JP2007214768A - Imaging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging device that can prevent frame missing and the sound break of recorded moving picture data when a moving picture is continuously recorded on a plurality of recording media. <P>SOLUTION: When recording media are switched during the continuous recording of the moving picture to the plurality of recording media, a control section 19 carries on the moving picture recording by automatically changing recording conditions (the number of pixels, the number of recording frames, and compressibility) previously set by a user on condition that a threshold data write speed determined according to the recording conditions exceeds a data writing speed of the switched recording medium. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an imaging apparatus (for example, a digital camera) capable of recording a moving image.

  In recent years, in an imaging device such as a digital camera capable of moving image recording, an increase in the number of pixels and an increase in the number of recorded frames are performed in order to perform higher-quality moving image recording. For example, as the number of pixels, a VGA size (640 × 480 dots), a high vision type (1920 × 1080 dots), and the like have become widespread.

  However, as the number of pixels and the number of recording frames increase in this way, the moving image recording time when using a recording medium of the same capacity is shortened. Therefore, in order to secure a larger recording capacity, a digital camera capable of mounting a plurality of external recording media has been proposed, and an example thereof can be seen in Patent Document 1.

  The digital camera described in Patent Document 1 includes a writing speed detection unit and a writing medium selection unit in addition to mounting a plurality of external recording media. The writing speed detection unit detects the data writing speed of each external recording medium by actually writing benchmark data or recording data to each external recording medium, or by obtaining the type of each external recording medium. It is. On the other hand, the writing medium selection unit selects an external recording medium into which recording data is written based on the data writing speed detected by the writing speed detection unit.

Then, the digital camera of Patent Document 1 can appropriately select an external recording medium to which recording data is written from a plurality of external recording media in consideration of the data writing speed of each external recording medium detected by the writing speed detection unit.
JP 2001-352510 A

  However, in the digital camera disclosed in Patent Document 1, when two external recording media can be mounted, the external recording medium with the higher data writing speed detected by the writing speed detection unit is used for moving image recording, and data writing is performed. The slower external recording medium is used for still image recording. That is, the digital camera disclosed in Patent Document 1 does not take into consideration that moving images are continuously recorded on a plurality of recording media.

  Generally, moving image data has a very large amount of data per unit time. Therefore, a situation in which the data writing speed of the recording medium is not sufficient with respect to the data amount of moving image data per unit time tends to occur. In this situation, frame dropping or sound interruption occurs in the recorded moving image data.

  For example, when continuously recording moving images on two recording media under the same moving image recording conditions, if the data writing speed of the recording medium recorded later is lower than the recording medium recorded first, Frame dropping or sound interruption may occur in the moving image data recorded after the recording medium is switched.

  In view of the above problems, it is an object of the present invention to provide an imaging device that can prevent frame dropping or sound interruption of recorded moving image data when continuously recording moving images on a plurality of recording media. And

  In the present invention, the imaging apparatus has an writing speed detection unit that detects a data writing speed to a recording medium, and is an imaging apparatus capable of continuously recording moving images on a plurality of recording media, when moving image recording is set or when moving images are recorded. During recording, the data writing speed of the recording medium is compared with the threshold data writing speed determined according to the moving picture recording conditions, and continuous moving picture recording is performed under the moving picture recording conditions according to the comparison result. It is characterized by comprising a control unit for determining whether or not it is possible.

  Generally, when moving image recording is performed under moving image recording conditions (number of pixels, number of shot frames, compression rate, etc.) that exceed the allowable range of data writing speed, various problems (such as dropped frames or broken sound in moving image data) ) Occurs. However, the control unit of the imaging apparatus of the present invention has a function of performing comparison / determination according to the data writing speed at the time of moving image recording setting or during moving image recording. In particular, the data writing speed (threshold data writing speed) determined according to the moving picture recording conditions can be compared with the data writing speed of the recording medium detected by the writing speed detector. Then, the imaging apparatus of the present invention can make various determinations based on the threshold data writing speed.

  For example, the imaging apparatus of the present invention can determine whether or not to continue moving image recording that is continuous on a plurality of recording media based on the magnitude relationship with the threshold data writing speed as a boundary. That is, the imaging apparatus determines that it is suitable for continuous video recording if the recording medium has one data writing speed (for example, a data writing speed faster than the threshold data writing speed) with respect to the threshold data writing speed. Or a recording medium having the other data writing speed (for example, a data writing speed slower than the threshold data writing speed) can be determined to be unsuitable for continuing the continuous moving image recording.

  Further, in the imaging measure of the present invention, when the control unit determines that continuation of the moving image recording is impossible, the threshold data writing speed is changed by changing the moving image recording condition, and the moving image recording is continuously controlled. It is desirable to do.

  That is, with such a control unit, for example, by reducing the moving image recording conditions, it is possible to change from a plurality of existing threshold data writing speeds to a relaxed threshold data writing speed according to a plurality of moving image recording conditions. Then, since the threshold data writing speed is reduced, the control unit changes the comparison result between the threshold data writing speed and the writing speed of the recording medium after switching to a suitable one for continuing the continuous moving image recording. It can be said that. Therefore, the image pickup apparatus of the present invention can further prevent the occurrence of problems such as frame dropping and sound interruption of moving image data when continuously recording moving images on a plurality of recording media.

  Further, in the imaging apparatus of the present invention, when the control unit determines that continuation of moving image recording is impossible, it may be controlled not to continuously record moving images.

  With such a control unit, since the moving image recording itself stops, the above-described problems cannot occur.

  In the imaging apparatus of the present invention, the control unit assigns priorities to the plurality of recording media and performs moving image recording based on the data writing speeds of the plurality of recording media detected by the writing speed detection unit. In this case, the recording media to be used may be selected in the order of higher priority.

