JP2006081083A - Imaging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shorten the convergence time of an auto-white balance in the case of the rise of a power supply, and to realize a more rapid accurate auto-white balance control in an imaging device capable of simultaneously recording a still image and a moving image. <P>SOLUTION: The imaging device has first and second image sensors and first and second signal processing means to output signals from the first and second image sensors. In the imaging device, it has the initial values of white balances different in the first signal processing and the second signal processing, the initial value closer to an environment in the case of a start is selected and the white-balance control is conducted. Also, it has a mutual translation table or a translation system regarding the white-balance control between the first signal processing and the second signal processing, and the initial value closer to the environment in the case of the start is selected. In the imaging, the white-balance control of the signal processing in which the initial value is not selected is translated on the basis of the translation table or the translation system from the control of another signal processing, in which the initial value is selected, and the white-balance control is continued. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an imaging apparatus capable of simultaneously recording moving images and still images.

There is a demand for recording a specific scene as a still image while shooting a video with a video camera. Conventionally, a video camera with a still camera has been proposed in which a still camera and a video camera are combined into a single device, and the still camera can be operated to operate the still camera without interrupting shooting with the video camera ( For example, see Patent Document 1).
Japanese Patent No. 0573600

  However, in the above invention, since auto white balance control is performed independently in signal processing for moving image and still image shooting, it takes time for auto white balance control to stabilize when the power is turned on. It had the disadvantage that it would end up.

  In the present invention, in view of the above problems, in an imaging device capable of recording moving images and still images simultaneously, the convergence time of auto white balance when power is turned on is shortened, and quicker and more accurate auto white balance control is realized. The task was to do.

  The present invention has been made to solve such problems.

As means for solving the problems, the present invention provides:
In an imaging apparatus having first and second image sensors, and first and second signal processing means for output signals of the first and second image sensors, first signal processing and second signal processing are performed. It is characterized in that the white balance control is performed by selecting a different initial value of the white balance and selecting an initial value closer to the environment at the time of startup.

Furthermore, the feature of the present invention is that
In an imaging apparatus having first and second image sensors, and first and second signal processing means for output signals of the first and second image sensors, first signal processing and second signal processing are performed. Has different white balance initial values, has a mutual conversion table or conversion formula for white balance control between the first signal processing and the second signal processing, and sets the initial value closer to the environment at the time of startup. The white balance control of the signal processing that is selected and the initial value is not selected is converted based on the conversion table or the conversion formula from the control of the other signal processing in which the initial value is selected, and the white balance control is continued. It is characterized by that.

Furthermore, the feature of the present invention is that
The first image sensor is an image sensor for moving image shooting, and the second image sensor is an image sensor for still image shooting.

Furthermore, the feature of the present invention is that
The white balance initial value in the first signal processing is set to a lower color temperature side than the white balance initial value in the second signal processing.

Furthermore, the feature of the present invention is that
The white balance initial value in the first signal processing is set to a higher color temperature side than the white balance initial value in the second signal processing.

  According to the present invention, in an imaging device capable of simultaneously recording moving images and still images, different values are set for the initial value of auto white balance between moving image signal processing and still image signal processing, and the power is turned on. By selecting an initial value closer to the environment, it is possible to shorten the convergence time of the auto white balance control and realize a quicker and more accurate auto white balance control.

  Also, there is a mutual conversion table or conversion formula for white balance control between video and still image signal processing, and initial value is selected for auto white balance control of signal processing that was not selected at startup. By converting from the other signal processing control based on the conversion table or conversion formula, the convergence time of the auto white balance control can be shortened, and more rapid and accurate auto white balance control can be realized. .

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to examples.

  FIG. 1 is a schematic configuration diagram showing the configuration of the present embodiment.

  Reference numeral 101 denotes a lens, and a diaphragm 102 is disposed behind the lens 101. The light passing through the lens 101 and the diaphragm 102 is separated in two directions by the half mirror 103 and formed as subject images on the imaging surfaces of the movie CCD 105 and the still CCD 107, respectively. At this time, a shutter 104 is provided in front of the Still CCD 107 so that extra charge is not accumulated during the readout period. In the movie CCD 105 and the still CCD 107, the formed subject image is converted from an optical signal to a video signal.

  The video signal obtained by the movie CCD 105 is sent to the movie signal processing unit 112. The video signal is subjected to predetermined processing in the Movie signal processing unit 112 and is recorded on the magnetic tape 115 or output to the display 116.

