JP2006325075A - Camera-shake detection apparatus and photographing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology of executing a camera-shake correction always with accuracy in a photographing state while suppressing the power consumption. <P>SOLUTION: A camera is provided with gyro sensors 20A, 20B with a sleep mode function, and high pass filters 22A, 22B. When a photographing setting mode is set, the gyro sensors 20A, 20B are set to a sleep mode ON state. When the mode is switched into a moving picture display mode, the camera sets the gyro sensors 20A, 20B to a sleep mode OFF state. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a camera shake correction mechanism provided in a photographing apparatus such as a camera, and more particularly to a camera shake detection process.

  A camera with a camera shake correction function is provided with a camera shake detector such as a gyro sensor. When the camera body yaws or pitches due to camera shake during camera operation, the gyro sensor detects an angular velocity caused by a change in the posture of the camera. Then, in order to prevent image blurring, the optical system or the image sensor shifts so as to cancel the movement of the camera due to camera shake. When a gyro sensor is used, an output voltage from the gyro sensor is input to a high-pass filter in order to cut a DC component due to drift (see, for example, Patent Documents 1 and 2).

In a camera with a camera shake correction function, camera shake correction is always executed while the camera shake correction mode is set. However, camera shake correction can be stopped under certain conditions. For example, the operation / stop of the shake correction mechanism can be switched in accordance with the use of the eyepiece finder or the liquid crystal monitor in the photographing mode state (see Patent Document 3).
Japanese Patent Laid-Open No. 9-247520 JP 2003-57706 A JP 2002-156675 A

  For displays other than moving images, such as playback image display or shooting condition setting screen display, power is supplied to the gyro sensor and camera shake correction mechanism without the need to perform camera shake correction, resulting in wasted power consumption. Yes. However, if the power supply to the gyro sensor is stopped during the screen display other than the moving image, the camera shake cannot be detected quickly due to the characteristics of the gyro sensor when switching to the moving image display. The camera shake correction does not work with high accuracy.

  The photographing apparatus of the present invention is a photographing apparatus such as a digital camera, a movie camera, or a portable terminal / mobile phone having a photographing function, which has a photographing optical system and a recording means for recording a subject image formed by the photographing optical system. It is. Further, the photographing apparatus includes a moving image display unit that displays a subject image formed by the photographing optical system in real time and a non-moving image display unit that displays a screen other than the real time moving image. Here, the screen display other than the moving image is not related to the recording of the subject image to be shot, the confirmation of the composition, etc., such as the display of the playback record image, the display of the shooting condition setting screen such as the menu screen, etc. Means screen display.

  An imaging device includes an angular velocity sensor that outputs an angular velocity signal corresponding to an angular velocity caused by camera shake, a detection unit that detects camera shake based on a voltage value and a reference voltage value of the angular velocity signal, a control unit, and a displacement amount due to camera shake. And a camera shake correction means for adjusting an image formation area by the photographing optical system so as not to cause image blur. For example, when the angular velocity sensor outputs a voltage signal and a high-pass filter that removes a DC component from the angular velocity signal from the angular velocity sensor is provided, the voltage signal from which the DC component has been removed is detected from the high-pass filter. The angular velocity sensor is, for example, a gyro sensor, and it is preferable to apply a vibration gyro sensor using a crystal of quartz in order to detect camera shake with high accuracy. When the angular velocity is detected, a fluctuation angular velocity due to a posture variation of a photographing apparatus such as a camera is detected as a camera shake based on the voltage value of the angular velocity signal and the reference voltage. The reference voltage is a value serving as a reference for the voltage value of the angular velocity signal, and is output from the angular velocity sensor in the gyro sensor. For example, an amplifier may be connected after the high-pass filter. The camera shake correction unit may adjust the position of the imaging area corresponding to the image circle in accordance with the camera shake, and may be configured to shift the optical system or the image sensor in the direction perpendicular to the optical axis.

  The angular velocity sensor of the present invention is a sensor that can be switched from an operation state to an operation stop state. When the angular velocity sensor enters an operation stop state, the voltage value of the angular velocity signal becomes the same as the reference voltage value. Here, the operation stop state indicates a state where the function of measuring the angular velocity cannot be exhibited, and electric power necessary for realizing the function again is supplied to the angular velocity sensor. As the angular velocity sensor having the above characteristics, for example, an angular velocity sensor capable of executing the sleep mode may be applied. When the sleep mode is set, power supply to some modules of the angular velocity sensor such as the sensor element and the amplifier is cut off, and an angular velocity signal based on the reference voltage is output.