  Then, since it is used (recorded) from an external recording medium having a high data writing speed, high-quality moving image recording becomes possible. In addition, when the moving image recording conditions are collectively set for all the recording media, a situation in which the control unit determines that continuation of moving image recording is impossible is relatively likely to occur at the time of subsequent switching of the external recording medium. Therefore, it is possible to suppress the probability of occurrence of a situation in which the control unit determines that continuation of moving image recording is impossible when the first external recording medium is switched.

  In the imaging apparatus of the present invention, a priority order input unit that assigns priorities to a plurality of recording media is provided, and the control unit assigns priority given by the priority order input unit when recording a moving image. It is desirable to select the recording media to be used in the descending order.

  With such an imaging apparatus, moving image recording can be performed on a recording medium desired by the user in the order desired by the user by using the priority order input unit. Therefore, it is possible to cope with the case where it is desired to record a moving image only on a certain recording medium or the case where it is desired to continuously record a moving image on only some of all the recording media loaded.

  In addition, a moving image recording condition input unit that sets moving image recording conditions corresponding to each of a plurality of recording media individually or collectively may be provided.

  With such an imaging apparatus, it is possible to perform moving image recording under a moving image recording condition desired by the user by using the moving image recording condition input unit. Further, when the moving image recording conditions are individually set, the degree of freedom is higher, and when the moving image recording conditions are collectively set, the usability is improved.

  It should be noted that the moving image recording conditions in the imaging apparatus of the present invention preferably include at least one of the three parameters of the number of pixels, the number of frames to be photographed, and the compression rate.

  With such an imaging apparatus, the relationship between the quality of moving images (for example, the number of pixels, the number of shot frames, and the compression rate) and the data writing speed can be easily understood by the user, and the setting of moving image recording conditions is facilitated.

  According to the present invention, there is provided an imaging device capable of preventing frame dropping or sound interruption of recorded moving image data when continuously recording moving images on a plurality of recording media.

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

<Configuration of digital camera>
FIG. 1 is a block diagram showing a schematic configuration of a digital camera 1 according to an embodiment of the present invention. 2A and 2B are an external side view and an external rear view of the digital camera 1, respectively. As shown in FIGS. 1 or 2A and 2B, the digital camera 1 includes a lens unit 11, a lens movement control unit 12, an image processing unit 13, a timing control circuit 14, and a flash unit. 15, an image display unit 16, an external interface unit 17, an operation unit 18, a control unit 19, a communication interface 20, and a nonvolatile memory 21.

<About the lens unit>
The lens unit 11 includes an imaging optical system OS11a that captures a light beam from a subject, and a CCD (Charged Coupled Device) 11b that irradiates the light beam guided by the imaging optical system OS.

  The imaging optical system OS11a is housed in the lens barrel LB {see FIG. 2A} and acquires the light rays of the subject. The imaging optical system OS11a includes at least a zooming lens ZL that bears zooming, a shutter ST that adjusts light rays from the subject, and a focusing lens FL that bears focusing.

  The CCD 11b receives a light beam taken in by the imaging optical system OS11a and converts it into an electrical signal (that is, a photoelectric conversion element). The CCD 11b is configured to include a large number of three types of pixels that selectively receive red (R) light, green (G) light, and blue (B) light.

<Lens movement control unit>
The lens movement control unit 12 appropriately moves the lens of the imaging optical system OS11a for zooming and focusing. The lens movement control unit 12 includes various motors (12a to 12c), corresponding motor control circuits (12d to 12f), and a lens position detection circuit 12g.

  Specifically, the motors are a zoom motor ZM12a that moves the zooming lens ZL, a shutter motor SM12b that opens and closes the shutter ST, and a focus motor FM12c that moves the focusing lens FL.

  Specifically, the motor control circuit controls the zooming motor ZM12a by controlling the zooming motor ZM12a, the zooming motor ZM control circuit 12d, and the shuttering motor SM12b by controlling the driving of the shutter. The motor SM control circuit 12e and the focus motor FM control circuit 12f that controls focusing and the like by driving and controlling the motor FM12c for focus.

  The lens position detection circuit 12g irradiates a reflection pattern (not shown) attached to the outer peripheral surface of the lens barrel LB with a light beam and detects reflected light from the reflection pattern (for example, photo). A reflector). That is, the lens position detection circuit 12g detects the positions of various lenses by detecting reflected light from the reflection pattern. The lens position detection circuit 12g is not limited to a configuration such as a photo reflector, and may detect the positions of various lenses by counting drive pulses of various motors.

<About the image processing unit>
The image processing unit 13 generates image data from the electronic data of the CCD 11b. Specifically, the image processing unit 13 includes a signal processing circuit 13a, an A / D converter 13b, an image processing circuit 13c, and an image memory 13d.

  The signal processing circuit 13a processes an analog signal output from each pixel of the CCD 11b, and the A / D converter 13b converts the processed analog signal from the signal processing circuit 13a into a digital signal. The image processing circuit 13c is a circuit that performs image processing such as black level correction, white balance adjustment, and γ correction. The image memory 13d temporarily records image data generated through the signal processing circuit 13a, the A / D converter 13b, and the image processing circuit 13c.

<About the timing control circuit>
The timing control circuit 14 generates drive control signals for the CCD 11b, the signal processing circuit 13a, and the A / D converter 13b based on the reference clock transmitted from the control unit 19.

<About the flash unit>
The flash unit 15 includes a flash light emitting unit 15a and a flash circuit 15b. The flash light emitting unit 15a increases the light (reflected light) from the subject by irradiating the subject with a light beam, and allows the CCD 11b to be easily imaged. The flash circuit 15b is a circuit that controls light emission by the flash circuit 15a.

