JP2006217159A - Imaging apparatus, imaging data recording method, and slave information acquiring method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging data recording method and a slave information acquiring method for surely and successively recording imaging data. <P>SOLUTION: Master equipment 10 records the imaging data obtained as a result of photographing operation by a user in recording media in the master equipment 10. Here, when the remaining recording time of recording media decreases below a designated time, the recording destination of the imaging data is automatically switched to recording media of slave equipment 20 connected to the master equipment 10 through a network. The designated time is previously set by the user of the master equipment 10 to an arbitrary value. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an imaging apparatus, an imaging data recording method, and a slave information acquisition method capable of easily realizing reliable recording of imaging data or continuous recording of imaging data.

  Imaging devices such as video cameras are becoming more popular in ordinary households as prices and compactness are further advanced with the recent development of data processing technology and recording technology. In addition, products that enable long-time recording by expanding the battery duration and improving the recording density are put on the market one after another. Various improvements in such an imaging apparatus result in improving the portability of the imaging apparatus.

  With the widespread use of imaging devices such as those mentioned above, various recording methods have been adopted so that important recordings are not lost or recorded data is not lost if there is a problem with replacement of recording media such as tapes or any other problems. Has been.

  Conventionally, each operation mode such as a sync operation mode, a relay operation mode, and an external operation mode is set so that imaging data obtained by an imaging apparatus such as a video camera is recorded reliably or continuously. The user selects one of these operation modes according to the value of the imaging data and the importance of ensuring the continuity of the data.

  Here, each of these operation modes will be described. Note that the master device is a video camera or the like that acquires images and sounds as electrical signals via a CCD (Charge-Coupled Device), a microphone, etc., and encodes these electrical signals using a predetermined encoding method if necessary. It is an imaging device. On the other hand, a slave device is a device that is connected to a master device via a predetermined network and includes recording means that can record encoded image data and audio data (imaging data).

[Synchro operation mode]
The synchro operation mode is a mode in which the same data as the imaging data recorded by the master device is recorded in the slave device in conjunction (synchronization) with the recording operation of the imaging data in the master device. The imaging data of the master device is transmitted to the slave device via the network. In addition, the master device transmits a recording start command and a recording stop command to the slave device at the recording start and recording stop timings, respectively, and links the recording operations of the two. In other words, in this mode, the image data is completely duplicated and recorded. In this operation mode, it is necessary to secure a large-capacity recording medium for storing data. For example, even if the tape or disk on which the imaging data is recorded is damaged and the data cannot be read, The image data remains in the complete form on the other recording medium, and the risk of losing the image data is extremely low.

[Relay operation mode]
The relay operation mode is a slave device when the recordable time (for example, the remaining amount of tape) of the recording medium (for example, a recording medium such as a tape or a recordable DVD (Digital Versatile Disk)) becomes small. A recording start command is transmitted to the master device, and control is performed so that the imaging data being acquired by the master device is recorded in the slave device. Thus, even when the recording medium is exchanged in the master device, the imaging data of the master device is recorded in the slave device, and continuous shooting is possible.

[External operation mode]
The external operation mode records from the master device to the slave device when the master device start / stop key is pressed, regardless of whether the master device can use the recording media (for example, whether a tape is loaded). A start command or a recording stop command is transmitted, and imaging data being acquired by the master device is recorded in the slave device. In this case, the master device does not perform imaging data recording operation.

  In addition, there is a master device that can display the operation state of the slave device from the viewpoint of reliably performing the imaging data recording in the slave device. This is realized by the master device inquiring the status of the slave device by a prescribed command. The display function displays, for example, the operation state of the slave device (that is, whether the slave device is in the recording state, the standby state, or the stop state) on the display panel of the master device, for example. In the above-described external operation mode, it is determined whether or not the slave device is to perform a recording operation using the inquiry result of the specified command.

  Note that the command transmitted from the master device to the slave device depends on the protocol of the network connecting the master device and the slave device. For example, when a master device and a slave device are connected by an IEEE 1394 network, an AV / C (Audio / Video Control) command is used. In this case, normally, the recording start command is a “REC” command, and the recording stop command is a “REC-PAUSE” command. However, since some devices do not support the “REC-PAUSE” command, the user uses the “REC-PAUSE” command as the recording stop command or uses the “STOP” command in the master device. There are many things that can be selected.

  A typical device that is not compatible with the “REC-PAUSE” command is a hard disk device. Originally, the pause state refers to a state in which a tape can be loaded and recording can be performed in a recording apparatus that uses a tape as a recording medium, and is distinguished from a stop (stop) state. Therefore, a device using a hard disk as a recording medium, such as a hard disk device, has no loading and does not have the concept of “pause”.

  As for the synchro operation mode described above, for example, a similar function is disclosed in the recording system of Patent Document 1. In the recording system of Patent Document 1, synchronization data for time synchronization is transmitted from a master device to a slave device, and synchronization between the master device and the slave device is performed according to this synchronization data.・ Recording is performed.

Japanese Patent No. 3544538

  Patent Document 2 discloses an editing system that transmits a video signal from a master device to a slave device connected to the master device via an IEEE 1394 cable.

