JP2005210748A - Imaging apparatus and imaging method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging apparatus and an imaging method capable of remarkably shortening the time required for convergence to proper brightness using a simple method. <P>SOLUTION: When a user selects an initial brightness adjustment quantity setting mode by a mode key operation of a key input section 18 provided in a digital camera 10, an initial brightness adjustment quantity setting screen 20 is displayed on a liquid crystal screen of an LCD unit 16 in place of an initial screen. When the user inputs and sets an arbitrary initial brightness adjustment quantity by a cursor key operation in such a display state, the input and set brightness adjustment quantity is stored in a non-volatile memory 17. Thereafter, when the user operates a power supply on/off key to turn off a power supply and then turn on the power supply again, the brightness adjustment operation relative to an imaging device 11 is started by using the initial brightness adjustment quantity stored in the non-volatile memory 17. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an imaging apparatus and an imaging method suitable for use in a camera apparatus such as a digital camera having an automatic brightness adjustment function.

  2. Description of the Related Art Conventionally, in an imaging apparatus such as a digital camera, in order to continuously display an automatic brightness adjustment function, that is, a finder (through) image with appropriate brightness on a monitor, an “image output from an imaging element such as a CCD” A function that calculates the average luminance value of the signal and repeats the process of increasing / decreasing the aperture amount, luminance adjustment amount, gain, etc. at the next CCD exposure at a certain rate based on the average luminance value at each CCD exposure timing. Many have been adopted.

  FIG. 8A is a diagram showing a time transition state from the time of power-on of the luminance average value calculated based on the image signal output from the CCD, and FIG. 8B is a graph showing the luminance adjustment amount of the CCD. FIG. 8C is a diagram showing a time transition state from when the power is turned on, and FIG. 8C is a time transition state from when the power is turned on at the amplification factor set in the AGC amplifier for adjusting the level of the image signal output from the CCD FIG. 8D is a diagram showing a time transition state from the time of power-on of the diaphragm amount set in the diaphragm device arranged in front of the CCD. Note that the average brightness value is a value that increases when the subject is bright and decreases when the subject is dark, as shown in the figure, and is calculated based on the image signal output from the AGC amplifier. FIGS. 8A to 8D show examples in which the brightness of the surrounding (subject) hardly changes. FIGS. 8B to 8D show images. When adjusting the brightness of the signal, an example is shown in which three of the brightness adjustment amount, the aperture amount, and the gain are adjusted equally in a balanced manner.

  As shown in FIG. 8 (a), immediately after the power is turned on, if the average luminance value of the image signal captured from the CCD through the diaphragm device and amplified by the AGC gain amplifier is higher than the appropriate value, FIG. 8 (b) to FIG. As shown in FIG. 8 (d), while the determination that the luminance average value is high is repeated, the luminance adjustment amount is shortened stepwise, the aperture area of the aperture device is narrowed stepwise, and the gain is decreased stepwise. Thus, an image signal with appropriate brightness is obtained. On the contrary, immediately after the power is turned on, if the average luminance value of the image signal captured from the CCD through the diaphragm device and amplified by the AGC amplifier is lower than the appropriate value, the determination that the average luminance value is low is repeated. The brightness adjustment amount is increased stepwise, the aperture area of the aperture device is increased stepwise, and the gain is increased stepwise to obtain an image signal with appropriate brightness.

  Although it is unclear whether the surroundings are bright or dark at the time of initial power-on of the image pickup apparatus in the above-described conventional technology, predetermined fixed values (predetermined values) are set as the initial exposure time, initial aperture amount, and initial gain. Therefore, depending on the ambient brightness, an image signal with a brightness that is far from the correct brightness may be obtained immediately after the initial power-on. In this case, the brightness of the image signal is the appropriate brightness. There was a problem that it took a long time to become.

  As a method for solving the above-described conventional problems, it is appropriate to increase the rate of change of the brightness adjustment amount and then reduce the rate of change of the brightness adjustment amount for a predetermined period immediately after the initial power-on of the imaging device. There is a method of shortening the time required for convergence to luminance (see Patent Document 1).

JP 2000-253321 A

However, the above-described solution uses a combination of the first luminance adjustment operation in which the rate of change in the luminance adjustment amount is large and the second luminance adjustment operation in which the rate of change in the luminance adjustment amount is small and the power is turned on. Since it is necessary to switch from the first luminance adjustment operation to the second luminance adjustment operation after a predetermined time, there is a problem that the luminance adjustment operation becomes complicated.
Although the above solution can reduce the time required to converge to the appropriate brightness to some extent, the predetermined fixed values are set as the initial exposure time, the initial aperture amount, and the initial gain. Since it is similar to technology, it cannot achieve significant time savings.

  The present invention has been made in view of such conventional problems, and provides an imaging apparatus and an imaging method capable of significantly reducing the time required to converge to appropriate luminance using a simple method. With the goal.

  In order to solve the above-described problem, the imaging apparatus according to claim 1 is an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal, wherein the imaging unit includes luminance of the image signal. A brightness adjustment amount setting means for manually setting an arbitrary brightness adjustment amount; a start instruction means for instructing start of periodic imaging by the imaging means; and a start instruction means. An initial luminance control unit that sets an adjustment amount of a luminance level by the luminance adjustment unit based on the luminance adjustment amount set by the luminance adjustment amount setting unit when the start of periodic imaging is instructed; and the imaging unit Detecting means for detecting the luminance level of the image signal periodically output from the image sensor, and the luminance adjusting means based on the luminance level of the image signal periodically detected by the detecting means And characterized by including a proper brightness control means for setting the adjustment amount of the brightness levels by.

  The imaging apparatus according to claim 2, wherein the imaging apparatus includes an imaging unit that periodically repeats imaging and periodically outputs an image signal. The imaging unit adjusts the luminance level of the image signal. Means for instructing the start of periodic imaging by the imaging means, and periodically detecting ambient brightness before the start instruction means instructing the start of periodic imaging When the start of periodic imaging is instructed by the brightness detection means and the start instruction means, the brightness level adjustment amount by the brightness adjustment means is determined based on the ambient brightness detected by the brightness detection means. Initial luminance control means for setting, detection means for detecting the luminance level of the image signal periodically output from the imaging means, and the luminance level of the image signal periodically detected by the detection means Based, characterized by comprising a suitable brightness control means for setting the adjustment amount of the brightness level by the brightness adjustment means.

  According to a third aspect of the present invention, there is provided the imaging apparatus according to the second aspect, further comprising a holding unit that holds information based on ambient brightness detected by the brightness detection unit, and the initial luminance control unit includes: When the start instruction unit instructs the start of periodic imaging, the luminance level adjustment amount by the luminance adjustment unit is set based on the information held in the holding unit.

