JP5857501B2 - Camera body and interchangeable lens barrel - Google Patents

Description

  The present invention relates to a camera body and an interchangeable lens barrel.

  Conventionally, in a flash device built in or attached to a digital camera, the flash device emits a small amount of light (so-called preliminary light emission) before photographing, and the amount of light reflected from a subject received through the photographing lens during the preliminary light emission. Based on the above, there is known a technique for determining a light emission amount to be emitted from a flash device during flash photography (see Patent Document 1).

JP 2006-317664 A

  If the information on the interchangeable lens side cannot be obtained when the camera body starts the shooting sequence, it may cause a release time lag. For example, since the preliminary light emission and the light emission amount determination as described above are performed after the photographing sequence is started, if it takes time to determine the light emission amount because the information on the interchangeable lens side cannot be obtained, It takes a long time to start flash photography after starting the sequence.

(1) The invention according to claim 1, first a communication contacts and second communication contacts, and a mounting portion Fit the interchangeable lens barrel, the interchangeable lens barrel mounted to the mounting portion Between the first communication unit that performs the first communication every first predetermined time via the first communication contact and the interchangeable lens barrel attached to the attachment unit via the second communication contact. A light emitting instruction unit for instructing light emission to a second communication unit that performs second communication every second predetermined time shorter than the first predetermined time , and a flash unit that performs first light emission and second light emission after the first light emission A photometric unit that measures reflected light during the first emission through the interchangeable lens barrel, an aperture value in the interchangeable lens barrel during the first emission, a light emission amount by the flash unit during the first emission, and a photometric measurement by the photometric unit Based on the calculation unit for calculating the first light emission amount based on the result and the aperture error information of the interchangeable lens barrel. A second light emission amount obtaining light emission amount correction unit that corrects the first amount of light emission have a flash controller for controlling the flash unit to perform a second light-emitting the second light emission amount, the diaphragm drive instruction to the interchangeable lens barrel It was transmitted over the first communication unit, a control unit for controlling the first communication unit and the second communication unit to receive the stop error information after driving the diaphragm from the interchangeable lens barrel via the second communication unit And a camera body.
(2) The invention according to claim 2 includes a first communication contact and a second communication contact, and an attachment portion for attaching the interchangeable lens barrel and an interchangeable lens barrel attached to the attachment portion. The first communication unit that performs the first communication every first predetermined time via the first communication contact and the interchangeable lens barrel attached to the attachment unit via the second communication contact. A second communication unit that performs the second communication every second predetermined time shorter than the predetermined time, a light emission instruction unit that instructs the flash unit to perform the first light emission and the second light emission after the first light emission, The photometry unit that measures the reflected light during the first emission through the interchangeable lens barrel, the aperture value in the interchangeable lens barrel during the first emission, the amount of light emitted by the flash unit during the first emission, and the photometry result by the photometry unit Based on the calculation unit for calculating the first light emission amount based on the aperture error information of the interchangeable lens barrel. A light emission amount correction unit that obtains a second light emission amount obtained by correcting the first light emission amount, a flash control unit that controls the flash unit to perform the second light emission with the second light emission amount, and an aperture drive instruction for the interchangeable lens barrel A control unit that controls the first communication unit and the second communication unit so as to receive the aperture error information after driving the aperture from the interchangeable lens barrel via the second communication unit. Are interchangeable lens barrels that can be attached to a camera body.

  According to the present invention, information on the interchangeable lens side can be quickly transmitted to the camera body in a state where the camera body has started the shooting sequence.

1 is a perspective view illustrating an interchangeable lens camera system according to an embodiment of the invention. It is sectional drawing explaining a camera system. It is a schematic diagram which shows the detail of the contact group in a lens mount. It is a timing chart which shows the example of command data communication. It is a timing chart which shows the example of hotline communication. It is a flowchart which illustrates the flow of the process which a body side control part performs at the time of flash imaging operation. (a) It is a figure which illustrates a to-be-photographed object. (b) It is a figure which illustrates the output of an evaluation value. (a) It is a figure which illustrates the relationship between the correction value of light emission amount, and the reflectance of a to-be-photographed object. (b) It is a figure which illustrates the relationship between the correction value of light emission amount, the reflectance of a to-be-photographed object, and an aperture variation error.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a perspective view illustrating an interchangeable lens camera system according to an embodiment of the invention. FIG. 1 shows only devices and apparatuses according to the present invention, and illustration and description of other devices and apparatuses are omitted. The camera system 1 includes a camera body 100, an interchangeable lens 200 that can be attached to and detached from the camera body 100, and a flash device 300 that can be attached to and detached from the camera body 100.

  A body side lens mount 101 for detachably attaching the interchangeable lens 200 is provided on the front surface of the camera body 100. On the upper surface of the camera body 100, an accessory mounting portion 105 for detachably mounting the flash device 300 is provided.

  The interchangeable lens 200 is provided with a lens side lens mount 201 that fits with the body side lens mount 101. When the interchangeable lens 200 is attached to the camera body 100, a contact group 102 (described later in detail) composed of a plurality of contacts provided on the body side lens mount 101 is provided on the lens side lens mount 201 of the interchangeable lens 200. It is connected to a contact group 202 (detailed later) consisting of a plurality of contact points. The contact groups 102 and 202 are used for power supply from the camera body 100 to the interchangeable lens 200 and transmission / reception of signals between the camera body 100 and the interchangeable lens 200.

  The flash device 300 is provided with an attachment portion that fits into the accessory attachment portion 105 of the camera body 100. When the flash device 300 is attached to the camera body 100, predetermined communication is performed between the camera body 100 and the flash device 300 via a contact (not shown) provided in the accessory mounting portion 105. The contents of communication include information for instructing light emission, information indicating the light emission amount, and information notifying the light emission preparation state.

  An imaging element 104 is provided behind the body side lens mount 101 in the camera body 100. Above the camera body 100, a release button 107 as an input device is provided. The user uses the input device such as the release button 107 to give a shooting instruction to the camera body 100, a shooting condition setting instruction, and the like.

<Interchangeable lens>
FIG. 2 is a sectional view for explaining the camera system 1. The interchangeable lens 200 includes an imaging optical system 210 that forms a subject image, and an iris diaphragm (hereinafter referred to as a diaphragm) 220 that limits a light beam. The imaging optical system 210 includes a plurality of lenses 210a to 210c. The focusing lens 210b is a lens for adjusting the focus position of the subject image. The zoom lens 210c is a lens for adjusting zooming.

