The present Application is based on International Application No. PCT/EP2006/062621, filed May 24, 2006 which in turn corresponds to France Application No. 05 05211, filed on May 24, 2005, and priority is hereby claimed under 35 USC §119 based on these applications. Each of these applications are hereby incorporated by reference in their entirety into the present application.
The invention relates to a method for beam formation by calculation. In particular, the invention is applicable to the compensation for the effects of failures of one or more active modules distributed over an antenna of a radar with electronic scanning. The method according to the invention can notably be implemented within an airborne weather radar.
An antenna with electronic scanning can comprise a large number of active modules. Accordingly, in order to optimize the availability of a radar comprising an antenna with electronic scanning, the impact of the failure of one or more active modules on the main functions of the radar must be limited. It is thus desirable that the loss of several active modules does not compromise the receiving function of the radar in order to reach an optimum level of service. These constraints are justified notably when such a radar is used for applications requiring a high level of security and reliability of operation such as that required, for example, in the case of an airborne radar on a commercial aircraft, for example of the weather radar type.
In the case of a radar whose beam is formed by calculation, the full set of samples coming from the active modules is used in reception. When an active module is defective due to a malfunction or fault, the samples can no longer be employed for the formation of the beam without significantly degrading the reception performance of the radar. The tolerance to these failures of active modules can notably be improved by using interpolation methods for the spatial samples missing due to failures. The radar beam is then formed by calculation using the interpolations as if they were real samples.
For this purpose, there exist linear prediction methods which, by means of the valid samples coming from the active modules in nominal operation, allow the complete signal as it is received by the radar to be decomposed into a sum of sinusoidal signals with amplitudes and frequencies that said methods seek to estimate. Aside from the discrete Fourrier transform, which does not directly provide this decomposition, the other linear interpolation techniques require the estimation of covariance matrices. These adaptive techniques may be readily applied to antennas whose active modules are uniformly distributed over the surface of the antenna.
However, the estimation of covariance matrices is complex and imprecise on an antenna whose active modules are distributed according to a non-constant distribution law over the surface of the antenna. The linear prediction methods are therefore maladapted to this type of antenna due to their complexity and their cost.
The invention aims notably to overcome the aforementioned drawbacks. For this purpose, the subject of the invention is a method for formation by calculation of a beam whose main lobe of a microwave signal is oriented in a direction Uzf pointed to by a scanning antenna comprising active modules, the scanning being effected in one or more planes. The active modules are identified by a rank i and by coordinates in a reference base forming a plane within which the active modules of the antenna are substantially included. For each defective active module of rank ip, the missing samples of the microwave signal a(îp) are calculated by one or more non-adaptive interpolations using the samples coming from the active modules in nominal operating mode situated in the neighborhood of the defective active modules. The beam is formed as if the interpolated samples a(îp) were the real measurements.
In another embodiment, the active modules of a scanning antenna in a plane are arranged in rows and have as coordinates a position along an axis perpendicular to the rows of active modules of the antenna. The active modules deliver, after sampling, samples a(i). The samples of the missing microwave signal a(îp) are defined according to the following formula:
The non-adaptive interpolation step can, for example, comprise the following steps:
In another embodiment, the active modules of a scanning antenna in a plane are arranged in rows and have as coordinates a position (z(i)) along an axis perpendicular to the rows of active modules of the antenna. The active modules deliver, after sampling, samples a(i). The samples of the missing microwave signal a(îp) are defined, for a particular direction Uz1, according to the following formula:
The method according to the invention can notably comprise the following steps:
The active modules can for example be distributed according to a non-constant distribution law over the surface of the antenna.
The method according to the invention may notably be applied to a radar designed for the detection and localization of weather phenomena.
The invention presents notably the advantage that the additional cost in computation power resulting from the invention is very low compared to that required by a channel formation without compensation.
Other features and advantages of the invention will become apparent with the aid of the description that follows with regard to the appended drawings which show:
The antenna with electronic scanning illustrated in
The distance between two rows 1 that are consecutive along the axis OZ is not necessarily constant nor regular.
The operation described in the following corresponds to the case of a calibrated radar, in other words whose response in phase and in amplitude of all the elements is the same or only depends on the difference in step due to the distribution of the active modules 2. Moreover, the individual diagram, denoted g({right arrow over (U)}), of the active modules 2 is identical.
When the radar receives a signal of wavelength λ and of power flux Φ coming from a direction
identified by its direction cosines (Uy, Yz), a voltage a(i) is created by this signal at the output of each row 1 of rank i. The voltage a(i) is proportional to
A weighting denoted W(i) is assigned to each row 1 of rank i. The direction of formation of the main lobe oriented toward the targeted direction is denoted Uzf. When the operation of the radar is nominal, in other words there are no defective active modules, the signal received by the radar corresponding to the contribution of all of the rows 1 is equal to:
The method according to the invention additionally comprises the step 101 for linear interpolation of missing spatial samples. The linearity of the interpolation step 101 according to the invention allows other spectral analysis methods to be used downstream. The failure of at least one active module 2 of a row 1 leads to the loss of one sample a(îp). An estimation of this sample a(îp) can be calculated using the samples from its neighborhood by a linear operation. Thus, it can be written that:
In the case where there is only one defective signal source, the series of received signals a(i) corresponds to the sampling, possibly irregular, of a spatial sinusoid according to the points z(i). The spatial frequency of this sinusoid is given by the term Uz/λ. To within the noise which is assumed to be independent from one source to another, the samples a(i) are disposed on a circle in the complex plane.
