JP4586044B2 - Image recording apparatus, control method therefor, and imaging apparatus - Google Patents

Description

The present invention relates to an image recording apparatus capable of dubbing image data, a control method therefor , and an imaging apparatus.

  2. Description of the Related Art Conventionally, in an imaging apparatus such as a video camera, a method has been devised in which a captured image is recorded on a magnetic tape and recorded in a nonvolatile memory and loaded into a personal computer. This is because a video camera has been developed for television and uses a magnetic tape as a recording medium, but a nonvolatile memory is easier to capture an image into a personal computer.

  Hereinafter, a conventional imaging apparatus will be described with reference to FIG. FIG. 7 is a block diagram illustrating an overall configuration of a conventional imaging apparatus.

  In FIG. 7, an imaging apparatus 100 includes an imaging lens 101, an aperture 102 for exposure control, an imaging element 103 that photoelectrically converts incident light, and a gamma process of an image signal connected to the imaging element 103. A signal processing circuit 104 that performs contour correction processing (aperture correction), white balance processing, encoding processing, and the like, and a magnetic tape recording device 105 that is connected to the signal processing circuit 104 via a changeover switch 110 and uses a magnetic tape as a recording medium. And a non-volatile memory recording device 106 that uses a non-volatile memory as a recording medium, a recording medium selection device 109 that switches connection between the signal processing circuit 104 and each recording device, and a signal processing circuit 104, and an image signal Image processing data table that stores various image processing data used for gamma processing, contour correction processing, and white balance processing Constituted by the Le 107.

  Incident light that has passed through the imaging lens 101 is imaged on the image sensor 103 after the exposure amount is adjusted by the diaphragm 102. The formed image is photoelectrically converted by the image sensor 103 and sent to the signal processing circuit 104. The signal processing circuit 104 performs gamma processing, contour correction processing, white balance processing, encoding processing, and the like on the transmitted image signal using various image processing data stored in the image processing data table 107. The image signal subjected to the image processing is output to the magnetic tape recording device 105 or the non-volatile memory recording device 106 selected by the recording medium selection device 109, and is recorded as image data. Various image processing data stored in the image processing data table 107 are adapted to the characteristics of the television monitor.

The magnetic tape recording device 105 mainly records moving image signals. For example, the recorded image signals are reproduced and viewed on a television monitor. The non-volatile memory recording device 106 mainly records an image signal of a still image. For example, the non-volatile memory is removed from the imaging device, the image signal is read out by a personal computer, and the image signal is viewed on a display monitor of the personal computer. Or print with a printer.
JP-A-7-184097

  However, in the conventional imaging apparatus, since the image processing data stored in the image processing data table 107 is adapted for television use, when an image is captured in a personal computer, the gamma characteristic, aperture, color, etc. Since it is not compatible with a display monitor of a personal computer, image reproducibility may be impaired.

  In general, a television monitor has a gamma characteristic of 2.2 and a color temperature characteristic of 9600K (NTSC Japan), whereas a personal computer display monitor has a gamma characteristic of 1.8 and a color temperature characteristic of 6500K (reference value), which are clearly different. There is. Since the display monitor of a personal computer has a higher resolution than that of a television monitor, excessive edge enhancement leads to a decrease in image quality. Furthermore, when the image is output to a printer by a personal computer, the contour is emphasized on the printer side, so that there are many cases where the contour is excessively emphasized. On the contrary, when the image processing data is matched with the display monitor of the personal computer, the image quality when displayed on the television monitor is lowered.

The present invention performs gamma correction, contour correction processing, or white balance processing according to the recording medium to be dubbed even when dubbing image data that has been subjected to different image processing between different types of recording media. the image recording apparatus and control method of that which is possible to perform, as well as an object to provide a.

In order to achieve the above object, a method for controlling an image recording apparatus according to claim 1 is characterized in that image data recorded on a first recording medium subjected to a first image processing suitable for a first medium is recorded on the first recording medium. In the control method of an image recording apparatus having recording control means for dubbing to a second recording medium of a type different from the first recording medium, when the recording control means performs the dubbing, the conversion processing means includes the first recording medium . for the image data recorded on the first recording medium is subjected to first image processing, gamma processing, contour correction processing, and, at least one of white balance processing, different from the first image processing It is characterized by comprising a step of performing a conversion process so that the second image processing suitable for the second medium is performed and the image data to be recorded on the second recording medium is obtained .

