JP2008032872A - Photometric device and camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To accurately perform photometry of field luminance and photometry of strobe light for photographing by one light receiving means without complicating constitution. <P>SOLUTION: The photometric device has: an accumulation type light receiving means 130 used for the photometry of the field luminance and the photometry of the strobe light; a strobe light guiding means 134 guiding a part of the strobe light to the light receiving means without irradiating field; and an external light shielding means 131 arranged between the strobe light guiding means and the light receiving means, and switching between a state where the strobe light is not shielded to the light receiving means via the strobe light guiding means and a state where external light is shielded to the light receiving means through the strobe light guiding means. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a photometric device and a camera having a light receiving means used for field luminance metering and strobe light metering.

  A photometric device has been proposed (Patent Document 1) that compares the output value obtained by preliminarily emitting strobe light prior to the actual photographing and measuring the reflected light from the subject and the output value when the strobe is not emitting light, that is, when the strobe light is stationary. ing. In this proposal, the amount of strobe light emission at the time of actual photographing is determined based on this comparison value. Further, the reflected light photometry by the subject of the preliminary light emission strobe light and the steady light photometry when the strobe light is not emitted are performed using the same photometry sensor. By doing so, the space efficiency of the camera is increased and the cost is reduced.

  In addition, an optical sensor is optimally arranged in which the strobe light metering for controlling the strobe light emission amount, the subject reflected light at the time of strobe preliminary light emission, and the constant light metering at the time of non-strobe light emission are independent. In this way, a proposal (Patent Document 2) has been made to improve the space efficiency of the camera. An outline of the single-lens reflex type camera disclosed in this proposal is shown in FIG.

As shown in FIG. 7, an optical fiber 134 is attached to the strobe light emitting panel 132c. When the strobe light is emitted, a part of the strobe light comes out of the exit of the optical fiber 134 from the strobe light emitting panel 132c via the optical fiber 134. The strobe light is received and monitored by a dedicated optical sensor 137 (137a is a visibility filter). The flash light emission is stopped when an appropriate amount of received light (strobe light emission amount) is reached. In addition, the photometry of the field luminance is performed by the photometric sensor 130 (130a is a visibility filter). The other members are the same as those shown in FIG.
Japanese Patent Laid-Open No. 06-250252 JP 2002-122905 A

  The object field light is reflected by the reflecting mirror through the photographing lens, and is primarily imaged on the focusing plate. The object scene image formed here is further subjected to secondary image formation on a photometric sensor via an imaging lens. A photometric method for evaluating the output of the photometric sensor is called a TTL photometric method. Many conventional single-lens reflex cameras adopt the TTL photometry method. This TTL photometry method makes it possible to accurately measure the field luminance.

  However, in the TTL metering method, the reflecting mirror is raised during photographing, and the field light that passes through the photographing lens is imaged on the image sensor (or film), and the object field is formed on the focus plate. The light will not come. That is, during shooting, the finder image (focus plate image) is not visible to the photographer, and the field luminance cannot be measured. This is because even if the camera emits strobe light for photographing, the reflecting mirror is raised as described above before the strobe light is emitted. For this reason, the photometric sensor 130 holding the focusing plate cannot measure the light emission amount of the strobe light. On the other hand, if the structure shown in FIG. 7 is taken, the problem is solved.

  On the other hand, let us consider a case in which an optical fiber is provided and the same photometric sensor is used to measure the strobe light at the time of actual photographing and the constant light metering when the strobe is not emitted. Assume that luminance is detected from an object scene image formed on a photometric sensor through a photographing lens. Then, external light enters the photometric sensor from the strobe light emitting panel through the optical fiber, and the luminance of the object scene image incident through the photographing lens to be originally measured cannot be detected accurately. In other words, it has been difficult to simply measure the strobe light at the time of actual photographing and the constant light metering when the strobe is not emitted by the same photometric sensor.

(Object of invention)
SUMMARY OF THE INVENTION An object of the present invention is to provide a photometric device and a camera that can accurately perform object field luminance metering and strobe light metering with a single light receiving means without using a complicated configuration.

