JP2007114093A - Device, method, and program for clarifying image; device, method, and program for measuring speed; device, method, and program for determining image clarity - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To clearly reproduce an object observed by an SAR (synthetic aperture radar) when a radio wave scattering body exists around it or when luminance of an oscillating (moving) object is weak. <P>SOLUTION: This device comprises a reference function creating section 142 for creating a reference function, based on distance relation information of the SAR and object based on moving information of the SAR and forecasting moving information of the object, and an azimuth compression processing section 138 for azimuth-compressing data after range compression and creates data after the azimuth compression, based on the reference function created by the reference function creating section 142. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  An embodiment according to the present invention includes an image sharpening device, an image sharpening method, and an image sharpening program for sharpening an image of a target from data of the target observed by a SAR (Synthetic Aperture Radar). , And a speed measuring device, a speed measuring method, a speed measuring program for measuring the speed of the target observed by the SAR, and a sharpness of an image of the target indicated by the data of the target observed by the SAR The present invention relates to an image definition device, an image definition method, and an image definition program.

Conventionally, there has been an isolated scattering point method ISAR (Inverse Synthetic Aperture Radar) processing for reproducing an image of a target by tracking an object exhibiting strong radio wave scattering in the absence of a radio wave scatterer.
JP-A-11-183606 JP 2003-130950 A

In the conventional isolated scattering point method ISAR processing, tracking is unstable and the target image is not clearly sharpened when there is a radio wave scatterer around or when the brightness of a moving (moving) target is weak. There was a problem.
Further, conventionally, there has been a problem that it is impossible to calculate the speed of the target in the range direction and the azimuth direction.

  The embodiment of the present invention has been made to solve the above-described problem, and even when there is a radio wave scatterer in the surrounding area or when the luminance of the shaking target is low, the target image is correctly and clearly displayed. It aims to become. Another object of the embodiment of the present invention is to calculate the speed of the target in the range direction and the azimuth direction.

An image sharpening device according to an embodiment of the present invention is an image sharpening device that sharpens an image of a target from data of the target observed by the SAR.
The distance relationship between the SAR and the target based on the data input unit that inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR, and the SAR movement information and the predicted movement information of the target. A reference function generation unit that generates a reference function based on information by a processing device and stores the reference function in a storage device, and azimuth compresses the range-compressed data input by the data input unit based on the reference function generated by the reference function generation unit An azimuth compression processing unit that generates data after azimuth compression by a processing device, and a data storage unit that stores data after azimuth compression generated by the azimuth compression processing unit in a storage device.

  The image sharpening device according to the embodiment of the present invention further includes a speed input unit that inputs a predicted moving speed, which is a predicted speed at which the target moves, using an input device, and the reference function generating unit includes A reference function is generated based on the predicted moving speed input by the speed input unit and the distance relation information.

  Furthermore, the speed input unit of the image sharpening device according to the embodiment of the present invention inputs a plurality of predicted movement speeds, and the reference function generation unit includes a plurality of predicted movement speeds input by the speed input unit. A plurality of reference functions are generated based on each predicted moving speed and distance relationship information, and the azimuth compression processing unit is configured to generate a plurality of azimuth-compressed data based on the reference functions of the plurality of reference functions generated by the reference function generation unit. The image sharpening device further includes a sharpness calculation unit that calculates the sharpness of the image indicated by each post-azimuth compression data of the plurality of post-azimuth compression data generated by the azimuth compression processing unit by the processing device. The data storage unit stores data having the highest image sharpness calculated by the sharpness calculation unit in a storage device.

  Further, the speed input unit of the image sharpening device according to the embodiment of the present invention inputs the predicted moving speed in the range direction and the predicted moving speed in the azimuth direction as the predicted moving speed. .

  Further, the sharpness calculation unit of the image sharpening device according to the embodiment of the present invention is a processing device that calculates the sharpness of an image based on the luminance of the pixel of the image indicated by the azimuth-compressed data generated by the azimuth compression processing unit. It is characterized by determining by.

  The image sharpening device according to the embodiment of the present invention further includes a synthetic aperture time information input unit that inputs synthetic aperture time information having a synthetic aperture time start time and a synthetic aperture time end time using an input device. The reference function generation unit generates a reference function based on the synthetic aperture time information and the distance relation information input by the synthetic aperture time information input unit.

  Furthermore, the synthetic aperture time information input unit of the image sharpening device according to the embodiment of the present invention inputs a plurality of synthetic aperture time information, and the reference function generation unit inputs the synthetic aperture time information input unit. A plurality of reference functions are generated from each synthetic opening time information and distance relation information of the plurality of synthetic opening time information, and the azimuth compression processing unit is configured to generate each reference function of the plurality of reference functions generated by the reference function generating unit. A plurality of azimuth-compressed data based on the image azimuth, and the image sharpening device further processing the image sharpness of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated by the azimuth compression processing unit And the data storage unit stores data having the highest image sharpness calculated by the sharpness calculation unit in a storage device. .

  Further, the definition calculation unit of the image definition apparatus according to the embodiment of the present invention calculates the definition of the image based on the luminance of the pixel of the image indicated by the azimuth compressed data generated by the azimuth compression processing unit. The determination is made by a processing device.

  In addition, the data input unit of the image sharpening device according to the embodiment of the present invention inputs an image after azimuth compression, and the image sharpening device further receives the azimuth compressed image input by the data input unit. An azimuth decompression processing unit for decompressing the azimuth compression of the image, wherein the azimuth compression processing unit performs azimuth compression on the data decompressed by the azimuth decompression processing unit based on the reference function generated by the reference function generation unit; It is characterized by generating post-compression data.

  The image sharpening device according to the embodiment of the present invention further includes an image cutout unit that cuts out a partial image including a target from the image after azimuth compression input by the data input unit, and the azimuth decompression The processing unit decompresses the azimuth compression for the partial image cut out by the image cutout unit.

  Furthermore, the azimuth decompression processing unit of the image sharpening device according to the embodiment of the present invention uses a reference function generated based on distance relationship information between the SAR and the target that is not based on the predicted movement information of the target. The azimuth compression is decompressed with respect to the image after azimuth compression.

  Further, the azimuth compression processing unit of the image sharpening device according to the embodiment of the present invention is the range-compressed data based on the reference function equation 5 obtained from the equation 4 representing the distance relationship information between the SAR and the target. The azimuth is compressed.

  In addition, the reference function generation unit of the image sharpening device according to the embodiment of the present invention substitutes the predicted moving speed of the target and the synthetic aperture time calculated based on the synthetic aperture time information with respect to Equation 5 above. Thus, a reference function is generated.

  The image sharpening device according to the embodiment of the present invention further calculates a correction amount according to the range direction speed of the target, and the range input by the data input unit based on the calculated correction amount. A range migration correction unit that performs range migration correction on post-compression data, wherein the azimuth compression processing unit generates azimuth-compressed data by performing azimuth compression on the corrected data that has been subjected to range migration correction by the range migration correction unit. And

  Furthermore, the range migration correction unit of the image sharpening device according to the embodiment of the present invention calculates a correction amount based on the following formula 6, and performs range migration correction based on the calculated correction amount. And

A speed measuring device according to an embodiment of the present invention is a speed measuring device that measures the speed of a target observed by a SAR.
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device, a speed input unit that inputs a plurality of predicted speeds by the input device, and a plurality of data input by the speed input unit. A plurality of reference functions are generated by the processing device based on the predicted speeds of the SAR, the distance information between the SAR and the target based on the SAR movement information and the predicted movement information of the target, and stored in the storage device A reference function generation unit that performs the azimuth compression on the range-compressed data input by the data input unit based on the reference functions of the plurality of reference functions generated by the reference function generation unit, and processes the plurality of azimuth-compressed data The image shown by each azimuth-compressed data of the azimuth compression processing unit generated by the azimuth compression processing unit and the plurality of azimuth-compressed data generated by the azimuth compression processing unit In the case of generating the reference function used to generate the azimuth-compressed data having the highest definition calculated by the processing device and the definition calculation unit that calculates the definition by the above-described definition calculation unit, the distance relation information And a speed determining unit that determines by the processing device that the input predicted speed is the speed of the target.

An image definition determination apparatus according to an embodiment of the present invention is an image definition determination apparatus that determines the definition of an image of a target indicated by target data observed by a SAR.
A data input unit that inputs range-compressed data that has been range-compressed with respect to the target data observed by the SAR by an input device, an azimuth compression processing unit that compresses the compressed data input by the data input unit by a processing device, and The azimuth compression processing unit includes a sharpness calculation unit that calculates the sharpness of the image by the processing device based on the luminance of the pixel of the image indicated by the azimuth-compressed data obtained by azimuth compression.

  In addition, the sharpness calculation unit of the image sharpness determination apparatus according to the embodiment of the present invention is configured such that the higher the peak value of the amplitude representing the luminance of the pixel of the image indicated by the azimuth-compressed data, the clearer the image. It is determined that it is.

