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Digital Camera Patent Abstract
A digital camera is composed of a camera body and a lens unit removebly
attached to the camera body. When the lens unit is attached to the
camera body, the lens unit and camera body send and receive control
signals by antennas and wireless I/Fs each disposed on the lens
unit and the camera body, respectively. In addition, data of the
image captured with the lens unit is sent to the camera body by
serial drivers, each disposed on the lens unit and the camera body,
through connection contacts that electrically connect the lens unit
and the camera body. When the lens unit is detached from the camera
body, on the other hand, the control signals are sent and received
by the antennas and the wireless I/Fs, and the image data is sent
by the wireless communication.
Digital Camera Patent Claims
1. A digital camera including a lens unit having a taking lens and
a solid state imaging device and outputting image data, and a camera
body to which said lens unit is removably attached and storing said
image data, said digital camera comprising: a wireless communication
device for sending and receiving data between said lens unit and
said camera body via radio waves; a one-way communication device
for communicating data faster than said wireless communication device
in one direction from said lens unit to said camera body when said
lens unit is attached to said camera body; a lens detector for detecting
attachment/detachment of said lens unit to/from said camera body;
and a controller for controlling the data communication, said controller
controlling said wireless communication device to send and receive
control signals between said lens unit and said camera body via
said radio waves while controlling said one-way communication device
to send image data obtained with said lens unit to said camera body
when the attachment of said lens unit is detected by said lens detector,
said controller controlling said wireless communication device to
send and receive said control signals between said lens unit and
said camera body via said radio waves and to send said image data
to said camera body via said radio waves when the detachment of
said lens unit is detected by said lens detector.
2. A digital camera as claimed in claim 1, wherein said one-way
communication device is a high-speed serial communication device
using Low-Voltage Differential Signaling for communicating said
data through connection contacts which electrically connect said
lens unit and said camera body when said lens unit is attached to
said camera body.
3. A digital camera as claimed in claim 1, wherein said one-way
communication device is a short range optical communication device.
4. A digital camera as claimed in claim 1, wherein said controller
controls said one-way communication device to send main image data
with predetermined number of pixels to said camera body and stores
said main image data in a first memory in said camera body when
an image is captured with said lens unit attached to said camera
body, and said controller stores said main image data in a second
memory in said lens unit and controls said wireless communication
device to send thumbnail image data with lower number of pixels
than said main image data to said camera body and stores said thumbnail
image data in said first memory when an image is captured with said
lens unit detached from said camera body.
5. A digital camera as claimed in claim 4, wherein said lens unit
includes a compression device for compressing said image data, and
said camera body includes a comparing device for comparing a data
rate necessary for sending said main image data to said camera body
with an effective data transmission rate of said wireless communication
device, said comparing device comparing said data rate with said
effective data transmission rate when the detachment of said lens
unit is detected by said lens detector, said thumbnail image data
compressed by said compression device being sent to said camera
body via said radio waves when said data rate is more than said
effective data transmission rate, said main image data compressed
by said compression device being sent to said camera body via said
radio waves when said data rate is equal to or less than said effective
data transmission rate.
6. A digital camera as claimed in claim 5, wherein when said data
rate is more than said effective data transmission rate, a thumbnail
image file including said thumbnail image data and link information
to said main image data corresponding to said thumbnail image data
is stored in said first memory of said camera body, and a main image
file including said main image data and link information to said
thumbnail image data corresponding to said main image data is stored
in said second memory of said lens unit.
7. A digital camera as claimed in claim 6, wherein said thumbnail
image file and said main image file have an identical file name.
8. A digital camera as claimed in claim 7, wherein said camera
body has a display device for displaying said main image data and
said thumbnail image data on an identical screen.
9. A digital camera as claimed in claim 6, wherein said wireless
communication device sends at least one of said file name and a
folder name of said thumbnail image file stored in said first memory
to said lens unit, and wherein said main image file is assigned
with a file name or a folder name derived from said file name or
said folder name sent from said first memory.
10. A digital camera as claimed in claim 6, wherein when said lens
unit is attached, said controller sends a command requesting said
lens unit for said main image file corresponding to said thumbnail
image file in a case where said thumbnail image file is stored in
said first memory, and replaces said thumbnail image file by said
main image file when receiving said main image file corresponding
to said thumbnail image file from said lens unit in accordance with
said command.
11. A digital camera as claimed in claim 6, wherein when said thumbnail
image file stored in said first memory is a thumbnail movie file,
thumbnail movie data included in said thumbnail movie file is added
to a main movie file stored in said second memory before said thumbnail
movie file is replaced by said main movie file.
12. A digital camera as claimed in claim 5, wherein said controller
controls said one-way communication device to send through image
data obtained with said lens unit to said camera body when the attachment
of said lens unit is detected by said lens detector, and said controller
controls said compression device to compress said through image
data and controls said wireless communication device to send said
compressed through image data to said camera body when the detachment
of said lens unit is detected by said lens detector.
