JP2011237716A - Digital camera and method for controlling the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a digital camera capable of executing a photographing operation by a body motion desired by a user in a hands-free state.SOLUTION: The digital camera (100) having a housing includes: an attitude detecting section (320) detecting an attitude of the housing; a motion detecting section (320) detecting a motion generated on the housing; and a control section (300) registering an output pattern based on an output from the motion detecting section (320) in response to a gesture performed by a camera user on a registration mode for registering a gesture of a user, and comparing the output from the motion detecting section (320) with the registered output pattern on a photographic mode capable of executing a photographing operation by a body motion of a user. The control section (300) permits a photographing operation when determining that the output from the motion detecting section agrees with the registered output pattern, and detecting that the housing is in the prescribed attitude by the output from the attitude detecting section.

Description

  The present invention relates to a digital camera and a control method thereof. In particular, the present invention relates to a digital camera capable of shooting in a hands-free state by attaching a camera housing to a user's body.

  The camera described in Patent Document 1 can operate the camera in accordance with vibration generated in the camera. This camera performs a predetermined operation according to the direction of vibration. The camera described in Patent Document 2 can change the slide show display speed according to the tilt of the camera housing. Patent Documents 3 and 4 disclose an electronic device that registers a body motion and performs a predetermined operation when the registered body motion is detected.

JP 2000-125184 A JP 2007-49484 A JP 2009-212633 A JP 2008-77192 A

  With the techniques described in Patent Documents 1 and 2, the camera can be operated without using mechanical operation members such as buttons and switches. For example, the camera can be operated by performing a body motion (gesture) such as shaking an arm after fixing the camera to a wrist or the like. In other words, by using the techniques disclosed in Patent Documents 1 and 2, the camera can be operated even in a hands-free state. The hands-free state is a state where the camera is held by the holder and is not held by the user. Patent Documents 3 and 4 do not disclose the photographing operation of the camera. However, when a camera is attached to the body and photographing is performed in a hands-free state, it is desirable that the photographing operation can be performed with the body motion desired by the user.

  An object of the present invention is to cause a camera to perform a photographing operation by a physical motion desired by a user in a hands-free state.

  A digital camera according to an aspect of the present invention is a digital camera having a housing, a posture detection unit that detects a posture of the housing, a motion detection unit that detects a motion generated in the housing, and a user In the registration mode for registering the gesture of the camera, in the shooting mode in which the output pattern is registered based on the output output by the motion detection unit according to the gesture performed by the user of the camera, and the shooting operation can be performed according to the gesture performed by the user And a control unit that compares the output of the motion detection unit with a registered output pattern. When the control unit determines that the output of the motion detection unit matches the registered output pattern, and detects that the housing is in a predetermined posture from the output of the posture detection unit, the photographing operation It is characterized by permitting.

  A control method according to another aspect of the present invention is a control method for controlling a digital camera having a housing, the posture detecting step for detecting the posture of the housing, and the motion generated in the housing. In the registration mode for registering the motion detection step and the user's gesture, the motion pattern is registered based on the motion detected in the motion detection step according to the gesture performed by the user of the camera, and photographed according to the gesture performed by the user A control step of comparing the motion detected in the motion detection step with the registered motion pattern in a photographing mode capable of motion, wherein the control step includes the motion detected in the motion detection step; It is determined that the registered motion patterns match, and the case is in a predetermined posture from the detection result in the posture detection step. If the Rukoto is detected, characterized in that the photographing operation is permitted.

  According to the embodiment of the present invention, it is possible to cause the camera to perform a shooting operation according to a body motion desired by the user in a hands-free state.

1 is an external perspective view of a front side showing a schematic configuration of a digital camera. It is an external appearance perspective view of the back side showing a schematic structure of a digital camera. It is a block diagram which shows the internal structure of a digital camera schematically. It is a flowchart which shows the main routine of the control performed by a system controller. It is a flowchart which shows the interruption routine of the attitude | position / motion detection process performed by a system controller. It is a flowchart which shows the control procedure (control routine) which a system controller performs in gesture registration mode. It is a flowchart which shows the interruption routine of gesture detection performed by a system controller. It is a figure which shows the state which looked at the camera hold | maintained in the normal position from the front. It is a figure which shows the state which looked at the camera hold | maintained at the vertical position from the front. (A) It is a figure which shows switch operation for starting gesture registration. (B) It is a figure which shows an example of the gesture registered. (C) It is a figure which shows switch operation for complete | finishing gesture registration. (A) It is the graph which measured the acceleration pattern produced by gesture several times. (B) It is a graph which shows the average and the band (band) of the acceleration pattern which arose by gesture. It is the side view which showed the support state of the camera in a hands free state. It is a figure which shows the camera holder holding a camera.

  FIG. 1 is an external perspective view showing a schematic configuration of a digital camera 100 (also simply referred to as a camera) according to an embodiment of the present invention. FIG. 1 shows the front side of the digital camera 100. The front side is the side that faces the subject during shooting. The digital camera 100 is shown as an example of an imaging device. FIG. 2 is an external perspective view showing the schematic configuration of the digital camera 100, and shows the back side of the digital camera 100. The back side is the side where the digital camera 100 faces the user during shooting.