JP 2000-36937 A

  However, in the relay operation mode as described above, when the remaining recording medium of the master device becomes, for example, 5 minutes (that is, when only 5 minutes can be recorded), recording by the slave device is possible. The remaining amount is specified by a fixed value such as “5 minutes” or “30 seconds”. For this reason, in order for the user to start recording by the slave device, shooting must be continued up to the designated remaining amount, which is very inconvenient.

  In addition, regarding the function of displaying the status of the slave device on the master device, only the “operating status” of the slave device is displayed, so there is not enough recording media or battery remaining on the slave device. However, the user may not notice and there is a possibility that recording of the imaging data may fail.

  Furthermore, when the master device is operating in the external operation mode, the recording media of the slave device and the remaining battery level are unknown, so the recording media of the slave device suddenly terminates and the shooting data Will not be recorded as scheduled.

  Therefore, an object of the present invention is to provide an imaging data recording method and a slave information acquisition method for easily realizing reliable or continuous recording of imaging data.

  A further object of the present invention is to provide an imaging apparatus and an imaging data recording method in which a user can set a recording start condition by a slave device in the relay operation mode. The starting condition in this case is, for example, that the recording medium remaining amount (for example, remaining recording time) and the remaining battery amount (operable time) of the master device become values specified by the user.

  A further object of the present invention is to provide an imaging apparatus having a function of displaying the remaining amount of recording media (for example, remaining recording time) and the remaining amount of battery (for example, remaining operating time) of the slave device. .

  In addition, when the master device is operating in the external operation mode, the present invention further checks the recording medium remaining amount of the slave device, the remaining battery amount, etc. An object of the present invention is to provide an imaging apparatus having a specification for forcibly switching to a recording operation by a master device.

  According to a first embodiment of the present invention, there is provided a first recording means for recording imaging data obtained by a photographing operation, and imaging data when a remaining recording time of the first recording means is shorter than a predetermined time. The image pickup apparatus is configured to have recording control means for controlling the recording to be recorded on the second recording means. In this case, the predetermined time is designated by the user.

  Further, the recording destination of the imaging data may be switched based on not only the remaining recording time of the first recording means but also the remaining battery time of the master device. Furthermore, this idea may be extended so that the recording destination of the imaging data is switched based on the combination of the remaining recording time of the first recording means and the remaining battery time of the master device. According to this embodiment, it is possible to obtain a safe backup of imaging data, and it is possible to record a continuous series of imaging data even while the master device is performing tape exchange or the like.

  According to a second embodiment of the present invention, in the first embodiment described above, the first recording means is a recording medium built in or loaded in the imaging apparatus, and the second recording means is connected via a network. The imaging device is configured to be an external recording device connected to each other.

  A third embodiment of the present invention is an imaging device that operates as a master device by accessing a slave device including a first recording unit via a network, and the imaging device includes a predetermined number of slave devices. By transmitting this command, slave information acquisition means for acquiring the remaining recording time of the first recording means is provided.

  According to this embodiment, the master device can grasp the remaining recording time of the recording media of the slave device.

  A fourth embodiment of the present invention is an image pickup apparatus configured to further include a second recording unit and a recording control unit in the third embodiment of the present invention. The recording control means is the remaining of the first recording means obtained from the slave information obtaining means when operating in the mode for recording the imaging data obtained by the photographing operation in the first recording means of the slave device. When the recording time becomes shorter than the predetermined time, control is performed so that the imaging data is recorded in the second recording means.

  The predetermined time described above is preferably designated as an arbitrary time by the user. Further, the recording destination of the imaging data may be switched based on not only the remaining recording time of the first recording means but also the remaining battery time of the slave device. Furthermore, this idea may be extended so that the recording destination of the imaging data is switched based on the combination of the remaining recording time of the first recording means and the remaining battery time of the slave device. Further, according to the embodiment, in the master device, when the remaining recording time of the recording medium of the slave device becomes short, the recording destination of the imaging data can be forcibly set as the master device. The risk of losing is reduced.

  A fifth embodiment of the present invention is an image pickup apparatus configured to further include a display unit and a display control unit in the third embodiment of the present invention. The display control means operates when the imaging data obtained by the photographing operation is recorded in the first recording means of the slave device in the mode for recording the remaining of the first recording means obtained from the slave information acquisition means. When the recording time becomes shorter than the predetermined time, control is performed so that the fact is displayed on the display means.

  The predetermined time described above is preferably designated as an arbitrary time by the user. Further, according to this embodiment, it can be seen that the remaining recording time of the recording medium of the slave device has become short in the master device, and the user then takes measures to normally record the imaging data by various methods. be able to.

  According to a sixth embodiment of the present invention, there is provided a recording step for recording imaging data obtained by a photographing operation in the first recording means, and a case where the remaining recording time of the first recording means is shorter than a predetermined time. And a recording control step for controlling to record the imaging data in the second recording means. In this case, the predetermined time is designated by the user.

  According to a seventh embodiment of the present invention, there is provided a method for accessing a slave device provided with a first recording means via a network and recording imaging data with an imaging device that operates as a master device. Includes a step of transmitting a predetermined command to the slave device, and a slave information acquiring step of acquiring a remaining recording time of the first recording means by receiving a response to the predetermined command from the slave device.

