JP2008301245A - Imaging apparatus and image recording method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To notify a user, easily to comprehend, about which image is recorded on which recording medium even when images are being recorded over a plurality of recording media. <P>SOLUTION: A CPU 12 outputs to a recording medium 46 to which image data are not transferred, recording history information of image data being transferred to another recording medium at present. When an image 1 is being output to a recording medium 46A, for example, the CPU 12 outputs recording history information indicating that the image 1 has been recorded on the recording medium 46A, to a recording medium 46B and records it thereon. Otherwise, when an image 2 is being output to the recording medium 46B, the CPU 12 outputs recording history information indicating that the image 2 has been recorded on the recording medium 46B, to the recording medium 46A and records it thereon. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to recording continuously acquired image data on a plurality of recording media.

In Patent Document 1, an imaging lens, an aperture shutter and the same drive device, an image pickup means having the same drive device as a CCD, a signal processing means having an image pickup signal processing circuit and a memory for temporarily storing a digital video signal, a card I / F, recording means having recording medium insertion slots A and B, and control means having various switches and a CPU for controlling the above means, and recording video signal data temporarily stored in the memory during continuous shooting. The two semiconductor memory cards attached to A and B are divided and transferred at a rate that is half proportional to the access time of each semiconductor memory card and recorded in parallel.
Japanese Patent Laid-Open No. 7-135589

  In Patent Document 1, one frame image is divided and recorded on a plurality of recording media during shooting, and the data that has been divided and recorded at the time of non-shooting is combined into one image and re-recorded in one memory. However, there is a possibility that the user does not notice that all the image data does not fit on one recording medium, and the data is lost. Therefore, the present invention informs the user in an easy-to-understand manner which image is recorded on which recording medium even if images are recorded on a plurality of recording media.

  An imaging apparatus according to the present invention receives a subject image via a photographing optical system, outputs an analog image signal indicating the subject image, and converts the analog image signal output from the imaging unit into digital image data. A conversion unit for conversion, a recording unit including two or more recording media for recording the image data output from the conversion unit, and a recording destination of the image data each time new image data is output from the conversion unit Is determined as any one of the recording media included in the recording unit and the image data is not being recorded, and the image data is output to the determined recording medium and recorded. In addition, the recording history information indicating the recording medium determined as the recording destination of the image data is output and recorded on at least one recording medium that is not determined as the recording destination of the image data. Comprising a recording control unit.

  According to the present invention, when an image is recorded on a certain recording medium, the recording destination of the image data is recorded as recording history information on another recording medium, so there are a plurality of recording media and the image is recorded on one recording medium. Even if the images are not collected, the user can easily know where the image is recorded by referring to the record history information.

  The recording control unit secures a transfer area corresponding to the physical recording position and recording capacity of the image data in the recording medium on the recording medium that is not determined as the recording destination of the image data, and records in the transfer area. History information may be recorded.

  In this way, when collecting the image data on one recording medium, it is only necessary to transfer and record the corresponding image data as it is in the secured transfer area, and the processing is simplified.

  The recording control unit may record a reduced image of the image data whose recording destination is indicated by the recording history information in the transfer area.

  The user can refer to the reduced image in addition to the recording history information, and can easily grasp what kind of image data is recorded on which recording medium.

  The recording unit includes three or more recording media, and the recording control unit records the recording history information and the reduced image on one or more specific recording media among the recording media of the recording unit. Of these, any one of the recording media other than the specific recording medium that is not recording image data may be determined as a recording destination of new image data.

  In this way, the recording destination of each image can be listed with reference to the information of the specific recording medium.

  The image recording method according to the present invention includes a step of outputting image data and a recording destination of image data to any one of recording media not recording image data each time new image data is output. After the determination, the image data is output to and recorded on the determined recording destination recording medium, and the image data recording destination is set to at least one recording medium that has not been determined as the recording destination of the image data. Outputting and recording recording history information indicating the determined recording medium.