  1 and 2, the digital camera 100 includes a photographing lens 102, a flash device 104, a power switch 106, a release switch 108, an acceleration sensor 114, a playback switch 120, a menu switch 122, and a zoom. Instruction switches 126 and 128, a cross key switch 130, a touch panel display 132, a first mode setting switch 140, and a second mode setting switch 145 are provided.

  In FIG. 1, the taking lens 102 has a configuration in which the lens barrel unit does not protrude from the main body of the digital camera 100 in the image recording mode. However, the photographing lens 102 may have a configuration in which the mirror copper unit protrudes from the main body in the image recording mode. The flash device 104 emits light as needed to irradiate the subject with light during photographing. The flash device 104 may be composed of a high-pressure discharge circuit and a xenon tube, or may be composed of a high-intensity LED (laser diode).

  Each switch (operation switch) of the digital camera 100 is operated by the user of the digital camera 100. Each switch sends an instruction to the system controller 300 in accordance with a user operation. Each switch constitutes the operation unit 350 of the digital camera 100.

  The power switch 106 instructs the system controller 300 to start and shut down the digital camera 100. The release switch 108 instructs the system controller 300 to start the shooting operation. The zoom instruction switches 126 and 128 instruct the system controller 300 to change the magnification of the photographing lens 102 when the digital camera 100 is set to the image recording mode.

  The playback switch 120 instructs the system controller 300 to switch the digital camera 100 in the image recording mode to the image playback mode or switch the digital camera 100 in the image playback mode to the image recording mode. The menu switch 122 instructs the system controller 300 to call the menu screen on the touch panel display 132. The user instructs the system controller 300 to change various settings of the digital camera 100 in the image recording mode or the image reproduction mode by touching the menu screen displayed on the touch panel display 132. The menu switch 122 instructs the system controller 300 to stop displaying the menu screen on the touch panel display 132.

  When the menu screen is displayed on the touch panel display 132, the cross key switch 130 instructs the system controller 300 to change various settings of the digital camera 100 in accordance with a user operation. The various settings of the digital camera 100 may be changed by operating the touch panel 338 when the menu screen is displayed.

  The first mode setting switch 140 is a switch for selecting a “gesture registration mode” that enables registration of a user's gesture (body motion). The second mode setting switch 145 is a switch for selecting a “gesture shooting mode” in which the camera can start shooting according to the gesture of the user. The gesture registration mode and the gesture shooting mode may be selected by selecting an icon, a menu, or the like displayed on the touch panel display 132 with the cross key switch 130, the user's finger, a pen, or the like.

  The acceleration sensor 114 detects acceleration applied to the digital camera 100 as described later. As the acceleration sensor 114, a sensor using MEMES (micro electro mechanical systems) has already been put into practical use. The acceleration sensor 114 detects the acceleration generated in the direction along the X, Y, and Z axes shown in FIGS. The acceleration sensor 114 may be configured to detect angular velocities around the X, Y, and Z axes as necessary.

  FIG. 3 is a block diagram schematically showing the internal configuration of the digital camera 100. A system controller 300 that functions as a control unit for controlling the operation of the digital camera includes a CPU 302 and a plurality of circuit blocks (functional blocks). The plurality of circuit blocks include an image processing circuit 304, a compression / decompression circuit 306, an AD (analog-digital) converter 308, an audio codec circuit 310, and the like. The CPU 302 and the plurality of circuit blocks are connected to each other via a control line and a bus line, and each circuit block is controlled by a command from the CPU.

  The system controller 300 (control unit) includes an image sensor 314, a diaphragm drive mechanism 316, a shutter drive mechanism 318, a posture / motion detection circuit 320, a microphone amplifier 322, a speaker amplifier 326, a display element drive circuit 332, a touch panel drive circuit 336, and a memory. Electrically connected to the card 340, FlashRom (flash read only memory) 342, SDRAM (synchronous dynamic random access memory) 344, light emitting element 348 for display, operation unit (switches) 350, and flash control circuit 352 Connect to.

  The photographing lens 102 forms an image on the image sensor 314 with light taken from outside the camera. The image sensor 314 converts an optical image formed on the image sensor 314 into an image signal by photoelectric conversion. The image sensor 314 is, for example, a CCD (charge coupled device) sensor or a CMOS (complementary metal oxide semiconductor) sensor. The imaging element IF circuit 312 includes a circuit that generates a drive signal for the imaging element 314 in accordance with a control signal from the system controller 300, an AD conversion circuit that performs AD conversion on the output of the imaging element 314, and the like. The image signal of the optical image is AD converted by the image sensor IF circuit 312 and input to the system controller 300 as image data. The imaging lens 102, the imaging element 314, and the imaging element IF circuit 312 constitute an imaging unit 370.

  The aperture driving mechanism 316 drives an aperture that controls the amount of light passing through the taking lens 102. The shutter drive mechanism 318 drives a shutter that sets the image sensor 314 to an exposure state and a light shielding state.