  According to a fourth aspect of the present invention, there is provided an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal. The imaging unit adjusts the luminance level of the image signal. Means for detecting the luminance level of the image signal periodically output from the imaging means, and the luminance by the luminance adjusting means based on the luminance level of the image signal periodically detected by the detection means Appropriate luminance control means for setting a level adjustment amount, end instruction means for instructing the end of periodic imaging by the imaging means, start instruction means for instructing start of periodic imaging by the imaging means, When the end instruction means instructs the end of periodic imaging, the holding means for holding information based on the brightness level adjustment amount by the brightness adjustment means immediately before the instruction, and the opening An initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjusting unit based on information held in the holding unit when the instruction unit instructs to start periodic imaging. Features.

  According to a fifth aspect of the present invention, in the imaging device according to the fourth aspect, the end instruction means includes means for instructing power-off of the imaging apparatus.

  The imaging apparatus according to claim 6, wherein the imaging apparatus includes an imaging unit that periodically repeats imaging and periodically outputs an image signal. The imaging unit adjusts the brightness level of the image signal. A start instruction means for instructing start of periodic imaging by the imaging means, and a shooting environment determination means for determining a shooting environment when start of periodic imaging is instructed by the start instruction means, Based on the shooting environment determined by the shooting environment determination unit, an initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjustment unit, and a luminance level of an image signal periodically output from the imaging unit is detected. Based on the luminance level of the image signal periodically detected by the detecting means and the appropriate luminance control for setting the amount of adjustment of the luminance level by the luminance adjusting means. Characterized in that and means.

  The imaging apparatus according to claim 7, wherein the imaging apparatus includes an imaging unit that periodically repeats imaging and periodically outputs an image signal. The imaging unit adjusts the brightness level of the image signal. A start instruction means for instructing start of periodic imaging by the imaging means, and an acquisition means for acquiring current time information when the start instruction means is instructed to start periodic imaging, Based on the time information acquired by the acquisition unit, an initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjustment unit, and detection that detects a luminance level of an image signal periodically output from the imaging unit And an appropriate brightness control means for setting an adjustment amount of the brightness level by the brightness adjusting means based on the brightness level of the image signal periodically detected by the detecting means. Characterized in that Bei was.

  The imaging apparatus according to claim 8, wherein the imaging apparatus includes an imaging unit that periodically repeats imaging and periodically outputs an image signal, and the imaging unit adjusts the luminance level of the image signal. A shooting mode setting means for manually setting an arbitrary shooting mode among a plurality of types of shooting modes, a start instruction means for instructing start of periodic imaging by the imaging means, and a cycle by the start instruction means When the start of general imaging is instructed, the luminance by the luminance adjustment unit based on the acquisition mode information acquired by the acquisition unit and the acquisition mode information acquired by the acquisition unit Initial luminance control means for setting a level adjustment amount, detection means for detecting the luminance level of an image signal periodically output from the imaging means, and the detection Based on the brightness level of the cyclically image signal detected by the stage, characterized by comprising a suitable brightness control means for setting the adjustment amount of the brightness level by the brightness adjustment means.

  The imaging apparatus according to claim 9, wherein the imaging apparatus includes an imaging unit that periodically repeats imaging and periodically outputs an image signal. The imaging unit adjusts the luminance level of the image signal. A start instruction means for instructing start of periodic imaging by the imaging means, and an acquisition means for acquiring current position information when the start instruction means is instructed to start periodic imaging; Based on the position information acquired by the acquisition unit, an initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjustment unit, and detection that detects the luminance level of an image signal periodically output from the imaging unit And an appropriate brightness control means for setting an adjustment amount of the brightness level by the brightness adjusting means based on the brightness level of the image signal periodically detected by the detecting means. Characterized in that Bei was.

  The imaging apparatus according to claim 10 is the imaging apparatus according to any one of claims 1 to 9, wherein the imaging means includes an imaging element, and the brightness adjusting means adjusts an exposure time of the imaging element. It is characterized by including the means to do.

  An imaging apparatus according to an eleventh aspect is the imaging apparatus according to any one of the first to tenth aspects, wherein the imaging means includes a diaphragm device that adjusts an amount of light applied to the imaging element, and the brightness adjustment. The means includes means for adjusting a diaphragm amount of the diaphragm device.

  The imaging device according to claim 12 is the imaging device according to any one of claims 1 to 11, wherein the imaging means includes an amplifier that amplifies an image signal output from the imaging device, and the brightness adjusting means. Includes means for adjusting the amplification factor of the amplifier.

  The imaging apparatus according to claim 13 is the imaging apparatus according to any one of claims 1 to 12, wherein the start instruction means includes means for instructing power-up of the imaging apparatus. .

  An imaging apparatus according to a fourteenth aspect is the imaging apparatus according to any one of the first to thirteenth aspects, wherein the appropriate luminance control means is based on a luminance level of an image signal periodically detected by the detection means. The brightness level adjustment amount by the brightness adjusting means is increased or decreased by a predetermined amount.

  The imaging method according to claim 15 includes a step of manually setting an arbitrary luminance adjustment amount, a step of instructing the start of periodic imaging by the imaging unit, and the start of periodic imaging by the imaging unit. When instructed, the step of adjusting the luminance level of the image signal output by the imaging unit based on an arbitrary luminance adjustment amount manually set, and the luminance level of the image signal periodically output from the imaging unit And a step of adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the periodically detected image signal.

  The imaging method according to claim 16 includes a step of periodically detecting ambient brightness, a step of instructing start of periodic imaging by the imaging unit, and a periodical start of imaging by the imaging unit. When instructed, the step of adjusting the luminance level of the image signal output by the imaging unit based on the ambient brightness detected immediately before the instruction, and the luminance level of the image signal periodically output from the imaging unit And a step of adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the image signal detected periodically.

  The imaging method according to claim 17, wherein the imaging unit is configured to periodically detect the luminance level of the image signal periodically output from the imaging unit and the luminance level of the image signal periodically detected. Adjusting the luminance level of the image signal to be output, instructing the end of periodic imaging by the imaging unit, and instructing the end of periodic imaging by the imaging unit, The step of holding information based on the adjustment amount of the luminance level, the step of instructing the start of periodic imaging by the imaging unit, and the case of instructing the start of periodic imaging by the imaging unit are held. And adjusting the luminance level of the image signal output from the imaging unit based on the information.

  The imaging method according to claim 18 is a step of instructing start of periodic imaging by the imaging unit, and a step of acquiring current time information when the start of periodic imaging by the imaging unit is instructed. And adjusting the luminance level of the image signal output from the imaging unit based on the acquired time information, detecting the luminance level of the image signal periodically output from the imaging unit, and periodically And adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the detected image signal.

  As described above, according to the invention described in claims 1 and 15, the initial luminance adjustment amount can be manually set in accordance with the user's intention, and the luminance is based on the initial luminance adjustment amount manually set by the user. Since the adjustment can be started, compared to the case where the setting value of the initial luminance adjustment amount is a fixed value as in the prior art, an image signal that is out of brightness immediately after the start of periodic imaging is instructed. The frequency of capturing can be reduced, and the time from when the user gives an instruction to start periodic imaging until it converges to the appropriate luminance can be greatly shortened. As a result, there is no possibility of missing a photo opportunity or shooting an image with a low brightness.

