JP2009290510A - Image pickup apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image pickup apparatus capable of performing light control with high accuracy. <P>SOLUTION: The image pickup apparatus is provided with a strobe, an optical system, an AF sensor, an AE sensor, and a microcomputer. Upon receiving an image capturing start signal, the microcomputer causes the strobe, to perform first preliminary light emission and then the strobe to perform second preliminary light emission, causes the AE sensor to acquire a light at an arbitrary sensitivity in the first preliminary light emission, and the AE sensor to acquire a light at sensitivity higher or lower than the arbitrary sensitivity in response to information about the distance acquired by the AF sensor in the second preliminary light emission. Then, the microcomputer calculates the light emission quantity of main light emission, in response to a result of the photometry of the AE sensor. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to an imaging apparatus provided with light emitting means. More specifically, the present invention relates to an imaging device capable of adjusting the amount of light emitted during photographing (main light emission).

  2. Description of the Related Art Conventionally, there are imaging apparatuses such as digital cameras that shoot light by irradiating a subject with light. In such an imaging apparatus, in order to irradiate the subject with an optimal amount of light, there is an imaging apparatus in which the light emission amount of the main light emission is changed based on the distance between the subject and the imaging apparatus.

  For example, in the TTL dimming method generally used in the imaging apparatus, the light emission amount of the main light emission is determined by the following procedure. First, this imaging apparatus performs prior light emission (hereinafter referred to as preliminary light emission) before photographing, and measures reflected light from a subject via a lens. Next, the imaging apparatus acquires the reflectance of the subject based on the photometric result of the reflected light. Based on the reflectance of the subject, the amount of main light emission at the time of shooting is determined.

  In another imaging apparatus, the amount of main light emission is determined by the following procedure. This imaging apparatus first performs preliminary light emission. At this time, the imaging apparatus acquires the reflected light from the subject and measures the brightness (luminance) of the reflected light. As a result, when the brightness of the measured reflected light is greater than a predetermined value (for example, when the subject is present near the imaging device), the amount of preliminary light emission is reduced. On the other hand, when the brightness of the reflected light that has been measured is smaller than a predetermined value (for example, when the subject is located far from the imaging device), the amount of preliminary light emission is increased. Then, the imaging device performs preliminary light emission again.

  Thus, preliminary light emission is repeated until the luminance of the reflected light that has been measured is included in a predetermined range, and the light emission amount of the main light emission is adjusted based on the photometric result (the luminance of the reflected light) included in the predetermined range.

Furthermore, in the imaging apparatus shown in Patent Document 1, the amount of light emission of main light emission is determined by the following means. In the imaging apparatus of Patent Document 1, preliminary light emission is first performed. At this time, the imaging apparatus acquires reflected light from the subject and measures the luminance of the reflected light. As a result, when the brightness of the measured reflected light is smaller than a predetermined value, the light receiving sensitivity when acquiring the reflected light is increased. On the other hand, when the brightness of the reflected light measured is greater than a predetermined value, the light receiving sensitivity when acquiring the reflected light is lowered. Then, the imaging device performs preliminary light emission again. Thus, preliminary light emission is repeated until the photometric reflected light is included in a predetermined range, and the light emission amount of the main light emission is adjusted based on the photometric result (the luminance of the reflected light) included in the predetermined range.
JP 2000-187266 A

  An object of the present invention is to provide an imaging apparatus capable of adjusting the amount of light emission of main light emission with higher accuracy.

  That is, according to the present invention, the first preliminary light emission, the second preliminary light emission performed after the first preliminary light emission, or the main light emission includes light emitting means for irradiating the subject with light reflected by the subject. An optical system for condensing; distance measuring means for acquiring information about a distance from the apparatus to the subject; and light reflected by the subject during the first or second preliminary light emission; A photometric means for measuring the brightness of the light, a light quantity calculating means for calculating the emitted light quantity of the main light emission according to the photometric results at the time of the first or / and the second preliminary light emission, And a control means for controlling the light emitting means and the photometry means when an instruction to start photographing is received. When the control means receives the imaging start signal, the control means causes the light emitting means to perform the first preliminary light emission, and then causes the light emitting means to perform the second preliminary light emission, while the first light emission means. In the preliminary light emission, after the light is measured by the photometry means with the first light receiving sensitivity, the light is determined according to the information about the distance to the subject acquired by the distance measurement means in the second preliminary light emission. The photometry means is made to acquire light with a second light receiving sensitivity different from the first light receiving sensitivity.

  In this way, the light receiving sensitivity at the time of the second preliminary light emission can be raised or lowered with respect to the arbitrary sensitivity set at the time of the first preliminary light emission according to the distance measurement result of the distance measuring means. For this reason, even when the distance from the device to the subject is short, even when the first preliminary light emission occurs, the dimming is over (the amount of light is larger than the dynamic range of the image sensor). In the second preliminary light emission, the light receiving sensitivity can be lowered. Thus, it is possible to prevent over-dimming during the second preliminary light emission. On the other hand, even when the distance from the device to the subject is far, even when the light is under dimming (the amount of light is less than the dynamic range of the image sensor) during the first preliminary light emission, In the second preliminary light emission, the light receiving sensitivity can be increased. Thereby, dimming under can be prevented during the second preliminary light emission. That is, when the distance from the device to the subject is short, there is generally a high possibility that the light control will be over. In addition, when the distance from the device to the subject is far, there is generally a high possibility that the dimming will be under. Therefore, if comprised in this way, it can prevent more that the emitted light quantity of this light emission is determined according to the light control result with a bad precision.