Digital Camera Patent Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to a digital camera composed
of a lens unit having a taking lens and a solid state imaging device,
and a camera body to which the lens unit is removably attached.
[0003] 2. Description Related to the Prior Art
[0004] Digital cameras are widely used, and include a solid state
imaging device such as a CCD image sensor for capturing an image
to store data of the image to a data storage. Digital cameras in
which a lens unit having a taking lens and a solid state imaging
device is removably attached to a camera body are also known.
[0005] Among such digital cameras, some allow both remote photographing
and normal photographing. In the remote photographing, photographing
is performed while the lens unit is detached from the camera body,
and the data is exchanged wirelessly between the lens unit and the
camera body. In the normal photographing, photographing is performed
while the lens unit is attached to the camera body (for example,
Japanese patent laid-open publication Nos. 10-117302, 10-243277
and 11-298770, and U.S. Pat. No. 6,052,509 corresponding to Japanese
patent laid-open publication No. 9-261519).
[0006] The digital cameras disclosed in the above publications
are composed of a lens unit having a solid state imaging device
incorporated therein, and a camera body to which the lens unit is
removably attached. The camera body processes and stores image data,
and also displays the image. These digital cameras have a wireless
communication device for sending and receiving data via radio waves
between the lens unit and the camera body. The digital cameras are
capable of the remote photographing by sending and receiving image
data and control signals via radio waves. Since there is no restraint
of a cable, such digital cameras are easier to handle than the digital
cameras in which the lens unit and the camera body are connected
through the cable.
[0007] In the digital cameras disclosed in the above publications,
however, communication speed of the wireless communication is generally
slower than that of wired communication. Therefore, the communication
speed becomes insufficient when large volumes of image data are
obtained by the lens unit per unit time, such as during high speed
continuous shooting of still images or high definition movie shooting.
There is another problem in that the data transmission has to be
performed with extremely wideband frequency.
[0008] Moreover, the wireless communication has lower stability
as compared to the wired communication. Therefore, when noise occurs
during the transfer of movie data, the data transfer momentarily
stops, and the movie data having defect may be recorded in a recording
medium of the camera body.
[0009] The data communication can also be performed by wired communication
through connection contacts such as mount portions or slots when
the lens unit is attached to the camera body. Accordingly, the disadvantage
of slow communication speed can be improved by switching to the
wired communication when the lens unit is attached to the camera
body. However, such solution of merely switching the communication
system brings another problem that the wireless communication device
is wasted when the lens unit is attached to the camera body.
SUMMARY OF THE INVENTION
[0010] An object of the present invention is to provide a digital
camera capable of remote photographing and preventing insufficiency
of communication speed, at a low cost.
[0011] In order to achieve the above and other objects, a digital
camera of the present invention composed of a lens unit having a
taking lens and a solid state imaging device, and a camera body
to which the lens unit is removably attached includes a wireless
communication device, a one-way communication device, a lens detector
and a controller. The wireless communication device sends and receives
data between the lens unit and the camera body via radio waves.
The one-way communication device communicates data faster than the
wireless communication device in one direction from the lens unit
to the camera body when the lens unit is attached to the camera
body. The lens detector detects attachment/detachment of the lens
unit to/from the camera body. The controller controls the data communication.
When the attachment of the lens unit to the camera body is detected
by the lens detector, the controller controls the wireless communication
device to send and receive control signals between the lens unit
and the camera body via the radio waves. At the same time, the controller
controls the one-way communication device to send image data obtained
with the lens unit to the camera body. When the detachment of the
lens unit from the camera body is detected by the lens detector,
the controller controls the wireless communication device to send
and receive the control signals between the lens unit and the camera
body via the radio waves and to send the image data to the camera
body via the radio waves.
[0012] The one-way communication device is preferably a high-speed
serial communication device using Low-Voltage Differential Signaling
for the one way communication through connection contacts which
electrically connect the lens unit and the camera body when the
lens unit is attached to the camera body. The one-way communication
device may be a short range optical communication device.
[0013] When an image is captured with the lens unit attached to
the camera body, the controller preferably controls the one-way
communication device to send main image data with predetermined
number of pixels to the camera body, and the main image data is
stored in a first memory in the camera body. When an image is captured
with the lens unit detached from the camera body, the controller
stores the main image data in a second memory in the lens unit and
controls the wireless communication device to send thumbnail image
data with lower number of pixels than the main image data to the
camera body, and the thumbnail image data is stored in the first
memory.
[0014] Preferably, the lens unit includes a compression device
for compressing the image data, and the camera body includes a comparing
device for comparing a data rate necessary for sending the main
image data to the camera body with an effective data transmission
rate of the wireless communication device. The comparing device
compares the data rate with the effective data transmission rate
when the detachment of the lens unit from the camera body is detected
by the lens detector. When the data rate is more than the effective
data transmission rate, the thumbnail image data compressed by the
compression device is preferably sent to the camera body via the
radio waves. When the data rate is equal to or less than the effective
data transmission rate, the main image data compressed by the compression
device is preferably sent to the camera body via the radio waves.