  In order to achieve the above object, the present invention provides storage type light receiving means used for field luminance metering and strobe light metering, and receiving the light without irradiating a part of the strobe light to the field. A strobe light guiding means for guiding the light to the light receiving means, a state in which the strobe light is disposed between the strobe light guiding means and the light receiving means and does not block the strobe light to the light receiving means via the strobe light guiding means, and the strobe light guiding means The photometric device includes an external light shielding unit that switches a state of shielding external light to the light receiving unit via the light source.

  Similarly, in order to achieve the above object, the present invention provides a strobe light emitting means built in a camera, a storage type light receiving means used for field luminance metering and strobe light metering, and a part of the strobe light. Strobe light guiding means for guiding the light to the light receiving means without irradiating the object field, and strobe light to be disposed between the strobe light guiding means and the light receiving means and to the light receiving means via the strobe light guiding means The camera has a non-light-shielding state and an external light-shielding means for switching between a state of shielding external light to the light-receiving means via the strobe light guiding means.

  According to the present invention, it is possible to provide a photometric device or a camera capable of accurately performing photometry of field luminance and strobe light for photographing with a single light receiving means without using a complicated configuration. It is.

  The best mode for carrying out the present invention is as shown in Examples 1 to 3 below.

  FIG. 1 is a configuration diagram showing an outline of a digital single-lens reflex camera according to Embodiment 1 of the present invention. In FIG. 1, reference numeral 101 denotes a CPU (central processing unit), and the operation of the camera is controlled by the CPU 101. Reference numeral 105 denotes a photographic lens that forms an image of the object field light on the CCD 106 that is an image sensor. Reference numeral 102 denotes a shutter that controls the amount of light in the field that reaches the CCD 106 from the photographing lens 105 by adjusting the timing of the opening / closing operation.

  Part of the object field light is guided to a later-described known phase difference type focus detection unit by a semi-transmissive main mirror 121 and a sub mirror 122. In this focus detection unit, it is detected in which direction and how much the focus of the field light imaged by the photographing lens 105 is deviated from the light receiving surface of the CCD 106. That is, a so-called defocus amount is detected. The phase difference focus detection unit includes a field lens 123, a secondary imaging lens 124, and a focus detection line sensor (CCD) 119. This phase difference focus detection unit can detect a focus in a specific area on the finder screen.

  The CPU 101 sends a driving amount pulse of the photographing lens 105 to the photographing lens drive control unit 125 in consideration of the lens driving sensitivity of the photographing lens 105 (fineness of control unique to the lens) with respect to the defocus amount. The photographing lens drive control unit 125 drives the pulse motor in accordance with the sent drive pulse, and drives the photographing lens 105 to the in-focus position. Thereby, automatic focus adjustment is performed.

  Reference numeral 128 denotes a focusing plate placed on an imaging plane equivalent to the imaging plane of the CCD 106. The object scene image formed on the focus plate 128 is provided to the user's eyes through the pentaprism 127 and the eyepiece 126. That is, it has a TTL type optical finder configuration.

  A photometric sensor 130 is used as a light receiving means for measuring the luminance of visible light in the object scene. The visible light of the object scene is imaged on the photometric sensor 130 by the imaging lens 129 through the visibility filter 130a. The photometric sensor 130 has a light receiving area divided into 3 × 5 in the vertical and horizontal directions. Then, the main area of the viewfinder field (field area) of the camera is divided into 3 × 5 areas, and photometry can be performed at a wavelength that matches the human visual sensitivity.

  Reference numeral 132 denotes a small strobe built into the camera. The strobe 132 includes a xenon tube 132a, a reflector 132b, and a strobe light emitting panel 132c for efficiently emitting strobe light to the front surface. The strobe 132 is normally closed inside the camera (pop-down state). At the time of flash emission, the flash protrudes from the camera around the hinge portion 132d (pop-up state), and the flash emission is performed with the flash emission panel 132c facing the subject. The photometric sensor 130 is also used as a light receiving means for measuring the strobe light from the strobe 132 as will be described later.

  Here, the structure until the photometric sensor 130 receives the strobe light from the strobe 132 will be described in detail.