<About the image display>
The image display unit 16 includes a VRAM (Video Random Access Memory) 16a, an LCD (Liquid Crystal Display) 16b, and an EVF (Electric View Finder) 16c. The VRAM 16a records image data generated based on the subject light image from the imaging optical system OS11a. The LCD 16b / EVF 16c displays various data such as image data recorded in the VRAM 16a.

<External interface>
The external interface unit 17 includes a first external recording medium mounting unit 17a (hereinafter referred to as a first mounting unit 17a) and a second external recording medium mounting unit 17b (hereinafter referred to as a second mounting unit 17b). The first mounting portion 17a has a first external recording medium 30a (hereinafter referred to as a first recording medium 30a), and the second mounting portion 17b has a second external recording medium 30b (hereinafter referred to as a second recording medium 30b). Can be installed. That is, in the digital camera 1 according to the present embodiment, two external recording media can be loaded simultaneously.

<About the control panel>
The operation unit 18 (moving image recording condition input unit, priority input unit) is a button, a switch, or the like for instructing the control unit 19 of various operation contents by the user. The operation unit 18 includes at least a power switch 18a, a zoom button 18b, a mode dial 18c, a menu button 18d, a quick view button 18e, a release button 18f (not shown in FIG. 2), and a cross key. 18g.

  The power switch 18a is a switch for controlling start / stop of the entire digital camera 1, and the zoom button 18b is a button for operating zooming. The mode dial 18c is a dial for switching between the moving image mode and the still image mode, and the menu button 18d is a button for displaying a menu on the LCD 16b. The quick view button 18e is a button for displaying a live view on the LCD 16b, and the release button 18f is a button for starting various types of imaging. The cross key 18g is a key for moving the cursor displayed in the image of the LCD 16b when the menu is displayed with the cross key surrounding the periphery and determining the menu selected by the center determination button.

<About the control unit>
The control unit 19 is a central part that controls the operation of the entire digital camera 1 and organically controls the driving of each member of the digital camera 1 to control the overall operation {for example, moving image recording or still image Recording switching control, etc.}. In the digital camera 1 according to the present embodiment, the control unit 19 writes the data on the first recording medium 30a attached to the first attachment unit 17a and the second recording medium 30b attached to the second attachment unit 17b. Includes a writing speed detecting unit 190 for detecting.

<About the writing speed detector>
Next, the writing speed detection unit 190 according to the present embodiment will be described. FIG. 3 is an explanatory diagram showing a schematic configuration of the writing speed detection unit 190. The writing speed detection unit 190 includes an external recording medium detection unit 191, a writing speed measurement unit 192, and a memory 193. The external recording medium detection unit 191 detects whether or not the first recording medium 30a and the second recording medium 30b are attached to the first mounting unit 17a and the second mounting unit 17b.

  In the writing speed measuring unit 192, the external recording medium detection unit 191 detects that the corresponding first recording medium 30a or second recording medium 30b is mounted on the first mounting unit 17a or the second mounting unit 17b. Then, the data writing speed of the mounted external recording medium is measured. Specifically, the measurement of the data writing speed is performed by writing benchmark data to the loaded first recording medium 30a or second recording medium 30b. The data writing speed may be measured by determining the type of the external recording medium that is loaded.

  A specific example of writing benchmark data and detecting the data writing speed is shown below. Assume that 10 MB capacity data is prepared as benchmark data. Assume that when 10 MB of benchmark data is actually written on a recording medium, it takes 5 seconds to complete the writing. In this case, 10 MB / 5 seconds = 2 MB / second is the data writing speed.

  In the memory 193, the data writing speed measured by the writing speed measuring unit 192 is recorded. Note that the recording of the data writing speed to the memory 193 may be performed in association with the recording medium ID determined for each recording medium. In this way, when the external recording medium is once removed from the first mounting portion 17a or the second mounting portion 17b and the same external recording medium is mounted again on the first mounting portion 17a or the second mounting portion 17b, This is effective in that it is not necessary to measure the data writing speed again.

  The data writing speed of each external recording medium may be recorded in a readable manner on each external recording medium itself, not on the memory 193. Even in this case, when the external recording medium is once removed from the first mounting portion 17a or the second mounting portion 17b and the external recording medium is mounted again on the first mounting portion 17a or the second mounting portion 17b. This is effective in that it is not necessary to measure the data writing speed again.

  There is also a method of detecting the data writing speed of the recording medium using moving image data to be recorded when a moving image recording request is actually made. Specifically, when a moving image recording request is made in a state where the first recording medium 30a is attached to the first attachment unit 17a and the second recording medium 30b is attached to the second attachment unit 17b, the control unit First, the moving image data to be recorded is actually written to both the first recording medium 30a and the second recording medium 30b.

  Then, the data writing speed at that time is measured by the writing speed measuring unit 192, and the moving image recording is continued for the external recording medium having the higher data writing speed, and the moving image recording is performed for the slower external recording medium. Stop. This is effective in that it is not necessary to record the data writing speed of the external recording medium in the memory 193 or the external recording medium itself, and the amount of memory can be reduced.

<Communication interface>
The communication interface 20 performs control such as protocol conversion according to specifications such as USB supported by the digital camera 1. That is, using the communication interface 20 enables communication with external devices including a network.

<Non-volatile memory>
The non-volatile memory 21 includes an EEPROM (electrically erasable and programmable ROM), a FLASH memory, and the like, and is a memory that holds data even when the digital camera 1 is turned off. The nonvolatile memory 21 according to the present embodiment is for storing a threshold data writing speed corresponding to each moving image recording condition. Details of the threshold data writing speed corresponding to each moving image recording condition will be described later.

