EP0385989A1

EP0385989A1 - Device for the display of a plurality of radar images

Info

Publication number: EP0385989A1
Application number: EP88904239A
Authority: EP
Inventors: Jean-Pierre Andrieu; Dominique Gault; Jean-Claude Henri
Original assignee: Thomson CSF SA
Current assignee: Thales SA
Priority date: 1987-05-07
Filing date: 1988-05-06
Publication date: 1990-09-12
Also published as: US5036326A; FR2614994A1; JPH02503470A; WO1988008988A1; FR2614994B1

Abstract

L'invention a pour objet un procédé et un dispositif de visualisation de plusieurs images radar en une image résultante unique, formée par une mosaïque des différentes images radar. A cet effet, l'invention prévoit l'utilisation de moyens (71, 71a) d'exclusion mutuelle des images radar, de sorte qu'un point donné de l'image résultante corresponde à la visualisation d'un et d'un seul radar.The subject of the invention is a method and a device for displaying several radar images in a single resulting image, formed by a mosaic of the various radar images. To this end, the invention provides for the use of means (71, 71a) for mutual exclusion of the radar images, so that a given point of the resulting image corresponds to the visualization of one and only one. radar.

Description

Device for viewing multiple RADAR images

The present invention relates to the display of radar images and, more particularly, the case where the same geographical area is covered by several radars and where it is desired to obtain a single resulting image, formed by a mosaic of the images supplied by the different radars.

The need to create a mosaic arises in particular when the position of a radar is such that it is not possible for it to cover the entire area it is responsible for monitoring, due to obstacles such as mountains or tall buildings introducing a shadow in the monitored area, that is to say an area without echo. This is for example frequently the case with airport surveillance radars.

To cover the entire area, one or more additional radars are then necessary and are arranged so that they can reach the shadow areas of the first radar.

To allow an operator to have the image of the entire area - on a single screen, it is then necessary to create a mosaic of the images provided by the different radars.

It is known to produce this mosaic by taking, for each of the pixels of the resulting image, a video equal to a function (average, maximum, etc.) of each of the pixels supplied by the different radars. Because, in general, the images provided by the different radars overlap, there are then distinguished on the single screen two types of zones: - those which are reached by a single radar;

- those reached by several radars (at least two).

In the second type of zone; the echoes of detected objects (planes for example) processed by each of the radars must of course be superimposed on the screen and, therefore, on a given aircraft, match one and only one echo. However, this requirement is not necessarily fulfilled here due to the asynchronism of the rotation of the radars: in fact, there can be movement of the airplane between the moment when it is detected by the first radar and the instant when it is detected by the second.

On the other hand, the radar video signal always contains a certain noise, and, with this type of system, the noises are added in the areas common to several radars.

The present invention aims to constitute a mosaic from a plurality of radar images, which avoids the above drawbacks by the use of means for mutual exclusion of radar images: at a given point of the resulting image corresponds thus the visualization of one and only one radar.

Other objects, features and results of the invention will emerge from the following description, illustrated by the appended figures which represent:

- Figure 1, the block diagram of a conventional digital image transformer;

- Figure 2, a first embodiment of the mosaic according to the invention;

- Figure 3, a second embodiment of the mosaic according to the invention;

- Figure 4, the block diagram of a digital image transformer comprising an auxiliary memory called block memory;

- Figure 5, a third embodiment of the mosaic according to the invention;

- Figure 6, the detail of one of the elements of the previous figure; - Figure 7, a fourth embodiment of the mosaic according to the invention.

In these different figures, the same references refer to try the same things.

FIG. 1 represents a conventional digital image transformer.

It is recalled that such a transformer, also called TDI, has the essential role of transforming a radar image supplied in polar coordinates and relatively slow renewal in a television type image, bright, allowing its exploitation in an illuminated atmosphere.

The TDI therefore receives, on the one hand, video signals from the radar receiver and, on the other hand, rotation signals from the radar antenna.

The video signals consist, on the one hand, of a synchronization signal indicating that an impulse has been emitted by the radar and, on the other hand, by the video proper, constituted by all the responses (echoes) to this impulse. These video signals are received by an input interface 1 which mainly comprises circuits for sampling the analog input information and a memory allowing the memorization of the video information corresponding to each radar pulse.

The rotation signals are constituted, on the one hand, by a North signal which is a top provided at each pass of the antenna to the North and, on the other hand, by an angle increment signal, indicating that the beam has rotated 1 / n ^è of a revolution with respect to the previous increment, if n increments correspond to 360 °. These rotation signals are received by a set 3 of coordinate conversion circuits.