  In FIG. 1, a strobe light emitting panel 132c is connected to an optical fiber 134, which is a strobe light guiding means, at the outer periphery thereof. The optical fiber 134 guides the strobe light to the photometric sensor 130 (actually, in front of the visibility filter 130a). Here, the photometric sensor 130 is a storage type sensor, and it is possible to monitor the amount of strobe light emission by its function. When the strobe light emission amount reaches an appropriate value, the CPU 101 sends a stop signal to a strobe circuit 109 shown in FIG. 3 described later to stop the strobe light emission.

  That is, the same storage-type photometric sensor 130 is used for the photometric sensor for measuring the field luminance and the photometric sensor for measuring the strobe light (strobe main light emission) for photographing.

  However, as described above, simply using the same photometric sensor 130 causes the following problems. It is assumed that luminance is detected from an object scene image formed on the photometric sensor 130 through the photographing lens 105. At this time, outside-field light enters the photometric sensor 130 through the optical fiber 134 from the strobe light emitting panel 132c made of the transparent material. As a result, it is impossible to accurately detect the luminance of the object scene image incident through the photographing lens 105 to be originally measured. Therefore, an external light shielding means for shielding external light is required.

  Here, the external light shielding means according to the first embodiment will be described with reference to FIG. FIG. 2 is a diagram in which the camera is in a shooting (exposure) state with the flash 132 emitting light.

  In FIG. 2, the main mirror 121 is in an up state (a state in which it is retracted from the photographing optical path). A part of the strobe light generated by the strobe light emission due to the photographing operation enters the photometric sensor 130 from the strobe light emitting panel 132c via the optical fiber 134. The optical fiber 134 is divided in the middle with a predetermined gap. In order to minimize the loss of light energy due to such division, condensing lenses 135 a and 135 b are arranged on both sides of the cut surface of the optical fiber 134. Here, 131 is an L-shaped lever which is an external light shielding means provided on the hinge shaft of the main mirror receiving plate 121a holding the main mirror 121. The L-shaped lever 131 can rotate as indicated by an arrow A in conjunction with the rotation operation associated with the up and down of the main mirror 121. The distal end portion 131a of the L-shaped lever 131 can enter the gap portion of the condensing lenses 135a and 135b disposed at both ends of the cut surface of the optical fiber 134 (in the broken line state in FIG. 2).

  That is, in the shooting standby state of the camera that measures the subject brightness (the state shown in FIG. 1), unnecessary external light that the tip 131a of the L-shaped lever 131 enters the photometric sensor 130 from the strobe light emitting panel 132c via the optical fiber 134. Rotate until the component is shielded (broken line in FIG. 2).

  As described above, unnecessary external light components via the optical fiber 134 are shielded by the external light shielding means, which is a mechanical shutter called the L-shaped lever 131, except when the strobe light is emitted for photographing or during photographing operation. The unnecessary external light component is prevented from entering the photometric sensor 130. In other words, when measuring the field luminance, unnecessary external light components incident from the strobe light emitting panel 132 c are shielded by the L-shaped lever 131. Therefore, it is possible to accurately measure the field luminance under normal light other than the strobe light with the photometric sensor 130. On the other hand, during strobe light emission (main light emission) for photographing, the external light shielding means does not shield strobe light from the optical fiber 134. Therefore, the strobe light from the optical fiber 134 can be accurately measured by the photometric sensor 130. Therefore, it is possible to accurately measure strobe light emission for photographing with the photometric sensor 130, and it is possible to accurately measure the field light incident from the photographing lens 105 with the same photometric sensor 130. .

  FIG. 3 is a block diagram showing a circuit configuration of the camera having the above configuration. In FIG. 3, reference numeral 101 denotes a CPU (central processing unit). Connected to the CPU 101 are a ROM 103a, a RAM 103b, a data storage unit 104, and an image processing unit 108, which store control programs. Furthermore, an LCD control unit 111, a release switch (SW) 114, and a DC / DC converter 117 for supplying power are also connected.

