JP2015029188A - Electronic apparatus and control method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To save power consumption so that timing of the next shooting in interval shooting is not delayed.SOLUTION: An electronic apparatus having imaging means comprises: recording control means that performs interval recording in which an image captured by the imaging means is recorded at an interval based on a predetermined set interval; and control means that after recording based on the interval recording, when a time to the next recording is equal to or shorter than a predetermined time, controls the electronic apparatus to operate without transition to a power saving state, and when the time to the next recording is longer than the predetermined time, controls the electronic apparatus to transition to the power saving state and operate.

Description

  The present invention relates to an electronic apparatus capable of interval recording in which photographing is repeatedly performed at regular time intervals and a control method thereof.

  As a video camera shooting method, there are a shooting method in which a user performs a shooting operation such as recording start and stop by hand, an interval recording method in which recording of a predetermined unit time is repeated at regular time intervals, and the like. Japanese Patent Application Laid-Open No. 2004-151858 proposes that, in interval shooting, shooting is performed only when the optical axis of the shooting lens is within the range of the shooting permission inclination and the shooting permission method set by the user.

JP 2011-197467 A

  Interval shooting interval (interval) may also consume power, hinder driving for long periods of time and not being able to perform long interval shootings if the camera is turned on and in normal operation. There is. Therefore, when the interval photographing interval is long, it is desirable to save power consumption by setting the operation mode to the power saving mode. On the other hand, if the transition to the power saving mode is made when the time until the next shooting is short, the return processing from the power saving mode may not be in time for the next shooting timing, and the shooting timing may be shifted (delayed). There is.

  In view of the above problems, an object of the present invention is to provide an electronic device that can save power consumption so that the timing of the next shooting in the interval shooting is not delayed.

The electronic device of the present invention is
An electronic device having imaging means,
Recording control means for performing interval recording for recording images picked up by the image pickup means at intervals based on a predetermined set interval;
If the time until the next recording is less than or equal to a predetermined time after the recording by the interval recording, the electronic device is operated without changing to the power saving state, and the time until the next recording is longer than the predetermined time. In this case, the electronic device includes control means for controlling the electronic device to operate by making a transition to the power saving state.

  According to the present invention, power consumption can be saved so that the timing of the next shooting in the interval shooting is not delayed.

1 is a block diagram illustrating a configuration example of an imaging device according to an embodiment. FIG. 3 is a diagram illustrating an example of an appearance of an imaging apparatus according to an embodiment. FIG. 4 is a diagram illustrating an appearance and a display example of the imaging apparatus according to the embodiment. FIG. 10 is a diagram showing a display example by the imaging device. The flowchart which shows an interval recording mode process. The flowchart which shows a moving image interval recording process. The flowchart which shows the process by sub CPU. The flowchart which shows the file integration process by 2nd Embodiment. The figure explaining the rotation process at the time of interval recording.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<First Embodiment>
FIG. 1 is a block diagram illustrating a configuration example of an imaging apparatus according to the first embodiment. In the present embodiment, a digital video camera (hereinafter simply referred to as a camera) including a camera unit 101 as an imaging unit will be described as an example of an imaging device.

  The camera has a main CPU 107 and a sub CPU 114 as arithmetic units that control the operation of the entire camera. The main CPU 107 reads a program from the program / data storage unit 106 and executes various processes. The sub CPU 114 reads the program from the program / data storage unit 116 and executes various processes. Both the main CPU 107 and the sub CPU 114 control the entire camera according to the program read by each. The read program has a function for causing the main CPU 107 and the sub CPU 114 to execute a plurality of tasks in parallel. Specifically, a camera control task, a recorder control task, and a display control task operate under the control of the main CPU 107, and a mode control task and a power control task operate under the control of the sub CPU 114. The main CPU 107 and the sub CPU 114 exchange data by serial communication via the serial I / F 118 and the serial I / F 119.

  The camera unit 101 includes a mechanism for inputting an analog video signal obtained by imaging to a moving image recording apparatus. More specifically, the camera unit 101 includes a lens for imaging light from a subject, an image sensor that photoelectrically converts a subject image formed by the lens, a circuit that drives the image sensor, and the like. The video processing unit 102 converts the analog video signal input from the camera unit 101 into digital moving image data, and performs correction based on predetermined image processing such as noise removal. The operations of the camera unit 101 and the video processing unit 102 are controlled by a camera control task executed by the main CPU 107. The camera control task functions as a recording control unit that performs interval recording that records images captured by the camera unit 101 at intervals based on a predetermined set interval. In addition, the video processing unit 102 uses, for example, an image captured by the camera unit 101 under the control of the main CPU 107, using an attitude of the imaging device (camera body) detected by the body orientation detection unit 110 described below. A specific process such as rotation is performed.

  The encoder / decoder unit 104 encodes the moving image data from the video processing unit 102. The moving image data encoded by the encoder / decoder unit 104 is temporarily stored in, for example, a temporary storage unit 103 configured by a RAM, and then stored in the moving image storage unit 105 together with accompanying management data. At the time of reproducing a moving image, the encoded moving image data (image data) read from the moving image storage unit 105 is provided to the encoder / decoder unit 104 via the temporary storage unit 103 and decoded. The decoded moving image data is then developed in a moving image frame buffer (not shown) in the temporary storage unit 103. Storage control of the encoder / decoder unit 104 and the moving image storage unit 105 is controlled by a recorder control task executed by the main CPU 107.

  In the recorder control task, an interval recording operation for automatically recording a moving image, for example, at regular intervals is controlled at an interval based on the set interval. The recording time of interval recording is set to several frames in the video signal system, and the repetition time can be set by the user in units of minutes / hours. In the interval recording, an image captured by the camera unit 101 is recorded at an interval based on a predetermined setting interval. A plurality of moving image scenes recorded by interval recording can be combined as one moving image scene by the encoder / decoder unit 104.

  The management data read from the moving image storage unit 105 is used to generate OSD (On Screen Display) data, that is, data for character display superimposed on a captured image / reproduced image and data for GUI (Graphical User Interface). . The generated OSD data is drawn in an OSD frame buffer (not shown) in the temporary storage unit 103. The contents of the moving image frame buffer and the OSD frame buffer are superimposed on the display control unit 111 and displayed on the LCD panel 112. The operation keys 108 and the touch panel 109 are both operation units for receiving operation instructions from the user.

