JPH09102928A - Device and method for recording and reproducing digital image data - Google Patents

Abstract

PROBLEM TO BE SOLVED: To discriminate divided images in the case of reproducing a moving image when recording image data expressing a high definition image on a magnetic tape 8 dividing them for existent image data by one frame at a DVTR. SOLUTION: An image is picked up by using a CCD 11 having almost 130000 picture elements composed of 1440 horizontal picture elements and 960 vertical picture elements. At a DSP 13, a reduced image having almost 350000 picture elements composed of 720 horizontal picture elements and 480 vertical picture element and four divided images are generated. These images are recorded in a magnetic tape 8 after frames are formed. In a moving image reproducing mode, the reduced image and divided images with formed frames are displayed on a monitor display device 42 so that the reduced image or divided images can be discriminated at a glance. In a still picture reproducing mode, the source definition image is restored from four divided images and printed by a printer 41.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a digital image data recording apparatus and method for recording unit image data having a predetermined data amount in a unit image data recording area of a recording medium such as a digital video tape recorder, and the like. The present invention relates to an apparatus and method for reproducing image data from a recording medium that has been recorded.

[0002]

BACKGROUND OF THE INVENTION A digital video tape recorder (DVTR) images a subject using a solid-state electronic image pickup device such as a CCD and converts a video signal representing the subject image obtained by the image pickup into digital image data. Then, it is recorded on a magnetic tape. The CCD used in the image pickup section of the digital video tape recorder is 72 in the horizontal direction.
Generally, 0 pixels x 480 vertical pixels = about 350,000 pixels. In a digital video tape recorder, frame recording in which one frame is composed of two fields and a frame image is recorded, and field recording in which a field image for each field is recorded is possible. In the case of frame recording, continuous photographing is performed at a predetermined shutter speed at a period of 1/30 second, and in the case of field recording, continuous photographing is performed at a predetermined shutter speed at a period of 1/60 second. In both frame recording and field recording, the image data for one frame is recorded on the magnetic tape in a time of 1/30 second and using a recording area of 10 tracks.

[0003] Thus, digital video tape
In a recorder, one frame of image data of digital image data obtained by photographing a subject using a 350,000 pixel CCD is generally recorded on 10 tracks in 1/30 second. Recording methods have become standard in the industry (for example, NIKKEI ELECTRONI
CS BOOKS "Data Compression and Digital Modulation" pp. 137-
152 page, see Nikkei BP, 1993).

On the other hand, the image quality in the image pickup section of a digital video tape recorder depends on the number of pixels of the CCD, and the higher the number of pixels of the CCD, the higher the image quality. However, in order to improve the image quality, a CCD with a large number of pixels
In order to record the image data obtained from this CCD on a magnetic tape, a recording area of 1/30 seconds or more and a recording area of 10 tracks or more are required for recording the image data, and the above-mentioned digital video tape recorder is used. It will not meet the standards you have set.

In order to record the image data obtained by picking up an image of a subject using a CCD having a large number of pixels on a recording medium while maintaining compatibility with existing recording standards, the obtained image data is recorded in one frame. It suffices to record the image data by dividing it into minute image data amounts.

However, if the image data is simply divided and the divided image data is recorded on the magnetic tape so that the data amount of the image data obtained from the CCD having a large number of pixels becomes the image data amount for one frame, it is reproduced. It may not be possible to understand what the divided image represented by the divided image data represents. An operator who is viewing the reproduced image may erroneously think that a failure has occurred in the device.

[0007]

DISCLOSURE OF THE INVENTION The present invention uses a large amount of data by imaging in order to obtain a high-quality still image while maintaining compatibility with existing standards such as the recording standard of a digital video tape recorder. An object of the present invention is to obtain image data, and when this image data is divided and recorded on a recording medium, it is possible to know at reproduction time that the image is represented by the divided image data.