  Further, according to the invention of claim 2 and claim 16, the initial luminance adjustment amount is automatically set according to the ambient brightness, and the luminance adjustment is started by the automatically set initial luminance adjustment amount. Immediately after instructing the start of periodic imaging, it is possible to reduce the frequency of capturing image signals that are out of brightness, and the time from the user instructing the start of periodic imaging to the convergence to the appropriate brightness It can be greatly shortened. Furthermore, the user is freed from the troublesome manual setting.

  According to the invention of claim 4 and claim 17, when the end of periodic imaging is instructed, information based on the luminance adjustment amount immediately before the instruction is retained, and the initial luminance based on the retained information is stored. Since the brightness adjustment is started according to the adjustment amount, it is possible to reduce the frequency of capturing an image signal with a low brightness immediately after instructing the start of periodic imaging, and the user instructs the start of periodic imaging. It is possible to greatly reduce the time until the brightness converges to the appropriate brightness. Furthermore, the user is freed from the troublesome manual setting.

  According to the sixth to ninth and the eighteenth aspects of the present invention, the environment, time, photographing mode, position, etc. at the time when the start of periodic imaging is instructed are determined, and the initial luminance based on the determination result Since the brightness adjustment is started according to the adjustment amount, it is possible to reduce the frequency of capturing an image signal with a low brightness immediately after instructing the start of periodic imaging, and the user instructs the start of periodic imaging. It is possible to greatly reduce the time until the brightness converges to the appropriate brightness. Furthermore, the user is freed from the troublesome manual setting.

<First Embodiment>
FIG. 1 is a block diagram showing a circuit configuration of an embodiment of an image pickup apparatus according to the present invention. A digital camera is taken as an example of the image pickup apparatus.
In FIG. 1, a digital camera 10 includes an imaging unit 11, an A / D converter 12, a signal processing unit 13, a control unit 14, a TG 15, an LCD unit (display unit) 16, a nonvolatile memory 17, a key input unit 18, and A flash memory 19 is provided.

The imaging unit 11 includes an aperture device 111, a CCD (imaging device) 112, and an AGC amplifier 113.
The diaphragm device 111 adjusts the amount of incident light irradiated on the CCD 112.
The CCD 112 takes a subject light image incident through the aperture device 111 and converts it into an image signal, which is output to the AGC amplifier 113.
The AGC amplifier 113 amplifies the image signal output from the CCD 112 and outputs it to the A / D converter 12.

The A / D converter 12 converts the image signal output from the AGC amplifier 113 into a digital signal and outputs the digital signal to the signal processing unit 13.
The signal processing unit 13 performs image processing such as pixel interpolation processing, white balance processing, luminance / color difference signal conversion processing on the image signal output from the A / D converter 12 and outputs the processed image signal to the control unit 14.

  The control unit 14 includes peripheral circuits (not shown) such as a processor (CPU), a program storage memory, and a RAM. In the control unit 14, the processor controls the entire operation of the digital camera 10 and various programs (initial brightness adjustment amount setting program and brightness adjustment) stored in the program storage memory in a timely manner based on the main control program or a selection operation by the user. And the various functions of the digital camera 10 are executed. For example, the initial luminance adjustment amount setting function is executed according to the initial luminance adjustment amount setting program when the main power of the digital camera 10 is turned on, or the luminance adjustment function is executed according to the luminance adjustment program when the main power is turned on.

The TG 15 controls the exposure timing and the brightness adjustment amount of the CCD 112 based on the control signal output from the control unit 14.
The LCD unit 16 displays a through image (finder image) at the time of shooting standby and displays a reproduced image at the time of image reproduction. In addition, for operation assistance, it is possible to display a processing menu at the time of selecting a function and display a setting figure or icon.
The non-volatile memory 17 saves and stores an initial luminance adjustment amount (adjustment value), which will be described later, and holds information that needs to be held even when the power is turned off.

The key input unit 18 includes a function selection key (for example, a mode key) for selecting various functions and screens, a cursor key including four keys, an up key, a down key, a left key, and a right key, a shutter key, a set key, and the like. And a power on / off key (main power key). When these keys are operated, a signal corresponding to the operation state is sent to the processor of the control unit 14.
The flash memory 19 saves and records image data obtained by the imaging unit 11 in response to the operation of the shutter key by the user. The flash memory 19 may be detachable from the digital camera 10, or the initial luminance adjustment amount may be stored in the flash memory 19 instead of the nonvolatile memory 17.

<Manual setting of initial brightness adjustment amount>
2A is a flowchart showing an operation example when setting an initial luminance adjustment amount, FIG. 2B is a flowchart showing an example of luminance adjustment operation when the main power is turned on, and FIG. It is a figure which shows one Example of the initial stage luminance adjustment amount setting screen displayed on some.
In FIG. 2, the processor of the control unit 14 performs the initial luminance adjustment amount setting procedure specified by the initial luminance adjustment amount setting program and the luminance adjustment procedure at the time of main power-on specified by the luminance adjustment program. Control the behavior.

  In FIG. 2A, when the user turns on the main power key of the key input unit 18, a status signal is sent to the processor of the control unit 14 (hereinafter simply referred to as a processor), and the processor displays the liquid crystal screen of the LCD unit 16. The image signal sequentially output from the imaging unit 11 is displayed as a through image on the upper side, and at the same time, an initial screen as shown in a screen A1 in FIG.

  In this state, when the mode key is operated by the user and the initial luminance adjustment amount setting mode is selected, a status signal is sent to the processor (YES in step T2), and the processor replaces the initial screen on the liquid crystal screen with FIG. The initial brightness adjustment amount setting screen 20 as shown in the screen A2 is displayed (step T3). The initial brightness adjustment amount setting screen 20 displayed here is created based on the initial brightness adjustment amount currently held and stored in the nonvolatile memory 17. Further, the initial luminance adjustment amount currently held and stored in the nonvolatile memory 17 is read out and stored in the RAM in the control unit 14.

Subsequently, the processor checks the status signal from the key input unit 18, and transitions to step T5 if the left or right key of the cursor keys is operated by the user, and transitions to step T6 otherwise (step S6). T4).
That is, when the user visually determines the brightness of the subject (surrounding) and determines that the subject is bright, the left key of the cursor key is operated. If the user determines that the subject is dark, the status signal is output by operating the right key of the cursor key. Sent to the processor.

If an operation of the left key is detected in step T4, the dark portion 22 of the initial luminance adjustment amount setting window 21 on the initial luminance adjustment amount setting screen 20 is simultaneously reduced and stored in the RAM as shown in the screen A3 of FIG. The initial brightness adjustment amount is changed, and the process returns to step T3 in order to display the dark portion 22 having an area corresponding to the changed initial brightness adjustment amount on the initial brightness adjustment amount setting window 21 (step T5). When the right key operation is detected in step T4, the dark portion 22 of the initial luminance adjustment amount setting window 21 on the initial luminance adjustment amount setting screen 20 is enlarged, and at the same time, the initial luminance adjustment amount stored in the RAM. And return to step T3.
The processes in steps T3 to T5 are repeated until the initial luminance adjustment amount desired by the user is reached.