  With the imaging apparatus according to the present invention, in the relay operation mode, the recording start condition by the slave device can be arbitrarily set by the user. Thereby, the user can set the recording medium remaining amount (recordable time) and the battery remaining amount (operable time) of the master device to arbitrary values, for example.

  In addition, the remaining amount of recording medium (recordable time), remaining amount of battery (operable time), and the like of the slave device are displayed on a predetermined display unit of the imaging device by the imaging device according to the present invention. As a result, the user can easily determine how much image data can be recorded by the slave device. For example, when the master device is operating in the external operation mode, the user can use this information to If the recording capacity falls below the specified remaining amount, the possibility of failing to record the imaging data is reduced if the recording can be automatically switched to the master device.

  First, an outline of an imaging system including an imaging apparatus according to an embodiment of the present invention will be described with reference to FIG. In the imaging system shown in FIG. 1, the master device 10 is an imaging device according to the present invention, for example, a device such as a video camera. The slave device 20 is a device that can record image data from the master device 10 and functions as an external recording device from the master device 10.

  Examples of the slave device 20 include a video camera 21, a hard disk device 22, a personal computer 23, a DVD recorder 24, and the like similar to the master device 10, for example. The recording medium of the slave device 20 is, for example, a tape or a recordable DVD for the video camera 21, a hard disk for the hard disk device 22, and a recordable DVD for the personal computer 23 or DVD recorder 24. Or a recording medium such as a hard disk. However, the slave device 20 of the present invention may be configured by any device, and the type of recording medium is not limited.

  Here, the imaging data is data obtained as a result of the user performing a shooting operation using the imaging apparatus (that is, the master device 10). For example, the DV (Digital Video) format, which is a home digital video format, This is data according to the HDV (High Definition Video) standard that enables recording and reproduction of high definition HD (High Definition) video using a DV standard cassette tape for home use.

  The master device 10 and the slave device 20 are connected by a network 30 such as IEEE1394. In this embodiment, the description will be made on the assumption that the connection is based on the IEEE 1394 network. However, the present invention is not limited to such a network. Any network may be used as long as imaging data can be transmitted from the master device 10 and a command for causing the slave device 20 to perform a predetermined operation can be transmitted via the network. The slave device 20 may also include a device that is directly connected to a predetermined terminal of the master device 10 without going through a network.

  In the IEEE 1394 network, the master device 10 and the slave device 20 are normally connected using an IEEE 1394 cable. However, the network 30 of the present invention can be configured not only by a wired network but also by a wireless network.

  In the IEEE 1394 network, recording operation control and operation state confirmation of the slave device 20 are performed by AV / C commands transmitted from the master device 10.

  For example, a company that provides a service that captures the appearance of a wedding reception is often required to shoot everything without interruption from the beginning to the end of the wedding reception. In the configuration of one imaging system, it is desirable to perform imaging using the relay operation mode. In this mode, it is usually possible to shoot using the master device 10 and record the image data on the slave device 20 only while the recording medium is exchanged. Imaging data can be extracted from the moment.

  In this case, the slave device 20 needs to be connected to the master device 10 with an IEEE 1394 cable. For example, if it is lightweight, the slave device 20 can be carried with the master device 10 by a photographer. It can also be installed at any location in the venue or in the adjacent room.

  Next, a transition example of the setting screen in the imaging apparatus according to an embodiment of the present invention will be described with reference to FIG. The screen 40 to the screen 80 shown in FIG. 2 can be displayed on the display panel of the imaging apparatus so as to overlap with the captured image, for example, by OSD (On Screen Display).

  The screen 40 displays an input / output setting screen 41 when the user performs a predetermined operation on the master device. Therefore, the user selects one of several functions displayed on the input / output setting screen 41. Here, “external REC control” (indicated by reference numeral 42) related to the present invention is selected. The selection by the user is performed, for example, by pressing an up button or a down button provided in the imaging apparatus to bring the cursor to the position of “external REC control”, and similarly pressing a determination button provided in the imaging apparatus there. .

  When “external REC control” is selected on the screen 40, the screen transitions to the screen 50, where an external REC control screen 51 is displayed. In this example, three setting items “REC control mode”, “standby command”, and “relay start time” are shown.

  Here, when the “REC control mode” is selected, the screen transitions to the screen 60, where the REC control mode designation screen 61 is displayed. This is a screen for designating which of the three operation modes described above, that is, the operation mode among the sync operation mode, the relay operation mode, and the external operation mode. When the operation mode is determined using the determination button or the like, the designated operation mode is recorded in the memory or the like, and then the screen 50 is changed again.

  When “standby command” is selected on the external REC control screen 51 shown on the screen 50, the screen transitions to the screen 70, where a standby command designation screen 71 is displayed. As described above, this is a screen for designating which type of recording stop command the slave device 20 accepts, and “REC-PAUSE” or “STOP” is selected. Is determined, the designated recording stop command is recorded in the memory or the like, and thereafter, the screen 50 is changed again.

