Singh, Thomas L. Bougher, Baratunde A. Cola (9 October 2015). "A carbon nanotube optical rectenna". Nature Nanotechnology. 10 (12): 1027–1032. Bibcode:2015NatNa..10.1027S. doi:10.1038/nnano.2015.220. PMID 26414198.CS1 maint: uses authors parameter (link)
  15. Patent application WO 2014063149 relates
  16. "New solar technology could break photovoltaic limits" (Press release). University of Missouri. May 16, 2011.
  17. Colin Poitras (February 4, 2013). "UConn Professor's Patented Technique Key to New Solar Power Technology" (Press release).
  18. Zhu, Z (2013). Rectenna Solar Cells. New York: Springer. pp. 209–227.
  19. Zhu, Zixu; Joshi, Saumil; Grover, Sachit; Moddel, Garret (2013-04-15). "Graphene geometric diodes for terahertz rectennas". Journal of Physics D: Applied Physics. 46 (18): 185101. doi:10.1088/0022-3727/46/18/185101. ISSN 0022-3727.
  20. Custer, James P.; Low, Jeremy D.; Hill, David J.; Teitsworth, Taylor S.; Christesen, Joseph D.; McKinney, Collin J.; McBride, James R.; Brooke, Martin A.; Warren, Scott C.; Cahoon, James F. (2020-04-10). "Ratcheting quasi-ballistic electrons in silicon geometric diodes at room temperature". Science. 368 (6487): 177–180. doi:10.1126/science.aay8663. ISSN 0036-8075. PMID 32273466. S2CID 215550903.
  • William C. Brown's Distinguished Career
  • Zhang, Xu; Grajal, Jesús; Vazquez-Roy, Jose Luis; Radhakrishna, Ujwal; Wang, Xiaoxue; Chern, Winston; Zhou, Lin; Lin, Yuxuan; Shen, Pin-Chun; Ji, Xiang; Ling, Xi; Zubair, Ahmad; Zhang, Yuhao; Wang, Han; Dubey, Madan; Kong, Jing; Dresselhaus, Mildred; Palacios, Tomás (2019). "Two-dimensional MoS2-enabled flexible rectenna for Wi-Fi-band wireless energy harvesting". Nature. 566 (7744): 368–372. doi:10.1038/s41586-019-0892-1. PMID 30692651. S2CID 59307657. Lay summary Science Daily (January 28, 2019).
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.