JP2006013579A - Photographing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a photographing apparatus comprising a lens unit and a camera main body wherein a user can more easily correct programs. <P>SOLUTION: A digital camera 2 is provided with the lens unit 22 comprising: a photographing lens 4; a CCD image sensor 39; and a data memory 42, and with the camera main body comprising: a signal processing circuit 65; a control section 67; a read section 68; a ROM 70; and an SDRAM 73. The data memory 42 stores specification information of the lens unit 22. When the lens unit 22 is mounted on the camera main body 23, the read section 68 receives a detection signal and starts reading the specification information stored in the data memory 42. The RAM 71 stores the specification information, the control section 67 carries out various settings on the basis of the data stored in the RAM 71 to be able to drive a CCD image sensor 39, a lens motor 53, and an iris motor 55. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a photographing apparatus such as a digital camera.

  In recent years, photographing apparatuses such as digital cameras have rapidly spread. The imaging device includes an image sensor such as a CCD image sensor that outputs an image signal. The image data of the subject is formed based on the image signal output from the image sensor, and the formed image data is attached to the imaging device. Recorded on a recording medium. The photographing device is provided with a switch for switching between a camera mode for photographing a subject and a playback mode for displaying image data recorded on a recording medium on a display screen provided in the digital camera. The user switches the switch. Depending on the purpose, use the photographic device.

  Currently, the pursuit of miniaturization and convenience has been advancing for photographing apparatuses, and various devices have been made to realize miniaturization and high convenience. For example, a thin battery with a thin rectangular parallelepiped shape as a power supply battery, or a lens mirror that holds the zoom lens even when zooming is performed by bending the optical system of the zoom lens. In some cases, the tube is prevented from jumping out of the housing of the photographing apparatus. In particular, a lens unit having a photographic lens, an image sensor that outputs an image signal based on an image formed by the photographic lens, and a signal processing circuit that processes the image signal from the image sensor and forms image data. In a photographing apparatus composed of a camera body, high-quality images can be easily acquired by exchanging the lens unit. In Patent Document 1, an image signal is stored in a camera unit having a photographing lens, an image sensor that outputs an image signal, a signal processing circuit that processes the image signal from the image sensor, and a connector for outputting the image signal to the outside. An imaging device capable of mounting a memory unit is shown.

Japanese Patent Application Laid-Open No. 8-290431

  By the way, an imaging apparatus is already devised in which the imaging apparatus is configured by a lens unit having an imaging lens and an imaging element, and a camera body that processes image signals output from the imaging element to form image data. . The lens unit that can be freely exchanged is provided with a non-volatile memory that stores a program for controlling the lens unit. The camera body has a reading means for reading the program from the memory and the reading means for reading the program. Control means for controlling the lens unit based on the program, and after the lens unit is mounted on the camera body, data and programs are read from the lens unit to the camera body and stored, and the stored data Since the lens unit is controlled based on the program, the combination of the photographic lens and the image sensor can be freely determined. This makes it easy to design a high-quality lens unit and offers a wide variety of lens units. We were able to.

  However, if a memory storing a program for controlling the lens unit is provided in the lens unit, the program must be read from the memory provided in the lens unit to the camera body when the lens unit is mounted on the camera body. For example, if the drive control of the focus motor or zoom motor provided in the lens unit is complicated, the program may become large and it may take time to transfer the program from the lens unit to the camera body. For this reason, it takes time from when the lens unit is mounted to the camera body until it is possible to take a picture, and the user may miss a photo opportunity.

  The present invention has been made in view of the above circumstances, and an object thereof is a high-quality lens that includes a lens unit having a photographing lens and a CCD image sensor, and a camera body that controls the operation of the lens unit. An object of the present invention is to provide a photographing apparatus that can start photographing in a shorter time after the lens unit is attached to the camera body while facilitating unit design.