In order to achieve the above object, an image recording apparatus according to claim 5 is different from the first recording medium in the image data recorded on the first recording medium subjected to the first image processing. In an image recording apparatus having recording control means for dubbing to a second recording medium, when the recording control means performs the dubbing, an image that has been subjected to the first image processing and recorded on the first recording medium for the data, gamma processing, contour correction processing, and, to be recorded at least one of white balance processing, the first second image processing different from the image processing is performed the second recording medium has a conversion processing means for performing conversion processing so that the image data, the recording control means, after performing a conversion process by the conversion processing means to said first recording medium on the recorded image data Wherein the dubbing the image data into the second recording medium.
In order to achieve the above object, an imaging apparatus according to a tenth aspect includes an image recording apparatus according to any one of the fifth to ninth aspects, an imaging unit that forms an image of incident light and outputs image data. Image processing means for selectively performing first image processing or second image processing different from the first image processing on the image data, and the recording control means includes the image processing When the first image processing is performed on the image data by the means, the image data is applied to the first recording medium, and the second image processing is performed on the image data by the image processing means. When applied, the image data is recorded on the second recording medium, respectively.

According to the present invention, even when dubbing image data that has undergone different image processing between different types of recording media , the same gamma correction and contour correction as the image data recorded on the dubbing destination recording medium. Processing or white balance processing can be performed.

  FIG. 1 is a block diagram showing the overall configuration of an imaging apparatus that is a reference of the present invention.

  In FIG. 1, an imaging apparatus 100 includes an imaging lens 101, a diaphragm 102 for exposure control, an imaging element 103 that photoelectrically converts incident light, and a gamma process for an image signal connected to the imaging element 103. A signal processing circuit 104 that performs contour correction processing (aperture correction), white balance processing, encoding processing, and the like, and a magnetic tape recording device 105 that is connected to the signal processing circuit 104 via a changeover switch 110 and uses a magnetic tape as a recording medium. And a non-volatile memory recording device 106 using a non-volatile memory as a recording medium, and various image processing data connected to the signal processing circuit 104 via the changeover switch 111 and used for gamma processing, contour correction processing, and white balance processing of the image signal. Image processing data table 107A for tape and image processing data table for memory 107B and the signal processing circuit 104 and the recording device, and a recording medium selection unit 109 which performs the connection switching simultaneously between each of the image processing data table.

  In the above configuration, the recording medium selection device 109 selects the connection between the signal processing circuit 104 and the magnetic tape recording device 105 or the non-volatile memory recording device 106 with the changeover switch 110, and simultaneously the signal processing circuit 104 and the tape image. The connection with the processing data table 107A or the memory image processing data table 107B is selected by the changeover switch 111.

  Incident light that has passed through the imaging lens 101 is imaged on the image sensor 103 after the exposure amount is adjusted by the diaphragm 102. The formed image is photoelectrically converted by the image sensor 103 and sent to the signal processing circuit 104. The signal processing circuit 104 uses the various image processing data stored in either the tape image processing data table 107A or the memory image processing data table 107B selected by the recording medium selection device 109 to supply the supplied image. Signal gamma processing, contour correction processing, white balance processing, encoding processing, and the like are performed. When the magnetic tape recording device 105 is selected by the recording medium selection device 109, the image signal is processed by the image processing data in the tape image processing data table 107A and recorded as image data in the magnetic tape recording device 105. When the non-volatile memory recording device 106 is selected by the recording medium selection device 109, the image signal is processed with the image processing data in the memory image processing data table 107B and recorded as image data in the non-volatile memory 106.

  The magnetic tape recording device 105 uses a magnetic tape having a large storage capacity as a recording medium in order to record image data such as moving images. On the other hand, the nonvolatile memory recording device 106 uses a nonvolatile memory typified by a flash ROM (flash memory) as a recording medium. The non-volatile memory can record image data such as a still image and read it out at random, and since it is compact in size, it can be removed and directly connected to a personal computer or the like.