The TDI also includes a memory 4, called image memory, containing in digital form the image which will be displayed in television mode on the screen of a display device 6. The capacity of the memory 4 is adapted to the television standard used, that is to say that it comprises as many memory cells as the image displayed on the television screen comprises pixels. In addition, the luminance of each pixel is coded using a number of bits. The reading phases of the contents of memory 4, to destination of the screen 6, and writing to this memory of the radar information supplied by the interface 1 (via a block 2) are asynchronous: the reading has priority and, during a reading phase, the writing is stopped. The coordinate conversion assembly 3 therefore ensures the write memory addressing of the image memory 4, the interface 1 providing, via block 2, the video information to be written into memory in synchronism with the addressing.

A set 5 of reading circuits in television mode ensures the addressing in reading of the image memory 4.

The TDI also includes a set 2 of artificial remanence circuits which has the role of creating for the digital information contained in the memory k, for which there are no modifications due to aging, a remanence effect comparable to that which is produced on a residual tube where the brightness of a point begins to decrease as soon as it is registered.

The TDI also includes a control processor (not shown) receiving both the video and rotation signals and ensuring the control and synchronization of all the preceding circuits.

FIG. 2 represents a first embodiment of the mosaic according to the invention, in the case of two radars for example.

This figure therefore shows schematically two radars, 10 and 10a, providing video and rotation signals to two TDIs respectively; each of the TDIs consists of the sets 1 to 5 described above, the sets of the TDI of the radar 10a carrying an index a in order to distinguish them from those of the TDI of the radar 10. The video output from each of the image memories (4, 4a) is only transmitted to the display device 6 after an AND type validation logic circuit (71, 71a) and a summing device 72, connecting the outputs of circuits 71 and 71a.

Each of the TDIs further includes a memory, called a mosaic plane (70, 70a). This mosaic map contains, for each pixel, a validation bit authorizing or not authorizing, via the AND circuit (71, 71a), the transmission of the content of the image memory (4, 4a) to the display device 6 In the case of two radars, as shown in FIG. 2, the mosaic plane of the radar 10a is of course complementary to the mosaic plane of the radar 10.

The memories containing the mosaic plans can be read only memories, possibly programmable, or RAM memories whose content is loaded by the processor of the TDI, under the action of the operator.

FIG. 3 represents a second embodiment of the mosaic according to the invention, in which the mosaic planes no longer operate at the output of the image memories, but at the level of the remanence sets. In this figure, we find by way of example the two radars

10 and 10a, whose receivers and antennas supply the video and rotation signals to the TDIs constituted by the assemblies 1 to 5 (1a to 5a for the radar 10a).

In this embodiment, too, each TDI is associated with a mosaic plane, now marked 77 and 77a respectively, but this provides its validation information to the remanence set 2 (respectively 2a). This assembly also receives, as before, the incident video supplied by the interface 1 and the previously recorded video supplied by the image memory 4.

The operation of the remanence circuits is conventional, except as regards validation by the information contained in the mosaic plane (77, 77a).

It will be recalled that the remanence assembly is usually constituted by a RAM memory which receives the incident video on i bits, the video stored in the image memory on j bits and which supplies as output to the image memory a video on j bits, representing a predefined function of the two videos received. Such operation is for example described in the French patent application No. 82.17984 in the name of THOMSON-CSF.

In the case of FIG. 3, the remanence memory (2, 2a) admits an additional input coming from the mosaic plane (77, 77 a), on one bit (the validation bit), the output of this memory, always to the image memory (4, 4a), being then a function both of the two input videos and of the mosaic validation bit. In other words, this embodiment amounts to considering the mosaic as a particular law of persistence. This embodiment has the advantage, compared to the previous embodiment, of avoiding the validation logic (71,

71a).

The size of the memory forming the mosaic plane can be one bit per pixel. It can be lower, considering the pixels in the image memory in blocks, for each of which the mosaic bit is the same: in the case of blocks of 4 x 4 pixels for example, the size of the mosaic plane d is thus reduced. 'a factor

16.

FIG. 4 is the block diagram of a TDI comprising an intermediate memory, called block memory.

In this figure, we find the same elements as in Figure 1, except for a memory 8, called block memory, which is arranged between the incident video and the image memory, or more precisely between the interface 1 and the remanence set 2.

The organization of this intermediate memory is of the same type as that of the image memory 4, but the adjacent pixels are also grouped in blocks, or blocks, and these blocks are transferred in parallel in the image memory when they are completely filled. , which reduces the write load on the latter. Such a structure is for example described in document EP 68,852.