  A CCD control unit 107 is connected to the image processing unit 108, and a CCD 106 is connected to the CCD control unit 107. The CCD 106 has about 5 million effective pixels (2560 × 1920). A display drive unit 112 is connected to the LCD control unit 111, and a display unit 113 is connected to the display drive unit 112. The display unit 113 is a TFT color liquid crystal capable of displaying an image of 320 × 240 pixels obtained by thinning the image captured by the CCD 106 into 1/8 length and width. The DC / DC converter 117 is supplied with power from the battery 116.

  The CPU 101 performs various controls based on the control program in the ROM 103a. These controls include a process of reading a captured image signal output from the image processing unit 108 and performing DMA transfer to the RAM 103b. Similarly, a process of DMA-transferring data from the RAM 103b to the LCD control unit 111 is included. Also included is processing for JPEG compression of image data and storage in the data storage unit 104 in a file format.

  In addition, the CPU 101 instructs the CCD 106, the CCD control unit 107, the image processing unit 108, the LCD control unit 111, and the like to change the number of data fetching pixels and digital image processing.

  Reference numeral 119 denotes a pair of line sensors for focus detection. The focus detection control unit 120 performs A / D conversion on the voltage obtained from these line sensors 119 and sends it to the CPU 101. The focus detection control unit 120 also controls the accumulation time and AGC (auto gain control) of the line sensor 119 under the instruction of the CPU 101.

  The CPU 101 processes the signal sent from the focus detection control unit 120 to calculate the lens driving amount for the main subject to be brought into focus from the current focus detection state for the main subject. Then, an instruction is given to the taking lens driving unit 125. The photographic lens driving unit 125 can focus on the main subject by moving the focus adjustment lens in the photographic lens 105 based on this instruction.

  A photometric sensor 130 measures the luminance of the object scene and sends a signal to the CPU 101 as described above. The CPU 101 calculates the exposure amount of the camera based on this luminance information, and determines either or both of the shutter value and the aperture value of the photographing lens 105. The photometric sensor 130 measures the amount of light emitted from the strobe light emitting unit 133 and sends a signal to the CPU 101 during strobe light emission as described above. When the flash emission amount reaches an optimum value for exposure, the CPU 101 sends a stop signal to the flash circuit 109 to stop the flash emission unit 133 from emitting light. Also, based on the control of the CPU 101, an instruction of a photographing operation associated with the operation of the release switch 114, processing of a control signal for controlling the supply of power to each element, etc. to the DC / DC converter 117 are performed.

  The ROM 103a stores the control program as described above. The RAM 103b includes an image development area 103b1, a work area 103b2, a VRAM 103b3, and a temporary save area 103b4. The image development area 103b1 is used as a temporary buffer for temporarily storing a captured image (YUV digital signal) sent from the image processing unit 108 and JPEG compressed image data read from the data storage unit 104. . Furthermore, it is also used as an image-dedicated work area for image compression processing and decompression processing. The work area 103b2 is a work area for various programs. The VRAM 103b3 is used as a VRAM that stores display data to be displayed on the display unit 113. The temporary save area 103b4 is an area for temporarily saving various data. The data storage unit 104 is a non-volatile memory for storing captured image data compressed by JPEG by the CPU 101 or various attached data referred to by an application in a file format.

  The photographing lens 105 is composed of a plurality of lenses for optically projecting an object scene image onto the CCD 106, and the CCD (photoelectric conversion element) 106 converts the photographed image projected by the photographing lens 105 into an analog electric signal. It is an element for converting to. The CCD control unit 107 includes a timing generator for supplying a transfer clock signal and a shutter signal to the CCD 106. Further, a circuit for removing noise from the CCD output signal and performing gain processing, an A / D conversion circuit for converting an analog signal into a 10-bit digital signal, and the like are also included.

  The image processing unit 108 performs gamma conversion and color space conversion on the 10-bit digital signal output from the CCD control unit 107. Also, image processing such as white balance, AE, and flash correction is performed, and an 8-bit digital signal output in YUV (4: 2: 2) format is performed.

  The photographing lens 105, the CCD 106, the CCD control unit 107, and the image processing unit 108 constitute imaging means.