  The body orientation detection unit 110 is a posture detection unit that detects the orientation (posture) of the camera body. The main body direction detection unit 110 includes an acceleration sensor or a gyro sensor that can detect the direction of gravity. It is possible to detect whether the user is used upside down (inverted posture: described later with reference to FIG. 2C) or in a normal orientation (normal posture: described later with reference to FIG. 2B).

  The nonvolatile memory 113 is a memory for storing data. The nonvolatile memory may be SRAM, EEPROM, or FLASH-ROM. The power management unit 115 manages the power of the entire video camera. The power management unit 115 controls the power according to the change in the internal state managed by the mode control task executed by the sub CPU 114. For example, the power management unit 115 supplies power to the main CPU 107 if the imaging device is in an activated state, and shuts off the power to the main CPU 107 if the imaging device is in a power-off state or a power saving mode.

  FIG. 2 shows an example of an external view of a digital video camera. FIG. 2A is a front perspective view of the camera when the LCD panel 112 having the touch panel 109 is in a facing position and the camera is in a normal posture. FIG. 2B is a rear perspective view of the camera when the LCD panel 112 having the touch panel 109 faces the back and the camera is in a normal posture. The LCD panel 112 of FIG. 2B is in a state of being rotated about 180 degrees around the axis 210 from the facing position of FIG. FIG. 2C is a rear perspective view of the camera when the LCD panel 112 having the touch panel 109 faces the back and the camera is turned upside down (upside down) from the normal posture.

  The display unit including the LCD panel 112 is connected to the main body unit 201 having the camera unit 101 via a hinge unit (not shown) so as to be rotatable about a shaft 211 as a rotation axis. The display unit can rotate about 90 degrees about the axis 211 as a rotation axis, and is closed with respect to the main body (a position where the back side of the LCD panel 112 faces the main body 201) and an open position (FIG. 2 ( b) and the position of FIG. 2 (c). The display unit is also attached to the shaft 210 so as to be rotatable about 180 degrees. By rotating around this axis 210, the facing position where the display surface of the LCD panel 112 faces in the same direction (subject side) as the lens portion of the camera unit 101, and the display surface of the LCD panel 112 faces away from the subject side. It can be moved to the back position (FIGS. 2A and 2B).

  An origin 205 in FIGS. 2A to 2C indicates the same position of the LCD panel 112. As shown in FIG. 2B, the origin 205 located at the upper left in the normal posture with the display unit facing the back is the lower right when the display unit is facing the same normal posture (FIG. 2A). ). That is, in the state of FIG. 2B and FIG. 2A, it can be seen that the LCD panel 112 is upside down (180 degrees rotated) when viewed from the user. Also, as shown in FIG. 2B, the origin 205 located at the upper left in the normal posture with the display unit facing back is the lower right when the main body 201 is turned upside down at the same facing position (FIG. 2). (C)). 2B and 2C, it can be seen that the LCD panel 112 is upside down (180 degrees rotated) when viewed from the user.

  As shown in FIG. 2B, a shutter button 202 is attached to the main body 201 as a part of the operation key 108. The user can record a still image at an arbitrary timing by pressing the shutter button 202. Further, as shown in FIG. 2C, a lens cover slide switch 203 is attached to the main body 201 as a part of the operation key 108. The user can open and close the lens cover of the camera unit 101 by moving the lens cover slide switch 203.

The touch panel 109 and the LCD panel 112 can be configured integrally. For example, the light transmittance of the touch panel 109 is configured so as not to disturb the display of the LCD panel 112 and is attached to the upper layer of the display surface of the LCD panel 112. Then, the input coordinates on the touch panel 109 are associated with the display coordinates on the LCD panel 112. Thereby, a GUI (graphical user interface) can be configured as if the user can directly operate the screen displayed on the LCD panel 112. The sub CPU 114 can detect the following operation or state on the touch panel 109.
The touch panel 109 is touched with a finger or a pen (hereinafter referred to as touch-down).
The touch panel 109 is being touched with a finger or a pen (hereinafter referred to as touch-on).
The touch panel 109 is moved while being touched with a finger or a pen (hereinafter referred to as touch-move).
-A finger or pen that has been touching the touch panel 109 is released (hereinafter referred to as touch-up).
A state where nothing is touched on the touch panel 109 (hereinafter referred to as touch-off).

  These operations / states and the position coordinates of the finger or pen touching the touch panel 109 are notified from the sub CPU 114 to the main CPU 107 through the internal bus. The main CPU 107 determines what operation has been performed on the touch panel 109 based on the notified information. In the touch move, the moving direction of a finger or a pen moving on the touch panel 109 is detected as a movement amount for each vertical component / horizontal component on the touch panel 109 based on a change in position coordinates. In addition, it is assumed that a stroke is drawn when touch-up is performed on the touch panel 109 through a certain touch move from touch-down.

  The operation of drawing a stroke quickly is called a flick. The flick is an operation of quickly moving a certain distance while touching the finger on the touch panel 109 and releasing it, in other words, an operation of quickly tracing the touch panel 109 with a finger. When it is detected that a touch move is performed at a predetermined speed or more over a predetermined distance and a touch-up is detected as it is, it can be determined that a flick has been performed. In addition, when it is detected that a touch move is performed at a predetermined distance or more and less than a predetermined speed, it is determined that a drag has been performed. The touch panel 109 may be any of various types of touch panels such as a resistive film type, a capacitance type, a surface acoustic wave type, an infrared type, an electromagnetic induction type, an image recognition type, and an optical sensor type. good.

  The mode control task executed by the sub CPU 114 changes the operation state of the entire video camera in accordance with an instruction from the operation unit (operation key 108, touch panel 109) and a change in internal state managed by the mode control task itself. Therefore, the sub CPU 114 notifies the event to each task executed by the main CPU 107 via the serial I / Fs 118 and 119.

  FIG. 3 is a diagram illustrating an example of a screen displayed on the LCD panel 112 with respect to a specific orientation of the main body unit 201 in the shooting state. FIG. 3A shows an example of a screen displayed on the LCD panel 112 in the normal photographing mode when the main body unit 201 is in the normal posture and the display unit is in the back position. On the LCD panel 112, an image 301 captured by the camera unit 101 is displayed on the full screen, and a subject image 302 is displayed as an example of an image captured of the subject 310. In the upper left part of the screen, a menu button 303 which is a touch button indicating that an operation by touch is possible is displayed in OSD.