  When “relay start time” is selected on the external REC control screen 51 shown on the screen 50, the screen transitions to the screen 80, where a relay start time designation screen 81 is displayed. This is a screen for designating a condition for switching the storage location of the imaging data to the slave device 20 in the relay operation mode, and shows several candidates for the remaining amount of recording media in the master device 10. Among these, for example, when “30 seconds” is selected, the imaging data is recorded on the recording medium of the slave device 20 when the remaining recording medium of the master device 10 reaches 30 seconds. Thereafter, when the relay start time is determined using the determination button or the like, the determined value is recorded in a memory or the like, and then the screen 50 is changed again.

  In the example of the relay start time designation screen 81, several candidates for the remaining recording time are shown, but the user can also be configured to input a predetermined value. Further, not the remaining recording time but the remaining capacity or the remaining ratio (%) can be set as a reference. When the storage location of the imaging data specifies a condition for switching to the slave device 20 by time, it is necessary to perform switching control in consideration of the recording format. This is because the capacity of the recording medium that is “consumed” per time differs depending on the recording format in which the imaging data is configured. Also, in a moving image recording format that performs motion compensation, a small recording capacity may be sufficient when shooting a scene with little motion.

  Furthermore, it is possible to designate not the remaining recording medium but the remaining battery of the master device 10 (for example, the remaining battery time or remaining capacity). The drive system of the tape and disk consumes a large amount of power, and it is sufficiently effective to extend the operation time of the master device 10 just by performing these operations by the slave device 20.

  Further, on the relay start time designation screen 81, it is possible to designate the combination of the remaining recording medium of the master device 10 and the remaining battery.

  When the designation on the screen 60 to the screen 80 is completed and “(determine)” is selected on the external REC control screen 51 shown on the screen 50, the designated content is confirmed and the screen 40 is displayed. In the external operation mode, when the remaining amount of recording media in the slave device reaches a predetermined value, it can be controlled to force the recording destination of the imaging data to be the recording media of the master device. The case and the remaining amount can be specified by the user by adding an item such as “external operation start time” to the external REC control screen 51, for example.

  Next, an example of operations of the master device 10 and the slave device 20 when the relay operation mode is designated will be described with reference to FIG. The upper column 100 and the column 110 in FIG. 3 are portions showing operations related to the master device 10 in time series. The column 100 shows the timing when the start / stop key is pressed, and the column 110 shows a line D representing the operating state of the master device 10. On the other hand, in the column 120 at the bottom of FIG. 3, a line E representing the operation state of the slave device 20 is shown in time series in association with the operation of the master device 10.

  Here, the start / stop key (not shown) of the image pickup apparatus (master device 10) according to the present invention is substantially composed of, for example, one button, and starts when pressed once (recording start in the master device 10). Then, when it is pressed again, it becomes a stop (recording stop in the master device 10). However, when the recording medium is automatically stopped due to the end of the recording medium or the like, pressing the button thereafter (after the recording medium becomes usable) starts. Hereinafter, pressing the start button is expressed as a start key press, and pressing the stop button is expressed as a stop key press.

  When the user first presses the start key of the master device 10 at timing 130, the master device 10 starts recording of imaging data. Among the lines D, a horizontal dotted line indicates a stop state (or standby state), a horizontal solid line indicates a recording state, and alternate long and short dash lines between these states are Represents a transition to a state. The situation when the start key is pressed at timing 130 is indicated by the transition of the line D from the stop state to the recording state.

  When the user presses the stop key at timing 131, the recording operation of the master device 10 ends. This is indicated by the transition of line D from the recorded state to the stopped state.

  When the user presses the start key again at the timing 132, recording is started on the master device 10 as in the case of the timing 130 (transition from the stop state to the recording state on the line D). Thereafter, it is assumed that the remaining amount of the recording medium reaches the time set by the user at the timing indicated by the line A. Then, the master device 10 transmits a REC command to the slave device 20 at that time (timing 140), and recording of the imaging data in the slave device 20 is started (the line E changes from the stopped state to the recorded state). Transition). At this time, the imaging data acquired by the master device 10 is recorded on the recording medium of the master device 10 and also on the slave device 20. Here, the time designated for the remaining amount of recording media is the time designated by the user on the relay start time designation screen 81 of FIG.

  Next, when the user presses the stop key at timing 133, the recording operation of the master device 10 ends (the line D transitions from the recording state to the stop state). However, here, the recording operation in the slave device 20 continues.

  Thereafter, when the user presses the start key again at timing 134, recording starts on the master device 10 (the line D transitions from the stopped state to the recording state). The master device 10 transmits a REC command to the slave device 20 at that time (timing 141). At this time, the slave device 20 is already in a recording state, and there is no change in operation even if a REC command is received from the master device 10.

  As described above, in a situation where imaging data is recorded in both the master device 10 and the slave device 20, it is assumed that the recording medium of the master device 10 ends at the timing represented by the line B, that is, the remaining portion becomes zero. . Then, as indicated by line D, the operating state of the master device 10 changes from the recording state to the stopped state. At this time, the recording of the imaging data by the slave device 20 continues.

  Thereafter, it is assumed that the recording medium of the master device 10 has been exchanged and that the recording medium can be used at the timing indicated by the line C. After that, when the user presses the start key at timing 135, recording of imaging data is started in the master device 10 (the line D transitions from the stop state to the recording state). On the other hand, the slave device 20 continues the recording operation from the timing indicated by the line C to the timing 135. Here, the timing at which the recording medium can be used refers to the time when a new tape is loaded and the loading is completed, for example, in the case of a tape.