  For such an angular velocity sensor, the control means selectively outputs an operation signal for operating the angular velocity sensor and an operation stop signal for causing the operation to be stopped. Then, the control unit stops the angular velocity sensor during the screen display other than the real-time moving image, and operates the angular velocity sensor when the real-time moving image is displayed.

  While power is supplied to the shake detection component, the angular velocity sensor always outputs a signal, but when the angular velocity sensor is deactivated, an angular velocity signal whose voltage value matches the reference voltage is output from the angular velocity sensor. Is done. In the case of the angular velocity sensor capable of setting the sleep mode, the signal output based on the reference voltage value is maintained by cutting off the power supply to some modules of the angular velocity sensor such as the sensor element and the amplifier. During the display of a screen other than a moving image, the angular velocity signal is constant, and the angular velocity sensor supplies only the minimum necessary elements, so that power consumption until the photographing operation is performed can be suppressed. When the display is switched to the moving image display, the output signal from the angular velocity sensor or the high-pass filter is stabilized, so that the moving image can be confirmed without image blurring. In addition, even if a shooting operation is performed immediately, camera shake correction can be performed with high accuracy.

  The camera shake detection device of the present invention outputs an angular velocity signal corresponding to the angular velocity caused by the camera shake and can be switched to an operation stop state, and detection means for detecting camera shake based on the voltage value and the reference voltage value of the angular velocity signal. And a control means for selectively outputting an operation signal for operating the angular velocity sensor and an operation stop signal for causing the angular velocity sensor to be in an operation stop state, and the voltage value of the angular velocity signal is the value of the reference voltage in the operation stop state of the angular velocity sensor. In the same manner, the control means stops the angular velocity sensor during the screen display other than the real-time moving image, and operates the angular velocity sensor when the real-time moving image is displayed.

  The camera shake detection method of the present invention detects the camera shake based on the voltage value of the angular velocity signal corresponding to the angular velocity caused by the camera shake and the reference voltage value output from the angular velocity sensor that can be switched to the operation stop state, and operates the angular velocity sensor. The operation signal to be operated and the operation stop signal to be in the operation stop state are selectively output, and the voltage value of the angular velocity signal becomes the same as the reference voltage value in the operation stop state of the angular velocity sensor, and the real-time moving image During the screen display other than the above, the angular velocity sensor is stopped and the angular velocity sensor is operated when a real-time moving image is displayed.

  The program of the present invention includes a detecting means for detecting camera shake based on a voltage value and a reference voltage value of an angular velocity signal corresponding to an angular velocity caused by camera shake output from an angular velocity sensor that can be switched to an operation stop state, and an angular velocity sensor. A program for causing an operation signal to be operated and a control means for selectively outputting an operation stop signal to be in an operation stop state, wherein the voltage value of the angular velocity signal is the same as the reference voltage value in the operation stop state of the angular velocity sensor Thus, during the display of the screen other than the real-time moving image, the angular velocity sensor is stopped, and when the real-time moving image is displayed, the control means is caused to function.

  According to the present invention, it is possible to always perform camera shake correction with high accuracy in a shooting situation while suppressing power consumption.

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

  FIG. 1 is a schematic perspective view of a camera according to the first embodiment. FIG. 2 is a front view of the camera.

  The camera 10 is a digital camera having a camera shake correction function, and a camera shake correction mechanism 12 is provided behind the lens barrel 11 inside the camera body. A release button 13 and a camera shake correction button 16 are provided on the camera top surface 10U side, and an LCD 17 and a main power button 18 are provided on the camera back surface 10B. Further, on the camera rear surface 10B, a moving image display mode for displaying a subject image as a moving image in real time on the LCD 17, a mode switching button 15 for switching a shooting setting mode for setting shooting conditions and the like, and shooting conditions and the like are set. The cross button and the execution button (both not shown) are provided.

  Gyro sensors 20A and 20B as angular velocity sensors for detecting camera shake are provided inside the camera body, and the gyro sensors 20A and 20B detect angular velocities when the camera 10 yaws and pitches, respectively. However, the horizontal movement of the optical axis E of the photographing optical system (not shown) in the lens barrel 11, that is, the angle with respect to the X direction is yawing, and the vertical movement of the camera 10 perpendicular to the optical axis E, that is, The angle with respect to the Y direction is defined as pitching. The XY plane is perpendicular to the optical axis E, and the Z direction corresponds to the optical axis direction. The X and Y directions correspond to the horizontal direction and vertical direction of the camera 10, respectively. When the camera 10 is in the horizontal posture state, the X direction is a horizontal plane, and the Y direction is a direction along the vertical direction.