Furthermore, an image sharpening device according to an embodiment of the present invention is an image sharpening device that sharpens an image of a target from target data observed by the SAR.
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device, and a processing device that performs range migration correction of the data after range compression input by the data input unit and processes the corrected data A zero-padded data generated by the processing device with zero-padded data in which the number of pixels of the corrected data is raised to a power of two by padding the corrected data generated by the range-migration correcting unit with zeros A processing unit, an accompanying information input unit that inputs image accompanying information accompanying the image by an input device, a predicted moving speed that is a predicted speed at which the target moves, a start time of the synthetic opening time, and an end time of the synthetic opening time; A reference function information input unit for inputting synthetic aperture time information having A reference function is generated by the processing device based on the image accompanying information input by the report input unit, the predicted moving speed and the synthetic aperture time information input by the reference function information input unit, and the distance relationship information between the SAR and the target. The reference function generation unit and the zero padded data generated by the zero padding processing unit are subjected to FFT (Fast Fourier Transform) to generate post-FFT data by the processing device, and the reference function generated by the reference function generation unit is further subjected to FFT. An FFT processing unit that generates a post-FFT reference function by the processing device, an azimuth compression processing unit that compresses the post-FFT data by the processing device by azimuth based on the post-FFT reference function, and after azimuth compression that the azimuth compression processing unit compresses the azimuth An IFFT processing unit that performs IFFT (Inverse Fast Fourier Transform) on the data and generates post-IFFT data by a processing device; A data display unit that displays the post-IFFT data generated by the FT processing unit on a display device, and a definition determination input unit that inputs whether or not the post-IFFT data displayed by the data display unit is clear by the input device; And a data storage unit that stores the post-IFFT data in a storage device when it is determined that the definition determination unit is clear.

An image sharpening method according to an embodiment of the present invention is an image sharpening method of an image sharpening device that sharpens an image of a target from data of the target observed by the SAR.
The SAR and the target based on the data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR, and the movement information of the SAR and the predicted movement information of the target A reference function generation step in which the reference function generation unit generates a reference function based on the distance relationship information with the processing device and stores the reference function in the storage device, and on the data input step based on the reference function generated in the reference function generation step. The azimuth compression processing step in which the input data after range compression is azimuth-compressed and the azimuth compression processing unit generates the azimuth-compressed data by the processing device, and the data storage unit stores the azimuth-compressed data generated in the azimuth compression processing step. And a data storage step for storing the data.

An image sharpening program according to an embodiment of the present invention is an image sharpening program for an image sharpening device that sharpens an image of a target from data of the target observed by the SAR.
The SAR and the target based on the data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR, and the movement information of the SAR and the predicted movement information of the target A reference function generation step in which the reference function generation unit generates a reference function based on the distance relationship information with the processing device and stores the reference function in the storage device, and on the data input step based on the reference function generated in the reference function generation step. The azimuth compression processing step in which the input data after range compression is azimuth-compressed and the azimuth compression processing unit generates the azimuth-compressed data by the processing device, and the data storage unit stores the azimuth-compressed data generated in the azimuth compression processing step. Data storage step stored in the computer To.

A speed measurement method according to an embodiment of the present invention is a speed measurement method of a speed measurement device that measures the speed of a target observed by a SAR.
A data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR, and a speed input step in which the speed input unit inputs a plurality of predicted speeds by the input device; Refer to a plurality of reference functions based on each predicted speed of the plurality of predicted speeds input in the speed input step, and distance relation information between the SAR and the target based on the SAR movement information and the target predicted movement information. A reference function generation step generated by the function generation unit by the processing device and stored in the storage device, and after the range compression input in the data input step based on each reference function of the plurality of reference functions generated in the reference function generation step Azimuth compression processing in which the data is azimuth compressed and the azimuth compression processing unit generates a plurality of azimuth-compressed data by the processor A sharpness calculation step in which a sharpness calculation unit calculates a sharpness of an image indicated by each post-azimuth compression data of the plurality of post-azimuth compression data generated in the azimuth compression processing step, and the sharpness calculation When generating the reference function used to generate the azimuth-compressed data having the highest definition calculated in the step, the speed determination unit determines that the speed input in the distance relation information is the speed of the target by the processing device. And a speed determining step for determining.

A speed measurement program according to an embodiment of the present invention is a speed measurement program of a speed measurement device that measures the speed of a target observed by a SAR.
A data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR, and a speed input step in which the speed input unit inputs a plurality of predicted speeds by the input device; Refer to a plurality of reference functions based on each predicted speed of the plurality of predicted speeds input in the speed input step, and distance relation information between the SAR and the target based on the SAR movement information and the target predicted movement information. A reference function generation step generated by the function generation unit by the processing device and stored in the storage device, and after the range compression input in the data input step based on each reference function of the plurality of reference functions generated in the reference function generation step Azimuth compression processing in which the data is azimuth compressed and the azimuth compression processing unit generates a plurality of azimuth-compressed data by the processing unit. A sharpness calculation step in which a sharpness calculation unit calculates a sharpness of an image indicated by each post-azimuth compression data of the plurality of post-azimuth compression data generated in the azimuth compression processing step, and the sharpness calculation When generating the reference function used to generate the azimuth-compressed data having the highest definition calculated in the step, the speed determination unit determines that the speed input in the distance relation information is the speed of the target by the processing device. The speed determining step for determining is executed by a computer.

An image definition determination method according to an embodiment of the present invention is an image definition determination method of an image definition determination apparatus that determines the definition of an image of a target indicated by target data observed by SAR.
A data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR by the input device, and the azimuth compression processing unit inputs the compressed data input in the data input step by the processing device. Azimuth compression processing step for performing azimuth compression, and a sharpness calculation step in which the processing unit calculates a sharpness of the image based on the luminance of the pixel of the image indicated by the azimuth-compressed data that has been azimuth-compressed in the azimuth compression processing step. It is characterized by providing.

An image definition program according to an embodiment of the present invention is an image definition program of an image definition device that determines the definition of an image of a target indicated by the target data observed by the SAR.
A data input step in which the data input unit inputs the range-compressed data obtained by performing range compression on the target data observed by the SAR by the input device, and the azimuth compression processing unit inputs the compressed data input in the data input step by the processing device. Azimuth compression processing step for performing azimuth compression, and a sharpness calculation step in which the processing unit calculates a sharpness of the image based on the luminance of the pixel of the image indicated by the azimuth-compressed data that has been azimuth-compressed in the azimuth compression processing step. And making the computer execute.

  According to the image sharpening device, the image sharpening method, and the image sharpening program according to the embodiment of the present invention, the distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target. A reference function generator that generates a reference function based on the processing unit and stores the reference function in a storage device, and azimuth compresses the range-compressed data input by the data input unit based on the reference function generated by the reference function generator. By providing an azimuth compression processing unit that generates post-data using a processing device, the image of the target can be clearly sharpened even when there is a radio scatterer around it or when the brightness of the shaking target is weak. Can do.

  In addition, according to the speed measurement device, the speed measurement method, and the speed measurement program according to the embodiment of the present invention, the sharpness of the image that is indicated by each post-azimuth compression data of the plurality of post-azimuth compression data is calculated by the processing device. When the reference function used to generate the azimuth-compressed data with the highest sharpness calculated by the degree calculation unit and the sharpness calculation unit is generated, the predicted speed input in the distance relationship information is the target speed. If there is a speed determination unit that is determined by the processing device, the speed of the target in the range direction and the azimuth direction can be calculated.

  Furthermore, according to the image definition determination device, the image definition determination method, and the image definition determination program according to the embodiment of the present invention, the image definition is processed based on the luminance of the pixel of the image indicated by the azimuth-compressed data. By providing the sharpness calculation unit that is calculated by the apparatus, it is possible to determine whether or not the image is clear.

  First, an example of a hardware configuration of the image sharpening device 100 according to the embodiment will be described with reference to FIGS. 1 and 2.

FIG. 1 is a diagram illustrating an example of an appearance of an image sharpening device 100 according to an embodiment.
In FIG. 1, an image sharpening device 100 includes a CRT (Cathode Ray Tube) display device 901, a keyboard (K / B) 902, a mouse 903, a compact disc device (CDD) 905, a database 908, a system unit 909, and a server 910. These are connected by cables.
Further, the image sharpening apparatus 100 is connected to the Internet 940 via a local area network (LAN) 942 and a gateway 941.
Here, the CRT display device 901 is an example of the display device 984.

FIG. 2 is a diagram illustrating an example of a hardware configuration of the image sharpening device 100 according to the embodiment.
In FIG. 2, the image sharpening apparatus 100 includes a CPU (Central Processing Unit) 911 that executes a program. The CPU 911 is connected to the ROM 913, RAM 914, communication board 915, CRT display device 901, K / B 902, mouse 903, FDD (Flexible Disk) 904, CDD 905, and magnetic disk device 920 via the bus 912. The CPU is an example of a processing device.
The RAM 914 is an example of a volatile memory. The ROM 913 and the magnetic disk device 920 are examples of a nonvolatile memory. These are examples of the storage device 982.
The communication board 915 is connected to the LAN 942 or the like.
Further, the K / B 902, the mouse 903, and the like are examples of the input device 980.
The CPU 911 is an example of a processing device.

Here, the communication board 915 is not limited to the LAN 942 but may be directly connected to the Internet 940 or a WAN (Wide Area Network) such as ISDN. When directly connected to the Internet 940 or a WAN such as ISDN, the image sharpening apparatus 100 is connected to the Internet 940 or a WAN such as ISDN, and the gateway 941 is unnecessary.
The magnetic disk device 920 stores an operating system (OS) 921, a window system 922, a program group 923, and a file group 924. The program group 923 is executed by the CPU 911, the OS 921, and the window system 922.