  The tape image processing data table 107A stores various image processing data for gamma processing, contour correction processing, and white balance processing suitable for a television monitor, and the memory image processing data table 107B stores a display monitor of a personal computer. Various image processing data of gamma processing, contour correction processing, and white balance processing suitable for the above are stored. As a result, image data suitable for a television monitor is recorded on the magnetic tape recording device 105, and image data suitable for a display monitor of a personal computer is recorded on the nonvolatile memory recording device 106.

  Usually, various characteristics are different between a television monitor and a display monitor of a personal computer. For this reason, an image captured and processed by an imaging device adapted to various characteristics on the premise of a television monitor is a balanced image when played back on a television monitor, but when played back on a personal computer display monitor Often results in an unbalanced image. Elements that affect the balance of the image include gamma characteristics, edge enhancement, and white balance.

  Next, gamma correction in the imaging apparatus of FIG. 1 will be described with reference to FIG. FIG. 2 is a characteristic diagram showing gamma characteristics of the tape image processing data table 107A and the memory image processing data table 107B of FIG.

  In FIG. 2, curve a represents the gamma characteristic of the image processing data stored in the tape image processing data table 107A, and curve b represents the gamma characteristic of the image processing data stored in the memory image processing data table 107B. Each is shown. The gamma coefficient of the gamma characteristic a is 0.45, which is suitable for a television monitor, and the gamma coefficient of the gamma characteristic b is 0.56, which is suitable for a display monitor of a personal computer.

  In general, the gamma characteristic is expressed by the following equation using an applied voltage V and emission luminance L of a television monitor or the like.

L = cVγ (where c is a constant, and γ (gamma characteristic) takes a value of 2 to 3).
In this equation, since the applied voltage V is proportional to the input RGB value, a similar relationship is assumed between the RGB value and the luminance value. Generally, making this relationship linear is a process called gamma correction.

  The gamma characteristic is 2.2 for NTSC television monitors (2.5 for NTSC systems in Japan), 2.8 for PAL television monitors, and 1.8 for personal computer display monitors. For example, when an image is reproduced on an NTSC television monitor, if the gamma coefficient is 0.45 in the signal processing of the imaging apparatus, the total gamma characteristic becomes 1 as an image on the television monitor, and the gamma characteristic is balanced. Can be played back.

  However, when an image from an imaging device with a gamma coefficient of 0.45 is reproduced on a display monitor of a personal computer having a different gamma characteristic, the total gamma characteristic is less than 1. For this reason, an image with poor gradation is reproduced.

  In the present imaging apparatus, as described above, the gamma characteristic is switched by selecting the tape image processing data table 107A or the memory image processing data table 107B in accordance with the switching of the recording medium, which is suitable for the selected recording medium. Gamma processing can be performed.

  Next, contour enhancement correction in the imaging apparatus of FIG. 1 will be described with reference to FIG. FIG. 3 is a waveform diagram showing the difference between the edge enhancement corrections of the tape image processing data table 107A and the memory image processing data table 107B of FIG. 1, and FIG. 3A shows the tape image processing data table 107A. FIG. 6B is a waveform diagram of a signal at the time of edge enhancement correction using the memory image processing data table 107B.

  In FIG. 3A, the signal waveforms of the signal before the contour emphasis processing, the tape contour emphasis signal, and the tape contour emphasis signal from the top are shown. The waveform of the tape contour emphasis signal is This is a signal obtained by adding a contour enhancement signal for tape to a signal before the contour enhancement processing. In FIG. 3B, each signal waveform of the signal before the contour emphasis processing, the memory contour emphasis signal, and the memory contour emphasis signal from the top is shown, and the waveform of the memory contour emphasis signal is This is a signal obtained by adding a contour enhancement signal for memory to a signal before the contour enhancement processing. Each of the edge enhancement signals of the tape edge enhancement signal and the memory edge enhancement signal constitutes image processing data stored in the tape image processing data table 107A and the memory image processing data table 107B, respectively.

  In general, in an imaging apparatus, contour enhancement processing is performed in order to increase the sharpness during reproduction on a television monitor. In the contour enhancement process, a contour signal generated from the high-frequency component is added to the image signal, and the sharpness of appearance is increased. However, since it is possible for a personal computer to perform image processing on a favorite image by a user, an image that is not subjected to normal edge enhancement processing is preferable as the material. In general, the resolution of a display monitor of a personal computer is higher than that of a television monitor, and the contour is excessively emphasized when the sharpness of the image is increased.