  In order to achieve the above object, an imaging apparatus according to the present invention includes an imaging lens and an imaging element in an imaging apparatus having an imaging element that outputs an image signal based on a subject image formed by the imaging lens. A lens unit, a mount unit on which the lens unit can be detachably attached, and a signal processing means for forming image data based on an image signal input from the lens unit attached to the mount unit; It is comprised from the camera main body provided with. Furthermore, the lens unit is provided with data storage means for storing data unique to the lens unit, and a first connector for outputting the data stored in the data storage means to the outside. A second connector connected to one connector; a reading means for reading data from the data storage means via the second connector when the lens unit is mounted; and a lens unit and a camera based on the data read by the reading means Control means for controlling at least one of the main body and the main body is provided.

  Further, spec information relating to the spec of at least one of the photographing lens and the image sensor is stored as unique data of the lens unit, and the control means determines whether the lens unit and the camera body are based on the spec information. It is characterized by controlling at least one of them. The spec information includes format information indicating the model of the lens unit 22, serial number information indicating the serial number of the lens unit 22, F value information indicating the F value of the photographing lens 4, magnification information indicating the magnification of the photographing lens, Focal length information indicating the focal length of the taking lens, pixel information indicating the number of pixels in the vertical and horizontal directions of the image sensor such as a CCD image sensor, filter information related to a color filter provided in the image sensor, sensitivity information regarding sensitivity of the image sensor, Defective pixel information relating to defective pixels of the image sensor, image sensor drive information necessary for driving the image sensor, motor rotation speed information for moving the photographing lens in the optical axis direction, motor rotation speed information for driving the iris, shutter Rotation speed information of the motor that drives the image, and a shade for correcting shading included in the image Ring correction data, and the like color tone correction data for correcting the color tone of the image.

  In addition, the camera body is provided with a detection unit that detects whether or not the lens unit is mounted on the mount unit, and the reading unit detects the data when the detection unit detects that the lens unit is mounted on the mount unit. Reading of data from the storage means is started.

  According to the photographing apparatus of the present invention, a lens unit including a photographing lens and an image pickup device, a mount portion to which the lens unit can be detachably attached, and an image signal input from the lens unit attached to the mount portion. A camera body having a signal processing means for forming image data based on the data, and a lens storage unit storing data unique to the lens unit and data stored in the data storage means externally. A first connector for outputting to the camera, a second connector connected to the first connector on the camera body, and a reading means for reading data from the data storage means via the second connector when the lens unit is mounted. Based on the unique data of the lens unit read by the reading means, the lens unit and the camera body When the lens unit is attached to the camera body, the reading unit reads data specific to the lens unit stored in the data storage unit, and the control unit Since at least one of the lens unit and the camera body is controlled based on the data read by the reading means, the lens unit is attached to the camera while facilitating the design of a high-quality lens unit that is interchangeable. It is possible to provide a photographing apparatus that can start photographing in a shorter time after being attached to the main body.

  In addition, as the data unique to the lens unit, spec information regarding the spec of at least one of the photographing lens and the image pickup device is included, and the control means determines whether the lens unit and the camera body are based on the spec information. Since at least one of them is controlled, the control means can perform more precise control based on the specification information, and can provide a highly convenient photographing apparatus. In particular, as spec information, format information indicating the model of the lens unit 22, serial number information indicating the serial number of the lens unit 22, F-number information indicating the F value of the photographing lens 4, magnification information indicating the magnification of the photographing lens, photographing Focal length information indicating the focal length of the lens, pixel information indicating the number of vertical and horizontal pixels of the image sensor such as a CCD image sensor, filter information related to a color filter provided in the image sensor, sensitivity information regarding sensitivity of the image sensor, imaging Defective pixel information related to defective pixels of the element, imaging element driving information necessary for driving the imaging element, rotational speed information of the motor that moves the photographing lens in the optical axis direction, rotational speed information of the motor that drives the iris, shutter Rotation speed information of the motor to be driven, shading for correcting shading included in the image Ingu correction data, the color correction data for correcting the color tone of the image by storing in the data storage means, it is possible to more precisely control the at least one of the lens unit and the camera body.

