JP3809211B2 - Imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of image pickup devices, particularly to the technical field related to exposure control.
[0002]
[Prior art]
The configuration and operation of a conventional imaging device will be described below with reference to the block diagram of FIG.
[0003]
The configuration of the imaging apparatus shown in FIG. 8 is that 1 is an imaging lens group for a subject, 2 is a diaphragm mechanism means having a diaphragm blade structure that controls the amount of incident light, 3 is a drive motor that drives the diaphragm mechanism means 2, and 4 is a drive A diaphragm mechanism driving means 5 for driving the motor 3 is a transmittance variable filter means for controlling the light transmittance of incident light, and 6 is a transmittance variable filter driving means for driving the transmittance variable filter means 5.
[0004]
8 is an image sensor that photoelectrically converts incident light, 9 is an image sensor driving unit that controls a so-called electronic shutter function that controls the image sensor 8 to read the photoelectrically converted signal and controls the signal accumulation time. CDS / AGC means for performing auto gain control (hereinafter referred to as AGC) for sampling a signal photoelectrically converted by the image pickup device 8 and electrically amplifying the signal, and 11 an analog signal which is an output of the CDS / AGC means 10 Is an analog-digital conversion (hereinafter referred to as A / D conversion) means for converting the signal into a digital signal.
[0005]
Reference numeral 12 denotes camera signal processing means for generating a standard television signal by applying a synchronization signal after processing such as gamma correction, color separation, and color difference matrix. Here, the processing configuration necessary for explaining the conventional example of the present invention is shown. Only a portion is shown, 121 is a luminance / color signal generating means for separating the signal generated by the image sensor 8 into a luminance signal and a color signal, 122 is a red gain control means for controlling the gain for the red signal, 123 Is a blue gain control means for controlling the gain with respect to the blue signal, 124 is a color difference signal generating means for generating the color difference signals (RY) and (BY), and 125 is the color difference signal (RY), (B The color difference gain correcting means 126 for performing gain control for -Y), and an encoder means 126 for converting into a standard television signal.
[0006]
Reference numeral 13 denotes a digital-analog conversion (hereinafter referred to as D / A conversion) means for converting the output signal of the camera signal processing means 12 from a digital signal state to an analog signal, and reference numeral 14 fixes a white balance state to a preset state. To operate a so-called white balance preset function (hereinafter referred to as WB preset function) or a so-called white balance set function (hereinafter referred to as WB set function) that automatically optimizes the white balance state and then fixes the state. Key input means for inputting the trigger signal.
[0007]
Reference numeral 16 denotes an aperture mechanism 2, an electronic shutter function of the image sensor 8, an exposure control means for controlling exposure by controlling the AGC of the CDS / AGC means 10, a red gain control means 122, and a blue gain control means 123 to control white balance. It is a microcomputer provided with the white balance control means which controls a state.
[0008]
Automatic exposure control that automatically optimizes the brightness of the subject being photographed from moment to moment in order to enable the optimum image to be obtained with a simple shooting operation. There are automatic white balance control means for automatically optimizing the means and white balance state.
[0009]
Next, automatic exposure control means will be described.
[0010]
The exposure control of the microcomputer 16 detects the luminance signal generated by the luminance / color signal generation unit 121 of the camera signal processing unit 12, and according to the luminance signal, the AGC gain of the CDS / AGC unit 10, the aperture mechanism unit 2, The transmittance variable filter means 5 is controlled according to the control flowchart shown in FIG. 10 and the program diagram shown in FIG.
[0011]
In photographing under sufficient illuminance such as outdoors (area B shown in FIG. 9), the AGC gain is set to the minimum gain, and the transmittance variable filter means 5 is set to the maximum transmittance state (shown in FIG. 9 is 100%). Then, the control amount of the aperture mechanism means 2 is obtained in accordance with the signal detected in the exposure data detection step (S101 shown in FIG. 10) in the control value calculation step S109, and the exposure control according to the brightness of the subject is performed. When the brightness of the subject becomes dark and the diaphragm mechanism means 2 is in the open state (area A shown in FIG. 9) and cannot be controlled by the diaphragm mechanism means 2, the diaphragm mechanism means 2 is opened, and the transmittance variable filter means 5 is opened. In the maximum transmittance state, an AGC gain control amount corresponding to the brightness of the subject is obtained in the control value calculation step S104, and exposure control corresponding to the brightness of the subject is performed.