  Inside the interchangeable lens 200, a lens-side control unit 203 that controls each part of the interchangeable lens 200 is provided. The lens side control unit 203 includes a microcomputer (not shown) and its peripheral circuits. The lens side control unit 203 includes a lens side first communication unit 217, a lens side second communication unit 218, a focusing lens driving unit 212, a focusing lens position detecting unit 213, a zoom lens position detecting unit 219, an aperture driving unit 211, an aperture. A position detection unit 214, a ROM 215, and a RAM 216 are connected.

  The lens-side first communication unit 217 and the lens-side second communication unit 218 perform data communication with the camera body 100 by exchanging signals with the camera body 100 via the contact group 202. The focusing lens driving unit 212 includes an actuator such as a stepping motor, for example, and drives the focusing lens 210b in accordance with a signal input to the focusing lens driving unit 212. The focusing lens position detection unit 213 detects the position of the focusing lens 210b, for example, by counting the number of pulses of a signal input to the stepping motor included in the focusing lens driving unit 212. Alternatively, the position of the focusing lens 210b may be detected using a known distance encoder or the like provided in the interchangeable lens 200. The zoom lens position detection unit 219 detects the position of the zoom lens 210c using an encoder provided in the interchangeable lens 200, for example.

  The aperture driving unit 211 drives the aperture 220 in accordance with the signal input to the aperture driving unit 211 and changes its aperture. The aperture position detector 214 detects the state of the aperture 220 (drive direction (opening direction or closing direction) and set aperture value). The ROM 215 is a non-volatile storage medium, and stores a predetermined control program executed by the lens side control unit 203 in advance. The RAM 216 is a volatile storage medium and is used as a storage area for various data by the lens-side control unit 203.

<Camera body>
An optical filter 116 that combines an optical low-pass filter and an infrared cut filter is provided on the front surface of the image sensor 104. Subject light from the imaging optical system 210 enters the image sensor 104 through the filter 116. Inside the camera body 100, a body-side control unit 103 that controls each part of the camera body 100 is provided. The body side control unit 103 includes a microcomputer (not shown), a RAM, and peripheral circuits thereof. The body side first control unit 117, the body side second communication unit 118, and the lens attachment / detachment detection unit 119 are connected to the body side control unit 103.

  The body-side first communication unit 117 performs data communication with the lens-side first communication unit 217 by exchanging signals with the lens-side first communication unit 217 in the interchangeable lens 200 via the contact group 102. Do. Similarly, the body-side second communication unit 118 exchanges signals with the lens-side second communication unit 218 in the interchangeable lens 200 via the contact group 102, thereby communicating with the lens-side second communication unit 218. Perform data communication. The lens attachment / detachment detection unit 119 detects attachment / detachment of the interchangeable lens 200 based on a signal level of a specific contact described later in the contact group 102.

  A display device 111 configured by an LCD panel or the like is disposed on the back surface of the camera body 100. The body-side control unit 103 displays various menu screens for setting a subject image (so-called through image) based on the output of the image sensor 104, shooting conditions, and the like on the display device 111.

  The body-side control unit 103 further determines control information at the time of shooting such as exposure and imaging sensitivity based on the subject luminance based on the output of the image sensor 104. When the release button 107 (FIG. 1) is pressed, the subject luminous flux from the interchangeable lens 200 is guided to the image sensor 104. Then, a subject image is captured by the image sensor 104.

  Also, the body-side control unit 103 causes the flash device 300 to perform preliminary light emission prior to the main light emission that causes the flash device 300 to emit light at the time of shooting, and based on the amount of light reflected from the object field during the preliminary light emission, Determine the amount of light emitted. Preliminary light emission means that the flash device 300 emits light with a small amount of light before photographing in order to check the amount of reflected light of the object scene. The amount of reflected light is calculated based on the output of the image sensor 104.

<Flash device>
Inside the flash device 300, a flash device side control unit 303 and a light emitting unit 304 that control each part of the flash device 300 are provided. The flash device side control unit 303 includes a microcomputer (not shown) and its peripheral circuits. A light emitting unit 304 is connected to the flash device side control unit 303.

  The flash device side control unit 303 communicates with the camera body 100 by exchanging signals with the camera body 100 via the contact (not shown) of the accessory mounting unit 105 of the camera body 100 described above. I do. The light emitting unit 304 includes a charging circuit (not shown), a capacitor, and a discharge tube. The light emitting unit 304 charges a capacitor with electric power from a built-in battery (not shown) to store light emission energy, and discharges the light emission energy with a discharge tube to emit light.

<Description of contact group of lens mount>
FIG. 3 is a schematic diagram showing details of the contact groups 102 and 202 in the lens mounts 101 and 102. As shown in FIG. 3, the contact group 102 has 12 contacts BP1 to BP12. The contact group 202 has 12 contacts LP1 to LP12 corresponding to the 12 contacts. Hereinafter, BP1 to BP12 are referred to as body side contacts, and LP1 to LP12 are referred to as lens side contacts.

  The body side contacts BP1 and BP2 are connected to the first power supply circuit 120 in the camera body 100. The first power supply circuit 120 supplies the operating voltage of each part in the interchangeable lens 200 excluding the focusing lens driving part 212 to the body side contact BP1. That is, from the body side contact BP1 and the lens side contact LP1, the operating voltage of each part (including the lens side first communication part 217 and the lens side second communication part 218) in the interchangeable lens 200 excluding the focusing lens driving part 212 is set. Supplied. The body side contact BP2 is a ground terminal corresponding to the above operating voltage. That is, the body side contact BP2 and the lens side contact LP2 are ground terminals corresponding to the above operating voltage.

  In the following description, a signal line constituted by the body side contact BP1 and the lens side contact LP1 is referred to as a signal line V33. A signal line constituted by the body side contact BP2 and the lens side contact LP2 is referred to as a signal line GND.

  The body side contacts BP3, BP4, BP5, and BP6 are contacts for performing data communication called command data communication. These four body-side contacts are connected to the body-side first communication unit 117. The lens side contacts LP3, LP4, LP5, and LP6 connected to these four contacts are connected to the lens side first communication unit 217. The body-side first communication unit 117 and the lens-side first communication unit 217 perform data communication by exchanging signals through the four body-side contacts and the four lens-side contacts. The contents of data communication (command data communication) performed by the body-side first communication unit 117 and the lens-side first communication unit 217 will be described in detail later.