  The system controller 300 includes a microphone 324 via a microphone amplifier 322, a speaker 328 (sound generator) via a speaker amplifier 326, a display element 334 via a display element drive circuit 332, and a touch panel via a touch panel drive circuit 336. 338 is electrically connected to a removable memory card 340 via a socket 346. Note that the display element driver circuit 332 and the display element 334 form a display portion. The display element 334 and the touch panel 338 constitute a touch panel display 132. Further, the system controller 300 controls the lighting state of the display light emitting element 348.

  The CPU 302 of the system controller 300 controls the circuit block so as to perform the following operations. The image processing circuit 304 performs processing such as γ correction, color conversion, and demosaicing on the image data output from the image sensor IF circuit 312 and outputs the processed data to the compression / decompression circuit 306. The image processing circuit 304 also processes the display image data input from the imaging element IF circuit 312 at a predetermined frame rate (30 fps, 60 fps) when the digital camera 100 is in a state before photographing, and displays the display element. You may output to the drive circuit 332. This state before photographing is a state in which the digital camera 100 is set to the image recording mode and the user points the digital camera 100 toward the subject. The display element driving circuit 332 displays an image based on the image data output from the image processing circuit 304 on the display element 334. An image displayed on the display element at this time is generally called a through image, a live view image, a monitor image, or the like.

  The compression / decompression circuit 306 compresses the image data output from the image processing circuit 304 and records it on the memory card 340. The compression / decompression circuit 306 also decompresses the compressed image data read from the memory card and outputs the compressed image data to the display element driving circuit 332 when the digital camera 100 is set to the image reproduction mode. The display element driving circuit 332 displays an image based on the image data input from the compression / decompression circuit 306 on the display element 334. The AD converter 308 converts the output of a sensor or detection circuit provided in the digital camera into digital data.

  In the audio recording operation, the audio codec circuit 310 AD converts the audio signal output from the microphone amplifier 322 at a predetermined sampling rate and converts the audio signal into an audio file (MP3, WMA, etc.). Then, the audio codec circuit 310 stores the audio file in the memory card 340. In the audio reproduction operation, the audio codec circuit 310 reads an audio file from the memory card 340, converts it into an audio signal, and outputs the audio signal to the speaker amplifier 326. Thereby, sound is reproduced from the speaker 328.

  A touch panel 338 is disposed on the display element 334. The touch panel drive circuit 336 detects an operation position on the touch panel (a position pressed (contacted) with a finger, a pen, or the like) and outputs the detected position to the system controller 300. The display light emitting element 348 is configured by an LED (light emitting diode) or the like, and displays states such as an on / off state of the camera power, an access state to the memory card 340, and an operation state of the self-timer. One or more display light emitting elements 348 may be provided.

  The SDRAM 344 is mainly used as a work area (work area) when the image processing circuit 304 and the compression / decompression circuit 306 perform the above-described processing. The CPU 302 controls the camera based on the program code recorded in the FlashRom 342 and the control parameters. Gesture pattern data is registered in a gesture registration mode, which will be described later, and a shooting operation is performed using the registered pattern data of the gesture in a gesture shooting mode, which will be described later.

  The flash control circuit 352 is a circuit for emitting the auxiliary light source 354. The auxiliary light source 354 is a xenon tube, a high-intensity LED, a high-intensity lamp, or the like.

  The posture / motion detection circuit 320 is a posture detection unit for detecting the posture of the housing of the digital camera 100 (camera housing 100a) and a motion detection unit for detecting the motion of the housing. By detecting the movement of the housing of the digital camera 100, the gesture of the user wearing the digital camera 100 is detected. The posture / motion detection circuit 320 includes an acceleration sensor 114 for detecting acceleration in the three-axis (X, Y, Z-axis) directions of the digital camera 100 and its processing circuit 116. The acceleration sensor 114 includes an acceleration sensor unit 114a that detects acceleration in the X-axis direction, an acceleration sensor unit 114b that detects acceleration in the Y-axis direction, and an acceleration sensor unit 114c that detects acceleration in the Z-axis direction. In the present embodiment, the X axis is parallel to the lateral direction (or the long axis direction or the longitudinal direction) of the casing of the digital camera 100, and the Y axis is the vertical direction (or short) of the casing of the digital camera 100. The Z axis is parallel to the optical axis direction of the photographing lens 102 (or the thickness direction of the housing).

  The acceleration sensor 114 can measure the static acceleration of gravity, and at the same time can measure the dynamic acceleration caused by movement, impact, vibration, or the like. The direction of gravity applied to the digital camera 100 can be detected by analyzing the outputs of the acceleration sensor units 114a, 114b, and 114c in the three-axis directions, and the posture of the digital camera 100 (horizontal or tilt with respect to the direction of gravity) can be detected. Further, the moving direction of the digital camera 100 and the direction of impact applied to the digital camera 100 can also be detected. The output of the acceleration sensor 114 is converted into a predetermined signal by the acceleration sensor processing circuit 116 and supplied to the AD converter 308 of the system controller 300. As the posture / motion detection circuit 320, for example, ADXL327 manufactured by Analog Devices, Inc. can be used. The posture / motion detection circuit 320 is configured to detect angular velocities around the X, Y, and Z axes in addition to the acceleration sensors in the X, Y, and Z axes in order to increase the posture detection accuracy based on the rotation angle ( May already be put into practical use as a MEMS gyro sensor.

