JP5966276B2 - interchangeable lens - Google Patents

Description

The present invention also relates to the replacement lens.

  Digital cameras that can shoot movies are known. Generally, such a digital camera can record audio together with video and store it in a storage medium. For example, Patent Document 1 describes a digital camera that includes a camera body and an interchangeable lens and can shoot a moving image. This interchangeable lens has a driving speed that can drive the diaphragm at a driving sound level that is the same as or lower than the driving sound level of the smaller driving sound generated when the diaphragm is driven at the maximum speed and the minimum speed. Is transmitted to the camera body as a silent speed. This makes it possible to drive the aperture so that the drive sound of the aperture is not recorded when recording is performed, such as during moving image shooting.

JP 2009-288778 A

The subject of this embodiment is providing the interchangeable lens which can control a focusing lens suitably, and the camera body which can be mounted | worn with an interchangeable lens .

According to the first aspect of the present invention, there is provided a first command to drive the focusing lens at a predetermined image plane moving speed from an attachment portion to which the camera body can be attached, an imaging optical system having a focusing lens, and a camera body. A receiving unit for receiving a driving signal, a second driving signal for instructing to drive the focusing lens at a predetermined driving speed, a silent mode command signal, a driving unit for driving the focusing lens, and a first driving signal; Accordingly, a control unit that controls the drive unit so that the imaging plane of the imaging optical system moves at a predetermined image plane moving speed and a predetermined image plane when a silent mode command signal is received by the receiving unit. An upper limit determination unit that determines whether at least one of a focusing lens driving speed and a predetermined driving speed required to achieve the moving speed exceeds a predetermined upper limit speed. And the control unit determines that at least one of the driving speed of the focusing lens and the predetermined driving speed necessary to achieve the predetermined image plane moving speed exceeds the predetermined upper limit speed by the upper limit determination unit. In the case where the focusing lens is driven at a first driving speed equal to or lower than a predetermined upper limit speed, the receiving unit controls the camera body to perform a search operation in contrast type focus detection, or When the scanning operation in pupil division phase difference focus detection is performed, the first drive signal is received from the camera body, and when the camera body performs focusing drive based on the focus detection result, the second from the camera body. It is an interchangeable lens that receives a drive signal .

According to the present embodiment, it is possible to provide an interchangeable lens that can suitably control a focusing lens and a camera body that can be attached to the interchangeable lens .

It is the perspective view which showed the lens-interchangeable camera system to which this invention is applied. It is sectional drawing which showed the lens-interchangeable camera system to which this invention is applied. It is a schematic diagram which shows the detail of the holding | maintenance part 102,202. 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 figure which shows the correspondence of a lens position and a lens drive speed required when making an image surface moving speed constant in the said lens position. It is a figure which shows the correspondence of a lens position and a lens drive speed required when making an image surface moving speed constant in the said lens position. It is a figure which shows the correspondence of a lens position and a lens drive speed required when making an image surface moving speed constant in the said lens position.

(First embodiment)
FIG. 1 is a perspective view showing an interchangeable lens type camera system to which the present invention is applied. 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 1 includes a camera body 100 and a lens barrel 200 that can be attached to and detached from the camera body 100.

  The camera body 100 is provided with a body side mount portion 101 to which the lens barrel 200 is detachably attached. At a position near the body-side mount portion 101 (inner peripheral side of the body-side mount portion 101), a holding portion (electrically holding the contact point in a state of partially protruding toward the inner peripheral side of the body-side mount portion 101) ) 102 is provided. The holding portion 102 is provided with a plurality of contacts.

  Further, the lens barrel 200 is provided with a lens side mount portion 201 corresponding to the body side mount portion 101 to which the camera body 100 is detachably attached. In the vicinity of the lens side mount part 201 (inner peripheral side of the lens side mount part 201), a holding part (electrical) that holds the contact in a state of partially protruding to the inner peripheral side of the lens side mount part 201 ) 202 is provided. The holding portion 202 is provided with a plurality of contacts.

  When the lens barrel 200 is attached to the camera body 100, the holding portion 102 on the camera body 100 side provided with a plurality of contacts is electrically connected to the holding portion 202 on the lens barrel 200 side provided with a plurality of contacts. And physically connected. Both holders 102 and 202 are used for power supply from the camera body 100 to the lens barrel 200 and transmission / reception of signals between the camera body 100 and the lens barrel 200.

  An imaging element 104 such as a CMOS or a CCD is provided behind the body side mount 101 in the camera body 100. Above the camera body 100, a button 105 serving as an input device is provided. The user uses the input device such as the button 105 to instruct the camera body 100 to take a picture, set shooting conditions, and the like.

  FIG. 2 is a cross-sectional view showing an interchangeable lens type camera system to which the present invention is applied. The lens barrel 200 includes an imaging optical system 210 that forms a subject image. The imaging optical system 210 includes a plurality of lenses 210 a to 210 c and a diaphragm 211. The plurality of lenses 210a to 210c includes a focusing lens 210b for controlling the focus position of the subject image.

