The present invention discloses a method for regional attenuation correction of weather radar using a distributed microwave-links network. The present invention relates to the field of measuring rainfall by weather radar.
The attenuation of precipitation on the propagation of electromagnetic waves is one of the main factors that affect the quantitative precipitation estimation (QPE) by weather radar. The attenuation effect will cause a decrease in radar echo intensity and detection area. In particular, at relatively far distances, radar reflectivity factors are lower than actual values, and cannot reflect the actual distribution of rainfall. The quantitative precipitation estimation (QPE) by weather radar is still a problem due to the attenuation. In some weather radar applications, researchers desire to measure the actual attenuation along the propagation path to improve the effect of attenuation correction.
A new approach for rainfall measurement was recently presented using the attenuation of microwave links caused by rainfall. There are several cellular communication systems, microwave relay communication systems in the scanning area of weather radar, and the microwave propagation attenuation can be obtained by detecting the receive signal level (RSL) from the transmitter and receiver of a microwave link. During a rainfall event, the microwave is attenuated by falling raindrops when passing through the rain area. The microwave attenuation can be calculated by measuring the difference between clear and rainy days, the path integrated attenuation (PIA) of a single microwave link can be used to correct the attenuation of radar echo along the microwave path. Multiple microwave links can form a microwave links network with a certain topological structure, the area of network can be convert to the discrete grids, and the attenuation in each grid can be obtained by the computerized tomography (CT) imaging technology, based on which the attenuation of radar echo in the corresponding area can be corrected.
In the practical application, both the existing commercial microwave links in communication networks and building additional microwave links systems can be used to reginal attenuation correction of weather radar.
The object of the present invention is to provide a method for regional attenuation correction of weather radar by using a multiple microwave links network based on the tomographic reconstruction of attenuation coefficients, inversion techniques and attenuation correction modeling.
Particularly, the present invention provides a method for attenuation correction of weather radar comprising:
1. The attenuation A of microwave with a certain frequency band in a rainfall event can be obtained by the difference between clear day and rainy day:
A=T−T
wet (1)
where T is the total attenuation in the path, and Twet is the attenuation reference during the rain.
2. Constructing a joint observation network of microwave links and weather radar data as shown in
3. Based on the rain attenuation of the microwave links network, a joint iterative reconstruction algorithm is used to obtain the rain attenuation coefficient Kj of each grid.
1) Assuming the length of ith link is Li, the attenuation induced by rain is Ai
Assuming the number of grids after discretization is N, the rain attenuation of the ith microwave link can be expressed as
where lij is the length of the ith microwave link that passes through the jth grid; the unit of Kj is (dB/km).
The rain attenuation of the M microwave links can be expressed in vector form:
LK=A (4)
where A=(Ai)M×1 is the total attenuation column vector; L=(lij)M×N is the distance matrix; K=(kj)N×1 is the attenuation coefficient column vector.
2) The solution of K can be convert to the equation (4) as follows:
To minimize the error of Eq. (5), take the Simultaneous Iterative Reconstruction Technique (SIRT) for example to construct the cost function using the least-square criterion. The objective function was minimized by repeated iterations, and the optimal solution was obtained:
J(K)=(A−LK)T(A−LK)=min! (6)
To obtain the minimum cost function,
L
T
A=L
T
LK (7)
the iterative formula needed to solve Eq. (5) can be written as
4. The process of the corrected radar reflectivity factor is shown in
where dij is the length of the ith link between the radar and the grid through the jth grid.
5. The corrected radar reflectivity factor zij can be calculated by summing the radar-measured reflectivity factor zm
z
ij
=z
m
+2*Attij (10)
Various objects, features, and advantages of the present invention can be fully appreciated with reference to the following detailed description of the invention when considered in connection with the following drawings, in which like reference numerals identify like elements.
As shown in
1. Measure the attenuation of the microwave link in the specific frequency.
In the attenuation correction method based on the microwave link, the path integral attenuation value can be obtained by the measurement of single frequency, dual frequency and multi-frequency links, which typically select the same or similar frequency as radar in single-frequency links, and in dual-frequency or multi-frequency microwave links select one of the frequency is the same or similar as radar, others are generally selected to meet the attenuated pairs of values of both link frequencies are highly correlated during the rain.
The detail process is:
A=T−T
wet (1)
2. Constructing a joint observation network of microwave links and weather radar data as shown in
3. The attenuation due to the rain in each grid Kj are obtained as follows.
1) Assuming the length of ith link is Li, the attenuation induced by rain is Ai
Assuming the number of grids after discretization is N, the rain attenuation of the ith microwave link can be expressed as
where lij is the length of the ith microwave link that passes through the jth grid; the unit of Kj is (dB/km), and i=1 . . . M (M is the total number of microwave links).
The rain attenuation of the M microwave links can be expressed in vector form:
LK=A (4)
where A=(Ai)M×1 is the total attenuation column vector; L=(lij)M×N is the distance matrix; K=(kj)N×1 is the attenuation coefficient column vector.
2) The solution of K can be convert to the equation (4) as follows:
To minimize the error of Eq. (5), take the Simultaneous Iterative Reconstruction Technique (SIRT) for example to construct the cost function using the least-square criterion. The objective function was minimized by repeated iterations, and the optimal solution was obtained:
J(K)=(A−LK)T(A−LK)=min! (6)
To obtain the minimum cost function,
L
T
A=L
T
LK (7)
the iterative formula needed to solve Eq. (5) can be written as
4. Assuming that there are X lines between each grid point and the radar, we can substitute the attenuation coefficients obtained from Eq. (6) into Eq. (9). Then, we can get the path attenuation of the ith link between the radar and each grid point:
where dij is the length of the ith link between the radar and the grid point through the jth grid.
5. The corrected radar reflectivity factor zij can be calculated by summing the radar-measured reflectivity factor zm
z
ij
=z
m
+2×Attij. (10)
The derivation process are as follows.
1) the relationship between radar measured reflectivity factor Zm (mm6/m3) and the true reflectivity factor Zr (mm6/m3) is
where r is the distance between target and radar, K is the attenuation factor, k is the attenuation coefficient (dB/km).
z=10 log Z (12)
where the unit of z is dB, the unit of Z is mm6/m3.
2) Eq. (11) can be convert in the unit of dB as follows.
z
r(r)=zm(r)+2∫0Rkdr (13)
where the second item in right side of equation (13) is the path integrated attenuation of radar.
Number | Date | Country | Kind |
---|---|---|---|
201610951079.5 | Nov 2016 | CN | national |