  When the signal level of the signal input from each contact is equal to or higher than a predetermined reference level (for example, 2.0 V), the body-side first communication unit 117 and the lens-side first communication unit 217 receive the truth of the input signal. It is determined that the value represents “true” (also referred to as 1, H, High, etc.). Further, when the signal level of the signal input from each contact is equal to or lower than a predetermined reference level (for example, 0.8 V) set separately from the reference level, the input signal has the truth value “false”. (Also referred to as 0, L, Low, etc.). The same applies to the body-side second communication unit 118 and the lens-side second communication unit 218.

  The body side contact BP6 is connected to the power source Vcc (for example, 5 V) via the pull-up resistor R1 in the camera body 100. That is, the body side contact point BP6 is pulled up. On the other hand, the lens side contact LP6 is grounded through the pull-down resistor R2 in the interchangeable lens 200. That is, the lens side contact LP6 is pulled down.

  The resistance values of the pull-up resistor R1 and the pull-down resistor R2 are such that when the camera body 100 is attached to the interchangeable lens 200 and data communication is not performed by the lens-side first communication unit 217, the signal level of the body-side contact BP6 is It is determined to be a signal level corresponding to the truth value L (for example, a signal level of 0.8 V or less). For example, R1 = 10 kΩ and R2 = 100Ω.

  When the interchangeable lens 200 is not attached to the body side lens mount 101, the signal level of the body side contact point BP6 becomes a signal level corresponding to the truth value H (for example, 2.0 V or more). This is because the body side contact point BP6 is pulled up.

  A lens attachment / detachment detector 119 is connected to the body side contact BP6. The lens attachment / detachment detection unit 119 detects attachment / detachment of the interchangeable lens 200 based on the signal level of the body side contact BP6. Detection of attachment / detachment by the lens attachment / detachment detection unit 119 will be described in detail later.

  In the following description, a signal line constituted by the body side contact BP3 and the lens side contact LP3 is referred to as a signal line CLK. Similarly, a signal line formed by the body side contact BP4 and the lens side contact LP4 is a signal line BDAT, a signal line formed by the body side contact BP5 and the lens side contact LP5 is a signal line LDAT, and the body side contact BP6 and A signal line constituted by the lens side contact LP6 is referred to as a signal line RDY.

  The body side contacts BP7, BP8, BP9, and BP10 are contacts for performing data communication called hot line communication. These four body-side contacts are connected to the body-side second communication unit 118. The lens side contacts LP7, LP8, LP9, and LP10 connected to these four contacts are connected to the lens side second communication unit 218. The body-side second communication unit 118 and the lens-side second communication unit 218 perform data communication by exchanging signals through the four body-side contacts and the four lens-side contacts. The contents of data communication (hotline communication) performed by the body-side second communication unit 118 and the lens-side second communication unit 218 will be described in detail later.

  In the following description, a signal line constituted by the body side contact BP7 and the lens side contact LP7 is referred to as a signal line HREQ. Similarly, the signal line formed by the body side contact BP8 and the lens side contact LP8 is the signal line HANS, the signal line formed by the body side contact BP9 and the lens side contact LP9 is the signal line HCLK, and the body side contact BP10 and A signal line constituted by the lens side contact LP10 is referred to as a signal line HDAT.

  The body side contacts BP11 and BP12 are connected to the second power supply circuit 121 in the camera body 100. The second power supply circuit 121 supplies the driving voltage of the focusing lens driving unit 212 to the body side contact BP12. That is, the driving voltage of the focusing lens driving unit 212 is supplied from the body side contact BP12 and the lens side contact LP12. The body side contact BP11 is a ground terminal corresponding to the drive voltage. That is, the voltage at the body side contact BP11 and the lens side contact LP11 is a ground voltage corresponding to the drive voltage.

  In the following description, the signal line constituted by the body side contact BP11 and the lens side contact LP11 is referred to as a signal line PGND. A signal line constituted by the body side contact BP12 and the lens side contact LP12 is referred to as a signal line BAT.

<Description of command data communication>
The first lens side communication unit 217 performs data communication with the first body side communication unit 117 via the lens side contacts LP3 to LP6, that is, the signal lines CLK, BDAT, LDAT, and RDY. This data communication is repeated every 16 milliseconds, for example. In this data communication, reception of control data from the body side first communication unit 117 and transmission of response data to the body side first communication unit 117 are performed in parallel. Hereinafter, details of communication performed between the lens-side first communication unit 217 and the body-side first communication unit 117 will be described. In the present embodiment, communication performed between the lens-side first communication unit 217 and the body-side first communication unit 117 is referred to as command data communication.

  FIG. 4 is a timing chart showing an example of command data communication. When the body-side first communication unit 117 and the lens-side first communication unit 217 are not performing data communication (before time T1 in FIG. 4), the signal level of the signal line RDY is the signal level corresponding to the truth value L. It has become.

  The body-side first communication unit 117 first checks the signal level of the signal line RDY at the start of command data communication (T1). The signal level of the signal line RDY indicates whether the lens-side first communication unit 217 can communicate. That is, the lens side first communication unit 217 transmits a signal indicating whether or not the lens side first communication unit 217 can perform data communication to the lens side contact LP6. This signal is neither a data signal nor a clock signal. If the lens-side first communication unit 217 is in a state where data communication cannot be performed, an H (High) level signal is output from the lens-side contact LP6. When the signal line RDY is at the H level, the body-side first communication unit 117 does not start communication until the signal line RDY is at the L level. Also, the next process during communication is not executed.

  If the signal line RDY is at L (Low) level, the first body-side communication unit 117 outputs the clock signal 401 from the body-side contact BP3. The body-side first communication unit 117 outputs a body-side command packet signal 402 that is the first half of the control data from the body-side contact BP4 in synchronization with the clock signal 401. When the clock signal 401 is output to the signal line CLK, the first lens-side communication unit 217 outputs the lens-side command packet signal 403 that is the first half of the response data from the lens-side contact LP5 in synchronization with the clock signal 401. To do.

  The lens side first communication unit 217 sets the signal level of the signal line RDY to the H level in response to the completion of transmission of the lens side command packet signal 403 (T2). The lens side control unit 203 starts a first control process 404 that is a process according to the content of the received body side command packet signal 402. For example, when the received body-side command packet signal 402 has a content requesting specific data, the lens-side control unit 203 executes a process for generating the data as the first control process 404.