  FIG. 3B is an example of a screen displayed on the LCD panel 112 in the normal photographing mode when the automatic rotation function is in the off state and the main body unit 201 is in the inverted posture. The automatic rotation function refers to a user-desired image (with the normal operability maintained even when upside down by rotating the GUI direction and the recorded video direction according to the orientation of the main body. This is a function that realizes recording an image as seen on the panel. When the automatic rotation function is on and the orientation of the main body is upside down (upside down) with respect to gravity, the photographed image is rotated 180 degrees (equivalent to upside down, left and right inversion) and recorded as an image file. Thus, when the main body is played back in a normal posture or when played back by an external device such as a television, the direction of the subject in the image can be viewed as the correct direction with respect to the direction of gravity. This automatic rotation function can be switched on or off on the menu screen.

  In this automatic rotation function, the main body orientation detection unit 110 detects whether the main body is upside down (upside down posture) or not upside down (normal posture), and performs video processing control according to each state. It is realized by doing. Video processing according to each state will be described later. On the LCD panel 112 in FIG. 3B, an image 301 captured by the camera unit 101 is displayed in full screen, and a subject image 302 is displayed as an example of an image captured of the subject 310. In the lower right part of the screen, a menu button 303 which is a touch button indicating that an operation by touch is possible is displayed upside down on the OSD (that is, an orientation in which the top of the gravity direction is below the menu button 303). . Here, the menu button 303 is displayed upside down because the automatic rotation function is off and the main body 201 is in an upside down posture.

  FIG. 3C is an example of a screen displayed on the LCD panel 112 in the normal photographing mode when the automatic rotation function is in the on state and the main body 201 is turned upside down (in the upside down state). On the LCD panel 112 in FIG. 3C, an image 301 captured by the camera unit 101 is displayed on the full screen, and a subject image 302 is displayed as an example of an image captured of the subject 310. In the upper left part of the screen, a menu button 303 which is a touch button indicating that an operation by touch is possible is displayed in OSD. Unlike the menu button of FIG. 3B, since the automatic rotation function is on, the menu button 303 is in the correct orientation as viewed from the user (that is, the orientation in which the direction of gravity is above the menu button 303). Is displayed. Further, as described above, the captured image is recorded as an image file after being subjected to a process of rotating 180 degrees (equivalent to vertical and horizontal reversal).

  4A to 4C show various display examples related to interval recording of the imaging apparatus. A shooting standby screen 401 in FIG. 4A is a display example displayed on the LCD panel during shooting standby (before the start of interval recording) when the interval recording mode is set. A recording setting button 402 and a START button 403 are displayed as touch buttons superimposed on the camera-through image (live view image). When the START button 403 is touched, moving image interval recording is started. When the record setting button 402 is touched, the screen transits to the record setting screen 404.

  FIG. 4B shows a display example of the recording setting screen 404. On the recording setting screen 404, the recording interval of interval recording can be set. An option (touch button) for setting the recording interval of interval recording to 5 seconds, 10 seconds, 30 seconds, 1 minute, and 10 minutes is displayed. When any option is touched, the recording interval of the touched option is set. Is set. The set recording interval is recorded in the nonvolatile memory 113.

  FIG. 4C shows a display example of an interval recording end confirmation screen displayed when the user performs an end operation during interval recording. A button 431 indicating “No” and a button 432 indicating “Yes” are displayed as touch buttons. When the button 431 is touched, the interval recording operation is continued. When the button 432 is touched, the interval recording operation is terminated.

  Next, processing in the interval recording mode in the imaging apparatus will be described. FIG. 5 shows a flowchart of the interval recording mode process. This processing is realized by developing the program recorded in the program / data storage unit 106 using the temporary storage unit 103 as a work memory and executing it by the main CPU 107. When the digital video camera is activated and set to the interval recording mode included in the photographing mode, the processing of FIG. 5 is started.

  In step S501, the main CPU 107 issues a display instruction to the LCD panel 112, and displays a camera-through image and a Bitmap (record setting button 402, START button 403) for OSD. In step S <b> 502, the main CPU 107 detects the posture of the camera body (main body unit 201) based on the output from the main body direction detection unit 110. In step S503, the main CPU 107 determines whether or not the posture detected in step S502 is an inverted posture. If the posture is not the upside-down posture but the normal posture, the process proceeds to S504. If the posture is the upside-down posture, the process proceeds to S505.

  In step S504, the main CPU 107 performs processing in the normal posture. Specifically, information indicating that a normal posture has been detected is recorded in the temporary storage unit 103 as posture information. Then, an OSD such as a touch button is displayed without rotating. Further, the image captured by the camera unit 101 is also displayed as a through image in the same direction without being subjected to rotation processing. A display example at this time is shown in FIG.

  In step S505, the main CPU 107 performs processing in an inverted posture. Specifically, information indicating that the inverted posture is detected is recorded in the temporary storage unit 103 as the posture information. When the automatic rotation function is on, the OSD such as a touch button is rotated 180 degrees and displayed. The video processing unit 102 rotates the video captured by the camera unit 101 by 180 degrees for recording in the moving image storage unit 105. However, recording is not yet performed at this point. For the image to be displayed on the LCD panel 112 as a through image (live view image), the image rotated by 180 degrees is further rotated by 180 degrees and displayed on the LCD panel 112 as a through image. A display example at this time is shown in FIG. Note that the through image is equivalent to an image captured as a result without being rotated. Therefore, for the through image, the image captured by the camera unit 101 may be displayed as it is without being rotated.

  In step S <b> 506, the main CPU 107 determines whether the START button 403 has been touched based on information received from the sub CPU 114 via the serial I / Fs 118 and 119. If it is determined that the START button 403 is touched, the process proceeds to S507, and if not, the process proceeds to S509.