  Inside the lens barrel 200, a lens control unit 203 that controls each part of the lens barrel 200 is provided. The lens control unit 203 includes a microcomputer (not shown) and its peripheral circuits. The lens control unit 203 is connected to a lens side first communication unit 217, a lens side second communication unit 218, a lens driving unit 212, a lens speed detection unit 214, a ROM 215, and a RAM 216.

  The lens-side first communication unit 217 and the lens-side second communication unit 218 transmit and receive signals to and from the camera body 100 via the communication contacts of the holding units 102 and 202. Each of the lens side first communication unit 217 and the lens side second communication unit 218 is a communication interface on the lens barrel 200 side. The lens control unit 203 performs communication (hotline communication, command data communication) described later with the camera body 100 (body control unit 103 described later) using these communication interfaces.

  The lens driving unit 212 includes a motor (for example, an actuator such as a stepping motor) that generates a driving force and a transmission system (for example, a combination of a plurality of gears) that transmits the driving force to the focusing lens 210b. The lens driving unit 212 is controlled by the lens control unit 203, and drives the focusing lens 210b in the optical axis direction at a driving speed designated by the lens control unit 203.

  The lens speed detection unit 214 is a sensor that detects the driving speed of the focusing lens 210b. The ROM 215 is a nonvolatile storage medium, and stores in advance a predetermined control program executed by the lens control unit 203, a maximum driving speed and a minimum driving speed of a focusing lens 210b described later, and the like. The RAM 216 is a volatile storage medium and is used as a temporary storage area for various data by the lens control unit 203.

  A shutter 115 for controlling the exposure state of the image sensor 104 and an optical filter 116 combining an optical low-pass filter and an infrared cut filter are provided on the front surface of the image sensor 104. The subject light that has passed through the imaging optical system 210 enters the image sensor 104 via the shutter 115 and the filter 116.

  Inside the camera body 100, a body control unit 103 that controls each part of the camera body 100 is provided. The body control unit 103 includes a microcomputer (not shown), a RAM, and peripheral circuits thereof.

  A body-side first communication unit 117 and a body-side second communication unit 118 are connected to the body control unit 103. The body-side first communication unit 117 is connected to the holding unit 102, and can transmit and receive signals to and from the lens-side first communication unit 217 through a plurality of contacts provided on the holding unit 102. Similarly, the body side second communication unit 118 can transmit and receive signals to and from the lens side second communication unit 218. In other words, each of the body-side first communication unit 117 and the body-side second communication unit 118 is a body-side communication interface. The body control unit 103 performs communication (hotline communication and command data communication) to be described later with the lens barrel 200 (lens control unit 203) using these communication interfaces.

  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 control unit 103 displays various menu screens for setting an image of a subject (a so-called through image) based on the output of the image sensor 104, shooting conditions, and the like on the display device 111.

  The camera body 100 has two types of shooting modes, a still image shooting mode for shooting a still image and a moving image shooting mode for shooting a moving image. When the user instructs the camera body 100 to set these shooting modes, the body control unit 103 starts an operation in the shooting mode. The camera body 100 includes a microphone (not shown), and audio input to the microphone is stored in a storage medium (not shown) together with a video during moving image shooting.

(Description of holding units 102 and 202)
FIG. 3 is a schematic diagram showing details of the holding units 102 and 202. In FIG. 3, the holding portion 102 is arranged on the right side of the body-side mount portion 101 in accordance with an actual mount structure. That is, the holding portion 102 according to the present embodiment is disposed at a location deeper than the mount surface of the body-side mount portion 101 (a location on the right side of the body-side mount portion 101 in FIG. 3). Similarly, the holding unit 202 is arranged on the right side of the lens side mount unit 201 because the holding unit 202 of the present embodiment is arranged at a position protruding from the mount surface of the lens side mount unit 201. Represents. Since the holding unit 102 and the holding unit 202 are arranged in this manner, the camera body 100 and the lens barrel 200 are brought into contact with each other by bringing the mounting surface of the body side mounting unit 101 into contact with the mounting surface of the lens side mounting unit 201. When the mount coupling is performed, the holding unit 102 and the holding unit 202 are connected, and the electrical contacts provided in both the holding units are also connected. Since such a mount structure is well known, further explanation and illustration are omitted.

  As shown in FIG. 3, the holding unit 102 has 12 contacts BP <b> 1 to BP <b> 12. The holding unit 202 has twelve contacts LP1 to LP12 corresponding to the twelve contacts described above.

  The contacts BP1 and BP2 are connected to the first power supply circuit 130 in the camera body 100. The first power supply circuit 130 supplies the operating voltage of each part in the lens barrel 200 excluding a circuit (such as the lens driving unit 212) having a driving system such as an actuator to the contact point BP1 and having a relatively large power consumption. That is, the operating voltage of each part in the lens barrel 200 excluding the above driving parts is supplied from the contact BP1 and the contact LP1. The voltage value that can be supplied to the contact point BP1 has a range from the minimum voltage value to the maximum voltage value (for example, a voltage width in the 3V range). Is a voltage value in the vicinity of the intermediate value. Thus, the current value supplied from the camera body 100 side to the lens barrel 200 side is a current value within a range of about several tens mA to several hundred mA in the power-on state.

