JP2011197467A - Photographic device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an image in a direction intended by a user, even if it is at an unstable position.

SOLUTION: From a user, the digital camera captures a photographing interval time Tint for interval photographing for the digital camera, photography permitting inclination angle θa and photography permitting direction ϕa, which are within a positioning range permitting photographing, and sets them. Each photographing interval time Tint, the digital camera captures the current inclination of this digital camera from an inclination circuit 250 that has an acceleration sensor 252, and compares it with the photography permitting inclination θa. Additionally, every photographing interval time Tint, the current direction of this digital camera is captured from a direction detecting circuit 240 that has a magnetic sensor 242, and compares it with the photographing permitting direction ϕa. Photographing is carried out only when it is determined from the comparison between them that the current inclination θ and direction ϕ fall within the range of the photographing permitting inclination θa and the range of photography permitting direction ϕa.

COPYRIGHT: (C)2012,JPO&INPIT

Description

  The present invention relates to a photographing apparatus that repeatedly performs photographing under predetermined conditions.

  In general, an interval shooting function is known in which a user repeatedly performs shooting at a desired time interval without giving a direct shooting start instruction such as operating a release switch. For example, Patent Document 1 discloses a technique for determining shooting intervals, the number of recorded pixels, the number of shots, sensitivity, and other interval shooting conditions according to the observation mode, the sport mode, the monitoring mode, the astronomical observation mode, and other shooting modes. It is disclosed.

  For example, when an imaging device is attached to a moving body and the interval shooting function is used, shooting can be performed from a different viewpoint than when the user holds the imaging device and performs shooting according to the attached moving body.

JP 2004-126242 A

  For example, when the photographing apparatus is attached to the moving body as described above and the posture of the photographing apparatus is not stable when using the interval photographing function, the photographing apparatus captures many images in directions not intended by the user. There is a risk of it.

  Therefore, an object of the present invention is to provide a photographing apparatus that acquires an image in a direction intended by a user even when the posture is not stable during repeated photographing such as interval photographing.

  In order to achieve the above object, one aspect of the photographing apparatus of the present invention includes a posture detecting unit that detects a posture of the photographing device, a photographing posture setting unit that sets a range of the posture of the photographing device that performs photographing, A determination unit that repeatedly performs determination that shooting is performed when the posture detected by the posture detection unit is within the range of the posture set by the shooting posture setting unit, and that shooting is not performed when out of the range, Photographing means for carrying out photographing when the judging means judges that photographing is to be carried out.

  According to the present invention, it is possible to provide a photographing device that acquires an image in a direction intended by a user even when the posture is not stable during repeated photographing such as interval photographing.

1 is a block diagram illustrating a configuration example of a photographing apparatus according to an embodiment of the present invention. 6 is a flowchart illustrating an example of setting operation of shooting conditions related to interval shooting. The figure for demonstrating the inclination-angle of an imaging device. The figure for demonstrating the azimuth | direction of an imaging device. 7 is a flowchart illustrating an example of a shooting operation in an interval shooting mode.

  First, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an outline of the internal configuration of the digital camera according to the first embodiment of the present invention.

  A system controller 100 that controls the operation of the digital camera includes a CPU 110, an image processing circuit 122, a compression / decompression circuit 124, an Autofocus (AF) control circuit 126, an Auto-Exposure (AE) control circuit 128, an AD A plurality of converters 130, a timer counter 132, a communication control circuit 134, a GPS decoder circuit 136, a motion vector detection circuit 138, a face recognition circuit 140, a voice codec circuit 142, and a power control circuit 144. It has a circuit block (functional block).

  The CPU 110 and the other circuit blocks described above are connected to each other via a control line and a bus line. Circuit blocks other than the CPU 110 included in the system controller 100 are controlled by the CPU 110.

  The system controller 100 is connected to the image sensor 214 via an image sensor interface (IF) circuit 212. The system controller 100 also includes a focus & zoom mechanism 218 for driving the photographing lens 216, a diaphragm driving mechanism 222 for driving the diaphragm 220 of the photographing lens 216, a shutter driving mechanism 226 for driving the shutter 224, and an image sensor. An image sensor displacement mechanism 228 for moving 214 is connected. The focus & zoom mechanism 218 is a mechanism for adjusting the focal position of the photographing lens 216 and the focal length of the photographing lens 216. A diaphragm 220 driven by the diaphragm driving mechanism 222 controls the amount of light passing through the photographing lens 216. The shutter 224 driven by the shutter driving mechanism 226 sets the image sensor 214 in the exposure state and the light shielding state. The image sensor displacement mechanism 228 is a mechanism for displacing the image sensor 214 on a plane perpendicular to the optical axis of the photographing lens 216 during the exposure operation in order to prevent image deterioration due to blurring.