The program group 923 stores programs that execute functions described as “˜units” in the description of the embodiments described below. The program is read and executed by the CPU 911.
In the file group 924, what is described as “to determination” in the description of the embodiment described below is stored as “to file”.
Also, the arrows in the flowcharts described in the following description of the embodiments mainly indicate data input / output, and the data for the data input / output is the magnetic disk device 920, FD, optical disk, CD, MD. (Mini disc), DVD (Digital Versatile Disk) and other recording media. Alternatively, it is transmitted through a signal line or other transmission medium.

  In addition, what is described as “unit” in the description of the embodiment described below may be realized by firmware stored in the ROM 913. Alternatively, it may be implemented by software alone, hardware alone, a combination of software and hardware, or a combination of firmware.

  In addition, a program that implements the embodiment described below may be stored using a recording device using another recording medium such as the magnetic disk device 920, FD, optical disk, CD, MD, DVD, or the like.

  1 and 2 are also examples of the appearance and hardware configuration of the speed measurement device and the image definition determination device, respectively.

Embodiment 1 FIG.
Next, the first embodiment will be described. In the first embodiment, the image sharpening device 100 and the image sharpening method that can correctly sharpen an image of a target even when there is a radio wave scatterer in the surroundings, or when the brightness of a moving target is weak. The image sharpening program will be described. The processing that the image sharpening apparatus 100, the image sharpening method, and the image sharpening program have is called a speed designation method ISAR.

  First, the sharpening of the target by the isolated scattering point method ISAR will be described based on FIG. 3 and FIG. 4, and then the sharpening of the target by the speed designation method ISAR will be described based on FIG. 5 and FIG.

FIG. 3 is a diagram illustrating the sharpening of the target by the isolated scattering point method ISAR when there is only one moving target. When data after range compression with only one moving target is input and processed by the isolated scattering point method ISAR, the isolated scattering point can be normally tracked because the brightness of only the target is strong. Succeeded in sharpening the target. That is, in this case, according to the isolated scattering point method ISAR, the target is reproduced more clearly than a normal SAR image.
FIG. 4 is a diagram illustrating the sharpening of a target by the isolated scattering point method ISAR when there is a moving target and a clutter that has a different speed from the target and has high luminance. When range-compressed data is input that includes a moving target and a clutter that has a different speed from the target and has a strong luminance, and is processed by the isolated scattering point method ISAR, it is focused on the clutter that has a higher luminance than the target. Therefore, the target is further blurred. That is, in this case, according to the isolated scattering point method ISAR, the target is reproduced in a blurred manner as compared with a normal SAR image.
Therefore, in the isolated scattering point method ISAR, the target cannot be clearly reproduced if different speed clutters are included in the image.

FIG. 5 is a diagram illustrating the sharpening of a target by the speed designation method ISAR when only one moving target exists. When range-compressed data having only one moving target is input and processed by the speed designation method ISAR, the target is successfully clarified when the speed of the target is input. That is, in this case, according to the speed designation method ISAR, the target is reproduced more clearly than a normal SAR image.
FIG. 6 is a diagram illustrating the sharpening of the target by the speed designation method ISAR when there is a moving target and a clutter having a different speed from the target and having a high luminance. If you input the data after range compression in which there is a moving target and a clutter that has a different speed from the target and has strong brightness, and processed by the speed specification method ISAR, the target will be Clutters that are sharpened and have different speeds are blurred. Here, when the moving speed of the clutter is the same as that of the target, the target is sharpened and the clutter is also sharpened by processing by the speed designation method ISAR.
Therefore, in the speed designation system ISAR, the target can be reproduced clearly even if different speed clutters are included in the image.

  Next, the relative motion between the SAR and the target, which is the basis of the speed designation method ISAR, will be described.

  First, based on FIG. 7, FIG. 8, the relative motion of SAR and a stationary body (target which does not move) is demonstrated. FIG. 7 is a diagram showing a relative relationship (distance) between the SAR and the stationary body after t seconds. FIG. 8 is a diagram illustrating movement of the stationary body in FIG. 7 due to rotation. That is, the stationary body itself does not move, but the stationary body moves by rotation when viewed from the SAR. That is, here, the stationary body is affected by the rotation. Here, the motion of a stationary body existing on the rotating coordinates is defined, and the Doppler frequency in that case is derived.

  7 and 8, the following equation is obtained as the relative motion (distance) between the SAR and the stationary body after t seconds.

さらに、

further,

式８を、マクローリン展開を用いて、式９のように二次の項まで展開する。

Expression 8 is expanded to a quadratic term as shown in Expression 9 by using Maclaurin expansion.

式９を用いて、式１０のようにドップラ周波数ｆ_ｄを表現できる。

Using Equation 9, the Doppler frequency f _d can be expressed as in Equation 10.

Next, based on FIGS. 9 and 10, the relative motion between the radar and the moving body (moving target), which is the basis of the speed designation method ISAR, will be described. FIG. 9 is a diagram showing a relative relationship (distance) between the SAR and the moving body after t seconds. FIG. 10 is a diagram illustrating movement of the moving body in FIG. Here, as described above, it is assumed that the moving body is affected by rotation. Here, the movement of the moving body in the azimuth direction and the range direction is defined, and the Doppler frequency f _d in that case is derived.

  9 and 10, the following equation is obtained as the relative motion (distance) between the SAR and the moving body after t seconds. Here, it is assumed that the target moves in a constant velocity linear motion for a predetermined period.

さらに、

further,

式１２を、マクローリン展開を用いて、式１３のように二次の項まで展開する。

Expression 12 is expanded to a quadratic term as shown in Expression 13 using Maclaurin expansion.

式１３を用いて、式１４のようにドップラ周波数ｆ_ｄを表現できる。

Using Equation 13, the Doppler frequency f _d can be expressed as in Equation 14.

ここで、

here,

である。

It is.

Next, the reference function E _ref for azimuth compression considering the movement of the target can be obtained from the Doppler _center frequency f _dcE and the Doppler frequency change rate β _P obtained by the above equation 14 as follows. it can.

Here, in the speed designation method ISAR, the predicted speed in the range direction and the predicted speed in the azimuth direction of the target are input as v _A and v _R to the reference function E _ref , and azimuth compression is performed. While confirming blurring of the image after azimuth compression, the process is repeated a plurality of times to output the most tightened (clear) image. Thereby, in the speed designation method ISAR, a clear image of the moving target is obtained. Here, even if there is a clutter having a different speed, the image is sharpened based on the designated predicted speed, so that it is not affected by the clutter.

Further, the synthetic aperture time _{T A_isar} used for ISAR becomes less synthetic aperture time _{T A} normal SAR. In addition, the higher the sway of the target, the higher the resolution can be obtained with a shorter synthetic aperture time. Furthermore, by shortening the synthetic opening time T A — _isar , it is possible to consider that the target is moving at a constant linear velocity. Therefore, here, the start time α _start of the synthetic opening time T A — _isar and the synthetic opening time T _An end time α _{end of A_isar} can be arbitrarily selected. For example, the following more optional end time alpha _{end The} synthetic aperture time to normalize _{T A} 1, start time alpha _start and synthetic aperture time _{T A_isar} synthetic aperture time _{T A_isar} used for ISAR for SAR as shown in Equation 17 It can be so. The synthetic opening time T A — _isar is, for example, 2 seconds when the SAR synthetic opening time T _A is 5 seconds and the start time α _start is 1.5 seconds and the end time α _end is 3.5 seconds. It is. This normalizes the synthetic aperture time _{T A} for SAR in Equation 17 by one, the start time alpha _start 0.3, an end time alpha _{end The} select 0.7, and cut out 2 seconds.

In addition, the range migration correction according to the speed in the range direction of the target is also performed each time the azimuth is compressed, thereby achieving high resolution. The correction amount _Cr is obtained from Equation 18 shown below, and the corresponding time range is shifted by one line so that the trajectory of the target becomes a straight line in the azimuth direction. The correction amount _Cr is usually obtained as a real number, and the integer part thereof corresponds to a pixel level shift amount in the range direction. The decimal part corresponds to a shift amount of 1 pixel or less in the range direction, and is interpolated by a third-order convolution interpolation method or a polyphase filter.

  Next, functions of the image sharpening device 100 according to the first embodiment will be described with reference to FIG. FIG. 11 is a functional block diagram illustrating functions of the image sharpening device 100 according to the first embodiment.

  The image sharpening device 100 sharpens the image of the target from the data of the target observed by the SAR. Here, the image sharpening device 100 sharpens the image of the target from the data of the target observed by the SAR, for example, by the speed designation method ISAR. The image sharpening device 100 includes an input unit 110, a processing unit 130, a storage unit 160, a display unit 170, an input device 980, a storage device 982, and a display device 984.