  If the user does not operate the left key or the right key in step T4, the processor checks the status signal from the key input unit 18, and if the set key is operated, the process proceeds to step T7. If not, the process returns to step T3. That is, until the user operates the set key, the initial luminance adjustment amount changing process in step T5 is repeated in response to the user's operation of the left key or the right key (step T6).

  When the set key is operated, the processor is changed in the initial luminance adjustment amount changing process in step T5, and the initial luminance adjustment amount stored in the RAM is updated and stored in the nonvolatile memory 17 as a set value. As shown in screen A4, the process returns to step T1 to return to the initial screen (step T7).

  In this way, means for manually setting an arbitrary initial luminance adjustment amount (initial luminance adjustment amount setting screen display processing in step T3, setting value change processing in steps T4 and T5, and setting value update storage processing in step T7). By providing, the initial luminance adjustment amount manually set at the next power-on can be used.

The initial luminance adjustment amount described above is a value that can uniquely determine the initial aperture amount, the initial exposure time, and the initial gain based on the adjustment amount. A correspondence table of the adjustment amount, the initial aperture amount, the initial exposure time, and the initial gain is stored in advance.
For example, in the flowchart of FIG. 2A, when the left key is operated, the initial exposure time is shortened by an amount corresponding to the operation amount (number of operations), the initial aperture amount is increased, and the initial gain is decreased. The initial brightness adjustment amount is updated and stored in the nonvolatile memory 17. Further, when the right key is operated, the initial brightness adjustment amount is updated and stored in the nonvolatile memory 17 so that the initial exposure time is longer, the initial aperture amount is smaller, and the initial gain is larger by an amount corresponding to the operation amount. Is done.

  In the flowchart of FIG. 2A described above, an initial luminance adjustment amount is set so as to lower the initial luminance of the image signal when the user inputs that the subject (ambient) is bright. The initial brightness adjustment amount is set to increase the initial brightness of the image signal when darkness is input, but the user can change the initial brightness adjustment amount by inputting the brightness information of the subject (surrounding) as it is. Instead, when the user determines that the subject (surrounding) is dark, the initial luminance adjustment amount is set so as to increase the initial luminance of the image signal by directly inputting that the initial luminance of the image signal is to be increased. When the user determines that the subject (ambient) is bright, the initial luminance of the image signal is lowered by directly inputting that the initial luminance of the image signal is to be lowered. It may be set the period brightness adjustment amount.

  In the flowchart of FIG. 2A described above, an arbitrary initial luminance adjustment amount is manually input and set, and the arbitrary initial luminance adjustment amount that has been input and set is stored in the nonvolatile memory 17. An arbitrary initial brightness adjustment amount is manually input and set, and an initial aperture amount, an initial exposure time, and an initial gain that are uniquely determined by the input initial setting and the correspondence table are stored in the nonvolatile memory 17. You may make it do.

  In the flowchart of FIG. 2A described above, an arbitrary initial luminance adjustment amount is manually input and set, and the arbitrary initial luminance adjustment amount that has been input and set is stored in the nonvolatile memory 17. Arbitrary initial aperture amount, arbitrary initial exposure time, and arbitrary initial gain can be manually input and set individually, and this arbitrary initial aperture amount, arbitrary initial exposure time, and arbitrary May be stored in the nonvolatile memory 17.

  Further, in the flowchart of FIG. 2A described above, an arbitrary initial luminance adjustment amount for determining three values of the initial aperture amount, the initial exposure time, and the initial gain is manually input and set, and the nonvolatile memory is set. 17, but only one or two of the three values are manually input and set, and this input and set value may be stored in the non-volatile memory 17, Any one of the values may be a fixed value, and an arbitrary initial luminance adjustment amount for determining the other two values may be manually set and stored in the nonvolatile memory 17.

  For example, when the aperture device 111 is not provided (the aperture amount of the aperture device 111 is fixed), an arbitrary initial luminance adjustment amount for determining two values of an initial exposure time and an initial gain, or an arbitrary initial value An exposure time and an arbitrary initial gain are manually input and set. If the exposure time of the CCD 112 is fixed, an arbitrary initial luminance adjustment for determining two values of an initial aperture amount and an initial gain. When the gain of the AGC amplifier 113 is fixed, two values of the initial aperture amount and the initial exposure time are determined. Therefore, an arbitrary initial luminance adjustment amount or an arbitrary initial aperture amount and an arbitrary initial exposure time are manually input and set.

  When the aperture amount of the aperture device 111 and the exposure time of the CCD 112 are fixed, an arbitrary initial gain is manually input and set. When the exposure time of the CCD 112 and the gain of the AGC amplifier 113 are fixed, An arbitrary initial aperture amount is manually input and set, and if the aperture amount of the aperture device 111 and the gain of the AGC amplifier 113 are fixed, an arbitrary initial exposure time is manually input and set. .

  Further, in the initial luminance adjustment amount setting screen 20 of FIG. 3, the luminance adjustment amount is shown only in the light and dark portions of the luminance adjustment amount setting window 21, but the present invention is not limited to this. For example, the area ratio of the light / dark part or the luminance adjustment amount may be converted into a numerical value and displayed below the luminance adjustment amount setting window 21. The shape of the brightness adjustment amount setting window 21 is not limited to a rectangle (rectangle). For example, it may be circular or square. Further, the luminance adjustment amount setting window 21 may be a vertical type (bar graph shape). Alternatively, only the brightness adjustment amount may be digitized and displayed without providing the brightness adjustment amount setting window 21, and the value may be increased or decreased by key operation.

<Brightness adjustment at power-on>
In the flowchart of the brightness adjustment operation example when the main power is turned on in FIG. 2B, when the user operates the power on / off key of the digital camera 10 to turn on the main power, the shooting mode is set and the processor is nonvolatile. The initial brightness adjustment amount stored in the storage memory 17 is read (step S1), the read initial brightness adjustment amount is stored in the RAM, and the correspondence table stored in the nonvolatile memory 17 is stored in the initial brightness adjustment amount. After referring to the initial aperture amount, initial exposure time, and initial gain, the aperture amount of the aperture device 111 is set to the initial aperture amount, the initial exposure time is sent to the TG 15, and the gain of the AGC amplifier 113 is set to the initial gain. Set (step S2).

  Next, when the process proceeds from step S2 to step S3, in step S3, the processor performs the first imaging with the initial aperture amount, initial exposure time, and initial gain (initial brightness adjustment amount) set in step S2. Execute the process. Here, when a transition is made from step S6 or S8, which will be described later, to step S3, the processor performs the second and subsequent times depending on the aperture amount, exposure time, and gain corresponding to the brightness adjustment amount changed and set in the processing of step S6 or S8. An imaging process is executed.

Subsequently, the processor calculates the average luminance value of the image signal obtained by the imaging process in step S3 (step S4). An integrator may be provided separately, and the integrator may calculate the average luminance value of the image signal.
Next, the processor compares the acquired luminance average value with a predetermined first appropriate luminance value, and determines whether the luminance average value is brighter (higher) than the first appropriate luminance value (step). S5).