  Note that, as in Patent Document 1, which is the prior art, it is not necessary to determine whether or not to perform the second preliminary light emission in accordance with the photometric result of the photometry means at the time of the first preliminary light emission. Processing time from receiving a signal to shooting can be shortened.

  The other means collects the light reflected by the subject and the light emitting means for irradiating the subject with light as the first preliminary light emission, the second preliminary light emission performed after the first preliminary light emission, or the main light emission. An optical system that emits light, auxiliary light irradiation means for irradiating the subject with auxiliary light, and light reflected by the subject at the time of the auxiliary light irradiation or at the time of the first or second preliminary light emission. A photometric means for obtaining and measuring the brightness of the subject; a light quantity calculating means for calculating a light emission quantity of main light emission according to a photometric result in the first or / and second preliminary light emission; And a control means for controlling the light emitting means and the photometry means when a photographing start signal for instructing the start of photographing is received. When the control means receives the photographing start signal, the control means causes the light emitting means to perform the first preliminary light emission, and then causes the second preliminary light emission to be performed, while at the time of the first preliminary light emission. The first light receiving sensitivity is determined according to the information about the distance to the subject acquired by the distance measuring means at the time of the second preliminary light emission after the light measuring means acquires light with the first light receiving sensitivity. The light metering means is made to acquire light with a second light receiving sensitivity different from the light receiving sensitivity.

  The present invention can adjust the emitted light amount of the main light emission with higher accuracy regardless of the distance from the apparatus to the subject. Further, the light emission amount of the main light emission can be calculated in a shorter time.

(Embodiment 1)
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The imaging device 1 in the present embodiment is configured with a single-lens reflex digital camera. The first embodiment uses an AE sensor 210 as photometric means. The AE sensor 210 measures the brightness of the light reflected by the mirror. In the first embodiment, an AF sensor 209 is used as a distance measuring unit. The AF sensor 209 detects the focus position of the focus lens 3011. The AF sensor 209 outputs the detected in-focus position to the microcomputer 213 as information regarding the distance. That is, the AF sensor 209 acquires information regarding the distance to the subject.

1. Configuration 1-1 Overview of Overall Configuration FIG. 1 is a perspective view of an imaging apparatus 1 according to the present embodiment. FIG. 2 is a configuration diagram of the imaging apparatus 1 according to the present embodiment.

  The imaging device 1 in the present embodiment includes an imaging device body 2 and an interchangeable lens 3 to which the imaging device body 2 can be attached and detached.

  The imaging apparatus main body 2 includes a mirror box, a CMOS sensor 202, an eyepiece lens 203, a DSP 204, a buffer memory 205, a liquid crystal monitor 206, a power source 207, a body mount 208, an AF sensor 209, and an AE sensor 210. A flash memory 211, a card slot 212, a microcomputer 213, a shutter switch 214, a strobe 215, and an auxiliary light irradiation unit 220.

  The interchangeable lens 3 includes an optical system 301, an actuator that drives the optical system 301, a diaphragm 302, a diaphragm driving unit 303 that drives the diaphragm 302, a zoom ring 304, a focus ring 305, an actuator and a diaphragm driving unit 303. And a lens controller 306 for controlling. This will be specifically described below.

1-2 Configuration of Imaging Device Main Body 2 The imaging device main body 2 captures a subject image condensed by the optical system 301 of the interchangeable lens 3 and records it as image data.

  The mirror box switches the optical path of the optical signal from the optical system 301 included in the interchangeable lens 3 in order to selectively cause the subject image to enter either the CMOS sensor 202 or the eyepiece lens 203. The mirror box includes a main mirror 2011, a sub mirror 2012, a mirror driving unit 2013, a shutter 2014, a shutter driving unit, a focusing screen 2016, and a prism 2017.

  The main mirror 2011 is disposed so as to be movable forward and backward with respect to the optical path to the CMOS sensor 202 in order to guide the subject image to the eyepiece lens 203. The sub mirror 2012 reflects a part of the optical signal input from the optical system 301 included in the interchangeable lens 3 and enters the AF sensor 209. Part of the optical signal input to the AF sensor 209 is incident on the sub mirror 2012 via the main mirror 2011.

  When the main mirror 2011 enters the optical path to the CMOS sensor 202, a part of the optical signal input from the optical system 301 included in the interchangeable lens 3 is reflected by the main mirror 2011, and the focusing screen 2016. And enters the eyepiece lens 203 through the prism 2017. In the focusing screen 2016, a part of the optical signal is diffused. The optical signal diffused by the focusing screen 2016 is incident on the AE sensor 210. On the other hand, when the main mirror 2011 is retracted from the optical path to the COMS sensor, the optical signal input from the optical system 301 included in the interchangeable lens 3 enters the CMOS sensor 202.

  The mirror drive unit 2013 includes mechanical parts such as a motor and a spring, and drives the main mirror 2011 and the sub mirror 2012 based on the control of the microcomputer 213.

  The shutter 2014 switches between blocking and passing an optical signal from the interchangeable lens 3 with respect to the CMOS sensor 202. The shutter drive unit includes mechanical parts such as a motor and a spring, and drives the shutter 2014 under the control of the microcomputer 213. In short, the shutter 2014 is opened and closed to adjust the amount of light hitting the CMOS sensor 202 over time.