[0015] When the data rate is more than the effective data transmission
rate, it is preferable that a thumbnail image file including the
thumbnail image data and link information to the main image data
corresponding to the thumbnail image data is stored in the first
memory of the camera body, and a main image file including the main
image data and link information to the thumbnail image data corresponding
to the main image data is stored in the second memory of the lens
unit.
[0016] The thumbnail image file and the main image file preferably
have an identical file name.
[0017] It is preferable that the camera body has a display device
for displaying the main image data and the thumbnail image data
on an identical screen.
[0018] The wireless communication device preferably sends at least
one of the file name and a folder name of the thumbnail image file
stored in the first memory to the lens unit. The main image file
is preferably assigned with a file name or a folder name derived
from the file name or the folder name sent from the first memory.
[0019] When the lens unit is attached to the camera body, it is
preferable that the controller sends a command requesting the lens
unit for the main image file corresponding to the thumbnail image
file in a case where the thumbnail image file is stored in the first
memory, and replaces the thumbnail image file by the main image
file when receiving the main image file corresponding to the thumbnail
image file from the lens unit in accordance with the command.
[0020] When the thumbnail image file stored in the first memory
is a thumbnail movie file, it is preferable that thumbnail movie
data included in the thumbnail movie file is added to a main movie
file stored in the second memory before the thumbnail movie file
is replaced by the main movie file.
[0021] When the attachment of the lens unit to the camera body
is detected by the lens detector, the controller preferably controls
the one-way communication device to send through image data obtained
with the lens unit to the camera body. When the detachment of the
lens unit from the camera body is detected by the lens detector,
the controller preferably controls the compression device to compress
the through image data and controls the wireless communication device
to send the compressed through image data to the camera body.
[0022] According to the present invention, the wireless communication
device is used only for sending and receiving the control signals,
and the image data is sent by the one-way communication device when
the lens unit is attached to the camera body. Owing to this, it
is possible to make the best use of the wireless communication device
and the one-way communication device. In addition, since the image
data is sent by the one-way communication device, the communication
speed is prevented from being insufficient. Moreover, since the
one-way communication device is used only for sending the image
data, the number of the connection contacts which electrically connect
the lens unit and the camera body can be reduced, and therefore
the production costs can be lowered.
[0023] The one-way communication device helps lowering the production
costs as compared to a two-way communication device.
[0024] When an image is captured with the lens unit detached from
the camera body, the main image data is stored in the second memory
in the lens unit, and the thumbnail image data is sent to the camera
body by the wireless communication device and stored in the first
memory. Therefore the movie shooting or the high speed continuous
shooting of still images can be performed regardless of the communication
speed of the wireless communication device. Since the main image
data is not sent to the camera body by the wireless communication
device, an occurrence of noise on the main image data due to the
lack of speed of the wireless communication can be prevented.
[0025] When an image is captured with the lens unit detached from
the camera body, the main image data is not transferred, but the
compressed thumbnail image data is transferred to the camera body
in a case where the data rate is more than the effective data transmission
rate. Owing to this, the communication speed of the control signals
by the wireless communication device can be prevented from lowering,
and therefore degradation in response time for each operation can
be prevented.
[0026] The main image file is assigned with the file name or the
folder name derived from the file name or the folder name of the
thumbnail image file. Owing to this, it is easy to find the files
which correspond to each other. When the main image file and the
thumbnail image file have the identical file name, it becomes even
easier to find the files corresponding to each other.
[0027] The thumbnail image data and the main image data are displayed
on the identical screen, and therefore the images captured while
the lens unit is detached from the camera body can be checked.
[0028] When the lens unit is attached to the camera body after
an image is captured with the lens unit detached from the camera
body, the thumbnail image file stored in the first memory is automatically
replaced by the main image file stored in the second memory. Owing
to this, it is prevented that the thumbnail and main image files
are left stored in two different memories separately.
[0029] When the thumbnail image file is the thumbnail movie file,
the thumbnail movie data included in the thumbnail movie file is
added to the main movie file before the thumbnail movie file is
replaced by the main movie file. Owing to this, the main movie file
can be produced efficiently.
[0030] When the lens unit is detached from the camera body, the
through image data is sent after being compressed, and therefore
reducing burden on the wireless communication device. Accordingly,
the communication speed of the control signals can be prevented
from lowering.