A digital image data recording apparatus according to the present invention includes a solid-state electronic image pickup device for generating a data amount n times as large as the image data amount of unit image data for one frame image, and the solid-state electronic image pickup device is used to capture an object. Image pickup means for outputting fine image data representing a subject image obtained by image pickup, the fine image data so that the data amount of the fine image data output from the image pickup means is equal to the data amount of the unit image data. Is divided into n pieces of divided image data, and identification data indicating which part of the fine image the divided image represented by the divided image data obtained by the image data dividing means corresponds to. Generated identification data generating means, n pieces of divided image data output from the image data dividing means The divided image data recording control means for recording in the unit image data recording area and the identification data generated by the identification data generating means are associated with the n pieces of divided image data to assist other than the unit image data recording area of the recording medium. An identification data recording control means for recording in the area is provided.

The present invention also provides a method of recording digital image data. That is, fine image data representing a subject image obtained by picking up an image of a subject using a solid-state electronic image pickup device that generates a data amount n times as large as the image data amount of unit image data for one frame of image is obtained. The fine image data is divided into n pieces of divided image data so that the data amount of the obtained fine image data is equal to the data amount of the unit image data, and the divided image data obtained by the image data division processing is used. Identification data indicating which part of the fine image the represented divided image corresponds to is obtained, and n divided image data obtained by the image data dividing process is recorded as n unit image data on a recording medium. Identification data generated by the identification data generation process recorded in the area is associated with the n pieces of divided image data, and the identification data of the recording medium is recorded. Characterized by recording in the auxiliary area other than the image data recording area.

When the image data and the identification data are recorded on the recording medium as described above, they are reproduced as follows. As the reproducing device, the data amount is the above from the fine image data obtained by imaging the subject using the solid-state electronic image pickup device that generates the data amount n times the image data amount of the unit image data for one frame image. The fine image data is divided into n divided image data so as to be equal to the data amount of the unit image data, and then recorded in n unit image data recording areas of the recording medium. A record in which identification data indicating which part of the fine image corresponds to the divided image is recorded in an auxiliary region other than the unit image data recording region associated with the n divided image data. A reading means for reading n pieces of the divided image data and the identification data from the medium, and a mode for selectively setting a moving image reproduction mode and a still image reproduction mode. Constant means based on the identification data read by said reading means in response to the still image reproduction mode is set by said mode setting means,
Fine image data restoring means for restoring and outputting the fine image data representing a fine image from the n pieces of divided image data, and reading by the reading means in response to the moving image reproduction mode being set by the mode setting means. Identification code data insertion for inserting identification code data into the n pieces of divided image data so as to display an identification code indicating which part of the fine image corresponds to the divided image on the basis of the obtained identification data. Means are provided.

As a reproducing method, a data amount is calculated from fine image data obtained by imaging a subject using a solid-state electronic image pickup device that generates a data amount n times the image data amount of unit image data for one frame image. Is equal to the data amount of the unit image data, the fine image data is n
It is determined to which part of the fine image the divided image, which is divided into the divided image data and then recorded in the n unit image data recording areas of the recording medium, and which is represented by the divided image data. The n pieces of divided image data and the identification data are read from the recording medium in which the identification data represented is associated with the n pieces of the divided image data and recorded in the auxiliary area other than the unit image data recording area, and the moving image reproduction mode is set. The still image reproduction mode can be selectively set, and a fine image is generated from the n divided image data based on the identification data read by the reading process in response to the setting of the still image reproduction mode. The fine image data represented is restored and output, and the identification data read by the reading means in response to the setting of the moving image reproduction mode. Based on data and inserts an identification code data into n of the divided image data to an identification code representing whether the corresponding where part of the definition image displayed on the divided image.

The unit image data corresponds to one frame image data according to the above-mentioned current industry standard.

The expression "equal to the data amount of unit image data" does not necessarily have to be equal in the unit of 1 byte. In short, since the standard defines the amount of data that can be recorded in the unit image data recording area of the recording medium, it should be understood as the amount of data that meets this standard.

In the present invention, a solid-state electronic image pickup device for generating image data having a data amount n times the image data amount of unit image data is used. Since a solid-state electronic image pickup device having a large number of pixels is used, a high quality image is captured at the stage of image pickup.

In order to record the image data thus obtained, which is capable of producing a high quality image, while maintaining compatibility with the recording method according to the existing standard and without damaging the image data. In the present invention, the image data obtained from the solid-state electronic image pickup device is divided into n pieces of divided image data. The n pieces of divided image data obtained by the division are recorded on the recording medium according to the standard recording method.