  According to the present invention, when an image is recorded on a certain recording medium, the recording destination of the image data is recorded as recording history information on another recording medium, so there are a plurality of recording media and the image is recorded on one recording medium. Even if the images are not collected, the user can easily know where the image is recorded by referring to the record history information.

<First Embodiment>
FIG. 1 is a block diagram showing a configuration of an electronic camera according to an embodiment of the present invention. The camera 10 shown in the figure is a digital camera that converts an optical image of a subject into digital image data and records it on a recording medium, and has a recording / playback function for still images and a recording / playback function for moving images with sound. .

  The overall operation of the camera 10 is centrally controlled by a central processing unit (CPU) 12 built in the camera. The CPU 12 functions as a control unit that controls the camera system according to a predetermined program, and also functions as a calculation unit that performs various calculations such as an automatic exposure (AE) calculation and an automatic focus adjustment (AF) calculation.

  The CPU 12 is connected to a memory control circuit 16 via a bus 14, and the memory control circuit 16 is connected to a ROM 20 and a memory (SDRAM) 22 via a bus 18. The ROM 20 stores a program executed by the CPU 12 and various data necessary for control. The memory 22 is used as a program development area and a calculation work area for the CPU 12, and is also used as a temporary storage area for image data and audio data. Note that the ROM 20 that is a nonvolatile storage means may be rewritable or may be rewritable like an EEPROM.

  The camera 10 is provided with operation means 30 for the user to input various commands. The operation unit 30 includes various operation units such as an image quality mode setting operation unit 31, a recording pixel number setting operation unit 32, a moving image / still image mode selection operation unit 33, a shutter button 34, and a continuous shooting mode setting operation unit 35.

  The image quality mode setting operation unit 31 is an operation means for setting the recording image quality (here, the compression rate) of captured image data. In the camera 10 of this example, three types of image quality (recording compression rate) of “FINE” with high image quality (low compression rate), “NORMAL” with standard image quality, and “BASIC” with high compression rate are selected according to the purpose of shooting. Can be selected.

  The recording pixel number setting operation unit 32 is an operation means for setting the recording pixel number (image size) of the captured image data. In the camera 10 of this example, the number of recording pixels can be selected from 2832 × 2128 (6M), 2048 × 1536 (3M), 1280 × 960 (1M), and 640 × 480 (VGA). The data amount (file size) of the captured image changes depending on the combination of the recording image quality and the number of recording pixels.

  The moving image / still image mode selection operation unit 33 is an operation means for switching between “moving image mode” for recording moving images and “still image mode” for recording still images. The shutter button 34 is an operation means for inputting an instruction to start shooting, and functions as a recording start (start) / stop (stop) button in moving image shooting, and functions as a release button in still image shooting. The shutter button 34 is composed of a two-stroke switch having an S1 switch that is turned on when half-pressed and an S2 switch that is turned on when fully pressed.

  The continuous shooting mode setting operation unit 35 performs a continuous shooting mode in which continuous shooting (continuous shooting) of still images is performed by pressing the shutter button 34 once, and one stationary operation is performed by pressing the shutter button 34 once. This is an operation means for switching between a normal mode (single shooting mode) for executing image shooting.

  Although not shown in the figure, the operation means 30 includes a mode selection means for switching between the photographing mode and the reproduction mode, a zoom operation means for changing the photographing magnification and the reproduction magnification, and a menu screen on the liquid crystal monitor 40. Menu button to be displayed, cross key for selecting a desired item from the menu screen (cursor moving operation means), OK button for commanding confirmation of selection item and execution of processing, deletion of desired object such as selection item, and cancellation of instruction contents Alternatively, operation means such as a cancel button for inputting a command for returning to the previous operation state is also included. Note that the operation means 30 is not limited to a push-type switch member, dial member, lever switch, or the like, and includes those realized by a user interface that selects a desired item from a menu screen. It is.

