JP2011139353A - Imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform photographing without fail even while a photographer is under the situation different from usual. <P>SOLUTION: An imaging apparatus includes: an imaging part 27 which can capture a motion image and a still image; and a control part 44 which is connected to a detection device 6 for detecting camera shake and performs first camera shake control corresponding to the motion image and second camera shake control, different from the first camera shake control, corresponding to the still image. The control part changes each of the first camera shake control and the second camera shake control in accordance with a change in biological information of a photographer detected by biological sensors 8, 16. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an imaging apparatus that performs imaging using biological information.

  In recent years, it has been proposed to detect a photographer's biological condition and perform imaging with bright image quality when the photographer is happy or perform imaging with dark image quality when sad. In addition, it has been proposed to change the blur correction amount of the imaging apparatus between when the photographer is stationary and when the photographer is running (see, for example, Patent Document 1).

JP 2008-122485 A

  However, in the conventional imaging apparatus, there has been no proposal to perform shooting definitely when the photographer is in an unusual state.

  An object of the present invention is to provide an imaging apparatus that can definitely perform shooting even when a photographer is in an unusual state.

  The imaging device of the present invention is connected to an imaging unit capable of capturing moving images and still images, and a detection device that detects camera shake, and corresponds to the first camera shake control corresponding to the moving images, the still image, and the first A control unit that performs a second camera shake control different from the camera shake control, and the control unit performs the first camera shake control and the second camera shake control according to a change in the photographer's biometric information detected by the biosensor. It is characterized by changing each control.

  The imaging apparatus of the present invention includes an imaging unit that can capture a moving image and a still image using an optical system, and a control unit connected to a detection device that detects camera shake, and the control unit includes a biological sensor. A first correction unit that corrects camera shake using a part of the optical system according to a change in the photographer's biological information detected by the above and a second correction unit that is different from the first correction unit are used in combination. It is characterized by performing camera shake control.

  Further, the imaging apparatus of the present invention includes the imaging unit that performs imaging, the change unit that can change the setting of the detection device that detects camera shake, and the change according to a change in the photographer's biological information detected by the biological sensor. And a control unit that controls the setting unit to change the setting of the detection apparatus.

  In addition, the imaging apparatus of the present invention includes an imaging unit that performs imaging and a control unit that is connected to a detection device that detects camera shake, and the control unit changes the biometric information of the photographer detected by the biosensor. Accordingly, the camera shake of the camera shake detected by the detection device whose amplitude exceeds a predetermined value is corrected.

  According to the present invention, it is possible to surely take a picture even when the photographer is in an unusual state.

It is a figure which shows the outline | summary of the camera system which concerns on embodiment. It is the figure which looked at the camera system which concerns on embodiment from the top. It is a figure which shows the state which hold | maintained the imaging lens which concerns on embodiment with the left hand. It is a figure which shows the state which hold | maintained the imaging lens which concerns on embodiment with the left hand. It is a figure which shows the biometric information detection part provided in the camera main body which concerns on embodiment. It is a figure which shows the structure of the biometric information detection part provided in the camera main body which concerns on embodiment. 1 is a block diagram of a camera system according to an embodiment. It is a flowchart which shows the detection process of a photographer's biometric information, and the setting of imaging conditions which concern on embodiment.

  A camera system according to an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram illustrating an outline of a camera system according to an embodiment, and the camera system 1 is a single-lens reflex camera system with an interchangeable lens.

  The camera system 1 includes a camera body 2 and a replaceable photographing lens 3. The photographing lens 3 includes a lens group 4 including a focus lens, a zoom lens, and an anti-vibration lens, a driving device (not shown) that drives the diaphragm 5 and the lens group 4, and an angular velocity sensor 6 for detecting camera shake of the camera system 1. have. Here, the angular velocity sensor 6 has a gyro sensor for detecting biaxial shake. The above-described drive device (not shown) has a plurality of motors (for example, a vibration wave motor and a VCM), drives the focus lens in the optical axis direction, and drives the anti-vibration lens in a direction different from the optical axis direction. . The taking lens 3 has a lens CPU 7 that controls the entire taking lens 3 and cooperates with the camera body 2.

  FIG. 2 is a view of the camera system 1 as viewed from above, and shows a state in which the camera body 2 is held by the operator's right hand and the photographing lens 3 is held by the left hand. As shown in FIG. 2, the photographic lens 3 detects the photographer's heart rate, blood flow, blood pressure, perspiration, body temperature, and pressure for holding the photographic lens 3 at a position where the photographer's left hand finger or palm touches. Lens-side biosensor unit 8 (8A to 8D) (see FIGS. 3, 4 and 7). The lens-side biosensor unit 8 includes a plurality of electrode units 9 (reference electrode 9a and detection electrode 9b) separated from each other, a plurality of light emitting units 10a to 10d, and a plurality of light receiving units 11a to 11d, and a pulse wave. Has a pulse wave detection device 12 for detecting. The pulse wave detection device 12 is used to measure the blood flow and blood pressure of the photographer as will be described later. As shown in FIG. 2, the light emitting units 10a to 10d and the light receiving units 11a to 11d are alternately arranged. Has been.