  If it is determined in step S5 that the luminance average value is brighter than the first appropriate luminance value, the processor subtracts a predetermined amount from the luminance adjustment amount currently stored in the RAM and returns to step S3 (step S3). S6). Here, when the predetermined amount is subtracted from the luminance adjustment amount, the aperture amount is increased by a predetermined amount (the aperture opening area is reduced), the luminance adjustment amount is decreased by a predetermined time, and the gain is decreased by the predetermined amount. To do.

  If it is determined in step S5 that the luminance average value is not brighter than the first appropriate luminance value, the process proceeds to step S7, and the processor determines the luminance average value and the first predetermined value. The second appropriate luminance value slightly lower (darker) than the appropriate luminance value is compared, and it is determined whether or not the average luminance value is darker (lower) than the second appropriate luminance value.

  If it is determined that the average luminance value is darker than the second appropriate luminance value, the processor adds a predetermined amount to the luminance adjustment amount currently stored in the RAM and returns to step S3 (step S8). ). Here, when a predetermined amount is added to the luminance adjustment amount, the aperture amount is decreased by a predetermined amount (the aperture opening area is increased), the luminance adjustment amount is increased by a predetermined time, and the gain is increased by a predetermined amount. To do.

If it is determined in step S7 that the average luminance value is not darker than the second appropriate luminance value, the average luminance value is a value between the first appropriate luminance value and the second appropriate luminance value. Since the average brightness value is within the range of the appropriate brightness value, the process returns to step S3 without increasing or decreasing the brightness adjustment amount stored in the RAM.
Through the above processing, a through image with appropriate brightness is displayed on the liquid crystal screen of the LCD unit 16, and image data with appropriate brightness is recorded in the flash memory 19 by operating the shutter key.

  As described above, the initial luminance adjustment amount (initial aperture amount, initial exposure time, and initial gain) can be set according to the user's intention by the initial luminance adjustment amount setting operation of FIG. Since the aperture amount, the exposure time, and the gain can be controlled in steps S3 to S8 based on the brightness adjustment amount so as to approach the appropriate brightness, compared with the case where the initial brightness adjustment amount is set to a fixed value as in the conventional technique. Because the frequency of taking out images that are out of brightness immediately after the power is turned on is reduced, the time from the power-on to the convergence to the appropriate brightness is shortened, resulting in missed photo opportunities, There is no such thing as taking a picture that is out of place.

  FIG. 4 shows the average brightness value of the output signal from the imaging unit 11, the aperture amount of the aperture device 111, the exposure time of the CCD 112, and the AGC gain 113 in the luminance adjustment method of the present invention shown in the flowchart of FIG. It is a figure which shows the time transition state from the time of power-on of the gain of, and as is clear from the figure, the time from power-on to convergence to the appropriate brightness is much faster than in the prior art. .

  If the initial brightness adjustment amount is stored in the nonvolatile memory 17 in the form of the initial aperture amount, the initial exposure time, and the initial gain, the processor stores the initial aperture amount stored in the nonvolatile memory 17; The initial exposure time and initial gain are read out, the read initial aperture amount, initial exposure time, and initial gain are stored in the RAM, the aperture amount of the aperture device 111 is set to the initial aperture amount, and the initial exposure time is set to TG15. The gain of the AGC amplifier 113 is set to the initial gain.

  In the present invention, when only one or two of the initial aperture amount, initial exposure time, and initial gain are stored in the nonvolatile memory 17, or the initial aperture amount, initial exposure time, and initial gain are stored. The same can be applied to the case where the initial luminance adjustment amount that uniquely determines only two values is stored in the nonvolatile memory 17. However, in this case, at the time of automatic brightness adjustment, the brightness level of the image signal is adjusted by changing and controlling only one or two values of the initial aperture amount, the initial exposure time, and the initial gain.

  In the above embodiment, the exposure time, the aperture amount, and the gain are adjusted in a balanced manner on the basis of the initial luminance adjustment amount, but the three adjustment levels of the exposure time, the aperture amount, and the gain are adjusted. You may make it differ. For example, the exposure time adjustment amount is increased and the gain adjustment amount is decreased.

  In the above embodiment, the exposure time, the aperture amount, and the gain are all adjusted regardless of the initial luminance adjustment amount. However, the exposure time, the aperture amount, and the gain are adjusted according to the value of the initial luminance adjustment amount. You may make it switch the value adjusted among three values. For example, when the initial luminance adjustment amount is small, the adjustment is performed only by adjusting the exposure time, and when the initial luminance adjustment amount is large and cannot be handled only by adjusting the exposure time, the gain adjustment is started.

  In the above embodiment, when the user operates the power on / off key of the digital camera 10 to turn on the main power, the shooting mode is set and the processing of the flowchart shown in FIG. 2B is started. When the shooting mode is selected by operating the mode key by the user with the main power turned on, or when the start of moving image shooting (moving image recording) is instructed by the user operating the shutter key (FIG. 2 ( You may make it start the process of the flowchart shown to b).

<Second Embodiment>
In the first embodiment, the initial brightness adjustment amount is set manually (key operation). However, the present invention is not limited to this, and an automatic setting unit may be provided to automatically set the initial brightness adjustment amount. Hereinafter, automatic setting means for the initial luminance adjustment amount will be described.
FIG. 5 is a block diagram showing a circuit configuration of an embodiment of the image pickup apparatus of the present invention. A digital camera is taken as an example of the image pickup apparatus.

  In FIG. 5, the digital camera 30 includes an imaging unit 11, an A / D converter 12, a signal processing unit 13, and a control unit that have the same configuration and functions as the digital camera 10 illustrated in FIG. 1 (first embodiment). 14, a TG 15, an LCD unit (display unit) 16, a nonvolatile memory 17, a key input unit 18, and a flash memory 19, and a simple and low-power optical sensor 20 ′. Furthermore, a clock (calendar) unit 21 'and a GPS unit 22' are provided as photographing environment information acquisition devices required in a third embodiment to be described later.

  The optical sensor 20 ′ is provided on the front side of the digital camera 30, captures the amount of light around the camera, and sends information corresponding to the brightness of the periphery to the processor of the control unit 14. In this case, the processor holds this information in the RAM or nonvolatile memory 17. The nonvolatile memory 17 also has information based on the aperture amount, exposure time, and gain immediately before the main power is turned off, or information based on the luminance level of the image signal captured by the imaging unit 11 immediately before the main power is turned off. It can also be held.

  FIG. 6 is a flowchart showing an embodiment of the initial luminance adjustment amount setting operation by the automatic setting means, and FIG. 6A shows the automatic adjustment of the initial luminance adjustment amount using the light sensor output while the main power is turned off. FIG. 6B shows an example in which the luminance adjustment amount immediately before the main power supply is turned off is automatically set as the initial luminance adjustment amount.