BRIEF DESCRIPTION OF THE DRAWINGS
[0031] The above objects and advantages of the present invention
will become more apparent from the following detailed description
when read in connection with the accompanying drawings, in which:
[0032] FIG. 1 is a perspective view illustrating a digital camera
in which a lens unit is detached from a camera body according to
a first embodiment of the present invention;
[0033] FIG. 2 is a rear view of the camera body;
[0034] FIG. 3 is a plan view illustrating a mode selection dial;
[0035] FIG. 4 is an explanatory view illustrating a setup screen;
[0036] FIG. 5 is a block diagram illustrating an electrical structure
of the digital camera according to the first embodiment,
[0037] FIG. 6 is a block diagram illustrating a structure of a
lens detector;
[0038] FIG. 7 is an explanatory view illustrating a composition
of a main still image file;
[0039] FIG. 8 is an explanatory view illustrating a composition
of a thumbnail still image file;
[0040] FIG. 9 is an explanatory view illustrating a composition
of an incomplete main movie file;
[0041] FIG. 10 is an explanatory view illustrating a composition
of a thumbnail movie file;
[0042] FIG. 11 is an explanatory view illustrating a composition
of a complete main movie file;
[0043] FIG. 12 is an explanatory view illustrating a memory structure
of a recording medium in the camera body in which only main image
files are stored;
[0044] FIG. 13 is an explanatory view illustrating the memory structure
of the recording medium in the camera body in which thumbnail image
files are also stored after remote photographing;
[0045] FIG. 14 is an explanatory view illustrating a memory structure
of a recording medium in the lens unit;
[0046] FIG. 15 is an explanatory view illustrating the memory structure
of the recording medium in the camera body in which the thumbnail
image files are replaced by main image files after a synchronization
process;
[0047] FIG. 16 is a flow chart explaining a production process
of initialization information;
[0048] FIG. 17 is the flow chart continued from FIG. 16 explaining
the production process of initialization information;
[0049] FIG. 18 is a flow chart explaining an image capturing process
to store a main image file in the lens unit and a thumbnail image
file in the camera body when a still image is captured by the remote
photographing;
[0050] FIG. 19 is the flow chart continued from FIG. 18 explaining
the image capturing process to store the main image file in the
lens unit and the thumbnail image file in the camera body when the
still image is captured by the remote photographing;
[0051] FIG. 20 is a flow chart explaining an image capturing process
only to store the main image file in the camera body when a still
image is captured by the remote photographing;
[0052] FIG. 21 is a flow chart explaining an image capturing process
to store the main image file in the camera body when a still image
is captured by normal photographing;
[0053] FIG. 22 is the flow chart continued from FIG. 21 explaining
the image capturing process to store the main image file in the
camera body when the still image is captured by the normal photographing;
[0054] FIG. 23 is a flow chart explaining the synchronization process;
[0055] FIG. 24 is the flow chart continued from FIG. 23 explaining
the synchronization process;
[0056] FIG. 25 is a perspective view illustrating a digital camera
in which a lens unit is detached from a camera body according to
a second embodiment of the present invention; and
[0057] FIG. 26 is a block diagram illustrating an electrical structure
of the digital camera according to the second embodiment.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0058] In FIG. 1, a digital camera 10 according to a first embodiment
is explained. The digital camera 10 is composed of a camera body
11 and a lens unit 12. The lens unit 12 is removably attached to
the camera body 11. The digital camera 10 is capable of normal photographing
which is performed while the lens unit 12 is attached to the camera
body 11 and remote photographing which is performed while the lens
unit 12 is detached from the camera body 11.
[0059] At a front surface of the lens unit 12, a taking lens 13
is located. A lens side mount portion 14 is formed at a rear surface
of the lens unit 12. The lens side mount portion 14 has three bayonet
claws 15 arranged at regular intervals along an outer periphery
of the lens side mount portion 14. Inside of the lens unit 12 is
provided a CCD image sensor (hereinafter, CCD) 16 as a solid state
imaging device for capturing a subject image focused by the taking
lens 13.
[0060] An antenna 17 for sending and receiving data with the camera
body 11 is disposed on an outer peripheral face of the lens unit
12. The lens side mount portion 14 is provided with a lens connection
contact group 18. The lens connection contact group 18 is composed
of, for example, twenty four connection contacts PL1 to PL24 (see
FIG. 6). Each bayonet claw 15 has eight connection contacts. As
the lens unit 12, several kinds of the lens units with different
focal lengths of the taking lens 13 or with different numbers of
pixels in the CCD 16, or those capable of monochrome photography,
infrared photography or the like are prepared.
[0061] A camera side mount portion 19 is formed at a front surface
of the camera body 11. The camera side mount portion 19 has three
bayonet gaps 20 arranged at regular intervals along an outer periphery
of the camera side mount portion 19. In order to attach the lens
unit 12 to the camera body 11, the bayonet claws 15 are forced into
the bayonet gaps 20, and the lens unit 12 is rotated in clockwise
direction, thereby coupling the bayonet claws 15 with the bayonet
claws 20a in a meshed manner.