  The lens-side biosensor unit 8 includes a sweat sensor 13 that detects the amount of sweat of the photographer, a temperature sensor 14 that detects the body temperature of the photographer, and a pressure sensor 15 that detects the pressure at which the photographer holds the photographing lens 3. (Refer to FIG. 3 and FIG. 4). When the photographer holds the photographing lens 3 and performs a zoom operation or a manual focus operation, the left thumb is separated from the other fingers. Therefore, the lens-side biosensor unit 8 is at least one of the zoom operation position and the manual focus operation position, and is separated from the position corresponding to the thumb of the left hand and the position corresponding to a finger other than the thumb. Is provided. More specifically, the lens-side biosensor unit 8 is provided at a position where a zoom operation rubber or a focus operation rubber is provided, and is provided so as to contact the left hand or to face the left hand. Yes.

  3 and 4 are views showing a state in which the photographing lens 3 is held by the left hand. FIG. 3 shows a state in which the photographing lens 3 is held with the back of the left hand on the lower side, and FIG. The state which hold | maintained the photographic lens 3 in the state in the left side is shown. Since the manner of holding the taking lens 3 varies depending on the photographer and the shooting state (for example, horizontal position shooting or vertical position shooting), a plurality of lens-side biosensors 8 (8A to 8D) are arranged on the circumference of the shooting lens 3. Provided. Here, the lens-side biosensor units 8B to 8D each have a plurality of electrode units 9, a pulse wave detection device 12, a sweat sensor 13, a humidity sensor 14, and a pressure sensor 15, similarly to the lens-side biosensor unit 8A. is doing. In this way, by providing a plurality of lens-side biosensors 8 (8A to 8D) on the circumference of the photographing lens 3, it is possible to detect biometric information from the palm of the left hand. As described above, in the present embodiment, the plurality of lens-side biosensors 8 (8A to 8D) are provided according to the zoom operation position and the manual focus operation position, but depending on the photographer and the shooting state. Thus, a plurality of lens-side biosensors may be provided at positions other than the above positions as long as the biometric information can be detected even when the manner of holding the photographing lens 3 is changed.

  In addition, since the force with which the thumb of the left hand holds the photographing lens 3 is not so large, the pressure sensor 15 corresponding to the thumb of the left hand may be omitted in the lens-side biosensor units 8B and 8C. Similarly, when it is not necessary to increase the detection accuracy of the lens-side biosensor unit 8, the number of parts of the photographing lens 3 can be suppressed by appropriately omitting the sensor at the position corresponding to the thumb of the left hand. Further, the lens CPU 7 may be controlled to emit light only when a finger is applied to the light emitting units 10 a to 10 d of the pulse wave detection device 12.

  Returning to FIG. 2, the camera body 2 according to the present embodiment is such that the photographer's heart rate, blood flow, blood pressure, perspiration, body temperature, pressure for holding the camera body 2, etc. It has a camera body side biosensor unit 16 for detecting. As shown in FIG. 5, the camera body-side biosensor unit 16 includes a plurality of electrode units 17 having the same configuration as the plurality of electrode units 9, and a pulse wave detection device 20 having the same configuration as the pulse wave detection device 12. have. That is, as shown in FIG. 6A, the plurality of electrode portions 17 have a plurality of reference electrodes 17a and detection electrodes 17b separated from each other. 6B, the pulse wave detection device 20 includes a plurality of light emitting units 18a to 18d and a plurality of light receiving units 19a to 19d to detect a pulse wave. The camera body-side biosensor unit 16 includes a sweat sensor 21 that detects the amount of sweat of the photographer, a temperature sensor 22 that detects the body temperature of the photographer, and a pressure sensor that detects the pressure at which the photographer holds the camera body 2. 23.

  As is clear from FIG. 2, when the photographer holds the camera body 2, the right thumb is positioned on the back of the camera body 2, the right index finger is positioned near the release SW 24, and the other It leaves with three fingers. Therefore, the camera body-side biosensor 16 is separated from the camera back position corresponding to the thumb of the right hand, the vicinity of the release SW 24, and the camera front position where the other three fingers hold the camera body 2. Is provided. In addition, you may provide the main body side biosensor part 16 in release SW24. Here, the camera body side biosensor unit provided at the camera back surface position and the camera front surface position has the same configuration as the camera body side biosensor unit 16 although not shown. In the camera body 2, at least one of the camera front surface position where the other three fingers hold the camera body 2 and the camera back surface position corresponding to the thumb of the right hand holds the camera body 2. It can be said. In addition, a number of operations SW are provided on the back of the camera body 2, and these operations SW are operated with the right thumb. Therefore, in the present embodiment, at least one of the SW operated by the thumb of the right hand, the release SW 24, and the power switch is an operation unit for operating the camera body 2. A shooting mode SW 25 for setting a shooting mode is provided on the upper surface of the camera body 2.

  Returning to FIG. 1, the camera body 2 includes a position (reflection position) that reflects the light beam from the photographing lens 3 and guides it to a finder optical system 26 described later, and the light beam from the photographing lens 3 is constituted by a CCD or a CMOS. A movable mirror 28 that is movable at a retreat position that is retracted so as to be incident on the imaging element 27, and a part of the movable mirror 28 is a semi-transmissive region. And a sub-mirror 30 that reflects to a focus detection sensor 29 that performs focus detection.

  The light beam reflected by the movable mirror 28 is guided to the finder optical system 26 via the focusing screen 31 and the pentaprism 32. The finder optical system 26 is composed of a plurality of lenses, and the photographer can check the object field with the finder optical system 26. On the other hand, when the movable mirror 28 is in the retracted position, the light beam from the photographing lens 3 enters the image sensor 27 via the low-pass filter 33. Here, an imaging substrate 34 is provided in the vicinity of the imaging element 27.