  The flowchart of FIG. 4 shows a main routine of control executed by the system controller 300. In the main routine, a procedure relating to the characteristic part of the embodiment is described, and other procedures are omitted.

  In step S100, when the power switch 106 is turned on and the system controller 300 is activated, initial setting operations (memory initialization, peripheral circuit initialization, etc.) are performed.

  In step S102, an image is acquired from the image sensor 314 at a predetermined frame rate, and an operation (live view operation) for displaying an image of the subject on the display element 334 is started.

  In step S104, it is determined whether the “gesture registration mode” is selected by operating the first mode setting switch 140, which is one of the operation switches. If the gesture registration mode is selected, the routine proceeds to step S150 (FIG. 6). If not selected, the routine proceeds to step S106.

  In step S <b> 106, it is determined whether the “gesture shooting mode” is selected by operating the second mode setting switch 145, which is one of the operation switches. When the gesture shooting mode is selected, the routine proceeds to step S108, and when it is not selected, the routine proceeds to S136, and the normal camera operation is performed.

  When “gesture shooting mode” is selected and steps S108 to S148 are executed, a shooting operation can be executed with a predetermined gesture registered by the user. When “gesture registration mode” is selected and S150 to S170 are executed, a predetermined gesture of the user who permits the photographing operation can be registered as an acceleration pattern. The acceleration pattern is a time change pattern of the acceleration of the camera casing 100a by gesture, and is described as an example of an exercise pattern.

  In step S108, the live view operation is stopped. This is because the “gesture shooting mode” is based on the premise that the camera is operated in a hands-free state, and the camera is fixed to the user's body via the camera holder as shown in FIGS. Therefore, it is difficult for the user to see the display element, and display is unnecessary. By stopping the live view operation, the power consumption of the camera 100 can be reduced. That is, the operations of the display unit (the display element driving circuit 332 and the display element 334) are stopped, and the operations of the imaging element IF circuit 312 and the imaging element 314 are stopped.

  In step S110, an operation mode in which the speaker 328 as a sound generation unit generates a shooting operation sound during the shooting operation starts. In the hands-free state, the user cannot confirm the shooting operation by display. Therefore, the operation mode for sounding is set when it is not the operation mode for sounding the shooting operation sound (release sound) so that it can be surely confirmed whether or not the shooting operation has been performed.

  In step S112, since the holding state of the camera 100 is not always stable in the hands-free state, the camera 100 is likely to be shaken (vibrated). Therefore, a process for preventing the acquired image from being deteriorated (blurred) due to camera shake is performed. For example, the following shooting conditions are set. The ISO sensitivity is increased and the shutter speed is increased. For this reason, the program diagram is changed so as to increase the shutter speed. The program diagram defines a combination of an aperture and a shutter speed corresponding to the brightness of the subject, and is stored in, for example, FlashRom 342. Alternatively, the focal length of the photographic lens is set to a short value (zoomed out to the wide angle side). Alternatively, if the camera 100 has a shake correction mechanism, a shake correction operation is permitted.

  In step S <b> 114, the registered gesture pattern data is read from the FlashRom 342. In the present embodiment, it is assumed that there is only one pattern data. However, when there are a plurality of registered gesture pattern data, the gesture pattern is displayed on the touch panel display 132, and a desired pattern is displayed to the user by operating the cross key switch 130 or touching the touch panel display 132. You may make it choose.

  In step S116, the operation of the posture / motion detection circuit 320 is permitted, the timer counter is set, and the interrupt operation is permitted. The system controller 300 has a timer, and sets a timer counter so that an interrupt occurs every 1 msec, for example. Thereby, an interrupt is generated every 1 msec in parallel with the operation of the main routine of FIG. 4, and the interrupt processing routine “gesture detection 1” (FIG. 5) is called and executed. In this processing routine “gesture detection 1”, the posture and motion state (user gesture) of the camera 100 are calculated from the output of the posture / motion detection circuit 320 as information necessary for determining whether or not to perform a shooting operation. The

  In step S118, it is determined whether the “gesture detection flag” that is the control flag is set (for example, 1). If the gesture detection flag is set, the routine proceeds to step S120. If the gesture detection flag is not set, the routine proceeds to S138.

  In step S120, the system controller 300 blinks the display light emitting element 348 as the first display form to notify that the user's gesture has been detected. The display light emitting element 348 is an example of a display element that notifies the user that gesture has been detected in the first display form. The display element may be a light emitting unit at a position that can be visually recognized by the user when the camera is mounted on the body. Further, a speaker 328 (sound generation unit) may be used instead of the display element (light emitting unit) to notify that the gesture is detected by voice in the first mode.

  In step S122, it is determined whether the camera casing 100a is set to a predetermined posture. When the camera casing 100a is set to a predetermined posture, the routine proceeds to S124. When the camera casing 100a is not set to the predetermined posture, the routine proceeds to S138. As an example of the predetermined posture, the first posture where the long axis direction of the camera housing 100a is horizontal with respect to the ground, or the short posture direction of the camera housing 100a is horizontal with respect to the ground. The second posture is mentioned.