  The CMOS sensor 202 captures a subject image formed by the optical system 301 and generates image data. As shown in FIG. 3, the CMOS sensor 202 includes a light receiving element 2021, an AGC 2022 (gain control amplifier), and an AD converter 2023. The light receiving element 2021 converts an optical signal incident through the mirror box into an electric signal, and generates image data. The AGC 2022 amplifies the electric signal output from the light receiving element 2021. The AD converter 2023 is an AGC 2022 that converts the amplified electric signal into a digital signal.

  The eyepiece 203 passes an optical signal incident through the mirror box. Thus, the user can check the subject image condensed by the optical system 301 by looking into the eyepiece lens 203. In short, the eyepiece 203 is an optical viewfinder.

  The image processing unit (DSP 204) performs predetermined image processing on the image data output from the CMOS sensor 202. Examples of the predetermined image processing include gamma conversion, YC conversion, electronic zoom processing, compression processing, and expansion processing, but are not limited thereto.

  The buffer memory 205 functions as a work memory when the DSP 204 performs processing and when the microcomputer 213 performs control processing. The buffer memory 205 can be realized by, for example, a DRAM.

  The liquid crystal monitor 206 is disposed on the back side of the camera body, and can display image data generated by the CMOS sensor 202 or image data obtained by performing predetermined processing on the image data.

  The power source 207 supplies power to be consumed by the camera system. The power source 207 may be, for example, a dry battery or a rechargeable battery. Moreover, the power supplied from the outside by the power source 207 cord may be supplied to the camera system.

  The body mount 208 is a member that allows the interchangeable lens 3 to be attached and detached together with the lens mount 307 of the interchangeable lens 3. The body mount 208 can be electrically connected to the interchangeable lens 3 using a connection terminal or the like, and can also be mechanically connected by a mechanical member such as a locking member. The body mount 208 can output a signal from the lens controller 306 included in the interchangeable lens 3 to the microcomputer 213 and can output a signal from the microcomputer 213 to the lens controller 306 of the interchangeable lens 3. That is, the microcomputer 213 can transmit and receive control signals, information on the optical system 301, and the like with the lens controller 306 on the interchangeable lens 3 side.

  The AE sensor 210 is a photometric unit that acquires light that has passed through the optical system 301 during preliminary light emission and measures the brightness of the acquired light. As shown in FIG. 4, the AE sensor 210 can include a light receiving element 2101, an amplifier 2102, a digital circuit 2103 (or a measuring instrument), and the like.

  In short, the AE sensor 210 acquires light and measures the brightness of the light. Specifically, the AE sensor 210 acquires light and generates an electrical signal. The AE sensor 210 converts the electrical signal into a digital signal. Thereafter, the AE sensor 210 converts the digital signal into luminance. A specific output of the light control sensor is, for example, a luminance value 230 (8-bit conversion).

  The light receiving element 2101 includes a photoelectric conversion element such as a photodiode, and receives an optical signal diffused by the focusing screen 2016.

  The light receiving element 2101 is configured to change the light receiving time. In this case, the light receiving element 2101 can change the light receiving time by including a light receiving region such as a photodiode and a storage region such as an integrating amplifier. The light receiving time is set by a control signal from the microcomputer 213. The control signal includes a light reception time. More specifically, when the light receiving element 2101 receives a light reception start signal from the microcomputer 213, the light receiving region starts to receive light. Then, the electrical signal received in the light receiving region is stored in the storage region. Thereafter, the light receiving region continues to receive light until the set light receiving time elapses. That is, the light receiving region ends light reception when the light receiving time has elapsed from the start of light reception. By taking out the accumulated electric charge as an electric signal, light can be received for a set light reception time. In short, the light receiving element 2101 has a configuration like an electronic shutter.

  The amplifier 2102 is configured by an integration amplifier or the like, and amplifies the electric signal output from the light receiving element 2101. Here, the amplification level (light reception sensitivity) is determined by the ISO sensitivity included in the control signal received from the microcomputer 213.

  The digital circuit 2103 measures the brightness of the subject and converts the electrical signal output from the amplifier 2102 into a digital signal. Specifically, a luminance value corresponding to the brightness of light is calculated. For example, when the luminance value is expressed by 8 bits, it can be expressed by a gradation of 0 to 255 (rounded off after the decimal point). Note that the luminance value of the present embodiment is obtained by calculating the average of a plurality of pixels. For example, when the image data is divided into nine and the luminance value of each area is calculated, the luminance values of the pixels included in one divided area are calculated one by one. Then, the calculated luminance value is averaged within one area. Thereby, the luminance value in each region can be calculated.

  Hereinafter, the calculation of the luminance value will be specifically described. First, the luminance of each pixel is calculated based on the digital signal. Thereafter, an integrated value of luminance in each region is calculated. Here, the integrated value Ba (a = 1, 2,..., Total number of areas) of each region is the luminance Yab (b = 1, 2,..., Total number of pixels in the region a) in each region. ) (Formula 1).

Ba = ΣYab (Formula 1)
When the integrated value of each region is calculated, the integrated value of each region is divided by the total number of pixels in each region. Thereby, the luminance of the pixels in each region can be averaged, and the luminance value of each region can be calculated. Here, when the luminance of each pixel is expressed by 8 bits, the luminance value can be expressed by a gradation of 0 to 255 (rounded off after the decimal point).