  The image signal obtained by the Still CCD 107 is sent to the Still signal processor 114. The image signal is subjected to predetermined processing in the Still signal processing unit 114 and recorded in the memory card 118.

  Reference numeral 111 denotes a camera microcomputer. Through the movie CCD control unit 106 and the still CCD control unit 108, control such as accumulation and reading of the movie CCD 105 and the still CCD 107 is performed. Further, through the movie signal processing unit 112 and the still signal processing unit 114, automatic white balance control for capturing moving images and still images is performed, and processing is performed so that the white balance of each of the moving images and still images becomes appropriate.

  The auto white balance control in moving image shooting and still image shooting by the camera microcomputer 111 will be described in detail later.

  FIG. 2 is a perspective view showing an overview of the image pickup apparatus of the present embodiment.

  Reference numeral 120 denotes an imaging apparatus main body. A recording medium such as a magnetic tape and a memory card is accommodated in the imaging apparatus main body 120 so that a video signal and a still image can be recorded and reproduced. Reference numeral 121 denotes a lens unit. Reference numeral 122 denotes a microphone, which is provided for recording sound during shooting. Reference numeral 123 denotes an electronic viewfinder (EVF), which is provided for aiming and checking a subject when taking a picture by looking into the camera.

  Reference numeral 124 denotes a moving image trigger switch. The moving image trigger switch 124 is a push button, and is a switch operated by the user to transmit the start and end of moving image shooting to the device. Reference numeral 125 denotes a still image trigger switch. The still image trigger switch 125 is a push button, and is a switch operated by the user to transmit the start and end of still image shooting to the device.

  A flash device 131 emits light as needed as an auxiliary means for photographing a still image.

  A mode dial 126 is composed of a rotary switch. The mode dial 126 can select, for example, “playback” set to the playback mode, “camera” set to the camera mode, and “OFF” which is not one of them.

  Reference numeral 127 denotes a group of operation switches, on which keys for a reproduction system and menu operation are arranged for the user to operate the main body.

  Reference numeral 128 denotes a liquid crystal panel attached to the side of the main body so as to be freely opened and closed. Like the EVF 123, the liquid crystal panel 128 is mainly used for confirming a subject image during camera shooting and for displaying a reproduced image during reproduction. The liquid crystal panel 128 can be rotated in the horizontal direction while being opened from the main body 120.

  Reference numeral 129 denotes a speaker, which is provided for outputting sound when reproducing. A battery 130 is detachable from the main body 120.

  Next, the auto white balance control process at the start-up in the image pickup apparatus of the present embodiment will be described with reference to the schematic configuration diagram of FIG. 1 and the flowcharts of FIGS.

  FIG. 3 is a flowchart showing the auto white balance control of the moving image signal processing at the time of activation of this embodiment. When the moving image shooting auto white balance control is started (S101), the camera microcomputer 111 sets the initial value of the color temperature in the moving image shooting auto white balance control to the moving image initial value (for example, the low color temperature side) ( S102). Subsequently, the camera microcomputer 111 detects the white balance of the moving image in this state based on the video signal sent from the Movie CCD 105 (S103). The detected color is compared with the color of the white balance detection result in still image shooting described later (S104). As a result of the comparison, if the detected color in moving image shooting is closer to white than the detected color in still image shooting, the camera microcomputer 111 continues the automatic white balance control for moving image shooting as it is (S106). Conversely, when the detected color in moving image shooting is not closer to white than the detected color in still image shooting, the camera microcomputer 111 sets the color temperature in the moving image shooting auto white balance control to an initial value for still images (for example, a high value). The color temperature is set again (S105), and the moving image shooting auto white balance control is continued again (S106).

  FIG. 4 is a flowchart showing the auto white balance control of the still image signal processing at the time of activation of this embodiment. When the auto white balance control for still image shooting is started (S201), the camera microcomputer 111 changes the initial value of the color temperature in the auto white balance control for still image shooting to the initial value for still image (for example, the high color temperature side). Set (S202). Subsequently, the camera microcomputer 111 detects the white balance of the still image in this state based on the image signal sent from the Still CCD 107 (S203). The detected color is compared with the color of the white balance detection result in the above-described moving image shooting (S204). If the detected color in still image shooting is closer to white than the detected color in moving image shooting as a result of the comparison, the camera microcomputer 111 continues auto white balance control for still image shooting as it is (S206). Conversely, when the detected color in still image shooting is not closer to white than the detected color in moving image shooting, the camera microcomputer 111 sets the color temperature in the auto white balance control for still image shooting to the initial value for moving images (for example, low The color temperature is set again (S205), and auto white balance control for still image shooting is continued again (S206).