The input unit 110 includes a data input unit 112, a reference function information input unit 114, an accompanying information input unit 120, and a definition determination input unit 122.
The data input unit 112 uses the input device 980 to input range-compressed data obtained by performing range compression on the target data observed by the SAR. Here, the data after range compression refers to an image having a high resolution only in the range direction in which the pulse compression processing is performed in the range direction.
The reference function information input unit 114 includes a speed input unit 116 and a synthetic aperture time information input unit 118. The speed input unit 116 inputs a predicted moving speed, which is a predicted speed at which the target moves, from the input device 980. Here, the predicted moving speed has a predicted speed v _{R in} the range direction and a predicted speed v _{A in the} azimuth direction. The synthetic opening time information input unit 118 inputs synthetic opening time information having a synthetic opening time start time α _start and a synthetic opening time end time α _end by the input device 980.
Accompanying information input unit 120 inputs the input device 980 image accompanying information accompanying the predicted velocity v _A non-image prediction velocity v _R and the azimuth direction in the range direction, such as the speed of the position and SAR of SAR.
The sharpness determination input unit 122 uses the input device 980 to input a determination as to whether post-IFFT data displayed by the data display unit 172 described later is clear.

The processing unit 130 includes a range migration correction unit 132, a zero padding processing unit 134, an FFT processing unit 136, an azimuth compression processing unit 138, an IFFT processing unit 140, and a reference function generation unit 142.
Range migration correction unit 132 calculates the correction amount C _r in accordance with the range direction velocity v _R of the target, based on the calculated correction amount C _r, the range for the data after range compression the data input unit 112 inputs Migration correction is performed and corrected data is generated. Here, the range migration correction unit 132 calculates the correction amount C _r in accordance with the predicted velocity v _R of the input range direction, perform range migration correction.
The zero padding processing unit 134 generates zero padded data in which the number of pixels of the corrected data is a power of two by padding the corrected data generated by the range migration correcting unit 132 with 0. In order to perform fast Fourier transform (FFT), the number of pixels must be a power of two. Therefore, the zero padding processing unit 134, for example, as shown in Expression 19 below, the number of pixels N in the azimuth direction for fast Fourier transform, which is the smallest power of 2 larger than the number of pixels in the cut out azimuth direction. _Fft is calculated, and 0 (zero) is padded by the number N _{zero_pad of} pixels to be padded with zeros, which is the number of pixels that is insufficient for the number, as shown in Equation 20 below.

ＦＦＴ処理部１３６は、ゼロ詰め処理部１３４が生成したゼロ詰めデータをアジマスラインごとに複素高速フーリエ変換し周波数領域に変換したＦＦＴ後データを処理装置により生成する。さらに、ＦＦＴ処理部１３６は、後述する参照関数生成部１４２が生成した参照関数をＦＦＴしＦＦＴ後参照関数を処理装置により生成する。
アジマス圧縮処理部１３８は、後述する参照関数生成部１４２が生成した参照関数に基づき、データ入力部１１２が入力したレンジ圧縮後データをアジマス圧縮しアジマス圧縮後データを処理装置により生成する。ここでは、アジマス圧縮処理部１３８は、ＦＦＴ後参照関数に基づき、ＦＦＴ後データをアジマス圧縮する。アジマス圧縮処理部１３８は、例えば、切り出された画像の１アジマスラインとアジマス圧縮用の参照関数について、周波数領域で掛け合わせることで、アジマス圧縮（相関処理）を行う。これにより、時間領域におけるアジマス方向への高分解能化を図る。
ＩＦＦＴ処理部１４０は、アジマス圧縮処理部１３８がアジマス圧縮したアジマス圧縮後データを逆高速フーリエ変換（ＩＦＦＴ）し、ＩＦＦＴ後データを処理装置により生成する。ＩＦＦＴ処理部１４０は、周波数領域でアジマス圧縮処理されたデータについて、ＩＦＦＴを行うことで、ＩＳＡＲ処理画像を生成する。
参照関数生成部１４２は、ＳＡＲの移動情報と目標物の予測移動情報とに基づいたＳＡＲと目標物との距離関係情報に基づき参照関数を処理装置により生成して記憶装置９８２に記憶する。参照関数生成部１４２は、例えば、上記式１６の参照関数Ｅ_ｒｅｆを生成する。予測移動情報とは、速度入力部１１６が入力した予測移動速度である。例えば、上記式１６はレンジドップラー再生方式を対象に生成しているが、再生方式はこれに限定するものではなく、スポットライトなど、それ以外の再生方式でも構わない。他の再生方式の場合であっても、アジマス圧縮を遡って実施することで対応できる。

The FFT processing unit 136 uses the processing device to generate post-FFT data obtained by performing complex fast Fourier transform on the zero-padded data generated by the zero-padding processing unit 134 for each azimuth line and converting the data into the frequency domain. Further, the FFT processing unit 136 performs FFT on the reference function generated by the reference function generation unit 142 described later, and generates a post-FFT reference function by the processing device.
The azimuth compression processing unit 138 performs azimuth compression on the range-compressed data input by the data input unit 112 based on a reference function generated by a reference function generation unit 142, which will be described later, and generates azimuth-compressed data by the processing device. Here, the azimuth compression processing unit 138 performs azimuth compression on the post-FFT data based on the post-FFT reference function. The azimuth compression processing unit 138 performs azimuth compression (correlation processing) by multiplying, for example, one azimuth line of the extracted image and a reference function for azimuth compression in the frequency domain. This achieves high resolution in the azimuth direction in the time domain.
The IFFT processing unit 140 performs inverse fast Fourier transform (IFFT) on the azimuth-compressed data that has been azimuth-compressed by the azimuth compression processing unit 138, and generates post-IFFT data by the processing device. The IFFT processing unit 140 generates an ISAR-processed image by performing IFFT on the data subjected to azimuth compression processing in the frequency domain.
The reference function generation unit 142 generates a reference function by the processing device based on the distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target, and stores the reference function in the storage device 982. For example, the reference function generation unit 142 generates the reference function E _ref of Expression 16 above. The predicted movement information is the predicted movement speed input by the speed input unit 116. For example, Equation 16 above is generated for the range Doppler playback method, but the playback method is not limited to this, and other playback methods such as spotlights may be used. Even in the case of other reproduction methods, it can be handled by retroactively performing azimuth compression.

The storage unit 160 includes a data storage unit 162.
The data storage unit 162 stores in the storage device 982 the data after IFFT obtained by performing IFFT on the data after azimuth compression generated by the azimuth compression processing unit 138. Here, the data storage unit 162 stores the post-IFFT data in the storage device 982 when the definition determination unit 122 determines that the definition is clear. For example, the data storage unit 162 stores, in the storage device 982, an image including a real part and an imaginary part in which a moving target is clarified.

The display unit 170 includes a data display unit 172.
The data display unit 172 displays the post-IFFT data generated by the IFFT processing unit 140 on the display device 984. The data display unit 172 displays the data after IFFT by calculating the power from the complex number.

  Next, the operation of the image sharpening apparatus 100 according to the first embodiment will be described with reference to FIG. FIG. 12 is a flowchart illustrating an image sharpening method based on the speed designation method ISAR, which is an operation of the image sharpening apparatus 100 according to the first embodiment.

First, in the data input step (S101), the data input unit 112 uses the input device 980 to input range-compressed data obtained by performing range compression on the target data observed by the SAR. Next, the range migration correction step (S102), the range migration correction unit 132 calculates the correction amount C _r in accordance with the range direction velocity v _R of the target, based on the calculated correction amount C _r, the data The range-compressed data input by the input unit 112 is subjected to range migration correction to generate corrected data. Here, the range migration correction unit 132 receives the distance r (t) between the SAR and the target obtained in a reference function generation step (S106) described later, and based on the received r (t), the range migration correction amount C _r is calculated. For example, the range migration correction unit 132 calculates the correction amount _Cr based on Equation 18. Next, in the zero padding processing step (S103), the zero padding processing unit 134 fills the corrected data generated by the range migration correcting unit 132 with zeros, thereby setting the number of pixels of the corrected data to a power of two. The padding data is generated by the processing device. Here, the zero padding processing unit 134 calculates the number of pixels to be padded with zeros based on, for example, Expressions 19 and 20. Next, in the fast Fourier transform processing step (S104), the FFT processing unit 136 performs FFT on the zero padded data generated by the zero padding processing unit 134 and generates post-FFT data by the processing device.

In part with the above processing, in the accompanying information input step (S105), the accompanying information input unit 120 inputs image accompanying information accompanying the image such as the position of the SAR and the speed of the SAR by the input device 980. Further, here, the reference function information input unit 114, the moving predicted speed at which the predicted travel speed _v A of the target, _{v R} start time alpha _start the synthetic aperture end time of time _{T A_isar} synthetic aperture time _{T A_isar} Synthetic opening time information having α _end is input by the input device 980. Next, in the reference function generation step (S106), the reference function generation unit 142 processes the reference function based on the distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target. And is stored in the storage device 982. For example, the reference function generation unit 142 generates the reference function E _ref of Expression 16 above. In addition, the reference function generation unit 142 outputs r (t) to (S102). Next, in the fast Fourier transform processing step (S107), the FFT processing unit 136 performs FFT on the reference function generated by the reference function generation unit 142 and generates a post-FFT reference function by the processing device.