[0012]
On the contrary, when the brightness of the subject is high illuminance, the aperture mechanism means 2 is in a small aperture state, and there is a problem that a diffraction phenomenon occurs and the image quality deteriorates. This problem is likely to occur even during general outdoor photography as the performance of the image pickup device 8 is improved and the size is reduced due to recent technological advances. I came. Therefore, when the diaphragm mechanism means 2 is in a small diaphragm state where a diffraction phenomenon occurs (area C shown in FIG. 9), the AGC gain is set to the minimum gain, and the diaphragm mechanism means 2 is a small diaphragm that does not cause the diffraction phenomenon. In this state, the transmittance of the transmittance variable filter means is obtained in the control value calculation step S107 according to the signal detected in the exposure data detection step S101, and exposure control is performed according to the brightness of the subject. The control value of each parameter obtained in this way is output in the control value output step S110, and the control value is updated to always follow the brightness of the subject so as to achieve an optimal exposure state.
[0013]
Next, automatic white balance control means will be described.
[0014]
The camera signal processing unit 12 corrects the gain of the red signal R and the blue signal B generated by the luminance / color signal generation unit 121 by the gain control units 122 and 123, respectively, and the low frequency component generated by the luminance / color signal generation unit 121. Are input to the color difference signal generation means 124 together with the luminance signal YL, and color difference signals (R−Y) and (B−Y) are generated. Further, the color difference signal is gain-corrected by the color difference gain correction means 125 and then input to the encoder means 126 together with the luminance signal to generate a standard television signal. The white balance control means of the microcomputer 16 detects the color difference signal and controls the red gain control means 122 and the blue gain control means 123 according to the color difference signal.
[0015]
Next, the operation of the white balance control means of the microcomputer 16 will be described with reference to a control flowchart shown in FIG.
[0016]
First, automatic white balance means for automatically performing white balance control according to the shooting situation detects the color signal of the subject from the color difference signals (RY) and (BY) in the color data detection step S901, and determines the R signal state. In step S910, in the B signal state determination step S914, the red signal, the blue signal and the reference value corresponding to white are compared, and if not appropriate, the red gain control unit 122 and the blue gain control unit 123 White balance control is automatically performed by correcting the gain and outputting the correction data in the control value output step S908. When a trigger signal for selecting a WB preset function is input from the key input means 14, the trigger signal is determined in a WB preset function determination step S902, and detected in the color data detection step S901 in a WB preset control step S909. Regardless of the color data, the control values of the respective gains of the red gain control means 122 and blue gain control means 123 in a white state having a predetermined color temperature set in advance are output. Similarly, when the WB set function is selected by the key input unit 14, the color information of the subject is detected in the same manner as the automatic white balance unit, and the gain control of the red gain control unit 122 and the blue gain control unit 123 is performed. When the statuses of the red signal and the blue signal are both appropriate values, the WB set function is performed by holding the red and blue gains at that time in the hold step S907.
[0017]
[Problems to be solved by the invention]
However, since the above-described variable transmittance filter means has different spectral characteristics depending on the light transmittance, even if the white balance state is optimally controlled, the brightness of the subject changes and the light transmittance of the variable transmittance filter means changes. Then, the spectral characteristics also change, and there is a problem that the optimal white balance state cannot be maintained. In particular, when the WB preset function or the WB set function is used, the white balance control state is fixed, so that the change in spectral characteristics of the transmittance variable filter means directly affects the white balance state.