  As a result, the AE sensor 210 measures the brightness of the subject based on the output from the light receiving element 2101. Then, the photometric result is output to the microcomputer 213. The AE sensor 210 may have any configuration as long as it can measure the brightness of the subject. Therefore, the luminance value can be calculated by a method similar to center-weighted metering, multi-segment metering, weighted metering, evaluation metering, or the like. Here, the AE sensor 210 of the present embodiment uses a sensor that divides image data into nine parts and measures the average brightness of each region.

  The AF sensor 209 detects the in-focus position of the focus lens 3011 based on the optical signal of the subject incident through the optical system 301. Accordingly, the microcomputer 213 drives the focus lens 3011 to perform focusing. The AF sensor 209 is realized by a phase difference method that is a conventional technique. Therefore, the AF sensor 209 includes a condenser lens, an aperture mask, a separator lens, a line sensor, and the like so that the focus position of the focus lens 3011 for focus adjustment can be detected. The focus position of the focus lens 3011 acquired by the AF sensor 209 is output to the microcomputer 213. The microcomputer 213 calculates the distance (for example, 70 cm) from the imaging device 1 to the subject according to the focus position of the focus lens 3011. The calculation of the distance to the subject according to the in-focus position can be performed using table information in which the in-focus position and the distance to the object are associated with each other.

  The flash memory 211 is a storage medium used as a built-in memory. The flash memory 211 can store image data or image data obtained by performing predetermined processing on the image data. Also, digitized audio signals can be stored. In addition, it is possible to store programs for controlling the microcomputer 213, setting values, and the like in addition to image data and audio signals.

  The card slot 212 is a slot for attaching / detaching the memory card 216. The memory card 216 can store image data or image data obtained by performing predetermined processing on the image data. Also, digitized audio signals can be stored. In short, the memory card 216 is a storage medium.

  The microcomputer 213 controls the entire imaging apparatus main body 2. The microcomputer 213 may be realized by a microcomputer or a hard wired circuit. That is, the microcomputer 213 executes various controls. Various controls are described in 1-4.

  The shutter switch 214 is a button provided on the upper surface of the imaging apparatus main body 2 and is an operation unit that detects half-pressing and full-pressing operations from the user. The full-press operation is an operation for starting shooting from the user. When the shutter switch 214 receives a half-press operation from the user, the shutter switch 214 outputs a half-press signal to the microcomputer 213. On the other hand, when the shutter switch 214 receives a full-press operation from the user, the shutter switch 214 outputs a full-press signal to the microcomputer 213. That is, in the present embodiment, the full-press signal is a shooting start signal. Based on these signals, the microcomputer 213 performs various controls.

  The strobe 215 is a light emitting unit that irradiates a subject with light based on a control signal from the microcomputer 213. Therefore, the strobe 215 enables preliminary light emission and main light emission for the subject. As the preliminary light emission, the first preliminary light emission and the second preliminary light emission are enabled. The second preliminary light emission is preliminary light emission performed after the first preliminary light emission. Here, the preliminary light emission is light irradiation performed after an operation for starting photographing with respect to the shutter switch 214 and before an imaging operation for photographing with the CMOS sensor 202. Further, the main light emission is light irradiation performed together with an imaging operation for photographing with the CMOS sensor 202. Note that the control signal from the microcomputer 213 includes information regarding the amount of light to be irradiated.

  The auxiliary light irradiating unit 220 is auxiliary light irradiating means for irradiating the subject with light for performing AF assist under the control of the microcomputer 213. The microcomputer 213 outputs a control signal to the auxiliary light irradiation unit 220 in order to irradiate the subject with AF auxiliary light when the shutter switch is half-pressed. In addition, the auxiliary light irradiation part 220 can be comprised by LED etc., for example.

1-3 Configuration of Interchangeable Lens 3 The optical system 301 includes a focus lens 3011, a zoom lens 3012, and an objective lens 3013, and condenses light from the subject. The focus lens 3011 is driven by an actuator or a focus ring 305 to adjust the focus. The zoom lens 3012 is driven by an actuator to adjust the zoom magnification. In short, the focus lens 3011 and the zoom lens 3012 are movable lenses.

  The actuator includes a focus driving unit 3021, a zoom driving unit 3022, and an aperture driving unit 303. The focus driving unit 3021 drives the focus lens 3011 according to the control of the lens controller 306. The zoom drive unit 3022 drives the zoom lens 3012 according to the control of the lens controller 306.

  The stop 302 adjusts the amount of light passing through the optical system 301. The light can be adjusted by increasing or decreasing the aperture diameter composed of five blades.

  The aperture driving unit 303 changes the size of the aperture diameter of the aperture 302. In the first embodiment, the size of the aperture diameter of the diaphragm 302 is changed based on the control of the lens controller 306. Here, the size of the opening diameter can be designated by the F value. The diaphragm driving unit 303 drives the diaphragm 302 based on the control from the lens controller 306. However, the diaphragm driving unit 303 is not limited to this and may be driven by a mechanical method. In this case, an interlocking pin is provided on the body mount 208, and the driving of the interlocking pin is received by the aperture driving unit 303 to drive the aperture 302. The interlock pin is driven by a motor or the like controlled by the microcomputer 213.

  The focus ring 305 is provided on the exterior of the interchangeable lens 3 and drives the focus lens 3011 according to an operation from the user. The zoom ring 304 is provided on the exterior of the interchangeable lens 3 and drives the zoom lens 3012 according to an operation from the user.