  The image sensor 214 is configured by a CCD, a C-MOS, or the like, and photoelectrically converts a subject image formed by the photographing lens 216 to generate an image signal. The image sensor IF circuit 212 drives the image sensor 214 in accordance with a control signal from the system controller 100, and converts an image signal output from the image sensor 214 into image data as a digital signal.

  The system controller 100 is further connected to a shake detection circuit 230, an azimuth detection circuit (electronic compass) 240, an inclination angle detection circuit 250, and an atmospheric pressure / water pressure detection circuit 260. The shake detection circuit 230 includes an X-axis gyro 232, a Y-axis gyro 234, and an angular velocity sensor processing circuit 236. The orientation detection circuit 240 includes a magnetic sensor 242 and a magnetic sensor processing circuit 244. The tilt angle detection circuit 250 includes an acceleration sensor 252 and an acceleration sensor processing circuit 254. The atmospheric pressure / water pressure detection circuit 260 includes a pressure sensor 262 and a pressure sensor processing circuit 264.

  The system controller 100 is connected to the microphone 274 via the microphone amplifier 272 and is connected to the speaker 284 via the speaker amplifier 282. The system controller 100 is connected to the display element 314 via the display element drive circuit 312, connected to the touch panel 324 via the touch panel drive circuit 322, and connected to the socket 332 and the removable memory card 334. The system controller 100 is connected to a FlashRom 340 as a non-volatile memory, an SDRAM 350 as a volatile memory, a communication circuit 360, a GPS receiving circuit 370, and an operation switch 380 that is an operation member of the digital camera.

The CPU 110 controls each circuit block as follows.
The image processing circuit 122 performs processing such as γ correction, color conversion, and demosaicing on the image data input from the image sensor IF circuit 212 and outputs the processed data to the compression / decompression circuit 124. The image processing circuit 122 also has an imaging element IF circuit when the digital camera is in a shooting preparation state (the digital camera is set in an image recording mode and the user points the digital camera toward a subject). The display image data input from 212 is processed at a predetermined frame rate (for example, 30 fps or 60 fps) and output to the display element driving circuit 312.

  The display element driving circuit 312 outputs an image based on the image data output from the image processing circuit 122 to the display element 314. The display element 314 displays an image input from the display element driving circuit 312. At this time, an image displayed on the display element 314 is generally referred to as a through image, a live view image, a monitor image, or the like.

The compression / decompression circuit 124 compresses the image data output from the image processing circuit 122 and records it on the memory card 334. The compression / decompression circuit 124 also decompresses the compressed image data read from the memory card 334 and outputs the decompressed image data to the display element driving circuit 312 when the digital camera is set to the image reproduction mode. The display element driving circuit 312 outputs an image based on the image data input from the compression / decompression circuit 124 to the display element 314. The display element 314 displays an image input from the display element driving circuit 312.
A touch panel 324 is disposed on the display element 314, and the touch panel drive circuit 322 detects an operation position (a position pressed with a finger or a pen) on the touch panel 324 and outputs the detected position to the system controller 100.

  The FlashRom 340 records program codes 342 and control parameters 344 used when the CPU 110 controls each circuit block.

  The SDRAM 350 is mainly used as a work area 352 when the image processing circuit 122 and the compression / decompression circuit 124 execute the processing.

The AF control circuit 126 adjusts the position of the photographing lens 216 so that the sharpness of the subject image is maximized based on the image data output from the imaging element IF circuit 212 during display of the live view image. In this embodiment, a focus adjustment method generally called a contrast method is used.
The AE control circuit 128 acquires conditions (aperture setting value, shutter speed, white balance, γ correction, etc.) when acquiring a still image based on image data output from the image sensor IF circuit 212 during display of a live view image. ).

  The AD converter 130 converts the output of a sensor provided in the digital camera into digital data. The sensors include an X-axis gyro 232 and a Y-axis gyro 234 that constitute a shake detection circuit 230, a magnetic sensor 242 that constitutes an orientation detection circuit 240, an acceleration sensor 252 that constitutes an inclination detection circuit 250, and an atmospheric pressure / water pressure detection circuit. Sensors such as a pressure sensor 262 constituting 260 are arranged in the digital camera.

  The timer counter 132 generates a time signal serving as a reference for operation and notifies the CPU 110 of the time signal. Based on the output of the timer counter 132, the operation time of the digital camera, the acquisition interval of the image data, the exposure time of the image sensor, the shooting interval in the interval shooting, and the like are set.