  Further, the camera body is provided with a detecting means for detecting whether or not the lens unit is mounted on the mount portion, and the reading means stores data when the detecting means detects that the lens unit is mounted on the mount portion. By starting the reading of data from the means, the reading means can reliably read the data from the data storage means when the lens unit is mounted on the mount, and a more convenient photographing apparatus is provided. Can do.

  FIG. 1 is an external perspective view of a digital camera of the present invention. A photographing lens 4 for forming a subject image is provided on the front surface of the digital camera 2, and a shutter button 6 for starting photographing in response to a pressing operation, a setting of the digital camera 2, and the like are simply displayed on the upper portion of the digital camera 2. An upper display panel 8 for exposure, an exposure mode dial 10 for setting an exposure operation in accordance with an external environment such as clear sky, cloudy, indoors, and the like are provided. Although not shown, the digital camera is provided with a USB port, an IEEE 1394 port, a video terminal, and the like on the side portion.

  A perspective view of the back surface of the digital camera 2 is shown in FIG. On the back of the digital camera 2, a viewfinder eyepiece window 12 to be looked into when checking the position of the subject in the frame, a liquid crystal panel (hereinafter referred to as LCD) 14 for displaying a through image or a menu image of the subject, and turning on the LCD 14 LCD display button 15 for switching between / OFF, cross operation button 17 operated when selecting an appropriate item from the menu image displayed on LCD 14, and pressing operation when executing the selected item An execution button 19, a cancel button 20 for canceling the selection operation and the execution operation, and the like are provided.

  As shown in FIG. 3, the digital camera 2 includes a lens unit 22 and a camera body 23. The outer shape of the lens unit 22 is formed in a columnar shape, the photographing lens 4 is exposed from one end thereof, and a CCD image sensor or the like is incorporated therein. At the other end of the lens unit 22, a connection portion 22 a for combining with the camera body 23 is formed. The camera body 23 is formed with a mount portion 23 a for fitting a connection portion 22 a formed on the lens unit 22. A mount release button 27 that is pressed when the lens unit 22 is removed from the camera body 23 is provided near the mount portion 23a. By pressing the mount release button 27, the lens unit 22 is removed from the mount portion 23a. Is possible.

  FIG. 4 is a cross-sectional view of the lens unit 22 and the periphery of the mount portion 23a of the camera body 23 cut vertically along the optical axis direction. The outside of the lens unit 22 is covered with an exterior cover 30, and a notch 35 that engages with a protrusion 32 described later is formed on the outer periphery of the exterior cover 30, and the photographing lens 4 is held inside the exterior cover 30. A lens barrel 37 for holding the lens holding frame 36 movably in the optical axis direction, an optical low-pass filter (hereinafter referred to as O-LPF) 38, a mechanical shutter 41, a sub circuit board 40 on which a CCD image sensor 39 is assembled, data A main circuit board 45 provided with a memory (data storage means) 42, a first connector 43, and the like is incorporated. On the image plane side of the photographing lens 4, an iris 47 that adjusts the amount of incident light, a mechanical shutter 41, an O-LPF 38 that cuts high-frequency components of light incident from the photographing lens 4, and a CCD image sensor 39 are arranged in this order. . The lens motor that moves the lens holding frame 36 and the iris motor that adjusts the operation of the iris are stepping motors that rotate by a predetermined angle in response to the input of the pulse signal. The lens motor and the iris motor are respectively controlled by the motor controller. The drive is controlled. The CCD image sensor 39 has, for example, 720 pixels in the vertical direction and 960 pixels in the horizontal direction. The CCD image sensor 39 is arranged perpendicular to the optical axis of the photographing lens 4. The sub circuit board 40 provided with the CCD image sensor 39 is the main circuit board 45. And a flexible circuit board 50. In addition to the data memory 42, the main circuit board 45 is provided with a motor controller that controls the driving of the lens motor and the iris motor. Note that the CCD image sensor is not limited to having 720 pixels in the vertical direction and 960 pixels in the horizontal direction, and a CCD image sensor having a larger number of pixels or a smaller number of pixels may be used.