In this way, the image quality of the high quality image data obtained by the image pickup is preserved as it is and is recorded in a form conforming to the conventional standard. Therefore, when the still image mode is set, high-quality still images can be reproduced.

When the moving image reproducing mode is set, an identification code indicating which part of the fine image corresponds to the divided image is displayed. It can be seen that the image is a divided image, and moreover, the divided image representing which part of the fine image can be known.

The device for reproducing the still image may be configured independently. In this case, as a reproducing device, the amount of data is calculated from the fine image data obtained by capturing an image of a subject using a solid-state electronic image pickup device that generates n times the amount of image data of unit image data for one frame image. So as to be equal to the data amount of the unit image data, the fine image data is divided into n divided image data and then recorded in the n unit image data recording areas of the recording medium, and the divided image is divided. The divided image represented by the data is
Identification data indicating which part of the fine image corresponds to the n pieces of divided image data is recorded in an auxiliary area other than the unit image data recording area, and n pieces of the divided image are recorded from the recording medium. Reading means for reading image data and identification data, and fine image data restoration for restoring and outputting the fine image data representing a fine image from the n pieces of divided image data based on the identification data read by the reading means Means are provided.

As a reproducing method, the amount of data is calculated from the fine image data obtained by capturing an image of a subject using a solid-state electronic image pickup device that generates a data amount n times the image data amount of unit image data for one frame image. Is equal to the data amount of the unit image data, the fine image data is n
It is determined to which part of the fine image the divided image, which is divided into the divided image data and then recorded in the n unit image data recording areas of the recording medium, and which is represented by the divided image data. The n pieces of divided image data and the identification data are read from the recording medium in which the identification data represented is associated with the n pieces of the divided image data and recorded in the auxiliary area other than the unit image data recording area, and the reading processing is performed. Based on the read identification data, the fine image data representing a fine image is restored from the n pieces of divided image data and output.

Since the data amount of the image data becomes enormous, normally, the n divided image data obtained by the image data division processing are data-compressed and recorded in the n unit image data recording areas of the recording medium. Become. In this case, during reproduction, compressed image data will be decompressed to restore a fine image.

At the time of recording, a reduced image of a fine image represented by the fine image data obtained by the image pickup is displayed, reduced image data having a data amount of the unit image data is generated, and the reduced image data generation processing is performed. The reduced image data obtained by the above may be recorded in the unit image data recording area of the recording medium in association with the n pieces of divided image data.

As a result, a reduced image of a fine image can be obtained, and the state of the fine image can be known without restoring the fine image.

Part of the image data of at least one of the n pieces of divided image data and the reduced image data so that a frame is formed in the image may be image data representing the frame.

Since a frame is displayed during reproduction of a moving image, it can be understood that the image is a reduced image or a divided image only by looking at the frame.

In this case, when reproducing the still image, when the fine image data is restored from the n divided image data based on the identification data read by the reading process, it is formed inside the fine image. It is preferable to remove the image data representing the frame so as to remove the frame.

This makes it possible to prevent the image from becoming hard to see due to the frame inside the fine image.

Further, at the time of recording, a reduced image of a fine image represented by the fine image data obtained by the image pickup is displayed, reduced image data having a data amount of the unit image data is generated, and a part of the divided image is generated. The reduced image data generated by the reduced image data generation processing may be inserted into the divided image data obtained by the image data division processing so that the reduced image appears in the area.

When the reduced image data representing the reduced image of the fine image and having the data amount of the unit image data is recorded in the unit recording area, the reduced image appears in a part of the divided image. As described above, the reduced image data may be inserted into the divided image data read from the recording medium.

When a moving image is reproduced, a reduced image of the fine image which is the original of the divided image is displayed in the divided image, so that it is possible to know at a glance where the divided image is in the fine image.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Prior to the description of the structure and operation of a digital video tape recorder, an existing standard industry standard relating to a recording system on a magnetic tape by the digital video tape recorder will be described.

The recording format of the magnetic tape is shown in FIG. 6 (A).
And (B). FIG. 6A shows the tracks Tr of the magnetic tape 8, and a large number of tracks Tr are formed at a constant angle in the oblique direction with respect to the longitudinal direction of the magnetic tape 8. Of these many tracks Tr
One frame of digital image data is recorded using ten tracks.