  In addition, when printing is performed using a printer with contour emphasis applied, many printer drivers also perform contour emphasis during printing. Therefore, if an image with contour emphasis is printed in advance, the contour portion becomes thicker. In many cases, the result is an unnatural image.

  In the present imaging apparatus, as described above, the tape image processing data table 107A or the memory image processing data table 107B is selected in accordance with the switching of the recording medium, and the contour correction processing is switched. A suitable contour correction process can be performed.

  Next, white balance correction in the imaging apparatus of FIG. 1 will be described with reference to FIG. FIG. 4 is a diagram showing the difference in target values of white balance between the tape image processing data table 107A and the memory image processing data table 107B of FIG. 1, and FIG. The figure shown, (b) is the figure which showed the target value of the white balance for memory.

  The target value of the tape white balance in FIG. 4A is stored in the tape image processing data table 107A and used as image processing data. FIG. 4B shows the target value of the memory white balance, which is stored in the memory image processing data table 107B, and is also used as image processing data.

  The target value of (a) in the figure is slightly warm because the television monitor has relatively high color temperature characteristics, but the target value of (b) is relatively low for the display monitor of a personal computer. The temperature characteristics are low, and the neutral setting is used in order to avoid the color on the white part during printing.

  In general, the color temperature characteristics of a television monitor vary depending on the television system and each region, but the NTSC system is 6740K (9300K in Japan's NTSC system), the PAL system and the HDTV (High Definition Television) system. It is 6504K. On the other hand, the color temperature characteristics of display monitors of personal computers have not been standardized by manufacturers, but due to the widespread use of the concept of color management, many are based on 6500K.

  Normally, white balance correction is performed so that G = R = B. Depending on the monitor, the image may appear amber or blue, and the display of a television monitor with a color temperature characteristic of 9300K and a display of a personal computer with 6500K. The same color is often not visible on the monitor.

  In the present imaging apparatus, the white balance target value is switched by selecting the tape image processing data table 107A or the memory image processing data table 107B in accordance with the switching of the recording medium as described above. White balance processing suitable for the image can be performed.

  Note that each recording device of the magnetic tape recording device 105 and the nonvolatile memory recording device 106 uses a magnetic tape and a nonvolatile memory as recording media, but other recording media may be used. The image processing data in the tape image processing data table 107A and the memory image processing data table 107B may have other different values.

  The imaging apparatus 100 uses gamma processing, contour correction processing, and white balance processing image processing data suitable for a television monitor and a personal computer display monitor, respectively, as a tape image processing data table 107A and memory image processing data. Each of the images is stored in the table 107B, and the magnetic tape recording device 105 or the nonvolatile memory recording device 106 is selected by the recording medium selection device 109, and the tape image processing data table 107A or the memory image processing corresponding to the selected recording device is selected. The image processing data in the data table 107B is selected, and the image signal is processed by the signal processing circuit 104 using the selected image processing data, and is recorded in the selected magnetic tape recording device 105 or nonvolatile memory recording device 106. By It is possible to record image data that has been subjected to optimal gamma processing, contour processing, and white balance processing for each recording device equipped with a fixed recording medium. An optimal image can be obtained according to the purpose of use such as use with a personal computer.

  An imaging apparatus according to an embodiment of the present invention will be described with reference to FIG. FIG. 5 is a block diagram showing the overall configuration of the imaging apparatus according to the embodiment of the present invention.

  In FIG. 5, an imaging apparatus 100 includes an imaging lens 101, a diaphragm 102 for exposure control, an imaging element 103 that photoelectrically converts incident light, and a gamma process of an image signal connected to the imaging element 103. A signal processing circuit 104 that performs contour correction processing, white balance processing, encoding processing, and the like, a magnetic tape recording device 105 that uses a magnetic tape as a recording medium, and a nonvolatile memory that are connected to the signal processing circuit 104 via a changeover switch 110 A non-volatile memory recording device 106 having a recording medium as a recording medium, a recording medium selecting device 109 for switching connection between the signal processing circuit 104 and each recording device, a magnetic tape recording device 105, and a non-volatile memory recording device 106 Are connected via the change-over switches 112 and 113, and the signal conversion for converting the image processing using the image processing conversion data is performed. A circuit 114, a first conversion data table 116 and a second conversion data table 117 which are connected to the signal conversion circuit 114 via the changeover switch 115 and store image processing conversion data used for image processing conversion, and signal conversion The circuit 114, each conversion data table, and a dubbing selection device 118 that simultaneously switches each connection between the recording devices.