  FIG. 7 is a block diagram of the camera system 1. The description will be continued with reference to FIG. 7 in addition to FIG. The imaging substrate 34 includes a drive circuit 34A that drives the imaging device 27, an A / D conversion circuit 34B that converts the output of the imaging device 27 into a digital signal, an image processing control circuit 34C that includes an ASIC, and the like. The image processing control circuit 34C performs image processing such as white balance adjustment, sharpness adjustment, gamma correction, and gradation adjustment on the image signal converted into the digital signal, and also performs image compression such as JPEG. The compressed image is stored in the image recording medium 35, and an image (live view image) is displayed on the rear liquid crystal monitor 37 under the control of the rear liquid crystal monitor control circuit 36. The rear liquid crystal monitor control circuit 36 can also display an image (live view image) on a display unit (not shown) that displays information in the viewfinder field of view when the movable mirror 28 is in the retracted position.

  In addition, the imaging board 34 has a contrast AF circuit 34D that extracts a high-frequency component of a signal from the imaging device 27 and detects a focus lens position where the maximum is detected. An image signal from the image processing control circuit 34C is input to the contrast AF circuit 34D. The contrast AF circuit 34D extracts a predetermined high-frequency component from the imaging signal using a bandpass filter, performs detection processing such as peak hold and integration, generates an AF evaluation value signal, and outputs the AF evaluation value signal to the CPU 44.

  In addition, audio collected by a microphone 42, which will be described later, is attached to the above-mentioned live view image, and MPEG or H.264 is added. A moving image can be generated by performing a process such as H.264. For example, 30 fps can be set as the frame rate of the moving image.

  As described above, the lens CPU 7 drives the image stabilizing lens in the photographing lens 3 in a direction different from the optical axis direction by a driving device (not shown) so as to cancel the amount of camera shake detected by the angular velocity sensor 6. Correction is being performed. In addition to the optical camera shake correction, the camera shake correction may be performed by driving the image sensor 27 in a direction different from the optical axis direction to cancel the camera shake, or by canceling the camera shake by the electronic camera shake correction. Also good. In this electronic shake correction, a motion (motion amount) between a plurality of images output from the image processing control circuit 34C is calculated, and an image reading position is set so as to cancel the calculated motion (motion amount) between images. The image blur on the image storage medium 35 is corrected by control. How to use these plural image stabilization methods will be described later.

  The calendar unit 38 includes a crystal oscillator and a clock integrated circuit, and automatically counts calendar information such as year, month, day, hour, and minute. An EEPROM (electrically erasable programmable read only memory) 39 is a storage device for storing camera adjustment values and setting values. In addition to AF adjustment data, AE adjustment data, etc. It stores the date, time, and other data at the time of manufacture. The EEPROM 39 stores human biometric information values. In the present embodiment, the EEPROM 39 stores heart rate, blood flow, blood pressure, body temperature, pressure for holding the camera body 2 (holding force), and pressure for holding the photographing lens 3 (holding force) as biometric information values. Yes. The biometric information is obtained by measuring and storing the normal biometric information of the photographer in advance. Further, this biometric information value may be stored as data specifying the photographer.

  The camera body 2 includes a photometric sensor 40 that measures the luminance of the object field in the vicinity of the pentaprism 32, and a GPS (Global Positioning System) module 41 above the pentaprism 32. Position information (latitude, longitude, altitude) is acquired by receiving signals from GPS satellites. The camera body 2 also includes a microphone 42 that records the sound of the object scene at a position where it does not interfere with the photographic lens 3 at the mount portion on which the photographic lens 3 is mounted, and a speaker 43 near the finder optical system 26. ing. The release SW 24 is a two-stage switch, and when the photographer presses the release SW 24 halfway, the lens-side biosensor unit 8 and the camera-side biosensor unit 16 start detecting the biometric information of the photographer. At the same time, it is a switch that performs a shooting preparation operation (for example, autofocus or photometry) and instructs the shooting (still image or moving image) when the photographer fully presses the release SW 24.

  The main body CPU 44 controls the entire camera system 1 in cooperation with the lens CPU 7. In the present embodiment, the main body CPU 44 captures images based on outputs from the lens-side biosensor unit 8 and the camera-side biosensor unit 16. The biometric information of the person is acquired, and control such as setting of the camera system 1 and operation assistance is performed. Hereinafter, acquisition of the biometric information of the photographer of the lens side biosensor unit 8 and the camera side biosensor unit 16 will be described.

(Heart rate measurement)
As described above, the reference electrode 9a and the detection electrode 9b of the plurality of electrode portions 9 are provided at the position where the photographer holds the photographing lens 3 with the left hand, and the position where the photographer holds the camera body 2 with the right hand. Are provided with reference electrodes 17a and detection electrodes 17b of a plurality of electrode portions 17. The detection potentials from the detection electrodes 9b and 17b are output to the main body CPU 44 after the potential difference is amplified by a differential amplifier (not shown). The main body CPU 44 calculates the heart rate of the photographer based on the potential difference between the detection electrodes 9b and 17b.