[0018]
An object of the present invention is to provide an imaging apparatus capable of maintaining an optimal white balance state and obtaining an optimal image even when exposure control is performed using a transmittance variable filter means.
[0019]
[Means for Solving the Problems]
The present invention achieves the above object by the following configuration.
(1) An image sensor that photoelectrically converts light incident from an object imaging lens, and a variable transmittance that changes the light transmittance of the light incident on the image sensor provided on the optical path of the imaging lens. The filter means and the signal photoelectrically converted by the image sensor are processed. TV signal Signal processing means for generating an image signal, and the generated Projection An image pickup apparatus comprising a white balance control means for controlling a white balance state of an image signal,
The image pickup apparatus according to claim 1, wherein the white balance control unit changes a correction amount per unit control for correcting a white balance state according to a change amount of light transmittance of the transmittance variable filter unit.
(2) An image sensor that photoelectrically converts light incident from an object imaging lens, and a variable transmittance that changes the light transmittance of the light incident on the image sensor provided on the optical path of the imaging lens. The filter means and the signal photoelectrically converted by the image sensor are processed. TV signal Signal processing means for generating an image signal, and the generated Projection An image pickup apparatus comprising a white balance control means for controlling a white balance state of an image signal,
The imaging apparatus according to claim 1, wherein a correction interval for correcting a white balance state is changed by the white balance control unit in accordance with a change amount of light transmittance of the transmittance variable filter unit.
(3) An image sensor that photoelectrically converts light incident from an object imaging lens, and a variable transmittance that changes the light transmittance of light incident on the image sensor provided on the optical path of the imaging lens. A filter means; a signal processing means for processing a signal photoelectrically converted by the imaging device to generate a video signal to be a television signal; a white balance control means for controlling a white balance state of the generated video signal; An imaging apparatus comprising white balance holding means for holding a state controlled by the white balance control means,
An image pickup apparatus that corrects a white balance state according to a light transmittance of the transmittance variable filter means when the white balance state is held by the white balance holding means.
(4) When the white balance holding means holds the white balance state, the white balance control means generates correction data for optimally correcting the white balance state according to the light transmittance of the transmittance variable filter means. Comprising a stored data table, selecting correction data in the data table in accordance with a change amount of light transmittance of the transmittance variable filter, and correcting the selected correction data to a current white balance control state. The imaging device according to (3).
[0026]
DETAILED DESCRIPTION OF THE INVENTION
An image pickup apparatus according to the present invention intends to achieve the above object by a configuration including a correction unit that corrects a white balance control unit in accordance with the light transmittance of the transmittance variable filter unit. .
[0027]
Even if exposure control is performed using the transmittance variable filter means with the above-described configuration, an optimal white balance state can be maintained, and an optimal image corresponding to various subjects and shooting conditions can be provided.
[0028]
The above embodiment will be described in detail by way of examples.
[0029]
【Example】
Embodiments of the present invention will be described below with reference to the drawings.
[0030]
(First embodiment)
FIG. 1 is a block diagram showing the configuration of the first embodiment of the present invention. The portion denoted by the same reference numerals in FIG. 8 of the conventional example is a block having the same function as that of the conventional example, and the process of processing the video signal is the same.
[0031]
In the embodiment of the present invention, a transmittance detecting means 7 for detecting the transmittance of the transmittance variable filter means is added, and the processing of the white balance control means in the microcomputer 15 of the first embodiment of the present invention is different from the conventional example. The process is controlled according to the control flowchart shown in FIG. The control of the exposure control means is the same as in the conventional example.
[0032]
Next, the operation of the automatic white balance control means characteristic of the first embodiment of the present invention will be described with reference to the control flowchart of FIG.
[0033]
As in the prior art, the automatic white balance control means detects the color signal of the subject from the color difference signals (R−Y) and (B−Y) in the color data detection step S201, and the R signal state determination step S203 and the B signal state determination step. In S211, a red signal, a blue signal, and a reference value corresponding to white are compared, and if they are not suitable, the gains of the red gain control unit 122 and the blue gain control unit 123 are corrected according to the difference from the reference value, and a control value output In step S219, white balance control is automatically performed by outputting the correction data.