  The camera body 23 is formed with a mount portion 23a for fitting and holding the connection portion 22a of the lens unit 22, and the mount portion 23a is fitted into a first connector 43 provided on the main circuit board 45 of the lens unit 22. A second connector 52 and a protrusion 32 that engages with a notch 35 formed in the exterior cover 30 of the lens unit 22 are provided. When the connecting portion 22a of the lens unit 22 is fitted into the mount portion 23a of the camera body 23, the second connector 52 is fitted into the first connector 43 so that the first connector 43 and the second connector 52 are electrically connected. When the connection portion 22a is fitted into the mount portion 23a until the flange portion 30a formed on the outer periphery of the exterior cover 30 contacts the periphery of the mount portion 23a, the protrusion 32 engages with the notch 35, and the lens unit 22 is engaged with the camera body 23. Retained. When removing the lens unit 22 from the camera body 23, the lens unit 22 is pulled out from the camera body 23 while pressing the mount release button 27. When the mount release button 27 is pressed, the protruding protrusion 32 is retracted and is not engaged with the notch 35, so that the lens unit 22 can be pulled out from the mount portion 23a.

  FIG. 5 shows a block diagram of the digital camera. The lens unit 22 includes a photographic lens 4, a lens motor controller 54 that controls driving of a lens motor 53 that moves the holding frame 36 that holds the photographic lens 4 in the optical axis direction, an iris 47, and an iris motor 55 that operates the iris 47. An iris motor controller 56 for controlling the driving of the shutter, a shutter motor controller 59 for controlling the driving of the shutter motor 58 for operating the mechanical shutter 41, a CCD driver 57 for controlling the driving of the CCD image sensor 39, a data memory 42, and the like. ing. The drive of the CCD image sensor 39 that outputs light from the photographing lens 4 as an electrical image signal by photoelectric conversion is controlled by a drive pulse supplied from a CCD driver 57. The data memory 42 is configured by an EEPROM (Electrically Erasable Programmable ROM) which is a nonvolatile memory, and stores spec information of the lens unit 22 as unique data of the lens unit 22. In the data memory 42, as specification information, format information indicating the model of the lens unit 22, serial number information indicating the serial number of the lens unit 22, F value information indicating the F value of the photographing lens 4, and magnification of the photographing lens are shown. Magnification information, focal length information indicating the focal length of the photographing lens, pixel information indicating the number of pixels in the vertical and horizontal directions of the CCD image sensor 39, filter information related to a color filter provided in the CCD image sensor 39, sensitivity of the CCD image sensor 39 Sensitivity information, defective pixel information regarding defective pixels of the CCD image sensor 39, CCD drive information necessary for driving the CCD image sensor 39, rotational speed information of the lens motor 53, rotational speed information of the iris motor 55, shutter motor information Rotation speed information, shade included in image Shading correction data for correcting the ring, such as color tone correction data for correcting the color tone of the image are stored.

  The camera body 23 includes a timing generator 63, a signal processing unit (signal processing unit) 65, a control unit 67 that is a control unit, a lead unit 68 that is a reading unit, a mount detection unit 69 that is a detection unit, a ROM 70, and a compression processing unit. 72, SDRAM 73, media controller 75, LCD controller 76, image processing unit 80, image correction unit 81, and the like. The timing generator 63 generates a driving pulse necessary for transferring charges output from the photodiode units regularly arranged in the CCD image sensor 39, and inputs the generated driving pulse to the CCD driver 57. The CCD driver 57 is connected to the CCD image sensor 39 and appropriately inputs drive pulses supplied from the timing generator 63 to the CCD image sensor 39. The CCD image sensor 39 responds to the drive pulses input from the CCD driver 57. Output image signal.