<Details of control method during movie recording>
Next, details of a control method during moving image recording by the control unit 19 of the digital camera 1 will be described. A feature of the control method at the time of moving image recording by the control unit 19 according to the present embodiment is that the recording medium can be smoothly switched when moving image recording is continuously performed on a plurality of recording media. Therefore, it is possible to prevent frame dropping or sound interruption of recorded moving image data.

  First, a method for selecting a recording medium at the time of moving image recording by the control unit 19 will be described. The control part 19 selects the recording medium at the time of moving image recording based on a user's prior setting. This will be described in detail with reference to FIGS.

  FIG. 4 is an explanatory diagram showing a menu setting screen 40 of the digital camera 1. The menu setting screen 40 is displayed on the LCD 16b when the power of the digital camera 1 is input and the menu button 18d is pressed.

  FIG. 4A is an explanatory diagram showing a state when the basic 1 tab 41 a is selected on the menu setting screen 40. When the menu button 18d is pressed while the power of the digital camera 1 is input, the screen displayed first is the state in which the basic 1 tab 41a corresponding to this FIG. 4A is selected. It is a screen. On this screen, the exposure mode, AF mode, photometry mode, and flash mode can be set by operating the cross key 18g.

  FIG. 4B is an explanatory diagram showing a state when the basic 2 tab 41 b is selected on the menu setting screen 40. From the state in which the basic 1 tab 41a is selected (see FIG. 4A), the screen in the state in which the basic 2 tab 41b is selected is displayed by pressing the right key of the cross key 18g once. Is done.

  On the screen shown in FIG. 4B, the shooting sound mode, date input mode, recording condition mode, and recording medium selection mode can be set by operating the cross key 18g.

  The shooting sound mode is a mode for determining whether or not there is a shutter sound, and the date input mode is a mode for determining whether or not date information is to be taken into a recorded image. The recording condition mode is a mode for setting whether the recording conditions (number of pixels, number of recording frames, image quality (compression rate)) are set manually or automatically, and the recording medium selection mode performs recording. This is a mode for selecting a recording medium. Here, the reason that the recording condition mode is not simply the moving picture recording condition mode but the recording medium selection mode is simply set instead of the moving picture recording medium selection mode is that the setting for the still image is also used.

  When the recording medium selection mode is selected by operating the cross key 18g on the screen shown in FIG. 4B, the screen shown in FIG. 4C is displayed. Here, one of three displayed options, AUTO, the first external recording medium (first recording medium), or the second external recording medium (second recording medium) is selected. .

  In the screen shown in FIG. 4C, AUTO is selected, and the corresponding first recording medium 30a or second recording medium 30b is only in one of the first mounting portion 17a and the second mounting portion 17b. In the case of being mounted, when there is a moving image recording request, the moving image recording is performed on the mounted external recording medium.

  When AUTO is selected, the first recording medium 30a is mounted on the first mounting portion 17a, and the second recording medium 30b is mounted on the second mounting portion 17b, the moving image data is first written at the data writing speed. Is recorded on the faster external recording medium. When there is no remaining memory in the external recording medium, moving image data is recorded following the other external recording medium (which has a slower data writing speed) (for the control method when switching the external recording medium) Will be described later). In this way, since it is used (recorded) from an external recording medium with a high data writing speed, high-quality moving image recording is possible.

  In addition, when the first external recording medium or the second external recording medium is selected on the screen shown in FIG. 4C and there is a moving image recording request, the selected first recording medium 30a or second Moving image recording is performed only on the recording medium 30b.

  In addition to AUTO, the first external recording medium, and the second external recording medium, which are options for the recording medium selection mode, another option (hereinafter referred to as “user setting”) may be provided. The feature of “user setting” is that when the first recording medium 30a is attached to the first attachment portion 17a and the second recording medium 30b is attached to the second attachment portion 17b, the moving image data is recorded first. The user can set the recording medium to be set in advance. Other than that, it is exactly the same as AUTO.

  With such options, moving image recording can be performed continuously on the first recording medium 30a and the second recording medium 30b in the order desired by the user.

  FIG. 4D is an explanatory diagram showing a state when the application 1 tab 41 c is selected on the menu setting screen 40. The screen shown in FIG. 4D is displayed when the right key of the cross key 18g is pressed once from the state where the basic 2 tab 41b is selected (see FIG. 4B). .

  In the screen shown in FIG. 4D, the recording conditions (the number of pixels, the number of recording frames, the image quality (compression rate)) for recording on the first recording medium 30a are set by operating the cross key 18g. It can be carried out. The recording conditions set here are effective when the recording condition mode is set manually on the screen shown in FIG.

  FIG. 4E is an explanatory diagram showing a state when the application 2 tab 41 d is selected on the menu setting screen 40. The screen shown in FIG. 4E is displayed when the right key of the cross key 18g is pressed once from the state in which the application 1 tab 41c is selected (see FIG. 4D).

  In the screen shown in FIG. 4E, the recording conditions (the number of pixels, the number of recording frames, the image quality (compression rate)) for recording on the second recording medium 30b are set by operating the cross key 18g. It can be carried out. The recording conditions set here are effective when the recording condition mode is set manually on the screen shown in FIG.

  In the present embodiment, as described above, the recording condition (moving image recording condition) includes three parameters: the number of pixels, the number of shooting frames, and the compression rate. Therefore, the relationship between the quality of the moving image and the data writing speed is easily understood by the user, and the recording conditions can be easily set.

  In the digital camera 1 configured as described above, when the application 1 tab 41c shown in FIG. 4 (d) is selected, the recording conditions for recording on the first recording medium 30a are set, and in FIG. 4 (e). When the application 2 tab 41d shown is selected, the recording conditions for recording on the second recording medium 30b are set.