[0034]
Here, when the brightness of the subject is in the state of the area C shown in FIG. 9, exposure control is performed by the transmittance variable filter means 5, but the light transmittance of the transmittance variable filter means 5 changes according to the brightness of the subject. Then, the spectral characteristics also change as shown in FIG. Therefore, even if the color temperature state of the subject is constant, when the brightness of the subject changes, the spectral characteristic changes in order to vary the light transmittance of the transmittance variable filter means 5, and the light incident on the image sensor 8 changes. Affects the color temperature state.
[0035]
For example, when the spectral characteristic of the transmittance variable filter means 5 is 100% as shown in FIG. 3, the light transmittance is flat in all wavelengths, and the light of any wavelength is uniformly transmitted. However, if the light transmittance at a wavelength of 550 nm is reduced to 50% and 20%, the transmittance is higher in the wavelength region on the blue side than on the red side. When the light transmittance is 100%, white balance is obtained. Even if the state is optimally controlled, if the light transmittance of the transmittance variable filter means decreases, the color component ratio on the blue side increases and the white balance state shifts to the blue side.
[0036]
Thus, even if the light transmittance of the transmittance variable filter means 5 changes and the white balance state temporarily shifts, the automatic white balance control means detects the amount of shift of the white balance state from the color signal of the video, Correction can be made for feedback control. However, except when the light source changes greatly, such as when shooting from indoor shooting to outdoor shooting, the color temperature condition rarely changes greatly when shooting at the same time. It is slow so as not to stand out.
[0037]
For example, when the deviation amount E in the white balance state is detected, the correction amount C that optimizes the white balance is not corrected at a time, but is multiplied by the correction coefficient K (K <1). In addition, by using C ′ (C ′ = K * C), the correction amount per unit control is reduced, and control is performed so as to gradually become suitable. Therefore, it takes time until the optimal state is controlled once the white balance state shifts once the light transmittance of the transmittance variable filter means 5 changes. Furthermore, since the brightness of the subject is not constant but always changes, the light transmittance of the transmittance variable filter means 5 always changes, and the white balance state continues to be unstable.
[0038]
In the R gain control unit and B gain control unit of the automatic white balance control means of the embodiment of the present invention, the red signal, the blue signal and the reference value corresponding to white are compared with each other. The gain control unit 122 and the blue gain control unit 123 perform gain correction. The transmittance detection unit 7 detects the light transmittance of the transmittance variable filter unit, and the transmittance variable filter unit 5 is fixed at a constant light transmittance. When the correction is performed, the correction amount C1 (C1 = K1 * C), which is obtained by multiplying the correction amount C by the correction coefficient K1 (K1 <1), reduces the white balance correction amount per unit control and corrects the change. Make it inconspicuous.
[0039]
When the light transmittance of the transmittance variable filter means 5 is changed, the white balance correction amount per unit control is obtained by C2 (C2 = K2 * C) obtained by multiplying the correction amount C by the correction coefficient K2 (K1 <K2 <1). Is made larger than when the light transmittance of the variable transmittance filter means is constant, and control is performed so as to quickly correct the deviation of the white balance state caused by the variable transmittance filter means.
[0040]
The control flowchart of FIG. 2 shows the case where the correction amount is set in two stages depending on whether the light transmittance of the transmittance variable filter means 5 is changed or not. Accordingly, the white balance correction amount may be varied.
[0041]
(Second embodiment)
The configuration of the second embodiment of the present invention is the same as that of the first embodiment, and only the white balance control means inside the microcomputer 15 of FIG. 1 is different. FIG. 4 is a control flowchart of the second embodiment. Indicates.
[0042]
Next, the operation of the automatic white balance control means characteristic of the second embodiment of the present invention will be described with reference to the control flowchart of FIG.