  When the first control process 404 is completed, the lens side control unit 203 notifies the lens side first communication unit 217 of the completion of the first control process 404. In response to this notification, the lens side first communication unit 217 outputs an L level signal from the lens side contact LP6 (T3). The body-side first communication unit 117 outputs a clock signal 405 from the body-side contact BP3 according to the change in the signal level. The body-side first communication unit 117 outputs a body-side data packet signal 406 that is the latter half of the control data from the body-side contact BP4 in synchronization with the clock signal 405.

  When the clock signal 405 is output to the signal line CLK, the lens-side first communication unit 217 outputs the lens-side data packet signal 407 that is the latter half of the response data from the lens-side contact LP5 in synchronization with the clock signal 405. To do.

  In response to the completion of transmission of the lens-side data packet signal 407, the lens-side first communication unit 217 sets the signal level of the signal line RDY to the H level again (T4). The lens side control unit 203 starts a second control process 408 that is a process according to the contents of the received body side command packet signal 402 and body side data packet signal 406. For example, if the received body-side command packet signal 402 is an instruction to drive the focusing lens 210b and the received body-side data packet signal 406 is the driving amount of the focusing lens 210b, the lens-side control unit 203 performs the second control process. As 408, processing for driving the focusing lens 210b by the driving amount is executed.

  When the second control process 408 is completed, the lens side control unit 203 notifies the lens side first communication unit 217 of the completion of the second control process 408. In response to this notification, the first lens side communication unit 217 outputs an L level signal from the lens side contact LP6 (T5).

  The communication performed at the above-described time T1 to time T5 is one command data communication. As described above, in one command data communication, body-side command packet signal 402 and body-side data packet signal 406 are transmitted one by one by body-side control unit 103 and body-side first communication unit 117, respectively. In other words, the body side command packet signal 402 and the body side data packet signal 406 together constitute one control data although it is divided and transmitted for convenience of processing.

  Similarly, in one command data communication, the lens-side command packet signal 403 and the lens-side data packet signal 407 are transmitted one by one by the lens-side control unit 203 and the lens-side first communication unit 217, respectively. That is, the lens side command packet signal 403 and the lens side data packet signal 407 are combined to form one response data. As described above, the lens-side first communication unit 217 performs reception of control data from the body-side first communication unit 117 and transmission of response data to the body-side first communication unit 117 in parallel.

  As described above, the lens side first communication unit 217 and the body side first communication unit 117 output various signals to the four signal lines (CLK, BDAT, LDAT, RDY) used for command data communication. . As is apparent from FIG. 4, the signal having the smallest change in signal level among these signals is a signal output to the signal line RDY by the lens-side first communication unit 217. That is, in the command data communication with the camera body 100, the lens side first communication unit 217 causes the lens side contacts LP3 to LP3 to minimize the change in the signal level of the lens side contact LP6 among the four lens side contacts LP3 to LP6. Control LP6.

  As for the first control process 404 and the second control process 408 described above, a predetermined specified (limit / upper limit) time is required with respect to the time required for the control process so that the process of the entire camera is not delayed. Are provided in advance in the memory of the lens side control unit 203. In command data communication, control processing (work) performed on the lens side is usually completed in about several hundred microseconds to several milliseconds if the lens side is operating normally. For this reason, a time obtained by adding a certain margin time to the working time on the lens side in command data communication is set as the specified time. In the present embodiment, the specified time is tuned to an appropriate value within a range of several tens of milliseconds to several hundreds of milliseconds, for example. That is, the lens side control unit 203 performs control so that the periods T23 and T45 illustrated in FIG. 4 do not exceed the specified time. In other words, while the camera body 100 is attached to the lens-side lens mount 201, the lens-side first communication unit 217 corresponds to the truth value H for the signal level of the lens-side contact LP6 continuously for the specified time or more. The lens side contact LP6 is controlled so as not to reach the signal level.

  Instructions to be transmitted from the body side control unit 103 to the lens side control unit 203 by command data communication include a driving instruction for the diaphragm 220 and an optical characteristic of the interchangeable lens 200 in addition to the specific data request and the focusing lens 210b driving instruction described above. Instructions for requesting information on the file are included.

<Description of hotline communication>
The second lens side communication unit 218 transmits lens position data to the second body side communication unit 118 via the lens side contacts LP7 to LP10, that is, the signal lines HREQ, HANS, HCLK, and HDAT. Hereinafter, details of communication performed between the lens-side second communication unit 218 and the body-side second communication unit 118 will be described. In the present embodiment, communication performed between the lens-side second communication unit 218 and the body-side second communication unit 118 is referred to as hotline communication.

  FIG. 5 is a timing chart showing an example of hotline communication. The body side control unit 103 of the present embodiment is configured to start hot line communication every second predetermined cycle Tn (in this embodiment, for example, 1 millisecond). This period is shorter than the period for performing the command data communication described above. FIG. 5A is a diagram illustrating a state in which hotline communication is repeatedly performed at predetermined intervals Tn. FIG. 5B shows a state in which a certain communication period Tx is expanded in the hot line communication repeatedly executed. Hereinafter, the procedure of hotline communication will be described based on the timing chart of FIG.

  When the hot line communication is started (T6), the body side second communication unit 118 first outputs an L level signal from the body side contact point BP7. The second lens side communication unit 218 notifies the lens side control unit 203 that this signal has been input to the lens side contact LP7. In response to this notification, the lens-side control unit 203 starts executing a generation process 501 that generates predetermined data. The generation processing 501 is, for example, the lens-side control unit 203 causing the focusing lens position detection unit 213 to detect the current focus position of the focusing lens 210b, and lens position data (corresponding to distance information Dist described later) representing the detection result. It is a process to generate.

  When the lens-side control unit 203 completes the generation process 501, the lens-side second communication unit 218 outputs an L-level signal from the lens-side contact LP8 (T7). The body-side second communication unit 118 outputs a clock signal 502 from the body-side contact BP9 in response to the input of this signal to the body-side contact BP8. The lens side second communication unit 218 outputs a lens position data signal 503 representing lens position data from the lens side contact LP10 in synchronization with the clock signal 502.

  When the transmission of the lens position data signal 503 is completed, the second lens side communication unit 218 outputs an H level signal from the lens side contact LP8 (T8). The body-side second communication unit 118 outputs an H-level signal from the lens-side contact LP7 in response to the input of this signal to the body-side contact BP8 (T9).