  The lens controller 306 controls the entire interchangeable lens 3. The lens controller 306 may be realized by a microcomputer or a hard-wired circuit.

1-4. Various controls in the microcomputer 213 The microcomputer 213 realizes a determination unit, a control unit, a light amount calculation unit, and a photographing unit.

1-4-1. Determination Unit The microcomputer 213 that realizes the determination unit, after accepting the imaging start signal, according to the luminance value (photometric result before preliminary light emission) input from the AE sensor 210 before the operation to start imaging with respect to the shutter switch 214. Then, it is determined whether or not preliminary light emission is performed. When the microcomputer 213 determines that the preliminary light emission is to be performed, the microcomputer 213 determines how many preliminary light emission needs to be performed. In the present embodiment, the selection is made from one or two times. When performing preliminary light emission twice, the first preliminary light emission is set as the first preliminary light emission, and the second preliminary light emission is set as the second preliminary light emission. In short, the microcomputer 213 determines the number of times of preliminary light emission.

  Here, the microcomputer 213 includes one luminance value (0 to 255) of each of the areas into which the screen is divided into nine in the first luminance range (for example, 235 to 255), or the second If one is included in the luminance range (for example, 0 to 20), it is determined that the preliminary light emission is performed once. Further, the microcomputer 213 includes two or more luminance values (0 to 255) in each of the divided areas of the screen in the first luminance range (for example, 235 to 255), or When two or more are included in the second luminance range (for example, 0 to 20), it is determined that the preliminary light emission is performed twice. For example, when the luminance value of the first photometric result (the luminance value of each region) is (245, 255, 200, 35, 15, 35, 140, 180, 170), the luminance value 245 and the luminance value Therefore, the microcomputer 213 determines that preliminary light emission is performed twice.

  The above embodiment is merely an example, and any configuration may be used as long as the number of times of preliminary light emission can be determined according to the photometric result. The number of preliminary light emission may be selected from a plurality of times without being limited to the above embodiment. Further, the number of times of preliminary light emission is determined according to the photometry result before the preliminary light emission. However, the present invention is not limited to this, and the number of preliminary light emission times may be determined according to the photometry result after the preliminary light emission. .

1-4-2. Control Unit The microcomputer 213 that implements the control unit controls the strobe 215 and the AE sensor 210 when receiving a shooting start signal. Specifically, when the microcomputer 213 determines that the preliminary light emission is performed twice, the microcomputer 213 controls the AE sensor 210 to set an arbitrary sensitivity (ISO 400). In FIG. 7, an arbitrary sensitivity is set as a reference sensitivity. If the sensitivity of the AE sensor 210 is set to an arbitrary sensitivity before receiving the shooting start signal, it is not necessary to set the arbitrary sensitivity after receiving the shooting start signal. In short, any sensitivity is the first light receiving sensitivity.

  Next, the microcomputer 213 controls the strobe 215 to cause the first preliminary light emission. At this time, the AE sensor 210 measures the brightness of the light reflected from the subject by the first preliminary light emission. This measurement result is taken as a first photometry result.

  Thereafter, the microcomputer 213 controls the AE sensor 210 and sets the sensitivity based on the information regarding the distance to the subject acquired by the AF sensor 209 before receiving the imaging start signal. The sensitivity (second light receiving sensitivity) set based on the information related to the distance to the subject is a first area where the distance to the subject is close to the imaging device (for example, 30 to 149 cm) as shown in FIG. If it is included, the sensitivity is set to be smaller than an arbitrary sensitivity (for example, ISO 200). On the other hand, when the distance to the subject is included in the second region (for example, 150 to 200 cm) far from the imaging device, the sensitivity is set with a sensitivity (for example, ISO 800) larger than an arbitrary sensitivity. Here, the first region is configured not to overlap the second region but to include a region having a shorter distance than the second region. Then, the microcomputer 213 controls the strobe 215 to cause the second preliminary light emission. At this time, the AE sensor 210 measures the brightness of the light reflected from the subject by the second preliminary light emission. This measurement result is taken as a second photometry result. The light quantity of the strobe during the first and second preliminary emission is not particularly limited, but is preferably constant. When the microcomputer 213 determines that the preliminary light emission is performed once, or when the microcomputer 213 determines that the preliminary light emission is not performed, the microcomputer 213 performs the same operation as that of the prior art. Since these operations are conventional techniques, 2. The operation will be briefly described.

  The microcomputer 213 sets the sensitivity of the AE sensor 210 based on the information about the distance to the subject acquired by the AF sensor 209 before receiving the shooting start signal. However, the present invention is not limited to this, and the shooting start signal is not limited thereto. The sensitivity of the AE sensor 210 may be set based on information about the distance to the subject acquired by the AF sensor 209 after reception.

1-4-3. Light quantity calculation means The microcomputer 213 realizing the light quantity calculation means calculates the light emission quantity of the main light emission according to the photometric result of the photometry means. The microcomputer 213 uses the first and second photometric results of the AE sensor 210 when the first and second preliminary light emission is performed before calculating the main light emission light quantity. Is calculated. That is, the microcomputer 213 calculates the light emission amount of the main light emission using the output of the AE sensor 210 at the time of the first preliminary light emission and the output of the AE sensor 210 at the time of the second preliminary light emission. In the present embodiment, when the microcomputer 213 determines that the preliminary light emission is not performed, the light emission amount of the main light emission is calculated based on the photometric result before the preliminary light emission. Further, when the microcomputer 213 determines that the preliminary light emission is performed once, the light emission amount of the main light emission is calculated based on the photometric result at the time of the preliminary light emission. In these processes, the light emission quantity of the main light emission can be calculated by the same method as in the prior art.