  FIG. 8 shows the camera casing 100a set to the first posture. The first posture is a posture when the camera 100 is held at the normal position. The XYZ axes described in FIG. 8 are the same as the XYZ axes described in FIG. In step S122, it is determined whether the X axis (long axis) of the camera 100 is horizontal with respect to the ground. That is, it is determined whether or not the X axis is perpendicular to the direction of gravity. The degree (angle) of deviation from the horizontal direction (direction perpendicular to the direction of gravity) of the X axis can be defined by the rotation angle θz1 around the Z axis. In FIG. 8, with the X axis parallel to the ground as a reference (0 degree), the counterclockwise rotation angle around the Z axis is plus (+) and the clockwise rotation around the Z axis The angle is minus (-). When the absolute value of the rotation angle θz1 is smaller than the first predetermined value θth1 (that is, when the condition −θth1 <θz1 <+ θth1 is satisfied), it is determined that the camera housing is in the first posture.

  FIG. 9 shows the camera housing set to the second posture. The second posture is a posture when the camera is held in a vertical position. The XYZ axes described in FIG. 9 are the same as the XYZ axes described in FIG. In step S122, it is further determined whether the X axis of the camera is perpendicular to the ground. That is, it is determined whether or not the X axis is parallel to the direction of gravity. The degree (angle) of deviation from the gravity direction of the X axis can be defined by the rotation angle θz2 around the Z axis. In FIG. 9, the rotation angle in the counterclockwise direction around the Z axis is defined as plus (+), with the X axis being parallel to the gravity direction as a reference (0 degree), and the clockwise rotation angle around the Z axis. Is minus (-). When the absolute value of the rotation angle θz2 is smaller than the second predetermined value θth2 (that is, when the condition of −θth2 <θz2 <+ θth2 is satisfied), it is determined that the camera housing is in the second posture. = Θz1-90 ° holds.

  The first predetermined value θth1 and the second predetermined value θth2 are control parameters that are determined as appropriate assuming an actual photographing operation. If the first predetermined value θth1 or the second predetermined value θth2 is small, it is difficult to photograph. The camera 100 may have a configuration in which the values of the first predetermined value θth1 and the second predetermined value θth2 can be set by operating an operation switch (such as the cross key switch 130) of the camera 100. In this case, the first predetermined value θth1 and the second predetermined value θth2 can be appropriately set by the user according to his / her preference. The rotation angles θz1 and θz2 are detected in an interrupt routine (FIG. 5) for posture / motion detection processing and stored in a predetermined work area of the SDRAM 344.

  In step S124, the system controller 300 turns on the display light emitting element 348 as the second display form to notify that the user's gesture is detected and that the camera housing is in a predetermined posture in which photographing is permitted. The user performs a predetermined gesture and confirms whether or not the camera has detected the gesture in the first display form, and then sets the posture of the camera housing to a predetermined position so that the second display form is performed. The camera can execute a shooting operation. Further, a speaker 328 (sound generation unit) may be used instead of the display element (light emitting unit) to notify that the gesture has been detected by voice in the second mode.

  In step S126, the system controller 300 permits the imaging operation by controlling the imaging element IF circuit 312 and the imaging element 314. Thereby, the imaging operation of the imaging unit 370 starts.

  In step S128, the system controller 300 controls the aperture driving mechanism 316 as a photographing operation, exposes the image sensor 314 under a predetermined condition, and acquires image data. Then, the system controller 300 generates an image file and stores it in the memory card 340. In conjunction with this exposure operation, the speaker 328 reproduces a shooting operation sound (release sound) to notify the user that the shutter has been operated.

  In step S <b> 130, the system controller 300 controls the imaging element IF circuit 312 and the imaging element 314 to prohibit the imaging operation. Thus, the operation of the imaging unit is stopped. In the present embodiment, step S130 is provided because a still image is acquired. However, when a moving image is acquired, step S130 is not provided and shooting may be continued.

  In step S132, the “gesture detection flag” is initialized (for example, 0), and the photographing operation is prohibited. The photographing operation is not permitted until the user newly gestures and the “gesture detection flag” is set again (for example, 1).

  In step S134, the system controller 300 turns off the display light emitting element 348. With this turn-off operation, the user can recognize that the shooting has been completed.

  In step S138, the state of the power switch 106 is detected. If the power switch 106 is off, the control ends. If the power switch 106 is on, the routine proceeds to step S140.

  In step S140, it is determined whether the “gesture shooting mode” has been canceled by operating the second mode setting switch 145, which is one of the operation switches. When the gesture shooting mode is canceled, the routine proceeds to S142. If the gesture shooting mode has not been canceled, the routine proceeds to S118, and the “gesture shooting mode” is maintained.

  In step S142, the operation of the posture / motion detection circuit 320 is prohibited (stopped). Timer counter operation stops and interrupt operation stops.

  In step S144, an image is acquired from the image sensor 314 at a predetermined frame rate, and the operation of displaying the subject image on the display device 334 (live view operation) is resumed.