[0062] When the lens unit 12 is attached to the camera body 11,
the lens connection contact group 18 is electrically connected to
a camera connection contact group 59 (see FIG. 5) provided on the
camera side mount portion 19. As in the case of the lens connection
contact group 18, the camera connection contact group 59 is composed
of twenty four connection contacts PB1 to PB24 (see FIG. 6). Each
of the connection contacts PB1 to PB24 is connected to each of the
connection contacts PL1 to PL24 of the lens unit 12 when the lens
unit 12 is attached to the camera body 11.
[0063] In addition, the camera side mount portion 19 is provided
with a lock pin 21. When the lens unit 12 is attached to the camera
body 11, the lock pin 21 becomes engaged with a pin hole (not shown)
of the lens side mount portion 14, and rotation of the lens unit
12 is locked. Owing to this, the lens unit 12 is prevented from
dropping off from the camera body 11.
[0064] A mount lid 22 is contained inside the camera side mount
portion 19. The mount lid 22 is biased by a spring in a forward
direction, so as to prevent dust or the like from entering to the
camera body 11 while the lens unit 12 is not attached.
[0065] A lock release button 23 is located near the camera side
mount portion 19. When the lock release button 23 is depressed while
the lens unit 12 is attached to the camera body 11, the lock pin
21 is moved backwards and released from the engagement with the
pin hole. When the lock release button 23 is depressed, and the
lens unit 12 is rotated, the lens unit 12 is detached from the camera
body 11.
[0066] A flash unit 24 is disposed on the upper front surface of
the camera body 11. A shutter button 25, a mode selection dial 26
and an antenna 27 are disposed on an upper surface of the camera
body 11. The shutter button 25 is depressed when an image is captured.
The mode selection dial 26 is rotated to select a mode. The antenna
27 sends and receives data with the lens unit 12 via radio waves.
[0067] As shown in FIG. 2, a power operation button 28, an LCD
29, a cursor operating button 31, a menu button 32, an execution
button 33 and a cancel button 34 are disposed on a rear surface
of the camera body 11. The LCD 29 displays images, various setup
screens and the like.
[0068] The camera body 11 has a movie capture mode, a still image
capture mode, a setup mode for making various settings, and a playback
mode for reproducing recorded images. The mode selection dial 26
is rotated to select one of the modes. As shown in FIG. 3, for example,
when a symbol "Cam" on the mode selection dial 26 is positioned
to an arrow 35, the still image capture mode is selected. Similarly,
"Mov" selects the movie capture mode, "Setup"
selects the setup mode and "Play" selects the playback
mode.
[0069] When the setup mode is selected by rotating the mode selection
dial 26 to "Setup" position, for example, a setup screen
shown in FIG. 4 is displayed on the LCD 29. At this time, setting
of a desired item can be modified by operating the operation buttons
31 to 34.
[0070] For example, in the item of "MEMORY MODE", either
"FINE" or "BASIC" as to image quality (JPEG
compression rate) is selected by placing a cursor 36 on one of them,
and operating the execution button 33.
[0071] In the item of "NUMBER OF RECORDED PIXELS", one
of "2400.times.1800", "1600.times.1200", "1024.times.768"
and "640.times.480" is selected for "STILL IMAGE",
and one of "1920.times.1080", "640.times.480"
and "320.times.240" is selected for "MOVIE".
In the item of "SHARPNESS", one of "HARD", "NORMAL"
and "SOFT" is selected.
[0072] As shown in FIG. 5, the lens unit 12 has a lens controller
40 for controlling each part of the lens unit 12. The lens controller
40 is provided with a ROM 40a and a RAM 40b. The ROM 40a stores
a program for controlling each part of the lens unit 12. The RAM
40b temporarily stores work data. The lens controller 40 controls
each part of the lens unit 12 based on the program stored in the
ROM 40a.
[0073] A timing generator (hereinafter, TG) 42 is connected to
the lens controller 40 through a data bus 41. The CCD 16, an analog
signal processor 43, an A/D converter 44 and a digital signal processor
45 are connected to the TG 42, and controlled by a timing signal
generated by the TG 42.
[0074] The lens controller 40 controls the TG 42 to drive the CCD
16, the analog signal processor 43, the A/D converter 44 and the
digital signal processor 45. The CCD 16 photoelectrically converts
the subject image focused by the taking lens 13 into an electric
signal and outputs it as an image signal.
[0075] The CCD 16 is connected to the analog signal processor 43
and outputs the image signal thereto. The analog signal processor
43 is connected to the A/D converter 44. The analog signal processor
43 removes noise from the image signal and/or amplifies the same,
and outputs it to the A/D converter 44. The processed image signal
is converted from an analog signal form into a digital signal form
in the A/D converter 44 to be output as image data.
[0076] The A/D converter 44 is connected to the digital signal
processor 45. The digital signal processor 45 applies various image
processing such as offset correction, white balance (WB) correction,
y correction, YC conversion and the like to the image data obtained
from the A/D converter 44, and converts the image data into a YC
signal in an uncompressed state in real time.
