JPS63241484A - Data processing system - Google Patents

Abstract

PURPOSE:To shorten a data processing time and to obtain a distinct image by generating a azimuth direction reference function necessary for azimuth compression by using Doppler frequency information generated at the time of SAR data processing. CONSTITUTION:This system consists of a data processor 41 which generates high-resolution image data for data acquired by a synthetic aperture radar (SAR) and a quick-looking device 42 which generates image data in real time. Then the device 42 is provided with a Doppler frequency information extraction part 25, which is connected to the azimuth direction reference function generation part 7 of the data processor 41 directly through a communication line 26. In this constitution, an extraction part 25 extracts the accurate Doppler frequency information generated by a SAR data compression part 22 and sends out it too the azimuth direction reference generation part 7 through the line 26. Consequently, the generation part 7 generates the accurate azimuth direction reference function with an extremely small processing quantity.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a synthetic aperture radar (Synthetic Aperture Radar) which is mounted on a mobile platform such as an aircraft or an artificial satellite and is used for the purpose of observing ground conditions in extremely precise photographic form. 5ynthetic
The present invention relates to a data processing system that generates desired image data from data acquired by Aperture Radar (SAR), and particularly relates to a technique for generating high-resolution image data.

(Prior Art) A conventional data processing system that generates desired image data from data acquired by SAR is as shown in FIG.
Consisting of a data processing bag W31 and a quick look device 32, as is well known, the receiving station that receives SAR radio waves etc. and the processing station that performs data processing are geographically separated by a considerable distance, but the data processing device Reference numeral 31 is installed in the processing station, and quick look device 32 is installed in the receiving station, and the reproducing devices are not related in operation and have different characteristics or functional purposes.

The data processing device 31 is intended to generate high-resolution image data, and performs predetermined data compression processing on the file device 1 in which SAR raw data is stored and the SAR raw data read from the file device 1. The image processing means, which is composed of an image processing means that generates high-resolution image data (SAR image data) and a file device 10 that stores the generated SAR image data, is composed of a digital computer and basically is the range compression section 2,
Each processing section includes a range direction reference function generation section 3, a parameter calculation section 4, a corner turn section 5, an azimuth compression section 6, an azimuth direction reference function generation section 7, and an image data conversion section 8.

The contents of the file device 1 (SAR raw data) are acquired by the receiving station. In other words, the receiving station acquires all the data necessary for image processing, such as the data acquired by SAR, the attitude data and orbit data of the artificial satellite, and the magnetic tape on which this data is stored is transported to the processing station and filed. Device 1
That is.

Each processing section of the image processing means performs the following processing.

The parameter calculation unit 4 calculates parameters required by each processing unit based on the satellite's orbit data and attitude data, such as the earth radius, ground surface velocity vector, Doppler frequency information, etc., and uses them as a range direction reference function. Generating part 3
is given to the azimuth direction reference function generator 7.

The range direction reference function generation section 3 and the range compression section 2 perform data compression in the range (distance) direction. This range compression is to compress the chirp modulated wave of the transmission pulse into a sharp pulse, and as a result, the target information spread as a two-dimensional hologram is compressed in the range direction.

This compression is performed by correlating the received signal with the conjugate function of the transmitted signal. The range direction reference function generation section 3 generates this conjugate function, and the range compression section 2 receives the SAR raw data and the correlation function signal from the range direction reference function generation section 3 and calculates the correlation. When performing correlation, fast Fourier transform (Fast Fourier Transform) is used as convolution integral.
i+: F F T ) to convert into the frequency domain and perform high-speed calculation.

The data that has been subjected to range compression in this way is arranged in the range direction, but in order to perform the next compression in the azimuth direction, the data must be rearranged in the azimuth direction, and this rearrangement is performed in the corner turn section. I'm doing it at 5.

Azimuth compression, like range compression, is performed by correlating the received signal with its conjugate function with respect to a specific target.

The conjugate function is a mated filter function defined by the orbital data and attitude data of the satellite, which is a moving platform, and the azimuth direction reference function generator 7 generates this function signal based on the Doppler frequency information input from the parameter calculation unit 4. The data is sent to the compression section 6. The azimuth compression section 6 correlates the received signal from the corner turn section 5 with the function signal.

The azimuth-compressed signal is then arranged into image data by the image data conversion section 8 and outputted to the file device 10 as SAR image data.

The details of this data processing device 31 are provided by Fukuizumi et al.:
“Digital image processing of synthetic aperture radar signals” (NEC
Technical Report Volj4 No. 31981 ppj4-39
) is described.

