JP7424416B2 - accessory - Google Patents

Description

The present invention relates to accessories .

Accessories that can be attached to and detached from a camera body are known (for example, Patent Document 1). Conventionally, it has been necessary to attach accessories to a camera body in a state where they can be used properly.

Japanese Patent Application Publication No. 2004-117380

An accessory according to a first aspect of the present invention is an accessory that can be attached to a camera body, and includes a communication section that includes a circuit that communicates with the camera body, and a communication section that communicates with the camera body via the communication section. a ready terminal used to indicate whether communication is possible; a first data terminal to which a first data signal from the camera body to the communication section is input; and a second data signal output from the communication section to the camera body. a second data terminal for outputting a clock signal from the communication section to the camera body; a first clock terminal for outputting a third data signal from the communication section to the camera body in synchronization with the clock signal; three data terminals, the ready terminal, the first data terminal, the second data terminal, the first clock terminal, and the third data terminal are arranged in order.

Diagram schematically showing the configuration of the camera system A circuit diagram schematically showing the electrical connection between the camera body and the interchangeable lens according to the first embodiment Timing chart showing an example of command data communication Timing chart showing an example of hotline communication Front view schematically showing the mount surface of the camera body as seen from the interchangeable lens side Front view schematically showing the mounting surface of an interchangeable lens as seen from the camera body side A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a second embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a third embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a fourth embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a fifth embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a sixth embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a seventh embodiment A circuit diagram schematically showing electrical connection between a camera body and an interchangeable lens according to the eighth embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a ninth embodiment A circuit diagram schematically showing an electrical connection between a camera body and an interchangeable lens according to a tenth embodiment

(First embodiment)
FIG. 1 is a diagram schematically showing the configuration of a camera system 1 according to the first embodiment. The camera system 1 includes a camera body 2 and an interchangeable lens 3 as an example of an accessory that can be attached to and detached from the camera body 2.

The interchangeable lens 3 includes a lens-side mount 31 , a lens-side terminal holding section 32 , a lens-side control section 33 having a lens-side communication section 34 , a lens-side storage section 35 , an imaging optical system 36 , and a drive section 37 . The lens side mount 31 and the lens side terminal holding section 32 will be described in detail later.

The lens side control section 33 is composed of a microcomputer, its peripheral circuits, and the like. The lens-side communication unit 34 performs data communication with the camera body 2, which will be described later. The lens side communication section 34 is connected to a lens side terminal group (described later) provided on the lens side terminal holding section 32. The lens side storage section 35 is a nonvolatile storage medium. The lens side storage section 35 is connected to the lens side control section 33. The lens-side storage unit 35 stores in advance a predetermined control program and the like executed by the lens-side control unit 33 . The lens-side control unit 33 controls the interchangeable lens 3 by reading a control program from the lens-side storage unit 35 and executing the program.

The imaging optical system 36 forms a subject image on the imaging surface of an image sensor 27, which will be described later. The optical axis O of the imaging optical system 36 substantially coincides with the center positions of the lens-side mount 31 and the body-side mount 21, which will be described later. The imaging optical system 36 in FIG. 1 generally includes a lens 36a, a focus lens 36b, and a lens 36c. The focus lens 36b is a lens that adjusts the imaging position of the subject image. The drive unit 37 is connected to the lens-side control unit 33 and includes an actuator (not shown) and the like. The drive unit 37 drives the focus lens 36b in the optical axis direction (+Z direction, −Z direction) using this actuator or the like.

The camera body 2 includes a body-side mount 21, a body-side terminal holding section 22, a body-side control section 23 having a body-side communication section 24, a body-side storage section 25, a power supply section 26, an image sensor 27, and a lock pin (to be described later). It has a switch 28 that detects the state.

The body-side control section 23 is composed of a microcomputer, its peripheral circuits, and the like. Note that the body-side control unit 23 performs various controls on the body, but in this case, only the portions related to communication will be described, and other functions will be omitted. The body-side communication unit 24 performs data communication with the interchangeable lens 3, which will be described later. The body side communication section 24 is connected to a body side terminal (described later) provided on the body side terminal holding section 22. Note that some terminals of the body-side terminal holding section 22 are connected to the body-side control section 23 as described later. The body side storage section 25 is a nonvolatile storage medium. The body-side storage section 25 is connected to the body-side control section 23 . The body-side storage section 25 stores in advance a predetermined control program and the like executed by the body-side control section 23 . The body-side control unit 23 controls the camera body 2 by reading a control program from the body-side storage unit 25 and executing the program.

The power supply section 26 has a power source and supplies power to the inside of the camera body 2 and the interchangeable lens 3. The power feeding section 26 is connected to a body-side terminal group (described later) provided on the body-side terminal holding section 22 and the body-side control section 23 . The image sensor 27 is, for example, a solid-state image sensor such as a CCD or a CMOS. The image sensor 27 is connected to the body-side control section 23, images a subject, and outputs an image signal. A description of the processing of the output imaging signal will be omitted.

FIG. 2 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3. As shown in FIG. The body side terminal holding part 22 has a LDET (B) terminal, a VBAT (B) terminal, a PGND (B) terminal, a V33 (B) terminal, a GND (B) terminal, an RDY (B) terminal, a DATAB (B) terminal, It has a CLK (B) terminal, a DATAL (B) terminal, an HCLK (B) terminal, and an HDATA (B) terminal. These 11 body-side terminals are collectively referred to as a body-side terminal group.

The LDET (B) terminal is a terminal used to detect attachment and detachment of the interchangeable lens 3. The LDET (B) terminal is connected to the body-side control section 23 via a resistor R2. A power supply V33 supplied from the power supply unit 26 is connected between the resistor R2 and the body-side control unit 23 via the resistor R1, and the LDET (B) terminal is pulled up.

The VBAT (B) terminal, the PGND (B) terminal, the V33 (B) terminal, and the GND (B) terminal are power supply system terminals connected to the power supply unit 26. In FIG. 2, arrows indicate the direction of the supplied power. The VBAT (B) terminal is a terminal used to supply power to the interchangeable lens 3. The drive section 37 of the interchangeable lens 3 is driven by the power supplied via the VBAT (B) terminal. The operation of the drive section 37 requires a larger voltage and a larger current than the lens-side control section 33, and the power supply voltage applied to the VBAT (B) terminal by the power supply section 26 is about 10V at maximum. In the following description, the voltage that the power supply section 26 applies to the VBAT (B) terminal will be referred to as a drive system voltage. That is, the camera body 2 supplies the drive system power supply voltage to the interchangeable lens 3 from the VBAT (B) terminal. The PGND (B) terminal is a ground terminal corresponding to the VBAT (B) terminal, and is used as a ground potential (ground) for the power supply voltage of the drive system.

The V33(B) terminal is a terminal used to supply power to the interchangeable lens 3. The lens-side control section 33 and the like are operated by power supplied from the power supply section 26 via the V33(B) terminal. Each section such as the lens-side control section 33 operates with a smaller voltage and a smaller current than the driving section 37. The voltage that the power supply unit 26 applies to the V33(B) terminal is approximately 3.3V at maximum. In the following description, the voltage that the power supply section 26 applies to the V33(B) terminal will be referred to as a circuit system voltage. That is, the camera body 2 supplies the power supply voltage of the circuit system to the interchangeable lens 3 from the V33(B) terminal. The GND (B) terminal is a ground terminal corresponding to the V33 (B) terminal, and is used as a ground potential (ground) for the power supply voltage of the circuit system.

The RDY(B) terminal is connected to the body side communication section 24. The DATAB (B) terminal, CLK (B) terminal, DATAL (B) terminal, HCLK (B) terminal, and HDATA (B) terminal are communication system terminals connected to the body side communication section 24. The RDY (B) terminal, DATAB (B) terminal, CLK (B) terminal, and DATAL (B) terminal are used for command data communication, which will be described later. Further, the HCLK (B) terminal and the HDATA (B) terminal are connected to the body side communication section 24 and used for hotline communication, which will be described later. In FIG. 2, the flow of signals is shown by arrows. The potential of the RDY(B) terminal indicates whether or not the interchangeable lens 3 is capable of command data communication. The DATAB (B) terminal is a terminal to which a data signal is output toward the interchangeable lens 3. The CLK (B) terminal is a terminal to which a clock signal (C clock signal) is output from the camera body 2 toward the interchangeable lens 3 .

The DATAL (B) terminal is a terminal into which a data signal from the interchangeable lens 3 is input.

The HCLK (B) terminal is a terminal into which a clock signal (H clock signal) from the interchangeable lens 3 is input. The HDATA (B) terminal is a terminal into which a data signal from the interchangeable lens 3 is input.

The lens side terminal holding part 32 has an LDET (L) terminal, a VBAT (L) terminal, a PGND (L) terminal, a V33 (L) terminal, a GND (L) terminal, an RDY (L) terminal, a DATAB (L) terminal, It has a CLK (L) terminal, a DATAL (L) terminal, an HCLK (L) terminal, and an HDATA (L) terminal. These 11 lens-side terminals are collectively referred to as a lens-side terminal group. When the interchangeable lens 3 is attached to the camera body 2, the body-side terminal and the lens-side terminal are electrically connected, as shown by the broken line in FIG. Specifically, the LDET (L) terminal is connected to the LDET (B) terminal, the VBAT (L) terminal is connected to the VBAT (B) terminal, and the PGND (L) terminal is connected to the PGND (B) terminal. The V33 (L) terminal is connected to the V33 (B) terminal, the GND (L) terminal is connected to the GND (B) terminal, and the RDY (L) terminal is connected to the RDY (B) terminal. , the DATAB(L) terminal is connected to the DATAB(B) terminal, the CLK(L) terminal is connected to the CLK(B) terminal, the DATAL(L) terminal is connected to the DATA(B) terminal, and the HCLK The HCLK (L) terminal is connected to the (B) terminal, and the HDATA (L) terminal is connected to the HDATA (B) terminal. Signals input to or output from each lens-side terminal correspond to the body-side terminal with which it comes into contact.

The LDET (L) terminal is a terminal used to detect attachment and detachment of the interchangeable lens 3. The LDET (L) terminal is connected to ground (GND) via a resistor R3. When the interchangeable lens 3 is attached to the camera body 2, the LDET (L) terminal and the LDET (B) terminal are electrically connected, and the LDET (B) terminal is pulled down. This allows the camera body 2 to detect that the interchangeable lens 3 is attached.

The VBAT (L) terminal, PGND (L) terminal, V33 (L) terminal, and GND (L) terminal are connected to the VBAT (B) terminal, PGND (B) terminal, V33 (B) terminal, and GND (B) terminal, respectively. This is a power supply system terminal that is electrically connected. In FIG. 2, arrows indicate the direction of the supplied power. The drive unit 37 of the interchangeable lens 3 is driven by the power supplied via the VBAT(L) terminal. The PGND (L) terminal is a ground terminal corresponding to the VBAT (L) terminal, and is used as a ground potential (ground) for the power supply voltage of the drive system. A so-called bypass capacitor C1 is connected between the VBAT (L) terminal and the PGND (L) terminal.

The V33 (L) terminal is a terminal used to supply power to the interchangeable lens 3. The V33 (L) terminal and the GND (L) terminal are connected to various parts such as the lens side control section 33. The lens-side control section 33 and the like are operated by power supplied from the power supply section 26 via the V33(B) terminal. The GND (L) terminal is a ground terminal corresponding to the V33 (B) terminal, and is used as a ground potential (ground) for the power supply voltage of the circuit system. A bypass capacitor C2 is connected between the V33 (L) terminal and the GND (L) terminal.

The RDY (L) terminal is connected to the body side communication section 24 via the RDY (B) terminal. The DATAB (L) terminal, CLK (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal are the DATAB (B) terminal, CLK (B) terminal, DATAL (B) terminal, respectively. This is a communication terminal electrically connected to the HCLK (B) terminal and the HDATA (B) terminal. The RDY (L) terminal, DATAB (L) terminal, CLK (L) terminal, and DATAL (L) terminal are used for command data communication, which will be described later. Further, the HCLK (L) terminal and the HDATA (L) terminal are used for hotline communication, which will be described later.

The VBAT (L) terminal and the PGND (L) terminal are connected to the drive section 37 via the lens side control section 33. The V33 (L) terminal and the GND (L) terminal are connected to various parts such as the lens side control section 33. The RDY (L) terminal, DATAB (L) terminal, CLK (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal are each connected to the lens side communication section 34.