  The LCD control unit 111 receives YUV digital image data transferred from the image processing unit 108 or YUV digital image data obtained by performing JPEG decompression on an image file in the data storage unit 104. Then, after converting into an RGB digital signal, a process of outputting to the display driving unit 112 is performed. The display driving unit 112 performs control for driving the display unit 113.

  The LCD control unit 111, the display drive unit 112, and the display unit 113 constitute display means.

  The release switch 114 is a switch for instructing the start of the shooting preparation operation and the shooting operation. The release switch 114 has a two-step switch position when pressed by the user, and a camera setting lock operation such as white balance and AE is performed by detecting the first-stage position (switch SW1 is ON). . In the detection of the second stage position (ON of the switch SW2), an operation for capturing an object scene image signal is performed.

  The battery 116 is a rechargeable secondary battery or a dry battery. The DC / DC converter 117 receives a power supply from the battery 116 and generates a plurality of power supplies by performing boosting and regulation. A power supply of a necessary voltage is supplied to each element including the CPU 101. The DC / DC converter 117 can control the start and stop of each voltage supply by a control signal from the CPU 101.

  Next, a series of photographing operations when the strobe light emission of the camera having the above configuration is performed will be described with reference to the flowchart of FIG.

  In FIG. 4, when the power switch (not shown) is turned on from the camera inoperative state, the power of the camera is turned on (step # 200), and the CPU 101 switches the switch SW1 to the one-step position by pressing the release switch 114. Wait until it is turned on (step # 201). When it is detected that the switch SW1 is turned on, field luminance information obtained by dividing the photographic field into 3 × 5 is obtained from the photometric sensor 130 (operation of photometry 1), and then stored in the memory (step #). 202). At this time, the distal end portion 131a of the L-shaped lever 131 is in a state of entering the gap portions of the condensing lenses 135a and 135b arranged at both ends of the cut surface of the optical fiber 134 (the broken line state in FIG. 2).

  Next, the strobe 132 performs light emission (preliminary light emission) of a certain amount (for example, 1/10 of full light emission) to the object scene (step # 203). Then, the reflected light of the strobe light applied to the object in the object scene is again measured by the photometric sensor 130 (operation of photometry 2) (step # 204). In photometry 1 and 2, since the light beam passing through the optical fiber 134 is shielded by the tip 131a of the L-shaped lever 131, the field luminance information at the time of non-flash emission and pre-flash emission is accurately measured. . After that, the difference between the field luminance information stored in step 202 when the flash is not fired and the field brightness information when the flash is preliminarily fired is calculated, and the true brightness of the subject actually illuminated with the flash light is obtained. Is calculated. Based on this, the optimum light emission amount of the strobe 132 for properly illuminating the main subject is determined. Further, based on the field luminance information obtained by the photometry in step # 202, the photographing lens aperture value and the shutter time, which are exposure values of the camera, are determined by a program built in the camera according to a predetermined photometric algorithm calculation. . The algorithm for calculating the optimum exposure value from each 3 × 5 luminance information obtained from the photometric sensor 130 may be a simple addition average, or the maximum in the photometric area corresponding to the focus detection area determined in step # 204. An operation with weighting may be used.

  Here, it is assumed that the focus detection area selection mode of the camera is set to the manual mode (a focus detection area selection switch (not shown) is turned on). In this case, the photographer can arbitrarily select one of a plurality of focus detection areas by a switch dial operation (not shown). On the other hand, assume that the focus detection area automatic mode is set. In this case, one of the plurality of focus detection areas is selected by the focus detection area automatic selection subroutine based on the defocus amounts in the plurality of focus detection areas of the phase difference type focus detection unit. Several methods are conceivable as algorithms for automatically selecting a focus detection area. However, in the multipoint AF camera, a near point priority algorithm that puts a weight on the central focus detection area known in the art is effective.

  As described above, even if the focus detection area selection mode is set to the manual mode or the automatic mode, one focus detection area is determined as a result. Then, a lens extension amount to be finally obtained is determined from the focus detection deviation amount (defocus amount) obtained here and the lens driving sensitivity of the photographing lens 105 mounted on the camera (step # 205). Next, the CPU 101 sends a signal to the photographing lens drive control unit 125 according to the signal of the line sensor 119 in a state before the lens is driven. As a result, the predetermined amount of the photographing lens 105 can be driven (step # 206).