  The contact BP2 is a ground terminal corresponding to the operating voltage given to the contact BP1. That is, the contact BP2 and the contact LP2 are ground terminal voltages corresponding to the above operating voltage.

  In the following description, the signal line constituted by the contact point BP1 and the contact point LP1 is referred to as a signal line V33. A signal line constituted by the contact point BP2 and the contact point LP2 is referred to as a signal line GND. These contacts LP1, LP2, BP1, BP2 constitute a power supply system contact for supplying power from the camera body 100 side to the lens barrel 200 side.

  The contacts BP3, BP4, BP5, and BP6 are connected to the body-side first communication unit 117. The contact points LP3, LP4, LP5, and LP6 on the lens barrel 200 side corresponding to these contact points 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 transmit and receive signals to and from each other using these contacts (communication system contacts). The contents of communication performed by the body-side first communication unit 117 and the lens-side first communication unit 217 will be described in detail later.

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

  The contacts BP7, BP8, BP9, and BP10 are connected to the body-side second communication unit 118. The contact points LP7, LP8, LP9, and LP10 on the lens barrel 200 side corresponding to these contact points are connected to the lens-side second communication unit 218. The lens-side second communication unit 218 transmits signals to the body-side second communication unit 118 using these contacts (communication system contacts). The contents of 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 contact BP7 and the contact LP7 is referred to as a signal line HREQ. Similarly, a signal line composed of the contact point BP8 and the contact point LP8 is signal line HANS, a signal line composed of the contact point BP9 and the contact point LP9 is signal line HCLK, and a signal line composed of the contact point BP10 and the contact point LP10 is signaled. Called line HDAT.

  The contact BP11 and the contact BP12 are connected to the second power supply circuit 131 in the camera body 100. The second power supply circuit 131 supplies a driving voltage of a circuit (such as the lens driving unit 212) having a driving system such as an actuator and a relatively large power consumption to the contact point BP12. That is, the driving voltage of the lens driving unit 212 is supplied from the contact point BP12 and the contact point LP12. The voltage value that can be supplied to the contact point BP12 has a range from the minimum voltage value to the maximum voltage value, all of which are larger than the voltage value range that can be supplied to the contact point BP1 (for example, The maximum voltage value that can be supplied to the contact point BP12 is several times the maximum voltage value that can be supplied to the contact point BP1). That is, the voltage value supplied to the contact point BP12 is a voltage value whose magnitude is different from the voltage value supplied to the contact point BP1. The voltage value that is normally supplied to the contact BP12 is a voltage value in the vicinity of an intermediate value between the maximum voltage value and the minimum voltage value that can be supplied to the contact BP12. As a result, the current supplied from the camera body 100 side to the lens barrel 200 side has a current value of about 10 mA to several A in the power-on state.

  The contact BP11 is a ground terminal corresponding to the drive voltage given to the contact BP12. That is, the contact BP11 and the contact LP11 are ground terminals corresponding to the drive voltage.

  In the following description, a signal line constituted by the contact BP11 and the contact LP11 is referred to as a signal line PGND. A signal line constituted by the contact BP12 and the contact LP12 is referred to as a signal line BAT. These contacts LP11, LP12, BP11, BP12 constitute a power supply system contact for supplying power from the camera body 100 side to the lens barrel 200 side.

  As is apparent from the magnitude relationship between the voltage value (current value) supplied to the contacts BP12 and LP12 and the voltage value (current value) supplied to the contacts BP1 and LP1, the voltages are supplied to the contacts. The difference between the maximum value and the minimum value of the current flowing through the contact point BP11 and the contact point LP11 serving as the ground terminals for each of the voltages is larger than the difference between the maximum value and the minimum value of the current flowing through the contact point BP2 and the contact point LP2. ing. This is because the power consumed by each drive unit having a drive system such as an actuator is larger than that of an electronic circuit such as the lens control unit 203 in the lens barrel 200, and it is not necessary to drive the driven member. In some cases, each drive unit does not consume power.

(Description of command data communication)
The lens control unit 203 controls the lens-side first communication unit 217 and receives control data from the body-side first communication unit 117 via the contacts LP3 to LP6, that is, the signal lines CLK, BDAT, LDAT, and RDY. Reception and transmission of response data to the body-side first communication unit 117 are performed in parallel at a first predetermined cycle (for example, 16 milliseconds in this embodiment). 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 control unit 203 and the lens-side first communication unit 217 and the body control unit 103 and the body-side first communication unit 117 is referred to as “command data communication”. A transmission line composed of four signal lines (signal lines CLK, BDAT, LDAT, and RDY) used for command data communication is referred to as a first transmission line.