<Automatic setting of initial brightness adjustment amount by light sensor output>
In FIG. 6 (a), when the user operates the power on / off key of the digital camera 10 to turn off the main power, the processor sends a control signal to the light sensor 20 ′ to turn on the light sensor, and from the light sensor 20 ′. Sensor output (brightness signal around the camera detected by the optical sensor 20 ′) is acquired (step U 1), a luminance adjustment amount corresponding to the detected value is calculated, and the initial luminance adjustment amount is stored in the RAM or the nonvolatile memory 17. The count process of a time counter (not shown) is started while being stored (step U2).

  Next, the processor monitors the count value of the time counter, and whether or not the count value has reached a predetermined value, that is, whether or not a predetermined time has elapsed since the brightness adjustment amount was updated and stored in the RAM or the nonvolatile memory 17. (Step U3), if the predetermined time has not elapsed, the process proceeds to Step U4. If the predetermined time has elapsed, the time counter is cleared and the process returns to Step U1 to newly acquire the optical sensor output.

  The processor examines the status signal from the key input unit 18 and determines whether or not the main power supply is turned on (step U4). If the main power supply is turned on, the processor makes a transition to step U5, and if not, step U3. Return to. That is, the calculation of the luminance adjustment amount based on the detection value of the optical sensor 20 ′ is repeated every predetermined time until the main power source is turned on.

When the main power source is turned on, the process proceeds to step S1 in FIG. 2B described above, and thereafter, brightness adjustment is performed by the same operation as steps S1 to S8 (step U5).
With the configuration shown in FIG. 6A, the initial luminance adjustment amount (initial aperture amount, initial exposure time, and initial gain) is automatically set, so that the user is free from the trouble of manual setting. In addition, the brightness is adjusted when the power is turned on by the automatically set initial brightness adjustment amount, that is, the initial brightness adjustment amount set according to the light sensor detection value immediately before the main power is turned on. The frequency of taking out the deviated image is reduced, and it is possible to approach the appropriate luminance in a short time as compared with the conventional technique.

  In the description of the flowchart of FIG. 6A, the output of the optical sensor 20 ′ is detected in step U1, and the luminance adjustment amount corresponding to the detected value is set in step U2, but the optical sensor 20 ′ is not provided. In step U1, the CCD 112 may be periodically turned on and off, and in step U2, a luminance adjustment amount may be set according to the luminance level of the image signal obtained by the signal processing unit 13.

  In the description of the flowchart of FIG. 6A, the brightness adjustment amount corresponding to the detection value is calculated and stored in the RAM or the nonvolatile memory 17 in step U2, but the detection value of the optical sensor 20 ′ is used as the calculation value. It may be stored in the RAM or the non-volatile memory 17 as it is, and the initial luminance adjustment may be executed by calculating the initial luminance adjustment amount based on the detection value stored when the main power is turned on.

  In the description of the flowchart of FIG. 6A, the initial luminance adjustment amount is stored in the RAM or the nonvolatile memory 17, but the aperture amount, the exposure time, and the amount corresponding to the detection value of the optical sensor 20 ′ are set. The gain may be stored in the RAM or the nonvolatile memory 17.

  In the description of the flowchart of FIG. 6A, the initial brightness adjustment amount for determining three values of the initial aperture amount, the initial exposure time, and the initial gain is automatically determined, and the RAM or nonvolatile memory 17 is used. However, only one or two of the three values are automatically determined, and the automatically determined value is stored in the RAM or nonvolatile memory 17, or the three values are stored. Any one of the values may be a fixed value, and an initial luminance adjustment amount for determining the other two values may be automatically determined and stored in the RAM or the nonvolatile memory 17.

  In the description of the flowchart of FIG. 6A, the processing of steps U1 to U3 is repeatedly performed while the main power is off, and the shooting mode is set when the main power is turned on, as shown in FIG. The processing of the flowchart shown is started, but the processing of steps U1 to U3 is repeatedly performed while a processing mode other than the shooting mode (reproduction mode or the like) is set while the main power is on. When the shooting mode is selected by operating the mode key, the processing of the flowchart shown in FIG. 2B may be started. Furthermore, while the moving image shooting (moving image recording) process is not executed with the main power turned on, the processes of steps U1 to U3 are repeated, and the start of moving image shooting is instructed by the operation of the shutter key by the user. Then, the processing of the flowchart shown in FIG. 2B may be started.

<Automatic setting of initial brightness adjustment amount by last memory>
In FIG. 6B, when the user turns off the main power by operating the power on / off key of the digital camera 10 in a state where the processes of steps S3 to S8 shown in FIG. The processor saves and stores the brightness adjustment amount stored in the RAM immediately before the main power is turned off, that is, the brightness adjustment amount of the through image displayed immediately before the main power is turned off, in the nonvolatile memory 17 as the initial brightness adjustment amount (Step S1). V1).

The processor checks the status signal from the key input unit 18 to determine whether or not the main power source is turned on. If the main power source is turned on, the processor makes a transition to Step V3 (Step V2).
When the main power is turned on, that is, when displaying a live view image is started, the initial brightness adjustment amount stored in the nonvolatile memory 17 in step V1 is used to perform the same operation as in steps S1 to S8 in FIG. Brightness adjustment is performed (step V3).

  As described above, the configuration shown in FIG. 6B frees the user from the troublesome manual setting as in the case shown in FIG. Further, since the brightness adjustment amount immediately before the main power is turned off is stored in the nonvolatile memory 17 as the initial brightness adjustment amount, when the shooting time and the shooting place are not so far apart, for example, shooting while searching for the shooting target in a field or indoor In such a case, that is, when shooting is performed with the power turned on and off many times in a short time, the time until the proper luminance is reached for the second and subsequent main power ons is shortened.

  Note that the automatic setting of the initial luminance adjustment amount by the optical sensor output (FIG. 6A) and the automatic setting of the initial luminance adjustment amount by the last memory (FIG. 6B) are alternatively selected in the digital camera 30. Possible switches may be provided so that the user can select a desired automatic setting method. With this configuration, the user can select an automatic setting method according to his / her shooting style, shooting location, and shooting time.

  In the description of the flowchart of FIG. 6B, the luminance adjustment amount immediately before the main power supply is turned off is stored in the nonvolatile memory 17, but the luminance value of the image signal captured immediately before the main power supply is turned off is saved. The brightness adjustment may be performed by calculating the brightness adjustment amount based on the brightness value when the main power is turned on.

  In the description of the flowchart of FIG. 6B, the luminance adjustment amount immediately before the main power supply is turned off is stored and held, and when the main power supply is turned on, the photographing mode is set and the luminance adjustment stored and held. The processing of the flowchart shown in FIG. 2B is started based on the amount, but the mode is switched when another processing mode is selected by the user operating the mode key while the shooting mode is set. When the immediately previous luminance adjustment amount is stored and held, and the shooting mode is selected again by the user operating the mode key, the processing of the flowchart shown in FIG. 2B is performed based on the stored and adjusted luminance adjustment amount. You may make it start. Furthermore, the brightness adjustment amount immediately before the end of the moving image shooting (moving image recording) process is stored and held, and when the start of moving image shooting is instructed again by the user operating the shutter key, the stored and held luminance adjustment is performed. You may make it start the process of the flowchart shown in FIG.2 (b) based on quantity.