  In S507, the main CPU 107 starts a timer for recording a moving image interval. More specifically, the main CPU 107 records the time (Tstart) at the time when the START button 403 is touched in the temporary storage unit 103 or starts measuring the time from when the START button 403 is touched. Further, the main CPU 107 reads out the recording interval of the moving image interval recording recorded as the set value from the nonvolatile memory 113. The timing of each shooting (scheduled recording time for each recording) in moving image interval recording is determined by the recording interval × (number of shooting times−1) from the time when the START button 403 is touched. For example, if the recording interval is set to 30 seconds, each shooting timing is from the touch of the START button 403, the first time after 0 seconds, the second time after 30 seconds, the third time after 60 seconds, and the fourth time. After 90 seconds ... In step S508, the main CPU 107 performs a moving image interval recording process. Details of the moving image interval recording process will be described later with reference to FIG.

  In step S <b> 509, the main CPU 107 determines whether the shutter button 202 is pressed based on information received from the sub CPU 114 via the serial I / Fs 118 and 119. If it is determined that the button has been pressed, the process proceeds to S510, and if not, the process proceeds to S512. In S510, the main CPU 107 starts a still image interval shooting timer, as in S507. In step S511, the main CPU 107 performs still image interval recording processing.

  In step S <b> 512, the main CPU 107 determines whether or not the recording setting button 402 has been touched based on information received from the sub CPU 114 via the serial I / Fs 118 and 119. If it is determined that the recording setting button 402 has been touched, the process proceeds to S513. If it is determined that the record setting button 402 has not been touched, the process proceeds to S514. In S513, the main CPU 107 displays the recording setting screen described with reference to FIG. When a touch on any of the options displayed on this recording setting screen is received and any of the options is touched, the recording interval of the touched option is recorded in the nonvolatile memory 113 as a set value.

  In step S <b> 514, the main CPU 107 determines whether or not a non-operation state in which there is no operation on the touch panel 109 or other operation keys 108 has passed for 3 minutes or more. If it is determined that the non-operation state has passed for 3 minutes or more, the process proceeds to S517 (auto power off) in order to automatically turn off the power for the purpose of power saving. If it is determined that 3 minutes or more have not elapsed, the process proceeds to S515. The time for determining the no-operation state is 3 minutes, and is not limited to 3 minutes as long as it is a predetermined time.

  In step S515, the main CPU 107 determines whether or not an operation for turning off the power has been performed. In this embodiment, it is assumed that the operation for moving the lens cover slide switch 203 to close is an operation for turning off the power. Therefore, if there is an operation to close the lens cover slide switch 203, the process proceeds to S517, and if not, the process proceeds to S516.

  In step S516, the main CPU 107 determines whether there is an instruction to transition to a mode other than the interval recording mode. If it is determined that there is an instruction to transition to a mode other than the interval recording mode, the process ends without turning off the power. If it is determined that there is no transition instruction, the process proceeds to S502 and the process is repeated.

  In step S517, the main CPU 107 performs processing for turning off the power. Specifically, the main CPU 107 notifies the sub CPU 114 of a power OFF request via the serial I / Fs 118 and 119. When the sub CPU 114 is notified of the power OFF request, the sub CPU 114 executes a power OFF process. By this power-off process, the supply of power from the power management unit 115 to the main CPU 107 is stopped, and the moving image interval recording mode process ends. It is assumed that the sub CPU 114 stores a battery and is always activated regardless of whether the power source of the main CPU 107 is on or off as long as there is a remaining battery level. Further, it is assumed that the sub CPU 114 requires only a small amount of power compared to the power for driving the main CPU 107.

  FIG. 6 shows a flowchart of the moving image interval recording process. This process is a detail of the process of S508 described above in FIG. This processing is realized by developing the program recorded in the program / data storage unit 106 in the temporary storage unit 103 and executing it by the main CPU 107.

  In step S <b> 601, the main CPU 107 determines whether to return from power-off. If the process is not a return from power-off but touching the START button 403, the process proceeds to S602. If the process is a return from power-off, the process proceeds to S603. In step S <b> 602, the main CPU 107 sets shooting number information k indicating the number of shootings up to the present time to 0 and stores it in the temporary storage 103. The number-of-shoots information k is arranged on the temporary storage unit 103, but is sent to the sub CPU 114 via the serial I / F 118 and 119 and held when the main CPU 107 is turned off.

  The return from power OFF checked in S601 includes a return from a power saving mode described later. In step S <b> 603, the main CPU 107 acquires the interval recording parameters and return factor information saved in step S <b> 617 described later from the sub CPU 114 via the serial I / Fs 118 and 119, and records the acquired information in the temporary storage unit 103. . Note that the interval recording parameters to be returned in this process include posture information, shooting number information, recording start time, and the like. The return factor information is information indicating whether the power is turned on by an end operation of interval recording or whether the power is turned on in accordance with the expiration of the activation timer. In step S <b> 604, the main CPU 107 instructs the video processing unit 102 to rotate the video based on the attitude information received from the sub CPU 114, and rotates the video displayed on the LCD panel 112. This is the same as the processing of S503 to S505 described above. If the posture is normal, the recording image is rotated 360 degrees, or if the posture is upside down, the recording image is rotated 180 degrees. It should be noted that instead of rotating 180 degrees, a process of inverting the left and right and top and bottom of the image may be performed. The orientation of the resulting image is the same whether the 180 degree rotation or left / right up / down inversion processing is performed.

  In step S <b> 605, the main CPU 107 executes a posture information update prohibition process so that the output from the main body orientation detection unit 110 is not acquired. Or you may make it aim at power saving by stopping the direction detection in the main body direction detection part 110. FIG. In the subsequent processing, the posture information held in the temporary storage unit 103 is referred to. Thus, after the start of the interval recording, the posture at the time when the update is prohibited in S605 is used instead of the posture detected at that time. In this way, the image rotation processing is performed at the time of the second and subsequent image recording based on the posture used at the time of the first image recording. The posture information referred to here is the posture information detected immediately before starting the video interval recording or the posture information transmitted from the sub CPU 114. Both are information indicating the posture detected immediately before the start of moving image interval recording (that is, immediately before the START button 403 is touched).

  As described above, during moving image interval recording, processing is performed based only on the posture at the start of moving image interval recording (in other words, the posture at the time of the first shooting), and even if the posture changes during the recording, it is reflected in the detected posture. do not do. In this way, consistency can be maintained with respect to the orientation of a series of images recorded by interval recording. For example, even if the images recorded in the interval recording are combined later, there is a mismatch between the images such that the orientation of the image suddenly changes in the middle of the combined video. Can be prevented. In addition, when the camera is tilted during interval recording or when the user's posture is changed by intentionally changing the posture, the orientation of the subject in the recorded video is changed from the orientation at the start time. As a result, the user viewing the recorded image knows that the camera posture has changed during the interval recording. On the other hand, if the user intentionally changes the posture of the camera during the interval recording, an image as intended by the user is recorded.