  In step S146, the setting of the shooting operation sound set in step S110 is returned to the original setting (setting before entering the gesture shooting mode).

  In step S148, the shooting conditions set in step S112 are returned to the original shooting conditions (the shooting conditions set before entering the gesture shooting mode).

  The flowchart in FIG. 5 shows an interrupt routine of the posture / motion detection process executed by the system controller 300. Using the timer of the system controller 300, the system controller 300 generates an interrupt signal at a predetermined cycle (for example, every 1 msec). The interrupt routine is executed in synchronization with the interrupt signal.

  In step S200, the system controller 300 uses the AD converter 308 to measure the output (acceleration in the three axis directions) from the posture / motion detection circuit 320.

  In step S202, the output data measured in step S200 is stored as log data (history data) in the work memory. The work memory is provided in a part of the SDRAM 344, for example. Log data is a series of measured output data.

  In step S204, the log data corresponding to the acceleration in the three-axis directions is analyzed by a known method to detect the camera posture (angles θz1 and θz2). The detection result is stored at a predetermined address in the work memory.

  In step S206, it is determined whether the registered pattern data (time change pattern of acceleration) and the pattern data of gesture (detected gesture) obtained by analyzing log data match.

  If it is determined in step S208 that the detected gesture is a registered gesture as a comparison result in step S204, the routine proceeds to step S208. If it is determined that the detected gesture is not a registered gesture, the routine ends.

  In step S210, a gesture detection flag is set (for example, 1).

  The flowchart of FIG. 6 shows a control procedure executed by the system controller 300 in the “gesture registration mode”.

  When the “gesture registration mode” is selected by operating the first mode setting switch 140 or the like in step S104 (FIG. 4), steps S150 to S170 are executed. Information (gesture pattern data) necessary for executing a shooting operation in the “gesture shooting mode” is generated and stored.

  An example of the registered gesture is shown in FIG. The gesture shown in FIG. 10 (b) is an operation of swinging up the forearm obliquely upward from the elbow as a base point, and swinging it down to a position where the forearm is horizontal (hereinafter referred to simply as “arm swing down”). Called operation). It should be noted that if the gesture is such that some acceleration is generated in the three acceleration sensor units 114a, 114b, and 114c in the camera, it is possible to register other than the gesture shown in FIG.

  In step S150, the process waits until an operation for instructing measurement start (registration start) is performed. For the operation to instruct the start of measurement, for example, the operation of the release switch 108 which is one of the operation switches can be used. The user turns on the release switch 108 at the start of the “arm swinging operation”, and instructs the system controller to start gesture measurement. (FIG. 10 (a)). When this operation is detected, the routine proceeds to S152.

  In step S152, one of the display light emitting elements 348 is turned on to inform the user that the user's gesture is being measured.

  In step S154, the operation of the posture / motion detection circuit 320 is permitted, and a timer counter is set to permit the interrupt operation. For example, the timer counter is set so that an interrupt is generated every 1 msec. As a result, an interrupt is generated every 1 msec, and the interrupt processing routine “gesture detection 2” is called and executed. In the interrupt processing routine “gesture detection 2”, log data required for creating gesture pattern data is recorded based on the output of the posture / motion detection circuit 320.

  In step S156, the process waits until an operation for instructing the end of gesture measurement is performed. For this operation, for example, the operation of the release switch 108 which is one of the operation switches can be used. At the end of the “arm swinging operation”, the user turns on the release switch 108 and instructs the system controller to end the gesture measurement (FIG. 10C). When this operation is detected, the routine proceeds to S158.

  In step S158, the light-emitting display light emitting element 348 is turned off to notify that the measurement of the user's gesture has been completed.

  In step S160, the operation of the posture / body motion detection circuit 320 is prohibited (stopped), and the operation of the timer counter is stopped (interrupt operation is stopped).

  In step S162, it is determined whether the gesture detection operation has been performed a predetermined number of times. That is, it is determined whether the number of gesture detections has reached a predetermined value. When the number of gesture detections reaches a predetermined value, the routine proceeds to S164. If the number of gesture detections has not reached the predetermined value, the routine proceeds to S150. Even if the same gesture “arm swinging operation” is executed, the speed of movement is different. Accordingly, it is necessary to detect average gesture pattern data by detecting a plurality of times.

  In step S164, one of the display light emitting elements 348 blinks. This blinking indicates that the detection of the user's gesture has been completed. This blinking also indicates that gesture pattern data is being generated.

  In step S166, gesture pattern data is generated based on the log data recorded in the work area.

  For example, assume that log data of five gestures is measured. When log data (acceleration in one direction among the X-axis, Y-axis, and Z-axis directions) obtained by this measurement is plotted against time, a graph as shown in FIG. 11A is obtained. An average value of log data generated when performing gesture (“arm swinging operation”) is calculated from this graph and used as gesture pattern data (acceleration time dependency pattern). An allowable value is also calculated on the basis of the variation (for example, standard deviation σ) of five measurement values for the pattern data. For example, the upper limit is (average value + σ) and the lower limit is (average value−σ). The region defined by the calculated allowable value is a region sandwiched between the two broken lines in FIG. 11B, and is a band (band) centered on the average value. If there is log data of acceleration generated by the detected gesture in this region (band), the photographing operation is permitted. This calculation is performed on the acceleration output of each of the three acceleration sensor units. The band may have a width proportional to the standard deviation σ (a width corresponding to variation).