  The signal processing unit 65 includes a correlated double sampling circuit, an amplification circuit, an A / D conversion circuit, and the like, and an image signal is input through the first and second connectors 43 and 52. The image signal is converted into an RGB analog signal for each cell of the CCD image sensor 39 by the correlated double sampling circuit, the RGB analog signal is amplified by the amplifier circuit, and digitally converted by the A / D converter circuit to form image data. The

  The image processing unit 80 corrects the white balance, sharpness, contrast, and the like of the image data. The ROM 70 is composed of a non-volatile flash memory, and stores various programs for controlling the operation of the digital camera 2. The control unit 67 reads and executes appropriate programs from the ROM 70 as appropriate. The control unit 67 also performs control of the media controller 75 that writes image data to the recording medium 82, control of the LCD controller 76 that drives the LCD 14, and the like.

  The SDRAM 73 temporarily stores image data formed by the signal processing circuit 65 and image data that has been subjected to image processing by the image processing unit 80. The image data formed by the signal processing circuit 65 is input to the SDRAM 73 and then sent to the image processing unit 80 where various image processing such as white balance, sharpness, and contrast is performed. The image data that has been subjected to image processing by the image processing unit 80 is temporarily stored in the SDRAM 73.

  The compression processing unit 72 compresses the image data processed by the image processing unit 80 and stored in the SDRAM 73 in accordance with, for example, JPEG (Joint Photographic Experts Group) standard. The compressed image data is stored in the SDRAM 73 by forming an image file in accordance with a predetermined format, for example, DCF (Dsign rule for Camera File system). The compression processing unit 72 has a function of compressing image data recorded on the recording medium 82 to form thumbnail image data, and image data read from the recording medium 82 is determined in advance. According to the method, the thumbnail image data is formed by being compressed to a predetermined size. When the formed image data is input to the LCD 14 via the LCD controller 76, the thumbnail image is displayed on the LCD 14.

  The media controller 75 writes image data to the recording medium 82 inserted into a card slot (not shown) and reads image data from the recording medium 82. The image file stored in the SDRAM 73 is read by the media controller 75 and written to the recording medium 82 in response to a user operation. When displaying a thumbnail image on the LCD 14, the image file recorded on the recording medium 82 is read by the media controller 75, and the thumbnail image data is converted by the compression processing circuit 72 based on the image data in the read image file. It is formed. The external interface 84 has a USB port, an IEEE 1394 port, and the like, and enables data communication for exchanging data with the outside.

  Various images are displayed on the LCD 14 in accordance with user operations. When the digital camera 2 is set to the still image shooting mode by operating the mode switch, a through image that displays the current subject image at a predetermined frame rate is displayed, and the user can take a picture while viewing the through image. It can be carried out. When the digital camera 2 is set to the playback mode, image data is read from the recording medium 82, and an image is displayed based on this image data.

  The mount detection unit 69 detects whether or not the projection 32 is engaged with the notch 35 based on the position of the projection 32, and the mount detection unit 69 uses the position of the projection 32 to change the tip to the notch 35. When the engagement is detected, a detection signal is input to the lead unit 68.

  The read unit 68 accesses the data memory 42 to read data, and stores the read data in the RAM 71. For example, when the lens unit 22 is attached to the camera body 23, a detection signal is input from the mount detection unit 69 to the lead unit 68, and in response thereto, the lead unit 68 receives the lens unit type and serial number from the data memory 42. , F value of the photographic lens 4, focal length of the photographic lens 4, magnification of the photographic lens 4, number of pixels of the CCD image sensor 39, sensitivity of the CCD image sensor 39, defective pixel information of the CCD image sensor 39, rotation of the lens motor 53 Specification information such as the speed, the rotation speed of the iris motor 55, shading data, and color correction data is read. The specification information read by the read unit 68 is written in the ROM 71. The read unit 68 monitors whether or not all data stored in the data memory 42 has been read, and ends the operation in response to reading all the data in the data memory 42.