Next, in the azimuth compression processing step (S108), the azimuth compression processing unit 138 performs the fast Fourier transform processing step (S104) based on the post-FFT reference function generated by the FFT processing unit 136 in the fast Fourier transform processing step (S107). Then, the post-FFT data generated by the FFT processing unit 136 is azimuth compressed, and the post-azimuth compressed data is generated by the processing device. Next, in the inverse fast Fourier transform processing step (S109), the IFFT processing unit 140 performs inverse fast Fourier transform (IFFT) on the azimuth-compressed data that has been azimuth-compressed by the azimuth compression processing unit 138, and the post-IFFT data is processed by the processing device. Generate. Next, in the data display step (S110), the data display unit 172 displays the post-IFFT data generated by the IFFT processing unit 140 on the display device 984. Next, in the sharpness determination input step (S111), the sharpness determination input unit 122 inputs, using the input device 980, a determination as to whether or not the data after IFFT displayed by the data display unit 172 is clear. When the sharpness determination input unit 122 inputs that the target is not clear (No in S111), the reference function information input unit 114 displays the predicted moving speeds v _A and v _R that are predicted speeds of movement of the target and the synthetic aperture time. entering through the input device 980 a synthetic aperture time information and a end time alpha _{end the} of T _{A_isar} start time alpha _start the synthetic aperture time _{T A_isar.} Then, the processes from the reference function generation step (S106) and the range migration correction step (S102) are performed again, and the processes are repeated until the image becomes clear. On the other hand, when the sharpness determination input unit 122 inputs that it is clear (Yes in S111), the process proceeds to the data storage step (S112). In the data storage step (S <b> 112), the data storage unit 162 stores in the storage device 982 post-IFFT data obtained by performing IFFT on the post-azimuth compressed data generated by the azimuth compression processing unit 138.

  According to the first embodiment, the target can be reproduced clearly even if different speed clutters are included in the image. Further, according to the first embodiment, the target can be clarified even when the target exists in the presence of other high brightness objects such as land.

  That is, according to the first embodiment, it is possible to realize ISAR processing that does not depend on the intensity of luminance of the target.

Embodiment 2. FIG.
Next, a second embodiment will be described. In the second embodiment, an image sharpening device 100 including a speed measuring device that measures the speed of the target object together with the sharpening of the target image in the first embodiment will be described.

First, the speed calculation of the target by the speed specification method ISAR will be described with reference to FIGS.
FIG. 13 is a diagram showing target speed calculation by the speed designation method ISAR when only one moving target exists. When range-compressed data having only one moving target is input and processed by the speed designation method ISAR, the target is successfully clarified when the speed of the target is input. Here, the speed of the target inputted when the target is sharpened is the correct speed of the target.
FIG. 14 is a diagram illustrating calculation of the speed of a target by the speed designation method ISAR when there is a moving target and a clutter having a speed different from that of the target and having high luminance. If you input the data after range compression in which there is a moving target and a clutter that has a different speed from the target and has strong brightness, and processed by the speed specification method ISAR, the target will be Clutters that are sharpened and have different speeds are blurred. Similar to the case where there is only one moving target, the speed of the target input when the target is sharpened is the correct target speed.

  Next, functions of the image sharpening device 100 according to the second embodiment will be described with reference to FIG. FIG. 15 is a functional block diagram illustrating functions of the image sharpening apparatus 100 according to the second embodiment. Here, only parts different from the function of the image sharpening apparatus 100 according to the first embodiment will be described.

The image sharpening device 100 according to the second embodiment includes a speed determining unit 144 in addition to the image sharpening device 100 according to the first embodiment.
Speed determining unit 144, the sharpness when the decision input unit 122 generates a reference function used to generate the data after azimuth compression type is sharp, predicted velocity v _A of the reference function generating unit 142 is used , V _R is determined by the processing device to be the speed of the target. Here, the speed of the target has a speed in the range direction and a speed in the azimuth direction.

That is, in the flowchart shown in FIG. 12, when the sharpness determination input unit 122 inputs that it is clear in the sharpness determination input step (S111) (Yes in S111), the speed determination unit 144 has the reference function generation unit 142. The processing device determines that the predicted speeds v _A and v _R used by are the target speeds. In the data storage step (S112), the data storage unit 162 stores the predicted speeds v _A and v _R determined by the speed determination unit 144 in the storage device 982 as the target speed.

  According to the second embodiment, the moving speed of the target can be calculated together with the sharpening of the target image.

Embodiment 3 FIG.
Next, Embodiment 3 will be described. In the third embodiment, an image sharpening device 100 including an image sharpness determination device that determines the sharpness of an image of a target will be described. In the above embodiment, the sharpness determination input unit 122 inputs the determination as to whether or not the image is clear, thereby determining the sharpness of the image. However, in the third embodiment, the sharpness of the image is mechanically determined to obtain the sharpest target image and the target speed.

First, a process for obtaining a clear target image in the above embodiment will be described with reference to FIG. FIG. 16 is a diagram illustrating an operation of the image sharpening apparatus 100 that determines the sharpness of an image by inputting a determination as to whether or not the image is clear.
In the image sharpening apparatus 100 that determines the sharpness of an image by inputting a determination as to whether or not the image is clear, first, the image after range compression, the predicted speed in the range direction, the predicted speed in the azimuth direction, and the like. Enter. Next, based on the input data, the speed designation method ISAR processing is performed up to the inverse fast Fourier transform processing step (S109). The generated image is displayed, and it is determined whether the image of the target is clear by visual observation or the like, and the determination is input. If the image is not clear, the above process is repeated until a clear image is obtained.

Next, processing for obtaining a clear target image in the third embodiment will be described with reference to FIG. FIG. 17 is a diagram illustrating the operation of the image sharpening apparatus 100 that mechanically determines the sharpness of an image.
The image sharpening apparatus 100 that mechanically determines the sharpness of an image inputs the image after the range compression, and outputs a mechanically clearest target image.
Therefore, although it took a lot of time to obtain a clear image, such as when the target moves in a complex manner within the synthetic aperture time for ISAR, the problem can be solved by using the method of the third embodiment. Can do.

Next, an overview of the image definition method of the image definition device according to Embodiment 3 will be described with reference to FIGS.
FIG. 18 is a diagram illustrating an example of a case where blurring occurs where an image is not clear. When a reference function that does not match is input to an image after range compression and azimuth compression processing is performed, the image after azimuth compression is blurred and a clear image cannot be obtained. That is, if the predicted speed of the target is different from the actual speed of the target, the reference function does not match, so that a clear image cannot be obtained. In this case, the peak of the amplitude value indicating the luminance of the target of the image after azimuth compression is low.
FIG. 19 is a diagram illustrating an example in which an image becomes clear. When a matching reference function is input to the image after range compression and azimuth compression processing is performed, a clear image that does not blur the image after azimuth compression is obtained. That is, the reference function matches when the predicted speed of the target is equal to the speed of the actual target, and a clear image is obtained. In this case, the peak of the amplitude value indicating the luminance of the target of the image after azimuth compression becomes high.

  Next, functions of the image sharpening device 100 according to the third embodiment will be described with reference to FIG. FIG. 20 is a functional block diagram illustrating functions of the image sharpening device 100 according to the third embodiment. Here, only parts different from the functions of the image sharpening device 100 according to the second embodiment will be described.

The image sharpening device 100 according to the third embodiment includes a sharpness calculation unit 146 in addition to the image sharpening device 100 according to the second embodiment. Further, the image sharpening device 100 according to the third embodiment may not include the sharpness determination input unit 122.
The definition calculator 146 calculates the definition of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated by the azimuth compression processing unit 138 by the processing device. The sharpness calculation unit 146 searches for the peak value of the amplitude representing the luminance of the pixel of the image indicated by the azimuth compression data generated by the azimuth compression processing unit 138, and the higher the peak value, the clearer the image. Judge that there is.
The speed input unit 116, for example, set the range _v a_max predicted velocity _{v A} of the azimuth _{direction, v A_mix} the range direction of predicted velocity _v range of _{R v r_max,} the _{v R_mix} and azimuth compression number N, less The input speed is calculated as shown in Equation 21, and the calculated speed is input.

  Next, the operation of the image sharpening apparatus 100 according to the third embodiment will be described with reference to FIG. FIG. 21 is a flowchart illustrating an image sharpness determination method for automating image sharpening by the speed designation method ISAR, which is an operation of the image sharpening apparatus 100 according to the third embodiment. Here, only parts different from the operation of the image sharpening apparatus 100 according to the second embodiment will be described.

First, S202 to S204 and S206 to S211 are set as a processing group A, and the processing group A is repeatedly executed while changing the speed input by the speed input unit 116 in a speed input step (S210) described later. The processing group A is repeated N times based on the above formula 21, for example.
Here, S201 to S209 are the same as S101 to S109, respectively.
At speed input step (S210), the speed input unit 116 inputs the input device 980 the predicted velocity v _a of the predicted velocity v _r and the azimuth direction of a predicted velocity range direction of movement of the target is. Speed input unit 116, for example, set the range _v a_max predicted velocity _{v A} of the azimuth _{direction, v A_mix} the range direction of predicted velocity _v range of _{R v r_max,} the _{v R_mix} and azimuth compression number N, the formula 21 The input speed is calculated as follows, and the calculated speeds v _r and v _a are input. In the sharpness calculation step (S211), the sharpness calculation unit 146 calculates the sharpness of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated by the azimuth compression processing unit 138 by the processing device. Next, in the speed determination step (S212), the speed determination unit 144 refers to the reference function used to generate the azimuth-compressed data having the highest sharpness calculated by the sharpness calculation unit 146. The predicted speeds v _R and v _A used by the function generator 142 are determined by the processing device as being the speed of the target. Next, in the data storage step (S213), the data storage unit 162 stores, in the storage device 982, the data determined by the definition calculation unit 146 to have the highest definition in the processing group A that has been executed a plurality of times. Here, as in the second embodiment, the data storage unit 162 stores the predicted speeds v _A and v _R input when calculating data determined to have high definition as the target speed.

