Quantifying Errors due to Frequency Changes and Target Location Uncertainty for Radar Refractivity Retrievals

Author:

Nicol J. C.1,Illingworth A. J.2,Darlington T.3,Kitchen M.3

Affiliation:

1. National Centre for Atmospheric Science, University of Reading, Reading, United Kingdom

2. University of Reading, Reading, United Kingdom

3. Met Office, Exeter, United Kingdom

Abstract

Abstract Radar refractivity retrievals can capture near-surface humidity changes, but noisy phase changes of the ground clutter returns limit the accuracy for both klystron- and magnetron-based systems. Observations with a C-band (5.6 cm) magnetron weather radar indicate that the correction for phase changes introduced by local oscillator frequency changes leads to refractivity errors no larger than 0.25 N units: equivalent to a relative humidity change of only 0.25% at 20°C. Requested stable local oscillator (STALO) frequency changes were accurate to 0.002 ppm based on laboratory measurements. More serious are the random phase change errors introduced when targets are not at the range-gate center and there are changes in the transmitter frequency (ΔfTx) or the refractivity (ΔN). Observations at C band with a 2-μs pulse show an additional 66° of phase change noise for a ΔfTx of 190 kHz (34 ppm); this allows the effect due to ΔN to be predicted. Even at S band with klystron transmitters, significant phase change noise should occur when a large ΔN develops relative to the reference period [e.g., ~55° when ΔN = 60 for the Next Generation Weather Radar (NEXRAD) radars]. At shorter wavelengths (e.g., C and X band) and with magnetron transmitters in particular, refractivity retrievals relative to an earlier reference period are even more difficult, and operational retrievals may be restricted to changes over shorter (e.g., hourly) periods of time. Target location errors can be reduced by using a shorter pulse or identified by a new technique making alternate measurements at two closely spaced frequencies, which could even be achieved with a dual–pulse repetition frequency (PRF) operation of a magnetron transmitter.

Publisher

American Meteorological Society

Subject

Atmospheric Science,Ocean Engineering

Reference25 articles.

1. Bartholomew, K. , 2012: Assessing the potential of radar refractivity retrievals for improved high resolution weather prediction. Ph.D. thesis, University of Reading, Reading, United Kingdom, 178 pp.

2. Understanding radar refractivity: Sources of uncertainty;Bodine;J. Appl. Meteor. Climatol.,2011

3. Refractivity retrieval using a phased array radar: First results and potential for multi-function operation;Cheong;IEEE Trans. Geosci. Remote Sens.,2008

4. Darlington, T. , cited 2010: Weather radar signal processing. U.S. patent number 20100052976. [Available online at http://www.freepatentsonline.com/y2010/0052976.html.]

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