  The spec information of the lens unit 22 written in the RAM 71 is input to the control unit 67, and the control unit 67 performs setting based on the spec information. For example, spec information such as the F value, the focal length, the magnification, the rotational speed of the lens motor 53, and the rotational speed of the iris motor 47 of the photographing lens 4 is a parameter value of an algorithm such as AF (Auto Focus) or AE (Auto Exposure). And used when setting the timing generator 63 and the signal processing unit 65 based on the specification information such as the number of pixels of the CCD image sensor 39, sensitivity, and defective pixel information. Further, the image correction unit 81 is set based on the color tone correction data and the shading correction data, and the color tone and shading of the image can be corrected.

  After the setting is made by the control unit 67, the timing generator 63 can generate a drive pulse necessary for driving the CCD image sensor 39 and send it to the CCD driver 57. The CCD driver 57 appropriately outputs the drive pulse. Input to the CCD image sensor 39 and cause the CCD image sensor 39 to output an image signal. The control unit 67 inputs an operation signal including a clock signal for driving the lens motor 53 to the lens motor controller 54, and the lens motor controller 54 generates a drive pulse for driving the lens motor 53 based on the operation signal. And input to the lens motor 53. The lens motor 53 is driven according to the drive pulse supplied from the lens motor controller 54, and the photographing lens 4 moves along the optical axis. The control unit 67 sends an operation signal for driving the iris motor 55 according to the control program to the iris motor controller 56, and the iris motor controller 56 supplies a drive pulse to the iris motor 55 based on the operation signal. Is driven to operate the iris 47. The shutter motor controller 58 receives an operation signal input from the control unit 67 and inputs a driving pulse to the shutter motor 41. The shutter motor is driven based on the driving pulse to operate the mechanical shutter 41. The image correction unit 81 set by the control unit 67 changes the RGB value of the image data to correct shading or the like in which the color tone of the image or the peripheral portion of the image is darker than the central portion.

  FIG. 6 shows a flowchart for explaining the present invention. When the lens unit 22 is mounted on the mount unit 23 a, the mount detection unit 69 detects that the lens unit 22 is mounted on the mount unit 23 a, and a detection signal is input from the mount detection unit 69 to the lead unit 68. In response to the input of the detection signal, the read unit 68 starts reading data from the data memory 42. The spec information of the lens unit 22 read from the data memory 42 is written in the RAM 71.

  The control unit 67 sets the timing generator 63 and the signal processing unit 65 based on the spec information of the lens unit 22. Further, an operation signal for driving the lens motor 53 and an operation signal for driving the iris motor 55 are input to the lens motor controller 54 and the iris motor controller 56 based on the spec information of the lens unit 22. The timing generator 63 inputs a drive pulse to the CCD driver, and the CCD driver sends the drive pulse to the CCD image sensor as appropriate to drive the CCD image sensor 39. The image signal output from the CCD image sensor 39 is input to the signal processing unit 65 via the first and second connectors 43 and 52. The motor controllers 54 and 56 input drive pulses to the lens motor 53 and the iris motor 55 based on the operation signals, respectively, to drive the lens motor 53 and the iris motor 55.

  When the shutter button 6 is pressed by the user, the processing of the image signal output from the CCD image sensor 39 is started, and the image data is processed by the correlated double sampling circuit, the amplification circuit, and the A / D conversion circuit. It is formed. The formed image data is temporarily stored in the SDRAM 73. The image data stored in the SDRAM 73 is compressed to a predetermined image quality by the compression processing unit 72 according to the JPEG standard, and is recorded on the recording medium 82 via the media controller 75.