  An operation signal from the operation means 30 is input to the CPU 12. The CPU 12 controls each circuit of the camera 10 based on an input signal from the operation means 30, for example, lens drive control, shooting operation control, image processing control, image data recording / playback control, display control of the liquid crystal monitor 40, etc. I do.

  The liquid crystal monitor 40 can be used as an electronic viewfinder for checking the angle of view at the time of shooting, and is used as a means for reproducing and displaying recorded images. The liquid crystal monitor 40 is also used as a user interface display screen, and displays information such as menu information, selection items, and setting contents as necessary. Instead of a liquid crystal display, other types of display devices (display means) such as an organic EL can be used.

  The camera 10 has a plurality (three in the figure) of media sockets (media mounting portions) 42A, 42B, and 42C, and the same or different types of recording media 46A, 46B, and 46C are placed in the respective media sockets 42A, 42B, and 42C. Can be installed. The form of the recording medium 46 is not particularly limited, and is various, such as a semiconductor memory card represented by SmartMedia (trademark), a portable small hard disk represented by Microdrive (trademark), a magnetic disk, an optical disk, a magneto-optical disk, and the like. Media can be used. In carrying out the present invention, the number of recording media and media sockets is not particularly limited as long as it is plural. The means for recording image data is not limited to a removable medium (a portable recording medium having a structure that is detachable from the camera 10), and may be a recording medium (an internal memory) built in the camera 10.

  The camera 10 has a function of automatically selecting a recording medium 46 used for recording. The media selection function of the camera 10 will be described later.

  Two media sockets 42 </ b> A, 42 </ b> B, and 42 </ b> C (may be collectively represented by the media socket 42) are connected to a media interface (I / F) circuit 52 via a bus 50. The media I / F circuit 52 is connected to the CPU 12 via the bus 14 and performs necessary signal conversion in order to deliver an input / output signal suitable for reading / writing of the recording medium 46 in accordance with a command from the CPU 12.

  Each of the media sockets 42A, 42B, and 42C has a media detection terminal (not shown) for detecting whether or not the recording media 46A, 46B, and 46C are mounted, and indicates whether the recording medium 46 is mounted or not mounted. The detection signal shown is input to the CPU 12 via the media I / F circuit 52.

  The camera 10 also includes a USB communication circuit 54 as a communication means for connecting to a personal computer or other external device. By connecting the camera 10 and an external device using a USB cable (not shown), it is possible to exchange data with the external device. Of course, the communication method is not limited to USB, and IEEE1394, Bluetooth, or other communication methods may be applied. The communication mode for communicating with an external device is automatically set over other modes (still image shooting mode / playback mode / movie mode) when the camera 10 is connected to the external device for communication. Is done.

  Next, the shooting function of the camera 10 will be described.

  The camera 10 includes a photographing lens 56 and a CCD solid-state imaging device (hereinafter referred to as CCD) 58. The taking lens 56 may be a single focus lens or a variable focal length such as a zoom lens.

  When the shooting mode is selected, power is supplied to the image pickup unit including the CCD 58 from a power supply unit (not shown), and the camera is ready for shooting. The light passing through the photographing lens 56 is imaged on the light receiving surface of the CCD 58 after the amount of light is adjusted by a diaphragm mechanism (not shown). A number of photodiodes (light receiving elements) are two-dimensionally arranged on the light receiving surface of the CCD 58, and red (R), green (G), and blue (B) primary color filters are provided corresponding to the photodiodes. They are arranged in a predetermined arrangement structure (Bayer, G stripe, etc.). The CCD 58 has an electronic shutter function for controlling the charge accumulation time (shutter speed) of each photodiode.

  The CPU 12 sends a command to the driver circuit 62 via the parallel input / output circuit 60 to control the charge accumulation time and charge transfer of the CCD 58. Instead of the CCD 58, another type of image sensor such as a CMOS may be used.

  The subject image formed on the light receiving surface of the CCD 58 is converted into a signal charge corresponding to the amount of incident light by each photodiode. The signal charge accumulated in each photodiode is sequentially read out as a voltage signal (image signal) corresponding to the signal charge based on a drive pulse given from the driver circuit 62 in accordance with a command from the CPU 12.