  However, based on the data writing speed detected by the writing speed detection unit 190, when the application 1 tab 41c shown in FIG. 4D is selected, recording is performed when recording is performed on an external recording medium having a higher data writing speed. The conditions may be set, and when the application 2 tab 41d shown in FIG. 4E is selected, the recording conditions for recording on the external recording medium with the slower data writing speed may be set.

  Further, the recording condition when recording on the first recording medium 30a and the recording condition when recording on the second recording medium 30b may be set in a lump. In this way, when it is desired to set the recording conditions for recording on the first recording medium 30a and the recording conditions for recording on the second recording medium 30b to be the same, it is convenient because it can be set at a time.

  Further, when the recording condition is set on the screen shown in FIG. 4D or FIG. 4E, the first recording medium mounted on the first mounting unit 17a or the second mounting unit 17b at that time. Comparison of data writing speed of 30a or second recording medium 30b with threshold data writing speed determined according to moving picture recording conditions, and setting of moving picture recording conditions such that threshold data writing speed exceeds data writing speed of recording medium It is possible to consider a configuration that prohibits the

  Note that the threshold data writing speed determined according to the moving picture recording conditions is a threshold of the writing speed of the recording medium in which almost no frame dropping or sound interruption occurs in each moving picture recording condition. Desired. It is assumed that the threshold data writing speed determined according to each moving image recording condition is stored in the nonvolatile memory 21.

  For example, on the screen shown in FIG. 4D, it is assumed that the number of pixels is set to a high-vision type (1920 × 1080 dots) and the number of recording frames is set to 30 fps (frames per seconds). It is assumed that the data writing speed of the first recording medium 30a is lower than the threshold data writing speed when the number of pixels is a high-vision type, the number of recording frames is 30 fps, and the image quality is FINE. In this case, when setting the image quality that is the next recording condition, it is impossible to set the image quality to FINE. Details of the image quality LINE will be described later.

Next, a recording medium selection procedure by the control unit 19 when moving image recording by the digital camera 1 is started will be described using the flowcharts of FIGS. 1 and 5. When a moving image recording request is made in the digital camera 1 (S ₁ ), the control unit 19 detects whether or not the recording medium selection mode is set to AUTO (S ₂ ). If the recording medium selection mode is not set to AUTO, the control unit 19 detects whether or not the recording medium selection mode is set to the first external recording medium (S ₃ ).

When the recording medium selection mode is set to the first external recording medium, the control unit 19 detects whether or not the corresponding first recording medium 30a is mounted on the first mounting unit 17a (S). ₄ ). When the first recording medium 30a is not attached, the control unit 19 may display a warning on the LCD 16b (S _5), the flow returns to S _4. On the other hand, in S _4, when the first recording medium 30a is mounted, the control unit 19 to perform the moving image recording on the first recording medium 30a (S _6), the remaining memory of the first recording medium 30a Video recording is continued until there is no recording or the recording command is canceled. Incidentally, if the remaining memory is lost or recording command of the first recording medium 30a is released, the control unit 19 terminates the moving image recording (S _7, S _8).

Further, in S _3, or the recording medium selection mode if it is set to the second external recording medium, the control unit 19, the second section 17b, the corresponding second recording medium 30b is mounted not Is detected (S ₉ ). If the second recording medium 30b is not mounted, the control unit 19 may display a warning on the LCD 16b (S _10), the flow returns to S _9. Or in S _9, when the second recording medium 30b is mounted, the control unit 19 to perform the moving image recording for the second recording medium 30b (S _11), the remaining memory of the second recording medium 30b is eliminated Alternatively, video recording is continued until the recording command is canceled. Incidentally, if the remaining memory is lost or recording command of the second recording medium 30b is released, the control unit 19 terminates the moving image recording (S _12, S _8).

Further, in S _2, when the recording medium selection mode is set to AUTO, the controller 19, first mounting portion 17a, to each of the second mounting portion 17b, the corresponding first recording medium 30a, the second recording medium 30b detects whether or not it is attached _{(S 13, S 14, S} 15). The first recording medium 30a, when neither is mounted in the second recording medium 30b (NO in NO and S ₁₅ in S _13), an alarm is displayed on the LCD16b (S _16), the flow returns to S _13.

In S _2, and the recording medium selection mode is set to AUTO, is mounted a first recording medium 30a only to the first mounting portion 17a is, the second mounting portion 17b is mounted a second recording medium 30b If not (nO at YES and S ₁₄ in S _13), the process proceeds to S _6. Then, the same processing as when the recording medium selection mode is set to the first external recording medium is performed (S ₆ , S ₇ , S ₈ ).

In S _2, the recording medium selection mode is set to AUTO, the first mounting portion 17a has not been mounted is the first recording medium 30a, the second recording medium 30b only to the second attachment portion 17b is mounted If it has flow proceeds to (YES at NO and S ₁₅ in S _13), S _11, to perform the same processing as when a recording medium selection mode is set to the second external recording medium (S _11, S _12, S _8).

In S _2, and the recording medium selection mode is set to AUTO, the first mounting portion 17a and the first recording medium 30a is mounted, and a second recording medium 30b is mounted on the second mounting portion 17b when on (YES at YES and S ₁₄ in S _13), the control unit 19 compares the data writing speed detected by the writing speed detection unit 190 (S _17). Here, it is assumed that the data writing speed of the first recording medium 30a is v ₁ and the data writing speed v ₂ of the second recording medium 30b.

If v ₁ ≧ v ₂ , first, moving image recording is performed on the first recording medium 30a (S ₁₈ ). Then, monitors whether or not the remaining memory of the first recording medium 30a is used up (S _19), if the remaining memory of the first recording medium 30a is used up, the process proceeds to S _11, below, the recording medium selection mode first The same processing as in the case where the external recording medium 2 is set is performed (S ₁₁ , S ₁₂ , S ₈ ). When the remaining memory of the first recording medium 30a is not lost monitors whether the recording command is canceled (S _20), and ends the recording if the recording command is canceled (S _8), the recording command if but not been released Back to S _18.