  In the above embodiment, the mount detection unit 69 detects whether or not the protrusion 32 is engaged with the notch 35 based on the position of the protrusion 32, and the protrusion 32 is engaged with the notch 35. The mount detection unit 69 inputs a detection signal to the lead unit 68, and the read unit 68 starts reading data from the data memory 42 in response to the input of the detection signal, but the lens unit 22 is mounted on the mount unit 23a. The method of detecting whether or not is not limited to this. For example, a switch that is pressed by the flange of the lens unit is provided around the mount portion formed on the camera body, and an ON signal is input to the lead portion in response to the lens unit being mounted on the camera body. May read data from the data memory in response to an ON signal input. Even when the mounting of the lens unit is detected by such a method, data can be reliably read from the data memory.

  In the above embodiment, the photographing lens provided in the lens unit is a type of lens that moves in the optical axis direction and focuses the lens. However, the photographing lens is a zoom lens that includes a plurality of magnifications. It doesn't matter. FIG. 7 is a block diagram schematically showing the electrical configuration of the digital camera. The lens unit 22 includes a photographic lens 89 that can perform a zoom operation, and further includes a zoom motor 90 that is driven during zooming and a focus motor 91 that is driven when focusing. The zoom motor 90 and the focus motor 91 are driven by drive pulses supplied from the zoom motor controller 94 and the focus motor controller 95, respectively. The CCD image sensor 96 is composed of 960 pixels vertically and 1280 pixels horizontally, and has a size corresponding to the photographing lens 89. In the data memory 98, specification information of the photographing lens 4 such as the zoom magnification, F value, and focal length of the photographing lens 89, the number of pixels of the CCD image sensor 96, sensitivity, filter information regarding the color filter, defective pixel information, and the like. The specification information of the CCD image sensor 96 is stored. The CCD image sensor 93 has a size of 960 pixels vertically and 1280 pixels horizontally corresponding to a 3 × zoom lens. However, the size of the CCD image sensor is not limited to this. For example, a 5 × zoom lens is used. When incorporated in a lens barrel, a CCD image sensor having a size of 1920 pixels in the vertical direction and 2560 pixels in the horizontal direction is used. By incorporating a CCD image sensor suitable for the photographing lens in advance, a higher-performance lens unit can be provided.

  In the above embodiment, the lens unit and the camera body are controlled based on the specification information of the photographing lens stored in the data memory of the lens unit and the specification information of the CCD image sensor. The control method is not limited to this. For example, identification information for identifying the lens unit is stored in advance in the data memory as unique data of the lens unit. As identification information, for example, binary data consisting of several bits can be used to shorten the data transfer time. When the lens unit is attached to the camera body, the identification information is read from the data memory, and the read identification information is written in the ROM. Various programs for controlling the operation of the digital camera 2 are stored in the ROM provided in the camera body, and the control unit controls the lens unit from the ROM based on the lens unit identification information written in the RAM. A control program is read out and executed. By doing so, it can be expected to shorten the time from when the lens unit is mounted to the camera body until the start of shooting.

  In the above embodiment, a digital camera is exemplified. However, the present invention is not limited to this, and the present invention is not limited to this, and is implemented in a camera-equipped mobile phone that has a telephone function and processes image signals from a CCD image sensor to form image data. May be. As shown in FIG. 8, the camera-equipped mobile phone 110 includes a caller (camera body) 112 having a call function, and a lens unit 114 that can be detachably attached to the caller 112. The lens unit 114 exposes a photographic lens 116, and a CCD image sensor (not shown) in the lens unit 114 or an EEPROM (data that stores data unique to the lens unit 114 including the photographic lens 116 and the CCD image sensor). Storage means). A second connector 118 connected to a first connector (not shown) provided on the lens unit 114 is provided on the upper side of the communication unit 112, and reading from an EEPROM provided on the lens unit is performed inside the communication unit 112. A control unit (not shown) for controlling the lens unit 114 based on the obtained data is provided. When the lens unit 114 is attached to the telephone set 112, the data stored in the EEPROM provided in the lens unit 114 is written in the RAM provided in the camera body 112, and the lens is based on the data written in the RAM. Control of the unit 114 is executed. Thus, by implementing the present invention for a camera-equipped mobile phone, it is possible to provide a low-cost camera-equipped mobile phone while facilitating the design of a lens unit that enables acquisition of high-quality images. Furthermore, it is possible to provide a camera-equipped mobile phone that can start shooting in a shorter time after the lens unit is attached to the telephone set.