[0077] When the lens unit 12 is attached to the camera body 11,
the YC signal is transferred in real time to the camera body 11
by a serial driver 48 which is described later. When the lens unit
12 is detached from the camera body 11, on the other hand, it takes
time to transfer the uncompressed YC signal by the wireless communication.
Therefore, the YC signal is firstly compressed in a compression
circuit 47 in the lens unit 12, and then transferred to the camera
body 11. The digital signal processor 45 also has a function to
produce thumbnail movie data by resizing main movie data, a function
to produce thumbnail still image data by resizing main still image
data, a function to produce through image data, and other functions.
Note that such data may be produced in the compression circuit 47,
as described later.
[0078] An AE/AF detector 46 is connected to the A/D converter 44,
and the image data is input to it from the A/D converter 44. The
AE/AF detector 46 is connected to the lens controller 40 through
the data bus 41, and controlled by the lens controller 40. The AE/AF
detector 46 detects an AE detection value and an AF detection value
based on the image data. The AE detection value is a value at which
most appropriate exposure is obtained. The AF detection value is
a value at which highest integration value of high-frequency components
in the image data is obtained. The AE and AF detection values obtained
by the AE/AF detector 46 are input to the lens controller 40.
[0079] The lens controller 40 controls electric shutter speed of
the CCD 16 based on the AE detection value, and moves a focus lens
of the taking lens 13 to an in-focus position by controlling a motor
(not shown) based on the AF detection value.
[0080] Besides the lens controller 40, the TG 42, the digital signal
processor 45 and the AE/AF detector 46, the compression circuit
47, the serial driver 48, a wireless I/F 49 and a media controller
51 are connected to the data bus 41, and controlled by the lens
controller 40.
[0081] The compression circuit 47 has a function to apply JPEG
compression to the through image data or the thumbnail movie data,
to which various image processing have been applied in the digital
signal processor 45, so as to convert it into Motion JPEG format,
a function to apply MPEG compression (MPEG-2, MPEG-4 compression
and the like) to the main movie data when capturing a movie, and
other functions. The compression format is not limited to the above,
but may be, for example, H.264 and so forth.
[0082] The serial driver 48 is connected to the lens connection
contact group 18. The serial driver 48 converts the image data of
a parallel signal form into a serial signal form, and sends the
image data to the camera body 11 through the lens connection contact
group 18. Note that the serial driver 48 transfers the image data
by Low-Voltage Differential Signaling (LVDS). The LVDS uses the
difference in voltage between two wires, and transfers image data
at high speed by serial transmission.
[0083] The wireless I/F 49 is connected to the antenna 17. Data
such as control signals are converted into data for wireless transmission
in the wireless I/F 49, and sent to the camera body 11 from the
antenna 17. The antenna 17 also receives data such as the control
signals sent from the camera body 11. Note that the wireless I/F
49 is a wireless LAN device (IEEE802.11b), and the antenna 17 sends
and receives the data in the 2.4 GHz bandwidth.
[0084] The medial controller 51 stores the compressed image data
in a recording medium 52 and reads out the image data stored in
the recording medium 52. Note that the recording medium 52 is, for
example, a memory card removably connected to the lens unit 12.
[0085] A power controller 53 is connected to the lens connection
contact group 18. A battery 54 and a DC/DC converter 55 are connected
to the power controller 53. The battery 54 is also connected to
the DC/DC converter 55. The power controller 53 controls the DC/DC
converter 55 to decrease the voltage supplied from the battery 54
to a predetermined value. Then, the decreased voltage is supplied
to each part of the lens unit 12. The DC/DC converter 55 is connected
to the lens connection contact group 18.
[0086] A power operating section 56 is connected to the power controller
53. The power controller 53 receives operation signals from the
power operating section 56. When an ON-signal as the operation signal
is input from the power operating section 56, the power controller
53 controls the DC/DC converter 55 to start supplying the electric
power to each part of the lens unit 12.
[0087] The camera body 11 has a camera controller 60 for controlling
each part of the camera body 11. The camera controller 60 is provided
with a ROM 60a and a RAM 60b. The ROM 60a stores a program for controlling
each part of the camera body 11. The RAM 60b temporarily stores
work data. The camera controller 60 controls each part of the camera
body 11 based on the program stored in the ROM 60a.
[0088] A serial driver 62, a wireless I/F 63, a compression/decompression
circuit 64, an LCD driver 65, a media controller 66, a flash controller
67 and an I/O port 68 are connected to the camera controller 60
through a data bus 61, and controlled by the camera controller 60.
[0089] The serial driver 62 is connected to the camera connection
contact group 59. The serial driver 62 receives the image data sent
from the serial driver 48 in the lens unit 12 by the LVDS through
the camera connection contact group 59, and converts the image data
of the serial signal form into the parallel signal form.