  The signal output from the CCD 58 is sent to the analog processing unit 64, where the R, G, B signals for each pixel are sampled and held (correlated double sampling processing), amplified, and then A / D converter 66 Sent to. The A / D converter 66 converts R, G, B signals that are sequentially input into digital signals and outputs them to the signal processing circuit 68.

  The signal processing circuit 68 processes the A / D converted digital image data in accordance with a command from the CPU 12. In other words, the signal processing circuit 68 includes a synchronization circuit (a processing circuit that converts a color signal into a simultaneous expression by interpolating a spatial shift of the color signal associated with the color filter array of the single CCD), and a luminance / color difference signal generation circuit. In addition to functioning as an image processing unit including a gamma correction circuit, a contour correction circuit, a white balance correction circuit, and the like, the image processing unit functions as an audio processing unit, and processes an image signal and an audio signal using the memory 22 in accordance with a command from the CPU 12.

  The RGB image data input to the signal processing circuit 68 is converted into a luminance signal (Y signal) and a color difference signal (Cr, Cb signal) by the signal processing circuit 68 and subjected to predetermined processing such as gamma correction. The The image data processed by the signal processing circuit 68 is stored in the memory 22.

  When outputting the image being captured to the liquid crystal monitor 40, the image data is read from the memory 22 and sent to the display control circuit 70 via the bus 14. The display control circuit 70 converts the input image data into a predetermined display signal (for example, an NTSC color composite video signal) and outputs it to the liquid crystal monitor 40.

  The image data in the memory 22 is periodically rewritten by the image signal output from the CCD 58, and the image signal generated from the image data is supplied to the liquid crystal monitor 40, so that the image being captured can be monitored in real time. 40. The photographer can check the shooting angle of view from the video (through movie image) displayed on the liquid crystal monitor 40.

  When the shutter button 34 is pressed and the S1 switch is turned on in the still image shooting mode, the CPU 12 detects this and performs AE and AF control. When the shutter button 34 is fully pressed (S2 = ON), the CPU 12 detects the recording. CCD exposure and readout control for capturing an image is started.

  That is, the CPU 12 performs various calculations such as a focus evaluation calculation and an AE calculation from the image data captured in response to S1 = ON, and controls a lens driving motor (not shown) based on the calculation result to take an image. The lens 56 is moved to the in-focus position, and a diaphragm mechanism (not shown) is controlled. Then, in response to S2 = ON, the charge accumulation time at the time of image acquisition is controlled.

  The captured image data is subjected to luminance / color difference signal conversion processing (YC processing) and other predetermined signal processing in the signal processing circuit 68 and then sent to the compression / expansion circuit 72, where a predetermined compression format (for example, , JPEG method). The compressed image data is recorded on the recording medium 46 via the media I / F circuit 52.

  When the moving image mode is selected by the moving image / still image mode selection operation unit 33, the camera 10 can record a moving image with sound. The recording operation starts when the shutter button 34 is pressed (S2 = ON). When the shutter button 34 is pressed again (S1 = ON), the moving image recording is stopped. Note that the recording operation may be performed while the shutter button 34 is continuously pressed, and the recording may be stopped by releasing the pressing.

  The sound at the time of moving image shooting is detected by a microphone 74 built in the camera 10, and the detection signal (audio signal) is amplified through an amplifier 76 and converted into a digital signal by an A / D converter 77. To the signal processing circuit 68. The signal processing circuit 68 converts the input audio data into a predetermined signal format. The audio data generated in this way is compressed in the compression / decompression circuit 72 together with the image data, and is recorded on the recording medium 46 via the media I / F circuit 52. The moving image data is recorded, for example, according to the motion JPEG format.