  The communication control circuit 134 controls a communication circuit including, for example, a USB device controller, a USB host controller, an IEEE 1394 controller, an Ethernet (registered trademark) controller, a wireless LAN controller, and the like. Thereby, the digital camera and the external device can communicate with each other.

The GPS decoder circuit 136 acquires orbit information received from the NAVSTAR satellite by the GPS receiving circuit 370. The CPU 110 detects the position information of the digital camera based on the acquired trajectory information.
The motion vector detection circuit 138 is a circuit that detects the amount of motion of the entire image and the amount of movement of a specific subject based on the motion vector between the image data input in time series from the imaging element IF circuit 212.

  The face recognition circuit 140 is a circuit that detects the position of a human face in an image from image data input from the imaging element IF circuit 212.

In the audio recording operation, the audio codec circuit 142 receives an audio signal received by the microphone 274, amplified and output by the microphone amplifier 272, and AD-converted at a predetermined sampling rate, and an audio file (for example, MP3, WMA (for example) Registered trademark file). These audio files are stored in the memory card 334. In the audio reproduction operation, the audio codec circuit 142 reads an audio file from the memory card 334, converts it into an audio signal, and outputs the audio signal to the speaker amplifier 282. The speaker amplifier 282 amplifies the input audio signal and reproduces the audio from the speaker 284.
Further, the power control circuit 144 controls the DC / DC converter 292 to convert the output of the battery 294 into a predetermined voltage, and supplies power to each circuit unit.

  The angular velocity sensor processing circuit 236 receives the outputs of the X-axis gyro 232 and the Y-axis gyro 234, converts them into predetermined signals, and outputs them to the AD converter 130. The CPU 110 inputs the output data of the angular velocity sensor processing circuit 236 converted by the AD converter 130, and acquires the shake of the digital camera as angular velocity data. The CPU 110 integrates the acquired angular velocity data, and calculates the amount of displacement of the image sensor 214 necessary to cancel the displacement of the subject image caused by the shake of the digital camera.

  The magnetic sensor 242 is a sensor for detecting the geomagnetic field. The output of the magnetic sensor 242 is converted into a predetermined signal by the magnetic sensor processing circuit 244 and input to the CPU 110 via the AD converter 130. CPU110 detects the azimuth | direction which is the information regarding the attitude | position of a camera on the basis of geomagnetism.

  The acceleration sensor 252 detects the direction of gravity and the impact applied to the camera. The output of the acceleration sensor 252 is converted into a predetermined signal by the acceleration sensor processing circuit 254 and input to the CPU 110 via the AD converter 130. CPU110 detects the inclination which is the information regarding the attitude | position of a camera on the basis of the horizontal surface which is a surface orthogonal to a gravity direction based on the information regarding the input gravity direction. Further, the CPU 110 detects information related to the impact generated in the camera. By using this information, a camera system that can be operated by hitting the camera body can be configured.

  The operation switch 380 includes a power switch for instructing to turn on / off the camera, a release switch for instructing start of a photographing operation, a zoom switch for instructing a zooming operation, a mode setting switch for setting an operation mode, and an UP for setting photographing conditions. / Down switch etc.

  As described above, for example, the tilt angle detection circuit 250 and the azimuth detection circuit 240 function as a posture detection unit that detects the posture of the photographing apparatus. For example, the CPU 110 performs photographing that sets a range of the posture of the photographing apparatus that performs photographing. It functions as an attitude setting unit and a determination unit that determines whether or not shooting is performed. For example, the imaging device IF circuit 212, the imaging device 214, the shooting lens 216, the focus and zoom mechanism 218, the aperture 220, the aperture drive mechanism 222, and the shutter. 224, the shutter drive mechanism 226, and the image sensor displacement mechanism 228 function as an imaging unit that performs imaging.

  Next, the operation of the digital camera according to the present embodiment will be described with reference to the drawings. Here, the operation of the CPU 110 in the system controller 100 executed based on the program code 342 recorded in the FlashRom 340 will be described with reference to a flowchart.

  In the interval shooting according to the present invention, the digital camera according to the present embodiment first sets shooting conditions for the interval shooting. What is set here is the shooting interval time (interval time) Tint of interval shooting and the conditions of the posture of the digital camera that performs shooting, that is, the shooting permission tilt angle θa and the shooting permission direction φa. Next, the digital camera performs interval shooting according to the set conditions.