  In step S <b> 606, the main CPU 107 determines whether an operation for terminating interval recording has been performed based on information received from the sub CPU 114 via the serial I / Fs 118 and 119. If the return factor information received from the sub CPU 114 indicates an interval recording end operation if it is immediately after returning from the power supply OFF, it is determined that there is an interval recording end operation. The interval recording end operation is a press of a reproduction button included in the operation key 108 for giving an instruction to shift to the reproduction mode. Operations other than pressing the playback button are not regarded as interval recording end operations. During the interval recording, operations other than pressing the playback button and moving the lens cover slide switch 203 to close (operation to turn off the power) are not performed. It will be ignored. If it is determined that there has been an interval recording end operation, the process proceeds to S607; otherwise, the process proceeds to S611.

  In step S <b> 607, the main CPU 107 displays an interval recording end confirmation screen on the LCD panel 112 for confirming to the user whether or not the interval recording is actually ended. A display example at this time is shown in FIG. In step S <b> 608, the main CPU 107 determines whether there is a touch (interval recording continuation operation) on the button 431 corresponding to “No”. If the button 431 is touched, the process proceeds to S614, and if not, the process proceeds to S609. In step S <b> 609, the main CPU 107 determines whether or not there is a touch (interval recording end determination operation) on the button 432 corresponding to “Yes”. If the button 432 has been touched, the process proceeds to S610; otherwise, the process returns to S608.

  In step S610, the main CPU 107 executes a posture information update prohibition release process, and advances the process to step S509 in FIG. After the process proceeds to S509 by this release processing, the posture information is updated to the posture detected by the main body orientation detection unit 110 every time the posture of the camera changes, and processing according to the postures of S503 to S505 is performed.

  On the other hand, if the operation for ending the interval recording has not been performed, in S611, the main CPU 107 determines whether or not the next recording start time in the interval recording has come. As described above, the shooting start time of each time is determined by the time of the recording interval × (number of shooting times−1) from the touch operation on the START button 403. Accordingly, the next (k + 1) -th recording start time is obtained as recording interval × k. If the next shooting is the first shooting, the recording start time is 0 second. Therefore, if the shooting count information k is 0, it is determined Yes. In the second and subsequent shootings, when the recording interval set by the timer started from the start of the previous shooting has been reached, or when the elapsed time from touching the START button 403 has reached the recording start time of the next recording Is determined as Yes. If the recording start time is reached, the process proceeds to S612; otherwise, the process proceeds to S614.

  In S612, the main CPU 107 records a moving image of N frames corresponding to a predetermined time (for example, 0.5 seconds) as one recording of the interval recording. The recorded N-frame moving image is stored in the moving image storage unit 105 as one moving image file for one recording. Note that a plurality of moving image files recorded in a series of interval recordings (from the touch of the START button 403 to the interval recording end operation) are recorded in the same folder generated at the start of interval recording. . Therefore, it is possible to identify a moving image file group photographed by a series of interval recordings by being recorded in the same folder. At this time, if the fixed posture information (corresponding to the posture at the first recording) held in the temporary storage unit 103 indicates an inverted posture, the image captured by the camera unit 101 is rotated by 180 degrees. And recorded. In S613, the main CPU 107 increments the number-of-shoots information k by one.

  FIG. 9A illustrates an example of interval recording according to the first embodiment. Reference numerals 901 to 904 denote moving images acquired by the image sensor, and the moving image 901 and the moving image 904 are captured in an inverted posture. In FIG. 9A, the first recording is in an inverted posture, and the moving image 901 is recorded as a moving image file 911 after being rotated 180 degrees. In this example, since the first recording is in an inverted posture, the second and subsequent moving images are subjected to a 180 degree rotation process regardless of the posture of the imaging apparatus. For this reason, when the second recording is performed in a normal posture, a moving image 902 is obtained on the image sensor, is subjected to a 180-degree rotation process, and is recorded as a moving image file 912. The same applies to the third and fourth moving images, and the moving images 903 and 904 are 180 degree rotated and recorded as moving image files 913 and 914. In this way, a series of moving image files obtained by interval recording are in a state in which all the directions of the top and bottom coincide with each other, and the image orientation consistency is maintained.

  In step S <b> 614, the main CPU 107 accesses the temporary storage unit 103 and determines whether or not the number-of-shoots information k indicating the number of shots up to now is M or less. M is assumed to be an integer of 1 or more. If the number of shootings is less than or equal to M, the process proceeds to S615 in order to wait until the next recording start time while the power is on. If the number of shootings is greater than M, the process proceeds to S616 so as to proceed to a process for saving power in the power-off state. Thus, in this embodiment, the transition to the power saving state is not executed until the number of times of recording in interval recording exceeds a predetermined number.

  Here, the reason why the power saving process (the shift to the power saving state) is not executed until the number of photographing exceeds M times is as follows. That is, when the interval recording is started by touching the START button 403, if the power is turned off to save power immediately after the first recording, the user cannot determine whether the interval recording is normally performed. , You might be worried. In addition, there is a possibility that the user wants to see a through image in order to confirm whether or not shooting with the composition intended by the user is performed. Therefore, in the process of S614, the through image is displayed without saving power from the start of interval recording to the Mth time. By doing in this way, the user can confirm that it is in the state of interval recording at the beginning of interval recording, and the user's anxiety can be resolved. If you have confirmed that you have successfully taken several times over M times, stop the display because of the nature of interval recording, the user may leave the camera on a tripod or floor. There are few obstacles even in the power saving state.

  If you think that it is only necessary to confirm the display immediately after the first recording, setting M = 2 will result in a power saving state (power OFF state) after the second recording. Power consumption. Further, considering the time until the user leaves the camera, the value of M may be set to a different value according to the recording interval. For example, assuming that the user stops viewing the display on the LCD panel 112 after about 1 minute from the start of interval recording, M = 6 when the recording interval is 10 seconds, and M = 1 when the recording interval is 1 minute. If the interval is 10 minutes, M = 0 may be set.