  In the motion JPEG method, the image data acquired from the CCD 58 is temporarily stored in the internal memory 22, and then converted into a luminance / color difference signal by the signal processing circuit 68, and JPEG compression is performed within one image, while the external recording medium 46. Still images are continuously stored at a constant frame rate (a preset frame rate). The file format of the moving image is not limited to motion JPEG, and other file formats such as MPEG may be applied. In the case of the MPEG system, recording is continuously performed on an external recording medium 46 while performing intra-frame compression and inter-frame compression.

  When the reproduction mode is selected by the operation means 30, the data of the last image file (last recorded file) recorded on the recording medium 46 is read. When the file related to the last recording is a still image file, the compressed data of the read image file is expanded to an uncompressed YC signal via the compression / expansion circuit 72, and the signal processing circuit 68 and the display control circuit 70. Is converted into a display signal via the, and then output to the liquid crystal monitor 40. As a result, the image content of the file is displayed on the liquid crystal monitor 40.

  When the reproduction target file is a moving image file, the first frame of the moving image is displayed on the liquid crystal monitor 40 as a representative image, and a screen for accepting an instruction to start moving image reproduction is displayed. When a predetermined operation is performed from the operating means 30 in a state where the first frame of the moving image is displayed and the moving image reproduction is started, the reproduction process of the moving image file starts, the moving image is displayed on the liquid crystal monitor 40, and the signal processing The audio data reproduced in the circuit 68 is output to the speaker 84 via the D / A converter 80 and the amplifier 82, and the audio recorded simultaneously with the moving image is also reproduced.

  During single-frame playback of a still image (including when the first frame of a moving image is displayed), the file to be played can be switched (forward / reverse) by operating the right or left key of the cross key. The image file at the frame-advanced position is read from the recording medium 46, and still images and moving images are reproduced and displayed on the liquid crystal monitor 40 in the same manner as described above.

  FIG. 2 is a flowchart of continuous shooting mode processing performed by the camera 10.

  In S <b> 11, a detection signal indicating a mounted state / not-mounted state is input to the CPU 12 via the media I / F circuit 52.

  In S12, the CPU 12 determines whether or not a detection signal indicating media attachment has been input. When the detection signal is input, the process proceeds to S13, and when the detection signal is not input, the process proceeds to R1.

  In S13, the media type detected to be inserted is recognized.

  In S14, it is determined whether or not the number of media types detected to be inserted is plural (here, the recording media 46A and 46B). If there are a plurality of media types, the process proceeds to S15, and if not, the process proceeds to R2.

  In S15, the recording capacity of each recording medium 46 is confirmed.

  In S16, the recording speed of each recording medium 46 is confirmed.

  In S17, it is determined whether or not the shutter button 34 is half-pressed. If the shutter button 34 is half-pressed, the process proceeds to S18. Otherwise, the process proceeds to R3.

  In S18, AF / AE processing is performed.

  In S19, it is determined whether or not the shutter button 34 has been fully pressed. If the shutter button 34 is fully pressed, the process proceeds to S21. If the shutter button 34 is not fully pressed, the process proceeds to S20.

  In S20, it is determined whether or not the half-press of the shutter button 34 is released. If the half-press is released, the process returns to S17. If the half-press is not released, the process returns to S19.

  In S21, a recording still image signal acquisition operation is performed.

  In S22, various processing is performed on the acquired still image signal to create still image data for recording.

  In S23, the obtained image data is alternately recorded on the recording media 46A and 46B.

  In S24, it is determined whether or not the shooting mode has been canceled. If the shooting mode is canceled, this process is terminated. If not, the process returns to S17.

  In R1, an error message indicating that no media is loaded is displayed.

  In R2, an image is recorded on the mounted recording medium 46.

  R3 continues to wait for a half-press input.

  FIG. 3 conceptually shows data recording on the recording media 46A and 47B in this processing.

  As shown in FIG. 3A, a plurality of still image data 1, 2,... Obtained by continuous shooting is output from the compression / decompression circuit 72 to the media I / F circuit 52 via the bus 14.