  The communication performed from time T6 to time T9 described above is one hot line communication. As described above, one lens position data signal 503 is transmitted by the lens side control unit 203 and the lens side second communication unit 218 in one hot line communication.

  Of the four lens side contacts LP7 to LP10 used for hotline communication, a signal that is neither a clock signal nor a data signal is output to the lens side contacts LP7 and LP8. The change in the signal level of these two lens side contacts is greater than that of the lens side contact LP6 used for command data communication. This is because hot line communication is executed in a shorter cycle than command data communication.

  The information transmitted from the lens side control unit 203 to the body side control unit 103 by hotline communication indicates the current position of the zoom lens 210c in addition to the above-described data indicating the focus position (corresponding to distance information Dist described later). Data, aperture variation error information ΔFno described later, and the like are included.

  The command data communication and hotline communication described above can be executed simultaneously in parallel. That is, one of the lens side first communication unit 217 and the lens side second communication unit 218 can communicate with the camera body 100 even when the other is communicating with the camera body 100. is there.

<Flash shooting operation>
Since the present embodiment is characterized by flash photography (particularly, correction of the light emission amount of the flash device 300) performed by the camera system 1 described above, the following description will be focused on flash photography operation.

  FIG. 6 is a flowchart illustrating the flow of processing executed by the body side control unit 103 during the flash photographing operation. The body-side control unit 103 repeatedly executes the processing of FIG. 6 when a main switch (not shown) provided in the camera body 100 is turned on and power is supplied to each unit of the camera system 1. Note that when power is supplied, the camera body 100 and the interchangeable lens 200 perform the above-described command data communication every about 16 milliseconds, and perform the above-described hotline communication every about 1 millisecond. However, hotline communication is performed only when necessary.

  In step 201 in FIG. 6, the body-side control unit 103 starts through image display and proceeds to step S202. Specifically, a monitor subject image acquired at a predetermined frame rate (for example, 30 frames / second) by the image sensor 104 before a shooting instruction is sequentially displayed on the display device 111. Further, the body side control unit 103 repeatedly performs photometry calculation in accordance with the frame rate. In the photometric calculation, subject brightness is calculated based on the output of the image sensor 104. The subject luminance is used to determine control information at the time of shooting such as exposure and sensitivity of the image sensor 104.

  In step S202, the body side control unit 103 determines whether or not the release switch is turned on. The release switch is configured to be turned on in conjunction with the pressing operation of the release button 107 and turned off in conjunction with the release of pressing. Turning on the release switch corresponds to a shooting instruction. When the release switch is turned on, the body-side control unit 103 makes a positive determination in step S202 and proceeds to step S203. If the release switch is not turned on, the body-side control unit 103 makes a negative determination in step S202 and proceeds to step S211.

In step S203, the body side control unit 103 controls the diaphragm 220 to the control diaphragm PreAv at the time of preliminary light emission prior to the preliminary light emission of the flash device 300. The control aperture PreAv at the time of preliminary light emission is calculated by the following equation (1) using the sensitivity set in the image sensor 104 at the time of preliminary light emission. The unit system of the control aperture PreAv is APEX.
PreAv = AvSvConst-PreSv (1)
In the above equation (1), AvSvConst is a constant term for appropriately determining the aperture value. PreSv is the sensitivity of the image sensor 104 and takes, for example, a value of 5 (equivalent to ISO 100) in the APEX unit system. The body side control unit 103 sends an instruction to the interchangeable lens 200 to drive the aperture 220 to the aperture value corresponding to the control aperture PreAv, and proceeds to step 204. Transmission / reception instructing driving of the diaphragm 220 from the camera body 100 to the interchangeable lens 200 is performed by command line communication.

  In step S204, the body side control unit 103 acquires the aperture variation error information ΔFno and the distance information Dist from the interchangeable lens 200, and proceeds to step S205. The aperture variation error information ΔFno is a value indicating the variation amount of the setting error between the set aperture value (target value) generated in the aperture 220 and the actual aperture value. The lens side control unit 203 of the interchangeable lens 200 transmits the aperture variation error information ΔFno (PreAv) corresponding to the control aperture PreAv to the camera body 100.

  The setting error between the set aperture value and the actual aperture value is determined by the mechanical accuracy of the imaging optical system 210 and the aperture 220, the backlash amount of the aperture drive unit 211, and the like. The setting error also changes depending on the aperture after driving the diaphragm 220. Therefore, when the interchangeable lens 200 receives a drive instruction from the camera body 100 to the control aperture PreAv, an aperture variation error corresponding to the latest state of the aperture 220 (drive direction (open direction or closed direction) and set aperture value). Information ΔFno is transmitted to the camera body 100. In the present embodiment, data indicating the relationship between the state of the diaphragm 220 and the diaphragm variation error information ΔFno is recorded in the ROM 215 in advance. The lens side control unit 203 reads the aperture variation error information ΔFno corresponding to the drive instruction received in step S203 from the ROM 215 and transmits it to the camera body 100. The unit system of aperture variation error information ΔFno is APEX.

  The distance information Dist is determined by the focus position of the imaging optical system 210, and indicates the distance (shooting distance) from the camera to the focused subject position. In the present embodiment, data indicating the relationship between the focus position and the shooting distance is recorded in the ROM 215 in advance. The interchangeable lens 200 transmits distance information Dist corresponding to the focus position after focus adjustment to the camera body 100. The unit of the distance information Dist is meters [m]. Transmission / reception of aperture variation error information ΔFno and distance information Dist from the interchangeable lens 200 to the camera body 100 is performed by hotline communication.

  In step S <b> 205, the body side control unit 103 instructs the flash device 300 to perform preliminary light emission. When the body-side control unit 103 acquires a signal indicating light emission preparation completion (charging completion) from the flash device 300, the body-side control unit 103 transmits a preliminary light emission timing signal to the flash device 300, and proceeds to step S206. Thereby, the flash device 300 causes the light emitting unit 304 to emit light with a predetermined preliminary light emission amount. Information indicating the light emission amount at the time of preliminary light emission (guide number GnMon at the time of preliminary light emission to be described later) is transmitted from the flash device 300 to the body side control unit 103.