  In the above configuration, the recording medium selection device 109 selects the connection between the signal processing circuit 104 and the magnetic tape recording device 105 and the nonvolatile memory recording device 106 by the recording medium selection device 109. The signal conversion circuit 114 converts image processing when image data recorded in the magnetic tape recording device 105 and the nonvolatile memory recording device 106 are dubbed to each other. Image processing conversion data is supplied from the first conversion data table 116 to the signal conversion circuit 114, and image processing conversion data different from the first conversion data table 116 is supplied from the second conversion data table 117 to the signal conversion circuit 114. Is done. The dubbing selection device 118 selects the dubbing direction using the changeover switches 112 and 113.

  Incident light that has passed through the imaging lens 101 is imaged on the image sensor 103 after the exposure amount is adjusted by the diaphragm 102. The formed image is photoelectrically converted by the image sensor 103 and sent to the signal processing circuit 104. The signal processing circuit 104 performs gamma processing, contour correction processing, white balance processing, encoding processing, and the like on the supplied image signal. The image signal is recorded as image data in the magnetic tape recording device 105 or the non-volatile memory recording device 106 selected by the recording medium selection device 109.

  When dubbing image data between the magnetic tape recording device 105 and the nonvolatile memory recording device 106, the recorded image data is first sent to the signal conversion circuit 114 via the changeover switch 112 or the changeover switch 113. The signal conversion circuit 114 uses the image processing conversion data stored in either the first conversion data table 116 or the second conversion data table 117 selected by the dubbing selection device 118 to perform gamma processing on the image data. , Contour correction processing, and white balance processing. When dubbing from the magnetic tape recording device 105 to the nonvolatile memory recording device 106 is selected by the dubbing selection device 118, the first conversion data table 116 is selected, and the nonvolatile memory recording device 106 transfers to the magnetic tape recording device 105. When dubbing is selected, the second conversion data table 117 is selected.

  Next, in the present embodiment, image data suitable for a television monitor is recorded on the magnetic tape recording device 105 and is suitable for a display monitor of a personal computer, similarly to the imaging device described with reference to FIGS. A case where image data is recorded in the nonvolatile memory recording device 106 will be described.

  When dubbing image data recorded on the magnetic tape recording device 105 for a television monitor to the nonvolatile memory recording device 106, it is necessary to convert the image data so as to be suitable for a display monitor of a personal computer. Therefore, dubbing is performed after the image data recorded on the magnetic tape recording device 105 is subjected to conversion processing such as gamma processing, contour correction processing, and white balance processing suitable for a display monitor of a personal computer. At this time, the image processing conversion data used for the conversion processing uses data stored in the first conversion data table 116. On the other hand, when dubbing image data recorded in the non-volatile memory recording device 106 for the display monitor of a personal computer to the magnetic tape recording device 105, the second conversion data table 117 is selected and the signal conversion circuit 114 selects it. Dubbing is performed after performing conversion processing suitable for a television monitor using the image processing conversion data.

  Although the magnetic tape and the nonvolatile memory are used as the recording media of the magnetic tape recording device 105 and the nonvolatile memory recording device 106, other recording media may be used.

  According to the above embodiment, the imaging apparatus 100 stores the first image processing conversion data used for conversion of the image data recorded on the magnetic tape recording apparatus 105 and the image data recorded on the nonvolatile memory recording apparatus 106. Conversion data table 116 and second conversion data table 117, and the first conversion data table 116 or the second conversion data when dubbing image data between the magnetic tape recording device 105 and the nonvolatile memory recording device 106. By converting image processing using each image processing conversion data stored in the data table 117, optimal gamma processing, contour correction processing, and white balance processing are performed for each recording device equipped with a predetermined recording medium. The recorded image data can be recorded, and the image data can be used for viewing and performance on a television monitor. Optimum image according to the use or the like intended use in coarsely braided computer is obtained.