  In step S168, the allowable value calculated in step S166, that is, the band is stored in the FlashRom as “gesture registration pattern data”.

  In step S170, the blinking display light emitting element 348 is turned off. It turns out that registration of a user's gesture was complete | finished by this light extinction.

  FIG. 7 shows an interrupt routine “gesture detection 2” executed by the system controller. An interrupt signal “gesture detection 2” is executed in synchronization with the interrupt signal by generating an interrupt signal at a predetermined cycle (for example, every 1 msec) using a timer included in the system controller.

  In step S220, the output (acceleration in three axes) of the posture / motion detection circuit 320 is measured using the AD converter 308 of the system controller 300.

  In step S222, the measured data is stored as log data in the work memory. The work memory is provided in a part of the SDRAM, for example.

  FIG. 12 is a diagram illustrating a support state of the camera 100 in the hands-free state. FIG. 12 shows a state in which the housing of the camera 100 is supported via the camera holder 500 attached to the right arm. The camera holder 500 is attached and fixed near the wrist of the user's forearm. The camera 100 is mounted and held on a camera holder 500. The camera 100 is fixed to the camera holder 500 so that the front faces almost the same side as the back of the hand. When the camera 100 is fixed in a state where the forearm is kept horizontal and the forearm is not twisted, the camera 100 assumes the same posture as when held in a normal position by holding it in the hand. The state shown in FIG. 9 is one of the support methods suitable for the camera of this embodiment.

  FIG. 13 shows a camera holder 500 that holds the camera 100 on the arm. The camera holder 500 includes a holder main body 502, arm bands 504a and 504b, and camera bands 506a and 506b. A camera receiving portion 508 is formed on the holder main body 502. The camera casing 100a is placed on the camera receiving portion 508 from the back of the camera 100. The camera casing 100a is fixed to the camera holder 500 with camera bands 506a and 506b. A hook-and-loop fastener (Velcro (trademark)) is attached to the camera bands 506a and 506b. The camera casing 100a is fixed by connecting the camera bands 506a and 506b on the front side of the camera. The camera casing 100a may be fixed by other methods.

  An arm receiving portion 512 is formed on the opposite side of the camera receiving portion 508. The arm receiving portion 512 is configured by a rubber or the like in which a curved surface substantially coinciding with the forearm is formed. The camera holder 500 is fixed to the forearm by joining the arm bands 504a and 504b.

-Effect-
According to the present embodiment, the system controller (control unit) 300 outputs to the output output by the posture / motion detection circuit (motion detection unit) 320 in accordance with the gesture performed by the user of the camera in the registration mode for registering the user's gesture. Register the output pattern based on this. The system controller (control unit) 300 determines that the output of the posture / motion detection circuit (motion detection unit) 320 matches the registered output pattern, and then determines whether the output of the posture / motion detection circuit (posture detection unit) 320 matches the output. When it is detected that the body 110a is in a predetermined posture, the photographing operation is permitted. Thereby, a camera can be image | photographed by the physical motion which a user desires in a hands-free state.

  The predetermined attitude of the casing is an attitude in which the absolute value of the angle θz1 between the major axis direction of the casing and the horizontal direction is smaller than the first predetermined value θth1, or the major axis direction of the casing and the gravity direction Is an attitude in which the absolute value of the angle θz2 is smaller than the second predetermined value θth2. Thereby, the photographing operation can be started at the normal position and the vertical position of the camera.

  The camera includes a display light emitting element 348 that emits light as a light emitting / sound generation unit or a speaker 328 that generates sound. When determining that the output of the motion detection unit matches the registered output pattern, the control unit causes the light emission / sound generation unit to emit light or sound in the first form. When the control unit further detects that the casing is in a predetermined posture, the control unit permits the light emission / sound generation unit to emit light or sound in the second form, and then permits the photographing operation. According to the first form, it is possible to notify the user that gesture has been detected, and according to the second form, it is possible to assist the user in setting the camera to a predetermined posture for photographing.

  Since the control unit stops the operation of the display unit in the shooting mode, the power consumption of the camera can be reduced. In the shooting mode, the control unit performs processing for preventing an image acquired by the shooting operation from being deteriorated due to shaking of the housing. As a result, a high-quality image can be acquired even in a shooting mode in which the housing is likely to be shaken in a hands-free state. In the shooting mode, since the sound generation unit generates a shooting operation sound during the shooting operation, the user can surely confirm whether or not the shooting operation has been performed. In the shooting mode, the control unit can reduce the power consumption of the camera if the rate at which the imaging unit acquires images is reduced.

  When the control unit generates an output pattern a predetermined number of times based on the output output from the motion detection unit, the control unit calculates a variation and an average for the output pattern generated a predetermined number of times, and the variation is centered on the average pattern. A band having a corresponding width is registered as an output pattern. Thereby, even if a user's gesture has dispersion | variation, a user's average gesture can be registered. When the output of the motion detection unit enters the band, the control unit determines that the output of the motion detection unit matches the registered output pattern, so that the camera can appropriately perform a photographing operation according to the body motion desired by the user. it can.