(Explanation of command data communication)
Control instructions (commands) and control contents (control data) are transmitted from the body side control section 23 to the lens side control section 33 of the interchangeable lens 3, and response contents (response data) are sent from the lens side control section 33 to the body side control section 23. The transmission of command data and other data is called command data communication. Command data communication is full duplex communication. Command data communication is performed via the body side communication section 24 and the lens side communication section 34 to the RDY (B) terminal, RDY (L) terminal, DATAB (B) terminal, DATAB (L) terminal, CLK (B) terminal, CLK This is done by digital data communication using the (L) terminal, DATAL (B) terminal, and DATAL (L) terminal.

The body-side control unit 23 transmits various control commands and control contents to the interchangeable lens 3 through command data communication via the body-side communication unit 24 and the lens-side communication unit 34, and receives response contents and other information from the interchangeable lens 3. Various information is transmitted and received between the interchangeable lens 3 and the interchangeable lens 3 by receiving data and the like. The control command here is, for example, a command to transmit lens information. The various information received from the interchangeable lens 3 includes, for example, model information of the interchangeable lens 3, information indicating optical characteristics such as the focal length of the imaging optical system 36, and the like. The various information transmitted to the interchangeable lens 3 includes, for example, control commands such as lens drive instructions, control details such as the amount of lens drive, and model information of the camera body 2. The control command also includes a drive command for the focus lens 36b. The lens side control unit 33 receives various control commands from the body side control unit 23 through command data communication, acquires control contents from the body side control unit 23, and sends response contents (for example, In response to an initialization control command from the camera body 2, information regarding the execution status of the initialization process, such as during initialization or completion of initialization, is transmitted.

FIG. 3 is an example of a timing chart showing the timing of command data communication. At the start of command data communication (T1), the body-side control unit 23 first checks the signal level of the RDY (B) terminal. The signal level of the RDY(B) terminal indicates whether command data communication of the lens side control unit 33 is possible. When the lens-side control unit 33 is in a state where command data communication cannot be performed, the lens side control unit 33 sets the signal level (potential) of the RDY (L) terminal to a high level (H level). When the lens side control unit 33 is in a state where command data communication can be performed, the lens side control unit 33 sets the signal level (potential) of the RDY (L) terminal to a low level (L level) via the lens side communication unit 34.

At the start of command data communication (T1), if the signal level of the RDY (B) terminal is low level (L level), the body side control unit 23 transmits the signal from the CLK (B) terminal via the body side communication unit 24. A C clock signal 401 is output. That is, the body-side control section 23 transmits the C clock signal 401 to the lens-side control section 33 via the CLK (B) terminal and the CLK (L) terminal. The frequency at which the C clock signal 401 in FIG. 3 repeats high and low levels is, for example, 8 MHz. The body-side control unit 23 outputs a body-side command signal 402, which is a control command, from the DATAB (B) terminal in synchronization with the C clock signal 401. That is, the body-side control section 23 transmits the body-side command signal 402 to the lens-side control section 33 via the DATAB (B) terminal and the DATAB (L) terminal. The body side command signal 402 shown by switching between high level and low level of DATAB in FIG. 3 is a signal representing control that the body side control unit 23 instructs the lens side control unit 33 through command data communication. For example, the body-side command signal 402 is a signal representing a request for model information of the interchangeable lens 3, or a signal representing an instruction to drive the focus lens 36b. As shown in FIG. 3, the timing at which the body-side command signal 402 is transmitted is different from the cycle of the C clock signal 401. The command signal 402 is periodically transmitted at a minimum interval of about 8 milliseconds in the case of initialization processing performed when the camera system 1 is powered on (power-on) or termination processing performed when the power is turned off. However, other than that, it is sent at any timing.

When the lens-side control unit 33 receives the body-side command signal 402 via the lens-side communication unit 34, the lens-side control unit 33 uses the error detection code (for example, checksum data, etc.) included in the body-side command signal 402 to output the body-side command signal. 402 is executed to check for the presence or absence of a communication error. Thereafter, the lens-side control unit 33 sets the signal level of the RDY (L) terminal to a high level (H level) (T2). The body-side control unit 23 does not transmit the C clock signal or the body-side command signal 402 when the signal level of the RDY (B) terminal is high level.
The lens-side control unit 33 starts the first control process 404 based on the instruction of the received body-side command signal 402.

When the first control process 404 is completed, the lens side control unit 33 sets the signal level of the RDY(L) terminal to a low level (L level) via the lens side communication unit 34 (T3). When the signal level of the RDY (B) terminal becomes low level, the body side control section 23 outputs the C clock signal 405 from the CLK (B) terminal. The frequency at which the C clock signal 405 repeats high and low levels is the same as that of the C clock signal 401, and is, for example, 8 MHz. That is, the body-side control section 23 transmits the C clock signal 405 to the lens-side control section 33 via the CLK (B) terminal and the CLK (L) terminal.
Furthermore, when the signal level of the RDY (B) terminal is at a high level, the body-side control unit 23 does not transmit or receive the body-side data signal 406 and the lens-side data signal 407.

The body-side control section 23 outputs a body-side data signal 406 from the DATAB (B) terminal via the body-side communication section 24 in synchronization with the C clock signal 405 . That is, the body-side control section 23 transmits the body-side data signal 406 to the lens-side control section 33 via the DATAB (B) terminal and the DATAB (L) terminal. Body-side data signal 406 is a signal representing a control parameter of body-side command signal 402. For example, when the body-side command signal 402 is a signal indicating an instruction to drive the focus lens 36b, the corresponding body-side data signal 406 is a signal indicating the amount of drive of the focus lens 36b. Alternatively, the body-side data signal 406 is a signal representing information (camera body model information, etc.) required by the lens-side control unit 33 in command data communication.

Further, when the C clock signal 405 is input to the CLK (L) terminal, the lens side control section 33 outputs the lens side data signal 407 from the DATAL (L) terminal in synchronization with the C clock signal 405. A lens-side data signal 407 shown by switching between high and low levels of DATAL in FIG. 3 is a signal transmitted from the lens-side control section 33 to the body-side control section 23 through command data communication. For example, if the body-side command signal 402 is a signal representing a request for model information of the interchangeable lens 3, the corresponding lens-side data signal 407 is a signal representing model information of the interchangeable lens 3. As shown in FIG. 3, the timing at which the body side data signal 406 and the lens side data signal 407 are transmitted is different from the cycle of the C clock signal 405. The body-side data signal 406 and the lens-side data signal 407 are transmitted for a minimum of about 8 milliseconds in the case of initialization processing performed when the camera system 1 is powered on (power-on) or termination processing performed when the power is turned off. It is sent periodically at intervals, but other than that it is sent at arbitrary timing.

When the transmission of the lens side data signal 407 is completed, the lens side control unit 33 sets the signal level of the RDY (L) terminal to high level again (T4). The lens-side control unit 33 starts a second control process 408 (described later) based on the instruction of the received body-side data signal 406.

Here, the first control process 404 and the second control process 408 performed by the lens-side control unit 33 will be described. For example, a case will be described in which the received body-side command signal 402 requests specific information about the interchangeable lens 3. The lens-side control unit 33 executes a process of generating requested information as a lens-side data signal 407 as a first control process 404 . The lens-side data signal 407 generated in the first control process 404 is transmitted to the body-side communication unit 24 of the body-side control unit 23 via the lens-side communication unit 34, the DATAL (L) terminal, and the DATAL (B) terminal. be done.

For example, a case will be described in which the received body-side command signal 402 is a signal indicating an instruction to drive the focus lens 36b. As a first control process 404, the lens-side control unit 33 executes a process of generating a signal indicating that a signal indicating an instruction to drive the focus lens 36b has been received. The signal generated in the first control process 404 is transmitted as a lens-side data signal 407 to the body-side communication unit of the body-side control unit 23 via the lens-side communication unit 34, the DATAL (L) terminal, and the DATAL (B) terminal. 24. As a second control process 408, the lens side control unit 33 executes a process of driving the lens by the drive amount specified by the body side data signal 406.

When the second control process 408 is completed, the lens side control unit 33 sets the RDY(L) terminal to a low level via the lens side communication unit 34 (T5).

The communication performed at timings T1 to T5 described above is one command data communication. In one command data communication, the body side control unit 23 transmits a body side command signal 402 and a body side data signal 406. That is, the body-side command signal 402 and the body-side data signal 406 together constitute one control instruction (command) and control contents (control data).

As described above, the lens-side control unit 33 receives control instructions (commands) and control contents (control data) from the body-side control unit 23, and transmits response contents (response data) to the body-side communication unit 24. Do this in parallel. In other words, command data communication is so-called full-duplex communication.

(Explanation of hotline communication)
Another communication system is communication in which data is sent in one direction from the lens-side control section 33 of the interchangeable lens 3 to the body-side control section 23 of the camera body 2, and this is called hotline communication. In hotline communication, the body-side control section 23 and the lens-side control section 33 communicate with each other via the body-side communication section 24 and the lens-side communication section 34 at the HCLK (B) terminal, HCLK (L) terminal, and HDATA (B) terminal. , and the HDATA (L) terminal. The body-side control unit 23 acquires information regarding the state of the interchangeable lens 3 from the lens-side control unit 33 of the interchangeable lens 3 through hotline communication. The information regarding the state of the interchangeable lens 3 includes, for example, the position of the focus lens 36b, the position of an image stabilization lens (not shown), the driving position of the aperture blades, and the like. The image stabilization lens is a member that can be moved (driven) to include a component perpendicular to the optical axis direction, and the diaphragm is a member that can be moved (driven) to change the size of the aperture through which the light flux passes. ) is a possible member. When this hotline communication is sent from the camera body via command data communication, the lens side is controlled independently of the command data communication until an instruction to end communication is sent. This is communication in which the unit 33 autonomously transmits lens data to the body-side control unit 23.

FIG. 4 is an example of a timing chart showing the timing of hotline communication. When the lens-side control unit 33 receives a command to start hotline communication from the body-side control unit 23 of the camera body through command data communication (T6), it performs a generation process 501. The generation process 501 is a process that acquires the state of the lens at a sampling period of, for example, 1 millisecond, and generates a lens signal 503 for hotline communication. When the generation of the lens signal 503 is completed (T7), the lens side control section 33 outputs the H clock signal 502 from the HCLK (L) terminal via the lens side communication section 34. That is, the H clock signal 502 is transmitted to the body-side control unit 23 via the HCLK (L) terminal and the HCLK (B) terminal. The frequency at which the H clock signal 502 in FIG. 4 repeats high and low levels is, for example, 2.5 MHz to 8 MHz. That is, the frequency of the H clock signal 502 for hotline communication is the same as or lower than the frequency of the C clock signal 401 for command data communication. That is, the cycle of the H clock signal 502 for hotline communication is the same as or longer than the cycle of the C clock signal 401 for command data communication.

The lens side control unit 33 transmits the lens signal 503 (for example, information regarding the position of the focus lens 36b) generated in the generation process 501 from the HDATA (L) terminal via the lens side communication unit 34 in synchronization with the H clock signal 502. Output. That is, the lens side control section 33 transmits the lens signal 503 to the body side communication section 24 of the body side control section 23 via the lens side communication section 34, the HDATA (L) terminal, and the HDATA (B) terminal. A lens signal 503 shown by HDATA switching between high level and low level in FIG. 4 is a signal transmitted from the lens side control unit 33 to the body side control unit 23 through hotline communication. The output of the H clock signal 502 and lens signal 503 ends at timing T8.
The lens-side control unit 33 repeats transmission of lens data through hotline communication at regular intervals (for example, 1 millisecond) until it receives an instruction to stop transmission of the lens signal 503 through command data communication. As shown in FIG. 4, the timing at which lens data is transmitted by hotline communication is different from the cycle of the H clock signal 502. The transmission interval of lens data by hotline communication is shorter than the transmission/reception interval of control commands (commands) and control contents (control data) by the above-mentioned command data communication.

Command data communication and hotline communication can be partially or completely executed in parallel. That is, the body-side control section 23 and the lens-side control section 33 can start and end hotline communication while performing command data communication. It is also possible to start and end command data communication while hotline communication is in progress.

As explained above, hotline communication is performed independently of command communication. The lens-side control unit 33 transmits information regarding the state of the interchangeable lens 3 to the body-side control unit 23 by hotline communication, regardless of command communication. Therefore, the body-side control unit 23 can continuously grasp the state of the interchangeable lens 3 even during command communication. Therefore, the body-side control unit 23 can continuously grasp the position of the focus lens 36b, and therefore can control autofocus at high speed, for example. The same applies to image stabilization control and aperture control.
Further, the body-side control unit 23 can issue various instructions to the interchangeable lens 3 at any timing by command communication even while the lens-side control unit 33 is performing hotline communication.