  Next, an imaging apparatus according to another embodiment of the present invention will be described with reference to FIG. FIG. 6 is a block diagram showing an overall configuration of an imaging apparatus according to another embodiment of the present invention.

  In FIG. 6, an imaging apparatus 100 includes an imaging lens 101, a diaphragm 102 for exposure control, an imaging element 103 that photoelectrically converts incident light, and a gamma process of an image signal connected to the imaging element 103. A signal processing circuit 104 that performs contour correction processing, white balance processing, encoding processing, and the like; and a recording apparatus 120 that is connected to the signal processing circuit 104 and includes a recording medium that records an image signal output from the signal processing circuit 104; A first output device 121 that outputs a digital image signal to a personal computer, a second output device 122 that outputs an analog image signal to a television monitor, and a recording device 120; It comprises a signal processing circuit 123 that performs predetermined signal processing on the recorded image data and sends it to the second output device 122. That.

  Incident light that has passed through the imaging lens 101 is imaged on the image sensor 103 after the exposure amount is adjusted by the diaphragm 102. The formed image is photoelectrically converted by the image sensor 103 and sent to the signal processing circuit 104. The signal processing circuit 104 performs gamma processing, contour correction processing, white balance processing, encoding processing, and the like on the image signal, and the processed image signal is sent to the recording device 120 and recorded as image data on the recording device 120. .

  The recorded image data is output as a digital signal from the first output device 121. On the other hand, the image data subjected to gamma processing, contour correction processing, and white balance processing by the signal processing circuit 123 from the second output device 122. Is output as an analog signal.

  The digital signal image data output from the first output device 121 is image data that has not undergone gamma processing, contour correction processing, and white balance processing, and is therefore suitable for use in a personal computer or the like. On the other hand, the image data of the analog signal that has been subjected to the above processing by the signal processing circuit 123 is suitable for use in a television monitor.

  Note that the recording medium of the recording device 120 may be a magnetic tape or a nonvolatile memory, or another recording medium. Further, signal processing via a signal processing circuit different from the signal processing circuit 123 may be performed before the first output device 121.

  According to the above-described embodiment, the imaging apparatus 100 outputs image data recorded on the recording apparatus 120 including a predetermined recording medium as a digital signal from one first output apparatus, and on the other hand, a signal processing circuit. After performing predetermined image processing at 123 and outputting as an analog signal from the second output device, it is possible to output both the image processed and the unprocessed image of the same image data. Optimal images can be obtained according to the purpose of use such as viewing on a monitor and use on a personal computer.

1 is a block diagram illustrating an overall configuration of an imaging apparatus serving as a reference of the present invention. FIG. 6 is a characteristic diagram showing gamma characteristics of the tape image processing data table 107A and the memory image processing data table 107B of FIG. 1; FIG. 7 is a waveform diagram showing a difference in contour enhancement correction between the image processing data table for tape 107A and the image processing data table for memory 107B in FIG. 1, and (a) is an outline enhancement correction using the image processing data table for tape 107A. (B) is a waveform diagram of signals at the time of edge enhancement correction using the memory image processing data table 107B. FIG. 7 is a diagram showing a difference between target values of white balance in the tape image processing data table 107A and the memory image processing data table 107B of FIG. 1, and (a) is a diagram showing target values of tape white balance; FIG. 6B is a diagram showing a target value for memory white balance. 1 is a block diagram illustrating an overall configuration of an imaging apparatus according to an embodiment of the present invention. It is a block diagram which shows the whole structure of the imaging device which concerns on other embodiment of this invention. It is a block diagram which shows the whole structure of the conventional imaging device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Imaging device 101 Imaging lens 102 Diaphragm 103 Imaging element 104,123 Signal processing circuit 105 Magnetic tape recording device 106 Non-volatile memory recording device 107 Image processing data table 107A Image processing data table for tape 107B Image processing data table for memory 109 Recording medium selection device 110, 111, 112, 113, 115 changeover switch 114 Signal conversion circuit 116 First conversion data table 117 Second conversion data table 118 Dubbing selection device 120 Recording device 121 First output device 122 Second Output device