The track format is shown in FIG. 6 (B). One track Tr includes a subcode recording area, a video recording area, an auxiliary recording area, an audio recording area, and a track information recording area. Information such as a time code and an absolute track number for high speed search is recorded in the sub code recording area. Digital image data representing a subject image is recorded in the video recording area. Data representing sound is recorded in the audio recording area. Information serving as a reference of the track Tr for the magnetic head to trace the center of the track Tr is recorded in the track information recording area. Auxiliary recording areas are provided discretely, and additional information is recorded in this auxiliary recording area.
The illustration of the gaps provided between the respective regions is omitted.

The CCD used in the image pickup section of a digital video tape recorder is generally (conventional) a horizontal C
72 horizontal direction with a CD transfer clock frequency of 13.5 MHz
A pixel with about 350,000 pixels of 0 pixels and 480 pixels in the vertical direction is used. Digital image data for one frame obtained by using such a CCD is recorded on the magnetic tape 8
Recorded on 10 tracks. This is an existing standard.

In order to improve the image quality of the image represented by the image data recorded on the magnetic tape 8, a CCD having a large number of pixels may be used. However, in a digital video tape recorder, the standard is set to record about 350,000 pixels of digital image data of 720 horizontal pixels and 480 vertical pixels on 10 tracks, so 350,000 pixels. C with more pixels than
If the digital image data obtained by picking up an image of a subject using a CD is recorded on the magnetic tape 8, it will be out of this standard. A digital video tape recorder according to the present invention uses a CCD having a number of pixels larger than the number of pixels of 350,000 pixels generally used in a digital video tape recorder to image an object, and a digital video tape recorder. It enables the recording of image data conforming to the conventional recording standard of a video tape recorder.

FIG. 1 shows an embodiment of the present invention and is a block diagram showing an electrical configuration of a digital video tape recorder (DVTR) capable of recording and reproducing digital image data. The overall operation of the digital video tape recorder is the system controller 10
Is governed by

As shown in FIG. 2, the CCD 11 used in the image pickup section of this digital video tape recorder has about 140 pixels of 1440 pixels in the horizontal direction and 960 pixels in the vertical direction.
It has a pixel count of 10,000 pixels, and it has 4
Double the amount of image data is obtained. The amount of image data for one frame obtained from the 1.4 million pixel CCD 11 corresponds to the amount of image data for four frames of the 350,000 pixel CCD.

In the digital video tape recorder of this embodiment, one frame of image data obtained from the CCD 11 is divided into four frames of image data, and each one frame is divided into 10 tracks and the magnetic tape 8 is used. By recording the image data onto the digital video tape recorder, it is possible to record image data conforming to the conventional recording standard of the digital video tape recorder while achieving high-quality shooting.

In the recording mode, the CCD 11 having the number of pixels of about 1.4 million pixels continuously shoots a subject at a constant cycle of 1 / 7.5 seconds. It is determined by so-called electronic shutter control so that the shutter speed for photographing is appropriate (for example, 1/60 second, or a shorter time than this if necessary).

A video signal representing a subject image is output from the CCD 11 every 1 / 7.5 seconds and is supplied to the analog / digital conversion circuit 12. The video signal is converted into digital image data in the analog / digital conversion circuit 12,
It is provided to a DSP (Disital Signal Processor) 13.

Horizontal input 1440 in the DSP 13
As shown in FIG. 3A, image data representing a reduced image of 720 horizontal pixels and 480 vertical pixels is generated from digital image data of approximately 1.4 million pixels of 960 vertical pixels. The reduced image data may be generated by performing a thinning process so that the number of pixels becomes 1/2 in both the horizontal and vertical directions. The DSP 13 also generates a divided image in addition to the reduced image. As shown in FIG. 2, a divided image is generated by generating a fine image of approximately 1.4 million pixels with 1440 pixels in the horizontal direction and 960 pixels in the vertical direction in the upper left area a ₁ , the upper right area a ₂ , the lower left area a ₃ and the lower right area. This is performed by dividing the area a ₄ (FIGS. 3 (b) to 3 (e)). The divided images a _{1 to} a ₄ are also images of about 350,000 pixels with 720 horizontal pixels and 480 vertical pixels.