(Explanation of lens mount mechanism)
The camera system 1 of this embodiment includes a so-called bayonet type lens mount mechanism. Hereinafter, the body side mount 21 of the camera body 2 and the lens side mount 31 of the interchangeable lens 3 will be explained in order.

FIG. 5A is a diagram schematically showing the mount of the camera body 2 viewed from the interchangeable lens 3 side. The camera body 2 includes the body-side mount 21 and the body-side terminal holding portion 22 described above in FIG. The body side mount 21 has an annular reference surface having a constant width. Further, the body-side mount 21 has a first body-side claw portion 29a, a second body-side claw portion 29b, a third body-side claw portion 29c, and a fourth body-side claw portion 29d. In the following description, these four claws will be collectively referred to as body-side claws 29.

The body-side claw portions 29 are arranged along the circular opening of the body-side mount 21 at intervals. As shown in FIG. 5(a), the body side first claw part 29a is at the upper right position, the body side second claw part 29b is at the upper left position, the body side third claw part 29c is at the lower left position, and the body side first claw part 29a is at the upper left position. The fourth side claw portions 29d are respectively arranged at the lower right position.

The circumferential lengths of the body-side first claw portion 29a to the body-side fourth claw portion 29d are different from each other. Specifically, the body side first claw part 29a is the longest, the body side third claw part 29c is the second longest, the body side fourth claw part 29d is the third longest, and the body side second claw part 29b is the longest. Shortest.

The body-side claw portion 29 protrudes from the body-side mount 21 toward the center of the opening, and on the circumference of the opening, there are a portion where the body-side claw portion 29 exists and a portion where the body-side claw portion 29 does not exist. . In the following description, a space 40a between the body-side first claw part 29a and the body-side fourth claw part 29d on the circumference of the opening of the body-side mount 21 is referred to as a body-side first insertion/extraction part 40a. Similarly, the space 40b between the body-side first claw part 29a and the body-side second claw part 29b is replaced by the body-side second insertion/extraction part 40b, and the body-side second claw part 29b and the body-side third claw part 29c. The space 40c between them is called a body-side third insertion/extraction part 40c, and the space 40d between the body-side third claw part 29c and the body-side fourth claw part 29d is called a body-side fourth insertion/extraction part 40d. These four body-side insertion/extraction parts are collectively referred to as body-side insertion/extraction parts 40.

A body-side terminal holding portion 22 is provided inside the opening of the body-side mount 21 . The body-side terminal holding portion 22 has an arcuate shape corresponding to the shape of the annular body-side mount 21 . The body-side terminal holding portion 22 is disposed above the opening of the body-side mount 21 in parallel with the opening of the body-side mount 21, and is preferably disposed at the center of the top as shown in FIG. 5(a). The body-side terminal holding portion 22 has a plurality of body-side terminals as described above. The plurality of body-side terminals are arranged in the body-side terminal holding portion 22 in a line inside the body-side mount 21 in an arc shape. As shown in FIG. 5(a), the multiple body side terminals are HDATA (B), HCLK (B), DATAL (B), CLK (B), DATAB (B), RDY (B), and GND (from the right side). Eleven terminals are arranged: B), V33 (B), PGND (B), VBAT (B), and LDET (B) on the leftmost side. Each of the body-side terminal groups is a conductive pin. The body side terminal group is pushed toward the -Z direction (FIG. 1) by a spring or the like (not shown). -The Z direction is the direction toward the interchangeable lens 3 attached to the camera, and is the direction toward the subject.

The body side mount 21 has a hole through which the lock pin 42 passes. The hole through which the lock pin 42 passes is located at the upper right of the fourth body-side claw portion 29d. That is, in the annular reference plane of the body-side mount 21, the hole of the lock pin 42 is located in the area where the body-side fourth claw part 29d exists and the body-side first claw part 29a exists in the opening of the body-side mount 21. placed between the areas. The lock pin 42 is pushed toward the -Z direction (FIG. 1) by a spring or the like (not shown).

FIG. 5(b) is a schematic diagram of the mount of the camera body 2 with the body-side mount 21 removed, viewed from the interchangeable lens 3 side. A first plate spring 41a is provided at a position corresponding to the body-side first claw portion 29a (on the back side of the body-side first claw portion 29a). Similarly, a second leaf spring 41b is provided at a position corresponding to the body-side second claw part 29b (on the back side of the body-side second claw part 29b), and a second plate spring 41b is provided at a position corresponding to the body-side third claw part 29c (the back side of the body-side second claw part 29b). A third plate spring 41c is provided on the back side of the third side claw part 29c, and a fourth plate spring 41c is provided at a position corresponding to the body side fourth claw part 29d (on the back side of the body side fourth claw part 29d). 41d is provided. In the following description, these four leaf springs are collectively referred to as leaf springs 41. The leaf spring 41 presses a lens-side claw portion, which will be described later, in the +Z direction (toward the camera body 2 side).

FIG. 6 is a diagram schematically showing the mount of the interchangeable lens 3 viewed from the camera body 2 side. The interchangeable lens 3 includes the lens-side mount 31 and the lens-side terminal holding section 32 described above in FIG. The lens side mount 31 has an annular reference surface having a constant width. When the interchangeable lens 3 is attached to the camera body 2, the annular reference surface of the lens side mount 31 comes into contact with the annular reference surface of the body side mount 21 described above. Furthermore, the lens side mount 31 has a cylindrical portion extending in the optical axis direction on its inner periphery. The lens-side mount 31 includes a first lens-side claw 39a, a second lens-side claw 39b, a third lens-side claw 39c, and a fourth lens-side claw at intervals along the outer circumference of its cylindrical portion. It has 39d. In the following description, these four claws will be collectively referred to as lens-side claws 39.

The lens-side claw portion 39 is provided in a direction that projects from the outer periphery of the cylindrical portion of the lens-side mount 31 toward the outside of the mount (radial direction from the optical axis O). As shown in FIG. 6, the first lens-side claw 39a is located at the upper left position, the second lens-side claw 39b is located at the upper right, the third lens-side claw 39c is located at the lower right, and the lens-side third claw 39c is located at the lower right. The four claw portions 39d are respectively arranged at the lower left position. On the rear side of the lens-side claw part 39 (on the reference surface side of the lens-side mount 31), there is a space into which the corresponding body-side claw part 29 enters when the interchangeable lens 3 is mounted on the camera body 2.

A lens-side terminal holding portion 32 is provided inside the opening of the lens-side mount 31 . The lens-side terminal holding portion 32 has an arcuate shape corresponding to the shape of the annular lens-side mount 31 . The lens-side terminal holding portion 32 is preferably arranged at the upper part of the lens-side mount 31 in parallel with the opening of the lens-side mount 31, and is preferably arranged at the center of the upper part as shown in FIG. The lens-side terminal holding portion 32 has a plurality of lens-side terminals as described above. The plurality of lens-side terminals are arranged in a circular arc shape in the lens-side terminal holding portion 32 inside the lens-side mount 31 in a line. As shown in FIG. 6, from the right side, the multiple lens side terminals are LDET (L), VBAT (L), PGND (L), V33 (L), GND (L), RDY (L), DATAB (L), Eleven terminals are arranged: CLK (L), DATAL (L), HCLK (L), and HDATA (L). The lens side terminal group is arranged so that each conductive contact surface is exposed toward the +Z direction (FIG. 1). The +Z direction is, in other words, the direction in which the subject light that has passed through the imaging optical system 36 heads toward the imaging element 27 .

The lens side mount 31 has a lock pin receiving portion 43 . As shown in FIG. 6, the lock pin receiving part 43 is arranged at the upper left of the lens-side fourth claw part 39d. That is, the lock pin receiving portion 43 is arranged between a portion of the lens-side mount 31 corresponding to the first lens-side claw portion 39a and a portion corresponding to the fourth lens-side claw portion 39d. The lock pin receiving portion 43 is a groove in which the lock pin 42 is accommodated when the interchangeable lens 3 is attached to the camera body 2. This groove is provided toward the −Z direction (FIG. 1).

When the interchangeable lens 3 is attached to the camera body 2, the plurality of body-side terminals physically contact the corresponding plurality of lens-side terminals. This contact electrically connects the plurality of body-side terminals and the plurality of lens-side terminals. That is, the plurality of body-side terminals and the plurality of lens-side terminals are electrically connected.

(Installing interchangeable lenses)
A method for attaching the interchangeable lens 3 to the camera body 2 will be explained. When attaching the interchangeable lens 3 to the camera body 2, first make the body side mount 21 and the lens side mount 31 face each other, align the lens side first claw part 39a with the body side first insertion/removal part 40a, and then Align the claw part 39b with the position of the body-side second insertion/extraction part 40b, align the lens-side third claw part 39c with the position of the body-side third insertion/extraction part 40c, and align the lens-side fourth claw part 39d with the body-side fourth insertion/extraction part. Adjust to position 40d. Then, the lens side first claw part 39a is inserted into the body side first insertion/extraction part 40a, the lens side second claw part 39b is inserted into the body side second insertion/extraction part 40b, and the lens side third claw part 39c is inserted into the body side It is inserted into the third insertion/extraction part 40c, and the lens-side fourth claw part 39d is inserted into the body-side fourth insertion/extraction part 40d. At this time, the LDET (L) terminal becomes the CLK (B) terminal, the VBAT (L) terminal becomes the DATAL (B) terminal, the PGND (L) terminal becomes the HCLK (B) terminal, and the V33 (L) terminal becomes the HDATA ( B) Contact each terminal.

From this state, the interchangeable lens 3 is rotated in the mounting direction 44 shown in FIGS. 5 and 6. That is, the body side first claw part 29a enters the space on the back side of the lens side first claw part 39a, the body side second claw part 29b enters the space on the back side of the lens side second claw part 39b, and the body side The third claw portion 29c enters into the space behind the lens-side third claw portion 39c, and the body-side fourth claw portion 29d enters into the space behind the lens-side fourth claw portion 39d. At this time, the plurality of lens-side terminals come into contact with the plurality of body-side terminals in order. Note that the camera body 2 instead of the interchangeable lens 3 may be rotated in a direction opposite to the mounting direction 44 shown in FIGS. 5 and 6.

When the lens-side claw parts 39 are inserted into the corresponding body-side insertion/extraction parts 40 and rotated in the mounting direction 44, the LDET (L) terminal, for example, becomes the CLK (B) terminal, the DATAB (B) terminal, and the RDY (B) terminal. terminal, GND (B) terminal, V33 (B) terminal, PGND (B) terminal, VBAT (B) terminal, and LDET (B) terminal in this order. For example, the VBAT (L) terminal includes the DATAL (B) terminal, CLK (B) terminal, DATAB (B) terminal, RDY (B) terminal, GND (B) terminal, V33 (B) terminal, PGND (B) terminal, Contact the VBAT (B) terminals in sequence. For example, the PGND (L) terminal is the HCLK (B) terminal, DATAL (B) terminal, CLK (B) terminal, DATAB (B) terminal, RDY (B) terminal, GND (B) terminal, V33 (B) terminal, PGND (B) Contact the terminals in sequence. For example, the V33 (L) terminal is the HDATA (B) terminal, HCLK (B) terminal, DATAL (B) terminal, CLK (B) terminal, DATAB (B) terminal, RDY (B) terminal, GND (B) terminal, V33 (B) Contact the terminals in sequence. For example, the GND (L) terminal is connected to the HDATA (B) terminal, HCLK (B) terminal, DATAL (B) terminal, CLK (B) terminal, DATAB (B) terminal, RDY (B) terminal, and GND (B) terminal in this order. Contact.

For example, the RDY (L) terminal contacts the HDATA (B) terminal, the HCLK (B) terminal, the DATAL (B) terminal, the CLK (B) terminal, the DATAB (B) terminal, and the RDY (B) terminal in this order. For example, the DATAB (L) terminal contacts the HDATA (B) terminal, the HCLK (B) terminal, the DATAL (B) terminal, the CLK (B) terminal, and the DATAB (B) terminal in this order. For example, the CLK (L) terminal contacts the HDATA (B) terminal, the HCLK (B) terminal, the DATAL (B) terminal, and the CLK (B) terminal in this order. For example, the DATAL (L) terminal contacts the HDATA (B) terminal, the HCLK (B) terminal, and the DATAL (B) terminal in this order. For example, the HCLK (L) terminal contacts the HDATA (B) terminal and then the HCLK (B) terminal in this order.