  For example, when the photographer does not hold the photographing lens 3, the photographer's left hand is not touching the reference electrode 9a and the detection electrode 9b, so that the gap between the reference electrode 9a and the detection electrode 9b is open. . The lens CPU 7 determines that the photographer does not hold the photographing lens 3 when the reference electrode 9a and the detection electrode 9b are open. Similarly, the main body CPU 44 determines that the photographer does not hold the camera main body 2 when the space between the reference electrode 17a and the detection electrode 17b of the heart rate detecting device is open.

(Blood pressure measurement)
The pulse wave detectors 12 and 20 measure the blood pressure of the photographer. Since pulse wave detection device 12 and pulse wave detection device 20 have the same configuration, detailed description of pulse wave measurement will be made only on pulse wave detection device 12. In the pulse wave detection device 12, for example, infrared rays are emitted from a plurality of light emitting units 10a to 10d, the infrared rays are reflected by a finger artery, and the reflected infrared rays are received by light receiving units 11a to 11d which are infrared sensors. The pulse wave of the finger part of the hand is detected (the blood flow volume of the peripheral blood vessel is detected). The main body CPU 44 calculates the blood pressure of the photographer based on the pulse wave from the pulse wave detection device 12. The lens CPU 7 is arranged corresponding to the little finger when it is determined that the finger (for example, little finger) of the photographer does not touch the photographing lens 3 from the outputs of the reference electrode 9a and the detection electrode 9b of the plurality of electrode portions 9. By prohibiting the light emission of the light emitting section, useless light emission is prevented and stray light is not emitted to the object scene. Similarly, the main body CPU 44 emits light from the pulse wave detection device 20 when the photographer's thumb is not touching the camera main body 2 based on the outputs of the reference electrodes 17a and the detection electrodes 17b of the plurality of electrode portions 17, for example. The light emission of the unit 18 may be prohibited.

(Sweating measurement)
Sweating can be detected by measuring hand impedance. The sweating sensors 13 and 21 have a plurality of electrodes and detect sweating. The reference electrode 9a and the reference electrode 17a may be used as a part of the plurality of electrodes. The sweat sensor 13 is provided in each of the lens-side biosensors 8A to 8D. However, mental sweat such as impression, excitement, and tension has less sweat amount and shorter sweat time. You may provide only in the lens side biosensor part 8B and 8C located in the palm side of a middle hand with much quantity.

(Temperature measurement)
The temperature sensors 14 and 22 use a thermistor method in which the resistance value changes due to heat. The sweating includes the above-described mental sweating and the thermal sweating for body temperature regulation, and the mental sweating and the thermal sweating interfere with each other. Therefore, the main body CPU 44 can determine whether the photographer's perspiration is mental perspiration or thermal perspiration based on the output of the perspiration sensors 13 and 21 and the output of the temperature sensors 14 and 22. For example, the main body CPU 44 can determine thermal sweating when the temperature detected by the temperature sensor 22 is high and a sweat signal from the sweat sensor 21 is always detected. Further, the main body CPU 44 determines that mental sweating occurs when the sweating signal from the sweating sensor 21 is irregularly output, and can detect that the photographer is in a state of emotion, excitement, or tension. When the temperature sensors 14 and 22 are omitted, the main body CPU 44 determines that the sweat signal from the sweat sensors 13 and 21 is based on the position information of the GPS module 41 and the date and time information from the calendar unit 38. Or thermal sweating may be determined. Further, the lens CPU 7 may determine whether the sweat of the left hand is mental sweating or thermal sweating based on the output of the sweat sensor 13 or the output of the temperature sensor 14.

(Pressure measurement)
The pressure sensor 15 is a capacitance type sensor, and measures the amount of deformation caused by the pressing force when the photographer holds the photographing lens 3. In the present embodiment, the pressure sensor 15 is provided below the operation rubber. The pressure sensor 23 is a similar capacitance type sensor, and measures the amount of deformation caused by the pressing force when the photographer holds the camera body 2. Note that pressure sensors 15 and 23 using strain gauges, electrostrictive elements, or the like may be applied.

  FIG. 8 is a flowchart showing a process of detecting a photographer's biometric information and setting shooting conditions under the control of the main body CPU 44. The following description will be made assuming that the main switch (power switch) of the camera body 2 is turned on.

  The main body CPU 44 determines whether or not the release SW 24 is half-pressed. If the release SW 24 is half-pressed, the process proceeds to step S2, and if the release SW 24 is not half-pressed, the determination of step S1 is repeated (step S1). The main body CPU 44 starts shooting preparation when the release SW 24 is half-pressed (step S2). Specifically, the main body CPU 44 performs focus detection of the object scene using the focus detection sensor 29 and measures the luminance of the object scene using the photometric sensor 40.

  Further, when the live view mode is set by a setting SW (not shown) provided on the back surface of the camera body 2, the main body CPU 44 retracts the movable mirror 28 to the retracted position, and the rear liquid crystal monitor control circuit 36. With this control, an image (live view image) is displayed on the rear liquid crystal monitor 37. The main body CPU 44 positions the movable mirror 28 at the reflection position when the live view mode is not set by a setting SW (not shown). The main body CPU 44 detects biological information of the left hand of the photographer by the lens-side biosensor unit 8 in conjunction with the lens CPU 7, and detects biological information of the right hand of the photographer by the camera-side biosensor unit 16 (step S3). . Here, the main body CPU 44 detects a photographer's heart rate, blood flow, blood pressure, sweating state, body temperature, and pressure (holding force) that holds the camera body 2 and the photographing lens 3. Note that the order of steps S2 and S3 may be interchanged or may be performed simultaneously.