  FIG. 4 is a timing chart showing an example of command data communication. The body control unit 103 and the body-side first communication unit 117 first check 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. The lens control unit 203 and the lens-side first communication unit 217 output a signal of H (High) level from the contact LP6 when communication is not possible. That is, the signal level of the signal line RDY is set to H level. When the signal line RDY is at the H level, the body control unit 103 and the body-side first communication unit 117 do not start communication until the signal line RDY is at the L level. Also, the next processing during communication is not executed.

  If the signal line RDY is at L (Low) level, the body control unit 103 and the first body side communication unit 117 output the clock signal 401 from the contact point BP3. That is, the clock signal 401 is transmitted to the first lens side communication unit 217 via the signal line CLK. In synchronization with the clock signal 401, the body control unit 103 and the body side first communication unit 117 output a body side command packet signal 402, which is the first half of the control data, from the contact point BP4. That is, the body side command packet signal 402 is transmitted to the first lens side communication unit 217 via the signal line BDAT.

  When the clock signal 401 is output to the signal line CLK, the lens control unit 203 and the lens-side first communication unit 217 synchronize with the clock signal 401, and the lens-side command packet that is the first half of the response data from the contact LP5. The signal 403 is output. That is, the lens-side command packet signal 403 is transmitted to the first body-side communication unit 117 via the signal line LDAT.

The lens control unit 203 and the lens side first communication unit 217 set 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 control unit 203 starts a first control process 404 (described later) that is a process according to the content of the received body-side command packet signal 402.

  When the first control process 404 is completed, the lens 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 contact LP6. That is, the signal level of the signal line RDY is set to L level (T3). The body control unit 103 and the first body side communication unit 117 output the clock signal 405 from the contact point BP3 in accordance with the change in the signal level. That is, the clock signal 405 is transmitted to the lens side first communication unit 217 via the signal line CLK.

  The body control unit 103 and the first body-side communication unit 117 output a body-side data packet signal 406 that is the latter half of the control data from the contact point BP4 in synchronization with the clock signal 405. That is, the body side data packet signal 406 is transmitted to the lens side first communication unit 217 via the signal line BDAT.

  Further, when the clock signal 405 is output to the signal line CLK, the lens control unit 203 and the lens side first communication unit 217 synchronize with the clock signal 405, and the lens which is the latter half of the response data from the contact LP5 receives the data packet signal. 407 is output. That is, the lens-side data packet signal 407 is transmitted to the first body-side communication unit 117 via the signal line LDAT.

  In response to the completion of transmission of the lens-side data packet signal 407, the lens control unit 203 and the lens-side first communication unit 217 set the signal level of the signal line RDY to the H level again (T4). The lens control unit 203 starts a second control process 408 (described later) that is a process according to the content of the received body-side data packet signal 406.

  Here, the first control process 404 and the second control process 408 performed by the lens control unit 203 will be described.

  For example, a case where the received body side command packet signal 402 is a content requesting specific data on the lens barrel side will be described. As the first control process 404, the lens control unit 203 analyzes the content of the command packet signal 402 and executes a process of generating the requested specific data. Further, as the first control process 404, the lens control unit 203 uses the checksum data included in the command packet signal 402 to easily determine whether there is an error in the communication of the command packet signal 402 from the number of data bytes. The communication error check process to check is also executed. The specific data signal generated in the first control process 404 is output to the body side as a lens-side data packet signal 407. In this case, the body side data packet signal 406 output from the body side after the command packet signal 402 is a dummy data signal (including checksum data) that has no particular meaning for the lens side. In this case, the lens control unit 203 executes the communication error check process as described above using the checksum data included in the body side data packet signal 406 as the second control process 408.

For example, a case where the received body-side command packet signal 402 is an instruction to drive a lens-side driven member will be described. For example, a case where the 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 will be described. As the first control process 404, the lens control unit 203 analyzes the content of the command packet signal 402 and generates an acknowledgment signal indicating that the content has been understood. Furthermore, the lens control unit 203 also executes the communication error check process as described above using the checksum data included in the command packet signal 402 as the first control process 404. The acknowledge signal generated in the first control process 404 is output to the body side as a lens side data packet signal 407. In addition, as the second control process 408, the lens control unit 203 executes an analysis process of the contents of the body side data packet signal 406 and uses the checksum data included in the body side data packet signal 406 as described above. Execute the check process.

  When the second control process 408 is completed, the lens control unit 203 notifies the lens side first communication unit 217 of the completion of the second control process 408. Accordingly, the lens control unit 203 causes the lens side first communication unit 217 to output an L level signal from the contact LP6. That is, the signal level of the signal line RDY is set to L level (T5).

  If the received body-side command packet signal 402 is an instruction to drive the lens-side driven member (for example, the focusing lens 210b) as described above, the lens control unit 203 notifies the lens-side first communication unit 217. While the signal level of the signal line RDY is set to L level, the lens driving unit 212 is caused to execute processing for driving the focusing lens 210b by the driving amount.