  In this example, the recording operation is continued from the timing indicated by the line C to the timing 135 regardless of the user's operation. However, if this portion is not recorded, This is because continuous imaging data cannot be obtained.

  Next, when the user presses the stop key at timing 136, the recording operation of the master device 10 ends (the line D transitions from the recording state to the stop state). The master device 10 has already finished exchanging its recording media and the remaining amount of recording media has reached a sufficient value. At that time (timing 142), the master device 10 issues a REC-PAUSE command to the slave device 20. Send. Therefore, the recording of the imaging data in the slave device 20 is stopped (the line E transitions from the recording state to the standby state). Here, it is assumed that “REC-PAUSE” is designated on the standby command designation screen 71 shown in FIG.

  In this way, the imaging data obtained by the master device 10 is recorded by the recording medium of the slave device 20 when the remaining amount of the recording medium of the master device 10 is low, and as a result, there is no leaking recording. Is realized. Recording on the slave device 20 is started, for example, when the remaining time of the recording medium of the master device 10 reaches a predetermined time, and the predetermined time is designated by the user.

  Further, the mode of the relay operation mode of the master device 10 and the slave device 20 shown in FIG. 3 is merely an example, and other modes related to the known relay operation mode are also included in the scope of the present invention.

  Next, an example of operations of the master device 10 and the slave device 20 when the external operation mode is designated will be described with reference to FIG. The column 150, the column 160, and the column 170 in FIG. 4 correspond to the column 100, the column 110, and the column 120 in FIG. 3, respectively. In the column 160, a line F representing the operation state of the master device 10 is shown, and in the column 170, the line G representing the operation state of the slave device 20 is associated with the operation of the master device 10. Shown in the series.

  Here, the start / stop key (not shown) of the image pickup apparatus (master device 10) according to the present invention is substantially composed of, for example, one button, and starts when pressed once (recording start in the slave device 20). Then, when it is pressed again, it becomes a stop (recording stop in the slave device 20). However, when the recording is automatically stopped due to the end of the recording medium of the slave device 20 or the like, the subsequent pressing of the button (after the recording medium becomes usable) starts. Hereinafter, pressing the start button is expressed as a start key press, and pressing the stop button is expressed as a stop key press.

  When the user first presses the start key of the master device 10 at timing 180, the master device 10 transmits a REC command to the slave device 20 at this time (timing 190), and the imaging data obtained by the master device 10 is transmitted. Recording is started in the slave device 20. This is indicated by the transition of the line G from the stop state to the recording state.

  When the user presses the stop key at timing 181, at this time (timing 191), the master device 10 transmits a REC-PAUSE command to the slave device 20, and the recording operation of the slave device 20 ends. This is indicated by the transition of the line G from the recording state to the stop state.

  When the user presses the start key again at timing 182, a REC command is transmitted from the master device 10 to the slave device 20, and recording starts at the slave device 20 as in the case of timing 180 (in line G, the stop state To the recording state).

  Thereafter, it is assumed that the remaining amount of the recording medium of the slave device 20 reaches the designated time at the timing indicated by the line A. Then, the master device 10 starts recording the imaging data on its own recording medium at that time (the line F transitions from the stop state to the recording state). At this time, the imaging data acquired by the master device 10 is recorded on the recording medium of the master device 10 and also on the slave device 20. Here, the time designated for the remaining amount of the recording medium is the time designated by the user, like the designated time described in FIG. 3, like the relay start time designation screen 81 in FIG. Can be specified on the screen.

  Next, when the user presses the stop key at the timing 183, the recording operation of the master device 10 and the slave device 20 ends (line F and line G transition from the recording state to the stop state, respectively).

  Thereafter, when the user again presses the start key at timing 184, recording is started in the master device 10 (the line F transitions from the stopped state to the recorded state). The master device 10 transmits a REC command to the slave device 20 at that time (timing 194). The slave device 20 starts recording in response to this command (the line G transitions from the stopped state to the recording state).

  As described above, in a situation where imaging data is recorded in both the master device 10 and the slave device 20, it is assumed that the recording medium of the slave device 20 ends at the timing represented by the line B, that is, the remaining portion becomes zero. . Then, as indicated by the line G, the operation state in the slave device 20 changes from the recording state to the stop state. However, even at this time, the recording of the imaging data by the master device 10 continues.

  Thereafter, when the user presses the stop key at timing 185, the recording operation of the master device 10 ends (the line F transitions from the recording state to the stop state). At the same time, the master device 10 transmits a REC-PAUSE command to the slave device 20 at this time (timing 195). The state does not change.

  Next, when the user presses the start key at timing 186, the recording operation of the master device starts again (the line F transitions from the stopped state to the recording state), and at the same time, the master device 10 At timing 196), the REC command is transmitted to the slave device 20. As described above, the slave device 20 does not change its state because the recording medium is finished.

  Thereafter, it is assumed that the replacement of the recording medium of the slave device 20 is completed and the recording medium becomes usable at the timing indicated by the line C. After that, when the user presses the start key at timing 187, recording of the imaging data is started in the slave device 20 (the line G transitions from the stopped state to the recording state). On the other hand, the master device 10 continues the recording operation from the timing indicated by the line C to the timing 187.