  As shown in FIG. 3B, in this process R2, the media I / F circuit 52 transfers these image data as they are to the recording medium 46A via the media socket. In this case, if the recording speed is slower than the transfer speed, the recording cannot catch up with the transfer. In order to solve this, there is no choice but to reduce the continuous shooting speed to lower the transfer speed, which has a great disadvantage for the user.

  On the other hand, as shown in FIG. 3C, in this process S13, the CPU 12 alternately transfers these image data to the media sockets 42 and 44 via the media I / F circuit 52, thereby sequentially transferring them. The received image data is alternately output to the recording media 46A and 46B. For example, when the next image data 2 is transferred during the recording of the image data 1 on the recording medium 46A, the image data 2 is output to the recording medium 46A. If it is less than twice the recording speed, there will be no time lag in both processes.

  In addition, the CPU 12 outputs the recording history information of the image data currently transferred to another recording medium to the recording medium 46 that does not transfer the image data.

  For example, when the image 1 is output to the recording medium 46A, the CPU 12 outputs and records recording history information indicating that the image 1 is recorded on the recording medium 46A. Alternatively, when the image 2 is output to the recording medium 46B, the CPU 12 outputs and records recording history information indicating that the image 2 is recorded on the recording medium 46B to the recording medium 46A.

  If this process is repeated, as shown in FIG. 4 (a), the recording medium 46A contains images 1, 3, 5,..., Odd-numbered transferred image data, history information of image 2, and history of image 4. The even-numbered transfer history of information, etc. is stored. The storage area for recording history information and image data is physically and continuously arranged alternately. That is, the recording history information and the storage area for the image data are continuously arranged so that the physical address spaces are alternated.

  Alternatively, as shown in FIG. 4 (b), the recording medium 46A has image data transferred to the even-numbered images 2, 4, 6,..., History information of image 1, history information of image 3,. The recording history transferred oddly such as is stored. The storage areas for recording history information and image data are alternated.

  These recording history information may be composed of text data or other readable data describing a message such as “Media A contains image data”.

  FIG. 5 shows a display example when data on the recording medium 46 is read and displayed by an electronic device such as the camera 10 or a personal computer.

  FIG. 5A is a list display of image data on the recording medium 46A. In this list display, thumbnail images of image data recorded on the recording medium 46A such as image 1, image 3,... And recording history information of images 2, 4,. Yes. Since the image data transferred to the even number is not stored in the recording medium 46A, their thumbnails are not displayed. Instead, since the storage destination “recording medium 46B” of those image data is displayed, it can be easily understood that the image data is recorded on another recording medium.

  FIG. 5B is a list display of image data on the recording medium 46B. In this list display, thumbnail images of image data recorded on the recording medium 46B such as image 2, image 4,... And recording history information of images 1, 3,. Yes. Since the odd-numbered transferred image data is not stored in the recording medium 46B, the thumbnails are not displayed. Instead, since the storage destination “recording medium 46A” of those image data is displayed, it can be easily understood that the image data is recorded on another recording medium.

  FIG. 5C shows an example of one-screen display of recording history information of the recording medium 46A or the recording medium 46B. In this case, the entire screen is displayed as a blacked-out image, and the image data storage destination “recording medium 46B” is displayed in part of the image, so that it is easy to record the image data on another recording medium. I understand.

Second Embodiment
FIG. 6 is a flowchart of continuous shooting mode processing according to the second embodiment. The same processes as those in the first embodiment are denoted by the same process numbers, and the description thereof is omitted.

  In S31, the transferred image data amount for recording is calculated. This data amount can be estimated from the compression rate of the output image data according to the image quality level desired by the user (non-compressed, fine, normal, economy, etc.), for example.

  In S 32, the image is recorded on one recording medium 46, and a data recording area (transfer area) corresponding to the data storage position and data amount of the image is secured on the other recording medium 46. Then, record history information is recorded in the secured transfer area, and the rest is secured as a free area. However, all of the reserved transfer areas may be filled with the record history information.