  In the above embodiment, the control unit controls the lens unit and the camera body based on the data read from the data memory of the lens unit. However, the target controlled by the control unit may be only the camera body. For example, a lens unit having a pan focus lens that is in focus from near to far is attached to the camera body, and in accordance with this, spec information is read from the data memory to the SDRAM of the camera body. When the shutter button is pressed by the user, the control unit sends a drive signal to the timing generator based on the spec information. The timing generator inputs a driving pulse to the CCD driver according to the input of the driving signal, and the CCD image sensor outputs an image signal according to the driving pulse input from the CCD driver. At this time, the mechanical shutter and iris provided in the lens unit are not operated, and an image signal is output using an electronic shutter function for adjusting the drive time of the CCD image sensor. The signal processing unit processes the image signal to form image data, and the image correction unit corrects the image data based on the color tone correction data and the shading correction data. In this way, the control unit may acquire image data without controlling the lens unit. In addition, when the digital camera is manually set and in a specific case, only the camera body can be controlled to acquire image data. For example, when the ISO sensitivity is set manually, the electronic shutter function of the CCD image sensor supports this, and when the shooting environment such as daylight shooting or indoor shooting is set manually, the image correction unit corrects the image data accordingly. By doing so, it is possible to acquire image data by controlling only the camera body. In this way, the control unit controls only the camera body, so that reduction of power consumption of the digital camera can be expected.

It is the perspective view which observed the digital camera of the present invention from the front. It is the perspective view which observed the digital camera later. It is a perspective view of the digital camera which separated the lens unit from the camera body. It is sectional drawing which cut | disconnected longitudinally the periphery of the lens unit and the mount of a camera main body along the optical axis of a photographic lens. It is the block diagram which showed roughly the electric structure of the digital camera which consists of a lens unit and a camera main body. It is a flowchart explaining the effect | action of this invention. It is the block diagram which showed roughly the electric structure of the digital camera provided with the zoom lens. It is a perspective view of the mobile phone comprised from the camera main body provided with the telephone call function, and the lens unit which can be attached or detached to this camera main body.

Explanation of symbols

2 Digital camera (photographing device)
4 Photographing lens 23 Mount part 39 CCD image sensor (imaging device)
42 Data memory (data storage means)
43 1st connector 52 2nd connector 65 Signal processing part (signal processing means)
67 Control unit (control means)
68 Lead part (lead means)
69 Mount detector (detection means)

Claims (3)

In an imaging device having an imaging device that outputs an image signal based on a subject image formed by a shooting lens,
A lens unit including the photographing lens and the imaging element;
A camera main body comprising: a mount part to which the lens unit can be detachably attached; and a signal processing means for forming image data of a subject based on an image signal input from the lens unit attached to the mount part. And consists of
The lens unit is provided with data storage means for storing data unique to the lens unit, and a first connector for outputting the data stored in the data storage means to the outside,
The camera body includes a second connector connected to the first connector, and a reading unit that reads data from the data storage unit via the second connector when the lens unit is mounted on the mount unit. An imaging apparatus comprising: control means for controlling at least one of the lens unit and the camera body based on data read by the reading means.   Spec information relating to specs of at least one of the photographic lens and the image sensor is stored as unique data of the lens unit, and the control means is configured to store the lens unit based on the spec information. The photographing apparatus according to claim 1, wherein at least one of the camera body and the camera body is controlled.   The camera body is provided with detection means for detecting whether or not the lens unit is attached to the mount part, and the detection means detects that the lens unit is attached to the mount part. The photographing apparatus according to claim 1, wherein the reading unit starts reading data from the data storage unit.

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