If v ₁ <v ₂ in S ₁₇ , first, moving image recording is performed on the second recording medium 30 b (S ₂₁ ). Then, monitors whether or not missing residual memory of the second recording medium 30b is (S _22), if the remaining memory of the second recording medium 30b is used up, the process proceeds to S _6, below, a recording medium selection mode first The same processing as in the case of setting to one external recording medium is performed (S ₆ , S ₇ , S ₈ ). When the remaining memory of the second recording medium 30b is not lost monitors whether the recording command is canceled (S _23), and ends the recording if the recording command is canceled (S _8), the recording command if but not been released Back to S _21.

  The above is the flow of selecting a recording medium at the time of moving image recording by the control unit 19 of the digital camera 1 according to the present embodiment. Next, when the first recording medium 30a is mounted on the first mounting portion 17a, the second recording medium 30b is mounted on the second mounting portion 17b, and the recording medium selection mode is set to AUTO. Details of the control procedure by the control unit 19 at the start of moving image recording and at the time of recording medium switching will be described.

  Since the recording medium selection mode is set to AUTO, as shown in the flowchart of FIG. 5, first, the data writing detected by the writing speed detection unit 190 out of the first recording medium 30a and the second recording medium 30b. Moving image recording is performed on a recording medium with a higher speed (hereinafter referred to as recording medium A).

  At this time, if the recording condition mode is automatically set on the screen in which the basic 2 tab 41 b is selected (see FIG. 4B), the recording condition is set by the control unit 19 by the writing speed detecting unit 190. Based on the detected data writing speed of the recording medium A and a threshold data writing speed determined in accordance with each moving picture recording condition, a recording condition is set so that no frame dropping or sound interruption occurs.

  As this algorithm, for example, searching for a recording condition that maximizes the threshold data writing speed within a range not exceeding the data writing speed of the recording medium A, and setting the recording condition can be considered.

  On the other hand, if the recording condition mode is set to manual on the screen in which the basic 2 tab 41b is selected (see FIG. 4B), when the recording medium A is the first recording medium 30a, the recording condition is The recording conditions are set on the screen selected in the application 1 tab 41c (see FIG. 4D). Similarly, when the recording medium A is the second recording medium 30b, the recording conditions are set on the screen (see FIG. 4E) on which the application 2 tab 41d is selected.

  Here, if the recording condition mode is set to manual on the screen in which the basic 2 tab 41b is selected (see FIG. 4B), the writing speed of the recording medium A is set to the manually set recording condition. It may happen that the threshold data writing speed is set below accordingly.

  When moving image recording is performed under the same recording conditions when the data writing speed of the recording medium A is lower than the threshold data writing speed determined according to the recording conditions, dropped frames or sound interruptions occur in the recorded moving image data. Sometimes. Therefore, in this case, the control unit 19 displays a warning on the LCD 16b and changes the recording condition to a recording condition in which the threshold data writing speed is lower than the data writing speed of the recording medium A. Alternatively, the control unit 19 may display the change contents of the recording condition on the LCD 16b and start moving image recording after waiting for the user's permission.

  As an algorithm for changing the recording condition, for example, a recording condition that maximizes the threshold data writing speed within a range not exceeding the data writing speed of the recording medium A is searched, and the recording condition is set. Conceivable.

  When the remaining memory of the recording medium A runs out due to the progress of moving image recording, since the recording medium selection mode is set to AUTO, the recording medium with the slower data writing speed detected by the writing speed detection unit 190 (Hereinafter referred to as recording medium B), moving image recording is performed.

  At this time, when the recording condition mode is automatically set on the screen in which the basic 2 tab 41b is selected (see FIG. 4B), the control unit 19 detects the recording detected by the writing speed detection unit 190. Based on the data writing speed of the medium B and the threshold data writing speed determined according to each moving picture recording condition, the recording condition is changed so as not to cause frame dropping or sound interruption, and the moving picture recording is continued.

  As this algorithm, for example, it is conceivable to search for a recording condition that maximizes the threshold data writing speed within a range not exceeding the data writing speed of the recording medium B, and to set the recording condition.

  If the recording condition mode is set to manual on the screen in which the basic 2 tab 41b is selected (see FIG. 4B), the recording condition is applied when the recording medium B is the first recording medium 30a. The recording conditions are set on the screen (see FIG. 4D) on which the 1 tab 41c is selected. Similarly, when the recording medium B is the second recording medium 30b, the recording conditions are set on the screen (see FIG. 4E) on which the application 2 tab 41d is selected.

  Here, if the recording condition mode is set to manual on the screen in which the basic 2 tab 41b is selected (see FIG. 4B), the data writing speed of the recording medium B is set to the manually set recording condition. May fall below a threshold data writing speed determined according to.

  When the data writing speed of the recording medium B is lower than the threshold data writing speed determined in accordance with the manually set recording conditions, if recording is continued under the same recording conditions, frame dropping or sound Cuts occur. Therefore, in this case, the control unit 19 displays a warning on the LCD 16b and changes the recording condition to a recording condition in which the threshold data writing speed is lower than the data writing speed of the recording medium B. Alternatively, the control unit 19 may display the change contents of the recording condition on the LCD 16b and continue the moving image recording after waiting for the user's permission.

  As an algorithm for changing the recording condition, for example, a recording condition that maximizes the threshold data writing speed within a range not exceeding the data writing speed of the recording medium B is searched, and the recording condition is set. Conceivable.