In the operation of the image sharpening apparatus 100 shown in FIG. 21, a process for searching for the highest sharpness is performed while changing the predicted speeds v _R and v _A. Next, the operation of the image sharpening device 100 that performs processing for searching for the highest sharpness while changing the synthetic aperture time T _{A_isar} in addition to the predicted speeds v _R and v _A will be described with reference to FIG. FIG. 22 is a flowchart illustrating the operation of the image sharpening apparatus 100 that performs a process of searching for the highest sharpness while changing the synthetic opening time T A — _isar in addition to the predicted speeds v _r and v _a . Here, only parts different from the operation of the image sharpening apparatus 100 shown in FIG. 21 will be described.

First, S202 to S204, S206 to S211 and S213 are set as processing group B, and the synthetic aperture time information input by the synthetic aperture time information input unit 118 in the synthetic aperture time information input step (S213) described later is changed. However, the processing group B is repeatedly executed. Treatment group B, for example, a synthetic aperture time T _A of the SAR and M division, repeated each of the M synthetic aperture time times. That is, for each processing group B that is executed M times, the processing group A is executed N times. That is, the processing group A is executed M × N times.
Here, S201 to S212 are the same as the operation of the image sharpening apparatus 100 shown in FIG.
In the synthetic aperture time information input step S213, the synthetic aperture time information input unit 118 uses the input device 980 to input synthetic aperture time information _including the start time α _start of the synthetic aperture time _{TA_isar} and the end time α _end of the synthetic aperture time. To do. Synthetic aperture time information input unit 118 is, for example, a synthetic aperture time T _A of the SAR and M division, inputs the M pieces each synthetic aperture time information.

  According to the third embodiment, it can be mechanically determined whether or not the target image is clear. Therefore, when the movement of the target within the synthetic aperture time for SAR is complicated, it takes a considerable time to obtain a high-quality ISAR image. According to the third embodiment, the time is reduced. It is possible to reduce the time required for obtaining a high-quality ISAR image.

Embodiment 4 FIG.
Next, a fourth embodiment will be described. In the fourth embodiment, an image sharpening device 100 that sharpens an image of a target when the target included in the SAR reproduced image (image after azimuth compression) is blurred will be described.

First, image reproduction by the isolated scattering point method ISAR when an image after azimuth compression is input will be described with reference to FIGS.
FIG. 23 is a diagram showing image reproduction by the isolated scattering point method ISAR when an image after azimuth compression in which a plurality of targets having different velocities exist is input. In this case, as described with reference to FIG. 3, a portion where only one target is present is cut out from the image after azimuth compression, and image reproduction by the isolated scattering point method ISAR is performed, so that an image of the target contained in the cut-out portion is obtained. Can be clarified. However, as described with reference to FIG. 4, if another target (clutter) is included in the portion cut out from the image after azimuth compression other than the target to be clarified, image reproduction by the isolated scattering point method ISAR is performed. The target image will fail to be sharpened even if
FIG. 24 is a diagram showing image reproduction by the isolated scattering point method ISAR when an image after azimuth compression in which a moving target on land exists is input. In this case, even if a portion including the target is cut out from the image after the azimuth compression and the image is reproduced by the isolated scattering point method ISAR, the image of the target fails to be sharpened due to the influence of the reflection from the land of zero speed. .

Next, image reproduction by the speed designation method ISAR when an image after azimuth compression is input will be described with reference to FIGS.
FIG. 25 is a diagram showing image reproduction by the speed designation method ISAR when an image after azimuth compression in which a plurality of targets having different speeds is present is input. In this case, as described in FIG. 5, a portion where only one target is present is cut out from the image after azimuth compression, and the image of the target contained in the cut out portion is obtained by performing image reproduction by the speed designation method ISAR. It can be sharpened. Further, as described with reference to FIG. 6, even if the target segment (clutter) is included in the portion cut out from the image after azimuth compression in addition to the target to be clarified, the image reproduction by the speed designation method ISAR is performed. By performing the above, the image of the target can be clarified.
FIG. 26 is a diagram showing image reproduction by the speed designation method ISAR when an image after azimuth compression in which a moving target on land exists is input. In this case, it is possible to sharpen the image of the target without being affected by the reflection from the land by cutting out a portion including the target from the image after the azimuth compression and performing the image reproduction by the speed designation method ISAR.

Next, a method for sharpening a target image when the target included in the image after azimuth compression by the image sharpening apparatus 100 according to the fourth embodiment is blurred will be described with reference to FIG. FIG. 27 is a diagram illustrating a method for sharpening an image of a target when the target included in the image after azimuth compression by the image sharpening device 100 according to the fourth embodiment is blurred.
First, a portion including the target is cut out from the input image after azimuth compression. In this case, any part may be used as long as the target is included, and clutter may be included. Next, the azimuth compression of the cut image is decompressed. By decompressing azimuth compression, data after range compression is generated. By performing image reproduction by the speed designation method ISAR on the data after the range compression, the target is clarified.

  Next, functions of the image sharpening device 100 according to the fourth embodiment will be described with reference to FIG. FIG. 28 is a functional block diagram illustrating functions of the image sharpening device 100 according to the fourth embodiment. Here, only parts different from the function of the image sharpening apparatus 100 according to the third embodiment will be described.

The image sharpening device 100 according to the fourth embodiment includes an image cutout unit 148 and an azimuth decompression processing unit 150 in addition to the image sharpening device 100 according to the third embodiment.
The image cutout unit 148 cuts out a partial image including the target from the image after azimuth compression input by the data input unit 112.
The azimuth decompression processing unit 150 decompresses azimuth compression for the image after azimuth compression.

  Here, thawing of azimuth compression refers to performing azimuth compression processing in reverse. Here, the azimuth compression processing is azimuth compression processing performed on the input image. Therefore, it is usually considered that the azimuth compression processing is based on the reference function not considering the movement of the target, rather than the azimuth compression processing based on the reference function considering the movement of the target. Therefore, instead of the azimuth compression processing based on the reference function in consideration of the movement of the target shown in the first embodiment, the azimuth decompression processing is performed based on the reference function obtained as follows, for example.

In the SAR, due to its imaging principle, the SAR moves at a certain speed. The SAR image always includes SAR flight information, reproduced image position information, and synthetic aperture time, and the relative distance relationship between the SAR and the target shown in Expression 22 can be calculated. From this, the Doppler frequency change can be calculated as shown in Equation 23 in the same manner as in the first embodiment. Then, the reference function E _ref for azimuth compression used at the time of reproducing the SAR image can be obtained as shown in Expression 24.

なお、ここでは、レンジ−ドップラ再生方式を対象としているが、これに限定するわけではなく、スポットライトなど、それ以外の再生方式でもアジマス圧縮を逆に実施することで対応できる。

Here, the range-Doppler reproduction method is targeted, but the present invention is not limited to this, and other reproduction methods such as spotlight can be dealt with by reversely performing azimuth compression.

Next, based on FIG. 29 and FIG. 30, the influence of the movement of the target in the frequency domain is shown below using the formula described in the first embodiment, and the influence of azimuth decompression will be described. FIG. 29 is a diagram illustrating the influence when the target moves in the range direction in the frequency domain. FIG. 30 is a diagram illustrating the influence when the target moves in the azimuth direction in the frequency domain.
As shown in FIG. 29, when the target moves in the range direction in the frequency domain, there is no change in the band, but a shift occurs. As shown in FIG. 30, when the target moves in the azimuth direction in the frequency domain, the band changes when the target moves in the direction opposite to the SAR. However, in other cases, it falls within the band of the target that does not move.

  When processing is reversed from SLC (single look complex) after convolution in the frequency domain, data lost due to frequency shift or band expansion accompanying movement cannot be reproduced. However, this is only a case where the out-of-band portion of the reference function assuming a stationary body is completely zero, and thus is generally not a problem.

  Next, the operation of the image sharpening device 100 according to the fourth embodiment will be described with reference to FIG. FIG. 31 is a flowchart illustrating an image sharpening method using a speed designation method ISAR process for a SAR reproduced image, which is an operation of the image sharpening apparatus 100 according to the fourth embodiment.

  In the data input step (S301), the data input unit 112 inputs an image after azimuth compression. Next, in the image cutout step (S302), the image cutout unit 148 cuts out a partial image including the target from the image after azimuth compression input by the data input unit 112. Next, in the zero padding processing step (S303), the zero padding processing unit 134 sets the number of pixels of the cut-out image to a power of 2 by padding the cut-out image with 0. The zero padding method may be the same as the method shown in the first embodiment. Next, in the fast Fourier transform processing step (S304), the FFT processing unit 136 performs FFT on the zero padded data generated by the zero padding processing unit 134 and generates post-FFT data by the processing device.

  In parallel with the above processing, in the incidental information input step (S305), the incidental information input unit 120 inputs image incidental information associated with the image such as the position of the SAR and the speed of the SAR by the input device 980. Next, in the azimuth compression reference function generation step (S306) for the stationary target, the reference function generation unit 142 generates a reference function that does not consider the movement of the target by the processing device. Next, in the fast Fourier transform processing step (S307), the FFT processing unit 136 performs FFT on the reference function generated by the reference function generation unit 142 and generates a post-FFT reference function by the processing device.