  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 control unit 103 and body side first communication unit 117 transmit body side command packet signal 402 and body side data packet signal 406 one by one. 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 control unit 203 and the lens side first communication unit 217 transmit the lens side command packet signal 403 and the lens side data packet signal 407 one by one. 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 control unit 203 and the lens-side first communication unit 217 perform 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. And do it. The contact LP6 and the contact BP6 used for command data communication are contacts through which asynchronous signals (signal level of the signal line RDY / H (High) level or L (Low) level) that are not synchronized with other clock signals are transmitted. is there.

(Description of hotline communication)
The lens control unit 203 controls the lens side second communication unit 218 to transmit lens position data to the body side second communication unit 118 via the contacts LP7 to LP10, that is, the signal lines HREQ, HANS, HCLK, and HDAT. Send. 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 control unit 203 and the lens-side second communication unit 218, and the body control unit 103 and the body-side second communication unit 118 is referred to as “hotline communication”. A transmission line composed of four signal lines (signal lines HREQ, HANS, HCLK, and HDAT) used for hot line communication is referred to as a second transmission line.

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

  At the start of hot line communication (T6), body control unit 103 and body-side second communication unit 118 first output an L level signal from contact point BP7. That is, the signal level of the signal line HREQ is set to L level. The lens side second communication unit 218 notifies the lens control unit 203 that this signal has been input to the contact LP7. In response to this notification, the lens control unit 203 starts executing a generation process 501 that generates lens position data. The generation process 501 is a process in which the lens control unit 203 causes a focusing lens position detection unit (not shown) to detect the position of the focusing lens 210b and generates lens position data representing the detection result.

  When the lens control unit 203 completes the generation process 501, the lens control unit 203 and the lens-side second communication unit 218 output an L level signal from the contact LP8 (T7). That is, the signal level of the signal line HANS is set to the L level. The body control unit 103 and the body-side second communication unit 118 output the clock signal 502 from the contact BP9 in response to the input of this signal to the contact BP8. That is, a clock signal is transmitted to the lens side second communication unit 218 via the signal line HCLK.

  The lens control unit 203 and the second lens-side communication unit 218 output a lens position data signal 503 representing lens position data from the contact LP10 in synchronization with the clock signal 502. That is, the lens position data signal 503 is transmitted to the body-side second communication unit 118 via the signal line HDAT.

  When the transmission of the lens position data signal 503 is completed, the lens control unit 203 and the second lens side communication unit 218 output an H level signal from the contact LP8. That is, the signal level of the signal line HANS is set to the H level (T8). The body-side second communication unit 118 outputs an H-level signal from the contact LP7 in response to the input of this signal to the contact BP8. That is, the signal level of the signal line HREQ is set to H level (T9).

  The communication performed from time T6 to time T9 described above is one hot line communication. As described above, in one hot line communication, one lens position data signal 503 is transmitted by the lens control unit 203 and the second lens side communication unit 218. The contacts LP7, LP8, BP7, and BP8 used for hotline communication are contacts through which asynchronous signals that are not synchronized with other clock signals are transmitted. That is, the contacts LP7 and BP7 are contacts through which asynchronous signals (signal level HREQ signal level / H (High) level or L (Low) level) are transmitted, and the contacts LP8 and BP8 are asynchronous signals (signal line HANS). Signal level / H (High) level or L (Low) level).

  Note that the command data communication and the hotline communication can be executed simultaneously or partially 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.

(Explanation of automatic focus adjustment)
The body control unit 103 is configured to execute a well-known automatic focus adjustment process. In this automatic focus adjustment process, the body control unit 103 is configured to be able to selectively use two types of focus detection processes. Specifically, the body control unit 103 can selectively use so-called pupil division phase difference type focus detection processing and so-called contrast type focus detection processing. The body control unit 103 uses these two types of focus detection processing properly depending on the shooting situation, the characteristics of the subject, and the like.

  The focus detection processing of the pupil division phase difference detection method by the body control unit 103 will be described. The image sensor 104 of the present embodiment has focus detection pixels (referred to as focus detection pixels). The focus detection pixels are the same as those described in Japanese Patent Application Laid-Open No. 2007-317951. The body control unit 103 performs focus detection processing by performing a known phase difference detection calculation using pixel output data from the focus detection pixels. The phase difference detection calculation is the same as that described in, for example, Japanese Patent Application Laid-Open No. 2007-317951, and thus the description thereof is omitted. The body control unit 103 performs automatic focus adjustment by causing the lens driving unit 212 to drive the focusing lens 210b based on the defocus amount obtained by the focus detection processing. In addition, when executing the pupil division phase difference type focus detection process, a reliable defocus amount may not be calculated. In this case, the body control unit 103 performs a so-called scanning operation that calculates the defocus amount while driving the focusing lens 210b within a predetermined range.

  A contrast-type focus detection process performed by the body control unit 103 will be described. The body control unit 103 performs a known contrast detection calculation using pixel output data from the imaging pixels included in the imaging element 104. The body control unit 103 executes a so-called search operation in which the contrast detection calculation is performed while driving the focusing lens 210b between the closest drive limit position and the infinity drive limit position, and the focus evaluation value (contrast value) Automatic focus adjustment is performed by detecting the position of the focusing lens 210b having a peak value.