When the interchangeable lens 3 is rotated by a predetermined angle with respect to the camera body 2, the attachment completion position is reached. At the mounting completion position, the corresponding body-side claw portion 29 and lens-side claw portion 39 face each other in the optical axis direction, and the lock pin 42 is pushed in the −Z direction in FIG. 1 and enters the lock pin receiving portion 43. When the lock pin 42 enters the lock pin receiving portion 43, the interchangeable lens 3 cannot be rotated to be removed from the camera body 2. That is, when the body-side claw portion 29 and the lens-side claw portion 39 reach the predetermined mounting completion position, the relative positions of the body-side mount 21 and the lens-side mount 31 are fixed. The lens-side claw portion 39 is pushed toward the body (+Z direction in FIG. 1) by the leaf spring 41. As a result, each of the plurality of lens-side terminals comes into contact with each of the corresponding plurality of body-side terminals, and is electrically connected.

In the following description, the state in which the body-side claw portion 29 and the lens-side claw portion 39 have reached a predetermined mounting completion position will be referred to as a mounting completion state. During mounting, the lens-side claw portion 39 is being rotated from the position where it is inserted into the body-side insertion/extraction portion 40 to just before the mounting completion position, or it is being rotated from just before the mounting completion position to the insertion position. It's called a state.

During the mounting state, the signal level of the LDET (B) terminal is pulled up and is at a high level. The body-side control unit 23 determines that the interchangeable lens 3 is not attached when it is detected that the signal level of the LDET (B) terminal is at a high level. The body-side control unit 23 prevents the power supply unit 26 from supplying power to the VBAT (B) terminal and the V33 (B) terminal when the interchangeable lens 3 is not attached.

When the attachment is completed, the signal level of the LDET (B) terminal is pulled down to low level as described above (FIG. 2). When it is detected that the signal level of the LDET (B) terminal becomes low level, the body-side control unit 23 determines that the interchangeable lens 3 is attached. Further, when the attachment is completed, the lock pin 42 enters the lock pin receiving portion 43, and the switch 28 (FIG. 1) interlocked with the lock pin 42 is turned on. When the body-side control unit 23 detects that the signal level of the LDET (B) terminal becomes low level and that the switch 28 is turned on, the body side control unit 23 starts supplying power to the V33 (B) terminal in the power supply unit 26. In other words, the power supply voltage for the circuit system is supplied. Note that the camera body 2 does not necessarily have to include the switch 28. If the switch 28 is not provided, the power supply section 26 may start supplying power to the V33 (B) terminal when it is detected that the signal level of the LDET (B) terminal becomes low level.

When the power supply to the V33 (B) terminal is started, the power supply voltage is supplied to the lens side control section 33 of the interchangeable lens 3 through the V33 (L) terminal, and the lens side control section 33 starts operating. . The lens-side control unit 33 that has started operating permits initial communication by command data communication with the body-side control unit 23. After the lens-side control unit 33 permits initial communication, the body-side control unit 23 starts initial communication. The initial communication includes a signal requesting the lens-side control unit 33 to supply power to the VBAT(L) terminal. When a signal requesting power supply to the VBAT (L) terminal is transmitted from the lens side control section 33 to the body side control section 23, the body side control section 23 supplies the power supply voltage to the VBAT (B) terminal, Initialization processing between the camera body 2 and the interchangeable lens 3 is performed. In the initialization process, information necessary for various operations of the camera system 1, such as shooting operations and focus adjustment operations, is exchanged between the camera body 2 and the interchangeable lens 3, and the lens position of the interchangeable lens is moved to a reference position. I do things.

When the user presses a lock release button (not shown) on the camera body when the mounting is completed, the lock pin 42 is retracted from the lock pin receiving portion 43. Thereby, the relative position between the body side mount 21 and the lens side mount 31 can be changed. In the body-side control unit 23, when the user presses a lock release button (not shown), a switch 28 linked to the lock release button turns off, causing the power supply unit 26 to supply power to the VBAT (B) terminal and the V33 (B) terminal. make it stop. From this state, when the interchangeable lens 3 is rotated in a direction opposite to the mounting direction 44 shown in FIGS. 5 and 6, the plurality of lens-side terminals come into contact with the plurality of body-side terminals in the reverse order to that described above. To go.

Note that the power supply does not have to be stopped in conjunction with the operation of the lock release button. In this case, the body-side control unit 23 causes the LDET (L) terminal and the LDET (B) terminal to separate from each other by rotating the interchangeable lens 3 in the opposite direction to the mounting direction 44, and the signal level of the LDET (B) terminal changes from the low level. When a change to the high level is detected, the power supply unit 26 is made to stop supplying power to the VBAT (B) terminal and the V33 (B) terminal. By doing so, the number of parts of the camera system 1 can be reduced. In addition, when it is detected that the lock release button is pressed and the signal level of the LDET (B) terminal changes from low level to high level, the VBAT (B) terminal and V33 (B) terminal are connected to the power supply unit 26. The power supply to the terminal may be stopped. Alternatively, when detecting either that the lock release button is pressed or that the signal level of the LDET (B) terminal changes from a low level to a high level, the body side control unit 23 sends the power supply unit 26 to the VBAT The power supply to the (B) terminal and the V33 (B) terminal may be stopped.

As described above, while the interchangeable lens is being attached to and removed from the camera body (attachment state), the lens-side terminal comes into contact with a body-side terminal other than the terminal that should correspond when the attachment is completed. It is desirable that the arrangement of the lens-side terminals and the body-side terminals is such that there are few problems caused by contact during attachment and removal.

(Terminal placement considering noise)
In this embodiment, the LDET (B) terminal among the plurality of body-side terminals is arranged at the leading edge in the lens mounting direction (arrow 44 in FIG. 5(a)). That is, the arrangement position of the LDET (B) terminal is the leftmost side of the body side terminal group in FIG. 5(a), as described above. Among the plurality of lens-side terminals, the LDET (L) terminal was similarly arranged at the leading edge in the lens mounting direction (arrow 44 in FIG. 6). That is, the arrangement position of the LDET (L) terminal is the rightmost side of the lens side terminal group in FIG. 6, as described above. Therefore, the LDET (B) terminal does not come into contact with any lens-side terminal other than the LDET (L) terminal until the attachment of the attached lens is completed. Therefore, in the process of attaching an interchangeable lens, the signal level of the LDET (B) terminal will not erroneously become low level, and the attachment of the lens will not be erroneously recognized.

In this embodiment, the VBAT (B) terminal is placed next to the LDET (B) terminal, that is, the second from the most distal end in the mounting direction. The VBAT(L) terminal was placed next to the LDET(L) terminal, that is, the second from the leading edge in the mounting direction. This is done in order to reduce the number of lens-side terminals with which the camera body-side VBAT (B) terminal comes into contact during the lens mounting process. The drive system power supply voltage applied to the VBAT (B) terminal is higher than other terminals, so if a high voltage is accidentally applied to the VBAT (B) terminal due to a malfunction in camera system 1, etc., the VBAT (B) If the terminal comes into contact with a terminal other than the VBAT (L) terminal, there is a risk that this high voltage will put an unexpected load on the electrical circuit inside the interchangeable lens. In this embodiment, the VBAT (B) terminal is located next to the LDET (B) terminal, so when the interchangeable lens 3 is attached, only one of the plurality of lens side terminals is connected to the VBAT (B) terminal. Only the LDET (L) terminal makes contact. As shown in FIG. 2, the LDET (L) terminal is grounded through the resistor R3, and even if a high voltage is applied from the VBAT (B) terminal, it will not affect the camera system 1.

In this embodiment, the PGND (B) terminal, which is at the ground potential, is placed next to the VBAT (B) terminal, that is, third from the leading edge in the mounting direction. The PGND (L) terminal was placed next to the VBAT (L) terminal, that is, the third from the leading edge in the mounting direction. The high voltage supplied from the VBAT (B) terminal is stored in the capacitor C1 connected to the VBAT (L) terminal. When the interchangeable lens 3 is rotated in the removal direction, the VBAT (L) terminal first contacts the PGND (B) terminal. The charge accumulated in the capacitor C1 is quickly discharged from the PGND (B) terminal, which is at ground potential, and does not affect other circuits of the camera system 1.

In this embodiment, the V33 (B) terminal is placed next to the PGND (B) terminal, that is, the fourth from the leading edge in the mounting direction, and the GND (B) terminal is placed next to it, that is, the fifth from the leading edge. did. The V33 (L) terminal was placed next to the PGND (L) terminal, that is, the fourth from the leading edge in the mounting direction, and the GND (L) terminal was placed next to it, that is, the fifth from the leading edge. The voltage supplied from the V33 (B) terminal is stored in the capacitor C2 connected to the V33 (L) terminal. When the interchangeable lens 3 is rotated in the removal direction, the V33 (L) terminal first contacts the GND (B) terminal. The charge accumulated in the capacitor C2 is quickly discharged from the GND (B) terminal, which is at ground potential, and does not affect other circuits of the camera system 1.

Arrange the RDY (B) terminal next to the GND (B) terminal, that is, the 6th from the leading edge, and place the DATAB (B) terminal next to it, that is, the 7th from the leading edge. The CLK (B) terminal is placed at the 8th position, the DATAL (B) terminal is placed next to it, that is, the 9th position from the leading edge, and the HCLK (B) terminal is placed next to it, that is, the 10th position from the leading edge. , and the HDATA (B) terminal was placed next to it at the rearmost end.

Arrange the RDY (L) terminal next to the GND (L) terminal, that is, the sixth from the leading edge, and place the DATAB (L) terminal next to it, that is, the seventh from the leading edge, and place the RDY (L) terminal next to it, that is, the seventh from the leading edge. The CLK (L) terminal is placed at the 8th position, the DATAL (L) terminal is placed next to it, that is, the 9th position from the leading edge, and the HCLK (L) terminal is placed next to it, that is, the 10th position from the leading edge. , the HDATA (L) terminal was placed next to it at the rearmost end.

Next, the influence of noise exerted by the communication line constituted by each body-side terminal and each lens-side terminal will be described. Hotline communication is communication in which information (lens data) is unilaterally transmitted to the body after communication is started, and is performed frequently (repeatedly at very short intervals). During hotline communication, a clock signal (H clock signal) is sent from the HCLK (L) terminal to the HCLK (B) terminal. Since the clock signal is a signal that repeats high and low levels in a short period, it can become a large noise source for other signals. Furthermore, since the clock signal sent from the HCLK (L) terminal to the HCLK (B) terminal is the signal output from the interchangeable lens 3, even if noise is mistakenly added to the clock signal, the camera body 2 side will be able to absorb that noise. cannot be recognized. In this way, there is a possibility that the clock signal (H clock signal) flowing through the HCLK terminal becomes a noise source or that noise is added to the clock signal (H clock signal), which may cause the camera system 1 to malfunction. be. Examples of malfunctions include erroneously detecting the attachment of an interchangeable lens and erroneously determining whether command communication is possible.

In this embodiment, the HCLK terminal is placed at a position away from the VBAT terminal to which a high voltage is applied. Since the voltage and current of the VBAT terminal that drives the drive unit 37 of the interchangeable lens 3 vary depending on the driving state of the drive unit 37, fluctuations in the voltage and current of the VBAT terminal may become noise for other terminals. Therefore, by separating the VBAT terminal from the HCLK terminal, it is possible to suppress noise caused by fluctuations in the voltage and current of the VBAT terminal from affecting the clock signal (H clock signal). It is possible to suppress noise from being added to the clock signal (H clock signal).
The RDY terminal is a terminal used to indicate whether command communication is possible. The HCLK terminal, which can be a noise source, is placed apart from the RDY terminal so that it is not adjacent to it. Therefore, it is possible to suppress noise caused by the clock signal (H clock signal) from affecting the signal at the RDY terminal.

Further, an HDATA terminal and a DATAL terminal were arranged on both sides of the HCLK terminal. By doing so, it is possible to suppress the influence of noise on the HCLK terminal on terminals other than the HDATA terminal and DATAL terminal. The signals flowing through the HDATA terminal and the DATAL terminal have less fluctuation than the clock signal (H clock signal). This is because the influence of fluctuations in the clock signal (H clock signal) can be suppressed from reaching terminals other than the HDATA terminal and the DATAL terminal.