  The flowchart shown in FIG. 2 shows the setting operation of shooting conditions related to interval shooting. This setting operation is executed when the user selects a mode for setting the operation conditions of the interval shooting operation. Selection of the mode setting by the user is performed by operating a mode setting switch that is one of the operation switches 380. Further, a switch equivalent to the mode setting switch may be displayed on the display element 314, and the displayed switch may be operated by the touch panel 324.

  In step S100, the CPU 110 instructs the display element driving circuit 312 to display on the display element 314 to prompt the user to set the shooting interval time (interval time). For example, a plurality of preset shooting interval time options can be displayed on the display element 314, and the user can select a desired shooting interval time from the options. This selection can be configured such that the user can select by operating an Up / Down switch which is one of the operation switches 380. Further, a switch equivalent to the Up / Down switch may be displayed on the display element 314, and the displayed switch may be operated by the touch panel 324 so that the switch can be selected.

  In step S102, the CPU 110 determines whether or not the user has selected the shooting interval time.

  If the shooting interval time is not selected as a result of the determination in step S102, in step S104, the CPU 110 sets the shortest time that can be set according to the shooting conditions as the shooting interval time Tint, and sets this as the control parameter 344 in the FlashRom 340. It is memorized as one of Thereafter, the CPU 110 shifts the processing to step S110. By setting the shortest time as the shooting interval time Tint, more images can be acquired. For this reason, possibility that the image which a user intends can be acquired increases.

  On the other hand, if the shooting interval time is selected as a result of the determination in step S102, the CPU 110 sets the shooting interval time selected by the user as the shooting interval time Tint in step S106, and sets it as the control parameter 344 in the FlashRom 340. Remember as one. Thereafter, the CPU 110 shifts the processing to step S110.

  In step S110, the CPU 110 instructs the display element driving circuit 312 to display on the display element 314 to prompt the user to set the focal length f of the photographic lens 216 (zoom the photographic lens 216 to a desired focal length). . For example, the setting of the focal length f of the photographing lens 216 can be configured such that the user can set it by operating a zoom switch which is one of the operation switches 380.

  In step S <b> 112, the CPU 110 performs a zooming operation by determining whether or not the user has performed an operation for setting the focal length f of the photographing lens 216, that is, the user presses one of the operation side switches 380. Judge whether or not it has been done.

  If the zooming operation is not performed as a result of the determination in step S112, in step S114, the CPU 110 causes the focus & zoom mechanism 218 to set the focal length f of the taking lens 216 to the widest side (short focus side). Command to set to. Thereafter, the CPU 110 shifts the processing to step S120. By setting the focal length f of the taking lens 216 to the wide end, the angle of view is maximized. For this reason, possibility that the image which a user intends can be acquired becomes high.

  On the other hand, if the zooming operation is performed as a result of the determination in step S112, in step S116, the CPU 110 instructs the focus & zoom mechanism 218 to drive the photographing lens 216 in the direction corresponding to the zooming operation. Thereafter, the CPU 110 shifts the processing to step S120.

  In step S120, the CPU 110 causes the display element driving circuit 312 to prompt the user to input a photographing allowable value Δa that is an allowable value of the tilt angle θ and the azimuth φ of the digital camera that allows the display element 314 to perform photographing. Command to

  Here, the tilt angle θ and the azimuth φ of the digital camera will be described. FIG. 3A is a view of the digital camera as viewed from the side. A reference plane H parallel to the ground is set, and an angle formed by the reference plane H and the optical axis OA of the photographing lens 216 of the digital camera is defined as a plus (downward) direction. And When the tilt angle θ is 0 degree, it means that the optical axis of the photographing lens 216 of the digital camera is horizontal with respect to the reference plane H. The tilt angle θ of the digital camera is detected by the tilt angle detection circuit 250.

  FIG. 3B is a diagram of the digital camera as viewed from above. Set a reference line M parallel to the geomagnetism (direction from south to north), and define the angle between this reference line M and the optical axis OA of the taking lens 216 of the digital camera as positive in the east direction. Thus, the direction is φ. When φ is 0 degree, it means that the optical axis of the taking lens 216 of this digital camera faces north. Note that the azimuth φ of the camera is detected by the azimuth detection circuit 240.

  An allowable width is required for the imaging permission inclination angle θa and the imaging permission azimuth φa that are permitted to be captured in the interval imaging. This is because it is rare that the orientation of the digital camera completely coincides with the set photographing permission inclination angle θa and photographing permission direction φa. If the allowable width is not set, there is a possibility that interval shooting is not performed at all, which is not practical. Therefore, a photographing allowable value Δa is required. In the present embodiment, the allowable width for the photographing permission inclination angle θa and the photographing permission direction φa is set with one photographing permission value Δa, but each of the photographing permission inclination angle θa and the photographing permission direction φa is set. Another allowable value may be set for. In step S120, for example, a plurality of preset allowable photographing values Δa are displayed on the display element 314, and the user operates the Up / Down switch to select a desired photographing allowable value Δa. It can be configured to do.

