Role of radar in microwaves

Skolnik, Merrill I.

doi:10.1109/22.989947

Cited by 105 publications

(38 citation statements)

References 20 publications

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“…In addition, microwave and mm-wave signals generated in the optical domain are ready to be distributed to a remote site using the state-of-the-art radio over fiber technology without the need of additional electrical to optical conversion. On the other hand, it is also desirable to generate microwave and mm-wave signals that are frequency chirped or phase-coded for applications such as in modern radar systems, to achieve pulse compression with an increased range resolution [2]. Chirped or phase-coded signals can be generated in the electrical domain using either analog or digital electronics, but the operating frequency is usually limited to several GHz.…”

Section: Introductionmentioning

confidence: 99%

Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator

Chi

Yao

2008

IEEE Microw. Wireless Compon. Lett.

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A novel approach to generating phase-coded millimeter-wave (mm-wave) signal in the optical domain is proposed. In the proposed system, a radio frequency signal is applied to a Mach-Zehnder modulator that is biased at the minimum transmission point to generate two optical sidebands with suppressed carrier. A differential group delay device is utilized to rotate the polarization states of the optical sidebands to ensure they are orthogonally polarized. The two sidebands are then sent to a polarization modulator (PolM), with their polarization directions aligned with the two principal axes of the PolM, to achieve phase coding. A 33-GHz mm-wave signal that is phase coded by an 8.28 Gb/s digital sequence is experimentally demonstrated. The approach has potential applications in mm-wave pulse compression radar and wireless communications.

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Section: Introductionmentioning

confidence: 99%

Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator

Chi

Yao

2008

IEEE Microw. Wireless Compon. Lett.

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“…Many historical accounts regard a superior, high power radar technology as a significant, if not decisive military advantage for Britain during World War II. [5][6][7] In particular, the radar systems of Britain and the U.S. were characterized by superior, high power microwave cavity magnetrons, based on the successful prototype developed by Boot and Randall in 1940. 8 In the ensuing seven decades, continued increases in microwave generator power and frequency have driven a large fraction of the advances in defense, commercial industry, and science.…”

Section: Introductionmentioning

confidence: 99%

Plasma physics and related challenges of millimeter-wave-to-terahertz and high power microwave generation

2008

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Homeland security and military defense technology considerations have stimulated intense interest in mobile, high power sources of millimeter-wave (mmw) to terahertz (THz) regime electromagnetic radiation, from 0.1 to 10THz. While vacuum electronic sources are a natural choice for high power, the challenges have yet to be completely met for applications including noninvasive sensing of concealed weapons and dangerous agents, high-data-rate communications, high resolution radar, next generation acceleration drivers, and analysis of fluids and condensed matter. The compact size requirements for many of these high frequency sources require miniscule, microfabricated slow wave circuits. This necessitates electron beams with tiny transverse dimensions and potentially very high current densities for adequate gain. Thus, an emerging family of microfabricated, vacuum electronic devices share many of the same plasma physics challenges that are currently confronting “classic” high power microwave (HPM) generators including long-life bright electron beam sources, intense beam transport, parasitic mode excitation, energetic electron interaction with surfaces, and rf air breakdown at output windows. The contemporary plasma physics and other related issues of compact, high power mmw-to-THz sources are compared and contrasted to those of HPM generation, and future research challenges and opportunities are discussed.

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“…In typical conical scan radar, a single parabolic dish is used. There are two servo motors used, one for elevation and the other one for azimuth [1][2][3]. We use a conical scan beam for target tracking.…”

Section: Introductionmentioning

confidence: 99%

A Novel Implementation Technique of Conical Scan Radar Using A Programmable Phased Array

Alfred

Chakravarty

Singh

et al. 2007

Int J Infrared Milli Waves

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In radar, planar phased array antenna plays vital role in electronic scanning in the azimuth and elevation direction to the horizon. In most operations using planar phased array both the coordinates of azimuth and elevation, are steered electronically. In this paper a conceptual schematic of a phased array antenna with programmable time delay units has been presented. It is shown that by suitably exploiting the time delay matrix one can have electronic beam rotation around the target axis as required in conical scan. Thus both the elevation and azimuth motors in conical scan system are replaced by electronic scanning. Heuristically, we have selected eight consecutive points for beam rotation in a polygon shape and can also be extended almost circular shape by increasing number of array elements and phase shifter (delays) in the delay matrix. The array requires dual control of phase gradient and individual phase values. The whole array is controlled by microcontroller. This presents exciting possibilities in radar operation.

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Role of radar in microwaves

Cited by 105 publications

References 20 publications

Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator

Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator

Plasma physics and related challenges of millimeter-wave-to-terahertz and high power microwave generation

A Novel Implementation Technique of Conical Scan Radar Using A Programmable Phased Array

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