Next, command data communication is communication in which information is transmitted and received bidirectionally between the body and the interchangeable lens, as described above. During command data communication, a clock signal (C clock signal) is sent from the CLK (B) terminal to the CLK (L) terminal. The clock signal transmitted at the CLK terminal can also be a source of noise for the same reason as described above. Further, if noise is added to the clock signal (C clock signal), an abnormality will occur in command communication. Therefore, in this embodiment, the CLK terminal is placed at a position away from the VBAT terminal to which a high voltage is applied. Since the voltage and current of the VBAT terminal that drives the drive unit 37 of the interchangeable lens 3 vary depending on the driving state of the drive unit 37, fluctuations in the voltage and current of the VBAT terminal may become noise for other terminals. Therefore, by separating the VBAT terminal from the CLK terminal, it is possible to suppress the influence of noise at the VBAT terminal on the clock signal (C clock signal). That is, it is possible to suppress noise from being added to the clock signal (C clock signal).
Further, the CLK terminal is placed apart from the RDY terminal, which is used to indicate whether command communication is possible, so as not to be adjacent to it.

Furthermore, if the HCLK terminal and the CLK terminal are placed adjacent to each other, one clock signal may affect the other clock signal and become a noise source. In this embodiment, the DATAL terminal is arranged between the CLK terminal and the HCLK terminal. Further, a DATAB terminal was arranged between the CLK terminal and the RDY terminal. That is, the DATAL terminal and the DATAB terminal are arranged on both sides of the CLK terminal. By doing this, it is possible to suppress the influence of noise caused by the CLK terminal on the camera system. Since the signals flowing through the DATAL and DATAB terminals have less fluctuation than the clock signal (C clock signal), the influence of fluctuations in the clock signal (C clock signal) can be suppressed from reaching terminals other than the DATA and DATAB terminals. It is.
When the DATAL terminal is placed between the CLK terminal and the HCLK terminal, the signal flowing through the DATAL terminal has less fluctuation than the clock signal of the CLK terminal (C clock signal) and the clock signal of the HCLK terminal (H clock signal), so the CLK The influence of fluctuations in the clock signal (C clock signal) at the terminal affects the clock signal (H clock signal) at the HCLK terminal, and the influence due to fluctuations in the clock signal (H clock signal) at the HCLK terminal affects the clock signal (C clock signal) at the CLK terminal. This is because it can prevent the signal from affecting the clock signal).

Furthermore, as described above, in order to perform command data communication, it is necessary to determine the level of the RDY terminal. That is, since the signal level of the RDY terminal indicates whether or not command data can be communicated, the influence of noise on the photographing operation is large. Here, consider a case where the body-side control unit 23 mistakenly recognizes that the communication is possible due to noise even though the command data cannot be communicated. In this case, the lens-side control unit 33 cannot receive the command data, but the body-side control unit 23 transmits the command data, and when the interchangeable lens performs control according to the command data, the body-side control unit 23 misrecognizes the command data. do. However, since the lens-side control unit 33 cannot accept command data, control based on the erroneously transmitted command data is not performed. Therefore, the operation of the camera system 1 is hindered. Therefore, it is necessary to prevent noise from being added to the signal at the RDY terminal. In order to prevent noise from being added to the signal at the RDY terminal, it is desirable to arrange terminals on both sides of the RDY terminal through which a relatively stable signal, that is, a signal whose signal level changes little per unit time, flows. In this embodiment, a GND terminal and a DATAB terminal are arranged on both sides of the RDY terminal. The GND terminal is stable because it is a ground potential terminal, and the DATAB terminal is also a terminal through which a more stable signal flows than the CLK terminal or HCLK terminal. By doing this, it is possible to suppress the influence of noise on the signal at the RDY terminal.

Next, the power (drive system power supply voltage) supplied from the VBAT (B) terminal to the VBAT (L) terminal is used to drive an actuator (for example, a stepping motor, etc.) of the drive unit 37 of the interchangeable lens 3. Therefore, the current flowing to the VBAT terminal varies greatly depending on whether the actuator is being driven or not. Such current fluctuations become a noise source for signals flowing to other terminals. In this embodiment, the VBAT terminal is placed at a position away from the RDY terminal, DATAB terminal, CLK terminal, and DATAL terminal used for command data communication, and the HCLK terminal and HDATA terminal used for hotline communication. Furthermore, a GND terminal, a V33 terminal, and a PGND terminal were arranged between the VBAT terminal and the terminals used for these communications. Among these terminals, the GND terminal and the PGND terminal in particular are terminals at ground potential, so that the influence of noise can be suppressed. This suppresses the influence of noise caused by fluctuations in the current flowing through the VBAT terminal on data communication.

The terminal arrangement considering the noise explained above will be summarized here.
The RDY terminal was placed away from either the VBAT terminal or the HCLK terminal, which are noise sources, so as not to be adjacent to them. This suppresses the influence of noise on the RDY terminal used to indicate whether command communication is possible.
The HCLK terminal, which is a noise source, is sandwiched between the HDATA terminal and the DATA terminal, and the CLK terminal is sandwiched between the DATA terminal and the DATAB terminal. That is, the HDATA terminal, HCLK terminal, DATA terminal, CLK terminal, and DATAB terminal are arranged in order from the rear end in the mounting direction. This suppresses the influence of noise caused by clock signals to the RDY terminal and the like.
Furthermore, in consideration of the influence of noise, the group of terminals for power supply and the group of terminals used for communication are placed apart from each other with the RDY terminal in between. In detail, the VBAT terminal, PGND terminal, V33 terminal, and GND terminal, which are power supply terminals, are arranged in order from the distal end side in the mounting direction across the RDY terminal, and the communication terminal is arranged on the rear end side in the mounting direction. The terminals to be used, DATAB terminal, CLK terminal, DATAL terminal, HCLK terminal, and HDATA terminal, were arranged in order from the tip side. This makes it possible to suppress the influence of the power supply terminal group such as the VBAT terminal on the terminals used for communication. Further, it is possible to suppress the influence of noise on the RDY terminal of the power supply system terminal group such as the VBAT terminal and the terminal group used for communication such as the HCLK terminal and the CLK terminal.

The HCLK terminal to which the clock signal (H clock signal) used for hotline communication is sent and the CLK terminal to which the clock signal (C clock signal) used for command data communication is sent, the HCLK terminal is connected from the VBAT terminal rather than the CLK terminal. placed in a remote location. This is because the clock signal (C clock signal) sent to the interchangeable lens via the CLK terminal is output by the body-side control unit 23 via the body-side communication unit 24, but the HCLK (L clock signal) is sent from the interchangeable lens via the lens-side communication unit 34. ) terminal that is sent to the camera body via the clock signal (H clock signal), the body-side control unit 23 will misrecognize it. This is because the influence on 1 is large.
Regarding the HCLK terminal and the GND terminal, the HCLK terminal is arranged at a position farther from the VBAT terminal than the GND terminal. Furthermore, a PGND terminal was arranged between the GND terminal and the VBAT terminal. Thereby, it is possible to shield noise caused by the VBAT terminal to the HCLK terminal to which the clock signal (H clock signal) used for hotline communication is sent.
Regarding the CLK terminal and the GND terminal, the CLK terminal is arranged at a position farther from the VBAT terminal than the GND terminal. Furthermore, a PGND terminal was arranged between the GND terminal and the VBAT terminal. Thereby, noise caused by the VBAT terminal to the CLK terminal to which a clock signal (C clock signal) used for command data communication is sent can be shielded.

(Terminal arrangement considering wear)
From now on, the contact of each terminal when attaching and detaching the interchangeable lens 3 to and from the camera body 2 will be described.
When attaching the interchangeable lens 3 to the camera body 2, the body side terminals come into contact with the lens side terminals one after another. The same applies when removing the interchangeable lens 3 from the camera body 2. That is, the body-side terminal, which is a pin protruding from the body-side terminal holding portion 22, and the lens-side terminal, which is an exposed conductive contact surface, are rubbed together one after another. Since multiple interchangeable lenses are attached to and removed from one camera body, the body-side terminals are more likely to wear out than the lens-side terminals. In particular, the body-side terminal located closer to the rear end in the mounting direction of the interchangeable lens 3 is rubbed against a larger number of lens-side terminals and is subjected to more friction. Therefore, the wear of the tip of the pin progresses more easily as the body terminal is located closer to the rear end than the body terminal located closer to the tip. Wear of the body-side terminal affects the contact with the lens-side terminal, so there is a risk that data communication may become unstable.
In this embodiment, since the LDET (B) terminal is disposed at the most distal end in the mounting direction, the wear of the LDET (B) terminal is the least. As a result, the LDET (B) terminal and the LDET (L) terminal are in good contact with each other, and there is little possibility that attachment or detachment of the interchangeable lens 3 will be erroneously detected.

As described above, in this embodiment, the CLK(B) terminal and the HCLK(B) terminal are placed at a position away from the VBAT(B) terminal in order to suppress the influence of noise on communication. That is, the VBAT (B) terminal was placed second from the front end in the mounting direction, and the CLK (B) terminal and HCLK (B) terminal were placed on the rear end side away from the VBAT (B) terminal. Therefore, the CLK (B) terminal and the HCLK (B) terminal are subject to more wear than the LDET (B) terminal and the VBAT (B) terminal. In this embodiment, the CLK (B) terminal and the HCLK (B) terminal are arranged immediately adjacent to the body-side first claw portion 29a. That is, the CLK (B) terminal and the HCLK (B) terminal are arranged closer to the inner peripheral edge, which is the inner peripheral edge of the body-side first claw portion 29a, than the VBAT (B) terminal. In other words, the distance between the CLK(B) terminal and the inner periphery of the body-side first claw 29a is shorter than the distance between the VBAT(B) terminal and the inner periphery of the body-side first claw 29a, and the distance between the HCLK(B) ) The distance between the terminal and the inner circumferential edge of the body-side first claw portion 29a is shorter than the distance between the VBAT(B) terminal and the inner circumferential edge of the body-side first claw portion 29a. As described above, the first leaf spring 41a is provided on the back side of the body-side first claw portion 29a, and the first leaf spring 41a presses the lens-side first claw portion 39a in the +Z direction (FIG. 1). From the perspective of the first leaf spring 41a, the distance between the CLK(B) terminal and the first leaf spring 41a and the distance between the HCLK(B) terminal and the first leaf spring 41a are both VBAT( B) It is shorter than the distance between the terminal and the first leaf spring 41a. The LDET (B) terminal is also similar to the VBAT (B) terminal, and the distance between the CLK (B) terminal and the first leaf spring 41a and the distance between the HCLK (B) terminal and the first leaf spring 41a are is also shorter than the distance between the LDET (B) terminal and the first leaf spring 41a. With this arrangement, the CLK (B) terminal and the HCLK (B) terminal are pressed more strongly against the lens side terminal than the VBAT (B) terminal and the LDET (B) terminal.

Also on the lens side, the CLK (L) terminal and the HCLK (L) terminal are arranged closer to the inner peripheral edge of the lens side first claw portion 39a than the VBAT (L) terminal. In other words, the distance between the CLK(L) terminal and the inner periphery of the lens-side first claw 39a is shorter than the distance between the VBAT(L) terminal and the inner periphery of the lens-side first claw 39a, and the distance between the HCLK(L) ) The distance between the terminal and the inner circumferential edge of the lens-side first claw part 39a is shorter than the distance between the VBAT(L) terminal and the inner circumferential edge of the lens-side first claw part 39a. Therefore, the CLK(L) terminal and HCLK(L) terminal located near the lens-side first claw portion 39a are pressed against the corresponding body-side terminals by the first leaf spring 41a when the mounting is completed. The LDET (L) terminal is also the same as the VBAT (L) terminal, and the distance between the CLK (L) terminal and the first leaf spring 41a and the distance between the HCLK (L) terminal and the first leaf spring 41a in the installed state are the same as the VBAT (L) terminal. Both distances are shorter than the distance between the LDET (L) terminal and the first leaf spring 41a. With this configuration, the CLK (L) terminal and the HCLK (L) terminal are pressed against the body side terminal more strongly than the LDET (L) terminal when the mounting is completed. As a result, even if the CLK (B) terminal and the HCLK (B) terminal are worn out, good contact can be maintained, the respective clock signals are stabilized, and stable data communication can be performed. For example, even if a shock is applied to the camera body 2 or the interchangeable lens 3 while maintaining the attached state, the contact between the CLK (B) terminal and the CLK (L) terminal and the contact between the HCLK (B) terminal and the HCLK (L) terminal may occur. Contact will be maintained.