  In step S <b> 206, the body-side control unit 103 controls accumulation of the image sensor 104 so as to synchronize with the preliminary light emission, and acquires a received light amount (amount of reflected light) based on the output of the image sensor 104. When the body-side control unit 103 acquires the amount of reflected light, the process proceeds to step S207. In the present embodiment, the evaluation value of 20 × 10 blocks is calculated based on the amount of light received by the image sensor 104. When a subject as shown in FIG. 7A is photographed, the output of the evaluation value is as shown in FIG. In this embodiment, each evaluation value is proportional to the amount of received light, and takes a value from 0 to 1023 as a value after A / D conversion (in the case of 10 bits). The output at the coordinates (i, j) of the evaluation value is expressed as Voy [i] [j].

In step S207, the body-side control unit 103 calculates the temporary light emission amount of the main light emission at the time of photographing with the flash device 300 based on the calculated evaluation value. The logarithm value HonGv of the guide number of the provisional light emission amount is calculated by the following equation (2).
HonGv = GvMon−Log2 ((ΣΣ (Voy [i] [j])) / (20 × 10))
+ GnConst-PreAv + HonAv (2)
In the above equation (2), GvMon is a light emission amount guide number of the flash device 300 at the time of preliminary light emission. The light emission amount guide number GvMon is calculated by the following equation (3).
GvMon = Log√2 (GnMon)… (3)
In the above equation (3), GnMon is a light emission amount guide number at the time of preliminary light emission. Log√2 () is a function that returns a logarithmic value of an argument with √2 as the base.

  In the above equation (2), Log2 () is a function that returns a logarithmic value of an argument with 2 as a base. The range of addition of two Σ is 0 to 19 for i and 0 to 9 for j. GnConst is a constant term for optimizing the light emission amount. HonAv is a control aperture at the time of shooting, and the unit system is APEX.

In step S208, the body side control unit 103 corrects the provisional light emission amount calculated in step S207. The provisional emission amount correction value DeltaY is a variable for correcting the provisional emission amount calculated from the reflectance RefEv of the subject, and the unit system is APEX. The reflectance RefEv of the subject is calculated by the following equation (4).
RefEv = 2 × log2 (Dist) + PreAv
+ Log2 ((ΣΣ (Voy [i] [j])) / (20 × 10)) + RefEvConst (4)
In the above equation (4), RefEvConst is a fixed value for calculating the reflectance RefEv of the subject. The reflectance RefEv is expressed by a relative value from a reference reflectance (for example, 18%), and the unit system is APEX. The reflectance RefEv takes both positive and negative values depending on whether it is higher or lower than the reference reflectance. Based on the reflectance RefEv of the subject, a provisional emission amount correction value DeltaY is calculated by the following equation (5).
DeltaY = KDltY x RefEv (5)
KdltY is a fixed value for obtaining a correction amount. The relationship between the provisional emission amount correction value DeltaY and the reflectance RefEv of the subject is as shown in FIG. The provisional light emission correction value DeltaY is calculated based on the distance information Dist (the distance between the camera and the subject) and the amount of light received during preliminary light emission. According to FIG. 8A, a larger correction value is added to the provisional light emission amount as the subject reflectance RefEv is larger, and a larger correction value is subtracted from the provisional light emission amount as the subject reflectance RefEv is smaller. That is, the correction value DeltaY is a correction amount necessary for photographing a white object white and a black object black.

Here, PreAv in the second term of the above equation (4) is a control aperture at the time of preliminary light emission. As described above, a setting error occurs between the aperture value actually controlled in the interchangeable lens 200. Accordingly, the range of the actual aperture value RealPreAv at the time of preliminary light emission is estimated as follows using the aperture variation error information ΔFno acquired from the interchangeable lens 200 in step S204.
RealPreAv = (PreAv + ΔFno) to (PreAv−ΔFno) (6)

  According to the above equation (6), due to the influence of the setting error of the diaphragm 220 at the time of preliminary light emission, an error of ΔFno is expected at the maximum in the reflectance RefEv of the subject calculated by the above equation (4). For this reason, in this embodiment, when the information of the aperture variation error ΔFno can be acquired from the interchangeable lens 200, the provisional light emission amount using the following formula (7) to the following formula (9) instead of the above formula (5). Calculate the correction value DeltaY. In this case, the relationship between the provisional emission amount correction value DeltaY, the object reflectance RefEv, and the aperture variation error ΔFno is shown in FIG.

(B) When the reflectance RefEv of the subject is larger than the aperture variation error ΔFno
DeltaY = KDltY x (RefEv-ΔFno) (7)
(B) When the reflectance RefEv of the subject is smaller than the aperture variation error ΔFno
DeltaY = KDltY x (RefEv + ΔFno) (8)
(C) In cases other than (b) and (b) above
DeltaY = 0 (9)
By calculating the provisional light emission amount correction value DeltaY using the above equation (7) to the above equation (9), it is possible to avoid unintentional overcorrection due to the control variation of the aperture 220. In FIG. 8B, only when the absolute value of the difference between the reflectance RefEv of the subject and the reference reflectance exceeds a size corresponding to the aperture variation error ΔFno, the provisional light emission amount at the time of photographing is corrected. That is, the correction amount DeltaY with respect to the provisional light emission amount is suppressed as compared with the case of FIG.

The body-side control unit 103 uses the logarithm value HonGv of the light emission amount guide number calculated by the above equation (2) and the correction value DeltaY to calculate the light emission amount guide number HonGn at the time of shooting using the following equation (10). Proceed to step S209.
HonGn = Power√2 (HonGv + DeltaY) (10)
In the above equation (10), Power√2 () is a function that returns the argument power of √2.

  In step S209, the body side control unit 103 sends an instruction to the interchangeable lens 200 to drive the aperture 220 to an aperture value corresponding to the control aperture HonAv at the time of shooting, and proceeds to step 210. Transmission / reception instructing driving of the diaphragm 220 from the camera body 100 to the interchangeable lens 200 is performed by command line communication. The control aperture HonAv at the time of shooting is determined based on the photometric calculation started in step S201.

  In step S210, the body side control unit 103 starts accumulation control of the image sensor 104, sends an instruction to the flash device 300, and calculates by the above equation (10) so as to be synchronized with accumulation (imaging) of the image sensor 104. Use the flash emission guide number HonGn when shooting. The body-side control unit 103 ends the accumulation of the image sensor 104 after a predetermined time has elapsed. The body side control unit 103 performs predetermined processing based on the output of the image sensor 104, records the processed image data file in a storage medium (not shown), and proceeds to step S211.