Claims (10)

Recording control means for dubbing image data recorded on the first recording medium which has been subjected to the first image processing suitable for the first medium, onto a second recording medium of a different type from the first recording medium In the control method of the image recording apparatus having
Wherein when the recording control means performs the dubbing, conversion processing means for the recorded image data subjected to the first image processing said first recording medium, gamma processing, contour correction processing, and The image data to be recorded on the second recording medium is subjected to the second image processing suitable for the second medium different from the first image processing at least one of the white balance processing. A method for controlling an image recording apparatus, comprising a step of performing a conversion process. It said recording control means, the image data recorded in the second image processing is performed the second recording medium, in the case of dubbing the first recording medium, said conversion processing means, the second for the image data recorded in the image processing is performed the second recording medium, gamma processing, contour correction processing, and, at least one of white balance processing, the first image processing is performed wherein The method of controlling an image recording apparatus according to claim 1, further comprising a step of performing a conversion process so as to be image data to be recorded on the first recording medium . 3. The method of controlling an image recording apparatus according to claim 1, wherein one of the first recording medium and the second recording medium is a magnetic tape, and the other is a nonvolatile memory. The first image processing is image processing suitable for a television monitor as the first medium, and the second image processing is a display monitor and printer of a personal computer as the second medium. The image recording apparatus control method according to claim 1, wherein the image recording apparatus is suitable for image processing. In an image recording apparatus having recording control means for dubbing image data recorded on a first recording medium subjected to first image processing to a second recording medium different in type from the first recording medium ,
Wherein when the recording control means performs the dubbing, the first image processing is subjected to for the image data recorded on the first recording medium, gamma processing, contour correction processing, and, white balance processing Conversion processing means for performing conversion processing so that at least one of the second image processing different from the first image processing is performed and image data to be recorded on the second recording medium is provided,
The recording control means performs a conversion process on the image data recorded on the first recording medium by the conversion processing means , and then dubbes the image data onto the second recording medium. Image recording device . It said conversion processing means, the image data recorded in the second image processing is performed the second recording medium, in the case of dubbing the first recording medium, said conversion processing means, the second The image data that has been subjected to the image processing and recorded on the second recording medium is subjected to at least one of gamma processing, contour correction processing, and white balance processing, and the first image processing is performed. all SANYO subjected to first recording medium to convert so that the image data to be recorded process,
The recording control means performs a conversion process on the image data recorded on the second recording medium by the conversion processing means , and then dubbes the image data onto the first recording medium. The image recording apparatus according to claim 5 . It said first gamma processing is performed on the recorded image data on a recording medium, contour correction processing, and gamma processing to the white balance processing is performed on the image data to be recorded on said second recording medium, A first conversion table for performing conversion processing so as to be contour correction processing and white balance processing ;
The second gamma processing is performed on the recorded image data on a recording medium, contour correction processing, and gamma processing white balance processing, which is performed on the image data to be recorded on the first recording medium, A second conversion table for performing a conversion process so as to be a contour correction process and a white balance process ,
Claim wherein the recording control means when performing the dubbing, the conversion processing means, characterized in that performing the conversion process by selecting one of the first conversion table and the second conversion table The image recording apparatus according to 5 or 6 . Wherein one of the first recording medium and the second recording medium is a magnetic tape, the other image recording according to any one of claims 5 to 7, characterized in that a non-volatile memory Equipment . The first image processing is image processing including gamma processing, contour correction processing, and white balance processing suitable for a television monitor, and the second image processing is a display monitor and printer of a personal computer. The image recording apparatus according to claim 5, wherein the image recording apparatus includes gamma processing, contour correction processing, and white balance processing suitable for the image processing. An image recording apparatus according to any one of claims 5 to 9,
Imaging means for imaging incident light and outputting image data;
Image processing means for selectively performing first image processing or second image processing different from the first image processing on the image data;
When the first image processing is performed on the image data by the image processing unit, the recording control unit stores the image data on the first recording medium and the image processing unit converts the image data on the image data. On the other hand, when the second image processing is performed, the image data is recorded on the second recording medium, respectively.

Images