  The transfer area is secured every time an image is output, and the image data and the transfer area are physically arranged alternately.

  S33 is the same as S24.

  As a result of the above processing, as shown in FIG. 7, the recording medium 46 </ b> A has image data transferred oddly as images 1, 3, 5..., History information of image 2, history information of image 4,・ ・ Records the even numbered recording history such as ・ ・. The recording history information and image data storage areas are physically arranged alternately. In addition, on the recording medium 46A, the even-numbered image data transferred to the images 2, 4, 6,..., The history information of the image 1, the history information of the image 3,. The history is stored. The recording history information and image data storage areas are physically arranged alternately. Furthermore, the capacity of one transfer area and the other image storage area are the same, and the physical positions are also associated.

  If the correspondence relationship between the physical addresses is mapped in advance, the correspondence can be made even if the types of the recording media 46A and 46B are not the same. When one capacity is smaller than the other, a restriction may be prevented so that the larger storage capacity does not exceed the smaller one, thereby preventing the correspondence from being broken.

  In this way, when the images recorded on one of the two recording media 46A and 46B are moved together to the other recording medium 46, the image data of the other recording medium is stored in the area secured on one recording medium. All you need to do is migrate. Note that data integration by data movement between recording media is performed, for example, as in Patent Document 1 or the following image transfer processing.

  FIG. 8 is a flowchart of image transfer processing executed by the camera 10.

  In S51, the user selects whether to transfer and integrate images from the recording media 46A to 46B or to transfer and integrate images from the recording media 46B to 46A. If it is selected to transfer the image from the recording medium 46A to 46B, the process proceeds to S52, and if it is selected to transfer the image from the recording medium 46B to 46A, the process proceeds to S54.

  In S52, the recording history information of the recording medium 46B is deleted.

  In S53, the image data of the recording medium 46A is transferred and recorded in the corresponding empty area of the recording medium 46B.

  In S54, the record history information of the recording medium 46A is deleted.

  In S53, the image data of the recording medium 46B is transferred and recorded in the corresponding free area of the recording medium 46B.

  In S56, it is determined whether transfer and recording of all images have been completed normally. If it is completed normally, this process is terminated. If it has not been completed normally, the process proceeds to S57 and an error message is displayed.

  That is, the image data of the corresponding other recording medium 46 is stored in the transfer area secured in one recording medium 46, and the image data is integrated into one medium. Since the transfer area and the recording area of the image data to be transferred and the capacity have a physical correspondence, the image transfer can be speeded up.

<Third Embodiment>
FIG. 9 is a flowchart of continuous shooting mode processing according to the third embodiment.

  S61 to S72 are the same as S1 to S22.

  In S73, a thumbnail image is created from the transferred image data.

  S74 is the same as S31.

  In S75, an image is recorded on one recording medium 46, and a transfer area corresponding to the physical data storage area and the data amount of the image is secured on the other recording medium 46. Then, record history information and thumbnail images are recorded in the secured transfer area, and the rest is secured as a free area. However, the entire reserved area may be filled with recording history information and thumbnail images.

  The area is secured every time the image is transferred, and the image data and the secured area are physically connected alternately.

  As a result, as shown in FIG. 10, on the recording medium 46A, images 1, 3, 5,..., Odd-numbered transferred image data, image 2 history information, image 4 history information,. The even-numbered image recording history and the thumbnail image corresponding to the main body image indicated by the image recording history are stored. The recording history information and image data storage areas are physically arranged alternately. Further, the image data transferred to the recording medium 46B as the even-numbered images 2, 4, 6,..., The history information of the image 1, the history information of the image 3,. A recording history and a thumbnail image corresponding to the main body image indicated by the image recording history are stored. The recording history information and image data storage areas are physically arranged alternately. Further, the capacity of one transfer securing area and the other image storage area are the same, and the physical position of the image recording area on one recording medium and the transfer area of the image secured on the other recording medium 46 Are associated.

