Experiments on Bragg and non‐Bragg scattering using single‐frequency and chirped radars

Lee, P. H. Y.; Barter, J. D.; Beach, Kory; Hindman, C. L.; Lake, Bruce M.; Rungaldier, H.; Thompson, H.R.; Yee, Richard W.

doi:10.1029/97rs01399

Cited by 28 publications

(14 citation statements)

References 26 publications

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“…The experimental facility, the X-band pulsechirped radar (PCR) that was used as the principal instrument in this experiment, the operating modes of the PCR, and the gate numbering correspondence to the PCR line-of-sight range have been described elsewhere [Lee et al, 1997a]. The optical specular event detector (OSED) [Barter and Lee, 1996] is an imaging detector at visible wavelengths which measures two-dimensionally resolved plane polarized returns.…”

Section: Introductionmentioning

confidence: 99%

What are the mechanisms for non‐Bragg scattering from water wave surfaces?

Lee¹,

Barter²,

Beach³

et al. 1999

Radio Science

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Abstract. Experimental data obtained in the past several years have provided conclusive evidence that non-Bragg scattering plays a major role in X-band microwave backscatter from water wave surfaces, and non-Bragg scattering events are especially noticeable at small grazing angles, for wind-roughened surfaces, in the presence of breaking waves. We have conducted scattering experiments under a variety of wind wave conditions in an attempt to determine the different mechanisms which contribute to non-Bragg scattering. At small grazing angles we find that non-Bragg scattering is due to fast scatterers generated by the wave breaking, and with increasing wave steepness and surface roughness, mechanisms of multiple scattering and multipath interference become increasingly important. -1 m) and the temporal radar backscatter was correlated with video images. They observed single-bounce backscatter from specular facets and gave quantitative results of the measured distribution of facet size. Closer scrutiny of their data reveals that the specular reflection they observed was not due to fast scatterers but rather to the slowest scatterers and was due to backscatter from the smoother patches in the troughs of larger waves. However, the notion of "specular reflection," which produces signals with HH = VV, was quickly adopted by theoreticians and modelers, and it was assumed that single-bounce reflection from specular facets was 123

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Section: Introductionmentioning

confidence: 99%

What are the mechanisms for non‐Bragg scattering from water wave surfaces?

Lee¹,

Barter²,

Beach³

et al. 1999

Radio Science

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“…Many experimental studies report that at low grazing angles, pulsed enhancements appear mostly at horizontal polarization [Kalmykov and Pustovoytenko, 1976;Trizna et al, 1991;McLaughlin et al, 1995;Lee et al, 1995Lee et al, , 1997. These enhancements, known as ''sea-spikes,'' are observed within a narrow polar diagram, which produces the spikes, and in narrow space-time bands.…”

Section: Introductionmentioning

confidence: 99%

Crosswind ocean radar backscatter and two‐scale scattering model at low grazing angles

2003

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[1] A two-scale model of rough surface in a crosswind ocean radar illumination is considered. Model characteristics such as polarization and azimuthal dependence are illustrated through numerical calculations. Predictions of the model are compared with rare field measurements made in a crosswind environment. Measurements were obtained at a 2°grazing angle. These data, collected by X-and Ka-band (9.3 and 34.6 GHz) radars under crosswind during the 1995 Coastal Ocean Probing Experiment (COPE) off the Oregon Coast, indicate that the backscatter intensity of local ''seaspikes'' measured with horizontal transmit-and-receive polarization (HH) reaches or exceeds that measured with the vertical transmit-and-receive polarization (VV). We suggest that for low grazing angles and in a crosswind environment, a radar geometrical condition can occur where some HH-spikes can be dominated by vertically polarized scattered radiation due to cross tilt of a long wave, when its local slope becomes greater than 45°.INDEX TERMS: 6959 Radio Science: Radio oceanography; 6969 Radio Science: Remote sensing; 4506 Oceanography: Physical: Capillary waves; 4504 Oceanography: Physical: Air/sea interactions (0312); KEYWORDS: radio oceanography, remote sensing, electromagnetic theory, capillary waves, air/sea interactions Citation: Smirnov, A. V., I. M. Fuks, and K. A. Naugonykh, Crosswind ocean radar backscatter and two-scale scattering model at low grazing angles,

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“…In addition the maximum of the Doppler spectra (power New experimental results obtained during the early to mid 90's sparked a renewed interest in appropriate scattering models to interpret polarized radar data. For example, experimental observations with the TRW X-band radar mounted on the bow of a boat in a Loch Lihnne experiment [Lee et al, 1995[Lee et al, , 1996 as well as complementary laboratory experiments [Lee et al, 1997a[Lee et al, , 1997b showed that for low grazing angles the horizontal returns could be larger than the vertical returns. Further, the regions where these events or spikes (HH/W >1) occurred were of an intermittent nature and the result of very low scattering returns, of the order of -60 to -100 dB range (See Figure 2 below).…”

Section: Problemmentioning

confidence: 99%

“…Indeed, the power spectrum of the polarized backscattered returns, also known as the Doppler spectrum, is routinely used in experiments for diagnostic and analysis of the distribution and speed of the scatterers on the moving surface, cf. [Lee et al, 1997a;Rozenberg et al, 1996;Lee et al, 1996;Lee et al, 1997b;Lee et al, 1995;Ja et al, 2001;Duncan et al, 1999]. …”

Section: Modeling Of Doppler Spectrummentioning

confidence: 99%

Electromagnetic Scattering from Multiple Scale Geometries

Caponi¹,

Sei²

2002

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Experiments on Bragg and non‐Bragg scattering using single‐frequency and chirped radars

Cited by 28 publications

References 26 publications

What are the mechanisms for non‐Bragg scattering from water wave surfaces?

What are the mechanisms for non‐Bragg scattering from water wave surfaces?

Crosswind ocean radar backscatter and two‐scale scattering model at low grazing angles

Electromagnetic Scattering from Multiple Scale Geometries

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