  In S614, instead of the determination process using the number of times of recording M, it may be determined whether or not a predetermined time (for example, 1 minute) has elapsed since the start of interval recording by touching the START button 403. good. In this case, the process proceeds to S615 when the predetermined time has not elapsed, and proceeds to S616 when the predetermined time has elapsed. In this way, regardless of the recording interval setting, from the start of interval recording until the user no longer sees the display, such as leaving the camera side, some operation display such as a through image or the time until the next shooting is displayed. Can be confirmed by the user. Note that the process of S614 may be omitted, and the process may proceed to S616 uniformly, and the power saving state may be entered immediately after the first recording.

  In step S615, the main CPU 107 displays the time until the next shooting (recording) on the LCD panel 112. As a result, the user can know how many seconds later the recording is started and the recording starts. Instead of or together with the time until the next photographing, at least one of information such as a through image, the number of times of photographing (k) up to the present, and the elapsed time from the start of interval recording may be displayed. Note that nothing may be displayed by omitting the process of S615.

The main CPU 107 shifts the imaging device to the power saving state when the time until the next recording of the interval recording exceeds a predetermined time, and performs imaging when the time until the next recording is equal to or shorter than the predetermined time. Control the device not to enter the power saving state. More specifically, in S616, the main CPU 107 determines whether or not the time T until the next shooting is equal to or shorter than the predetermined time T1. The time T until the next photographing is obtained as follows.
T = {recording interval × (k + 1)} − (time elapsed from the timer started in S507)
If the recording interval of the interval recording is set to a value equal to or less than T1, it is always determined Yes in S616, and thus the power saving process in S617 is not performed. If the recording interval is set to a value larger than T1, the determination changes depending on the timing when it is determined in S608 that the interval recording continuation operation has been performed. If it is determined that the time T until the next shooting is equal to or shorter than the predetermined time T1, the process proceeds to S615, and if not, the process proceeds to S617.

  As described above, the reason why the power saving process is performed only when the time until the next shooting is longer than the predetermined time T1 is as follows. In the case of performing power saving control, a time until a power saving state is established after a power OFF request is transmitted to the sub CPU 114 and the power of the main CPU 107 is turned off, or a time until recovery from the power saving state and recording becomes possible occurs. . For this reason, if the power saving state control is performed when the time T until the next shooting is short, it may not be in time to return from the power saving state and become ready for recording by the timing when recording must be started. There is. It becomes impossible to record at the timing when recording should be started, and there is a possibility that the shooting will be performed at a timing shifted (delayed) from the recording interval set by the user. In order not to fall into such a situation, the power saving process is performed only when the time until the next shooting is longer than the predetermined time T1. As a result, it is possible to perform photographing that faithfully follows the setting of the recording interval designated by the user. On the other hand, if the time until the start of the next shooting is long, the power consumption of the battery can be suppressed by turning off the main CPU 107 immediately.

  The temporary storage unit 103 storing the parameters for interval recording cannot maintain the stored contents in the power saving state. Therefore, in S617, the main CPU 107 can maintain the storage of the parameters for interval recording held in the temporary storage unit 103 in the power saving state before shifting the imaging apparatus to the power saving state. Evacuate. In other words, the main CPU 107 transmits parameters such as the posture information, the number-of-shooting information, and the time Tstart when the START button 403 is touched to the sub CPU 114 via the serial I / Fs 118 and 119. The sub CPU 114 stores the received recording parameter in the temporary storage unit 117. Since the temporary storage unit 117 maintains power supply even in the power saving state, the temporary storage unit 117 can maintain parameters even in the power saving state. As a result, even when the power of the main CPU 107 is turned off and the contents of the temporary storage unit 103, which is a volatile memory, are cleared, the posture information, the number-of-shooting information, and Tstart can be reacquired at the next return. . In the present embodiment, posture information, shooting count information, and Tstart are transmitted to the sub CPU 114 and recorded in the temporary storage unit 117, but may be recorded in the nonvolatile memory 113 instead. In this case, at the time of return from the power saving state, the main CPU 107 acquires the posture information, the number of shooting times information, and Tstart from the nonvolatile memory 113 (S603). In the present embodiment, the recording interval of the interval recording is stored in the nonvolatile memory 113 from the viewpoint that the change does not occur so frequently. Therefore, although the recording interval is not included in the parameter to be saved at the time of shifting to the power saving state, it goes without saying that the recording interval may be stored in the temporary storage unit 103 and may be the target of the saving process.

  In step S618, the main CPU 107 requests the sub CPU 114 to turn off the power via the serial I / Fs 118 and 119. When a power-off request is made, the main CPU 107 enters a power-off state (power saving state) by processing from the sub CPU 114, and the processing in FIG. Note that the still image interval recording process in S505 of FIG. 5 is the same process as the moving image interval recording process of FIG. 6 except that the recording target is not a moving image but a still image. That is, in the still image interval recording process, the processing in S612 is the still image recording process in the moving image interval recording process of FIG. 6, and one still image file is generated for each still image.

  Next, the operation of the sub CPU 114 in the moving image interval recording process of the imaging apparatus will be described. FIG. 7 is a control flowchart of the sub CPU 114 in the moving image interval recording process. This process is realized by developing a program stored in the program / data storage unit 116 in the temporary storage unit 117 and executing it by the sub CPU 114.

  In step S <b> 701, the sub CPU 114 clears the startup timer managed internally. In step S <b> 702, the sub CPU 114 performs processing for clearing the posture information / shooting number information managed by the temporary storage unit 117. In step S <b> 703, the sub CPU 114 determines whether or not the posture information, the number-of-shooting information, the time Tstart when the START button 403 is touched, and the recording interval are received from the main CPU 107 via the serial I / Fs 118 and 119. In this step, it is determined whether or not the sub CPU 114 has received various information transmitted from the main CPU 107 in S617 in FIG. If it is determined that the posture information, the number-of-shoots information, the time Tstart when the START button 403 is touched, and the recording interval are determined to have been received, the process proceeds to S704. If not, the process proceeds to S705.