  Next, in the azimuth decompression processing step (S308), the azimuth decompression processing unit 150 performs the fast Fourier transform processing step (S304) based on the post-FFT reference function generated by the FFT processing unit 136 in the fast Fourier transform processing step (S307). The FFT data generated by the FFT processing unit 136 is azimuth-decompressed, and the azimuth-decompressed data is generated by the processing device. Next, in the inverse fast Fourier transform processing step (S309), the IFFT processing unit 140 performs IFFT on the data after azimuth decompression performed by the azimuth decompression processing unit 150, and generates the data after IFFT by the processing device. Then, in the image sharpening process step (S310) by the speed designation system ISAR process, the image reproduction by the speed designation system ISAR process shown in the above embodiment is performed. In the data storage step (S311), the data storage unit 162 stores the reproduced image and the calculated speed as in the above embodiment.

  According to the fourth embodiment, the speed designation method ISAR process can be performed using SAR reproduction image, ISAR reproduction image, or the like as input data. Therefore, it is possible to sharpen a target that is blurred because it is included in a SAR reproduction image that can be usually obtained and that is blurred because it exists on land.

It is the figure which showed an example of the external appearance of the image sharpening apparatus 100 concerning embodiment. It is a figure which shows an example of the hardware constitutions of the image sharpening apparatus 100 in embodiment. It is a figure which shows the sharpening of the target by the isolated scattering point system ISAR when there is only one target that moves. It is a figure which shows the sharpening of the target by the isolated scattering point system ISAR when there is a moving target and a clutter having a different speed from the target and having a high luminance. It is a figure which shows the sharpening of the target by the speed designation | designated system ISAR when only one target which moves exists. It is a figure which shows the sharpening of the target by the speed designation | designated system ISAR when the target which moves and the clutter which has a different speed from a target and a brightness | luminance exists. It is a figure showing the relative relationship (distance) after t second of SAR and a stationary body. It is a figure which shows the movement by rotation of the stationary body in FIG. It is a figure showing the relative relationship (distance) after t second of SAR and a mobile body. It is a figure which shows the movement of the mobile body in FIG. FIG. 2 is a functional block diagram illustrating functions of the image sharpening device 100 according to the first embodiment. 3 is a flowchart illustrating a shake target sharpening method by a speed designation method ISAR, which is an operation of the image sharpening device 100 according to the first embodiment. It is a figure which shows the speed calculation of the target by speed designation | designated system ISAR when only one target which moves exists. It is a figure which shows the speed calculation of the target by the speed designation | designated system ISAR when the target which moves and the clutter which has a speed different from a target, and a brightness | luminance exists. FIG. 4 is a functional block diagram illustrating functions of an image sharpening device 100 according to a second embodiment. It is a figure which shows operation | movement of the image sharpening apparatus 100 which judges the clarity of an image by inputting the determination whether an image is clear. It is a figure which shows operation | movement of the image sharpening apparatus 100 which mechanically determines the definition of an image. It is the figure which showed the example in case the blurring which an image does not become clear occurs. It is the figure which showed the example in case an image becomes clear. FIG. 9 is a functional block diagram illustrating functions of an image sharpening device 100 according to a third embodiment. 12 is a flowchart illustrating an automatic method of image sharpening by a speed designation method ISAR, which is an operation of the image sharpening device 100 according to the third embodiment. It is a flowchart which shows operation | movement of the image sharpening apparatus 100 which performs the process which searches the thing with the highest sharpness, changing also about synthetic | combination opening time in addition to prediction speed. It is the figure which showed the image reproduction by the isolated scattering point system ISAR when the image after the azimuth compression in which a plurality of targets having different velocities exist is input. It is the figure which showed the image reproduction by the isolated scattering point system ISAR when the image after the azimuth compression in which the land movement target exists is input. It is the figure which showed the image reproduction by the speed designation | designated system ISAR when the image after the azimuth compression in which the several target from which speed differs exists is input. It is the figure which showed the image reproduction by the speed designation | designated system ISAR when the image after azimuth compression in which the land movement target exists is input. FIG. 10 is a diagram illustrating a method for sharpening an image of a target when the target included in the image after azimuth compression by the image sharpening device according to the fourth embodiment is blurred. FIG. 6 is a functional block diagram illustrating functions of an image sharpening device 100 according to a fourth embodiment. It is a figure which shows the influence at the time of a target moving to the range direction in a frequency domain. It is a figure which shows the influence when a target moves to an azimuth direction in a frequency domain. 10 is a flowchart illustrating a shake target sharpening method using a speed designation method ISAR process for a SAR reproduced image, which is an operation of the image sharpening apparatus 100 according to the fourth embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 Image sharpening apparatus, 110 input part, 112 Data input part, 114 Reference function information input part, 116 Speed input part, 118 Synthetic opening time information input part, 120 Accompanying information input part, 122 Sharpness determination input part, 130 Process , 132 Range migration correction unit, 134 Zero padding processing unit, 136 FFT processing unit, 138 Azimuth compression processing unit, 140 IFFT processing unit, 142 Reference function generation unit, 144 Speed determination unit, 146 Sharpness calculation unit, 148 Image cut Output unit, 150 azimuth decompression processing unit, 160 storage unit, 162 data storage unit, 170 display unit, 172 data display unit, 901 CRT display device, 902 K / B, 903 mouse, 904 FDD, 905 CDD, 908 database, 909 System unit, 910 server, 11 CPU, 912 bus, 913 ROM, 914 RAM, 915 communication board, 920 magnetic disk unit, 921 OS, 922 window system, 923 program group, 924 file group, 931 telephone, 932 FAX machine, 940 Internet, 941 gateway, 942 LAN, 980 input device, 982 storage device, 984 display device.

Claims (25)

In an image sharpening device that sharpens an image of a target from data of the target observed by SAR (Synthetic Aperture Radar),
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device;
A reference function generation unit that generates a reference function by a processing device based on the distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target, and stores the reference function in the storage device;
Based on the reference function generated by the reference function generation unit, the azimuth compression processing unit that azimuth-compresses the range-compressed data input by the data input unit and generates the azimuth-compressed data by a processing device;
An image sharpening apparatus comprising: a data storage unit that stores data after azimuth compression generated by the azimuth compression processing unit in a storage device. The image sharpening device further includes:
A speed input unit for inputting a predicted moving speed, which is a predicted speed at which the target moves, by an input device;
2. The image sharpening device according to claim 1, wherein the reference function generation unit generates a reference function based on the predicted moving speed input by the speed input unit and the distance relation information. The speed input unit inputs a plurality of predicted moving speeds,
The reference function generation unit generates a plurality of reference functions based on each predicted movement speed and distance relationship information of the plurality of predicted movement speeds input by the speed input unit,
The azimuth compression processing unit generates a plurality of azimuth-compressed data based on each reference function of the plurality of reference functions generated by the reference function generation unit,
The image sharpening device further includes:
A sharpness calculation unit that calculates the sharpness of an image indicated by each post-azimuth compression data of the plurality of post-azimuth compression data generated by the azimuth compression processing unit;
3. The image sharpening device according to claim 2, wherein the data storage unit stores data having a highest image sharpness calculated by the sharpness calculation unit in a storage device. 3. The image sharpening device according to claim 2, wherein the speed input unit inputs a predicted moving speed in the range direction and a predicted moving speed in the azimuth direction as the predicted moving speed. 4. The image definition according to claim 3, wherein the definition calculation unit determines the definition of the image based on the luminance of the pixel of the image indicated by the data after azimuth compression generated by the azimuth compression processing unit. Device. The image sharpening device further includes:
A synthetic aperture time information input unit for inputting synthetic aperture time information having a start time of the synthetic aperture time and an end time of the synthetic aperture time by an input device;
2. The image sharpening device according to claim 1, wherein the reference function generation unit generates a reference function based on the synthetic aperture time information and the distance relation information input by the synthetic aperture time information input unit. The synthetic opening time information input unit inputs a plurality of synthetic opening time information,
The reference function generation unit generates a plurality of reference functions based on each synthetic opening time information and distance relation information of the plurality of synthetic opening time information input by the synthetic opening time information input unit,
The azimuth compression processing unit generates a plurality of azimuth-compressed data based on each reference function of the plurality of reference functions generated by the reference function generation unit,
The image sharpening device further includes:
A sharpness calculation unit that calculates the sharpness of an image indicated by each post-azimuth compression data of the plurality of post-azimuth compression data generated by the azimuth compression processing unit,
7. The image sharpening device according to claim 6, wherein the data storage unit stores data having a highest image sharpness calculated by the sharpness calculation unit in a storage device. 8. The image definition according to claim 7, wherein the definition calculation unit determines the definition of the image based on the luminance of the pixel of the image indicated by the data after azimuth compression generated by the azimuth compression processing unit. Device. The data input unit inputs the image after azimuth compression,
The image sharpening device further includes:
An azimuth decompression processing unit that decompresses azimuth compression for the image after azimuth compression input by the data input unit,
The azimuth compression processing unit generates azimuth-compressed data by performing azimuth compression on the data decompressed by the azimuth decompression processing unit based on the reference function generated by the reference function generation unit. The image sharpening device described. The image sharpening device further includes:
An image cutout unit that cuts out a partial image including the target from the image after azimuth compression input by the data input unit;
The image sharpening apparatus according to claim 9, wherein the azimuth decompression processing unit decompresses azimuth compression for the partial image cut out by the image cutout unit. The azimuth decompression processing unit decompresses azimuth compression for an image after azimuth compression using a reference function generated based on distance relationship information between a SAR and a target that is not based on predicted movement information of the target. The image sharpening device according to claim 9. 2. The image sharpening according to claim 1, wherein the azimuth compression processing unit performs azimuth compression on the range-compressed data based on a reference function equation 2 obtained from equation 1 representing distance relationship information between the SAR and the target. apparatus.