Even if a part of the lens-side first claw part 39a is cut out, the entire protrusion located in the area facing the body-side first claw part 29a and the cut-out part will be cut out on the lens side. This is the first claw part. The notch may be cut out so that the lens side claw part is divided into two or more parts in the circumferential direction, or it may be cut out so that a part of the lens side claw part is cut out. At least a portion may be cut out so that the length in the radial direction is shortened. Further, the length of the lens-side claw portion in the circumferential direction may be changed within a range in which the lens-side claw portion passes through the corresponding body-side insertion/extraction portion. The same applies to the lens-side second claw portion 39b, the lens-side third claw portion 39c, and the lens-side fourth claw portion 39d. Further, the radial thickness of the cylindrical portion can be changed as appropriate, and the cylindrical portion may have a shape in which at least a portion thereof protrudes inward from the cylindrical portion of this embodiment.

As described above, the CLK (B) terminal and the HCLK (B) terminal are subject to more wear than the LDET (B) terminal and the VBAT (B) terminal. In this embodiment, the CLK (B) terminal and the HCLK (B) terminal are arranged immediately adjacent to the body-side first claw portion 29a. That is, the CLK (B) terminal and the HCLK (B) terminal are arranged closer to the inner peripheral edge of the body-side first claw portion 29a than the LDET (B) terminal and the VBAT (B) terminal. In other words, the distance between the CLK (B) terminal and the inner circumference of the body-side first claw portion 29a is longer than the distance between the LDET (B) terminal or the VBAT (B) terminal and the inner circumference of the body-side first claw portion 29a. The distance between the HCLK (B) terminal and the inner circumferential edge of the body-side first claw portion 29a is shorter than the distance between the LDET (B) terminal or the VBAT (B) terminal and the inner circumferential edge of the body-side first claw portion 29a. short. As described above, the first leaf spring 41a is provided on the back side of the body-side first claw portion 29a, and the first leaf spring 41a presses the lens-side first claw portion 39a in the +Z direction (FIG. 1). From the perspective of the first leaf spring 41a, the distance between the CLK(B) terminal and the first leaf spring 41a and the distance between the HCLK(B) terminal and the first leaf spring 41a are both LDET( It is shorter than the distance between the B) terminal or the VBAT (B) terminal and the first leaf spring 41a.

Also on the lens side, the CLK (L) terminal and the HCLK (L) terminal are arranged closer to the inner peripheral edge of the lens side first claw portion 39a than the LDET (L) terminal and the VBAT (L) terminal. In other words, the distance between the CLK (L) terminal and the inner peripheral edge of the lens-side first claw part 39a is longer than the distance between the LDET (L) terminal or the VBAT (L) terminal and the inner peripheral edge of the lens-side first claw part 39a. The distance between the HCLK (L) terminal and the inner circumferential edge of the lens-side first claw part 39a is shorter than the distance between the LDET (L) terminal or the VBAT (L) terminal and the inner circumferential edge of the lens-side first claw part 39a. short. Therefore, the CLK(L) terminal and HCLK(L) terminal near the lens-side first claw portion 39a are pressed against the corresponding body-side terminals by the first leaf spring 41a. With this arrangement, the CLK (B) terminal and the HCLK (B) terminal are pressed more strongly against the lens side terminal than the LDET (B) terminal and the VBAT (B) terminal. As a result, even if the CLK (B) terminal and the HCLK (B) terminal are worn out, good contact can be maintained and stable communication can be achieved. Further, for example, even if an impact is applied to the camera body 2 or the interchangeable lens 3 while maintaining the attached state, the contact between the CLK (B) terminal and the HCLK (B) terminal and the lens side terminal is maintained.

In this embodiment, the CLK(B) terminal and the HCLK(B) terminal are also near the body-side fourth claw portion 29d. That is, the CLK (B) terminal and the HCLK (B) terminal are arranged closer to the body-side fourth claw portion 29d than the VBAT (B) terminal and the LDET (B) terminal. In other words, the distance between the CLK (B) terminal and the body-side fourth claw 29d is shorter than the distance between the VBAT (B) terminal or LDET (B) terminal and the body-side fourth claw 29d, and the distance between the HCLK (B) ) The distance between the terminal and the body-side fourth claw portion 29d is shorter than the distance between the VBAT (B) terminal or the LDET (B) terminal and the body-side fourth claw portion 29d. As described above, the fourth leaf spring 41d is provided on the back side of the fourth body-side claw portion 29d, and the fourth leaf spring 41d presses the lens-side fourth claw portion 39d in the +Z direction (FIG. 1). Therefore, the CLK (B) terminal and HCLK (B) terminal near the lens-side fourth claw portion 39d are connected to the VBAT (B) terminal and the LDET (B) terminal by the first leaf spring 41a and the fourth leaf spring 41d. is also stably and firmly pressed against the lens side terminal.

The distance between the CLK (B) terminal described above and the body-side first claw portion 29a (the fourth body-side claw portion 29d is also the same, but will be omitted below) is the distance between one end of the body-side first claw portion 29a and the body-side first claw portion 29a. This refers to the straight-line distance from the CLK(B) terminal, and may be defined by the straight-line distance between the other end of the body-side first claw portion 29a and the CLK(B) terminal. Alternatively, the distance between the CLK(B) terminal and the body-side first claw portion 29a described above is the intermediate position of the body-side first claw portion 29a in the circumferential direction of the body-side mount 21 and the distance between the CLK(B) terminal and the body-side first claw portion 29a. It may also be defined by the straight distance between the The distances between other body-side terminals such as the HCLK (B) terminal, VBAT (B) terminal, and LDET (B) terminal and the body-side first claw portion 29a are also straight-line distances. The distance between the first leaf spring 41a (fourth leaf spring 41d) and the body-side terminal is also a straight-line distance.

Note that the distance between the CLK (B) terminal described above and the body-side first claw portion 29a (the fourth body-side claw portion 29d is also the same, but will be omitted below) is the distance in the circumferential direction of the body-side mount 21. It may be defined as an arc-shaped distance between one end of the body-side first claw portion 29a and the CLK(B) terminal, or an arc-shaped distance between the other end of the body-side first claw portion 29a and the CLK(B) terminal. It may be defined as distance. Alternatively, the distance between the CLK(B) terminal and the body-side first claw portion 29a described above is the intermediate position of the body-side first claw portion 29a in the circumferential direction of the body-side mount 21 and the distance between the CLK(B) terminal and the body-side first claw portion 29a. It may also be defined as an arcuate distance from The distances between other body-side terminals such as the HCLK (B) terminal, VBAT (B) terminal, and LDET (B) terminal and the body-side first claw portion 29a are also arcuate distances. The distance between the first leaf spring 41a (fourth leaf spring 41d) and the body-side terminal is also an arcuate distance.

Although the above description has been made regarding the camera body 2, the same applies to the interchangeable lens 3. In this embodiment, the CLK(L) terminal and the HCLK(L) terminal are arranged immediately adjacent to the lens-side first claw portion 39a. That is, the CLK (L) terminal and the HCLK (L) terminal are arranged closer to the lens-side first claw portion 39a than the VBAT (L) terminal and the LDET (L) terminal. In other words, the distance between the CLK(L) terminal and the lens-side first claw 39a is shorter than the distance between the VBAT(L) terminal or the LDET(L) terminal and the lens-side first claw 39a, and the distance between the HCLK(L) ) The distance between the terminal and the lens-side first claw portion 39a is shorter than the distance between the VBAT (L) terminal or the LDET (L) terminal and the lens-side first claw portion 39a. The lens-side first claw portion 39a is pressed in the +Z direction (FIG. 1) by the body-side first leaf spring 41a. Therefore, similarly to the above, the CLK (L) terminal and HCLK (L) terminal near the lens side first claw part 39a are connected to the body by the first leaf spring 41a than the VBAT (L) terminal or the LDET (L) terminal. It is pressed strongly against the side terminal.

In this embodiment, as shown in FIG. 5(a), the CLK (B) terminal and the HCLK (B) terminal are connected in a circle with the center position of the opening of the mount 21 (that is, the position of the optical axis O of the interchangeable lens 3). It is arranged inside a fan shape (range of angle 50) formed by the arcuate body-side first claw portion 29a. Alternatively, connect the CLK (B) terminal and the HCLK (B) terminal between the center position of the opening of the mount 21 (that is, the position of the optical axis O of the interchangeable lens 3) and both ends of the inner peripheral side of the first claw part 29a on the body side. placed inside the triangular area formed. Therefore, although the body-side first claw portion 29a does not exist on the extension line of the dashed-dotted line 51 connecting the center position of the opening of the mount 21 and the LDET (B) terminal, the center position of the opening of the mount 21 and the HCLK(B) terminal The body-side first claw portion 29a exists on the extension of the dashed-dotted line 52 connecting the terminal, and the body-side first claw portion 29a exists on the extension of the dashed-dotted line 53 connecting the center position of the opening of the mount 21 and the CLK (B) terminal. One claw portion 29a is present. As a result, in the attachment completion state, the CLK (B) terminal and the HCLK (B) terminal are pressed more strongly against the corresponding lens side terminal than the LDET (B) terminal.

As shown in FIG. 6, the CLK (L) terminal and the HCLK (L) terminal are connected to the center position of the opening of the mount 31 (that is, the position of the optical axis O of the interchangeable lens 3) and the arc-shaped lens side first claw portion 39a. It was placed inside a fan shape (range of angle 60) formed by. Alternatively, the CLK (L) terminal and the HCLK (L) terminal are formed at the center position of the opening of the mount 31 (i.e., the position of the optical axis O of the interchangeable lens 3) and at both ends of the outer peripheral side of the first claw part 39a on the lens side. placed inside a triangular area. Therefore, although the lens-side first claw portion 39a does not exist on the extension of the dashed-dotted line 61 connecting the center position of the opening of the mount 31 and the LDET (L) terminal, the center position of the opening of the mount 31 and the LDET (L) terminal The lens-side first claw portion 39a exists on the extension of the dashed-dotted line 62 connecting the terminal, and the lens-side first claw portion 39a exists on the extension of the dashed-dotted line 63 connecting the center position of the opening of the mount 31 and the CLK (L) terminal. One claw portion 39a is present. As a result, in the attachment complete state, the CLK(L) terminal and the HCLK(L) terminal contact the corresponding body-side terminal more stably than the LDET(L) terminal. In other words, the CLK (L) terminal and the HCLK (L) terminal are subjected to a stronger force pressing against the body side terminal than the LDET (L) terminal. Therefore, even if the tips of the CLK (B) terminal and the HCLK (B) terminal are worn out, the clock signal communication between the camera body 2 and the interchangeable lens 3 is performed stably.

In this embodiment, the CLK (B) terminal, CLK (L) terminal, HCLK (B) terminal, and HCLK (L) terminal have been described, but other communication terminals such as the HDATA (B) terminal and HDATA The same applies to the (L) terminal, DATAL (B) terminal, DATAL (L) terminal, DATAB (B) terminal, and DATAB (L) terminal. In other words, the HDATA (B) terminal, DATAL (B) terminal, and DATAB (B) terminal are arranged closer to the body side first claw portion 29a and first leaf spring 41a than the LDET (B) terminal and VBAT (B) terminal. (short distance). By doing this, the HDATA (B) terminal, DATAL (B) terminal, and DATAB (B) terminal are pressed more strongly against the lens side terminal than the VBAT (B) terminal and LDET (B) terminal, and Able to maintain good contact. Furthermore, the HDATA (L) terminal, DATAL (L) terminal, and DATAB (L) terminal are arranged closer to the lens-side first claw portion 39a than the LDET (L) terminal and the VBAT (L) terminal (the distance is short). By doing this, the HDATA (L) terminal, DATAL (L) terminal, and DATAB (L) terminal are pressed more strongly against the body side terminal than the VBAT (L) terminal and LDET (L) terminal, and are pressed against the lens side terminal. Able to maintain good contact.

(Second embodiment)
Next, the interchangeable lens 3A of the camera system 1 according to the second embodiment will be explained. FIG. 7 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3A according to the second embodiment. As shown in FIG. 7, the lens-side terminal holding portion 32A included in the interchangeable lens 3A according to the second embodiment includes an LDET (L) terminal, a VBAT terminal, and a (L) terminal, PGND (L) terminal, V33 (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA ( L) It has a terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens-side terminal holding section 32A included in the interchangeable lens 3A according to the second embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. No clock signal is input from camera body 2.

The interchangeable lens 3A according to the second embodiment is configured to synchronize data transmission and reception through command data communication, for example, using a method similar to a so-called start-stop synchronization communication method. At the start of command data communication, the signal train that the lens side communication section 34A receives from the body side communication section 24 via the DATAB (B) terminal and the DATAB (L) terminal is constant. Therefore, the lens-side control unit 33A can identify the signal train received from the body-side communication unit 24 at the start of command data communication, and determine the cycle timing and clock frequency necessary for synchronizing data transmission and reception by command data communication. It is possible.