  Here, in the present embodiment, since the luminance values of the nine divided areas are acquired, an example of a method for calculating the light emission amount of main light emission based on the luminance values of each area will be described. The following description is an example in the case of calculating the light emission amount of the main light emission based on the first and second photometric results. In the present embodiment, the light emission amount of the main light emission can be calculated by using the average of the first photometry result in the first preliminary light emission and the second photometry result in the second preliminary light emission. For example, when the first photometric result is a result as shown in FIG. 5 and the second photometric result is a result as shown in FIG. 5, the luminance value of each region is added to 2. By dividing, an average luminance value (first luminance value) can be calculated.

  Using this first luminance value, the average of all the regions is taken (that is, the luminance values of nine regions are added and divided by 9). Thereby, the second luminance value is calculated. This result is calculated using Equation 2 below.

  The calculation formula (Formula 2) of the light emission amount Sn of the main light emission is that the light emission amount of the preliminary light emission (when the light emission light amount is not changed in the first and second preliminary light emission) is Sp, the second luminance value is Vp, and AE When an appropriate luminance value determined by the light receiving sensitivity of the sensor 210 (during the first preliminary light emission) is Vn, it can be calculated by the following equation 2.

Sn = (Vn / Vp) Sp (Formula 2)
Thereby, the emitted light quantity of the main light emission can be calculated based on the first photometric result and the second photometric result.

1-4-4. Imaging Unit The microcomputer 213 that realizes the imaging unit causes the flash 215 to perform main light emission based on the light emission amount of main light emission calculated by the light amount calculation unit, and causes the CMOS sensor 202 or the like to perform image capturing. Briefly, the microcomputer 213 outputs a control signal including the amount of main light emission to the strobe 215. In addition, the microcomputer 213 drives the CMOS sensor 202, a mirror, and the like to photograph the subject. Note that these photographing operations are the same processing as in the prior art, and thus description thereof is omitted.

2. Operation Next, the operation of the imaging apparatus 1 configured as described above will be described with reference to the flowchart of FIG. This operation of the imaging apparatus 1 starts when the user turns the power supply 207 of the imaging apparatus 1 from OFF to ON. It is assumed that the shooting mode is set.

  First, the microcomputer 213 determines whether or not the shutter switch 214 has accepted a half-press operation (B1). The microcomputer 213 repeats Step B1 until the shutter switch 214 is half-pressed.

  When the microcomputer 213 detects that the shutter switch 214 has received a half-press operation, the AF sensor 209 acquires information regarding the distance to the subject (B2). In this case, the AF sensor 209 outputs the focus position of the focus lens for focusing to the microcomputer 213.

  After step B2, the brightness of the subject is measured by the AE sensor 210 (B3). As a result, a photometric result before preliminary light emission is output from the AE sensor 210 to the microcomputer 213. Note that the order of steps B2 and B3 may be reversed.

  Next, the microcomputer 213 determines whether or not the shutter switch 214 has been fully pressed (acquisition of a photographing start signal) (B4). The microcomputer 213 continues the process of step B3 until the shutter switch 214 is fully pressed. Although not shown, when the half-press signal from the shutter switch 214 to the microcomputer 213 is interrupted, the process proceeds to step B1.

  When the microcomputer 213 receives the photographing start signal, the microcomputer 213 determines whether or not preliminary light emission is necessary according to the photometric result before preliminary light emission, and determines the number of times of preliminary light emission if necessary (B5). If the microcomputer 213 determines that preliminary light emission is necessary, the process proceeds to step B7 (B6). On the other hand, if the microcomputer 213 determines that preliminary light emission is not necessary, the process proceeds to step B14 (B6).

  In step B7, the microcomputer 213 determines whether preliminary light emission is required twice (B7). If it is determined that preliminary light emission is required twice, the microcomputer 213 sets the light reception sensitivity of the AE sensor 210 to an arbitrary sensitivity (ISO400) (B8). The arbitrary sensitivity of the present embodiment is a predetermined sensitivity. Next, the microcomputer 213 controls the strobe 215 to cause the first preliminary light emission (B9). At this time, the AE sensor 210 measures the brightness of the light reflected from the subject by the first preliminary light emission. Thereafter, the microcomputer 213 adjusts the light receiving sensitivity of the AE sensor based on the information regarding the distance to the subject input from the AF sensor 209 (B10). At this time, the sensitivity to be set is set to be larger or smaller than an arbitrary sensitivity according to the information regarding the distance. Then, the microcomputer 213 controls the strobe 215 to cause the second preliminary light emission (B11). At this time, the AE sensor 210 measures the brightness of the light reflected from the subject by the second preliminary light emission. Thereafter, the process proceeds to step B14.

  On the other hand, when it is determined that the preliminary light emission is not required twice, the microcomputer 213 sets the light reception sensitivity of the AE sensor 210 to an arbitrary sensitivity (ISO400) (B12). The microcomputer 213 controls the strobe 215 to perform preliminary light emission (B13). At this time, the AE sensor 210 measures the brightness of the light reflected from the subject by the preliminary light emission. Thereafter, the process proceeds to step B14.