  FIG. 3 is a block diagram of the camera 10.

  A system control circuit 25 including a CPU controls the camera 10 and stores a program for executing processing operations of the entire camera in a ROM (not shown). Release switch 13A, camera shake correction switch 16A, main power switch 18A, release half-press switch mode changeover switch, cross button setting switch, execution button setting switch (both not shown), etc. are connected to system control circuit 25, and main power button When the main power switch 18A is turned on by an operation on the power supply 18, power is supplied to each circuit. Here, either the moving image mode or the shooting setting mode is selected and set.

  When the shooting mode is set, a processing operation for displaying a moving image is executed. Light passing through the photographing optical system reaches the CCD 21 via a lens shutter (not shown), and a subject image is formed on the light receiving surface of the CCD 21. In the CCD 21, an analog image signal corresponding to the subject image is generated by photoelectric conversion, and the image signal is sequentially read from the CCD 21 at predetermined time intervals by a CCD drive circuit (not shown). The analog image signal read from the CCD 21 is amplified and sent to the signal processing circuit 23.

  In the signal processing circuit 23, the analog image signal is converted into a digital signal, and various processes such as a white balance adjustment process and a gamma correction process are performed on the digital image signal. The processed image signal is temporarily stored in a frame memory (not shown) and sent to the LCD driver 26. The LCD driver 26 drives the LCD 17 based on the image signal. As a result, the subject image is displayed as a moving image on the LCD 17 provided on the back of the camera.

  In the AE block 27, the brightness of the subject is detected based on the image signal read from the CCD 21, and in the signal processing circuit 23, the brightness of the moving image is adjusted based on the detected brightness. In the AE block 27, the shutter speed and the exposure value of the aperture value are calculated in accordance with the setting operation related to the exposure and image quality by the user. When the release button 13 is half-pressed, the distance from the subject is detected by the AF sensor 28. A focusing lens (not shown) in the photographing optical system is driven by the AF driving unit 30 for focus adjustment.

  When the release button 13 is fully pressed, a photographing operation is executed. That is, based on the calculated exposure value, the aperture is controlled to have a predetermined aperture diameter, the shutter is opened at a predetermined opening for a predetermined period, and an image signal corresponding to the subject image is output from the CCD 21. Read out. The read image signal is processed by the signal processing circuit 23 and stored in a memory card (not shown) via the system control circuit 25. The shutter operation and aperture drive control are controlled by the exposure control unit 29.

  When the camera shake correction button 16 is pressed, the camera shake correction switch 16A is turned on, and an operation signal for executing camera shake correction is detected by the system control circuit 25. The camera shake detection unit 20 includes gyro sensors 20A and 20B, high-pass filters 22A and 22B, and amplifiers 24A and 24B, and detects an angular velocity when the camera posture changes due to camera shake as a voltage.

  The camera shake correction mechanism 12 includes a rectangular moving stage 33 in which the CCD 21 is mounted near the center, and a rectangular fixed stage 35 that faces the moving stage 33 in a state of being close to the moving stage 33. A support (not shown) is provided to support the. The fixed stage 35 is formed with an opening through which the light passing through the lens barrel 11 passes. The size of the opening is determined according to the movement range of the CCD 21.

  The moving stage 33 can move independently along the X and Y directions by driving a coil (not shown), and the system control circuit 25 calculates the displacement angle of the camera 10 based on the detected angular velocity. Then, the camera shake correction mechanism 12 is controlled via the stage drive circuit 38.

  More specifically, when the posture of the camera 10 fluctuates (yawing or pitching movement) due to a user's hand shake, a voltage signal (angular velocity signal) corresponding to the angular velocity of yawing or pitching is output from the gyro sensors 20A and 20B. The output voltage signals have their DC components removed by the high-pass filters 22A and 22B, respectively, and are amplified by the amplifiers 24A and 24B. When the amplified voltage signal is input to the system control circuit 25, a displacement angle corresponding to the fluctuation amount of the camera 10 is detected. Then, a control signal is output from the system control circuit 25 to the stage drive circuit 38 so as to cancel image blur due to camera shake, and the moving stage 33 moves in the X direction and the Y direction. As a result, an image by the photographing optical system is formed at a position relatively shifted along the light receiving surface of the CCD 21, and an image without image blur is formed on the CCD 21.