  Thereafter, the state of the switch SW1 is checked. If the switch SW1 is OFF, it returns to the standby state waiting for the switch SW1 to be turned ON (step # 201). Even if the switch SW1 is kept on (step # 207), it is assumed that the release switch 114 is not pushed down to the two-step position and the switch SW2 is off (step # 208). In this case, the process returns to step # 207 again, and as long as the switch SW1 continues to be turned on, it enters a standby state waiting for the switch SW2 to be turned on.

  On the other hand, looking at the viewfinder field of view in which the photographer is displayed in focus, the switch SW1 is continuously turned on (step # 207), and the release switch 114 is pressed down to the two-stage position, and the switch SW2 is turned on. It is assumed that it is turned on (step # 208). As a result, the main mirror 121 enters an up state (a state in which it is retracted from the photographing optical path). In conjunction with this, the tip 131a of the L-shaped lever 131 is retracted from the gap between the condensing lenses 135a and 135b disposed at both ends of the cut surface of the optical fiber 134. In this case, the CPU 100 transmits signals to a shutter control unit, a diaphragm driving unit, and a CCD control unit 107 (not shown) to perform a known photographing operation (step # 209).

  Here, in the photographing operation, first, the motor is energized via a motor control unit (not shown) to raise the main mirror 121, and the diaphragm of the photographing lens 105 is narrowed down. Thereafter, the magnet MG-1 of the shutter 102 is energized and the front curtain of the shutter 102 is opened, so that the accumulation of the field light in the CCD 106 is started. After a predetermined shutter time elapses, the magnet MG-2 is energized, and the rear curtain of the shutter 102 is closed, whereby the accumulation of the field light in the CCD 106 is completed.

  During the series of camera photographing operations described above, the strobe 132 emits light through the strobe circuit 109 until the start of travel of the rear curtain of the shutter 102, triggered by the front curtain travel completion signal of the shutter 102 (step # 210). The amount of light emission here is obtained by calculation by photometry 2 (step # 202) accompanying strobe preliminary light emission. At this time, the CPU 101 monitors the amount of strobe light incident on the photometric sensor 130 from the strobe light emitting panel 132c through the optical fiber 134 (step # 211). When the strobe light reaches the light emission amount calculated in step # 204, the CPU 101 issues a stop signal to the strobe circuit 109 to stop the light emission of the strobe 132 (step # 212).

  With the above operation, the CCD 106 accumulates the light amount from the object scene image accompanied with the strobe light.

  Next, the motor is energized again, the mirror is lowered, the shutter is charged, and the series of photographing operations) is completed (step # 213).

  Through the above-described photographing operations from step # 209 to # 213, the object scene image exposed to the CCD 106 is photoelectrically converted and converted into digital data of about 5 million pixels (2560 × 1920) by the image processing unit 108. The Thereafter, it is temporarily stored in the RAM 103b. Then, the stored entire image digital data of 2560 × 1920 pixels is converted into 320 × 240 pixel entire image data that has been subjected to thinning processing of 1/8 in the vertical and horizontal directions for display on the display unit 113. Then, it is stored again in the display VRAM 103b3, and the entire image data of 320 × 240 pixels is displayed on the display unit 113. Thereby, the photographer can confirm the whole image of the photographed image (step # 214).

  The entire image digital data of 2560 × 1920 pixels stored in the RAM 103b is JPEG-compressed and then recorded as image data on a recording medium such as a compact flash (registered trademark) by the data storage unit 104 (step #). 215). Next, the camera again enters a state where the photographer waits for input by some operation member (step # 216), and continues to display the entire image during that time. When an input is made, the entire image display on the display unit 113 is turned off, and a transition is made to a state corresponding to the input.

  FIG. 5 is a block diagram showing the main parts of a digital single-lens reflex camera according to Embodiment 2 of the present invention. The same parts as those in FIG. Other configurations of the camera (FIGS. 1, 3, and 4) and the like are the same as those in the first embodiment, and a description thereof will be omitted.