When the reduced image and the divided image are generated in the DSP 13, a frame (shown by hatching) of the reduced image and the divided image is formed as shown in FIGS. 4 (a) to 4 (e). If it is a reduced image, a frame is formed around the reduced image as shown in FIG. In the case of divided images, if the frame is simply formed in the peripheral portion of the divided image, the central portion of the fine image may be erased. Therefore, in the divided image, a frame is formed so that the central portion of the fine image always remains as shown in FIGS. 4 (b) to 4 (e). The formation of the frame in the divided image can be easily realized by an addressing operation. In this way, a frame is formed on the reduced image and the divided image as shown in FIGS. 5 (a) to 5 (e).

Image data representing a reduced image and a divided image in which a frame is formed is given from the DSP 13 to the memory 14 and temporarily stored therein. The memory 14 stores about 350,000 pixel image data
It has the capacity to store pieces.

The image data stored in the memory 14 are sequentially read, passed through the DSP 13, and given to the data rearrangement circuit 15. In the data rearrangement circuit 15, the image data is shuffled according to the DVTR recording format. The image data shuffled in the data rearrangement circuit 15 is supplied to the data compression circuit 16.

In the data compression circuit 16, DCT (Discre
te Cosine Transform) processing, quantization processing, etc. are performed to compress the image data.
The image data compressed by the data compression processing circuit 16 is sequentially given to the error correction code addition circuit 17 and the error correction code is added thereto. The error correction code adding circuit 17 has a system
The auxiliary area data is also given from the controller 10.
This auxiliary area data is identification data indicating that the image data is reduced image data, divided image data, and which part of the fine image is the divided image. It is added to each of the data.

The image data output from the error correction code addition circuit 17 is given to the modulation circuit 18 and coded (for example, N
It is RZI encoded) and given to the recording / reproducing amplifier circuit 19. The image data amplified by the recording / reproducing amplifier circuit 19 is given to the magnetic head 20. This allows the magnetic head 20
By this, image data is recorded in the video recording area A ₂ of each track of the magnetic tape 8 and auxiliary area data is recorded in the auxiliary recording area A ₃ . Recording of audio data and track information is of course also performed.

The total data amount of the reduced image data and the four divided image data is the CC of 350,000 pixels which is generally used.
Since it corresponds to 5 times the data amount of the image data for one frame obtained by photographing the object using D, it is recorded on the magnetic track 8 using 50 tracks.

The digital video tape shown in FIG.
The recorder can also reproduce the digital image data recorded on the magnetic tape 8.

The reproduction modes include a still image reproduction mode and a moving image reproduction mode, and mode setting switches 51 and 52 for setting the still image reproduction mode and the moving image reproduction mode are provided. The signals set by the mode setting switches 51 and 52 are given to the system controller 10.

In both the still picture reproducing mode and the moving picture reproducing mode, the image data, auxiliary area data and other data recorded on the magnetic tape 8 are read by the magnetic head 31 and given to the recording / reproducing amplifier circuit 19. The data amplified by the recording / reproducing amplifier circuit 19 is demodulated by the demodulator circuit 32.
Given to. Data demodulation is performed in the demodulation circuit 32, and the result is given to the error correction circuit 33. If the data demodulated in the demodulation circuit 32 has a data error, the error correction circuit
At 33, error correction processing is performed. The digital image data representing the subject image among the data subjected to the error correction processing is applied to the data expansion circuit 34, and the auxiliary area data is applied to the system controller 10.

The image data compressed by the data expansion circuit 34 is subjected to data expansion processing. The digital image data decompressed in the data decompression circuit 34 is supplied to the data rearrangement circuit 35. In the data rearrangement circuit 35, the digital video tape
The array of image data according to the recording format of the recorder is returned to the original array of image data (deshuffling).