  Magnetic sensors 34A and 34B such as Hall elements are arranged around the CCD 21 of the moving stage 33 along the X direction and the Y direction. On the other hand, on the fixed stage 35, magnets 36A and 36B are arranged along the X and Y directions so as to face the magnetic sensors 34A and 34B. When the hand movement is detected and the moving stage 33 moves, the magnetic sensors 34A and 34B detect magnetic field changes according to changes in the relative positions with respect to the magnets 36A and 36B, and the magnetic sensor signal processing circuits 40A and 40B move. The amount of movement of the stage 33 in the X and Y directions is detected. The system control circuit 25 feedback-controls the moving stage 33 based on the difference between the current relative position of the moving stage 33 and the set position.

  FIG. 4 is a diagram illustrating an equivalent circuit of the camera shake detection unit 20. The gyro sensor 20B, the high pass filter 22B, and the amplifier 24B have the same configuration.

The high pass filter 22A includes a capacitor 51 having a capacitance C and a resistor 52 having a resistance value R, and one end of the capacitor 51 and one end of the resistor 52 are connected to the gyro sensor 20A. A voltage V ₀ corresponding to the angular velocity of the camera 10 is output to the capacitor 51 side, and a reference voltage V _ref is output to the resistor 52 side. The amplifier 24A includes an operational amplifier 53 and resistors 54 and 55 having resistance values Rf and Rs, respectively. The time constant τ (= CR) of the high-pass filter 22A is set to a relatively large value so that low-frequency camera shake can be detected.

The gyro sensor 20A is a vibration gyro sensor using a crystal of crystal, and is configured to be able to execute a sleep mode. A control signal for setting the sleep mode to ON / OFF is transmitted from the system control circuit 25 to the terminal S1 of the gyro sensor 20A. When the sleep mode is set to ON, power is not supplied to elements essential for detecting angular velocity, such as a sensor element and an amplifier (none of which are shown) in the gyro sensor 20A, while the sleep mode is set to OFF. Power is supplied to the elements necessary for switching. While the sleep mode is set to ON, the voltage V ₀ output to the capacitor 51 matches the reference voltage V _ref .

  FIG. 5 is a flowchart showing the shooting operation process of the camera 10. FIG. 6 is a diagram showing a variation process (state transition) of the voltage output from the high-pass filter 22A. FIG. 7 is a timing chart of the photographing operation process.

  In step S101, the CCD 21 and the photographing optical system are initialized. In step S102, an interrupt process for executing the camera shake correction process is set as a timer. In step S103, it is determined whether or not a shooting setting mode is set. The shooting setting mode is set by operating the mode switching button 15.

  If it is determined in step S103 that the release correction mode is set, the process proceeds to step S104, and the sleep mode of the gyro sensors 20A and 20B is set to ON.

In FIG. 6, the voltage Vs (voltage at point B in FIG. 4) output from the high-pass filter 22A immediately after the shooting setting mode is set is shown over time (the same applies to the high-pass filter 22B). When the sleep mode is set to ON, the output voltage V ₀ from the gyro sensor 20A matches the reference voltage V _ref as described above. Therefore, an excessive state is started from when the sleep mode is set to ON until the output voltage is stabilized according to the time constant τ of the high-pass filter 22A. When the predetermined time elapses, the output voltage is substantially stabilized and the DC component is removed.

  In step S105, a shooting setting screen for setting an exposure value, white balance, the number of pixels, and the like is displayed on the LCD 17. In step S106, a selection process or a setting process such as a shooting condition is executed in accordance with an operation on the cross button and the execution button. When step S106 is executed, the process proceeds to step S108.

  On the other hand, if it is determined in step S103 that the shooting setting mode is not set, that is, the moving image mode, the process proceeds to step S107, and the sleep mode of the gyro sensors 20A and 20B is set to OFF. When step S107 is executed, the process proceeds to step S108. Note that power is always supplied to the camera shake correction mechanism while the main power is on.