[0043]
In the second embodiment, as in the first embodiment, the automatic white balance control means detects the color signal of the subject from the color difference signals (RY) and (BY) in the color data detection step S401, and R In the signal state determination step S406 and the B signal state determination step S410, the red signal, the blue signal, and the reference value corresponding to white are compared, and if not appropriate, the R gain control steps S407, S408, S409 are performed according to the difference from the reference value Then, the red gain control means 122 is corrected, and the gain of the blue gain control means 123 is corrected in the B gain control steps S411, S412 and S413. In the control value output step S414, white balance control is automatically performed by outputting the correction data.
[0044]
The white balance correction amount of the R gain control unit and the B gain control unit at this time is obtained by multiplying the correction amount C (K <1) by the correction amount C that optimizes the white balance with respect to E by the deviation amount of the white balance state. According to C ′ (C ′ = K * C), the correction amount per unit control is reduced, and control is performed so as to gradually become suitable. However, the correction coefficient K is constant regardless of the change in the light transmittance of the transmittance variable filter means 5.
[0045]
However, in the timer control step S404 and the WB control operation determination step S405, the interval for performing the white balance correction operation is controlled, the light transmittance of the transmittance variable filter means 5 is detected by the transmittance detection means 7, and the transmittance variable filter means 5 is detected. Is controlled to increase the interval T1 of the white balance correction operation when the light transmittance is fixed at a constant light transmittance, slow down the follow-up property, and make the correction change inconspicuous in the image.
[0046]
On the contrary, when the transmittance of the variable transmittance filter means 5 is changed, the follow-up property is corrected by correcting at the interval T2 (T2 <T1) shorter than the correction interval T1 when the light transmittance of the variable transmittance filter means is constant. To quickly correct according to the change in the color temperature state due to the change in the light transmittance.
[0047]
The control flowchart of FIG. 4 shows a case where the interval of the white balance correction operation is not set when the light transmittance of the transmittance variable filter means 5 changes, but the white balance correction operation according to the amount of change in the light transmittance. The interval may be variable.
[0048]
(Third embodiment)
The configuration of the third embodiment of the present invention is the same as that of the first embodiment, and only the white balance control means inside the microcomputer 15 shown in FIG. A flowchart is shown.
[0049]
Next, the operation of the automatic white balance control means, which is a feature of the third embodiment of the present invention, will be described with reference to the control flowchart of FIG.
[0050]
In the third embodiment, correction data for R gain and B gain necessary for each light transmittance are preset in the correction data reading step S504 in accordance with the spectral characteristics of the light transmittance of the transmittance variable filter means 5. When the light transmittance of the transmittance variable filter means 5 is changed by providing a lookup table (hereinafter referred to as LUT), correction data corresponding to the amount of change in light transmittance is selected from the aforementioned LUT, and R / By correcting the LUT data to the current white balance correction amount in the B gain correction step S505, the white balance state is not affected by the change in the spectral characteristics of the transmittance variable filter means.
[0051]
For example, when the spectral characteristic of the transmittance variable filter means 5 is as shown in FIG. 3, the LUT shown in FIG. 6 is provided. 3 and 6, when the light transmittance near 550 nm wavelength is 100%, the light transmittance near 550 nm wavelength is 50%, the red light transmittance is lower than 50%, and the blue light Since the transmittance is higher than 50%, the blue component is relatively increased even when the color temperature of the light source of the subject is not changed, and the blue balance is shifted from the white balance state when the light transmittance is 100%. End up. Therefore, the correction amount when the light transmittance is 50% from the LUT shown in FIG. 6 is R gain of +2 dB and B gain of −1.5 dB, and this correction amount is a set value of the R gain and B gain when the light transmittance is 100%. It is possible to maintain the white balance state when the light transmittance is 100%.
[0052]
(Fourth embodiment)
The configuration of the fourth embodiment of the present invention is the same as that of the first embodiment, and only the white balance control means inside the microcomputer 15 shown in FIG. A flowchart is shown.