  In FIG. 5, reference numeral 138 denotes an L-shaped lever corresponding to the L-shaped lever 131 (see FIG. 2) in the first embodiment, which is an external light shielding means. The L-shaped lever 138 is attached on an extension of a hinge portion 132d (also see FIG. 1) that is a rotation center for popping up and down the entire strobe 132 from the camera body.

  The L-shaped lever 138 follows the rotation of the hinge portion 132d accompanying the pop-up and pop-down of the strobe 132, and similarly to the description of FIG. 2, the leading end portion 138a is disposed on both sides of the cut surface of the optical fiber 134. Advance between 135b. Thereby, it is possible to transmit strobe light from the strobe light emitting panel 132c and to block unnecessary external light from the outside.

  That is, the strobe light can be guided to the photometric sensor 130 when the strobe 132 is popped up by the movement of the L-shaped lever 138, that is, when metering the strobe light for photographing. And when it is popping down, it is possible to block unnecessary external light from the outside from the strobe light emitting panel 132c.

  Originally, when the strobe 132 is popped down, it is not necessary to provide external light shielding means if the strobe light emitting panel 132c is completely shielded from light by the camera exterior. However, since the external light incident light from the gap in the exterior becomes a problem in practice, the above external light shielding means is necessary.

  In the second embodiment described above, when the camera is in a shooting standby state (photometric measurement of subject brightness), an unnecessary external light component via the optical fiber 134 is transferred to an external light shielding unit called a L-shaped lever 138 that is a mechanical shutter. To shade. The unnecessary external light component is prevented from entering the photometric sensor 130. That is, at this time, unnecessary external light components incident from the strobe light emitting panel 132 c are shielded by the L-shaped lever 131. Therefore, it is possible to accurately measure the field luminance under pure light other than the strobe light, and the photometric sensor 130. On the other hand, when the strobe light is emitted for photographing, the external light shielding unit does not shield the strobe light from the optical fiber 134. Therefore, the strobe light from the optical fiber 134 can be accurately measured by the photometric sensor 130. Therefore, it is possible to accurately measure strobe light emission for photographing with the photometric sensor 130, and it is possible to accurately measure the field light incident from the photographing lens 105 with the same photometric sensor 130. .

  FIG. 6 is a block diagram showing the main parts of a digital single-lens reflex camera according to Embodiment 3 of the present invention. The same parts as those in FIGS. Other configurations of the camera (FIGS. 1, 3, and 4) and the like are the same as those in the first embodiment, and a description thereof will be omitted.

  The external light shielding means in the third embodiment is different from the means using mechanical movable parts such as the L-shaped levers 131 and 138. In the third embodiment, the liquid crystal device 136 is disposed at the exit of the optical fiber 134 that guides the strobe light to the photometric sensor 130 (actually the front surface of the visibility filter 130a).

  The liquid crystal device 136 becomes a liquid crystal shutter by being controlled so as to be in a light-shielding state during shooting standby state of the camera and in a transmitting state during strobe light emission for shooting or during a shooting operation. Thereby, it can be set as the external light shading means which enables control of transmission and shading of the light from the strobe light emitting panel 132c.

  Here, in FIG. 1, when the user depresses the release switch 114 (see FIG. 3) to the two-stage position, the main mirror 121 is retracted out of the optical path of the photographic lens 105. Then, the amount of field light condensed by the photographing lens 105 is controlled by the shutter 102 and is displayed as a field image by the CCD 106 in a photoelectric conversion process. Thereafter, the image data is recorded on a recording medium such as a flash memory, and is displayed on the display unit 113 as a captured image. Here, 113 is an external display unit made of TFT color liquid crystal.

  In the above-described third embodiment, when the camera is in a shooting standby state (when subject luminance is measured), an unnecessary external light component via the optical fiber 134 is removed by an external light shielding unit, which is an electric shutter, the liquid crystal device 136. Shield from light. The unnecessary external light component is prevented from entering the photometric sensor 130. That is, at this time, unnecessary external light components incident from the strobe light emitting panel 132 c are shielded by the liquid crystal device 136. Therefore, it is possible to accurately measure the field luminance under normal light other than the strobe light with the photometric sensor 130. On the other hand, when the strobe light is emitted for photographing, the external light shielding unit does not shield the strobe light from the optical fiber 134. Therefore, the strobe light from the optical fiber 134 can be accurately measured by the photometric sensor 130. Therefore, it is possible to accurately measure strobe light emission for photographing with the photometric sensor 130, and it is possible to accurately measure the field light incident from the photographing lens 105 with the same photometric sensor 130. .