  In step B13, the microcomputer 213 calculates the light emission amount of the main light emission using the first and second photometry results as necessary (B14). Thereafter, the microcomputer 213 controls the strobe 215 to perform the main light emission based on the calculated main light emission amount (B15). In addition, the microcomputer 213 controls the CMOS sensor 202, the mirror, and the like, and captures the subject image formed by the optical system 301.

3. Summary As described above, the imaging apparatus 1 according to the present embodiment uses the strobe light 215 that irradiates the subject with light as the first preliminary light emission, the second preliminary light emission performed after the first preliminary light emission, or the main light emission. An optical system that collects the light reflected from the subject, an AF sensor 209 that acquires information about the distance from the imaging device 1 to the subject, and the reflected light from the subject during the first or second preliminary light emission. The AE sensor 210 that acquires light and measures the brightness of the subject, the microcomputer 213 that calculates the light emission amount of the main light emission according to the light measurement result in the first or / and second preliminary light emission, and the imaging device 1 On the other hand, it includes a microcomputer 213 that controls the strobe 215 and the AE sensor 210 when a shooting start signal for instructing the start of shooting is received. When the microcomputer 213 receives the shooting start signal, the microcomputer 213 causes the flash 215 to perform the first preliminary light emission, and then causes the flash 215 to perform the second preliminary light emission. The sensor 210 acquires light with an arbitrary sensitivity, and in the second preliminary light emission, the AE sensor 210 receives light with a sensitivity larger or smaller than the arbitrary sensitivity according to the information about the distance acquired by the AF sensor 209. Get it.

In this way, the light receiving sensitivity at the time of the second preliminary light emission can be raised or lowered with respect to the arbitrary sensitivity set at the time of the first preliminary light emission according to the distance measurement result of the distance measuring means. For this reason, even when the distance from the device to the subject is short, even when the first preliminary light emission occurs, the dimming is over (the amount of light is larger than the dynamic range of the image sensor). In the second preliminary light emission, the light receiving sensitivity can be lowered. Thus, it is possible to prevent over-dimming during the second preliminary light emission.
(Other embodiments)
Embodiment 1 was illustrated as embodiment of this invention. However, the present invention is not limited to the first embodiment, and can be implemented in other embodiments. Therefore, other embodiments of the present invention will be described collectively below.

  In the first embodiment, the CMOS sensor is exemplified as the imaging unit. However, other imaging means may be used instead of the CMOS sensor. In short, any device that captures a subject and generates image data may be used. As another imaging means, for example, a CCD image sensor may be used.

  In the first embodiment, the strobe is exemplified as the light emitting means. However, the present invention is not limited to this, and any object may be used as long as it can irradiate the subject with light. A flash using an LED is conceivable.

  In the first embodiment, the light emission amount is determined by the calculation formula for obtaining the light emission amount Sn. However, the present invention is not limited to this, and the light emission amount of the main light emission may be determined based on the guide number. Good.

  In the first embodiment, the light emission amount of the main light emission is calculated based on the second luminance value that is the average of the first photometry result and the second photometry result. However, the present invention is not limited to this. Absent. For example, the light emission amount of the main light emission may be determined using a known face detection technique. Further, when the first photometry result and the second photometry result are obtained as shown in FIG. 9, the main light emission is based on the photometry result of either the first photometry result or the second photometry result. The amount of emitted light may be calculated.

  In addition, the determination unit, the control unit, the light amount calculation unit, and the like are realized by a microcomputer. However, the present invention is not limited to this, and may be realized by a dedicated semiconductor circuit. Moreover, you may implement | achieve using a some microcomputer.

  The photometric means is realized by an AE sensor, but is not limited to this, and may be realized by an imaging means and a semiconductor circuit such as a microcomputer as described above.

  In the embodiment of the present invention, the light emission quantity of the main light emission is calculated using the photometric result (the luminance value at the time of preliminary light emission). However, the present invention is not limited to this, and the light emission quantity of main light emission may be determined by estimating the distance from the luminance value at the time of preliminary light emission. In this case, the distance to the subject is calculated based on a table that can calculate the distance (distance to the subject) corresponding to the luminance value at the time of preliminary light emission. Based on this calculation result, the light emission quantity of the main light emission is determined. Since the method for determining the amount of light emission of the main light emission based on the distance is a method used in the prior art, the description is omitted.

  In the first embodiment of the present invention, the sensitivity set in advance in steps B8 and B12 in FIG. 6 is set as an arbitrary sensitivity. However, the present invention is not limited to this. For example, the sensitivity corresponding to the photometric result measured by the AE sensor 210 before the preliminary light emission may be set as an arbitrary sensitivity.

  In another embodiment, the light receiving sensitivity may be changed (C10) according to the AF auxiliary light photometry result instead of the light receiving sensitivity change (B10) according to the distance measurement result.

  The operation of another embodiment will be described with reference to the flowchart of FIG. A description of processing similar to that in the flowchart of FIG. 6 is omitted.

  First, the same processing as in step B1 is performed (C1). When the shutter switch 214 is half-pressed in step C1, the microcomputer 213 controls the auxiliary light irradiation unit 220 to irradiate the subject with AF auxiliary light (C2). Thereafter, the AE sensor 210 performs AF auxiliary light. To measure the brightness of the light reflected from the subject (C3). Thereafter, the same processing as in Steps B4 to B7 is performed (C4 to 7).