[0053]
In the first, second and third embodiments, the means for correcting the change in the white balance state when the light transmittance of the transmittance variable filter means in the automatic white balance control means has been described. Even if the correction is not performed as in the first, second, and third embodiments, even if the image is temporarily deteriorated, correction is made to optimize the white balance gradually over time. Although the operation is performed, when the white balance state is fixed by the WB preset function or the WB set function, the change in the spectral characteristics by the transmittance variable filter means 5 directly affects the white balance state. The fourth embodiment is characterized in that, when the white balance state is fixed using the WB preset function or the WB set function, the change in the white balance state when the light transmittance of the transmittance variable filter means changes is corrected. To do.
[0054]
Next, the operation of the white balance control means of the WB preset function and the WB set function, which are the features of the fourth embodiment of the present invention, will be described with reference to the control flowchart of FIG. 7 and FIG.
[0055]
In the fourth embodiment, the transmittance detection means 7 changes the transmittance with respect to the gain values of the red gain control means 122 and the blue gain control means 123 fixedly set in the WB preset control step S711 and the WB set control step S707. The light transmittance of the filter unit 5 is detected, and the gain value fixed according to the light transmittance of the transmittance variable filter unit 5 is corrected in the R gain / B gain correction step S709.
[0056]
In the R gain / B gain correction step S 709, correction data for R gain and B gain necessary for each light transmittance according to the spectral characteristics of the light transmittance of the transmittance variable filter means 5 as in the third embodiment. Are provided in a preset LUT. For example, when the spectral characteristic of the transmittance variable filter means 5 is as shown in FIG. 3, the LUT shown in FIG. 6 is provided. 3 and 6, when the white balance state is fixed using the WB preset function or the WB set function when the light transmittance near the 550 nm wavelength is 100%, and the light transmittance near the 550 nm wavelength becomes 50%. Since the light transmittance of red is lower than 50% and the light transmittance of blue is higher than 50%, even if the color temperature of the light source of the subject does not change, the blue component is relatively increased, and the light The white balance state when the transmittance is 100% shifts to the blue side. Therefore, the correction amount when the light transmittance is 50% is +2 dB and the B gain is −1.5 dB from the LUT in FIG. 6, and this correction amount is set to the R gain and B gain setting values when the light transmittance is 100%. By correcting, the white balance state when the light transmittance is 100% can be maintained.
[0057]
The white balance correcting means of the first, second, third and fourth embodiments described above are the gains of the red gain control means 122 and the blue gain control means 123 according to the light transmittance of the transmittance variable filter means 5. However, when the spectral characteristics change, the color balance also changes. Therefore, if the color difference is also corrected by the color difference gain correction means 125, a more optimal image can be maintained.
[0058]
【The invention's effect】
As described above, according to the present invention, an imaging apparatus capable of maintaining an optimal white balance state and obtaining an optimal image even when exposure control is performed using a transmittance variable filter means. Can be provided. Details thereof will be described below.
[0060]
Book No. related to application 1 According to the invention, white balance control Means for changing the light transmittance of the variable transmittance filter means by changing the correction amount per unit control for correcting the white balance state in accordance with the change amount of the light transmittance of the variable transmittance filter means. As a result, the followability of white balance correction can be optimized, and an optimal image with inconspicuous change in white balance correction can be obtained.
[0061]
In addition, the 2 According to the invention, white balance control Correction interval for correcting the white balance state in accordance with the amount of change in light transmittance of the transmittance variable filter means But change Do According to the configuration, the followability of the white balance correction can be optimized with respect to the change in the light transmittance of the transmittance variable filter means, and an optimal image in which the change in the white balance correction is not noticeable can be obtained.
[0063]
In addition, the 3 According to the invention, the white balance holding means for holding the state controlled by the white balance control means is provided, and when the white balance state is held by the white balance holding means, the light transmission of the transmittance variable filter means Even if the light transmittance of the variable transmittance filter means changes when the white balance state is fixed using the WB preset function or the WB set function, the optimum white balance is corrected. Can keep the state.