Similar to the operation of the interchangeable lens 3 according to the first embodiment described using FIG. 3, the lens-side control section 33A of the interchangeable lens 3A according to the second embodiment is Receiving the body side command signal from the body side communication unit 34 via the DATAB (L) terminal and sending the lens to the body side communication unit 34 via the DATAB (L) terminal using the cycle timing and clock frequency Transmit side data signals. Note that the interchangeable lens 3A according to the second embodiment includes an ASIC (application specific integrated circuit) having a dedicated circuit for determining the cycle timing and clock frequency necessary for synchronizing data transmission and reception by command data communication. Good too.

Further, the lens-side terminal holding portion 32A of the interchangeable lens 3A according to the second embodiment has a configuration in which terminals other than the CLK(L) terminal in the example shown in FIG. 6 are arranged. That is, the lens side terminal holding portion 32A of the interchangeable lens 3A has LDET (L), VBAT (L), PGND (L), V33 (L), GND (L), RDY (L), DATAB (L), and DATAL. (L), HCLK (L), and HDATA (L) terminals are arranged.

(Third embodiment)
Next, the interchangeable lens 3B of the camera system 1 according to the third embodiment will be described. FIG. 8 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3B according to the third embodiment. As shown in FIG. 8, the lens-side terminal holding portion 32B included in the interchangeable lens 3B according to the third embodiment includes an LDET (L) terminal, a VBAT terminal, and a (L) terminal, PGND (L) terminal, V33 (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens-side terminal holding portion 32B included in the interchangeable lens 3B according to the third embodiment does not include the GND (L) terminal of the interchangeable lens 3 according to the first embodiment. Furthermore, the lens-side terminal holding portion 32B included in the interchangeable lens 3B according to the third embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. The clock signal used is not input from the camera body 2.

Therefore, in the interchangeable lens 3B according to the third embodiment, the PGND (L) terminal is used as the ground potential (ground) of the power supply voltage of the drive system, and is connected to various parts such as the lens side control section 33B. It is used as the ground potential (ground) for the power supply voltage of the circuit system. A bypass capacitor C2 is connected between the V33 (L) terminal and the PGND (L) terminal.

Further, the lens control unit 33B of the interchangeable lens 3B according to the third embodiment receives command data from the body side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, the lens-side terminal holding portion 32B of the interchangeable lens 3B according to the third embodiment has a configuration in which each terminal other than the GND (L) terminal and the CLK (L) terminal in the example shown in FIG. 6 is arranged. Be prepared. That is, the lens-side terminal holding portion 32B of the interchangeable lens 3B includes LDET (L), VBAT (L), PGND (L), V33 (L), RDY (L), DATAB (L), DATAL (L), and HCLK. (L) and HDATA (L) terminals are arranged.

(Fourth embodiment)
Next, the interchangeable lens 3C of the camera system 1 according to the fourth embodiment will be described. FIG. 9 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3C according to the fourth embodiment. As shown in FIG. 9, the lens-side terminal holding portion 32C included in the interchangeable lens 3C according to the fourth embodiment includes an LDET (L) terminal, a VBAT terminal, and a (L) terminal, V33 (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens-side terminal holding portion 32C included in the interchangeable lens 3C according to the fourth embodiment does not include the PGND(L) terminal of the interchangeable lens 3 according to the first embodiment. Furthermore, the lens-side terminal holding section 32C included in the interchangeable lens 3C according to the fourth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. The clock signal used is not input from the camera body 2.

Therefore, in the interchangeable lens 3C according to the fourth embodiment, the GND (L) terminal is used as the ground potential (ground) of the power supply voltage of the circuit system, and is connected to each part such as the drive unit 37. It is also used as the ground potential (ground) for the power supply voltage of the drive system. A bypass capacitor C1 is connected between the VBAT (L) terminal and the GND (L) terminal, and a bypass capacitor C2 is connected between the V33 (L) terminal and the GND (L) terminal.

Further, the lens control unit 33C of the interchangeable lens 3C according to the fourth embodiment receives command data from the body side communication unit 24 at the start of command data communication, similarly to the above-mentioned interchangeable lens 3A according to the second embodiment. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, the lens-side terminal holding portion 32C of the interchangeable lens 3C according to the fourth embodiment has a configuration in which terminals other than the PGND (L) terminal and the CLK (L) terminal in the example shown in FIG. 6 are arranged. Be prepared. That is, the lens side terminal holding portion 32C of the interchangeable lens 3C has LDET (L), VBAT (L), V33 (L), GND (L), RDY (L), DATAB (L), DATAL (L), HCLK. (L) and HDATA (L) terminals are arranged.

(Fifth embodiment)
Next, the interchangeable lens 3D of the camera system 1 according to the fifth embodiment will be described. FIG. 10 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3D according to the fifth embodiment. As shown in FIG. 10, the lens-side terminal holding portion 32D included in the interchangeable lens 3D according to the fifth embodiment includes an LDET (L) terminal, a VBAT terminal, and a (L) terminal, PGND (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens side terminal holding section 32D included in the interchangeable lens 3D according to the fifth embodiment does not include the V33(L) terminal of the interchangeable lens 3 according to the first embodiment, and the lens side control section 33D etc. The camera body 2 does not supply power to the camera body 2. Further, the lens-side terminal holding portion 32D included in the interchangeable lens 3D according to the fifth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3D according to the fifth embodiment includes a DC/DC converter 50. The DC/DC converter 50 is, for example, a step-down voltage conversion circuit, and is connected to the VBAT(L) terminal and the lens-side control section 33D. The DC/DC converter 50 converts the power supply voltage supplied from the camera body 2 via the VBAT(L) terminal, and supplies power to the lens-side control unit 33D and the like. A bypass capacitor C2 is connected between the wiring for supplying power from the DC/DC converter 50 to the lens-side control unit 33D and the GND (L) terminal.

Further, the lens control unit 33D of the interchangeable lens 3D according to the fifth embodiment receives commands from the body-side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, the lens-side terminal holding portion 32D of the interchangeable lens 3D according to the fifth embodiment has a configuration in which terminals other than the V33 (L) terminal and the CLK (L) terminal in the example shown in FIG. 6 are arranged. Be prepared. That is, the lens side terminal holding portion 32D of the interchangeable lens 3D has LDET (L), VBAT (L), PGND (L), GND (L), RDY (L), DATAB (L), DATAL (L), HCLK. (L) and HDATA (L) terminals are arranged.

(Sixth embodiment)
Next, the interchangeable lens 3E of the camera system 1 according to the sixth embodiment will be described. FIG. 11 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3E according to the sixth embodiment. As shown in FIG. 11, the lens-side terminal holding portion 32E included in the interchangeable lens 3E according to the sixth embodiment includes an LDET (L) terminal, a PGND terminal, and a (L) terminal, V33 (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens-side terminal holder 32E included in the interchangeable lens 3E according to the sixth embodiment does not include the VBAT(L) terminal of the interchangeable lens 3 according to the first embodiment, and supplies the VBAT(L) terminal to the drive unit 37, etc. The camera body 2 does not supply power to the drive system for this purpose. Furthermore, the lens-side terminal holding section 32E included in the interchangeable lens 3E according to the sixth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3E according to the sixth embodiment includes a DC/DC converter 51. The DC/DC converter 51 is, for example, a step-up voltage conversion circuit, and is connected to the V33 (L) terminal and the drive unit 37. The DC/DC converter 51 converts the power supply voltage supplied from the camera body 2 via the V33(L) terminal, and supplies power to drive system circuits such as the drive unit 37. A bypass capacitor C1 is connected between the wiring for supplying power from the DC/DC converter 51 to the drive unit 37 and the like and the PGND (L) terminal.

Further, the lens control unit 33E of the interchangeable lens 3E according to the sixth embodiment receives command data from the body side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, the lens-side terminal holding portion 32E of the interchangeable lens 3E according to the sixth embodiment has a configuration in which terminals other than the VBAT (L) terminal and the CLK (L) terminal in the example shown in FIG. 6 are arranged. . That is, the lens side terminal holding portion 32D of the interchangeable lens 3D has LDET (L), PGND (L), V33 (L), GND (L), RDY (L), DATAB (L), DATAL (L), HCLK. (L) and HDATA (L) terminals are arranged.

(Seventh embodiment)
Next, the interchangeable lens 3F of the camera system 1 according to the seventh embodiment will be described. Descriptions of configurations common to the first embodiment described above will be omitted. FIG. 12 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3F according to the seventh embodiment. As shown in FIG. 12, the lens-side terminal holding portion 32F included in the interchangeable lens 3F according to the seventh embodiment has an LDET (L) terminal, a VBAT ( L) terminal, PGND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens side terminal holding part 32F included in the interchangeable lens 3F according to the seventh embodiment does not include the V33 (L) terminal and the GND (L) terminal of the interchangeable lens 3 according to the first embodiment, The camera body 2 does not supply power to the lens-side control unit 33F and the like. Furthermore, the lens-side terminal holding section 32F included in the interchangeable lens 3F according to the seventh embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3F according to the seventh embodiment includes a DC/DC converter 52. The DC/DC converter 52 is, for example, a step-down voltage conversion circuit, and is connected to the VBAT(L) terminal and the lens-side control section 33F. The DC/DC converter 52 converts the power supply voltage supplied from the camera body 2 via the VBAT(L) terminal, and supplies power to the lens-side control unit 33F and the like.

Further, in the interchangeable lens 3F according to the seventh embodiment, the PGND (L) terminal is used as a ground potential (ground) for the power supply voltage of the drive system, and is connected to various parts such as the lens side control section 33F. , used as the ground potential (ground) for the power supply voltage of the circuit system. A bypass capacitor C2 is connected between the wiring for power supply from the DC/DC converter 52 to the lens-side control unit 33F, etc., and the PGND (L) terminal.

Further, the lens control section 33F of the interchangeable lens 3F according to the seventh embodiment receives the command data from the body side communication section 24 at the start of command data communication, similarly to the above-mentioned interchangeable lens 3A according to the second embodiment. Using the periodic timing and clock frequency determined by identifying the signal sequence, reception of the body-side command signal from the body-side communication unit 34 via the DATAB(L) terminal, and reception of the body-side command signal via the DATAB(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, in the lens side terminal holding portion 32F of the interchangeable lens 3F according to the seventh embodiment, each terminal other than the V33 (L) terminal, the GND (L) terminal, and the CLK (L) terminal in the example shown in FIG. It has an arranged configuration. That is, the lens side terminal holding portion 32F of the interchangeable lens 3F has LDET (L), VBAT (L), PGND (L), RDY (L), DATAB (L), DATAL (L), HCLK (L), HDATA. (L) has a configuration in which each terminal is arranged.

(Eighth embodiment)
Next, the interchangeable lens 3G of the camera system 1 according to the eighth embodiment will be described. Descriptions of configurations common to the first embodiment described above will be omitted. FIG. 12 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3G according to the eighth embodiment. As shown in FIG. 12, the lens-side terminal holding portion 32G included in the interchangeable lens 3G according to the eighth embodiment includes an LDET (L) terminal, a VBAT terminal, and a (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens side terminal holding part 32G included in the interchangeable lens 3G according to the seventh embodiment does not include the PGND (L) terminal and the V33 (L) terminal of the interchangeable lens 3 according to the first embodiment, The camera body 2 does not supply power to the lens-side control unit 33G and the like. Further, the lens-side terminal holding portion 32G included in the interchangeable lens 3G according to the eighth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3G according to the eighth embodiment includes a DC/DC converter 53. The DC/DC converter 53 is, for example, a step-down voltage conversion circuit, and is connected to the VBAT(L) terminal and the lens-side control section 33G. The DC/DC converter 53 converts the power supply voltage supplied from the camera body 2 via the VBAT(L) terminal, and supplies power to the lens-side control unit 33G and the like.

Further, in the interchangeable lens 3G according to the eighth embodiment, the GND (L) terminal is used as a ground potential (ground) for the power supply voltage of the circuit system, and is connected to each part such as the drive unit 37 to drive It is also used as the ground potential (ground) for the power supply voltage of the system. A bypass capacitor C1 is connected between the VBAT (L) terminal and the GND (L) terminal, and a bypass capacitor C1 is connected between the wiring for power supply from the DC/DC converter 53 to the lens side control unit 33G, etc. and the GND (L) terminal. is connected to bypass capacitor C2.