[0090] The serial drivers 48 and 62 are high-speed serial communication
devices which transfer image data obtained with the lens unit 12
to the camera body 11 in real time by use of two or four connection
contacts of the connection contact groups 18 and 59, respectively
in a parallel manner. The serial drivers 48 and 62 communicate data
only in one way: from the lens unit 12 to the camera body 11. For
this configuration, it is not necessary to provide the camera body
11 with an LVDS transmitter and the lens unit 12 with an LVDS receiver,
and therefore the production costs of the digital camera 10 can
be lowered. Moreover, power consumption can be also lowered as compared
to the case where two-way LVDS communication by use of common signal
lines is performed.
[0091] The wireless I/F 63 is connected to the antenna 27. The
antenna 27 sends and receives the data such as the image data and
the control signals with the lens unit 12. Note that a wireless
communication device is composed of the antennas 17 and 27, and
the wireless I/Fs 49 and 63. The data such as the control signals
are converted into the data for wireless transmission in the wireless
I/F 63, and sent to the lens unit 12 from the antenna 27. The antenna
27 also receives the data such as the image data and the control
signals sent from the lens unit 12. Note that the wireless I/F 63
is the wireless LAN device (IEEE802.11b), and the antenna 27 sends
and receives the data in the 2.4 GHz bandwidth.
[0092] The compression/decompression circuit 64 compresses the
image data received from the lens unit 12. In addition, the compression/decompression
circuit 64 decompresses image data recorded in a recording medium
72, which is described later, when the image data is reproduced.
That is, the compression/decompression circuit 64 has a function
to apply JPEG compression and decompression to the still image data,
a function to apply JPEG compression and decompression to the through
image data or the thumbnail movie data which is sent from the lens
unit 12 in Motion JPEG format, and a function to apply MPEG compression
and decompression to the main movie data when capturing a movie.
[0093] The through image data received from the lens unit 12 and
the image data recorded in the recording medium 72 are input to
the LCD driver 65, and displayed as the through image or the reproduced
image on the LCD 29.
[0094] The media controller 66 receives image data from the lens
unit 12 during the image capturing and records the image data in
the recording medium 72 to sort out from the through image data.
The media controller 66 also reads out the image data in the recording
medium 72. As in the case of the recording medium 52, the recording
medium 72 is the memory card removably connected to the camera body
11.
[0095] The flash controller 67 controls the flash unit 24 so as
to emit flash light. The I/O port 68 sends and receives signals
with the lens unit 12 through the camera connection contact group
59.
[0096] A power controller 75 is disposed in the camera body 11.
A battery 76 and a DC/DC converter 77 are connected to the power
controller 75. The battery 76 is also connected to the DC/DC converter
77. The power operation button 28 is connected to the power controller
75.
[0097] The power controller 75 is receives operation signals (ON/OFF
signals) produced by the operation of the power operation button
28. When the ON-signal is input, the power controller 75 controls
the DC/DC converter 77 to decrease the voltage of the battery 76
to a predetermined value. Then, the decreased voltage is supplied
to each part of the camera body 11. The battery 76 is also connected
to the camera connection contact group 59 and supplies the electric
power to the lens unit 12.
[0098] The shutter button 25 and an operating section 78 are connected
to the camera controller 60. The shutter button 25 outputs a shutter
signal S1 when it is depressed halfway and outputs a shutter signal
S2 when it is fully depressed. The operating section 78 is composed
of the cursor operating button 31, the menu button 32, the execution
button 33 and the cancel button 34, and outputs operation signals
corresponding to each operation button.
[0099] The camera controller 60 receives the shutter signal S1
or S2, or other operation signal, and executes the process corresponding
to each signal. The shutter button 25 is also connected to the camera
connection contact group 59. When the lens unit 12 is connected
to the camera body 11, the shutter signals S1 and S2 are directly
sent to the lens controller 40 in the lens unit 12 through the camera
connection contact group 59 and the lens connection contact group
18.
[0100] Hereinafter, a lens detector which detects attachment/detachment
of the lens unit 12 to/from the camera body 11 is explained. As
mentioned above, the lens connection contact group 18 of the lens
unit 12 is composed of twenty four connection contacts PL1 to PL24,
and the camera connection contact group 59 of the camera body 11
is composed of twenty four connection contacts PB1 to PB24. Each
of the connection contacts PB1 to PB24 of the camera body 11 are
connected to each of the connection contacts PL1 to PL24 of the
lens unit 12 when the lens unit 12 is attached to the camera body
11. For example, the connection contact PL1 is connected to the
connection contact PB1, and the connection contact PL24 is connected
to the connection contact PB24.
[0101] As shown in FIG. 6, for example, the connection contacts
PB22 and PB23 are connected to the I/O port 68. A pull-up resister
80 is connected to the connection contact PB23. The power controller
53 of the lens unit 12 is connected to the connection contact PL22.