[0064]
In addition, the 4 According to the invention, the white balance holding means for holding the state controlled by the white balance control means and the correction data for optimally correcting the white balance state according to the amount of change in the light transmittance of the variable transmittance filter means. In the case where a white balance state is held by the white balance holding unit, the correction data of the data table is selected according to the amount of change in the light transmittance of the variable transmittance filter, and the selection is performed. Even if the light transmittance of the variable transmittance filter means changes when the white balance state is fixed using the WB preset function or the WB set function, the white balance control state is corrected to the current white balance control state. Optimal video with no change in balance can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing the configuration of a first embodiment of the present invention.
FIG. 2 is a control flowchart of white balance control means of the first embodiment.
FIG. 3 is an explanatory diagram of spectral characteristics of a transmittance variable filter means.
FIG. 4 is a control flowchart of white balance control means of the second embodiment.
FIG. 5 is a control flowchart of white balance control means of the third embodiment.
FIG. 6 is an explanatory diagram of a lookup table according to the third embodiment.
FIG. 7 is a control flowchart of white balance control means of the fourth embodiment.
FIG. 8 is a block diagram showing a configuration of a conventional example
FIG. 9 is a program diagram of conventional exposure control means.
FIG. 10 is a control flowchart of conventional exposure control means.
FIG. 11 is a control flowchart of conventional white balance control means.
[Explanation of symbols]
1 Subject imaging lens
2 Aperture mechanism means
3 Aperture drive motor
4 Aperture mechanism drive means
5 Transmittance variable filter means
6 Transmittance variable filter drive means
7 Transmittance detection means
8 Image sensor
9 Image sensor drive means
10 CDS / AGC means
11 A / D conversion means
12 Signal processing means
13 D / A conversion means
15 Microcomputer of the first embodiment
16 Conventional microcomputer

Claims (4)

An image sensor that photoelectrically converts light incident from an object imaging lens; and a transmittance variable filter means that changes a light transmittance of light incident on the image sensor provided on an optical path of the imaging lens. , and a white balance control means for controlling a signal processing device which generates movies image signal comprising a television signal subjected to the processing on the photoelectric conversion signal, the white balance state of the movies image signal said generated by the image sensor An imaging device comprising:
The image pickup apparatus according to claim 1, wherein the white balance control unit changes a correction amount per unit control for correcting a white balance state according to a change amount of light transmittance of the transmittance variable filter unit. An image sensor that photoelectrically converts light incident from an object imaging lens; and a transmittance variable filter means that changes a light transmittance of light incident on the image sensor provided on an optical path of the imaging lens. , and a white balance control means for controlling a signal processing device which generates movies image signal comprising a television signal subjected to the processing on the photoelectric conversion signal, the white balance state of the movies image signal said generated by the image sensor An imaging device comprising:
The imaging apparatus according to claim 1, wherein a correction interval for correcting a white balance state is changed by the white balance control unit in accordance with a change amount of light transmittance of the transmittance variable filter unit. An imaging device for photoelectrically converting light incident Ri by lens for object imaging, transmittance variable filter for varying the light transmittance of light incident to the imaging element provided in the optical path of the lens for the imaging means, signal processing means for generating a video signal comprising a television signal subjected to the processing on the photoelectric conversion signal by the imaging device, and white balance control means control the white balance state of the generated video signal, An imaging apparatus comprising white balance holding means for holding a state controlled by the white balance control means,
An image pickup apparatus that corrects a white balance state according to a light transmittance of the transmittance variable filter means when the white balance state is held by the white balance holding means. The white balance control means stores correction data for optimally correcting the white balance state according to the light transmittance of the transmittance variable filter means when the white balance holding means holds the white balance state. A correction table of the data table is selected according to the amount of change in light transmittance of the transmittance variable filter, and the selected correction data is corrected to the current white balance control state. Item 4. The imaging device according to Item 3 .

Images