  The main body CPU 44 compares the biometric information value stored in the EEPROM 39 with the biometric information of the photographer acquired in step S3 to determine whether the biometric information has changed, that is, the photographer is in an excited state or a fatigued state. Is determined (step S4). The main body CPU 44 determines that the photographer may be excited when the detected heart rate and blood pressure are 10% or more higher than the heart rate and blood pressure stored in the EEPROM 39. The pressure (holding force) for holding the camera body 2 and the taking lens 3 is referred to.

  The main body CPU 44 determines mental sweating when the sweating signals from the sweating sensors 13 and 21 are irregularly output, and determines that the photographer is in an excited state. When the main body CPU 44 cannot discriminate between mental sweating and thermal sweating, the main body CPU 44 refers to the pressure (holding force) that holds the camera body 2 and the photographing lens 3 and stores either pressure (holding force) in the EEPROM 39. It is determined that the photographer is excited when the pressure is 10% or more higher than the applied pressure.

  In addition, instead of the output of the sweating sensors 13 and 21 and the output of the pressure sensors 15 and 23, or in addition to the output of the sweating sensors 13 and 21 and the output of the pressure sensors 15 and 23, refer to the output of the microphone 42. Also good. When the output from the microphone 42 has increased by 10 dB or more (for example, from 60 dB to 70 dB), the main body CPU 44 determines that something has happened at the shooting location and the photo opportunity is near or the photographer's excitement is expected. May be.

  Furthermore, the main body CPU 44 may determine that the shooting location is a school, a stadium, a wedding hall, or the like based on the output of the GPS module 41, and change the threshold value of the determination state of excitement. Specifically, when the shooting location is a school or a stadium, the output of the microphone 42 is likely to fluctuate due to cheering, etc., so the excitement of the photographer is expected when the output from the microphone 42 rises by 20 dB or more. Judge that. If the shooting location is a wedding hall, there will often be a photo opportunity after the presenter's remarks, so if the output from the microphone 42 decreases, it will be judged that the photo opportunity is near or the excitement of the photographer is expected. May be.

  The main body CPU 44 determines that the photographer is excited when the heart rate and blood pressure stored in the EEPROM 39 are increased by 15% or more. In this case, the outputs of the sweating sensors 13 and 21 and the outputs of the pressure sensors 15 and 23 may not be referred to. Instead of comparing the biometric information value stored in the EEPROM 39 with the biometric information of the photographer acquired in step S3, the main body CPU 44 changes the biometric information of the photographer acquired in step S3. Whether the photographer is in an excited state may be determined from the rate. Specifically, the main body CPU 44 determines whether or not the photographer is in an excited state based on whether or not the photographer's heart rate and blood pressure have increased over time. Further, even when the photographer's heart rate and blood pressure rise over time, the main body CPU 44 determines that the output of the sweat sensors 13 and 21 and the pressure sensor 15 and With reference to the output 23, it is determined whether or not the photographer is in an excited state. As described above, it may be determined whether the photographer is in an excited state based on the output of the microphone 42 or the output of the GPS module 41.

  The main body CPU 44 calculates the blood flow based on the pulse wave detected by the pulse wave detection devices 12 and 20, and detects the photographer's fatigue based on the calculation result. That is, since there is a correlation between the blood flow rate and fatigue, the blood flow rate is determined by comparing the calculated blood flow rate with the normal blood flow rate of the photographer stored in the EEPROM 39. It is determined that the photographer is in a fatigued state when it increases by more than a threshold value.

  When determining that the biometric information of the photographer has not changed in step S4, the main body CPU 44 determines whether or not the release SW 24 is fully pressed in step S5. Execute. In this shooting, for example, a still image or a moving image is shot according to the setting of the shooting mode SW25 or a setting SW (not shown). Still image shooting or moving image shooting settings may be selected by the shooting mode SW25, or a dedicated switch for moving image shooting may be provided, and the live view mode is set by a setting SW (not shown). In this state, moving image shooting may be started by pressing the above-described moving image shooting switch.

  If the release SW 24 is not fully pressed in step S5, the main body CPU 44 returns to step S1. On the other hand, if the main body CPU 44 determines that the photographer is in an excited state or a fatigued state in step S4, the live view mode is set by a setting SW (not shown) provided on the back of the camera main body 2. Even if not, the movable mirror 28 is moved to the retracted position, and an image (live view image) is displayed on the rear liquid crystal monitor 37 by the rear liquid crystal monitor control circuit 36 (step S7). This is because, as will be described later, the photographer is in an excited state or in a fatigued state, and is different from the normal state, so that an image is reliably captured. Further, the main body CPU 44 performs contrast AF using the output of the image sensor 27 instead of the focus detection sensor 29 because the movable mirror 28 is at the retracted position.

  Next, the main body CPU 44 sets the camera system 1 to the automatic shooting mode (step S8). Specifically, the main body CPU 44 sets automatic exposure (AE) and autofocus (AF), and automatically sets a shooting scene from portrait, sports, landscape, night view, sunset view, and the like. This automatic setting may be set based on the photometric result of the photometric sensor 40, time information from the calendar unit 38, and position information from the GPS module 41. The main body CPU 44 may set the ISO to a higher sensitivity side than normal (for example, ISO 800 or higher) and display a level in the finder to prevent the camera system 1 from tilting.

