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Abesht, M., Azadi Tinat, N., Oraizi, H. (2020). Design and Simulation of Array Antenna in Ku Band with High Gain and Very Low Sidelobe Level for Space and Radar Applications. Electronic and Cyber Defense, 8(2), 79-88.
Mohammad Abesht; Nima Azadi Tinat; Homayoon Oraizi. "Design and Simulation of Array Antenna in Ku Band with High Gain and Very Low Sidelobe Level for Space and Radar Applications". Electronic and Cyber Defense, 8, 2, 2020, 79-88.
Abesht, M., Azadi Tinat, N., Oraizi, H. (2020). 'Design and Simulation of Array Antenna in Ku Band with High Gain and Very Low Sidelobe Level for Space and Radar Applications', Electronic and Cyber Defense, 8(2), pp. 79-88.
Abesht, M., Azadi Tinat, N., Oraizi, H. Design and Simulation of Array Antenna in Ku Band with High Gain and Very Low Sidelobe Level for Space and Radar Applications. Electronic and Cyber Defense, 2020; 8(2): 79-88.

Design and Simulation of Array Antenna in Ku Band with High Gain and Very Low Sidelobe Level for Space and Radar Applications

رادار
Article 8, Volume 8, Issue 2 - Serial Number 24, February 2021, Pages 79-88    PDF (2.03 M)
Document Type: Original Article
Authors
Mohammad Abesht1; Nima Azadi Tinat* 2; Homayoon Oraizi3
1M.Sc., Shahroud University of Technology, Shahroud, Iran
2Assistant Professor, Department of Telecommunications, Shahroud University, Shahroud, Iran
3Professor, University of Science and Technology, Tehran, Iran
Receive Date: 13 August 2020Revise Date: 14 February 2021Accept Date: 21 February 2021 
Abstract
The purpose of this article is design and development of an aperture coupling microstrip array antenna with high gain, high bandwidth, low side-lobe level. work with optimally design of element started. Then, the complete 512 element array was fed to all the elements by feeding and distributing the same power and gain was obtained over 30 dB. To reduce the side-lobe level, the feed network is designed with Taylor distribution so that the specific range required for each element, which is different from the other elements, is obtained and also, all elements of the array are fed in phase. The elements that are in the middle of the array receive the most power and the elements that are in the besides of the array receive the least power. This structure is designed with 512 elements in an array of 32 × 16, and the operating frequency of the antenna is 12.5 to 14.9 GHz, equivalent to 17% of bandwidth in the Ku band. The gain of this antenna is 29 dB and gain variations over the entire frequency range is low, which is desirable and the side-lobe level also varies between -22 dB and -29 dB on both of the E-plane and H-plane. Finally, a metal reflector plate was used to lower the Backlobe level, reaching F/B levels above 35 dB. The overall dimensions of the antenna are 576 mm × 288 mm.
Keywords
Antenna array; Radar; Wideband; High Gain; Sidelobe Level; Nonuniform Distribution
References

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