When the moving image reproduction mode is set by the moving image reproduction mode setting switch 52, the image data output from the data rearrangement circuit 35 is given to the monitor display device 42. As a result, the monitor display device 42 is shown in FIG.
As shown in (e), a reduced image and a divided image in which a frame is formed around the image are sequentially displayed. Since a frame is formed in the image displayed on the monitor display device 42, it can be known that it is a reduced image or a divided image. Further, in the reproduction of the moving image, the reduced image and the divided image displayed on the monitor display device 42 display that the image is a reduced image, that it is a divided image, and what part of a fine image is the divided image. You may In this case, the auxiliary area data provided to the system controller 10 will be used.

When the still image reproduction mode is set by the still image reproduction mode setting switch 51, the image data output from the data rearranging circuit 35 is given to the image synthesizing circuit 36. In the image synthesizing circuit 36, the processing for removing the frame of each image in FIGS. 5 (a) to 5 (e) is performed.
The image shown in ~ (e) is restored. When the image is restored, the divided images shown in FIGS. 3B to 3E are combined based on the auxiliary area data to restore the original fine image shown in FIG.
Image data representing this fine image is given from the image synthesizing circuit 36 to the printer 41, and the fine image shown in FIG. 2 is printed.

FIG. 7 shows another embodiment and is a block diagram showing the electrical construction of a digital video tape recorder. In this figure, the same parts as those shown in FIG.

The digital video tape shown in FIG.
In the moving image reproducing mode, the recorder displays the divided image following the reduced image on the monitor display device 42 as shown in FIGS. 5 (a) to 5 (e), while the digital video tape shown in FIG. In the recorder in the moving image reproduction mode, a reduced image is displayed in a part of the divided image as shown in FIGS. 8 (a) to 8 (d). Digital shown in Fig. 7
Since the processing at the time of recording in the video tape recorder and the processing in the still image reproduction mode at the time of reproduction are the same as those of the digital video tape recorder shown in FIG. 1, the case where the moving image reproduction mode is set will be described.

When the moving image reproduction mode is set, the reduced image data and the divided image data output from the data rearrangement circuit 35 are given to the DSP 13A. In the DSP 13A, a window W is set in a partial area of the divided image as shown in FIGS. 8 (a) -8 (d). The reduced image is further reduced, and the reduced image is incorporated in the window W. The image data representing the divided image in which the reduced image is incorporated in the window W is given from the DSP 13A to the monitor display device 42.
As a result, the monitor display device 42 displays the divided image in which the reduced image is displayed in the window W as shown in FIGS. 8 (a) to 8 (d). In the reduced image displayed in the window W, it is advisable to process the image data in the DSP 13A so that an area is indicated by a broken line so that the divided image corresponds to which part of the fine image.

Further, as shown in FIGS. 8A to 8D, the process of inserting the reduced image into the divided image may be performed not only at the time of reproducing the moving image but also at the DSP 13A at the time of recording.
In that case, it is necessary to record the fine image data so that the fine image can be restored in the still image reproduction mode.

In the above description, a CCD having four times the number of pixels of a general CCD is used to capture an image of a subject at a cycle of 1 / 7.5 seconds to obtain image data for one frame.
Although it is divided into frames and recorded on the magnetic tape, one frame is recorded using not only a CCD having four times the number of pixels of a general CCD but also a CCD having an arbitrary n times the number of pixels. Image data may be obtained. In this case, the data is divided and recorded on the magnetic tape according to the number of pixels of the CCD used for photographing.

In the above, each circuit is composed of hardware, but a part of the hardware circuit is
It can also be realized by software.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an electrical configuration of a digital video tape recorder.

FIG. 2 shows the configuration of a CCD.

3A is a reduced image, and FIGS. 3B to 3E are divided images.

4A to 4E show a process of forming a frame on a reduced image and a divided image.

5A to 5E show a reduced image and a divided image in which a frame is formed.

FIG. 6A shows a recording format of a magnetic tape, and FIG. 6B shows a track format.

FIG. 7 shows another embodiment of digital video
It is a block diagram which shows the electric constitution of a tape recorder.

8A to 8D show divided images in which a reduced image is partially incorporated.