  Here, the case has been described where the initial color temperature value for moving image shooting auto white balance control is set to the low color temperature side, and the initial color temperature value for still image shooting auto white balance control is set to the high color temperature side. On the other hand, the initial value of color temperature in auto white balance control for movie shooting is set to the high color temperature side, and the initial value of color temperature in auto white balance control for still image shooting is set to the low color temperature side. It doesn't matter.

  Next, the movement of the auto white balance control point in the auto white balance control process at the start-up in the image pickup apparatus of the present embodiment will be described with reference to FIG.

  FIG. 5 is a diagram showing an auto white balance control axis for moving image shooting and still image shooting in the present embodiment. In the figure, 145 is a moving image auto white balance control axis, and 146 is a still image auto white balance control axis. The moving image shooting auto white balance control starts from a moving image auto white balance control point A141 on the low color temperature side as an initial value. Further, the auto white balance control for still image shooting starts from an auto white balance control point B′144 for still images on the high color temperature side as an initial value. Subsequently, white balance detection of the moving image and the still image is performed, and the detected colors are compared.

  When the detected color in moving image shooting is closer to white than the detected color in still image shooting, the control point in auto white balance control for still image shooting is the initial value for moving image from the current control point B′144. The process proceeds to the still image auto white balance control point A ′ 143 corresponding to the moving image auto white balance control point A 141, and still image shooting auto white balance control is performed. On the other hand, the auto white balance control for moving image shooting continues the control as it is.

  Conversely, when the detected color in still image shooting is closer to white than the detected color in moving image shooting, the control point in the moving image shooting auto white balance control is changed from the current control point A141 to the initial value for still image. Moving to a moving image auto white balance control point B 142 corresponding to a still image auto white balance control point B ′ 144, moving image shooting auto white balance control is performed. On the other hand, the auto white balance control for still image shooting continues the control as it is.

  As described above, in a two-plate imaging apparatus capable of recording moving images and still images simultaneously, different values are set for the initial value of auto white balance for moving image signal processing and still image signal processing, and the power is turned on. By selecting an initial value closer to the environment at the time of raising, the convergence time of auto white balance control can be shortened, and quicker and more accurate auto white balance control can be realized.

  In the present embodiment, the auto white balance control process at the time of activation in the first embodiment is replaced as follows.

  FIG. 6 is a schematic configuration diagram showing the configuration of the present embodiment.

  Reference numeral 201 denotes a lens, and a diaphragm 202 is disposed behind the lens 201. The light passing through the lens 201 and the diaphragm 202 is separated into two directions by the half mirror 203 and formed as subject images on the imaging surfaces of the movie CCD 205 and the still CCD 207, respectively. At this time, a shutter 204 is provided on the front surface of the Still CCD 207 so that extra charges are not accumulated during the readout period. In the movie CCD 205 and the still CCD 207, the formed subject image is converted from an optical signal to a video signal.

  The video signal obtained by the movie CCD 205 is sent to the movie signal processing unit 212. The video signal is subjected to predetermined processing in the movie signal processing unit 212 and is recorded on the magnetic tape 215 or output to the display 216.

  The image signal obtained by the Still CCD 207 is sent to the Still signal processing unit 214. The image signal is subjected to predetermined processing in the Still signal processing unit 214 and recorded in the memory card 218.

  Reference numeral 211 denotes a camera microcomputer. Through the movie CCD control unit 206 and the still CCD control unit 208, control such as accumulation and reading of the movie CCD 205 and the still CCD 207 is performed. Further, through the movie signal processing unit 212 and the still signal processing unit 214, auto white balance control for capturing moving images and still images is performed, and processing is performed so that the white balance of each of the moving images and still images becomes appropriate.

  A Still / Movie conversion table 210 is used when performing conversion processing from one of the moving image auto white balance control and the still image auto white balance control to the other.

  The auto white balance control in moving image shooting and still image shooting using the Still / Movie conversion table 210 by the camera microcomputer 211 will be described in detail later.

  Next, the auto white balance control process at the start-up in the image pickup apparatus of the present embodiment will be described with reference to the schematic configuration diagram of FIG. 6 and the flowcharts of FIGS.

