One of the fundamental objectives of meteorological radar systems is to sample the atmosphere surrounding the Earth to provide a quantitative measure of precipitation. Conventional meteorological radars provide coverage over long ranges, often on the order of hundreds of kilometers. A general schematic of how such conventional radar systems function is provided in
Embodiments of the invention improve the sensitivity of polarimetric radar data. This can be done during post processing or in real time during data collection. The sensitivity can be improved by calculating the reflectivity from a co-polar element (off-diagonal element) of the polarimetric covariance matrix, where the polarimetric covariance matrix is calculated from the complex antenna voltages projected in the horizontal and vertical polarization states.
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Embodiments of the invention improve the sensitivity of polarimetric radar data. In particular, embodiments of the invention improve the sensitivity of such systems with improved post processing techniques. This can be done using a co-polar element (off-diagonal element) of the covariance matrix to estimate the power and/or reflectivity of a region of interest. Such practices can also enhance echo identification and improve quantitative estimates of precipitation. Some embodiments of the invention have shown signal improvements by at least 3 dB.
Embodiments of the invention can be implemented in a number of ways. For instance, embodiments of the invention can be used in real-time with a polarimetric radar system or during post processing on previously collected polarimetric radar I/Q data. Embodiments of the invention can be implemented by software.
Radar interface 250 is coupled with bus 226. In some embodiments, radar interface 250 can be any type of communication interface. For example, radar interface 250 can be a USB interface, UART interface, serial interface, parallel interface, etc. Radar interface 250 can be configured to couple directly with any type of radar system such as a dual polarization radar system.
The computer system 200 also comprises software elements, shown as being currently located within working memory 220, including an operating system 224 and other code 222, such as a program designed to implement methods and/or processes described herein. In some embodiments, other code 222 can include software that provides instructions for receiving dual polarization radar data and manipulating the data according to various embodiments disclosed herein. In some embodiments, other code 222 can include software that can predict or forecast weather events, and/or provide real time weather reporting and/or warnings. Variations can be used in accordance with specific requirements. For example, customized hardware might also be used and/or particular elements might be implemented in hardware, software (including portable software, such as applets), or both. Further, connection to other computing devices such as network input/output devices can be employed.
Embodiments of the invention can be used to estimate the precipitation echo power and/or the reflectivity of a region of interest from dual polarization radar data using the off-diagonal elements of the polarimetric covariance matrix.
The reflectivity, for example, can be estimated using the co-polar covariance elements at block 316. For example, the reflectivity can be estimated using
where Ch and Gdr, are the radar system calibration constant and differential gains between the two polarization channels, and |{circumflex over (R)}hv| represents the off-diagonal co-polar covariance element at range r.
In a dual polarization radar system, the H and V signals are highly correlated in precipitation echo. Because of this high degree of correlation, {circumflex over (ρ)}co, the absolute value (e.g., modulus) of co-polar covariance element, Rhv, becomes the logarithmic (geometric) mean of the echo powers in horizontal and vertical polarization,
where Ph=|Vh|2 and Pv=Vv|2 define the echo powers in each polarization. At the limit of high ρHV(0), the finitely sampled ray estimator |{circumflex over (R)}hv| can be unbiased.
The mean power, Ph, of the echo signal received in a single polarization of a pulsed weather radar is typically obtained by averaging echo power samples, based on
P
h
=
|V
h|2
where h refers to the antenna voltages in a definite polarization—typically the horizontal polarization. The mean echo power is related to the radar reflectivity ηh, which is defined as the average radar cross section of distributed targets in a unit volume of observation:
where Shh is the horizontal back-scattering cross-section element of a scatterer in the volume. The relation of mean echo power and ηh can be
Ph=Chηh/r2
where Ch combines the radar system specific constant features. The dependence on the range of observation (r) includes geometric factors only.
In the context of a dual polarization radar, a signal vector is returned that includes the complex antenna voltages projected in the horizontal, Vh, and vertical, Vv, polarization states.
is the nth signal sample vector at gate m in a dual polarization radar. Instead of signal power, the signal now expands into the covariance matrix, R, which has the expectation value
Generally, Rhv=Rhv* applies. Using Rhh=Ph=|H|2 and Rvv=Pv=|V|2, the single polarization radar reflectivity ηh can be expanded into a pair of radar reflectivities (ηh, ηv), defined in the horizontal and vertical polarizations
Rhh=Chηh/r2
Rvv=ChGdrηv/r2
in which the common features of the radar calibration constant Ch are reused in the vertical polarization. The adjustment factor Gdr, accounts for the differential signal gains between the channels H and V. The system adjusted ratio
can define the differential reflectivity, which can be sensitive to the effective horizontal vs. vertical axis ratios of the back scatterers.
The absolute value (modulus) of the co-polar covariance element |Rhv| also relates to the radar reflectivities in the horizontal and vertical polarizations, too. In particular their geometric mean can be given by
|Rhv|=Ch(Gdr)1/2(ηhηv)1/2/r2.
The voltages from a dual polarization radar can include four significant terms: the horizontal signal H and the noise nh*, and the vertical signal V and the noise nv. The co-polar covariance element Rhv can be useful because these noise terms are uncorrelated. The co-polar covariance element can then be determined from
The cross diagonal elements do not contain noise terms. The following properties of white noise expectation values have been utilized
n
h
n
v
*
=
n
v
n
h*=0
n
h
n
h
*
\=P
h
N
n
v
n
v
*
=P
v
N
Rhhs, Rvvs, and Rhvs refer to elements obtained from signal alone.
As shown above, the co-polar covariance element Rhv are not affected by white noise. This is in contrast to the legacy power estimator Ph that includes noise. Moreover, these are biased when the noise is significant with respect to the signal. The embodiments of the invention, therefore, use the off-diagonal element of the covariance matrix Rhv to calculate the reflectivity. Because noise is not present, the results show improved sensitivity. Given any signal, |Rhv| appears insensitive to white noise.
In precipitation where PH and PV are highly correlated in range, shown by smooth co-polar correlation data, adjacent range gates I/Q data, M, from same pulse sample may be summed leading to
The co-polar covariance element can be estimated through a sequence of N pulses at mth range index location
One advantage of the estimator {circumflex over (R)}hv(m) is that it can be summed through local gates providing additional averaging, further reducing the apparent finite noise floor of {circumflex over (R)}hv.
The estimator value,
This estimator,
FIG. 5—compares the reflectivity derived from {circumflex over (R)}hh and {circumflex over (R)}hv based echo power estimators from radar observations and the corresponding expected noise thresholds. The dashed lines are the expected noise floor for the current state of art {circumflex over (R)}hh and {circumflex over (R)}hv using N samples and m range gates. The sensitivity increase of |{circumflex over (R)}hv| reflectivity is apparent.