The structure of the block memory can be identical to that of image memory; in an alternative embodiment, the structure of the block memory and its filling mode can be optimized in order to reduce the size of the block memory, as described for example in French patent application No. 86.01377.

The diagram in FIG. 1 is then modified in that the coordinate conversion assembly also provides the write and read addressing of the block memory.

FIG. 5 represents a third embodiment of the mosaic according to the invention in the case of TDIs provided with block memory.

In this figure, we therefore find the two radars 10 and 10a, each connected to the sets 1, 3, 8, respectively la, 3a, 8a, described in FIG. 4, the sets 4, 5 and 6 being common to the two radars, as well as the remanence set identified here 20.

The device of FIG. 5 further comprises an arbiter circuit 73, which has the function of authorizing the reading of one or the other of the memories of blocks 8 and 8a, since the outputs of these two memories are connected at the same input of the remanence assembly 20. This circuit 73 alternately and predefined authorizes the reading of one then of the other memory, and it accompanies this read authorization by an identification of the radar which is thus authorized to supply its information to the assembly 20; this identification can be constituted for example by a number.

The system of FIG. 5 also includes a memory 74, containing a single mosaic plane, also supplied to the remanence assembly 20.

An embodiment of the assembly 20 is described in more detail in FIG. 6.

The set 20 is constituted by the remanence memory 2 above, preceded by a validation logic which includes a comparator 21 and an AND circuit 22. The mosaic plane here contains, for each pixel, the identification of the radar to be taken into account. This identification is provided to the comparator 21 which also receives, from the arbiter circuit 73, the identification of the radar currently providing the video. The comparator 21 delivers a validation signal if the identification of the radar corresponds to that which is authorized by the mosaic plan. The validation signal is supplied to the AND circuit 22 which on the other hand receives the video and which transmits it in the event of validation to the afterglow memory 2. Another embodiment of the assembly 20 consists in proceeding in a similar manner to which is described above in FIG. 3, that is to say to admit at the input of the remanence memory the information (identification of the authorized radar) contained in the mosaic plane for each pixel. The content of memory 2 then takes this parameter into account and the information output from this memory is a function of both the two input videos, the identification of the radar providing the video and the identification of the authorized radar .

This embodiment allows the use of TDI comprising a block memory, with the advantages inherent therein. In addition, in the case where the block memory has a size smaller than that of the image memory, this embodiment has the advantage, compared to that of FIG. 3, of only splitting the block memories and not image memory.

FIG. 7 represents a fourth embodiment of the mosaic according to the invention, also in the case of TDIs provided with block memories.

In this embodiment, the system further comprises, for each of the radars, a memory called zone memory, referenced 75 and 75a respectively. In a TDI, such a memory is used in the case where it is desired to form "medallions" on the screen. Remember that "medallion" means a part the radar coverage area belonging to or not belonging to the image displayed on the screen, which is enlarged with respect to this image; this possibility is for example used when the operator wishes to examine a particular detail. The zone memory (75, 75a) in this case receives the coordinates of the block in reading, supplied by the conversion unit (3, 3a) and it contains the indication of membership or non-membership of this block in the image to view. Its content is for example controlled (via the radar processor) by the operator (arrow 750). It therefore delivers a read authorization or non-authorization to the block memory.

In the system of FIG. 7, the content of the zone memory is modified so as to also include the indications previously contained in the mosaic plans: the authorization to read is then a function not only of the wishes of "medallion" of the operator, but also the mosaic plan.

As in the previous embodiment, the system includes an arbiter circuit 73 which authorizes the reading alternately of the block memories 8 and 8a: consequently, the read authorization emanating from the zone memories (75, 75a) are transmitted to the memory blocks via an AND gate (76, 76a).

The advantage of this embodiment is that only the useful parts of the images of the two radars are sent to the remanence assembly 2, that is to say the parts actually used for the formation of the displayed mosaic. In this way, the access bus to the assembly 2 is half loaded than in the case of FIG. 5, where the entire video of the two radars is transmitted to the remanence assembly.

The invention described above was, of course, by way of nonlimiting example and it is thus, for example, that the various embodiments described for a mosaic with two radars can be extended to a mosaic at N radars.

Claims

1. A method of displaying several radar images in a single mosaic, each of the radar images being stored, the method being characterized in that it includes a step of mutual exclusion of the radar images.