[Explanation of symbols]

 8 Magnetic tape 10 System controller 13, 13A DSP 36 Image synthesis circuit

Claims (18)

[Claims] 1. A subject image obtained by imaging a subject using the solid-state electronic image pickup device, which includes a solid-state electronic image pickup device for generating a data amount n times as large as the image data amount of unit image data for one frame image. Of the fine image data output from the image pickup means so that the data amount of the fine image data output from the image pickup means is equal to the data amount of the unit image data. Image data dividing means for dividing, identification data generating means for generating identification data indicating which part of the fine image the divided image represented by the divided image data obtained by the image data dividing means, Divided image data for recording n divided image data output from the image data dividing means in n unit image data recording areas of a recording medium. Data recording control means and identification data recording control means for recording the identification data generated by the identification data generating means in an auxiliary area other than the unit image data recording area of the recording medium in association with the n divided image data. A digital image data recording device provided with. 2. The divided image data recording control means data-compresses the n divided image data output from the image data dividing means and records them in n unit image data recording areas of the recording medium. The digital image data recording device according to claim 1, which is a digital image data recording device. 3. A reduced image of a fine image represented by the fine image data output from said image pickup means,
The reduced image data generating means for generating reduced image data having a data amount equal to the data amount of the unit image data, and the reduced image data output from the reduced image data generating means are associated with n pieces of the divided image data. The image data recording apparatus according to claim 1, further comprising reduced image data recording control means for recording in a unit image data recording area of the recording medium. 4. Image data processing means for replacing part of image data of at least one of the n divided image data and the reduced image data with image data representing a frame so that a frame is formed in the image. Claim 1 or 3 provided with
The image data recording device described in. 5. A reduced image of a fine image represented by the fine image data output from said image pickup means,
Reduced image data generating means for generating reduced image data having the data amount of the unit image data, and divided image data obtained by the image data dividing means so that the reduced image appears in a partial area of the divided image. To
The digital image data recording apparatus according to claim 1, further comprising reduced image data inserting means for inserting the reduced image data generated by the reduced image data generating means. 6. The unit of data is the above-mentioned unit from the fine image data obtained by capturing an image of a subject using a solid-state electronic image sensor that generates a data amount n times the image data amount of unit image data for one frame image. The fine image data is divided into n divided image data so as to be equal to the data amount of the image data, and then recorded in the n unit image data recording areas of the recording medium and represented by the divided image data. From a recording medium in which identification data indicating which part of the fine image corresponds to the divided image is recorded in an auxiliary area other than the unit image data recording area in association with the n divided image data. a reading means for reading the n pieces of the divided image data and the identification data; a mode setting means for selectively setting a moving image reproduction mode and a still image reproduction mode; Based on the identification data read by the reading means in response to the still image reproduction mode being set by the mode setting means, the fine image data representing a fine image is restored from the n divided image data and output. The fine image data restoration means, and which part of the fine image corresponds to the identification data read by the reading means in response to the setting of the moving image reproduction mode by the mode setting means. A digital image data reproducing apparatus comprising identification code data insertion means for inserting identification code data into n pieces of the divided image data so that the identification code is displayed on the divided image. 7. A unit of image data is obtained from a fine image data obtained by capturing an image of a subject using a solid-state electronic image pickup device that generates a data amount n times the image data amount of unit image data for one frame image. The fine image data is divided into n divided image data so as to be equal to the data amount of the image data, and then recorded in the n unit image data recording areas of the recording medium and represented by the divided image data. From a recording medium in which identification data indicating which part of the fine image corresponds to the divided image is recorded in an auxiliary area other than the unit image data recording area in association with the n divided image data. Based on the reading means for reading the n pieces of divided image data and the identification data, and the identification data read by the reading means, the n pieces of the above A digital image data reproducing device comprising a fine image data restoring means for restoring and outputting the fine image data representing a fine image from the divided image data. 8. The n pieces of the divided image data are converted into image data representing a frame so that a frame is formed in the divided image, and then the n pieces of the unit image data recording areas are recorded. When the fine image data is restored from the n divided image data based on the identification data read by the reading means, the frame formed inside the fine image is removed. 8. The digital image data reproducing apparatus according to claim 6, further comprising frame image data removing means for removing the image data representing the frame. 