  Next, when the user presses the stop key at timing 188, the recording operation of the master device 10 ends (the line F transitions from the recording state to the stop state). Then, the master device 10 transmits a REC-PAUSE command to the slave device 20 at that time (timing 198). Therefore, the recording of the imaging data in the slave device 20 is stopped (the line G transits from the recording state to the standby state). Here, it is assumed that “REC-PAUSE” is designated on the standby command designation screen 71 shown in FIG.

  When the user presses the start key at timing 189, at this time (timing 199), the master device 10 transmits a REC command to the slave device 20, and the recording of the imaging data obtained by the master device 10 is recorded in the slave device 20. Started (line G transitions from a stopped state to a recorded state).

  In this way, in the external operation mode, the imaging data obtained by the master device 10 is basically recorded by the slave device 20, and when the remaining amount of recording media of the slave device 20 is low, the master device 10 Are recorded by other recording media. Recording on the master device 10 is started, for example, when the remaining time of the recording medium of the slave device 20 reaches a predetermined time, and the predetermined time is designated by the user.

  Further, the external operation mode of the master device 10 and the slave device 20 shown in FIG. 4 is merely an example, and other aspects related to a known external operation mode are also included in the scope of the present invention.

  Next, the configuration of the imaging device (master device 10) according to the present invention will be described with reference to FIG. The master device 10 includes a start / stop key 200, a display unit 210, a user I / F control unit 220, a memory 230, and a peripheral control unit 240. Among these, at least the user I / F control unit 220 and the peripheral control unit 240 are included. Can be controlled by one or a separate microcomputer.

  As described with reference to FIGS. 3 and 4, the start / stop key 200 is substantially one button, and when pressed, starts or stops the recording operation of the master device 10 or the slave device 20. Let In this example, it is assumed that the button is configured as one button, but the start key and the stop key may be physically separated to be configured as two or three buttons.

  The display unit 210 displays the received information regarding the slave device 20 or the like on a display panel (not shown) configured by the LCD or the like of the master device 10. Further, the display unit 210 can also display using the OSD, thereby displaying the information related to the slave device 20 and the like described above while displaying the captured image on the display panel. be able to. An example of the display mode will be described later with reference to FIG.

  The user I / F control unit 220 inputs the operation information of the start / stop key 200 and the setting information by the user, and records the imaging data on the main body, that is, the recording medium of the master device 10 according to the information, or the slave device 20. In addition, it is determined whether or not to record on the other recording medium, and predetermined information regarding the slave device 20 is output to the display unit 210.

  The memory 230 records setting information set by the user on each screen shown in FIG. The memory 230 is composed of a memory such as an EEPROM (Electronically Erasable and Programmable Read Only Memory).

  The peripheral control unit 240 controls access to the recording medium of the master device 10 and the recording medium of the slave device 20 connected to the master device 10 by IEEE 1394 and exchange of commands. The peripheral control unit 240 further includes a recording media control unit 240A and an IEEE 1394 control unit 240B.

  While the recording media control unit 240A acquires the remaining amount of the recording media of the master device 10 via the recording media mode control 220E of the user I / F control unit 220 and provides it to the user I / F control unit 220, The imaging data is received from the user I / F control unit 220 and is controlled to be recorded on a recording medium. Further, the IEEE 1394 control unit 240B acquires the operating state of the slave device 20, the remaining amount of recording media of the slave device 20, and the like and provides it to the user I / F control unit 220. On the other hand, the IEEE 1394 control unit 240B Control to start or stop recording. Such control of the slave device 20 is performed by an AV / C command, but the IEEE 1394 control unit 240B performs issuance of the AV / C command and issuance timing control.

  Next, the operation of the user I / F control unit 220 will be described in more detail. When the start / stop key 200 is pressed, the user I / F control unit 220 receives a signal from the start / stop key 200 and A / D converts it (220A). The value thus digitized is subjected to the key input detection (220B) to determine which button has been pressed.

  Next, the key input determined in this manner is converted into a predetermined control command (220C), and the control command is provided to the external REC control 220D. Furthermore, setting information 220G set by the user is provided from the memory 230 to the external REC control 220D.

  The external REC control 220D further acquires the remaining amount of the recording medium of the master device 10 from the recording media control unit 240A as necessary, and the operation status of the slave device 20 from the IEEE 1394 control unit 240B, and the slave device 20 The remaining amount of the recording medium is acquired, and using these pieces of information, it is determined at which timing recording data is to be recorded on which recording medium.

  The external REC control 220D generates an AV / C command (AV / C packet) (220F) when acquiring the operation state of the slave device 20 or recording on the recording medium of the slave device 20. It is transmitted to the slave device 20 via the IEEE 1394 control unit 240B.

  FIG. 6 shows an example of the AV / C packet 250 transmitted from the master device 10 to the slave device 20. The AV / C packet 250 is shown for each of the REC command, the REC-PAUSE command, and the STOP command. The type of the command is determined by “opcode” and “operand [0]” in the packet.

  Next, an outline of the control flow of the external REC control in the relay operation mode will be described with reference to FIG. The control flow can be repeatedly activated at a timing such as once per field of the captured image or once per second.