  FIG. 7 is a flowchart showing the auto white balance control of the moving image signal processing at the time of activation of this embodiment. When the moving image shooting auto white balance control is started (S301), the camera microcomputer 211 sets the initial value of the color temperature in the moving image shooting auto white balance control to the moving image initial value (for example, the low color temperature side) ( S302). Subsequently, the camera microcomputer 211 detects white balance of the moving image in this state based on the video signal sent from the Movie CCD 205 (S303). The detected color is compared with the color of the white balance detection result in still image shooting described later (S304). As a result of the comparison, if the detected color in moving image shooting is closer to white than the detected color in still image shooting, the camera microcomputer 211 continues the automatic white balance control for moving image shooting as it is (S306). Conversely, when the detected color in moving image shooting is not closer to white than the detected color in still image shooting, the camera microcomputer 211 stores the color temperature in moving image shooting auto white balance control in the Still / Movie conversion table 210. Based on the color temperature control point of still image shooting auto white balance control (S305), the moving image shooting auto white balance control is continued again (S306).

  FIG. 8 is a flowchart showing auto white balance control of the still image signal processing at the time of activation of this embodiment. When the still image shooting auto white balance control is started (S401), the camera microcomputer 211 changes the initial value of the color temperature in the still image shooting auto white balance control to the initial value for still image (for example, the high color temperature side). Set (S402). Subsequently, the camera microcomputer 211 detects the white balance of the still image in this state based on the image signal sent from the Still CCD 207 (S403). The detected color is compared with the color of the white balance detection result in the above-described moving image shooting (S404). As a result of the comparison, if the detected color in still image shooting is closer to white than the detected color in moving image shooting, the camera microcomputer 211 continues the auto white balance control for still image shooting as it is (S406). Conversely, when the detected color in still image shooting is not closer to white than the detected color in moving image shooting, the camera microcomputer 211 converts the color temperature in still image shooting auto white balance control to the Still / Movie conversion table 210. Is obtained from the color temperature control point of moving image shooting auto white balance control (S405), and still image shooting auto white balance control is continued again (S406).

  Here, the case has been described where the initial color temperature value for moving image shooting auto white balance control is set to the low color temperature side, and the initial color temperature value for still image shooting auto white balance control is set to the high color temperature side. On the other hand, the initial value of color temperature in auto white balance control for movie shooting is set to the high color temperature side, and the initial value of color temperature in auto white balance control for still image shooting is set to the low color temperature side. It doesn't matter.

  Also, here, a case has been described in which the conversion processing from one to the other of the moving image auto white balance control and the still image auto white balance control is performed based on the Still / Movie conversion table, but conversion is performed instead of the conversion table. You may make it perform a conversion process using a type | formula.

  Next, the movement of the auto white balance control point in the auto white balance control process at the start-up in the image pickup apparatus of the present embodiment will be described with reference to FIG.

  FIG. 9 is a diagram showing an auto white balance control axis for moving image shooting and still image shooting in the present embodiment. In the figure, 245 is a moving image auto white balance control axis, and 246 is a still image auto white balance control axis. The moving image shooting auto white balance control starts from a moving image auto white balance control point A241 on the low color temperature side as an initial value. Further, the auto white balance control for still image shooting starts from an auto white balance control point B′244 for still images on the high color temperature side as an initial value. Subsequently, white balance detection of the moving image and the still image is performed, and the detected colors are compared.

  If the detected color in moving image shooting is closer to white than the detected color in still image shooting, the control point in auto white balance control for still image shooting is changed from the current control point B'244 to the current moving image auto white. The process proceeds to the still image auto white balance control point C ′ 248 corresponding to the balance control point C247, and still image shooting auto white balance control is subsequently performed. On the other hand, the auto white balance control for moving image shooting continues the control as it is.

  Conversely, when the detected color in still image shooting is closer to white than the detected color in moving image shooting, the control point for moving image shooting auto white balance control is changed from the current control point A241 to the current still image auto Moving to the moving image auto white balance control point D249 corresponding to the white balance control point D′ 250, the moving image shooting auto white balance control is continued. On the other hand, the auto white balance control for still image shooting continues the control as it is.

  Here, conversion processing from the moving image auto white balance control point C247 to the still image auto white balance control point C'248, and the still image auto white balance control point D'250 to the moving image auto white balance control point D249. The conversion process is performed based on the Still / Movie conversion table or the Still / Movie conversion formula.