  In step S <b> 704, the sub CPU 114 records the posture information received from the main CPU 107, the number-of-shoots information k, the time Tstart when the START button 403 is touched, and the recording interval in the temporary storage unit 117. In step S <b> 705, the sub CPU 114 determines whether a power-off request has been received from the main CPU 107 via the serial I / Fs 118 and 119. In this step, it is determined whether or not the power OFF request transmitted from the main CPU 107 is received in S618 of FIG. If it is determined that a power-off request has been received, the process proceeds to S706; otherwise, the process returns to S703.

In step S <b> 706, the sub CPU 114 instructs the power management unit 115 to turn off the main CPU 107 and turns off the main CPU 107. In S707, the sub CPU 114 sets an activation timer until the next activation. The activation timer is set to a time shorter by a predetermined time T2 (for example, 5 seconds) than the time until the next recording start time. For example, the next recording start time is obtained as follows.
Tstart + {recording interval × (k + 1)}

Therefore, the activation timer is determined as follows.
Start timer = Tstart + {recording interval × (k + 1)} − current time−T2

  In step S708, the sub CPU 114 determines whether or not an interval recording end operation has been performed. If there is an end operation, the process proceeds to S711, and if not, the process proceeds to S709. In S709, the sub CPU 114 determines whether or not the activation timer set in S707 has expired (whether the activation timer has elapsed). If it is determined that the activation timer has expired, the process proceeds to S711. Otherwise, the process proceeds to S710.

  In S710, the sub CPU 114 performs a decrement process for the activation timer. In step S <b> 711, the sub CPU 114 instructs the power management unit 115 to turn on the main CPU 107, and turns on the main CPU 107. In step S <b> 712, the sub CPU 114 transmits attitude information, shooting number information k, Tstart, recording interval, and activation factor information to the main CPU 107 via the serial I / Fs 118 and 119. The activation factor information is information indicating whether the power is turned on by an interval recording end operation or whether the power is turned on when the activation timer expires.

  As described above, according to the present embodiment, in the moving image interval recording process and the still image interval recording process, it is possible to refer to the same posture information during recording in the interval recording mode. Therefore, when combining moving image scenes shot later in interval recording, it is possible to realize the connection intended by the user.

  In the above-described embodiment, an example is described in which the posture detected immediately before the trigger for starting the interval recording of a moving image or a still image (touching the START button 403 in the case of moving image interval recording) is held as posture information. did. However, the timing for detecting the posture to be held is not limited to this. The posture related to the first recorded image of interval recording is detected, and the same posture information as that of the first recorded image is referred to in the second and subsequent recorded images. Anything to do. For example, the posture detected immediately after the trigger for starting the interval recording and the posture detected immediately before, during or immediately after the first recording image shooting may be maintained as posture information.

  In the above-described embodiment, the example in which the 180-degree rotation process is performed when the camera is in the inverted posture has been described. However, the present invention is not limited to this, and the rotation process may be performed in a posture other than the normal posture. . For example, when it is detected that the camera is photographed in a vertical posture tilted by about 90 degrees from the normal posture, the image to be recorded is rotated 90 degrees in the opposite direction to the direction in which the camera is tilted and recorded. You may do it. Also in this case, processing is performed so as to match the posture of the first recorded image.

<Second Embodiment>
In the first embodiment described above, if the posture information (posture at the time of the first recording) held in the temporary storage unit 103 indicates an inverted posture, the image captured by the camera unit 101 is 180 degrees. Rotated and recorded. However, such rotation processing is not performed at the time of recording, and attribute information indicating posture information (posture at the time of the first recording) held in the temporary storage unit 103 is recorded in association with the image file. It may be. For example, instead of the configuration of the first embodiment in which when the first recording is imaged in an inverted posture and the second and subsequent images are recorded, the rotation processing according to the inverted posture is performed and the image is recorded, the rotation processing is performed. The image may be recorded by giving an attribute indicating the posture at the time of recording without executing. When the attribute assignment process is performed without performing the rotation process in this way, in the later combining process, all the images obtained by the series of interval recording are referred to the first time by referring to the attribute information given to the image. Rotate to match the orientation of the recorded image. For example, when combining a plurality of moving images obtained by a series of interval recordings, if the first recorded image shows an upside down posture with reference to the attribute information, a 180 degree rotation process ( After synthesizing (upper and lower left / right reversal processing), combine.

  In the second embodiment, a description will be given of a configuration in which video is rotated and combined based on the posture information of the top file when combining the moving image files recorded as described above. The configuration, overview, and display form on the LCD panel of the video camera main body according to the second embodiment are the same as those in the first embodiment (FIGS. 1, 2, and 3).

  FIG. 8 is a flowchart of control for rotating and combining video signals based on the posture information of the head file in moving image file combination executed after the end of interval recording. In step S <b> 801, the main CPU 107 acquires posture information associated with the head file of the moving image file group to be combined. As a group of moving image files to be combined, for example, when a user specifies one folder, all moving image files included in the specified folder can be targeted for combining. When images recorded in a series of interval recordings are stored in the same folder as in the first embodiment, a plurality of moving pictures recorded in a series of interval recordings can be combined as specified by specifying in this way. can do. The first file is, for example, a file with the smallest file number (a file with the smallest number included in the file name) among the moving image files included in the designated folder.

  Note that the method for specifying the file to be combined is not limited to this, and the file group is formed so that the user can arbitrarily specify the file to be combined, including any moving image file or still image. Anyway. Further, the posture information may be managed as metadata in a management file different from the image file, or may be posture information recorded in the header of the image file. When the acquisition of the posture information associated with the first file is completed, the process proceeds to S802.

  In step S802, the main CPU 107 initializes the file pointer managed by the internal variable with the pointer to the first file. The file pointer is managed as an identifier of each file, and is used in file open / close, read, write, decode, and encode processing. When the file pointer is initialized with the pointer of the first file, the process proceeds to S803.

  In step S803, the main CPU 107 instructs the encoder / decoder unit 104 to decode the file indicated by the file pointer in order to combine the files, and performs a decoding process. When the decoding process is completed, the process proceeds to S804. In step S804, the main CPU 107 determines whether the posture information associated with the decoded file is different from the posture information of the first file acquired in step S801. If it is determined that they are different, the process proceeds to S805, and if it is determined that they are the same, the process proceeds to S806.