<Third Embodiment>
In the second embodiment, the initial luminance adjustment amount is set based on the light sensor output immediately before the power is turned on and the luminance adjustment amount immediately before the power is turned off. The present invention is not limited, and the initial brightness adjustment amount can be automatically set based on the shooting environment information. Hereinafter, an automatic setting unit for the initial luminance adjustment amount based on the shooting environment information will be described.

  FIG. 7 is a flowchart showing an embodiment of the initial luminance adjustment amount setting operation by the automatic setting means. FIG. 7A is an example in which the initial luminance adjustment amount is automatically set based on the time. b) is an example in which the initial luminance adjustment amount is automatically set based on the date, and FIG. 7C is an example in which the initial luminance adjustment amount is automatically set based on the type of shooting mode. FIG. 7D shows an example in which the initial luminance adjustment amount is automatically set based on the shooting position (shooting location).

<Automatic setting of initial brightness adjustment amount based on time>
In this example, a clock (calendar) unit 21 ′ provided in the digital camera 30 is used. In addition, a time-luminance adjustment amount correspondence table (not shown) in which time information and luminance adjustment amounts are associated is stored in the nonvolatile memory 17 or a program storage memory of the control unit 14.

  In FIG. 7A, when the user turns on the main power, the processor acquires current time information from the clock unit 21 '(step W1), and the luminance adjustment amount according to the current time from the time-luminance adjustment amount correspondence table. Is set as the initial luminance adjustment amount. That is, the initial brightness adjustment amount is converted to the initial aperture amount, the initial exposure time, and the initial gain with reference to the correspondence table stored in the nonvolatile memory 17, and then the aperture amount of the aperture device 111 is set to the initial aperture amount. The initial exposure time is sent to the TG 15, and the gain of the AGC amplifier 113 is set to the initial gain. For example, an initial luminance adjustment amount that lowers the luminance level of the image signal is set at noon, and an initial luminance adjustment amount that increases the luminance level of the image signal at night is set (step W2). Next, the brightness adjustment is performed by the same operation as the above-described steps S3 to S8 in FIG. 2B with the brightness adjustment amount set in step W2 (step W3). In addition, you may make it discriminate | determine time divisions, such as night and a day, from the time acquired by the said step W1.

<Automatic setting of initial brightness adjustment amount by month and day>
In this example, a clock unit with calendar function 21 ′ provided in the digital camera 30 is used. Further, a month / day / brightness adjustment amount correspondence table (not shown) in which date information and brightness adjustment amounts are associated is stored in the nonvolatile memory 17 or a program storage memory of the control unit 14.

  In FIG. 7B, when the user turns on the main power, the processor acquires the current date information from the clock unit 21 '(step X1), and the brightness adjustment according to the date information from the month / day / brightness adjustment amount correspondence table. The amount is set as the initial luminance adjustment amount. For example, an initial luminance adjustment amount that lowers the luminance level of the image signal is set in summer, and an initial luminance adjustment amount that increases the luminance level of the image signal in winter is set (step X2). Next, the brightness adjustment is performed by the same operation as the above-described steps S3 to S8 in FIG. 2B with the initial brightness adjustment amount set in step X2 (step X3).

In addition, you may make it discriminate | determine the time of spring, summer, autumn and winter from the month and day acquired at the said step X1.
Further, a date-by-date time-brightness adjustment amount correspondence table in which the time information and the brightness adjustment amount are associated with each other by date information is stored in the nonvolatile memory 17 or the program storage memory of the control unit 14, and current date / time information is acquired. Thus, the corresponding luminance adjustment amount may be obtained and the initial luminance adjustment amount may be set.

<Automatic setting of initial brightness adjustment amount by shooting mode type>
In FIG. 7C, when the user turns on the main power, the processor checks the setting state of the shooting mode by operating the mode key, acquires and determines the currently set shooting mode type (step Y1), and sets the shooting mode type. Is set as the initial luminance adjustment amount. For example, if the set shooting mode is the night shooting mode, set the initial brightness adjustment amount to increase the brightness level of the image signal, and set the initial brightness adjustment amount to decrease the brightness level of the image signal in other shooting modes. (Step Y2). Next, the brightness adjustment is performed by the same operation as the above-described steps S3 to S8 in FIG. 2B with the initial brightness adjustment amount set in step Y2 (step Y3).

  In step Y2, the initial luminance adjustment amount can be set not only in the night shooting mode but also in the shooting mode such as the normal shooting mode, the close-up mode, the rapid shooting mode, and the panoramic shooting mode. Note that when shooting mode switching is selected using an electronic switch instead of a mechanical switch, information on the shooting mode set immediately before the main power supply is turned off is held in the nonvolatile memory 17, and the main power supply is set. By reading this information at the time of turning on, the currently set shooting mode type is acquired.

<Automatic setting of initial brightness adjustment amount according to shooting position>
In this example, a GPS unit 22 ′ provided in the digital camera 30 is used. Further, a position-luminance adjustment amount correspondence table (not shown) in which the location (position) and the luminance adjustment amount are associated is stored in the nonvolatile memory 17 or the program storage memory of the control unit 14.

  In FIG. 7D, when the user turns on the main power, the processor acquires and determines the current position information from the GPS unit 22 '(step Z1), and the brightness corresponding to the current position from the position-luminance adjustment amount correspondence table. The adjustment amount is taken out and set as the initial luminance adjustment amount. For example, an initial luminance adjustment amount that lowers the luminance level of the image signal is set if it is outdoors, and an initial luminance adjustment amount that increases the luminance level of the image signal if indoors is set (step Z2). Next, using the initial luminance adjustment amount set in step Z2, luminance adjustment is performed by the same operation as steps S3 to S8 in FIG. 2B described above (step Z3).

  As is apparent from the description of the flowchart of FIG. 7, the initial luminance adjustment amount can be automatically set according to the photographing environment when the power is turned on, so that the user is free from the trouble of manual setting. Further, since the brightness adjustment at the time of power-on is performed with the automatically set initial brightness adjustment amount, the same effect as in the second embodiment can be obtained.

  In the description of the flowchart of FIG. 7, the three values of the initial aperture amount, the initial exposure time, and the initial gain are automatically set based on the acquired shooting environment information. However, one of the above three values or Only two values may be automatically set.

In the description of the flowchart of FIG. 7, the shooting environment information is acquired when the main power is turned on, and the initial luminance adjustment amount is automatically set based on the shooting environment information. When the shooting mode is selected by the user operating the mode key while the processing mode (playback mode, etc.) is set, the shooting environment information is acquired, and the initial brightness adjustment amount is automatically set based on this shooting environment information. You may make it do. Further, when the start of moving image shooting is instructed by the user operating the shutter key while the main power is on, the shooting environment information is acquired, and the initial luminance adjustment amount is automatically set based on the shooting environment information. You may do it.
As mentioned above, although one Example of this invention was described, this invention is not limited to the said Example, It cannot be overemphasized that various deformation | transformation implementation is possible.