  The main body CPU 44 sets the auto shooting mode when the photographer's excitement state is medium or larger (for example, when the outputs of the lens-side biosensor 8 and the camera-side biosensor 16 are increased by 15% or more). Also good. The auto shooting mode may be set to enable / disable of the mode itself, or each function of the auto shooting mode may be set to enable / disable.

  Next, the main body CPU 44 sets an erroneous operation prevention mode (step S9). In the erroneous operation prevention mode, for example, when the photographer performs a predetermined operation such as a power switch, operation of the release SW 24, image deletion, format operation of the image storage medium 35, a confirmation display or a warning display is displayed in the viewfinder or Characters and icons are used for the rear liquid crystal monitor 37 or both the viewfinder and the rear liquid crystal monitor 37. Further, the main body CPU 44 may output a confirmation or warning sound from the speaker 43. Further, the main body CPU 44 may prohibit a predetermined operation. Specifically, the main body CPU 44 prohibits turning off the power switch, deleting the captured image by the image deleting unit, editing the captured image by the image editing unit, and formatting the image storage medium 35. The main body CPU 44 may execute the power switch off when the power switch is turned off a plurality of times even when the power switch is prohibited from being turned off. In addition, the main body CPU 44 is instructed to delete the captured image by the image deletion unit a plurality of times by the operation unit even when deletion of the captured image by the image deletion unit and editing of the captured image by the image editing unit are prohibited. In such a case, the shot image may be deleted by the image deletion unit. When the operation unit has been instructed to edit the shot image by the image editing unit a plurality of times, the shot image is shot by the image editing unit. You may make it edit. Note that the erroneous operation prevention mode may be set to enable or disable the mode itself, or each function of the erroneous operation prevention mode may be set to enable or disable.

  Next, the main body CPU 44 determines whether or not the set shooting mode is the still image shooting mode (step S10). If the still image shooting mode is set here, the still image correction mode is entered (step S11). On the other hand, if the still image shooting mode is not set, the moving image correction mode is set, and the moving image correction mode is entered (step S12).

  In the still image correction mode in step S11, when the photographer is in an excited state, the degree of camera shake increases, so the exposure control is changed to shorten the exposure time in order to reduce the influence of camera shake. In this case, the exposure calculation program diagram of the camera system 1 is changed so as to increase the shutter speed. As a result, the shutter opening time (not shown) is controlled to be short, and the image capturing time by the image sensor 27 is shortened. In the excited state, the amplitude is larger and the dominant vibration frequency tends to shift higher than in the mental state where the vibration characteristics of the vibration are calm, so the camera shake correction is also higher than in the normal state. The control is changed to the control using the control parameter suitable for the camera shake correction corresponding to the vibration having a large amplitude and a slightly quick cycle. For example, in a camera shake correction system using an angular velocity sensor 6 having a normal gyro sensor, signal processing that mainly detects low-frequency vibrations in the vicinity of several hertz (around 2 hertz) when imaging with the imaging device 27 is performed. However, the cut-off frequency of the digital filter of a digital circuit (not shown) is changed so that this main detection frequency is mainly detected as a frequency several times (6 to 10 hertz). In addition, when the change in the biological information is large, the amplitude becomes large. Therefore, there is a case where the camera shake cannot be completely corrected by one method of camera shake correction. For this reason, in the present embodiment, the camera shake when the amplitude is large is corrected by appropriately combining the three camera shake correction methods described above. Specifically, the lens CPU 7 drives the image stabilization lens based on the camera shake amount detected by the angular velocity sensor 6, and the main body CPU 44 corrects the image stabilization lens drive amount based on the camera shake amount detected by the angular velocity sensor 6. A camera shake amount that cannot be completely calculated is calculated, and the image sensor 27 may be driven based on the calculated camera shake amount. Further, electronic shake correction may be performed instead of driving the image sensor 27, or all three camera shake correction methods may be used. Note that the three camera shake correction methods described above may be selected in accordance with the remaining battery level of the camera system 1. For example, the main body CPU 44 may receive weight data of the anti-vibration lens from the lens CPU 7 and drive a lighter weight compared with the weight of the image sensor 27, and may be combined with electronic shake correction.

  In the moving image correction mode in step S12, the main body CPU 44 changes the exposure control so that the exposure time of each frame is shortened in order to reduce the influence of camera shake, as in the still image correction mode. In this case, the exposure calculation program diagram of the camera system 1 is changed so that the shutter speed becomes high, and camera shake correction is performed. Further, since the exposure time is longer than that in the case of a still image, it is required that the correction follow-up range for camera shake correction is wider. That is, the correction control is set to be duller than the vibration in the case of a still image, and the camera shake correction parameter is changed so as to intensively correct a shake with a larger amplitude. For example, in normal video shooting, assuming that the amplitude of N (N is a positive real number) degree / sec is followed, when the photographer is excited, the image stabilization is performed so as to follow the amplitude of 2N to 5N. It is only necessary to drive at least one of the lens and the image sensor 27. Moreover, you may make it select the amplitude to follow from 2N-5N according to the degree of excitement (degree of change of biometric information). Further, correction may be performed for the case where the amplitude of camera shake exceeds a predetermined value based on the degree of change in biological information.

  In addition, the main body CPU 44 considers the composition stability (look) between the moving image frames, and is a frame rate higher than the normal moving image shooting frame rate (for example, 60 fps when the normally set frame rate is 30 fps). Change to

  Furthermore, when recording a moving image, audio is recorded simultaneously with the normal image. However, if the photographer is excited, there is a possibility that the main CPU 44 is louder than the normal audio recording gain. Set to a low level to prevent saturation of audio recording level (sound cracking due to high volume input). The still image correction mode and the moving image correction mode may be set to enable / disable of the mode itself.