  The lens control unit 203 corresponds to two types of lens driving commands (first lens driving command and second lens driving command) for driving the focusing lens 210b. The first lens driving command is a command for driving the focusing lens 210b at a designated driving speed, and includes the driving amount and driving speed of the focusing lens 210b as parameters. When the body control unit 103 transmits a first lens driving command including the driving amount and driving speed of the focusing lens 210b to the lens control unit 203 by command data communication, the lens driving unit 212 specifies the driving amount specified at the specified driving speed. Only the focusing lens 210b is driven.

  On the other hand, the second lens drive command is a command for driving the focusing lens 210b so that the image forming surface by the image forming optical system 210 moves at a specified moving speed, and a moving amount of the image forming surface (image surface moving) as a parameter. Quantity) and the moving speed of the image plane (image plane moving speed). When the body control unit 103 transmits a second lens driving command including the image plane movement amount and the image plane movement speed to the lens control unit 203 by command data communication, the lens control unit 203 is designated at the designated image plane movement speed. The lens driving unit 212 is controlled so that the imaging plane of the imaging optical system 210 moves by the image plane movement amount, and the focusing lens 210b is driven.

  FIG. 6 is a diagram illustrating a correspondence relationship between a lens position and a lens driving speed necessary when the image plane moving speed is constant at the lens position, where the horizontal axis indicates the position of the focusing lens 210b and the vertical axis indicates the position. Each lens driving speed is shown. The lens barrel 200 shown as an example in FIG. 6 is configured such that the amount of image plane movement with respect to the lens driving amount increases as the distance from the closest side increases. That is, at the closest end, the focusing plane 210b is moved a little to move the imaging plane greatly.

  In the lens barrel 200 shown in FIG. 6, for example, when the focusing lens 210b is driven at a constant image plane moving speed from the closest end to the infinity end, it is necessary to gradually increase the lens driving speed. The ROM 215 stores in advance information indicating the correspondence between the lens position and the image plane movement amount as shown in FIG. 6, and the lens control unit 203 uses this information to move the focusing lens 210b to a certain image plane movement. Control to drive at speed.

  The body control unit 103 transmits a second lens driving command to the lens control unit 203 when performing a search operation in contrast type focus detection and performing a scan operation in pupil division phase difference type focus detection. To do. This is to increase the accuracy of focus detection by making the interval between contrast detection and phase difference detection constant. If focus detection is performed at a constant lens driving speed, the image plane may change rapidly in the vicinity of the closest end or the infinite end, and focus detection may not be performed correctly. Therefore, in the above case, it is desirable to drive the focusing lens 210b with a constant image plane moving speed. On the other hand, for example, when the focus detection process is completed and the in-focus position is determined, the first lens that drives the focusing lens 210b to the in-focus position, that is, the so-called in-focus drive, makes the lens driving speed constant. A drive command may be used.

(Description of silent mode)
The lens control unit 203 of the present embodiment performs control of the lens driving unit 212 based on two types of control modes (normal control mode and silent control mode). When the normal control mode is set in the lens control unit 203, the lens control unit 203 controls the lens driving unit 212 without limiting the driving speed of the focusing lens 210b. On the other hand, when the silent control mode is set in the lens control unit 203, the lens control unit 203 controls the lens driving unit 212 so that the driving speed of the focusing lens 210b does not exceed a predetermined maximum driving speed. Specifically, during the control of the lens driving unit 212, the driving speed of the focusing lens 210b detected by the lens speed detecting unit 214 is monitored so that the detected driving speed does not exceed the maximum driving speed. .

  For example, when the silent control mode is set in the lens control unit 203, if a first lens drive command specifying a lens drive speed exceeding the maximum drive speed is transmitted, the lens control unit 203 specifies the specified drive. The focusing lens 210b is driven not at the speed but at the maximum driving speed described above.

  In the present embodiment, the maximum driving speed of the focusing lens 210b in the silent control mode is determined based on the driving sound generated when the lens driving unit 212 drives the focusing lens 210b. For example, the maximum drive speed at which the drive sound does not exceed a predetermined volume (for example, 50 decibels) is set as the maximum drive speed in the silent control mode. When the moving image shooting mode is set in the camera body 100, the body control unit 103 transmits a silent control mode command to the lens control unit 203 by command data communication, and causes the lens control unit 203 to enter the silent control mode. On the other hand, when the still image shooting mode is set in the camera body 100, a normal control mode command is transmitted to the lens control unit 203, and the lens control unit 203 is shifted to the normal control mode.