  In step S805, the main CPU 107 instructs the video processing unit 102 to rotate the image so that the image is rotated in the orientation indicated by the orientation information of the head file acquired in step S801, and rotates the image. When the rotation of the video ends, the process proceeds to S806. In step S806, the main CPU 107 issues a file combination instruction to the video processing unit 102, and combines the files. When the file combination is completed, the process proceeds to S807.

  In step S <b> 807, the main CPU 107 performs an increment process of the file pointer managed internally in order to set the next file as a target to be combined. When the file pointer increment process is completed, the process proceeds to S808. In step S808, the main CPU 107 determines whether the file pointer incremented in step S807 exceeds the final file. If the final file is exceeded, the join process is complete. If it is determined that the final file is not exceeded, the process returns to 803 and the above-described process is repeated.

  If it is determined in S808 that the file pointer incremented in S807 exceeds the final file, the process proceeds to S809. In step S809, the main CPU 107 issues an encoding instruction to the encoder / decoder unit 104 to perform encoding processing in order to encode the combined file. When encoding is completed, this process is terminated.

  As described above, in the video file combination, since the posture information of the subsequent file is converted based on the posture information of the first file, the combined scene becomes the same posture information and realizes the combination intended by the user. It becomes possible. For example, when the moving image files 921 to 924 obtained by four moving image recordings are integrated as shown in FIG. 9B, the posture information of the first moving image file 921 indicates “inverted posture”. In FIG. 9, the side indicated by the bottom line of the image frame corresponds to the lower side of the imaging device. The moving image of the moving image file 921 is rotated 180 degrees by the automatic rotation function (rotated so that the thick line indicating the lower side of the imaging device is on the upper side), and the subject is in an upright state. When the moving image file 921 is combined as the first moving image file 931, the next moving image file 922 has the posture information in the normal posture and is different from the posture information of the first moving image file 921. Therefore, rotation processing is performed so that the top / bottom state of the image changes from the “normal posture” state to the “inverted posture” state, and the second moving image file 932 is combined with the moving image file 931. Is done. Similarly, for the third moving image file 923, the moving image file 933 obtained by performing the 180 degree rotation process is combined. Since the moving image file 924 has the same posture information as the first moving image file 921, the moving image file 924 is combined in a state of the moving image file 934 not subjected to the rotation process. In this way, when the combination of a series of moving image files obtained by interval recording is completed, the combined moving image files are all in a state in which the directions of the top and bottom are in agreement, and the consistency of the image orientation is maintained. .

  Note that the control of the main CPU 107 and the sub CPU 114 described above may be performed by a single piece of hardware, or the entire apparatus may be controlled by a plurality of pieces of hardware sharing the processing.

  Although the present invention has been described in detail based on the preferred embodiments thereof, the present invention is not limited to these specific embodiments, and various forms without departing from the gist of the present invention are also included in the present invention. included. Furthermore, each embodiment mentioned above shows only one embodiment of this invention, and it is also possible to combine each embodiment suitably.

  In the above-described embodiments, the case where the present invention is applied to a video camera has been described as an example. However, this is not limited to this example, and any electronic device having an imaging device capable of interval recording can be applied. Is possible. That is, the present invention can be applied to a personal computer or PDA having a camera function, a mobile phone terminal, a portable image viewer, a music player, a game machine, or the like.

(Other embodiments)
The present invention is also realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, etc.) of the system or apparatus reads the program code. It is a process to be executed. In this case, the program and the storage medium storing the program constitute the present invention.

Claims (13)

An electronic device having imaging means,
Recording control means for performing interval recording for recording images picked up by the image pickup means at intervals based on a predetermined set interval;
If the time until the next recording is less than or equal to a predetermined time after the recording by the interval recording, the electronic device is operated without changing to the power saving state, and the time until the next recording is longer than the predetermined time. In such a case, the electronic apparatus includes control means for controlling the electronic apparatus so as to be operated by being shifted to the power saving state. In addition, there is a display control means for controlling to display a confirmation screen as to whether or not to end the interval recording in response to an operation to end the interval recording between the interval recordings,
When the control screen is selected not to end the interval recording on the confirmation screen and the display of the confirmation screen ends, the control means omits the electronic device if the time until the next recording is a predetermined time or less. The electronic device is operated without being shifted to a power state, and when the time until the next recording is longer than the predetermined time, the electronic device is controlled to be moved to the power saving state and operated. Item 2. The electronic device according to Item 1.   The control means causes the electronic device to transition to the power saving state even if the time until the next recording is longer than the predetermined time until the recording is performed from the first time to the predetermined time in a series of interval recordings. The electronic apparatus according to claim 1, wherein the electronic apparatus is controlled so as to operate without any problems.   The electronic apparatus according to claim 1, further comprising a setting unit that sets the setting interval in accordance with a user operation.   5. The control unit according to claim 1, wherein the recording control unit performs control to capture and record a still image with the imaging unit at an interval based on the set interval as the interval recording. The electronic device described.   5. The recording control unit according to claim 1, wherein the recording control unit performs control so that a moving image having a predetermined length is captured and recorded by the imaging unit at an interval based on the set interval as the interval recording. The electronic device according to claim 1.   The electronic device according to claim 1, wherein the power saving state is a state in which power supply to the control unit is not performed.   The control means records the number of times recording is performed in a series of interval recordings recorded in the first memory that cannot maintain the stored contents in the power saving state before shifting to the power saving state. 8. The electronic device according to claim 1, wherein the number-of-times information shown is saved in a second memory capable of maintaining storage in the power saving state.   9. The electronic device according to claim 8, wherein the second memory maintains recording by receiving power supply even in the power saving state.   9. The electronic device according to claim 8, wherein the second memory is a non-volatile memory that maintains recording even when power is not supplied. A method for controlling an electronic apparatus having an imaging means,
A recording control step for performing interval recording for recording an image captured by the imaging means at an interval based on a predetermined set interval;
If the time until the next recording is less than or equal to a predetermined time after the recording by the interval recording, the electronic device is operated without changing to the power saving state, and the time until the next recording is longer than the predetermined time. And a control step of controlling the electronic device so that the electronic device is operated by being shifted to the power saving state.   The program for functioning a computer as each means of the electronic device as described in any one of Claims 1 thru | or 10.   A computer-readable storage medium storing a program for causing a computer to function as each unit of the electronic device according to any one of claims 1 to 10.

Images