  In step S <b> 122, the CPU 110 determines whether or not an allowable value for the photographing permission inclination angle θa and the photographing permission direction φa permitting the photographing is input by the user.

  If the allowable value is not input as a result of the determination in step S122, in step S124, the CPU 110 sets an initial set value corresponding to the set focal length f (that is, the angle of view) of the photographic lens 216 to the photographic allowable value Δ. Set as a and store it as one of the control parameters 344 in FlashRom 340. Thereafter, the CPU 110 shifts the processing to step S130.

  On the other hand, if an allowable value is input as a result of the determination in step S122, in step S126, the CPU 110 sets the allowable value input by the user as the photographing allowable value Δa, and sets it as one of the control parameters 344 in the FlashRom 340. Remember as. Thereafter, the CPU 110 shifts the processing to step S130.

  In step S130, the CPU 110 instructs the display element driving circuit 312 to display the display element 314 to prompt the user to input a photographing permission tilt angle θa that is the tilt angle θ of the digital camera that permits photographing. The user who sees this display inputs the photographing permission inclination angle θa. When inputting the photographing permission tilt angle θa, for example, the user tilts the digital camera to the tilt angle θ permitting photographing and operates a release switch which is one of the operation switches 380, thereby detecting the tilt angle θ. The circuit 250 may be detected and the value may be used as the input value. In this case, in step S130, the tilt angle detection circuit 250 starts detecting the tilt angle of the digital camera. Alternatively, the display element 314 may display a plurality of values of the inclination angle θ, and the user operates the Up / Down switch to select a desired photographing permission inclination angle θa.

  In step S <b> 132, the CPU 110 determines whether or not the user has input the photographing permission tilt angle θa that permits the photographing.

  As a result of the determination in step S132, if the photographing permission inclination angle θa is not input, in step S134, the CPU 110 sets the photographing permission inclination angle θa without inclination restriction, and stores it as one of the control parameters 344 in the FlashRom 340. Thereafter, the CPU 110 shifts the processing to step S130. “No tilt limit” means that photographing is permitted regardless of the value of the tilt angle θ. That is, photographing is permitted when the inclination angle θ is any value of 0 ° ≦ θ ≦ 360 °.

  On the other hand, as a result of the determination in step S132, if the photographing permission inclination angle θa is input, in step S136, the CPU 110 determines θx based on the inclination angle θx input by the user and the photographing allowable value Δa stored in the FlashRom 340. ± Δa is set to the photographing permission inclination angle θa, which is stored in the FlashRom 340 as one of the control parameters. Thereafter, the CPU 110 shifts the processing to step S140. At this time, when the tilt angle θ of the digital camera satisfies θx−Δa ≦ θ ≦ θx + Δa, photographing is permitted.

  In step S140, the CPU 110 instructs the display element driving circuit 312 to display on the display element 314 to prompt the user to set the photographing permission direction φa that is the direction of the digital camera that permits photographing. The user who sees this display inputs the photographing permission direction φa that permits photographing. In setting the shooting permission azimuth φa, for example, the user tilts the digital camera to the shooting permission azimuth φa that allows shooting, and operates a release switch that is one of the operation switches 380 to set the direction φ. It may be configured such that the direction detection circuit 240 detects and inputs the value. In this case, in step S140, the azimuth detection circuit 240 starts detecting the azimuth φ of the digital camera. Alternatively, the display element 314 may display a plurality of azimuth values, and the user may operate the Up / Down switch to select a desired photographing permission azimuth φa.

  In step S <b> 142, the CPU 110 determines whether or not the photographing permission direction φa is input by the user.

  As a result of the determination in step S142, if the photographing permission azimuth φa is not input, in step S144, the CPU 110 sets the photographing permission azimuth φa without azimuth restriction, and stores it as one of the control parameters 344 in the FlashRom 340. . Thereafter, the CPU 110 ends the process. “No azimuth restriction” means that photographing is permitted regardless of the value of the azimuth φ. That is, photographing is permitted when the azimuth φ is any value of 0 ° ≦ φ ≦ 360 °.

  On the other hand, as a result of the determination in step S142, if the photographing permission azimuth φa is input, in step S146, the CPU 110 based on the azimuth φx input by the user and the photographing allowable value Δa stored in the FlashRom 340. φx ± Δa is set as the photographing permission direction φa and is stored in the FlashRom 340 as one of the control parameters. Thereafter, the CPU 110 ends the process. That is, when the azimuth φ of the digital camera satisfies φx−Δa ≦ φ ≦ φx + Δa, photographing is permitted.