When the above-described silent control mode is set in the lens control unit 203, there is a possibility that the control of the lens driving unit 212 according to the above-described second lens driving command cannot be performed correctly. For example, when the focusing lens 210b is located in the range R1 shown in FIG. 6, in order to drive the focusing lens 210b at the image plane moving speed corresponding to FIG. It is necessary to drive the focusing lens 210b at a speed exceeding this. When the request from the camera body 100 for the image plane moving speed and the limit of the maximum driving speed in the silent control mode conflict with each other, the lens control unit 203 of the present embodiment limits the maximum driving speed as shown in FIG. The lens driving unit 212 is controlled with priority given to the above. In other words, in the range R1 shown in FIG. 6, when the focusing lens 210b is driven at the image plane moving speed corresponding to FIG. 6, the focusing lens 210b is driven at the maximum driving speed shown by the broken line in FIG. That is, the lens control unit 203 is different from the image plane movement speed requested by the camera body 100 (included in the second lens drive command) (as large as possible) in the range R1 in FIG. ) To move the imaging plane of the imaging optical system 210.

  Note that the lens control unit 203 of the present embodiment notifies the camera body 100 (body control unit 103) of the maximum drive speed in the initial communication with the camera body 100. Here, the initial communication means that the lens barrel 200 is attached to the camera body 100 and the camera body 100 changes from the power-off state to the power-on state, or when the camera body 100 is in the power-on state. This is communication for exchanging information between the camera body 100 and the lens barrel 200, which is executed by command data communication when the lens barrel 200 is mounted. In the initial communication, for example, information representing the optical characteristics of the imaging optical system 210 is transmitted from the lens barrel 200, and the above maximum driving speed is transmitted together with the information.

  Since the body control unit 103 can know the maximum driving speed in the silent control mode by initial communication, normally, when transmitting the second lens driving command in the silent control mode, a driving speed exceeding the maximum driving speed is designated. It will never be done. However, the lens-side first communication unit 217 cannot correctly receive the driving speed due to electrical noise or the like, and as a result, the lens control unit 203 determines that a driving speed exceeding the maximum driving speed is designated. The possibility remains. When the silent control mode is set, the lens control unit 203 of the present embodiment determines whether or not the drive speed specified by the second lens drive command exceeds the maximum drive speed just in case. In such a case, since the lens driving unit 212 is controlled so that the focusing lens 210b is driven at the maximum driving speed instead of the designated driving speed, the operation when the silent control mode is set is ensured.

  According to the camera system according to the first embodiment described above, the following operational effects can be obtained. (1) The lens-side first communication unit 217 receives from the camera body 100 a second lens drive command that instructs to drive the focusing lens 210b at a predetermined image plane moving speed, and a silent control mode command. The lens control unit 203 controls the lens driving unit 212 so that the imaging plane of the imaging optical system 210 moves at a predetermined image plane moving speed in response to the second lens driving command. When the silent control mode command is received by the lens-side first communication unit 217 and the silent control mode is set, the lens control unit 203 has a driving speed of the focusing lens 210b necessary to achieve the image plane moving speed described above. Whether or not exceeds a predetermined maximum driving speed. When it is determined that the driving speed of the focusing lens 210b exceeds the maximum driving speed, the lens driving unit 212 is controlled so that the focusing lens 210b is driven at the maximum driving speed. Since it did in this way, it becomes possible to drive a focusing lens suitably, without having to directly specify the lens drive speed for a camera main body to perform a silent operation.

(2) The lens-side first communication unit 217 receives a first lens drive command that instructs the camera body 100 to drive the focusing lens 210b at a predetermined drive speed. When the silent control mode command is received by the lens side first communication unit 217, the lens control unit 203 determines whether the driving speed specified by the first lens driving command exceeds a predetermined maximum driving speed. . The lens control unit 203 controls the lens driving unit 212 so that the focusing lens 210b is driven at the maximum driving speed when it is determined that the driving speed specified by the first lens driving command exceeds the maximum driving speed. As described above, the focusing lens 210b can be driven at a driving speed that takes noise into account even when a first lens driving command that specifies a driving speed larger than the maximum driving speed is received due to a communication error or the like. it can.

(3) When the camera body 100 performs a search operation in contrast-type focus detection and performs a scan operation in pupil-division phase-difference focus detection, the lens-side first communication unit 217 receives from the camera body 100. When the second lens driving command (command for designating the image plane moving speed) is received and the camera body 100 performs focusing driving based on the result of focus detection, the first lens driving command (lens driving speed) is received from the camera body 100. Command) is received. Since it did in this way, the camera body 100 can switch the driving method of the optimal focusing lens 210b according to a condition, and the usability of a lens barrel improves.

(4) During initial communication, the maximum drive speed in the silent control mode is transmitted from the lens control unit 203 to the body control unit 103. Since it did in this way, when using a 1st lens drive command, it becomes possible to designate an appropriate drive speed.

(Second Embodiment)
The camera system according to the second embodiment has the same configuration as the camera system according to the first embodiment, but performs control in consideration of not only the maximum drive speed but also the minimum drive speed in the silent control mode. . Hereinafter, this point will be described in detail. In addition, the same code | symbol is attached | subjected about the location similar to the digital camera which concerns on 1st Embodiment, and description is abbreviate | omitted.