  The main body CPU 44 determines whether or not the release SW 24 is fully pressed in step S13. If the release SW 24 is fully pressed, the main body CPU 44 proceeds to step S6 and executes photographing. In this case, when any of the auto shooting mode, the erroneous operation prevention mode, the still image correction mode, and the moving image correction mode is set to be effective, the shooting is performed using the function of each set mode. . In this case, since it is detected that the photographer is in an excited state and the movable mirror 28 is moved to the retracted position in advance, there is an effect that photographing can be performed quickly.

  On the other hand, the main body CPU 44 performs moving image shooting when the release SW 24 is not fully pressed in step S13 (step S14). The moving image shooting in step S14 is for reliably shooting an image even when the photographer is in an excited state. Specifically, the main body CPU 44 shoots a short moving image of about 4 to 6 seconds, for example, regardless of whether the still image shooting mode or the moving image shooting mode is set. At this time, the main body CPU 44 displays on the at least one of the finder optical system 26 and the rear liquid crystal monitor 37 that a moving image is being photographed. Thus, the photographer can recognize that a backup moving image is recorded, and thus can remove the worry of missing a photo opportunity. In this case, it is preferable that the display of the normal moving image recording is different from the display of the backup moving image recording. Specifically, the display of the backup moving image recording may be made more conspicuous by blinking, changing the color, or changing the display size.

  If a still image is cut out from the captured moving image, a still image can be obtained even if a photo opportunity is missed. The main body CPU 44 sets the frame rate according to the remaining capacity of the image recording medium 35, and sets the moving image shooting time from 4 seconds to 6 seconds. Further, when the remaining capacity of the image recording medium 35 is small, the main body CPU 44 can set the moving image shooting time to 3 seconds or less, or can switch to still image shooting. In this case, the number of still images to be shot or the number of shots for continuous shooting may be determined according to the remaining capacity of the image recording medium 35. In moving image shooting, sound may or may not be recorded. For example, when the frame rate exceeds 60 fps, sound may not be recorded.

  In step S14, the main body CPU 44 determines whether or not the release SW 24 is half-pressed even after shooting a short time movie (step S15). If the release SW 24 is half-pressed, the process returns to step S2. When the process proceeds from step S2 to step S14 again, a moving image can be captured intermittently. On the other hand, if the release SW 24 is not half-pressed in step S15, the main body CPU 44 returns the movable mirror 28 to the reflection position (step S16). In addition, if the photographer is excited or tired, it can be left as tag information or saved in another holder (for example, a holder for shooting when excited), and the photographer can edit the image. Can easily extract the images that interest you.

  In the flowchart of FIG. 8, the preparation for photographing is started after the release SW 24 is pressed halfway in step S <b> 1. However, both hands of the photographer touch each of the lens-side biosensor unit 8 and the camera-side biosensor unit 16. When the camera is in the camera, the outputs of the lens-side biosensor unit 8 and the camera-side biosensor unit 16 are detected. When the photographer's excitement state is detected, the preparation for shooting may be started in the same manner as when the release SW 24 is half-pressed. . Thereby, even when the photographer suddenly presses the release SW 24 suddenly, a focused image can be recorded.

  In the present embodiment, the photographer's biometric information is acquired based on the outputs of the lens-side biosensor unit 8 and the camera-side biosensor unit 16, but if a change in the biometric information can be detected, imaging is performed. Analogy with a person's emotional changes. In this case, it is not necessary to use a very expensive sensor as each of the lens side biosensor unit 8 and the camera side biosensor unit 16.

  Further, if the outputs of the lens-side biosensor unit 8 and the camera-side biosensor unit 16 are stored in a storage device (not shown) in association with the date / time information of the calendar unit 38 or the positioning information from the GPS module 41, Changes in the biometric information of the photographer according to the shooting location can be recorded. In this case, it is desirable to store changes in biological information for each photographer in a storage device (not shown).

(Correction mode)
The main body CPU 44 uses the date and time information from the GPS module 41 and the calendar unit 38 provided in the camera main body 2 to threshold the photographer's emotional judgment based on values acquired by the lens side biosensor unit 8 and the camera side biosensor unit 16. May be corrected. Specifically, if the photographer is in Hokkaido and the season is winter due to the output of the GPS module 41, the blood pressure increases, so the threshold for determining the excitement of the photographer may be increased.

  In the above-described embodiment, the auto shooting mode and the erroneous operation prevention mode are set at the same time. However, either one of the auto shooting mode and the erroneous operation prevention mode may be set.

  Further, in the above-described embodiment, when detecting the degree of fatigue of the photographer from the biological information, the time after the camera 2 is turned on, the number of operations of the release SW 24, the moving image shooting cumulative time, and the like are referred to. It may be. In this case, the photographer's fatigue level can be detected with higher accuracy. For example, when the cumulative power-on time for one day exceeds 1 hour, when the number of operations of the release SW 24 exceeds 200, or when the cumulative shooting time for moving images exceeds 1 hour, the photographer is in a fatigued state. It can be judged that there is.

  According to the camera system 1 according to this embodiment, when the photographer is in an unusual state, for example, when the photographer is excited or tired, it is possible to perform photographing without fail. . For example, parents may be excited and cheering while taking pictures depending on the situation of their children's activities in children's athletic meet. it can.