On the other hand, the quick look device 32 includes a file device 21 in which SAR raw data is stored, and a SAR data compression unit that performs data compression processing similar to that described above on the SAR raw data. It basically includes a display device (CRT) 24 for drawing and viewing processed image data on a display screen. As previously mentioned, the quick look device 32
is installed at the receiving station, so the contents of the file device 21 (
SAR raw data) consists of data acquired by SAR,
The orbit data, attitude data, etc. are separately given to the SAR data compression section 22 as a parameter signal a.

This quick look device 32 checks the operation of the data processing system, for example, checks in real time whether the currently acquired data relates to which part of the earth's surface or whether it can be used as regular data. The purpose is to Therefore, in response to the demand for high-speed processing, the SAR data compression unit 22 is configured with hardware, and thins out the SAR raw data stored in the file device 21 to reduce the amount of data to be processed.
The same data compression process as described above is performed on the AR raw data. However, since the purpose is to confirm the operation, the images obtained here have inferior resolution and are perfectly focused.

In other words, the SAR data compression unit 22 internally forms accurate Doppler frequency information (Doppler center frequency, Doppler frequency change rate), and uses it to perform data compression processing.

Here, the Doppler frequency information is formed as follows. That is, Doppler frequency information is obtained based on the satellite's orbit data and attitude data included in the parameter signal a, and this is used as an initial value, and a closed loop is configured so that the reproduced image is focused, and the initial value is finely adjusted. This fine adjustment is performed quickly because the amount of data to be processed is small.

<Problems to be Solved by the Invention> However, in the conventional data processing system described above, the Doppler frequency information necessary to obtain the azimuth direction reference function used in azimuth compression of the data processing device is
The parameter calculation unit calculates the satellite's orbit data and attitude data included in the SAR raw data stored in the file device, but if the orbit data and attitude data are inaccurate, accurate Doppler frequency Since information cannot be obtained, there is a problem in that a clear image may not be obtained.

Therefore, in order to obtain accurate Doppler frequency information and clear images, a data processing system as shown in FIG. 2 has been proposed in some cases. In this data processing system, the quick look device 32 is the same as that shown in FIG. 3, but the data processing device 30 is the same as that shown in FIG.
The processing format has been changed by adding a Doppler frequency information determination section 9). That is, in this data processing device 30, first, the azimuth direction reference function generation section 7 generates an azimuth direction reference function based on appropriate Doppler frequency information as an initial value given from the Doppler frequency information extraction determination section 9, and the azimuth direction reference function is generated by the azimuth direction reference function generation section 7. 6 performs azimuth compression using the azimuth direction reference function. From the result, the Doppler frequency information extraction/judgment section 9 estimates the Doppler frequency.

Next, the azimuth direction reference function generating section 7 generates an azimuth direction reference function based on this estimated Doppler frequency information. The above loop operation is then repeated to obtain accurate Doppler frequency information.

However, forming a loop configuration in this way has the following problems.The content of the loop operation described above is the same as that of the quick look device 32 described above, but the data processing device 30 handles a large amount of data. Therefore, if a loop configuration is used, each process of azimuth compression, Doppler frequency information extraction/judgment, and azimuth direction reference function generation will be performed on this large amount of data, and the process will be repeated, resulting in a large amount of processing time. It will become.

The present invention was made in view of the above-mentioned conventional problems, and its purpose is to make accurate Doppler frequency information generated by a quick look device available to a data processing device, thereby improving data processing efficiency. It is an object of the present invention to provide a data processing system that can shorten processing time in a processing device and obtain extremely clear images.

(Means for Solving the Problems) In order to achieve the above object, the data processing system of the present invention has the following configuration.

That is, the data processing system of the present invention includes a data processing device that performs compression processing on data acquired by a synthetic aperture radar to generate high-resolution image data, and a data processing device that generates high-resolution image data by compressing data acquired by the synthetic aperture radar; In a data processing system comprising a quick look device that performs compression processing on a required amount of data and generates image data in real time; the quick look device has a Doppler frequency that extracts Doppler frequency information formed during the compression processing. An information extractor is provided; the azimuth direction reference function generation section of the data processing device generates an azimuth direction reference function necessary for azimuth compression using the Doppler frequency information extracted by the Doppler frequency information extraction section. This is a characteristic feature.

(Function) Next, the function of the data processing system of the present invention configured as described above will be explained.

