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Journal Antennas №3 for 2016 г.
Article in number:
Features and fundamental benefits of the microwave photonic components to create ultra-wideband radar based on phased array antenna and active phased array antenna
Authors:
N. A. Golov - Assistant, Bauman Moscow State Technical University V. P. Savchenko - Dr.Sc. (Eng.), Deputy Executive Director of Division of JSC "RTI". E-mail: VSavchenko@oaorti.ru V. A. Usachev - Ph.D. (Eng.), Head of Department, Bauman Moscow State Technical University I. A. Sokolov - Ph.D. (Eng.), General Director of AO "NIIMP" (Zelenograd) S. V. Yagolnikov - Dr.Sc. (Eng.), Head of NIC 2 CNII 4
Abstract:
In the article the application features, advantages and characteristics of elements of fiber optics, optoelectronics and integrated optics for use in ultra-wideband radars have been reviewed. It has been noted that adoption of radio photonics technologies and element base into practice of development and creation of ultra-wideband radars based on phased array antennas and active phased array antennas al-lows providing significantly better specifications than when applying traditional solutions.
Pages: 19-25
References

 

  1. Jianping Yao. Microwave photonics // Journal of Lightwave Technology. 2009. V. 27. № 3. P. 314-335.
  2. Ghelfi P., Laghezza F., Scotti F., Onori D., Bogoni A. Photonics for radars operating on multiple coherent bands // Journal of Lightwave Technology. 2015. V. 34. № 2. P. 500-507.
  3. Scotti F., Laghezza F., Ghelfi P., Bogoni A. Multi-band software-defined coherent radar based on a single photonic transceiver // IEEE Trans. on Microwave Theory and Techniques. 2015. V. 63. № 2. P. 546-552.
  4. Laghezza F., Scotti F., Ghelfi P., Bogoni A., Serafino G., Pinna S., Onori D. Aerial field trial of the first photonics-based fully digital radar prototype // Tyrrhenian International Workshop on Digital Communications - Enhanced Surveillance of Aircraft and Vehicles (TIWDC/ESAV). 2014. P. 106-109.
  5. Scotti F., Laghezza F., Bogoni A., Onori D. Photonics-based dual-band radar demonstration for maritime traffic detection // International Topical Meeting on Microwave Photonics (MWP). 2015. P. 1-4.
  6. Ustrojjstva SVCH i antenny. Proektirovanie fazirovannykh antennykh reshetok / pod red. D.I. Voskresenskogo. M.: Radiotekhnika. 2003.
  7. Bratchikov A.N.Optical fibers and antennas // Proc. JINA 98 - 10th International Symposium on Antennas & EESC\'98 - 9th European Electromagnetic Structures Conference. Nov. 1998. Nice, France. P. 275-289.
  8. Dagli N.Wide-bandwidth lasers and modulators // IEEE Trans. on Microwave Theory and Technique. 1999. V. 47. № 7. P. 1151-1171.
  9. Kato K.Ultrawide-band/high-frequency photodetectors // IEEE Trans. on Microwave Theory and Technique. 1999. V. 47. № 7. P. 1265-1281.
  10. Iskander M.F., Zhang Z., Yun Z., et.al. New phase shifters and phased antenna array designs based on ferroelectric materials and CTC technologies // IEEE Trans. on Microwave Theory and Technique. Dec. 2001. V. 49. P. 2547-2553.
  11. Bratchikov A.N. Integralno-opticheskie fazovrashhateli SVCH- i millimetrovogo diapazona // Cb. trudov 15-jj Mezhdunar. Krymskojj konf. «SVCH-tekhnika i telekommunikacionnye tekhnologii» (KryMiKo-2000). Sevastopol. 2000. T. 1. S. 372-374.
  12. Marin V.P, Savchenko V.P., Fedorov V.K., Lucenko A.V. Tekhnologija proizvodstva izdelijj ehlektronnojj tekhniki / pod red. V.PMarina. M.: Radiotekhnika. 2015.