  In step S211, the body-side control unit 103 determines whether or not a power-off operation has been performed. When the main switch (not shown) is turned off, the body-side control unit 103 makes an affirmative determination in step S211, performs a predetermined power-off process, and ends the process of FIG. If the main switch (not shown) is not turned off, the body-side control unit 103 makes a negative determination in step S211 and returns to step S201. When returning to step S201, the above-described processing is repeatedly executed.

According to the embodiment described above, the following operational effects can be obtained.
(1) The camera body 100 has body side contacts BP3, BP4, BP5, and BP6 and body side contacts BP7, BP8, BP9, and BP10, and a body side lens mount 101 to which the interchangeable lens barrel 200 is detachably attached. Body-side first communication that performs command data communication between each of them and the interchangeable lens barrel 200 mounted on the body-side lens mount 101 via the body-side contacts BP3, BP4, BP5, and BP6. Between the unit 117 and the interchangeable lens barrel 200 attached to the body side lens mount 101 via the body side contacts BP7, BP8, BP9, and BP10 every second predetermined time shorter than the first predetermined time. From the body side second communication unit 118 that performs communication to the start of shooting after receiving a shooting instruction An instruction to drive the optical system to the interchangeable lens barrel 200 is transmitted via the body side first communication unit 117, and information from the interchangeable lens barrel 200 is received via the body side second communication unit 118. Since the first communication unit 117 and the body side control unit 103 that controls the body side second communication unit 118 are provided, information on the interchangeable lens 200 side is quickly transmitted to the camera body 100 in a state where the imaging sequence is started. it can.

(2) In the camera body 100 of the above (1), the information from the interchangeable lens barrel 200 is information used for calculation for shooting, and therefore the interchangeable lens used for calculation for shooting in the state where the shooting sequence is started. It is possible to suppress the occurrence of a release time lag due to the fact that information on the 200 side cannot be obtained.

(3) In the camera body 100 of (2) above, through the body side control unit 103 that instructs the flash device 300 that performs preliminary light emission before flash photography and main light emission at flash photography, and the interchangeable lens barrel 200. Body side control unit 103 that measures reflected light during preliminary light emission, aperture value PreAv in interchangeable lens barrel 200 during preliminary light emission, guide number GnMon of flash device 300 during preliminary light emission, and photometry by body side control unit 103 The body side control unit 103 that calculates the provisional emission amount HonGv based on the result, and the body side control that obtains the emission amount (HonGv + DeltaY) obtained by correcting the provisional emission amount HonGv based on the aperture variation error ΔFno of the interchangeable lens barrel 200. Unit 103 and a body side control unit 103 that controls the flash device 300 so as to perform the main light emission with the light emission amount (HonGv + DeltaY). The unit 103 transmits an aperture driving instruction to the interchangeable lens barrel 200 via the body-side first communication unit 117, and transmits the aperture variation error ΔFno after the aperture driving from the interchangeable lens barrel 200 to the body-side second communication unit 118. The body-side first communication unit 117 and the body-side second communication unit 118 are controlled so as to be received via the network. Accordingly, it is possible to prevent overcorrection due to an aperture setting error when determining the light emission amount during flash photographing based on the reflected light amount during preliminary light emission while suppressing the release time lag after the start of the photographing sequence.

(4) The interchangeable lens barrel 200 has lens side contacts LP3 to LP6 and lens side contacts LP7 to LP10, and a lens side lens mount 201 for detachably attaching to the camera body 100, and a lens side lens mount. A lens-side first communication unit 217 that performs command data communication with the camera body 100 attached at 201 via the lens-side contacts LP3 to LP6 for each first predetermined time, and a lens-side lens mount 201. A lens-side second communication unit 218 that performs hotline communication with the camera body 100 via the lens-side contacts LP7 to LP10 every second predetermined time shorter than the first predetermined time, and an optical system from the camera body 100 The drive instruction is received via the lens side first communication unit 217, and the optical system information is received via the lens side second communication unit 218. The lens-side first communication unit 217 and the lens-side control unit 203 that controls the lens-side second communication unit 218 so as to transmit the information to the camera body 100. It can be transmitted to the body 100.

(5) The interchangeable lens barrel 200 of (4) further includes an aperture drive unit 211 that changes the aperture value, and the drive instruction of the optical system is an aperture value change command. Can receive.

(6) The interchangeable lens barrel 200 of (5) further includes a ROM 215 that stores information indicating a relationship between a target aperture value and an actual aperture value, and the lens-side control unit 203 has a changed aperture. The lens-side second communication unit 218 is controlled so that the aperture variation error ΔFno information corresponding to the value is read from the ROM 215 and transmitted. Since different aperture variation error ΔFno information for each interchangeable lens barrel 200 is stored in the interchangeable lens barrel 200 side, all aperture variation error ΔFno information of the interchangeable lens barrel scheduled to be mounted on the camera body 100 side is stored. You do not have to leave it. In particular, it is preferable when there are many types of interchangeable lens barrels 200 to be combined.

(Modification 1)
In the above description, when the interchangeable lens 200 receives a drive instruction from the camera body 100 to the control aperture PreAv (S203), the aperture variation error information ΔFno corresponding to the latest state of the aperture 220 is transmitted to the camera body 100 (S204). ) Explained the example. When the aperture variation error information ΔFno differs depending on the position of the zoom lens 210c or the position of the focusing lens 210b, the aperture variation error information ΔFno corresponding to the latest position of the zoom lens 210c or the position of the focusing lens 210b is obtained from the camera body 100. To send to.

  In the case of the first modification, data indicating the relationship between the position of the zoom lens 210c or the position of the focusing lens 210b and the aperture variation error information ΔFno is recorded in the ROM 215 in advance. The lens side control unit 203 of the interchangeable lens 200 reads out the aperture variation error information ΔFno corresponding to each lens position detected by the focusing lens position detection unit 213 and the zoom lens position detection unit 219 from the ROM 215 and transmits it to the camera body 100. To do.

(Modification 2)
In general, the setting error between the set aperture value and the actual aperture value includes a reproducible error (offset component) that is reproduced every time the aperture 220 is driven (setting change), and the aperture 220 is driven (set). There is a non-reproducible error (variation component) every time the change is made. In the above description, an example has been described in which setting errors are handled without distinguishing between reproducible errors and non-reproducible errors.