  Next, the digital camera performs interval shooting according to the set conditions. The flowchart shown in FIG. 4 shows the operation in the interval shooting mode. This operation is executed when the interval shooting mode is selected by the user.

  For example, the user may select the mode by operating a mode setting switch that is one of the operation switches 380. Further, a switch equivalent to the mode setting switch may be displayed on the display element 314, and the displayed switch may be operated by operating the touch panel 324. In the present embodiment, the operation in the interval shooting mode is started by turning on the release switch, and the operation in the interval shooting mode is stopped by turning on the release switch again after the shooting operation is started. And A switch for instructing start and stop may be assigned to another switch other than the release switch.

  In step S200, the CPU 110 determines whether the release switch is turned on by the user and an instruction to start shooting is input. If the result of determination in step S200 is that there has been no input to start shooting, CPU 110 returns the process to step S200. That is, it waits until an instruction to start photographing is input.

  On the other hand, as a result of the determination in step S200, if an input for starting shooting is input, in step S202, the CPU 110 reads a control parameter 344 related to the interval shooting operation stored in the FlashRom 340. The control parameter 344 includes the shooting interval time Tint, the shooting permission tilt angle θa, and the shooting permission direction φa set in the operation described with reference to FIG. First, the CPU 110 sets a shooting interval time Tint, which is one of the control parameters 344, in the timer counter. Then, the operation of the timer counter is started. With this setting, the timer counter operates as an interval timer, and generates a timer interrupt signal at a predetermined shooting interval time Tint.

  In step S <b> 204, the CPU 110 determines whether or not the release switch is turned on again by the user and an input for stopping shooting is performed. As a result of the determination in step S <b> 204, if an input for stopping shooting is performed, the CPU 110 ends the process.

  On the other hand, if the result of determination in step S204 is that there has been no instruction to stop shooting, in step S206, the CPU 110 determines whether or not a timer interrupt has occurred using a timer counter. If the timer interrupt has not occurred as a result of the determination in step S206, the CPU 110 shifts the processing to step S204.

  On the other hand, if a timer interruption occurs as a result of the determination in step S204, in step S208, the CPU 110 determines whether or not the photographing permission inclination angle θa is limited. As a result of the determination in step S208, if there is no limitation on the photographing permission inclination angle θa, the CPU 110 moves the process to step S214.

  On the other hand, if the result of the determination in step S208 is that there is a limitation on the photographing permission tilt angle θa, in step S210, the CPU 110 inputs the output of the tilt angle detection circuit 250 and acquires the current tilt angle θ of the digital camera.

  In step S212, the CPU 110 compares the photographing permission inclination angle θa, which is one of the control parameters acquired in step S202, with the inclination angle θ acquired in step S208, and determines whether the inclination angle θ is within the photographing permission inclination angle θa. Determine whether. That is, it is determined whether or not θx−Δa ≦ θ ≦ θx + Δa is satisfied. If the result of determination in step S212 is that θx−Δa ≦ θ ≦ θx + Δa is not satisfied, the CPU 110 shifts the processing to step S204. This is the timing at which shooting should be performed defined by the shooting interval time Tint, but it means that the shooting operation is prohibited due to the restriction of the tilt angle θ.

  On the other hand, as a result of the determination in step S212, if θx−Δa ≦ θ ≦ θx + Δa is satisfied, in step S214, the CPU 110 determines whether or not the photographing permission direction φa is limited. As a result of the determination in step S208, if there is no restriction on the photographing permission direction φa, the CPU 110 moves the process to step S220.

  On the other hand, if the result of determination in step S214 is that there is a limit to the shooting permission direction φa, in step S216, the CPU 110 inputs the output of the direction detection circuit 240 and acquires the current direction φ of the digital camera.

  In step S218, the CPU 110 compares the shooting permission direction φa, which is one of the control parameters acquired in step S202, with the direction φ acquired in step S208, and determines whether the direction φ is within the range of the shooting permission direction φa. Determine whether. That is, it is determined whether or not φx−Δa ≦ φ ≦ φx + Δa is satisfied. If the result of determination in step S218 is that φx−Δa ≦ φ ≦ φx + Δa is not satisfied, the CPU 110 shifts the processing to step S204. This is the timing at which shooting should be performed defined by the shooting interval time Tint, but it means that the shooting operation is prohibited due to the restriction of the azimuth φ.