9. A reduced image of the fine image, reduced image data having a data amount of the unit image data is recorded in the unit image data recording area, and the reduced image is provided in a partial area of the divided image. 8. The digital image data reproducing apparatus according to claim 6, further comprising reduced image data inserting means for inserting the reduced image data into the divided image data read from the recording medium so that an image appears. 10. Fine image data representing a subject image obtained by picking up an image of a subject using a solid-state electronic image pickup device that generates a data amount n times the image data amount of unit image data for one frame of image, The divided image obtained by dividing the fine image data into n pieces of divided image data so that the data amount of the fine image data obtained by the image pickup becomes the data amount of the unit image data, and obtained by the image data division processing. Identification data indicating which part of the fine image the divided image represented by the data corresponds to is obtained, and n divided image data obtained by the image data division processing is converted into n unit images of the recording medium. A unit of the recording medium is recorded in the data recording area and the identification data generated by the identification data generating process is associated with the n pieces of divided image data. A digital image data recording method that records in an auxiliary area other than the image data recording area. 11. The n pieces of divided image data obtained by the image data dividing processing are data-compressed and recorded in n unit image data recording areas of the recording medium.
The method for recording digital image data according to 10. 12. A reduced image obtained by the reduced image data generation process, which represents a reduced image of a fine image represented by the fine image data obtained by the image pickup, generates reduced image data having a data amount of the unit image data, and generates the reduced image data. Image data is recorded in the unit image data recording area of the recording medium in association with the n divided image data.
The image data recording method according to claim 10. 13. The method according to claim 10, wherein a part of the image data of at least one of the n divided image data and the reduced image data is replaced with image data representing a frame so that a frame is formed in the image. The image data recording method described in 12. 14. A reduced image of a fine image represented by the fine image data obtained by the image pickup, reduced image data having a data amount of the unit image data is generated, and the reduced image data is generated in a partial area of the divided image. 11. The digital image data recording method according to claim 10, wherein the reduced image data generated by the reduced image data generating process is inserted into the divided image data obtained by the image data dividing process so that a reduced image appears. 15. A unit of image data having a unit of the above data amount from fine image data obtained by capturing an image of a subject using a solid-state electronic image pickup device that generates a data amount n times the image data amount of unit image data for one frame image. The fine image data is divided into n divided image data so as to be equal to the data amount of the image data, and then recorded in the n unit image data recording areas of the recording medium and represented by the divided image data. From a recording medium in which identification data indicating which part of the fine image corresponds to the divided image is recorded in an auxiliary area other than the unit image data recording area in association with the n divided image data. The n pieces of divided image data and the identification data are read, and the moving image reproduction mode and the still image reproduction mode can be selectively set. N based on the identification data read by the above-mentioned reading process in response to the setting of the
The fine image data representing the fine image is restored from the individual divided image data and output, and which part of the fine image is generated based on the identification data read in response to the setting of the moving image reproduction mode. A method for reproducing digital image data, wherein identification code data is inserted into the n pieces of divided image data so that an identification code indicating whether or not is displayed on the divided image. 16. The unit of data is the above-mentioned unit from the fine image data obtained by picking up an image of a subject using a solid-state electronic image pickup device that generates a data amount of n times the image data amount of unit image data for one frame of image. The fine image data is divided into n divided image data so as to be equal to the data amount of the image data, and then recorded in the n unit image data recording areas of the recording medium and represented by the divided image data. From a recording medium in which identification data indicating which part of the fine image corresponds to the divided image is recorded in an auxiliary area other than the unit image data recording area in association with the n divided image data. The n pieces of divided image data and the identification data are read, and the n pieces of the divided image data are read based on the identification data read by the reading process. A method for reproducing digital image data in which the above-mentioned fine image data representing a fine image is restored and output. 17. The n pieces of divided image data are converted into image data representing a frame so that a frame is formed in the divided image, and then the n pieces of unit image data recording area are stored. When the fine image data is restored from the n divided image data based on the identification data read by the reading process, the frame formed inside the fine image is removed. 16. The image data representing the frame is removed as described above,
The method for reproducing digital image data according to item 16. 18. A reduced image of the fine image, reduced image data having a data amount of the unit image data is recorded in the unit image data recording area, and the reduced image is formed in a part of the divided image. 17. The digital image data reproducing method according to claim 15, wherein the reduced image data is inserted into the divided image data read from the recording medium so that an image appears.