  In step S108, it is determined whether or not the camera shake correction switch 16A is in the ON state. If it is determined that the camera shake correction switch 16A is in the ON state, the process proceeds to step S109, and the camera shake correction variable IS is set to “1”. On the other hand, if it is determined that the camera shake correction switch 16A is not in the ON state, the process proceeds to step S110, and the camera shake correction variable IS is set to “0”. The camera shake correction variable IS is a variable indicating whether or not the camera shake correction mode is set. When the camera shake correction switch 16A is set to ON, IS = 1 is set, and the camera shake correction switch 16A is not set to ON. In this case, IS = 0 is set.

  In step S111, photometry is performed in the AE block 27, and the brightness adjustment process of the subject is executed. In step S112, a moving image display process is executed. In step S113, it is determined whether or not the release button 13 is half-pressed and the release half-press switch is in an ON state. If it is determined that the release button 13 is not half-pressed, the process returns to step S103. On the other hand, if it is determined that the release button 13 is half-pressed, the process proceeds to step S114, and focus adjustment processing is executed.

  In step S115, it is determined whether or not the release button 13 is fully pressed and the release switch 13A is in the ON state. If it is determined that the release switch 13A is not in the ON state, the process returns to step S103. On the other hand, if it is determined that the release switch 13A is in the ON state, the process proceeds to step S116, and a still image shooting operation is performed. That is, the aperture and shutter are driven based on the calculated exposure value to perform exposure control on the light receiving surface of the CCD 21, and then signal charges are read from the CCD 21, and predetermined processing is performed to generate still image data. Is done. In step S116, a recording process is executed.

  FIG. 7 shows a timing chart while the shooting setting mode is set. As described above, the DC components from the high-pass filters 22A and 22B are removed while the gyro sensors 20A and 20B are set to the sleep mode ON. Therefore, when the sleep mode is set to OFF for moving image display processing, the angular velocity signal detected immediately after that indicates the angular velocity due to camera shake, and camera shake correction is executed based on the detected angular velocity signal. In addition, in the period T1 in which the sleep mode is ON, power consumption for the gyro sensors 20A and 20B is reduced.

  FIG. 8 is an interrupt routine showing a camera shake correction process. The camera shake correction process is performed by interrupting the shooting operation process of FIG. 5 at intervals of 1 millisecond [mS].

  In step S201, the angular velocity with respect to the pitching of the camera 10 is detected based on the output voltage from the gyrometer 20A. In step S202, the X direction from the center position of the CCD 21 is detected based on the detection signal sent from the magnetic sensor 34A. A relative position along is detected. However, here, the position when the center of the CCD 21 is on the optical axis E is defined as the center position.

  In step S203, it is determined whether or not the camera shake correction variable IS = 1, that is, whether or not the camera shake correction mode is set. If it is determined that the camera shake correction variable IS = 0, that is, the camera shake correction mode is not set, the process proceeds to step S205, and the position of the CCD 21 is determined as the center position. On the other hand, if it is determined that the camera shake correction variable IS = 1, the process proceeds to step S204. In step S204, the displacement angle due to camera shake of the camera 10 is calculated. Based on the detected angular velocity, the attitude displacement angle of the camera 10 is calculated. Based on the attitude displacement angle of the camera 10, the position (set position) of the CCD 21 to be moved is calculated using a conversion coefficient according to characteristics such as the focal length. The control system using the camera shake correction mechanism has a response characteristic that automatically returns the position of the CCD 21 to the center position when the camera shake amount value “0” continues. As conventionally known, a loop with a predetermined time constant is inserted between the PID control block and the fluctuation amount (angle) calculation block due to camera shake of the camera 10 for stabilization.

  In step S206, the operation amount of the moving stage 33 is calculated based on the calculated setting position of the CCD 21 and the current position of the CCD 21 detected by the magnetic sensor 34A. In step S207, the moving stage 33 is moved by a predetermined distance based on the drive signal from the stage drive circuit 38 based on the calculated operation amount. Here, PID control is executed as feedback control.

  Although FIG. 8 shows a camera shake correction processing routine for yawing, the same camera shake correction processing is executed for pitching.

As described above, according to the present embodiment, the gyro sensors 20A and 20B and the high-pass filters 24A and 24B are provided in the camera 10, and the gyro sensors 20A and 20B have a sleep mode function. When the shooting setting mode is set, the gyro sensors 20A and 20B are set to the sleep mode ON. As a result, the same voltage V ₀ as the reference voltage V _ref is output from the gyro sensors 20A and 20B to the high-pass filters 22A and 22B, and the DC component of the output voltage is removed. When the mode is switched to the moving image display mode, the gyro sensors 20A and 20B are set to the sleep mode OFF.