On the other hand, if φx−Δa ≦ φ ≦ φx + Δa is satisfied as a result of the determination in step S218, in step S220, the CPU 110 instructs each unit to expose the image sensor 214 under predetermined exposure conditions.
In step S222, the CPU 110 generates an image file from the image data acquired in step S220, and records it in the memory card 334. Then, CPU 110 returns the process to step S204.

  As described above, according to the present embodiment, in interval shooting, shooting is performed only when the optical axis of the shooting lens 216 is within the range of the shooting permission tilt angle θa and the shooting permission direction φa set by the user. It will be. By using the interval shooting function, the user can perform shooting in a situation where shooting is not normally possible. For example, attach this digital camera to a moving body such as a model car, model airplane, model helicopter, model rocket, model ship, balloon, kite, frisbee, boomerang, pet dog, cat, wild animal, etc. Shooting can be performed. Even when taking an image using a moving body or animal whose orientation is not stable when the digital camera is attached as in these examples, the digital camera has a tilt angle and orientation desired by the user. Images can be acquired. Therefore, it is possible to prevent a large number of images not intended by the user from being photographed even in the interval photographing when the digital camera is attached to a moving body or the like. With this function, if this digital camera is used, a new video expression becomes possible.

[First Modification]
Next, a first modification of the embodiment will be described. Here, in the description of this modification, the description will be limited to the differences from the above embodiment, and the description of the same parts will be omitted. In the embodiment, the digital camera uses the acceleration sensor 252 of the tilt detection circuit 250 and the magnetic sensor 242 of the bearing detection circuit 240 as means for detecting the tilt angle θ and the direction φ, respectively. On the other hand, in the present modification, the X axis gyro 232 and the Y axis gyro 234 of the shake detection circuit 230 are used.

  The digital camera includes an X-axis gyro 232 and a Y-axis gyro 234 of a shake detection circuit 230 that function as an angular velocity sensor for detecting camera shake. The shake detection circuit 230 can obtain the deflection angle from the reference direction by integrating. The reference direction is the direction of the digital camera at the start of the integration operation. Therefore, if the photographing permission inclination angle θa and the photographing permission direction φa are set with reference to the direction of the digital camera at the start of the integration operation, the shake detection circuit 230 can play a role in place of the magnetic sensor 242 and the acceleration sensor 252. it can. That is, the present invention can be implemented even with a digital camera in which the magnetic sensor 242 and the acceleration sensor 252 are not mounted. Other configurations and operations thereof are the same as those of the above-described embodiment.

  Thus, for example, the shake detection circuit 230 functions as a posture detection unit that detects the posture of the photographing apparatus in the three-axis direction, and for example, the X-axis gyro 232 and the Y-axis gyro 234 function as angular velocity sensors.

  Also by this modification, the same effect as the above-described embodiment can be obtained.

[Second Modification]
Next, a second modification of the embodiment will be described. Here, in the description of this modification, the description will be limited to the differences from the above embodiment, and the description of the same parts will be omitted. In the embodiment, the digital camera uses the tilt angle θ and the azimuth φ as a reference for permission of photographing. On the other hand, in the present modification, the altitude (or water depth) of the digital camera is further used as a criterion for permission of photographing.

  In the present modification, the photographing permission altitude Aa is set based on the user's input, similarly to the photographing permission tilt angle θa and the photographing permission direction φa. For example, a plurality of altitude A values may be displayed on the display element 314, and the user may operate the Up / Down switch to select a desired photographing allowable altitude Aa.

  Then, as in the case of the tilt angle θ and the azimuth φ, the photographing permission altitude Aa and the altitude (or water depth) of the camera acquired by the atmospheric pressure / water pressure detection circuit 260 are compared at every photographing interval time Tint, Photographing is performed only when the altitude (or water depth) is within the range of the photographing permitted altitude Aa.

  According to the present modification, in addition to the same effects as those of the above-described embodiment, it is possible to perform photographing according to the user's desire with respect to altitude. For example, when photographing with the digital camera fixed to the heel, a photographing operation is performed only in a state where the heel is raised to a desired height.

[Third Modification]
In the digital camera, when the posture is not within the range set by the user, shooting is not performed. On the other hand, in the present modification, a memory card 334 having a sufficiently large storage capacity is mounted, and an image is acquired at every shooting interval time Tint. However, a captured image when the posture of the digital camera that has not been photographed in the embodiment is not within the range set by the user, and a captured image when the posture of the digital camera is within the range set by the user And store them separately.