  In the above, when the data writing speed of the recording medium A or the recording medium B is lower than the threshold data writing speed determined according to the manually set recording conditions, the data writing speed of the recording medium is the threshold data writing speed. The recording conditions were changed so as to exceed the above, and moving image recording was performed. However, a mode for stopping moving image recording in such a case may be provided in the recording medium selection mode. When such control is performed, the moving image recording itself is stopped, so that there is no possibility of frame dropping or sound interruption in the recorded moving image data.

Hereinafter, a specific example of a control procedure by the control unit 19 at the start of moving image recording and switching of the external recording medium will be described with reference to the flowcharts of FIGS. 1 and 6. In this specific example, the data writing speed of the recording medium _A is v _A and the data writing speed of the recording medium B is v _B. That is, v _A ≧ v _B.

  In addition, the digital camera 1 has two types of pixels: “VGA (640 × 480 dots)” and “QVGA (320 × 240 dots)”, and the number of recorded frames from “30 fps (frames per second), 24 fps”. Assume that the image quality can be selected from three types: “FINE (high image quality, that is, low compression ratio)”, STANDARD (medium image quality, that is, medium compression ratio), and ECONOMY (low image quality, that is, high compression ratio). In this specification, a high compression ratio indicates a case where the amount of data after compression is greatly reduced as compared to the amount of data before compression, and a low compression ratio indicates a comparison with the amount of data before compression. The case where the data amount after compression does not decrease so much will be shown.

  In the screen where the basic 2 tab 41b is selected (see FIG. 4B), the recording condition mode is set manually, and the set value is VGA, for both the first recording medium 30a and the second recording medium 30b. Assume 30 fps and ECONOMY. The threshold data writing speed determined by the conditions of VGA, 30 fps ECONOMY is vε, and the threshold data writing speed determined by the conditions of Vε, QVGA, 30 fps, ECONOMY is vδ. Note that vε and vδ can be determined empirically by conducting a preliminary experiment.

  That is, if the data writing speed of the recording medium is equal to or higher than vε, moving image recording is possible under the manually set recording conditions of VGA, ECONOMY, and 30 fps, while the data writing speed of the recording medium is higher than vδ and If it is less than vε, moving image recording is possible under conditions of QVGA, ECONOMY, and 30 fps. Further, if the data writing speed of the recording medium is less than vδ, moving image recording is possible only under the conditions of QVGA, ECONOMY, and 24 fps.

At this time, the control unit 19 performs the control shown in the flowchart of FIG. That is, when a moving image recording request is made (S ₁₀₀ ), the control unit 19 detects the magnitude relationship between v _A and vε (S ₁₀₁ ). If v _A ≧ vε, the number of pixels is set to VGA (S ₁₀₂ ), the number of recording frames is set to 30 fps (S ₁₀₃ ), and the image quality is set to ECONOMY (S ₁₀₄ ) as set manually.

If v _A <vε in S ₁₀₁ , the control unit 19 displays a warning to set the number of pixels to QVGA on the LCD 16 b (S ₁₀₅ ), and sets the number of pixels to QVGA (S ₁₀₆ ). Next, the magnitude relationship between v _A and vδ is detected (S ₁₀₇ ). If v _A ≧ vδ, the number of recorded frames is set to 30 fps (S ₁₀₃ ), and the image quality is set to ECONOMY (S ₁₀₄ ).

If v _A <v δ in S ₁₀₇ , the control unit 19 displays a warning to the effect that the recording frame number is set to 24 fps on the LCD 16 b (S ₁₀₈ ), and sets the recording frame number to 24 fps (S ₁₀₉ ). each set of image quality ECONOMY (S _104).

This completes the setting of recording conditions for recording moving images on the recording medium A, and the control unit 19 causes the recording medium A to perform moving image recording (S ₁₁₀ ). Then, the control unit 19, during moving image recording executing, monitors whether the release request recording command (S _111), if there is cancellation of recording command request, ends the moving image recording (S _112). During moving image recording, the remaining memory of the recording medium A is monitored ( _S113 ), and if there is remaining memory that can continue moving image recording, the process returns to _S110 .

If there is no remaining memory capable of continuing moving image recording, the magnitude relationship between v _B and vε is detected (S ₁₁₄ ). v If a _{B <vε,} to display a warning that setting the number of pixels to QVGA to LCD16b (S _115), sets the number of pixels to QVGA (S _116). Incidentally, at the time of recording to the recording medium A, already when the number of pixels is set to QVGA, the number of pixels is intact, set by the S ₁₁₆ is not changed.

Next, the magnitude relationship between v _B and v δ is detected (S ₁₁₇ ). v If a _B <v?, to display a warning to the effect that the 24fps the recording rate to LCD16b (S _118), setting the recording rate to (S ₁₁₉₎ to 24fps. If the number of frames to be recorded is already set to 24 fps during recording on the recording medium A, the number of frames to be recorded remains as it is, and the setting is not changed by _S119 . The image quality remains ECONOMY and is not changed.

Note that if v _B ≧ vε in S ₁₁₄ , it is clearly v _A ≧ vε at this time. Therefore, the recording condition for recording moving images on the recording medium B is that the moving images were recorded on the recording medium A. (The number of pixels is VGA, the number of recording frames is 30 fps, and the image quality is ECONOMY).

In S ₁₁₇ , if v _B ≧ v δ, then v _A ≧ v δ is obvious, so that recording conditions other than the number of pixels when recording moving images on the recording medium B are as follows. The recording conditions are the same as when recording (recording frame number is 30 fps, image quality is ECONOMY).