  If it is determined in step C7 that preliminary light emission is required twice, the microcomputer 213 sets the sensitivity of the AE sensor 210 to an arbitrary sensitivity as in step B8 (C8). Then, the microcomputer 213 controls the strobe 215 to cause the first preliminary light emission (C9) as in step B9. At this time, the AE sensor 210 measures the reflected light in the first preliminary light emission.

  Next, the microcomputer 213 adjusts the sensitivity of the AE sensor 210 in accordance with the photometric result of the light reflected from the subject by the AF auxiliary light (C10). The sensitivity of the AE sensor 210 to be adjusted is determined when the reflected light based on the AF auxiliary light is included in the first luminance region (for example, luminance values 126 to 255), and the subject is present nearby. Increase sensitivity. On the other hand, when the reflected light based on the AF auxiliary light is darker than the second luminance region (for example, luminance value 0 to 125), it is determined that the subject is present far away, and the light receiving sensitivity is reduced. In short, the first luminance area does not overlap with the second luminance area, and includes one having a luminance value larger than that of the second luminance area. Then, the microcomputer 213 controls the strobe 215 in the same manner as in step B11 to cause the second preliminary light emission (C11). At this time, the AE sensor 210 measures the reflected light in the second preliminary light emission. Steps C12 to C15 are the same as steps B12 to B15, and will not be described.

  In this way, when an accurate distance measurement cannot be performed in an environment where the shooting environment is dark, it is possible to irradiate the AF auxiliary light and obtain brightness instead of the distance to the subject. This makes it possible to adjust the light receiving sensitivity of the second preliminary light emission in consideration of the distance to the subject, so that more preferable light control can be performed. That is, it is effective when the shooting environment is dark.

  That is, the present invention is not limited to the above embodiment, and can be implemented in various forms.

  The present invention can be applied to an imaging apparatus provided with light emitting means. Specifically, it can be used for digital still cameras equipped with strobes, movies, mobile phones with camera functions, and the like.

1 is a perspective view of an imaging apparatus according to a first embodiment of the present invention. 1 is a block diagram showing a configuration of an imaging apparatus according to a first embodiment of the present invention. The figure for demonstrating the CMOS sensor concerning Embodiment 1 of this invention. The figure for demonstrating the AE sensor concerning Embodiment 1 of this invention. The figure for demonstrating the calculation method of the light emission quantity of the main light emission concerning Embodiment 1 of this invention. Flowchart for explaining an operation example of the imaging apparatus according to the first embodiment of the present invention. The figure for demonstrating operation | movement of the imaging device concerning Embodiment 1 of this invention. The figure for demonstrating the difference in the distance to the to-be-photographed object concerning Embodiment 1 of this invention. The figure for demonstrating the calculation method of the light emission amount of the main light emission concerning other embodiment. The flowchart for demonstrating the operation example of the imaging device concerning other embodiment

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Imaging device 2 Imaging device main body 3 Interchangeable lens 202 CMOS sensor 204 Image processing part (DSP)
205 Buffer Memory 206 Liquid Crystal Monitor 209 AF Sensor 210 AE Sensor 211 Flash Memory 212 Card Slot 213 Microcomputer 214 Shutter Switch 215 Strobe 216 Memory Card 220 Auxiliary Light Irradiation Unit 301 Optical System 2014 Shutter

Claims (2)

A light emitting means for irradiating the subject with light as the first preliminary light emission, the second preliminary light emission performed after the first preliminary light emission, or the main light emission;
An optical system that collects the light reflected from the subject;
Ranging means for obtaining information about the distance from the device to the subject;
Photometric means for acquiring light reflected by the subject and measuring the brightness of the subject at the time of the first or second preliminary light emission;
A light amount calculation means for calculating a light emission amount of main light emission according to a photometric result at the time of the first or / and second preliminary light emission;
A control means for controlling the light emitting means and the photometry means when receiving a photographing start signal instructing the apparatus to start photographing;
With
The control means includes
When receiving the shooting start signal,
After causing the light emitting means to perform the first preliminary light emission, causing the light emitting means to perform the second preliminary light emission,
In the first preliminary light emission, information on the distance to the subject acquired by the distance measuring means after the light is acquired by the photometry means with the first light receiving sensitivity in the second preliminary light emission. Causing the photometry means to acquire light with a second light receiving sensitivity different from the first light receiving sensitivity determined accordingly,
Imaging device. A light emitting means for irradiating the subject with light as the first preliminary light emission, the second preliminary light emission performed after the first preliminary light emission, or the main light emission;
An optical system that collects the light reflected from the subject;
Auxiliary light irradiation means for irradiating the subject with auxiliary light;
Photometric means for acquiring light reflected by the subject and measuring the brightness of the subject at the time of the auxiliary light irradiation or at the time of the first or second preliminary light emission;
A light amount calculation means for calculating a light emission amount of main light emission according to a photometric result at the time of the first or / and second preliminary light emission;
A control means for controlling the light emitting means and the photometry means when receiving a photographing start signal instructing the apparatus to start photographing;
With
The control means includes
When receiving the shooting start signal,
While causing the light-emitting means to perform the first preliminary light emission, the second preliminary light emission is performed,
In the first preliminary light emission, information on the distance to the subject acquired by the distance measuring means after the light is acquired by the photometry means with the first light receiving sensitivity in the second preliminary light emission. Causing the photometry means to acquire light with a second light receiving sensitivity different from the first light receiving sensitivity determined accordingly,
Imaging device.

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