For example, a captured image (out-of-condition image) when the posture of the digital camera is not within the range set by the user can be stored in a region different from the region that is normally stored. For example, image data of a digital camera is stored in a memory card in accordance with a DCF (Design rule for Camera File system) standard. Therefore, a folder different from the DCF standard may be generated, and images out of conditions may be stored in this folder. In addition, an out-of-condition image may be given a file name different from the standard and stored in a folder based on the DCF standard.
In either case, the captured image and the out-of-condition image when the posture of the digital camera is within the range set by the user are stored in the memory card 334 in a format that can be easily selected.

  According to this modification, the user can leave an opportunity to acquire a good image that is not intended from an out-of-condition image, and the user can easily select and remove an unnecessary image.

[Fourth Modification]
The digital camera according to the embodiment can be applied not only to a still image shooting operation but also to moving image shooting (movie shooting). That is, it is possible to control to perform a moving image shooting operation only when the posture of the digital camera is within the range set by the user.
Also in this modification, acquisition of useless data can be prevented.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, the problem described in the column of problems to be solved by the invention can be solved and the effect of the invention can be obtained. The configuration in which this component is deleted can also be extracted as an invention. Furthermore, you may combine suitably the component over a different modification.

  DESCRIPTION OF SYMBOLS 100 ... System controller, 110 ... CPU, 122 ... Image processing circuit, 124 ... Compression / decompression circuit, 126 ... AF control circuit, 128 ... AE control circuit, 130 ... AD converter, 132 ... Timer counter, 134 ... Communication control circuit, 136 ... GPS decoder circuit, 138 ... motion vector detection circuit, 140 ... face recognition circuit, 142 ... voice codec circuit, 144 ... power control circuit, 212 ... imaging element IF circuit, 214 ... imaging element, 216 ... photographing lens, 218 ... Zoom mechanism, 222 ... diaphragm drive mechanism, 224 ... shutter, 226 ... shutter drive mechanism, 228 ... imaging element displacement mechanism, 230 ... detection circuit, 232 ... X-axis gyro, 234 ... Y-axis gyro, 236 ... angular velocity sensor processing circuit, 240 ... direction detection circuit, 242 ... magnetic sensor, 244 ... magnetic sensor processing Road 250. Inclination angle detection circuit 252 ... Acceleration sensor 254 ... Acceleration sensor processing circuit 260 ... Barometric pressure / water pressure detection circuit 262 ... Pressure sensor 264 ... Pressure sensor processing circuit 272 ... Microphone amplifier 274 ... Microphone 282 ... Speaker amplifier, 284 ... Speaker, 292 ... DC converter, 294 ... Battery, 312 ... Display element drive circuit, 314 ... Display element, 322 ... Touch panel drive circuit, 324 ... Touch panel, 332 ... Socket, 334 ... Memory card, 342 ... Program code, 344 ... Control parameter, 350 ... SDRAM, 352 ... Work area, 360 ... Communication circuit, 370 ... GPS receiver circuit, 380 ... Operation switch, .theta .... Tilt, .phi .... Direction, A ... Altitude, OA ... Optical axis, H: reference plane, M: reference line, θa: photographing permission tilt angle, φa: photographing permission azimuth, A a: Altitude allowed for photographing.

Claims (5)

Posture detection means for detecting the posture of the photographing apparatus;
Photographing posture setting means for setting a range of posture of the photographing device that performs photographing;
A determination unit that repeatedly performs a determination that the photographing is performed when the posture detected by the posture detection unit is within the range of the posture set by the photographing posture setting unit, and that the photographing is not performed when the posture is out of the range; ,
Photographing means for performing photographing when the determination means determines that photographing is performed;
An imaging apparatus comprising: The posture detection means includes an acceleration sensor, and detects an inclination angle of the photographing apparatus, which is an angle formed by a horizontal plane and an optical axis of the photographing means, based on an output of the acceleration sensor.
The imaging apparatus according to claim 1, wherein: The posture detection means includes a magnetic sensor, and detects the azimuth of the photographing apparatus, which is an angle formed by the direction of geomagnetism and the optical axis of the photographing means, based on the output of the magnetic sensor.
The photographing apparatus according to any one of claims 1 and 2, wherein the photographing apparatus is characterized in that: The posture detecting means has an angular velocity sensor,
The posture detection means is based on an integral value of the output of the angular velocity sensor, and is an angle formed by a horizontal plane and the optical axis of the imaging means, and an inclination angle and geomagnetic direction of the imaging apparatus and an optical axis of the imaging means. Detecting the orientation of the imaging device, which is the angle formed;
The imaging apparatus according to claim 1, wherein:   5. The photographing apparatus according to claim 1, wherein the determination unit determines whether the photographing is performed or not at regular time intervals.

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