The reference function generation unit generates the reference function by substituting the predicted moving speed of the target and the synthetic opening time calculated based on the synthetic opening time information into the equation (2). 12. The image sharpening device according to 12. The image sharpening device further includes:
A correction amount is calculated according to the speed in the range direction of the target, and based on the calculated correction amount, a range migration correction unit that performs range migration correction on the range-compressed data input by the data input unit,
2. The image sharpening device according to claim 1, wherein the azimuth compression processing unit generates azimuth-compressed data by performing azimuth compression on the corrected data subjected to the range migration correction by the range migration correction unit. 2. The image sharpening apparatus according to claim 1, wherein the range migration correction unit calculates a correction amount based on the following Equation 3 and performs range migration correction based on the calculated correction amount.

In a velocity measuring device that measures the velocity of a target observed by a SAR (Synthetic Aperture Radar),
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device;
A speed input unit for inputting a plurality of predicted speeds by an input device;
A plurality of reference functions are processed by each predicted speed of the plurality of predicted speeds input by the speed input unit and distance relation information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target. A reference function generator that generates and stores the reference function in a storage device,
An azimuth compression processing unit that azimuth-compresses the range-compressed data input by the data input unit and generates a plurality of azimuth-compressed data by a processing device based on each reference function of the plurality of reference functions generated by the reference function generation unit When,
A definition calculation unit that calculates the definition of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated by the azimuth compression processing unit;
When generating the reference function used to generate the azimuth-compressed data having the highest definition calculated by the definition calculation unit, the predicted speed used by the reference function generation unit is the target speed. A speed measurement device comprising: a speed determination unit that is determined by a processing device. In an image sharpness determination device that determines the sharpness of an image of a target indicated by the data of the target observed by SAR (Synthetic Aperture Radar),
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device;
An azimuth compression processing unit that compresses the compressed data input by the data input unit with a processing device;
An image definition determination apparatus, comprising: a definition calculation unit that calculates the definition of an image based on the luminance of a pixel of an image indicated by azimuth-compressed data obtained by azimuth compression by the azimuth compression processing unit. 18. The image according to claim 17, wherein the sharpness calculation unit determines that the higher the peak value of the amplitude representing the luminance of the pixel of the image indicated by the azimuth-compressed data, the clearer the image. Sharpness determination device. In an image sharpening device that sharpens an image of a target from data of the target observed by SAR (Synthetic Aperture Radar),
A data input unit that inputs range-compressed data obtained by performing range compression on the target data observed by the SAR by an input device;
A range migration correction unit that performs range migration correction of the data after range compression input by the data input unit and generates corrected data by the processing device; and
A zero padding processing unit that generates zero padded data in which the number of pixels of the corrected data is a power of 2 by padding the post-correction data generated by the range migration correction unit;
An accompanying information input unit for inputting image accompanying information accompanying the image by an input device;
A reference function information input unit that inputs synthetic opening time information having a predicted moving speed that is a predicted speed at which the target moves, a start time of the synthetic opening time, and an end time of the synthetic opening time by an input device;
Based on the image accompanying information input by the accompanying information input unit, the predicted moving speed and the synthetic aperture time information input by the reference function information input unit, and the distance relation information between the SAR and the target, the reference function is obtained by the processing device. A reference function generator to generate;
The zero padded data generated by the zero padding processing unit is subjected to FFT (Fast Fourier Transform) to generate post-FFT data by a processing device, and further, the reference function generated by the reference function generating unit is FFTed to process the post-FFT reference function An FFT processing unit generated by the apparatus;
An azimuth compression processing unit that performs azimuth compression of post-FFT data by a processing device based on a post-FFT reference function;
IFFT processing unit that performs IFFT (inverse fast Fourier transform) on the azimuth-compressed data obtained by the azimuth compression processing unit and generates the post-IFFT data by a processing device;
A data display unit for displaying the post-IFFT data generated by the IFFT processing unit on a display device;
A definition input unit for determining whether or not the data after IFFT displayed by the data display unit is clear by an input device;
An image sharpening apparatus comprising: a data storage unit that stores the post-IFFT data in a storage device when the sharpness determination input unit determines that the data is clear. In an image sharpening method of an image sharpening device for sharpening an image of a target from data of the target observed by SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs data after range compression of the target data observed by the SAR by means of an input device;
A reference function generating step in which a reference function generating unit generates a reference function based on distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target, and stores the reference function in the storage device; ,
Based on the reference function generated in the reference function generation step, the azimuth compression processing step in which the data after the range compression input in the data input step is azimuth compressed and the azimuth compression processing unit generates the azimuth compression data by the processing unit;
A data storage step in which the data storage unit stores the post-azimuth compressed data generated in the azimuth compression processing step in a storage device. In an image sharpening program of an image sharpening device for sharpening an image of a target from data of the target observed by SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs data after range compression of the target data observed by the SAR by means of an input device;
A reference function generating step in which a reference function generating unit generates a reference function based on distance relationship information between the SAR and the target based on the movement information of the SAR and the predicted movement information of the target, and stores the reference function in the storage device; ,
Based on the reference function generated in the reference function generation step, the azimuth compression processing step in which the data after the range compression input in the data input step is azimuth compressed and the azimuth compression processing unit generates the azimuth compression data by the processing unit;
An image sharpening program which causes a computer to execute a data storage step in which a data storage unit stores data after azimuth compression generated in the azimuth compression processing step in a storage device. In a speed measuring method of a speed measuring device that measures the speed of a target observed by a SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs the data after the range compression on the target data observed by the SAR by the input device;
A speed input step in which a speed input unit inputs a plurality of predicted speeds by an input device;
Refer to a plurality of reference functions based on each predicted speed of the plurality of predicted speeds input in the speed input step, and distance relation information between the SAR and the target based on the SAR movement information and the target predicted movement information. A reference function generation step that is generated by the processing unit by the processing unit and stored in the storage unit;
Based on the reference functions of the plurality of reference functions generated in the reference function generation step, the range-compressed data input in the data input step is azimuth-compressed, and a plurality of azimuth-compressed data is generated by the processing device by the processing device. Azimuth compression processing step,
A definition calculation step in which the definition calculation unit calculates the definition of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated in the azimuth compression processing step;
When generating the reference function used to generate the azimuth-compressed data having the highest definition calculated in the definition calculation step, the speed determination unit determines that the speed input in the distance relation information is the target speed. And a speed determination step of determining by a processing device. In a speed measurement program of a speed measurement device that measures the speed of a target observed by a SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs the data after the range compression on the target data observed by the SAR by the input device;
A speed input step in which a speed input unit inputs a plurality of predicted speeds by an input device;
Refer to a plurality of reference functions based on each predicted speed of the plurality of predicted speeds input in the speed input step, and distance relation information between the SAR and the target based on the SAR movement information and the target predicted movement information. A reference function generation step that is generated by the processing unit by the processing unit and stored in the storage unit;
Based on the reference functions of the plurality of reference functions generated in the reference function generation step, the range-compressed data input in the data input step is azimuth-compressed, and a plurality of azimuth-compressed data is generated by the processing device by the processing device. Azimuth compression processing step,
A definition calculation step in which the definition calculation unit calculates the definition of the image indicated by each azimuth-compressed data of the plurality of azimuth-compressed data generated in the azimuth compression processing step;
When generating the reference function used to generate the azimuth-compressed data having the highest definition calculated in the definition calculation step, the speed determination unit determines that the speed input in the distance relation information is the target speed. A speed measurement program for causing a computer to execute a speed determination step determined by a processing device. In the image sharpness determination method of the image sharpness determination device that determines the sharpness of the image of the target indicated by the target data observed by the SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs the data after the range compression on the target data observed by the SAR by the input device;
An azimuth compression processing step in which the azimuth compression processing unit azimuth compresses the post-compression data input in the data input step by a processing device;
And a sharpness calculation step in which the sharpness calculation unit calculates the sharpness of the image based on the luminance of the pixel of the image indicated by the azimuth-compressed data that has been azimuth-compressed in the azimuth compression processing step. Sharpness judgment method. In the image sharpness determination program of the image sharpness determination device that determines the sharpness of the image of the target indicated by the target data observed by the SAR (Synthetic Aperture Radar),
A data input step in which the data input unit inputs the data after the range compression on the target data observed by the SAR by the input device;
An azimuth compression processing step in which the azimuth compression processing unit azimuth compresses the post-compression data input in the data input step by a processing device;
The computer executes a sharpness calculation step in which a sharpness calculation unit calculates the sharpness of an image based on the luminance of the pixel of the image indicated by the azimuth-compressed data compressed in the azimuth compression processing step. Image sharpness determination program.

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