Due to its inherent nature or functional purpose, the Quick Look device generates accurate Doppler frequency information during data compression processing, and uses this accurate Doppler frequency information to produce images with lower resolution but in focus. That is, although a clear image is obtained, accurate Doppler frequency information formed here is extracted by the Doppler frequency information extraction section.

Incidentally, the quick look device is installed in the receiving station, and the data processing device is installed in the processing station, and the receiving station and the processing station are usually separated geographically by a considerable distance im. Since the amount of data to be processed in the data processing device to generate the desired image data, that is, the amount of SAR raw data, is enormous, it is stored on a magnetic tape or the like at the receiving station and tracked to the processing station. I am trying to transport it by etc.

Therefore, as a method of transmitting the extracted Doppler frequency information to the data processing device side, the following three methods can be considered. First, since there is very little Doppler frequency information, it is possible to input it directly to the data processing device using a communication line. Second, the extracted Doppler frequency information is output to a display device, a printing device, etc., and the staff member visually checks the output content while contacting the staff member at the data processing device side by telephone. The third is SA from the receiving station to the processing station.
Since a magnetic tape or the like storing R raw data is transported, Doppler frequency information is also stored on the magnetic tape or the like.

In this way, the azimuth direction reference function generation section of the data processing device can accurately generate the azimuth direction reference function necessary for azimuth compression using the Doppler frequency information extracted by the Doppler frequency information extraction section with an extremely small amount of processing. Become.

As described above, according to the data processing system of the present invention, accurate Doppler frequency information generated by the quick look device can be used on the data processing device side, so that the azimuth direction reference function generation section of the data processing device can Using this accurate Doppler frequency information, an accurate azimuth direction reference function can be generated with an extremely small amount of processing. As a result, it is possible to provide a data processing system that can shorten processing time in a data processing device and obtain extremely clear images.

(Example) Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a data processing system according to an embodiment of the present invention. Components that are the same as those shown in FIGS. 2 and 3 are designated by the same reference numerals, and their explanations will be omitted.

In this data processing system, the quick look device 42 is provided with a Doppler frequency information extraction section 25, and the Doppler frequency information extraction section 25 and the azimuth direction reference function generation section 7 of the data processing device 41 are directly connected via a communication line 26. It is designed so that it can be connected.

In such a configuration, the Doppler frequency information extraction unit 2
5 extracts accurate Doppler frequency information formed by the SAR data compression section 22 and sends it to the azimuth direction reference function generation section 7 via the communication line 26. the result,
The azimuth direction reference function generating section 7 can generate an accurate azimuth direction reference function with an extremely small amount of processing.

(Effects of the Invention) As detailed above, according to the data processing system of the present invention, accurate Doppler frequency information generated by the quick look device can be used on the data processing device side, so data processing The azimuth direction reference function generating section of the apparatus can generate an accurate azimuth direction reference function using this accurate Doppler frequency information with an extremely small amount of processing.

As a result, it is possible to provide a data processing system that can shorten processing time in a data processing device and obtain extremely clear images.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a data processing system according to an embodiment of the present invention, and FIGS. 2 and 3 are block diagrams of a conventional data processing system. 1.10, 21.23...File device, 2.
... Range compression section, 3 ... Range direction reference function generation section, 4 ... Parameter calculation section,
5... Corner turn section, 6... Azimuth compression section, 7... Azimuth direction reference function generation section, 8... Image data conversion section, 22. ...
...SAR data compression unit, 24...Display device (
CRT), 25... Doppler frequency information extraction unit, 26... Communication line, 30.31.41.
...Data processing device, 32.42...Quick look device. Agent Patent Attorney Yoshihiro Yahata J-! L5 Ming 0 day return, Zudem θji turn, ) column v =
/ Diagram /) Daegs Δ Reason 1 Stem Destruction A Row 2nd
Figure 3 of the structure of the drawing bundle f゛-gun dying △

Claims (1)

[Claims] a data processing device that performs compression processing on data acquired by the synthetic aperture radar to generate high-resolution image data; and a data processing device that performs compression processing on the required amount of data extracted from the data acquired by the synthetic aperture radar to generate image data. In a data processing system comprising a quick look device that generates data in real time; the quick look device includes a Doppler frequency information extraction unit that extracts Doppler frequency information formed during the compression process; A data processing system characterized in that a direction reference function generation section generates an azimuth direction reference function necessary for azimuth compression using the Doppler frequency information extracted by the Doppler frequency information extraction section.