According to the method according to the invention, the missing samples are estimated by linear interpolation in a non-adaptive fashion, in other words where their interpolation does not depend on the variation of the received samples over time. The modulus of the radar signal is denoted A whereas the thermal noise relating to one row 1 of rank i is denoted b(i). One step of the method according to the invention amounts to recovering the missing sample
with the knowledge of the samples adjacent to the defective one equal to
The missing sample can notably be calculated in step 101 by a single linear interpolation of the method according to the invention with the following formula
In step 102, the beam is formed as if the interpolated sample a(îp) were the real measurement. The interpolation error ε is then substantially equal to
if the distribution of the active modules 2 is substantially regular.
The preceding description illustrates an example where only one row 1 of active modules 2 is defective. The same embodiment of the method according to the invention can be used to compensate for the failure of several rows 1 of active modules 2. In such a case, the same processing operation as described hereinabove is applied to each row 1 of defective active modules 2. Moreover, if several consecutive rows 1 of active modules 2 are defective, the rows 1 in nominal operation surrounding the defective rows are used for the interpolation. In the case of a radar comprising an antenna with electronic scanning in several planes, the interpolation is effected on all of the adjacent elements in the direction of the axis OZ, but also in the direction of the axis OY.
The sampling and the formation of the beam by calculation in step 102 is carried out in an identical manner to the embodiment previously described.
The preceding description illustrates an example where a single row 1 of active modules 2 is defective. The same embodiment of the method according to the invention can be used to compensate for the failure of several rows 1 of active modules 2. In such a case, the same processing operation as described hereinabove is applied to each row 1 of defective active modules 2. Moreover, if several consecutive rows 1 of active modules 2 are defective, the rows 1 in nominal operation surrounding the defective rows are used for the interpolation. In the case of a radar comprising an antenna with electronic scanning in several planes, the interpolation is effected on all of the adjacent elements in the direction of the axis OZ, but also in the direction of the axis OY in order to enhance the efficiency of the rejection of the noise signals in a given solid angle oriented with respect to a direction Uz1.
The beam is completed with the P interpolations of the faulty active modules 2, which yields the following P results: S1=S0+W(ip)×a1(îp), . . . , SP=S0+W(ip)×aP(îp). The resulting signals S1 . . . SP are subsequently normalized at step 120 in such a manner that all the beams thus formed have the same gain in the directed orientation Uzf, in other words in the direction pointed to by the antenna. From the resulting signals S1 . . . SP, the signal whose power calculated in step 121 is the lowest amongst all of the calculated signals is retained in step 122, in other words the signal j, j being in the range between 1 and P, corresponding to the equation |SJ|=min(|S1|, |S2|, . . . , |SP|).
As the gain from all the diagrams is identical in the main lobe, the criterion amounts to minimizing the gain in the direction of the interference. This minimization is valid for several interference noise signals as long as they are relatively close to one another. In the case of a waveform with no ambiguity in distance, for example of the Low Frequency of Recurrence (LFR) type, in airborne applications, this assumption is practically always verified.
The formation of the beam by calculation in step 102 is carried out in an identical manner to the embodiment previously presented. In this embodiment, the greater the number of defective rows 1 of active modules 2, the more advantageous it is to increase the number of assumptions of particular directions Uz1, Uz2, . . . , Uzp.
The preceding description illustrates an example where a single row 1 of active modules 2 is defective. The same embodiment of the method according to the invention can be used to compensate for the failure of several rows 1 of active modules 2. In such a case, the same processing operation as described hereinabove is applied to each row 1 of defective active modules 2. Moreover, if several consecutive rows 1 of active modules 2 are defective, the rows 1 in nominal operation surrounding the defective rows are used for the interpolation. In the case of a radar comprising an antenna with electronic scanning in several planes, the interpolation is effected on all of the adjacent elements in the direction of the axis OZ, but also in the direction of the axis OY in order to enhance the efficiency of the rejection of the noise signals in one of the given solid angles oriented with respect to the directions Uz1, Uz2, . . . , Uzp.
A radar implementing an embodiment of the method according to the invention can notably be airborne. In addition, the method according to the invention can, for example, be used in the steps for processing the signal received by a weather radar. The method according to the invention can notably be implemented by a digital computer.
It will be readily seen by one of ordinary skill in the art that embodiments according to the present invention fulfill many of the advantages set forth above. After reading the foregoing specification, one of ordinary skill will be able to affect various changes, substitutions of equivalents and various other aspects of the invention as broadly disclosed herein. It is therefore intended that the protection granted hereon be limited only by the definition contained in the appended claims and equivalents thereof.
Number | Date | Country | Kind |
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05 05211 | May 2005 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/062621 | 5/24/2006 | WO | 00 | 11/24/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/125817 | 11/30/2006 | WO | A |
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