  First, in step S10, the remaining amount (remaining time) of the recording medium of the master device 10 is acquired. For example, when the tape is loaded, the total recording time of the tape is grasped, and each time imaging data is recorded on the tape, the recording time is subtracted from the total recording time. Is stored in a memory or the like.

  Next, in step S12, it is determined whether or not the remaining amount of the recording medium acquired in step S10 exceeds the set time. Here, the set time is a time specified by the user on the relay start time specifying screen 81 in FIG. 2, and this setting information is recorded in the memory of the master device 10. When the remaining amount of the recording medium is smaller than the set time, that is, when the remaining recording medium is little, the process proceeds to step S14, where the operation state of the master device 10 is checked.

  If it is determined in step S14 that the master device 10 transitions to the recording state or the recording state (YES), a recording start command is transmitted to the slave device 20 in step S16, and the slave device 20 starts recording of imaging data. . However, in the case where the slave device 20 has already recorded the imaging data as in the timing 134 of FIG. 3, the state of the slave device 20 is not changed. If it is determined NO in step S14, the process ends without transmitting a command or the like.

  If the remaining amount of the recording medium is equal to or longer than the set time in step S12, that is, if the recording medium has a sufficient recording capacity, the process proceeds to step S18, where the operation state of the master device 10 is checked. The

  If it is determined in step S18 that the master device 10 transitions to the stop state or the standby state (YES), if the slave device 20 is in the recording state in step S20, a recording stop command is transmitted to the slave device 20. Stop recording the imaging data. If it is determined NO in step S18, the process ends without transmitting a command or the like.

  Next, an outline of the control flow of the external REC control in the external operation mode will be described with reference to FIG. Here, for example, it is determined whether or not the start / stop key is pressed at a timing such as once per field of the captured image or once per second, and the control flow is activated when the key is pressed.

  First, in step S30, the remaining amount (remaining time) of the recording medium of the slave device 20 is acquired. This process will be described in detail with reference to FIG.

  Next, in step S32, it is determined whether or not the remaining amount of the recording medium acquired in step S30 exceeds the set time. Here, the set time is a time specified by the user on a setting screen similar to the relay start time specifying screen 81 in FIG. 2, and this setting information is recorded in the memory of the master device 10. When the remaining amount of the recording medium is smaller than the set time, that is, when the remaining recording medium is little, the process proceeds to step S34.

  In step S34, control is performed to record the imaging data on the recording medium of the master device 10 instead of the slave device 20 (in some cases in parallel). For example, control is performed so that recording on the recording medium of the master device 10 is forcibly started when the remaining amount of the recording medium of the slave device 20 becomes smaller than a set time, and thereafter, the recording medium of the slave device 20 is replaced. Thus, until the remaining amount becomes equal to or longer than the set time, the imaging data is recorded on the recording medium of the master device 10 in response to pressing of the start / stop key of the master device 10.

  In addition, when the recording on the recording medium of the master device 10 is continued and the remaining amount of the recording medium of the slave device 20 becomes equal to or longer than the set time (due to replacement of the recording medium), the stop is performed. When the key is pressed, the recording on the recording medium of the master device 10 is stopped.

  In step S32, if the remaining amount of the recording medium acquired in step S30 is equal to or longer than the set time, it indicates that the recording medium capacity of the slave device 20 is still sufficient. In this case, the process proceeds to step S36. . In step S36, the operation state of the slave device 20 is acquired. In step S38, it is determined whether or not the operation state is a recording state.

  When it is determined in step S38 that the operation state of the slave device 20 is the recording state (YES), the process proceeds to step S40, and the master device 10 transmits a recording stop command or a recording standby command to the slave device 20. . When it is determined NO in step S38, the process proceeds to step S42, where the master device 10 transmits a recording start command to the slave device 20.

  Next, a processing flow in which the master device 10 acquires the remaining amount (remaining time) of the recording medium of the slave device 20 will be described with reference to FIG.

  In step S50, it is checked whether or not a predetermined time has elapsed. If it has elapsed, the process proceeds to step S52, and the remaining amount of the recording medium is inquired to the slave device 20 using a prescribed command. Next, in step S54, the response (transmission data) of the slave device 20 to the inquiry in step S52 is received.

  Thereafter, in step S56, it is determined whether or not a response from the slave device 20 has been received, that is, whether or not there has been a response to the inquiry command in step S52. Update the remaining amount information. This takes into account the case where the response from the slave device 20 to the inquiry command is delayed.

  The process shown in FIG. 9 is used here to acquire the remaining recording medium capacity of the slave device 20 in the external operation mode shown in FIG. It can also be used for a function of displaying (recordable time), remaining battery capacity (operable time), and the like.

  In this case, for example, the inquiry command is transmitted from the master device 10 at an order interval of several milliseconds to several seconds, and the slave device 20 that receives the inquiry command adds the usage time or remaining time of the recording medium as a response to the command. Reply to the master device 10. Such a response may be a physical quantity parameter instead of a time value. Further, as described above, the usage time and remaining time of the battery may be received as a response instead of the recording medium.