  In the camera system 1 according to the above-described embodiment, the lens interchangeable single-lens reflex camera system provided with the movable mirror 28 has been described as an example. However, the mirrorless without the movable mirror 28, the pentaprism 32, and the like. A photographing assist function using the outputs of the lens-side biosensor unit 8 and the camera-side biosensor unit 16 according to the present embodiment can also be employed in this type of interchangeable lens camera. In this case, since the movable mirror 28 is not provided, steps S7 and S16 in the flowchart shown in FIG. 8 can be omitted. Further, since the movable mirror 28 is not provided, the light beam from the object field does not reach the focus detection sensor 29. Therefore, focus detection may be performed by contrast AF using the image sensor 27 instead of the focus detection sensor 29. Note that Japanese Patent Laid-Open No. 2007-233302 (US Publication No. 2007070206937) proposes an image sensor AF that performs phase difference AF by providing AF detection pixels in the image sensor. Therefore, the contrast AF and the phase difference AF may be used in combination by adopting this imaging element AF in the mirrorless lens interchangeable camera.

  Further, control using the output of the camera-side biosensor unit 16 according to the present embodiment can be adopted for the video camera.

  Further, in the above-described embodiment, the biological information from both hands of the photographer is detected using the lens-side biosensor unit 8 and the camera-side biosensor unit 16, but for example, the sweat sensors 13, 21, the temperature sensor 14, 22. The pressure sensors 15 and 23 may be detection results from one hand. As long as other sensors can be detected from one hand according to the detection method, the detection result from one hand may be used.

  Further, instead of the lens side biosensor unit 8 and the camera side biosensor unit 16, a wearable biosensor may be used. Or you may make it use the lens side biosensor part 8 and the camera side biosensor part 17, and a wearable type biosensor in cooperation. As the wearable biosensor, a watch-type biosensor, a ring-type biosensor, or the like can be used. In this case, the output of the wearable biosensor may be transmitted to the camera body 2 by short-range communication. Details of the wristwatch-type biosensor are disclosed in, for example, Japanese Patent Application Laid-Open No. 2005-270543 (US Pat. No. 7,538,890).

  In the above-described embodiment, it is determined whether or not the photographer is in an excited state based on the biological information. However, the level of the photographer's excited state is determined based on the biological information of the photographer. Depending on the level of excitement, the control in the still image correction mode and the moving image correction mode may be made different. Further, the above-described camera shake correction may be performed when it is determined that the photographer is frustrated based on the biological information.

DESCRIPTION OF SYMBOLS 1 ... Camera system, 2 ... Camera body, 3 ... Shooting lens, 8 (8A-8D) ... Lens side biological sensor part, 16 ... Camera side biological sensor part, 26 ... Finder optical system, 27 ... Imaging element, 28 ... Movable Mirror, 38 ... Calendar part, 41 ... GPS module, 42 ... Microphone

Claims (11)

An imaging unit capable of capturing moving images and still images;
Connected to a detection device that detects camera shake, and includes a first camera shake control corresponding to the moving image, and a control unit corresponding to the still image and performing a second camera shake control different from the first camera shake control,
The said control part changes each control of said 1st camera shake control and said 2nd camera shake control according to the change of the photographer's biometric information detected with the biometric sensor, The imaging device characterized by the above-mentioned.   The imaging device according to claim 1, wherein the control unit changes detection sensitivity of the detection device when the imaging unit captures a still image.   The imaging apparatus according to claim 1, wherein the control unit changes an amplitude value for performing camera shake correction when the imaging unit captures a moving image. Imaging by the imaging unit is performed through an optical system,
The control unit performs shake control by using a first correction unit that corrects camera shake using a part of the optical system and a second correction unit that is different from the first correction unit. The imaging device according to any one of claims 1 to 3. An imaging unit capable of capturing moving images and still images using an optical system;
A control unit connected to a detection device for detecting camera shake, wherein the control unit corrects camera shake using a part of the optical system in accordance with a change in the photographer's biological information detected by the biosensor. An image pickup apparatus that performs camera shake control by using a first correction unit and a second correction unit different from the first correction unit in combination. An imaging unit for imaging;
A change unit capable of changing the setting of the detection device for detecting camera shake;
A control unit that controls the change unit to change the setting of the detection device according to a change in the biological information of the photographer detected by the biosensor;
An imaging apparatus comprising:   The imaging device according to claim 6, wherein the control unit changes detection sensitivity of the detection device. The imaging unit includes a shutter for controlling the imaging time,
The imaging apparatus according to claim 6, wherein the changing unit controls the shutter to shorten the imaging time according to a change in the photographer's biological information detected by the biological sensor. An imaging unit for imaging;
A control unit connected to a detection device that detects camera shake, wherein the control unit has an amplitude of a predetermined value out of the camera shake detected by the detection device according to a change in the biometric information of the photographer detected by the biosensor. An image pickup apparatus that corrects camera shake of a thing exceeding the range.   The imaging apparatus according to claim 9, wherein the control unit increases a frame rate when the imaging unit captures a moving image in accordance with a change in a photographer's biological information detected by the biological sensor. It has a voice recording device that records voice with a set gain,
11. The imaging apparatus according to claim 9, wherein the control unit changes the gain according to a change in a photographer's biological information detected by the biological sensor.

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