2. Method according to claim 1, characterized in that the radar image is provided in analog form and in polar coordinates; that the method further comprises, for each of the images, the following steps:

- image scanning; - coordinate conversion, making it possible to obtain an image in Cartesian coordinates;

- storage of the converted image; that the step of mutual exclusion of the images consists, for each image thus processed and for each pixel of this image, in the validation or non-validation of the image according to its membership or its non-membership in the mosaic displayed, and that the validated images are summed up and then viewed in television mode.

3. Method according to claim 1, characterized in that the radar image is provided in analog form and in polar coordinates; that the method further comprises, for each of the images, the following steps:

- image scanning;

- coordinate conversion, making it possible to obtain an image in Cartesian coordinates;

- storage of the converted image;

- afterglow, making it possible to obtain an aging of the stored image; that the step of mutual exclusion of images consists, for each image thus processed, in the validation or non-validation of the image during the remanence step as a function of its membership or non-membership of the displayed mosaic, and that the validated images are summed and then displayed in television mode.

4. Method according to claim 1, characterized in that the radar image is provided in analog form and in polar coordinates; that the method further comprises, for each of the images, the following steps;

- image scanning;

- first storage of the converted image; and that the method further comprises the following steps:

- alternative transmission of the different stored images;

- second storage of the transmitted images, after a remanence step;

- afterglow, during which the image having been the subject of the second storage is artificially aged, and during which mutual exclusion is carried out in the form of a validation or a non-validation of the images transmitted according to their membership or of their non-belonging to the displayed mosaic;

- viewing in television mode of the image stored a second time.

5. Method according to claim 1, characterized in that the radar image is provided in analog form and in polar coordinates; that the method further comprises, for each of the images, the following steps:

- image scanning;

- first storage of the converted image;

- validation or non-validation of the image stored in function tion of its belonging or not belonging to the displayed mosaic; and that the method further comprises the following steps: - alternative transmission of "different stored and validated images;

- second storage of the transmitted images;

- viewing in television mode of the image stored a second time.

6. Display device for implementing the method according to claim 2, characterized in that it comprises, for each of the radar images supplied in polar coordinates:

- means (1, 1a) for digitizing the image supplied;

- means (3, 3a) for converting coordinates;

- an image memory (4, 4a) for storing the converted image;

- a memory (70, 70 a) containing a mosaic plan constituted, for each pixel of the image, by the validation or non-validation information;

- logical means (71, 71a) for validating the pixels from the content of the mosaic memory and for transmitting the validated pixels; the device further comprising means for summing (72) the validated images and for viewing (6) the summed images.

7. Display device for implementing the method according to claim 3, characterized in that it comprises, for each of the radar images supplied in polar coordinates:

- means (1, 1a) for digitizing the image supplied; - means (3, 3a) for converting coordinates:

- an image memory (4, 4a) for storing the converted image;

- a memory (77, 77a) containing a mosaic plan constituted, for each pixel of the image, by the information of vali donation or non-validation;

- Means (2, 2a) ensuring the persistence of the stored image and the validation of the pixels on the basis of the information provided by the mosaic memory; the device further comprising means for summing (72) the validated images and for viewing (6) the summed images.

8. Display device for implementing the method according to claim 4, characterized in that it comprises, for each of the radar images supplied in polar coordinates: - means (1, 1a) for digitizing the image provided ;

- means (3, 3a) for converting coordinates;

- a block memory (8, 8a) ensuring a first storage of the converted image; the device further comprising: - arbiter means (73), ensuring an alternative transmission of the images stored in the block memories;

- an image memory (4) ensuring a second storage of the transmitted image;

- a memory (74) containing a mosaic plan constituted, for each pixel of the image of the image memory, by validation or non-validation information;

- Means (2) ensuring the persistence of the image of the image memory and the validation of the pixels on the basis of the information provided by the mosaic memory; - Display means (6) of the image of the image memory.

9. Display device for implementing the method according to claim 5, characterized in that it comprises, for each of the radar images supplied in polar coordinates: - means (1, 1a) for digitizing the image provided ;

- means (3, 3a) for converting coordinates;

- a block memory (8, 8a) ensuring a first memory sation of the converted image;

- an area memory (75, 75a) containing a mosaic plan made up, for each pixel of the image of the block memory, by validation or non-validation information; the device further comprising:

- Arbitrator means (73), ensuring an alternative transmission of the images stored in the block memories and validated;

- an image memory (4) ensuring a second storage of the transmitted image; - means (2) ensuring the persistence of the image of the image memory;

- Display means (6) of the image of the image memory.