Interpretation of VHF radar echoes from a complex flow field

M. L. Heron; M. O'Shea; J. Murphy; L. Petersen; D. Mollaghan; A. Prytz

Interpretation of VHF radar echoes from a complex flow field

M. L. Heron
, M. O'Shea
, J. Murphy
, L. Petersen
, D. Mollaghan
, A. Prytz

Research output: Contribution to conference › Paper › peer-review

Abstract

Bragg lines on spectra from ocean radar systems are broadened when echoes come into the antenna from different azimuths. Phased-array systems minimise the effects of this by selecting a small target area on the sea surface by beam-forming and range-gating. While phased array systems are better conditioned for high spatial resolution than direction finding systems, in some cases there may be fine structure in the surface current field within the smallest of target areas. In estuaries or other areas where there are sand banks and low islands there is potential for contamination from side-lobes of phased array antennas to contaminate adjacent pixels. This paper uses data from an area of highly complex flow field in Dingle Bay, Ireland to examine the complex structure of Bragg echoes. A numerical hydrodynamic model is used as an aid in understanding the degree of structure to be expected in the Bragg lines, and an improved analysis is described to extract surface current data from the radar echoes.

Original language	English
Publication status	Published - 2013
Event	OCEANS 2013 MTS/IEEE San Diego Conference: An Ocean in Common - San Diego, CA, United States Duration: 23 Sep 2013 → 26 Sep 2013

Conference

Conference	OCEANS 2013 MTS/IEEE San Diego Conference: An Ocean in Common
Country/Territory	United States
City	San Diego, CA
Period	23/09/13 → 26/09/13

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 14 Life Below Water

Keywords

Current monitoring
Estuaries
HF ocean radar

Cite this

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title = "Interpretation of VHF radar echoes from a complex flow field",

abstract = "Bragg lines on spectra from ocean radar systems are broadened when echoes come into the antenna from different azimuths. Phased-array systems minimise the effects of this by selecting a small target area on the sea surface by beam-forming and range-gating. While phased array systems are better conditioned for high spatial resolution than direction finding systems, in some cases there may be fine structure in the surface current field within the smallest of target areas. In estuaries or other areas where there are sand banks and low islands there is potential for contamination from side-lobes of phased array antennas to contaminate adjacent pixels. This paper uses data from an area of highly complex flow field in Dingle Bay, Ireland to examine the complex structure of Bragg echoes. A numerical hydrodynamic model is used as an aid in understanding the degree of structure to be expected in the Bragg lines, and an improved analysis is described to extract surface current data from the radar echoes.",

keywords = "Current monitoring, Estuaries, HF ocean radar",

author = "Heron, \{M. L.\} and M. O'Shea and J. Murphy and L. Petersen and D. Mollaghan and A. Prytz",

year = "2013",

language = "English",

note = "OCEANS 2013 MTS/IEEE San Diego Conference: An Ocean in Common ; Conference date: 23-09-2013 Through 26-09-2013",

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TY - CONF

T1 - Interpretation of VHF radar echoes from a complex flow field

AU - Heron, M. L.

AU - O'Shea, M.

AU - Murphy, J.

AU - Petersen, L.

AU - Mollaghan, D.

AU - Prytz, A.

PY - 2013

Y1 - 2013

N2 - Bragg lines on spectra from ocean radar systems are broadened when echoes come into the antenna from different azimuths. Phased-array systems minimise the effects of this by selecting a small target area on the sea surface by beam-forming and range-gating. While phased array systems are better conditioned for high spatial resolution than direction finding systems, in some cases there may be fine structure in the surface current field within the smallest of target areas. In estuaries or other areas where there are sand banks and low islands there is potential for contamination from side-lobes of phased array antennas to contaminate adjacent pixels. This paper uses data from an area of highly complex flow field in Dingle Bay, Ireland to examine the complex structure of Bragg echoes. A numerical hydrodynamic model is used as an aid in understanding the degree of structure to be expected in the Bragg lines, and an improved analysis is described to extract surface current data from the radar echoes.

AB - Bragg lines on spectra from ocean radar systems are broadened when echoes come into the antenna from different azimuths. Phased-array systems minimise the effects of this by selecting a small target area on the sea surface by beam-forming and range-gating. While phased array systems are better conditioned for high spatial resolution than direction finding systems, in some cases there may be fine structure in the surface current field within the smallest of target areas. In estuaries or other areas where there are sand banks and low islands there is potential for contamination from side-lobes of phased array antennas to contaminate adjacent pixels. This paper uses data from an area of highly complex flow field in Dingle Bay, Ireland to examine the complex structure of Bragg echoes. A numerical hydrodynamic model is used as an aid in understanding the degree of structure to be expected in the Bragg lines, and an improved analysis is described to extract surface current data from the radar echoes.

KW - Current monitoring

KW - Estuaries

KW - HF ocean radar

UR - https://www.scopus.com/pages/publications/84896387264

M3 - Paper

AN - SCOPUS:84896387264

T2 - OCEANS 2013 MTS/IEEE San Diego Conference: An Ocean in Common

Y2 - 23 September 2013 through 26 September 2013

ER -

Interpretation of VHF radar echoes from a complex flow field

Abstract

Conference

UN SDGs

Keywords

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