  According to each of the embodiments described above, in the single-lens reflex camera, the photometric sensor 130 which is one light receiving unit is used for the field luminance photometry and the strobe light photometry. Therefore, it contributes to space saving of the camera and cost reduction. That is, according to the first to third embodiments, it is possible to provide a camera capable of accurately performing field luminance metering and strobe light metering with a single light receiving unit without using a complicated configuration.

1 is a configuration diagram illustrating an outline of a digital single-lens reflex camera according to a first embodiment of the present invention. FIG. It is a block diagram which shows the principal part of the digital single-lens reflex camera of FIG. It is a block diagram which shows the electrical structure of the digital single-lens reflex camera of FIG. 2 is a flowchart illustrating a shooting operation of the digital single-lens reflex camera in FIG. 1. It is a block diagram which shows the principal part of the digital single-lens reflex camera which concerns on Example 2 of this invention. It is a block diagram which shows the principal part of the digital single-lens reflex camera which concerns on Example 3 of this invention. It is a block diagram which shows the outline of the conventional digital camera.

Explanation of symbols

101 CPU
105 Photo lens 106 CCD
121 Main mirror 130 Photometric sensor 131 L-shaped lever 132 Strobe 133d Hinge part 134 Optical fiber 136 Liquid crystal device 138 L-shaped lever

Claims (9)

Storage type light receiving means used for field luminance metering and strobe light metering,
A strobe light guiding means for guiding a part of the strobe light to the light receiving means without irradiating a part of the object scene;
Between the strobe light guiding means and the light receiving means, a state in which the strobe light to the light receiving means via the strobe light light guiding means is not shielded, and an external light to the light receiving means via the strobe light guiding means And an external light shielding means for switching the state of shielding the light.   The external light shielding means is in a state in which the strobe light to the light receiving means via the strobe light guiding means is not shielded at the time of metering of the strobe light emission for photographing, and the strobe light guiding means at the time of metering the subject brightness. The photometric device according to claim 1, wherein external light to the light receiving means via a light is blocked.   The photometric device according to claim 1, wherein the external light blocking unit is a unit that mechanically blocks external light to the light receiving unit via the strobe light guiding unit.   3. The photometric device according to claim 1, wherein the external light blocking means is means for electrically shielding external light to the light receiving means via the strobe light guiding means. A flash emission means built in the camera;
Storage type light receiving means used for field luminance metering and strobe light metering,
A strobe light guiding means for guiding a part of the strobe light to the light receiving means without irradiating a part of the object scene;
Between the strobe light guiding means and the light receiving means, a state in which the strobe light to the light receiving means via the strobe light light guiding means is not shielded, and an external light to the light receiving means via the strobe light guiding means And an external light shielding means for switching a state of shielding the light.   The external light shielding means is in a state in which the strobe light to the light receiving means via the strobe light guiding means is not shielded at the time of metering of the strobe light emission for photographing, and the strobe light guiding means at the time of metering the subject brightness. The camera according to claim 5, wherein external light to the light receiving means via a light is blocked. When located in the photographing optical path, a part of the photographing light flux is guided to the light receiving means, and at the time of photographing, the mirror member is retracted from the photographing optical path,
6. The external light shielding means is in a state of shielding external light to the light receiving means via the strobe light guiding means in conjunction with an operation of the mirror member retracting from the photographing optical path. Or the camera of 6. The strobe light emitting means is a pop-up type,
The external light shielding means is in a state of shielding external light to the light receiving means via the strobe light guiding means in conjunction with a pop-up operation of the strobe light emitting means. The listed camera. The camera according to claim 5 or 6, wherein the external light blocking means is electrically switched between a state of blocking incident light and a state of not blocking light.

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