  The master device 10 can display the recording medium remaining amount and the remaining battery amount of the slave device 20 on the display panel of the master device 10 by, for example, OSD. Further, such information regarding the recording medium may be automatically displayed when a condition designated by the user or a condition (value) fixedly set is satisfied, or may be displayed at a predetermined time or time interval. May be.

  As described above, the information related to the recording medium is displayed on the display panel of the master device 10 in relatively detail, but only a message indicating that the user's condition is satisfied is displayed on the display panel. May be.

  When the remaining amount of recording media or the remaining battery of the slave device 20 becomes smaller than the remaining amount specified by the user, an LED (Liquid Crystal Display) is used as a display means, and this is indicated by lighting or blinking of the LED. You may make it represent.

  FIG. 10 shows an example in which information relating to the remaining amount of recording medium and battery remaining in the slave device 20 and information relating to the operation state of the slave device are displayed on the display panel of the master device 10 by the OSD. . On the display panel 300, a captured image 302 such as a house or a tree is displayed, and the slave device information 301 is also displayed in an overlapping manner.

  The slave device information 301 indicates that the remaining amount of the recording medium is 3 minutes, the remaining amount of the battery is 100 minutes, and the current operation state of the slave device 20 is standby, that is, a standby state. .

It is a basic diagram showing the outline | summary of the imaging system containing the imaging device which concerns on one Embodiment of this invention. It is an approximate line figure showing screen transition of a user setting screen in an imaging device concerning one embodiment of this invention. It is an approximate line figure showing operation of a master device and operation of a slave device in relay operation mode of an imaging device concerning one embodiment of this invention in time series. It is a basic diagram which showed operation of a master device and operation of a slave device in an external operation mode of an imaging device concerning one embodiment of this invention in time series. 1 is a block diagram illustrating a configuration of an imaging apparatus according to an embodiment of the present invention. FIG. 6 is a schematic diagram illustrating an example of an AV / C command transmitted from a master device to a slave device in the imaging apparatus according to the embodiment of the present invention. 6 is a flowchart showing processing of external REC control in a relay operation mode of the imaging apparatus according to the embodiment of the present invention. 6 is a flowchart showing processing of external REC control in an external operation mode of the imaging apparatus according to the embodiment of the present invention. 6 is a flowchart illustrating processing when an inquiry command is transmitted to a slave device in the imaging apparatus according to the embodiment of the present invention. It is a basic diagram which shows the example which displayed slave apparatus information on the display panel of the imaging device which concerns on one Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Master apparatus, 20 ... Slave apparatus, 21 ... Video camera, 22 ... Hard disk drive, 23 ... Personal computer, 24 ... DVD recorder, 30 ... Network, 200 ..Start / stop key, 210 ... display unit, 220 ... user I / F control unit, 230 ... memory, 240 ... peripheral control unit

Claims (11)

First recording means for recording imaging data obtained by a shooting operation;
Recording control means for controlling the imaging data to be recorded in the second recording means when the remaining recording time of the first recording means is shorter than a predetermined time;
The imaging apparatus, wherein the predetermined time is designated by a user. The imaging device according to claim 1,
The first recording means is constituted by a recording medium built in or loaded in the imaging device,
The image pickup apparatus, wherein the second recording unit is an external recording apparatus connected via a network. The imaging device according to claim 1,
It further has a display means for displaying predetermined information,
The imaging apparatus is characterized in that the predetermined time is specified by being selected by a user from a plurality of candidates displayed on the display means. In an imaging device that accesses a slave device including a first recording unit via a network and operates as a master device,
An image pickup apparatus comprising: slave information acquisition means for acquiring a remaining recording time of the first recording means by transmitting a predetermined command to the slave device. The imaging apparatus according to claim 4,
A second recording means;
The remaining recording of the first recording means obtained from the slave information acquisition means when operating in the mode for recording the imaging data obtained by the photographing operation to the first recording means of the slave device An imaging apparatus, further comprising: a recording control unit that controls to record the imaging data in the second recording unit when the time becomes shorter than a predetermined time. The imaging apparatus according to claim 5,
The imaging apparatus, wherein the predetermined time is designated by a user. The imaging apparatus according to claim 4,
A second recording means;
Display means for displaying predetermined information;
The remaining recording of the first recording means obtained from the slave information acquisition means when operating in the mode for recording the imaging data obtained by the photographing operation to the first recording means of the slave device An image pickup apparatus, further comprising: a display control unit that controls to display the fact on the display unit when the time is shorter than a predetermined time. The imaging apparatus according to claim 7,
The imaging apparatus, wherein the predetermined time is designated by a user. The imaging apparatus according to claim 4,
Display means for displaying predetermined information;
An image pickup apparatus further comprising display control means for controlling to display the remaining recording time of the first recording means obtained from the slave information acquisition means on the display means. A recording step of recording the imaging data obtained by the imaging operation in the first recording means;
A recording control step for controlling the imaging data to be recorded in the second recording means when the remaining recording time of the first recording means is shorter than a predetermined time;
The imaging data recording method, wherein the predetermined time is designated by a user. A method for accessing a slave device including a first recording unit via a network and recording imaging data with an imaging device that operates as a master device,
Transmitting a predetermined command to the slave device;
A slave information acquisition method comprising: a slave information acquisition step of acquiring a remaining recording time of the first recording means by receiving a response to the predetermined command from the slave device.