Further, the lens control unit 33G of the interchangeable lens 3G according to the eighth embodiment receives commands from the body-side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, in the lens side terminal holding portion 32G of the interchangeable lens 3G according to the eighth embodiment, each terminal other than the PGND (L) terminal, the V33 (L) terminal, and the CLK (L) terminal in the example shown in FIG. It has an arranged configuration. That is, the lens side terminal holding portion 32G of the interchangeable lens 3G has LDET (L), VBAT (L), GND (L), RDY (L), DATAB (L), DATAL (L), HCLK (L), HDATA. (L) has a configuration in which each terminal is arranged.

(Ninth embodiment)
Next, the interchangeable lens 3H of the camera system 1 according to the ninth embodiment will be described. Descriptions of configurations common to the first embodiment described above will be omitted. FIG. 14 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3H according to the ninth embodiment. As shown in FIG. 14, the lens-side terminal holding portion 32H included in the interchangeable lens 3H according to the ninth embodiment has an LDET (L) terminal, a PGND terminal, and a (L) terminal, V33 (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens side terminal holding part 32H included in the interchangeable lens 3H according to the ninth embodiment does not include the VBAT (L) terminal and the GND (L) terminal of the interchangeable lens 3 according to the first embodiment, The camera body 2 does not supply power to the drive system for supplying the drive unit 37 and the like. Further, the lens-side terminal holding portion 32H included in the interchangeable lens 3H according to the ninth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3H according to the ninth embodiment includes a DC/DC converter 54. The DC/DC converter 54 is, for example, a step-up voltage conversion circuit, and is connected to the V33 (L) terminal and the drive unit 37. The DC/DC converter 54 converts the power supply voltage supplied from the camera body 2 via the V33 (L) terminal, and supplies power to drive system circuits such as the drive unit 37 .

Further, in the interchangeable lens 3H according to the ninth embodiment, the PGND (L) terminal is used as a ground potential (ground) for the power supply voltage of the drive system, and is connected to various parts such as the lens side control section 33H. , used as the ground potential (ground) for the power supply voltage of the circuit system. A bypass capacitor C1 is connected between the wiring for supplying power from the DC/DC converter 54 to the drive unit 37 and the like and the PGND (L) terminal.

Further, the lens control unit 33H of the interchangeable lens 3H according to the ninth embodiment receives the command data from the body side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAB(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, the lens-side terminal holding portion 32H of the interchangeable lens 3H according to the ninth embodiment has terminals other than the VBAT (L) terminal, the GND (L) terminal, and the CLK (L) terminal in the example shown in FIG. It has an arranged configuration. That is, the lens side terminal holding portion 32H of the interchangeable lens 3H has LDET (L), PGND (L), V33 (L), RDY (L), DATAB (L), DATAL (L), HCLK (L), HDATA. (L) has a configuration in which each terminal is arranged.

(Tenth embodiment)
Next, the interchangeable lens 3I of the camera system 1 according to the tenth embodiment will be described. Descriptions of configurations common to the first embodiment described above will be omitted. FIG. 15 is a circuit diagram schematically showing the electrical connection between the camera body 2 and the interchangeable lens 3I according to the tenth embodiment. As shown in FIG. 15, the lens-side terminal holding portion 32I included in the interchangeable lens 3I according to the tenth embodiment includes an LDET (L) terminal, a V33 (L) terminal, GND (L) terminal, RDY (L) terminal, DATAB (L) terminal, DATAL (L) terminal, HCLK (L) terminal, and HDATA (L) terminal. The functions and roles of these terminals are the same as those of the interchangeable lens 3 according to the first embodiment, so a description thereof will be omitted. The lens side terminal holding part 32I included in the interchangeable lens 3I according to the tenth embodiment does not include the VBAT (L) terminal and the PGND (L) terminal of the interchangeable lens 3 according to the first embodiment, The camera body 2 does not supply power to the drive system for supplying the drive unit 37 and the like. Further, the lens-side terminal holding portion 32I included in the interchangeable lens 3I according to the tenth embodiment does not include the CLK (L) terminal of the interchangeable lens 3 according to the first embodiment, and is used for command data communication. clock signal is not input from the camera body 2.

Therefore, the interchangeable lens 3I according to the tenth embodiment includes a DC/DC converter 55. The DC/DC converter 55 is, for example, a step-up voltage conversion circuit, and is connected to the V33 (L) terminal and the drive unit 37. The DC/DC converter 55 converts the power supply voltage supplied from the camera body 2 via the V33 (L) terminal, and supplies power to drive system circuits such as the drive unit 37.

Further, in the interchangeable lens 3I according to the tenth embodiment, the GND (L) terminal is used as the ground potential (ground) of the power supply voltage of the circuit system, and is connected to each part such as the drive unit 37 to drive the lens. It is also used as the ground potential (ground) for the power supply voltage of the system. A bypass capacitor C1 is connected between the wiring for supplying power from the DC/DC converter 55 to the drive unit 37 and the like and the GND (L) terminal.

Further, the lens control unit 33I of the interchangeable lens 3I according to the tenth embodiment receives data from the body-side communication unit 24 at the start of command data communication, similarly to the interchangeable lens 3A according to the second embodiment described above. Using the periodic timing and clock frequency determined by identifying the signal sequence, the body-side command signal is received from the body-side communication unit 34 via the DATAB(L) terminal, and the body-side command signal is received via the DATAL(L) terminal. A lens side data signal is transmitted to the body side communication section 34.

Further, in the lens side terminal holding portion 32I of the interchangeable lens 3I according to the tenth embodiment, each terminal other than the VBAT (L) terminal, the PGND (L) terminal, and the CLK (L) terminal in the example shown in FIG. It has an arranged configuration. That is, the lens-side terminal holding portion 32H of the interchangeable lens 3H has LDET (L), V33 (L), GND (L), RDY (L), DATAB (L), DATAL (L), HCLK (L), HDATA. (L) has a configuration in which each terminal is arranged.

Similarly to the first embodiment, the second to tenth embodiments also have the effect of suppressing the effects of various noises as described below. The RDY terminal was placed away from either the VBAT terminal or the HCLK terminal, which are noise sources, so as not to be adjacent to them. This suppresses the influence of noise on the RDY terminal used to indicate whether command communication is possible.
Further, the HCLK terminal, which is a noise source, is sandwiched between the HDATA terminal and the DATA terminal, and the CLK terminal is sandwiched between the DATA terminal and the DATAB terminal. That is, the HDATA terminal, HCLK terminal, DATA terminal, and DATAB terminal were arranged in order from the rear end in the mounting direction. This suppresses the influence of noise caused by clock signals to the RDY terminal and the like.
Furthermore, in consideration of the influence of noise, the group of terminals for power supply and the group of terminals used for communication are placed apart from each other with the RDY terminal in between. To be more specific, the VBAT terminal, the PGND terminal, the V33 terminal, and the GND terminal, which are power supply terminals, are arranged in order from the distal end side in the mounting direction across the RDY terminal, and the communication terminal is arranged on the rear end side in the mounting direction. The terminals to be used, DATAB terminal, DATAL terminal, HCLK terminal, and HDATA terminal, were arranged in order from the tip side. Thereby, it is possible to suppress the influence of the power supply terminal group such as the VBAT terminal on the terminals used for communication. Further, it is possible to suppress the influence of noise on the RDY terminal of the power supply system terminal group such as the VBAT terminal and the terminal group used for communication such as the HCLK terminal.

Regarding the HCLK terminal and the GND terminal, the HCLK terminal is arranged at a position farther from the VBAT terminal than the GND terminal. Furthermore, a PGND terminal was arranged between the GND terminal and the VBAT terminal. Thereby, it is possible to shield noise caused by the VBAT terminal to the HCLK terminal to which the clock signal (H clock signal) used for hotline communication is sent.

The following modifications are also possible, and it is also possible to combine one or more modifications with the above-described embodiment.
(Modification 1)
Either terminal used for command data communication or hotline communication may also have the function of transmitting a power-on signal from the interchangeable lens 3 to the camera body 2. For example, the interchangeable lens 3 is provided with a power switch function. Even when the interchangeable lens 3 is completely attached and the camera system 1 is powered off, the power supply section 26 supplies power from the V33(B) terminal to the lens-side control section 33 of the interchangeable lens 3. When the power switch of the interchangeable lens 3 is operated, the lens-side control section 33 outputs a power-on signal to the RDY (L) terminal via the lens-side communication section 34, for example. When the body-side control unit 23 detects a power-on signal via the RDY (B) terminal via the body-side communication unit 24, the body side control unit 23 performs the same operation as when a power switch (not shown) provided on the camera body 2 is operated. , transitions the camera system 1 from the power-off state to the power-on state.

(Modification 2)
In the embodiment, the DATAB (B) terminal is placed on the leading end side of the CLK (B) terminal in the mounting direction, and the DATAL (B) terminal is placed on the rear end side, but the positions of the DATAB (B) terminal and DATAL (B) terminal may be replaced. That is, the DATAL (B) terminal, the CLK (B) terminal, and the DATAB (B) terminal may be arranged in this order from the distal end side in the mounting direction.

Moreover, for each terminal of the lens-side terminal group described in each of the above-described embodiments, the LDET (L) terminal may be referred to as a detection terminal. Further, the VBAT(L) terminal may be referred to as a power supply terminal or a first power supply terminal. Further, the PGND(L) terminal may be referred to as a ground terminal or a first ground terminal. Further, the V33(L) terminal may be referred to as a power supply terminal or a second power supply terminal. Further, the GND (L) terminal may be referred to as a ground terminal or a second ground terminal. Further, the RDY(L) terminal may be referred to as a ready terminal. Further, the DATAB(L) terminal may be referred to as a data terminal or a first data terminal. Further, the CLK (L) terminal may be referred to as a clock terminal or a first clock terminal. Further, the DATAL (L) terminal may be referred to as a data terminal or a second data terminal. Further, the HCLK(L) terminal may be referred to as a clock terminal or a second clock terminal. Further, the HDATA(L) terminal may be referred to as a data terminal or a third data terminal.

Note that although the above embodiment has been described using an example of an interchangeable lens for a camera as an accessory, the accessory is not limited to an interchangeable lens. For example, it may be a teleconverter, a wide converter, a close-up ring, etc. that is attached between the camera body and the interchangeable lens and changes the focal length of the interchangeable lens. Alternatively, the present invention can also be applied to a mount adapter that allows accessories including interchangeable lenses of other mount standards to be attached to the above-mentioned camera body mount standard. In other words, the present invention can be similarly applied to any accessory that is used by being attached to a mount on a camera body. In that case, the lens-side terminal group, lens-side claw portion 39, lens-side communication portion 34, etc. correspond to the accessory-side terminal group, accessory-side protrusion, accessory-side communication portion, etc. of each accessory. In the embodiment described above, the accessory is detachable from the camera body, but the camera body described above is a mount adapter that allows an interchangeable lens of the above-mentioned mount standard to be attached to a camera body of a different mount standard. Alternatively, the above-mentioned accessories may be attached to the mount adapter.

DESCRIPTION OF SYMBOLS 1...Camera system, 2...Camera body, 3, 3A, 3B, 3C, 3D, 3E, 3F, 3G, 3H, 3I...Interchangeable lens, 21...Body side mount, 22...Body side terminal holding part, 31...Lens Side mount, 32, 32A, 32B, 32C, 32D, 32E, 32F, 32G, 32H, 32I... Lens side terminal holder

Claims (5)

An accessory that can be attached to a camera body,
a communication section including a circuit for communicating with the camera body;
a ready terminal used to indicate whether communication with the camera body via the communication unit is possible;
a first data terminal into which a first data signal from the camera body to the communication unit is input;
a second data terminal that outputs a second data signal from the communication unit to the camera body;
a first clock terminal that outputs a clock signal from the communication unit to the camera body;
a third data terminal that outputs a third data signal from the communication unit to the camera body in synchronization with the clock signal;
The ready terminal, the first data terminal, the second data terminal, the first clock terminal, and the third data terminal are arranged in this order. a detection terminal for causing the camera body to detect attachment of the accessory;
a power terminal to which power voltage is supplied from the camera body;
a ground terminal used as a ground potential of the power supply terminal,
The accessory according to claim 1, wherein the power supply terminal and the ground terminal are arranged between the detection terminal and the ready terminal. a control unit that includes the communication unit and controls communication with the camera body via the ready terminal, the first data terminal, and the second data terminal;
The accessory according to claim 1 or 2, wherein the control unit determines a frequency at which a signal included in the first data signal is received based on the first data signal. The accessory according to claim 3, wherein the control unit outputs a signal included in the second data signal at the frequency. The accessory according to claim 3 or 4, which does not include a terminal for receiving the second clock signal of the frequency generated by the camera body.

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