  Instead of this, a setting error of the diaphragm 220 may be divided into a reproducible error and a non-reproducible error. In this case, the aperture variation error information ΔFno may include both a reproducible error and a non-reproducible error, or may include, for example, only one of the dominant setting errors. Absent.

(Modification 3)
Although an example of the external type attached to the camera body 100 as the flash device 300 has been described, the flash device may be built in the camera body 100.

  The above description is merely an example, and is not limited to the configuration of the above embodiment.

DESCRIPTION OF SYMBOLS 1 ... Camera system 100 ... Camera body 101 ... Body side lens mount 102, 202 ... Contact group 103 ... Body side control part 105 ... Accessory attachment part 117 ... Body side 1st communication part 118 ... Body side 2nd communication part 200 ... Exchange Lens 201 lens side lens mount 203 lens side control unit 210 imaging optical system 210b focusing lens 210c zoom lens 211 aperture drive unit 213 focusing lens position detection unit 214 aperture position detection unit 215 ROM
217 ... Lens side first communication unit 218 ... Lens side second communication unit 219 ... Zoom lens position detection unit 220 ... Aperture 300 ... Flash device 303 ... Flash device side control unit 304 ... Light emitting unit

Claims (4)

A mounting portion which first has a communication contacts and second communication contacts, Fit the interchangeable lens barrel,
A first communication unit that performs first communication with the interchangeable lens barrel attached to the attachment unit via the first communication contact at a first predetermined time;
A second communication unit that performs second communication with the interchangeable lens barrel mounted on the mounting unit via a second communication contact at a second predetermined time shorter than the first predetermined time;
A light emission instruction unit for instructing light emission to a flash unit that performs the first light emission and the second light emission after the first light emission;
A photometric unit that measures the reflected light during the first emission through the interchangeable lens barrel;
A calculation unit that calculates a first light emission amount based on an aperture value in the interchangeable lens barrel at the time of the first light emission, a light emission amount by the flash unit at the time of the first light emission, and a photometric result by the photometry unit;
A light emission amount correction unit that obtains a second light emission amount obtained by correcting the first light emission amount based on aperture error information of the interchangeable lens barrel;
A flash control unit that controls the flash unit to perform the second light emission at the second light emission amount;
The diaphragm drive instruction for the previous SL interchangeable lens barrel and transmitted via the first communication unit, the said stop error information after driving the diaphragm from the interchangeable lens barrel to receive via the second communication unit A control unit for controlling the first communication unit and the second communication unit ;
The equipped Luke Merabodi. A first communication contact and a second communication contact, and an attachment portion for attaching the interchangeable lens barrel and the interchangeable lens barrel attached to the attachment portion via the first communication contact It is shorter than the first predetermined time through the second communication contact point between the first communication unit that performs the first communication every first predetermined time and the interchangeable lens barrel attached to the attachment unit. A second communication unit that performs second communication every second predetermined time; a light emission instruction unit that instructs light emission to a flash unit that performs first light emission and second light emission after the first light emission; and the interchangeable lens A photometric unit for measuring reflected light at the time of the first light emission through the lens barrel; an aperture value in the interchangeable lens barrel at the time of the first light emission; an amount of light emitted by the flash unit at the time of the first light emission; and the photometric unit A calculation unit for calculating the first light emission amount based on the photometric result of A light emission amount correction unit for obtaining a second light emission amount obtained by correcting the first light emission amount based on aperture error information of the interchangeable lens barrel; and the flash unit for performing the second light emission with the second light emission amount. A flash control unit to be controlled and an aperture drive instruction for the interchangeable lens barrel are transmitted via the first communication unit, and the aperture error information after the aperture is driven from the interchangeable lens barrel via the second communication unit. And a control unit that controls the first communication unit and the second communication unit so as to receive the interchangeable lens barrel. Every 1st predetermined time shorter than the 1st predetermined time between the 1st communication part which performs 1st communication for every 1st predetermined time between the interchangeable lens barrel with which it was equipped, and the exchangeable lens barrel A second communication unit that performs second communication, a light emission instruction unit that instructs the flash unit that performs first light emission and second light emission after the first light emission, and reflected light at the time of the first light emission A first light emission amount based on a photometry unit that measures the aperture value in the interchangeable lens barrel during the first light emission, a light emission amount by the flash unit during the first light emission, and a photometric result by the photometry unit A calculation unit for calculating, a light emission amount correcting unit for obtaining a second light emission amount obtained by correcting the first light emission amount based on aperture error information of the interchangeable lens barrel, and performing the second light emission with the second light emission amount And a flash control unit for controlling the flash unit as described above. A lens barrel,
An attachment portion having a first communication contact and a second communication contact, and attached to the camera body;
A third communication unit that performs first communication with the camera body mounted on the mounting unit via the first communication contact;
A fourth communication unit for performing second communication with the camera body mounted on the mounting unit via the second communication contact;
The third communication unit and the third communication unit so as to receive an aperture drive instruction from the camera body via the third communication unit and transmit aperture error information after the aperture drive to the camera body via the fourth communication unit. A control unit for controlling the fourth communication unit;
An interchangeable lens barrel. A communication unit that communicates with a mounted interchangeable lens barrel; a light emission instruction unit that instructs the flash unit to perform first light emission and second light emission after the first light emission; and the first Based on a photometric unit that measures reflected light at the time of light emission, an aperture value in the interchangeable lens barrel at the time of the first light emission, an amount of light emitted by the flash unit at the time of the first light emission, and a photometric result by the photometric unit A calculation unit that calculates a first light emission amount; a light emission amount correction unit that obtains a second light emission amount obtained by correcting the first light emission amount based on aperture error information of the interchangeable lens barrel; and An interchangeable lens barrel that can be attached to a camera body, and a flash control unit that controls the flash unit to perform second light emission,
An attachment portion having a first communication contact and a second communication contact, and attached to the camera body;
A first communication unit that performs a first communication with the camera body mounted on the mounting unit via the first communication contact for each first predetermined time;
A second communication unit that performs second communication with the camera body mounted by the mounting unit via the second communication contact for each second predetermined time shorter than the first predetermined time;
The first communication unit and the aperture drive instruction from the camera body are received via the first communication unit, and the aperture error information after the aperture drive is transmitted to the camera body via the second communication unit. A control unit for controlling the second communication unit;
An interchangeable lens barrel.

Images