  As described above, in a two-plate image pickup apparatus capable of simultaneously recording moving images and still images, there is a mutual conversion table or conversion formula relating to white balance control between moving image and still image signal processing. Auto white balance control for signal processing for which the initial value was not selected is converted from the control for the other signal processing for which the initial value is selected based on the conversion table or conversion formula, thereby converging auto white balance control. Time can be shortened, and quicker and more accurate auto white balance control can be realized.

1 is a schematic configuration diagram illustrating a configuration of an imaging apparatus according to a first embodiment of the present invention. It is a perspective view which shows the general appearance of the imaging device of this invention. It is a flowchart which shows the auto white balance control process of the signal processing for moving images at the time of starting of 1st Example of this invention. It is a flowchart which shows the auto white balance control process of the signal process for still images at the time of starting of the 1st Example of this invention. It is a figure which shows the auto white balance control axis | shaft in 1st Example of this invention. It is a schematic block diagram which shows the structure of the imaging device of the 2nd Example of this invention. It is a flowchart which shows the auto white balance control process of the signal processing for moving images at the time of starting of 2nd Example of this invention. It is a flowchart which shows the auto white balance control process of the signal process for still images at the time of starting of 2nd Example of this invention. It is a figure which shows the auto white balance control axis | shaft in 2nd Example of this invention.

Explanation of symbols

101 Lens 102 Aperture 103 Half mirror 104 Shutter 105 Movie CCD
106 CCD Control Unit for Movie 107 CCD for Still
108 Still CCD controller 111 Camera microcomputer 112 Movie signal processor 114 Still signal processor 115 Magnetic tape 116 Display 118 Memory card 120 Imaging device body 121 Lens unit 122 Microphone 123 Electronic viewfinder (EVF)
124 Trigger switch for moving picture 125 Trigger switch for still picture 126 Mode dial 127 Operation switch group 128 Liquid crystal panel 129 Speaker 130 Battery 131 Flashing device 141 Auto white balance control point A for moving picture
142 Auto White Balance Control Point B for Movie
143 Auto white balance control point A ′ for still image
144 Auto white balance control point B 'for still images
145 Auto White Balance Control Axis 146 for Movie Auto White Balance Control Axis 201 for Still Image Lens 202 Aperture 203 Half Mirror 204 Shutter 205 CCD for Movie
206 CCD Control Unit for Movie 207 CCD for Still
208 Still CCD control unit 210 Still / Movie conversion table 211 Camera microcomputer 212 Movie signal processing unit 214 Still signal processing unit 215 Magnetic tape 216 Display 218 Memory card 241 Movie auto white balance control point A
244 Auto white balance control point B 'for still image
245 Video auto white balance control axis 246 Still picture auto white balance control axis 247 Movie auto white balance control point C
248 Auto White Balance Control Point C 'for Still Images
249 Video auto white balance control point D
250 Auto white balance control point D 'for still image

Claims (8)

In an imaging apparatus having first and second image sensors, and first and second signal processing means for output signals of the first and second image sensors,
The first signal processing and the second signal processing have different white balance initial values, and the white balance control is performed by selecting an initial value that is closer to the startup environment. apparatus.   2. The imaging apparatus according to claim 1, wherein the first image sensor is an image sensor for moving image shooting, and the second image sensor is an image sensor for still image shooting.   The white balance initial value in the first signal processing is set to a lower color temperature side than the white balance initial value in the second signal processing. Imaging device.   3. The white balance initial value in the first signal processing is set to a higher color temperature side than the white balance initial value in the second signal processing. Imaging device. In an imaging apparatus having first and second image sensors, and first and second signal processing means for output signals of the first and second image sensors,
The mutual conversion table regarding the white balance control between the first signal processing and the second signal processing, having an initial value of white balance different between the first signal processing and the second signal processing. Alternatively, select the initial value closer to the startup environment with the conversion formula, and the white balance control of the signal processing that was not selected the initial value, the control of the other signal processing that was selected the initial value, An image pickup apparatus that performs conversion based on the conversion table or conversion formula and continues white balance control.   6. The imaging apparatus according to claim 5, wherein the first image sensor is an image sensor for moving image shooting, and the second image sensor is an image sensor for still image shooting.   The white balance initial value in the first signal processing is set to a lower color temperature side than the white balance initial value in the second signal processing. Imaging device.   The white balance initial value in the first signal processing is set to a higher color temperature side than the white balance initial value in the second signal processing. Imaging device.

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