  FIG. 8 is a diagram showing a correspondence relationship between the lens position and the lens driving speed required when the image plane moving speed is constant at the lens position. As in FIGS. 6 and 7, the horizontal axis indicates the focusing. The position of the lens 210b, and the vertical axis represents the lens driving speed. The lens control unit 203 limits the lens driving speed by the maximum driving speed as in the first embodiment, but further limits the lens driving speed by the minimum driving speed in the present embodiment. That is, the focusing lens 210b is driven at a speed ranging from the minimum driving speed to the maximum driving speed.

  The specific control content is the same as that related to the maximum drive speed described in the first embodiment. That is, when the lens control unit 203 receives the second lens driving command when the silent control mode is set, the driving speed of the focusing lens 210b necessary to achieve the designated image plane moving speed is a predetermined minimum. It is determined whether or not the driving speed is lower. When it is determined that the driving speed of the focusing lens 210b is lower than the minimum driving speed, the lens driving unit 212 is controlled so that the focusing lens 210b is driven at the minimum driving speed or higher. Similarly, when the first lens drive command is received, it is determined whether or not the designated lens drive speed is lower than the minimum drive speed. If it is lower, the minimum drive speed is used instead of the designated lens drive speed. Thus, the focusing lens 210b is driven.

  In addition, the lens control unit 203 according to the present embodiment transmits the minimum drive speed together with the maximum drive speed to the camera body 100 in the initial communication. The body control unit 103 can grasp how much lens driving speed is allowed in the silent control mode by acquiring these pieces of information in the initial communication, and thus can drive the focusing lens 210b more appropriately. Control can be performed.

  According to the camera system according to the second embodiment described above, the following operational effects can be obtained. (1) When the silent control mode command is received by the lens side first communication unit 217, the lens control unit 203 has a predetermined driving speed of the focusing lens 210b required to achieve a predetermined image plane moving speed. It is determined whether or not the minimum driving speed is exceeded. When it is determined that the driving speed of the focusing lens 210b is lower than the minimum driving speed, the lens driving unit 212 is controlled so that the focusing lens 210b is driven at the minimum driving speed. Since this is done, it becomes possible to control the driving of the focusing lens 210b in consideration of the generation of driving sound not only during high-speed driving but also during low-speed driving.

  The following modifications are also within the scope of the present invention, and one or a plurality of modifications can be combined with the above-described embodiment.

(Modification 1)
In each of the embodiments described above, when the required drive speed (or designated drive speed) exceeds the maximum drive speed, control is performed so that the focusing lens 210b is driven at the maximum drive speed instead of the drive speed. I was going. At this time, any driving speed below the maximum driving speed may be used instead of the maximum driving speed. The same applies to the minimum drive speed in the second embodiment. That is, when the required driving speed (or designated driving speed) is lower than the minimum driving speed, the focusing lens 210b is driven at any driving speed equal to or higher than the minimum driving speed instead of the driving speed. It may be.

(Modification 2)
The present invention is not limited to the above-described embodiments as long as it is a lens barrel used in a camera system in which lenses can be exchanged, and can be applied to anything. For example, the present invention can be applied to a so-called single-lens reflex camera system having a quick return mirror.

  As long as the characteristics of the present invention are not impaired, the present invention is not limited to the above-described embodiments, and other forms conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention. .

DESCRIPTION OF SYMBOLS 1 ... Camera, 100 ... Camera body, 101 ... Body side mount part, 102, 202 ... Holding part, 103 ... Body control part, 117 ... Body side 1st communication part, 118 ... Body side 2nd communication part, 200 ... Lens Lens barrel 201 ... Lens side mount part 203 ... Lens control part 210 ... Image forming optical system 210b Focusing lens 212 Lens drive part 214 Lens speed detection part 215 ROM 217 Lens side first 1 communication unit, 218... Lens side second communication unit

Claims (1)

An attachment part to which the camera body can be attached;
An imaging optical system having a focusing lens;
A first drive signal for instructing to drive the focusing lens at a predetermined image plane moving speed from the camera body, a second drive signal for instructing to drive the focusing lens at a predetermined driving speed, and silence A receiver for receiving a mode command signal;
A drive unit for driving the focusing lens;
A control unit that controls the drive unit so that an imaging plane of the imaging optical system moves at the predetermined image plane moving speed in response to the first drive signal;
When the silent mode command signal is received by the receiving unit, at least one of the driving speed of the focusing lens and the predetermined driving speed required to achieve the predetermined image plane moving speed is predetermined. An upper limit determination unit that determines whether or not the upper limit speed is exceeded,
The control unit is configured such that at least one of the driving speed of the focusing lens and the predetermined driving speed necessary for achieving the predetermined image plane moving speed by the upper limit determination unit exceeds the predetermined upper limit speed. If determined, the driving unit is controlled so that the focusing lens is driven at a first driving speed equal to or lower than the predetermined upper limit speed;
The receiving unit receives the first drive signal from the camera body when the camera body performs a search operation in contrast type focus detection or performs a scan operation in pupil division phase difference type focus detection. An interchangeable lens that receives the second drive signal from the camera body when the camera body performs focusing drive based on a focus detection result.

Images