It is a block diagram which shows the circuit structure of one Example of the imaging device of this invention. It is a flowchart which shows one Example of the manual setting operation | movement of an initial luminance adjustment amount, and a luminance adjustment operation. It is a figure which shows one Example of an initial luminance adjustment amount setting screen. It is a figure which shows the time transition state from the time of power ON of the brightness | luminance average value of the output signal from the imaging part in the brightness | luminance adjustment method of this invention, and the brightness | luminance adjustment amount with respect to an imaging part. It is a block diagram which shows the circuit structure of the other Example of the imaging device of this invention. It is a flowchart which shows one Example of the automatic setting operation | movement of an initial luminance adjustment amount. It is a flowchart which shows the other Example of the automatic setting operation | movement of an initial luminance adjustment amount. It is a figure which shows the time transition state from the time of power ON of the brightness | luminance average value of the output signal from the imaging part in the conventional brightness | luminance adjustment method, and the brightness | luminance adjustment amount with respect to an imaging part.

Explanation of symbols

10, 30 Digital camera 11 Imaging unit 111 Aperture device 112 CCD
113 AGC amplifier 12 A / D converter 13 Signal processing unit 14 Control unit 15 TG
16 LCD unit 17 Non-volatile memory 18 Key input unit 19 Flash memory 20 ′ Optical sensor 21 ′ Clock (calendar) unit 22 ′ GPS unit 20 Initial luminance adjustment amount setting screen

Claims (18)

In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
A luminance adjustment amount setting means for manually setting an arbitrary luminance adjustment amount;
Start instruction means for instructing start of periodic imaging by the imaging means;
When the start instruction unit instructs the start of periodic imaging, an initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjustment unit based on the luminance adjustment amount set by the luminance adjustment amount setting unit When,
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Start instruction means for instructing start of periodic imaging by the imaging means;
Brightness detection means for periodically detecting ambient brightness before the start instruction means instructs the start of periodic imaging;
When the start instruction unit instructs to start periodic imaging, an initial luminance control unit that sets an adjustment amount of the luminance level by the luminance adjustment unit based on the surrounding brightness detected by the brightness detection unit When,
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: Holding means for holding information based on ambient brightness detected by the brightness detection means;
The initial luminance control means sets the adjustment amount of the luminance level by the luminance adjusting means based on the information held in the holding means when the start instruction means instructs to start periodic imaging. The imaging apparatus according to claim 2. In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
End instruction means for instructing end of periodic imaging by the imaging means;
Start instruction means for instructing start of periodic imaging by the imaging means;
A holding unit that holds information based on a luminance level adjustment amount by the luminance adjustment unit immediately before the instruction when an end of periodic imaging is instructed by the end instruction unit;
An initial luminance control unit that sets an adjustment amount of a luminance level by the luminance adjustment unit based on information held in the holding unit when the start instruction unit instructs the start of periodic imaging;
An imaging apparatus comprising:   5. The image pickup apparatus according to claim 4, wherein the end instruction means includes means for instructing power-off of the image pickup apparatus. In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Start instruction means for instructing start of periodic imaging by the imaging means;
A shooting environment determination unit that determines a shooting environment when the start instruction unit instructs the start of periodic imaging;
Initial luminance control means for setting an adjustment amount of the luminance level by the luminance adjusting means based on the photographing environment determined by the photographing environment determining means;
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Start instruction means for instructing start of periodic imaging by the imaging means, and acquisition means for acquiring current time information when the start instruction means is instructed to start periodic imaging;
Initial luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the time information acquired by the acquisition means;
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Shooting mode setting means for manually setting an arbitrary shooting mode among a plurality of shooting modes;
Start instruction means for instructing start of periodic imaging by the imaging means;
An acquisition unit that acquires shooting mode information set in the shooting mode setting unit when the start instruction unit instructs to start periodic imaging;
Initial luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the shooting mode information acquired by the acquisition means;
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: In an imaging apparatus including an imaging unit that periodically repeats imaging and periodically outputs an image signal,
The imaging unit includes a luminance adjusting unit that adjusts the luminance level of the image signal,
Start instruction means for instructing start of periodic imaging by the imaging means;
An acquisition means for acquiring current position information when a start of periodic imaging is instructed by the start instruction means;
Initial luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the position information acquired by the acquisition means;
Detecting means for detecting a luminance level of an image signal periodically output from the imaging means;
Appropriate luminance control means for setting an adjustment amount of the luminance level by the luminance adjustment means based on the luminance level of the image signal periodically detected by the detection means;
An imaging apparatus comprising: The imaging means includes an image sensor,
The imaging apparatus according to claim 1, wherein the brightness adjusting unit includes a unit that adjusts an exposure time of the imaging element. The imaging means includes a diaphragm device that adjusts the amount of light applied to the imaging device,
The imaging apparatus according to claim 1, wherein the brightness adjusting unit includes a unit that adjusts a diaphragm amount of the diaphragm device. The imaging means includes an amplifier that amplifies an image signal output from the imaging device,
The imaging apparatus according to claim 1, wherein the luminance adjustment unit includes a unit that adjusts an amplification factor of the amplifier.   The imaging apparatus according to claim 1, wherein the start instruction unit includes a unit that instructs to start up the power supply of the imaging apparatus.   The said appropriate brightness control means increases / decreases the adjustment amount of the brightness level by the said brightness adjustment means only by predetermined amount based on the brightness level of the image signal periodically detected by the said detection means. The imaging device according to any one of 13. Manually setting an arbitrary amount of brightness adjustment;
Instructing the start of periodic imaging by the imaging unit;
A step of adjusting a luminance level of an image signal output by the imaging unit based on an arbitrary luminance adjustment amount manually set when an instruction to start periodic imaging by the imaging unit is given;
Detecting a luminance level of an image signal periodically output from the imaging unit;
Adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the periodically detected image signal;
An imaging method characterized by comprising: Periodically detecting ambient brightness;
Instructing the start of periodic imaging by the imaging unit;
Adjusting the brightness level of the image signal output by the imaging unit based on the ambient brightness detected immediately before the instruction when the start of periodic imaging by the imaging unit is instructed;
Detecting a luminance level of an image signal periodically output from the imaging unit;
Adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the periodically detected image signal;
An imaging method comprising: Detecting a luminance level of an image signal periodically output from the imaging unit;
Adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the periodically detected image signal;
Instructing the end of periodic imaging by the imaging unit;
When the end of periodic imaging by the imaging unit is instructed, holding information based on the adjustment amount of the luminance level immediately before the instruction;
Instructing the start of periodic imaging by the imaging unit;
Adjusting the luminance level of the image signal output by the imaging unit based on the held information when an instruction to start periodic imaging by the imaging unit is given;
An imaging method comprising: Instructing the start of periodic imaging by the imaging unit;
If the start of periodic imaging by the imaging unit is instructed, obtaining current time information;
Adjusting the luminance level of the image signal output by the imaging unit based on the acquired time information;
Detecting a luminance level of an image signal periodically output from the imaging unit;
Adjusting the luminance level of the image signal periodically output by the imaging unit based on the luminance level of the periodically detected image signal;
An imaging method comprising:

Images