[Modification 1]
In the above embodiment, the display operation of the imaging unit 370 is stopped before and after the operation of capturing a still image. However, the following modifications are possible.

  In order to photograph a still image, photographing preparation operations such as AF (focus adjustment operation) and AE (photometry operation) are required in advance. In order to immediately shoot when the shooting operation is permitted, it is desirable to always perform these shooting preparation operations. That is, it is desirable not to stop the operation of the imaging unit 370 in order to reduce the time lag (delay) of the shooting operation. For this reason, step S108 (and S144) is omitted, and the display operation is continued even in the hands-free state.

  However, reducing power consumption must be considered. Accordingly, in consideration of the fact that the live view operation is not particularly necessary in the hands-free state, the operation speed of the image capturing unit 370 (the rate at which image data is acquired from the image capturing unit) is reduced. By reducing the operation speed of the image capturing unit 370, it is possible to reduce the power consumption as compared to during normal camera operation.

[Modification 2]
In the above-described embodiment, the system controller 300 registers the time-dependent pattern of the acceleration of the housing as the gesture pattern data (that is, the motion pattern data of the camera housing by the gesture), and acquires the acquired acceleration of the housing. The log data (history data) was compared with the registered pattern.

  However, the system controller 300 may register a case speed pattern (speed time dependency) as gesture pattern data, and compare the acquired case speed log data with the registered pattern. In this case, the system controller 300 may calculate the speed from the acceleration, and the camera 100 may include a speed sensor as appropriate. Further, instead of the acceleration pattern, an angular velocity pattern can be used as the motion pattern.

  It should be noted that the present invention is not limited to the above-described embodiments and modifications, and it is obvious that various modifications can be made within the scope of the technical idea.

100 Digital Camera 100a Case 132 Touch Panel Display (Display Unit)
300 System controller (control unit)
320 Posture / Motion Detection Circuit (Posture / Motion Detection Unit)
328 Speaker (sound generator)
348 Light-emitting element for display (light-emitting part)

Claims (10)

A digital camera having a housing,
An attitude detection unit for detecting the attitude of the housing;
A motion detector for detecting motion generated in the housing;
In the registration mode for registering the user's gesture, an output pattern is registered based on the output output by the motion detection unit according to the gesture performed by the user of the camera,
A control unit that compares an output of the motion detection unit and a registered output pattern in a shooting mode in which a shooting operation is possible according to a gesture performed by a user;
When the control unit determines that the output of the motion detection unit matches the registered output pattern, and detects that the housing is in a predetermined posture from the output of the posture detection unit, the photographing operation A digital camera characterized by allowing   The predetermined attitude of the casing is an attitude in which the absolute value of the angle between the major axis direction of the casing and the horizontal direction is smaller than a first predetermined value, or the major axis direction of the casing and gravity 2. The digital camera according to claim 1, wherein the absolute value of the angle between the directions is smaller than the second predetermined value. Has a light emitting / sounding part that emits light
When the control unit determines that the output of the motion detection unit matches the registered output pattern, the control unit causes the light emission / sound generation unit to emit light or sound in the first form, and the casing is in a predetermined posture. 2. The digital camera according to claim 1, wherein when the detection is detected, the photographing operation is permitted after the light emission / sound generation unit emits light or sounds in the second form. A display unit for displaying images;
The digital camera according to claim 1, wherein in the shooting mode, the control unit stops the operation of the display unit.   The digital camera according to claim 1, wherein the control unit performs processing for preventing an image acquired by the shooting operation from being deteriorated due to blurring of the housing in the shooting mode. It has a sound generator that generates shooting action sound,
The digital camera according to claim 1, wherein the control unit is configured to cause the sound generation unit to generate the shooting operation sound during a shooting operation in the shooting mode. A display unit for displaying an image acquired by the imaging unit;
The digital camera according to claim 1, wherein the control unit lowers a rate at which the imaging unit acquires an image in the shooting mode.   When the control unit generates an output pattern a predetermined number of times based on the output output from the motion detection unit, the control unit calculates a variation and an average for the output pattern generated the predetermined number of times, and centers the average pattern The digital camera according to claim 1, wherein a band having a width corresponding to the variation is registered as an output pattern.   The digital camera according to claim 8, wherein the control unit determines that the output of the motion detection unit matches the registered output pattern when the output of the motion detection unit enters the band. A control method for controlling a digital camera having a housing,
A posture detecting step for detecting the posture of the housing;
A motion detection step for detecting motion generated in the housing;
In the registration mode for registering the user's gesture, registering an exercise pattern based on the exercise detected in the exercise detection step according to the gesture performed by the user of the camera,
A control step of comparing the motion detected in the motion detection step with the registered motion pattern in a shooting mode in which a shooting operation is possible according to a gesture performed by a user;
In the control step, it is determined that the motion detected in the motion detection step matches the registered motion pattern, and it is detected from the detection result in the posture detection step that the casing is in a predetermined posture. And a control method, wherein a photographing operation is permitted.

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