  With the recording history information and thumbnails of one recording medium, it is possible to easily grasp what image is recorded on the other recording medium.

  FIG. 11 is a flowchart of image transfer processing executed by the camera 10.

  S81 is the same as S51.

  In S82, the recording history information and thumbnails of the recording medium 46B are deleted.

  S83 is the same as S51.

  In S84, the recording history information and thumbnails of the recording medium 46A are deleted.

  S85 to S87 are the same as S55 to S57.

<Fourth embodiment>
When there are three or more recording media 46, at least one recording medium 46 is dedicated to recording recording history information (more preferably, recording history information and thumbnails), and at least two other recording media 46 are dedicated to recording main body image data. Good.

  For example, as shown in FIG. 12, sequentially arrived image data is alternately recorded on the recording medium 46A and the recording medium 46B, and the recording history information and thumbnail images of the main body images are continuously recorded on the recording medium 46C. And record.

  For example, when only the recording medium 46C is inserted into the card slot of the personal computer and the reproduction of the data on the recording medium 46C is instructed, the entire screen is displayed as a blacked-out image as shown in FIG. The image data storage destination “recording medium 46A” or “recording medium 46B” is displayed according to the record history information. In this way, it can be easily understood which recording medium the image data is recorded on.

Block diagram showing the internal structure of the camera Flowchart of continuous shooting mode processing according to the first embodiment The figure which shows notionally the image data recording to the recording media 46A and 46B The figure which shows notionally the physical arrangement | positioning of the image data and recording history information to the recording media 46A and 46B Display example when data of the recording medium 46 is read and displayed by an electronic device such as the camera 10 or a personal computer Flow chart showing the flow of user registration and image transfer during shooting The figure which shows notionally the physical arrangement | positioning of the image data and recording history information to the recording media 46A and 46B Flowchart of image transfer processing according to second embodiment Flowchart of continuous shooting mode processing according to the third embodiment The figure which shows notionally the physical arrangement | positioning of the image data and recording history information to the recording media 46A and 46B Flow chart of image transfer process The figure which shows notionally the physical arrangement | positioning of the image data and recording history information to recording medium 46A, 46B, and 46C Flowchart of image transfer processing according to the fourth embodiment

Explanation of symbols

12: CPU, 46: recording medium, 58: CCD

Claims (5)

An imaging unit that receives a subject image via a photographing optical system and outputs an analog image signal indicating the subject image;
A conversion unit that converts the analog image signal output from the imaging unit into digital image data;
A recording unit including two or more recording media for recording image data output from the conversion unit;
Each time image data is newly output from the conversion unit, the recording destination of the image data is determined as one of recording media that are not recording image data among the recording media included in the recording unit. In the above, the image data is output and recorded on the determined recording medium, and the image data is recorded on at least one recording medium that is not determined as the recording destination of the image data. A recording control unit that outputs and records recording history information indicating the previously determined recording medium;
An imaging apparatus comprising:   The recording control unit secures a transfer area corresponding to a physical recording position and a recording capacity of the image data in the recording medium in the recording medium that is not determined as a recording destination of the image data, and The imaging apparatus according to claim 1, wherein the recording history information is recorded in a transfer area.   The imaging apparatus according to claim 2, wherein the recording control unit records a reduced image of image data whose recording destination is indicated by the recording history information in the transfer area. The recording unit includes three or more recording media,
The recording control unit records the recording history information and the reduced image on one or more specific recording media among the recording media of the recording unit, and records other than the specific recording medium among the recording media of the recording unit. The imaging apparatus according to claim 3, wherein any one of the recording media that are not recording image data is determined as a recording destination of new image data. Outputting image data; and
Each time image data is newly output, the recording destination of the image data is determined as one of recording media that are not recording the image data, and then the image data is stored in the determined recording destination. Output and record to a recording medium, and output recording history information indicating the recording medium determined as the recording destination of the image data to at least one recording medium not determined as the recording destination of the image data Step to record and
An image recording method comprising:

Images