  The gyro sensors 20A and 20B may be angular velocity sensors such as a piezoelectric vibrator gyro sensor. Further, it is possible to set a mode other than the shooting setting mode (recording image mode or the like), and in that mode, the gyro sensors 20A and 20B may be set to the sleep mode ON. A configuration without a high-pass filter may be used.

It is a schematic perspective view of the camera which is 1st Embodiment. It is a front view of a camera. It is a block diagram of a camera. It is the figure which showed the equivalent circuit of the camera-shake detection part (gyro sensor, high pass filter, amplifier). It is the flowchart which showed the imaging | photography operation process of the camera. It is the figure which showed the fluctuation process (state transition) of the voltage output from a high pass filter. It is a timing chart of imaging operation processing. It is an interruption routine showing camera shake correction processing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Camera 15 Mode switching button 20 Camera shake detection part 20A, 20B Gyro sensor (angular velocity sensor)
21 CCD
22A, 22B High-pass filter 25 System control circuit 33 Moving stage V ₀ output voltage V _ref reference voltage

Claims (6)

Photographic optics,
Recording means for recording a subject image formed by the photographing optical system;
Moving image display means for displaying a subject image formed by the photographing optical system in real time;
A non-video display means for displaying non-real-time moving images on the screen;
An angular velocity sensor that outputs an angular velocity signal corresponding to the angular velocity caused by camera shake and can be switched to an operation stop state;
A high-pass filter that removes a DC component from the angular velocity signal from the angular velocity sensor;
Detecting means for detecting a displacement due to camera shake based on the voltage value of the angular velocity signal and the reference voltage value;
Control means for selectively outputting an operation signal for operating the angular velocity sensor and an operation stop signal for setting the operation stop state;
A camera shake correction unit that adjusts an imaging area formed by the photographing optical system so as not to cause image blur based on a displacement amount due to the camera shake;
The voltage value of the angular velocity signal is the same as the reference voltage value in the operation stop state of the angular velocity sensor,
An imaging apparatus, wherein the control means stops the angular velocity sensor during a screen display other than a real-time moving image, and operates the angular velocity sensor when a real-time moving image is displayed.   The photographing apparatus according to claim 1, wherein the angular velocity sensor is configured to be able to execute a sleep mode.   The photographing apparatus according to claim 1, wherein the angular velocity sensor is a vibration gyro sensor using a crystal of crystal. An angular velocity sensor that outputs an angular velocity signal corresponding to the angular velocity caused by camera shake and can be switched to an operation stop state;
Detection means for detecting camera shake based on the voltage value of the angular velocity signal and the reference voltage value;
Control means for selectively outputting an operation signal for operating the angular velocity sensor and an operation stop signal for causing the angular velocity sensor to be in an operation stop state;
The voltage value of the angular velocity signal becomes the same as the value of the reference voltage in the operation stop state of the angular velocity sensor,
The camera shake detection device characterized in that the control means stops the angular velocity sensor during a screen display other than a real-time moving image, and operates the angular velocity sensor when a real-time moving image is displayed. The camera shake is detected based on the voltage value of the angular velocity signal corresponding to the angular velocity caused by the camera shake and the reference voltage value output from the angular velocity sensor that can be switched to the operation stop state.
A method of selectively outputting an operation signal for operating the angular velocity sensor and an operation stop signal for causing the angular velocity sensor to stop operating,
The voltage value of the angular velocity signal is the same as the reference voltage value in the operation stop state of the angular velocity sensor,
A camera shake detection method, wherein the angular velocity sensor is stopped during a screen display other than a real-time moving image, and the angular velocity sensor is operated when a real-time moving image is displayed. Detecting means for detecting camera shake based on the voltage value and the reference voltage value of the angular velocity signal corresponding to the angular velocity caused by the camera shake output from the angular velocity sensor that can be switched to the operation stop state;
A program for functioning an operation signal for operating the angular velocity sensor and a control means for selectively outputting an operation stop signal for setting the operation stop state,
The voltage value of the angular velocity signal is the same as the reference voltage value in the operation stop state of the angular velocity sensor,
A program for causing the control means to function so that the angular velocity sensor is stopped during a screen display other than a real-time moving image, and the angular velocity sensor is operated when a real-time moving image is displayed. .

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