This completes the setting of the recording conditions for performing moving image recording on the recording medium B, and the control unit 19 causes the external recording medium B to perform moving image recording (S ₁₂₀ ). Then, the control unit 19, during moving image recording executing, monitors whether the release request recording command (S _121), if there is cancellation of recording command request, ends the moving image recording (S _112). Further, during moving image recording executing monitors the remaining memory of the recording medium B (S _122), the flow returns to S ₁₂₀ if there is residual memory that can continue moving image recording. If there is no remaining memory capable of continuing the moving image recording, the recording is terminated ( _S112 ).

  In the digital camera 1 configured as described above, the control unit 19 performs moving image recording in the order of the recording medium A and the recording medium B, and ends moving image recording when there is no remaining memory in the recording medium B. However, the control unit 19 runs out of the remaining memory of the recording medium A, and while recording a moving image on the recording medium B, another recording medium C is attached to the external recording medium mounting unit on which the recording medium A is mounted. When the recording medium B is mounted, this may be detected by the external recording medium detection unit 191, and when the remaining memory of the recording medium B runs out, the recording medium may be switched to the recording medium C to continue moving image recording.

  At this time, if the data writing speed of the recording medium C is not measured, the data writing speed of the recording medium C is written by the writing speed measuring unit 192 of the writing speed detecting unit 190 when moving image recording is performed on the recording medium B. Need to measure speed. However, if the measurement of the data writing speed of the recording medium C is not in time, the recording medium C under the recording conditions with the slowest threshold data writing speed (in this embodiment, the number of pixels is QVGA, the number of recording frames is 24 fps, and the image quality is ECONOMY). It is also possible to start moving image recording, detect the data writing speed of the recording medium C while performing moving image recording, and then change the recording conditions.

  In the digital camera 1 having the above-described configuration, the control unit 19 switches the recording conditions (the number of pixels, the number of recording frames, the compression) set in advance by the user when the recording medium is switched when recording a moving image continuously on a plurality of recording media. When the threshold data writing speed determined according to the rate exceeds the data writing speed of the recording medium after switching the recording medium, the recording condition is automatically changed and the moving image recording is continued. Therefore, when moving images are continuously recorded on a plurality of recording media, it is possible to prevent frame dropping or sound interruption of moving image data.

  In the above description, the control unit 19 compares the data writing speed of the recording medium during moving image recording with the threshold data writing speed under the set recording conditions to determine whether to change the recording conditions, Alternatively, it is determined whether or not to continue video recording. However, when the moving image mode is selected by the mode dial 18c, it may be determined whether or not moving image recording under the set recording conditions is possible for each recording medium mounted at that time.

  For example, when a recording medium having a data writing speed slower than the threshold data writing speed corresponding to the set recording condition is loaded, the fact is displayed on the LCD 16b. In such a case, the LCD 16b may display a selection screen for determining whether or not to continuously record a moving image so that the user can select it.

  In addition, this invention is not limited to said embodiment, A various change is possible in the range which does not deviate from the meaning of this invention. For example, in the present embodiment, the recording medium is two external recording media, but it may be configured such that one external recording medium and one recording medium built in the digital camera 1 are used. Further, the number of recording media to be mounted may be three or more.

  The present invention is effective as an imaging apparatus capable of recording a moving image.

1 is a block diagram illustrating a schematic configuration of a digital camera according to an embodiment of the present invention. 2A is an external side view of the digital camera according to the embodiment of the present invention, and FIG. 2B is an external rear view of the digital camera according to the embodiment of the present invention. It is explanatory drawing which shows the schematic structure of the write-speed detection part which concerns on this embodiment. It is explanatory drawing which shows the menu setting screen of the digital camera which concerns on this embodiment. It is a flowchart which shows the procedure of the recording medium selection by a control part at the time of the moving image recording by the digital camera which concerns on this embodiment. 6 is a flowchart illustrating a control procedure by a control unit at the start of moving image recording and switching of an external recording medium in the digital camera according to the present embodiment.

Explanation of symbols

1 Digital camera (imaging device)
18 Operation part (video recording condition input part, priority order input part)
19 Control unit 30a First external recording medium, first recording medium (recording medium)
30b Second external recording medium, second recording medium (recording medium)
190 Write speed detector

Claims (7)

An imaging apparatus having a writing speed detection unit for detecting a data writing speed to a recording medium and capable of continuously recording moving images on the plurality of recording media,
When the moving image recording is set or during the moving image recording, the data writing speed of the recording medium is compared with the threshold data writing speed determined according to the moving image recording condition, and the moving image recording condition is determined according to the comparison result. , A control unit for determining whether or not continuous video recording is possible,
An image pickup apparatus comprising: The control unit
2. The control according to claim 1, wherein when it is determined that continuation of moving image recording is impossible, the threshold data writing speed is changed by changing the moving image recording condition, and the moving image recording is continuously controlled. Imaging device. The control unit
The imaging apparatus according to claim 1, wherein if it is determined that continuation of moving image recording is not possible, control is performed such that continuous moving image recording is not performed. The control unit
Based on the data writing speeds of the plurality of recording media detected by the writing speed detection unit, priorities are assigned to the plurality of recording media, and when moving image recording is performed, the priorities are used in descending order. 4. The imaging apparatus according to claim 1, wherein a recording medium is selected. A priority order input unit for giving a priority order to the plurality of recording media is provided,
The control unit
4. The recording medium to be used according to claim 1, wherein when recording a moving image, the recording medium to be used is selected in the descending order of priority given by the priority order input unit. 5. Imaging device.   6. The moving image recording condition input unit that sets the moving image recording conditions corresponding to each of the plurality of recording media individually or collectively is provided. 6. Imaging device. The above video recording conditions are:
The imaging apparatus according to claim 1, wherein the imaging apparatus includes at least one of three parameters of the number of pixels, the number of photographed frames, and the compression rate.