The connection contact PL23 is grounded.
[0102] The lens detector which detects the attachment of the lens
unit 12 to the camera body 11 is composed of the connection contacts
PL23 and PB23, the pull-up resistor 80 and the I/O port 68. When
the lens unit 12 is not attached to the camera body 11, an electric
potential of the connection contact PB23 is increased to, for example,
about 5 volts by the pull-up resister 80, and a High-signal is input
to the I/O port 68. When the lens unit 12 is attached to the camera
body 11, the connection contacts PB23 and PL23 are connected to
each other. The connection contact PL23 is grounded, and therefore
the electric potential of the connection contact PB23 becomes 0
volt. Accordingly, a Low-signal is input to the I/O port 68.
[0103] The camera controller 60 obtains the detection signals (Low-signal,
High-signal) from the I/O port 68 and judges whether the lens unit
12 is attached to the camera body 11 or not based on the detection
signal.
[0104] When the lens unit 12 is attached to the camera body 11,
the I/O port 68 and the power controller 53 of the lens unit 12
are connected through the connection contacts PL22 and PB22. When
the camera controller 60 recognizes the attachment of the lens unit
12 after the power operation button 28 is operated to start the
power supply from the battery 76, the camera controller 60 outputs
a power control signal to the power controller 53 of the lens unit
12 through the I/O port 68. Upon receiving this control signal,
the power controller 53 starts supplying the electric power to each
part of the lens unit 12 even without the input of the ON-signal
from the power operating section 56, thereby automatically turning
on the lens unit 12.
[0105] The battery 76 of the camera body 11 is connected to the
connection contact PB21. The DC/DC converter 55 of the lens unit
12 is connected to the connection contact PL21. When the lens unit
12 is attached to the camera body 11, the power controller 53 and
the DC/DC converter 55 are connected to the battery 76 through the
connection contacts PL21 and PB21. Thus, the electric power can
be supplied to the power controller 53 and the DC/DC converter 55
from the battery 76. Owing to this, each part of the lens unit 12
can be driven by the battery 76 even when the battery 54 is not
mounted into the lens unit 12, or when the battery 54 does not have
enough power.
[0106] In the present embodiment, the battery 54 has a smaller
capacity than the battery 76. When the lens unit 12 is attached
to the camera body 11, the lens unit 12 operates on the electric
power supplied from the battery 76 of the camera body 11.
[0107] Next, a composition of a main still image file 85 stored
in the recording medium 72 of the camera body 11 or the recording
medium 52 of the lens unit 12 is explained. As shown in FIG. 7,
the main still image file 85 is composed of Tag information 85a,
thumbnail still image data 85b and main still image data 85c.
[0108] The Tag information 85a is composed of, for example, a manufacture
name, product name, version of the digital camera being used, shooting
date, ID which is individually assigned to the main still image
data 85c, and the like. The ID may be, for example, 128-bit random
numbers, or may be a combination of a serial number which is incremented
after each shooting with a manufacture original code, product name
code, product serial number and the like. The ID is produced by
the lens controller 40 or the camera controller 60, and sent to
the camera body 11 or the lens unit 12 to be stored as the Tag information
for a main image file or a thumbnail image file.
[0109] The thumbnail still image data 85b is of 160.times.120 pixels
and compressed in JPEG format. The main still image data 85c is
also compressed in JPEG format.
[0110] The main still image file 85 is stored in the recording
medium 52 of the lens unit 12 when the lens unit 12 is detached
from the camera body 11 and the wireless communication speed is
low with respect to the capacity of the main still image data 85c.
[0111] Next, a composition of a thumbnail still image file 86 stored
in the recording medium 72 of the camera body 11 is explained. As
shown in FIG. 8, the thumbnail still image file 86 is composed of
Tag information 86a and thumbnail still image data 86b. Unlike the
main still image file 85, the thumbnail still image file 86 does
not include main still image data.
[0112] The Tag information 86a has the same composition as the
Tag information 85a. Like the thumbnail still image data 85b, the
thumbnail still image data 86b is of 160.times.120 pixels and compressed
in JPEG format.
[0113] The thumbnail still image file 86 is stored in the recording
medium 72 of the camera body 11 when the lens unit 12 is detached
from the camera body 11 and the wireless communication speed is
low with respect to the capacity of the main still image data 85c.
[0114] Next, a composition of an incomplete main movie file 87
stored in the recording medium 52 of the lens unit 12 is explained.
As shown in FIG. 9, the main movie file 87 is composed of Tag information
87a, thumbnail still image data 87b and main movie data 87c.
[0115] The Tag information 87a has the same composition as the
Tag information 85a and 86a. The main movie file 87 is completed
when thumbnail movie data is added thereto in the camera body 11.
The incomplete main movie file 87 is stored in the recording medium
52 of the lens unit 12 when the lens unit 12 is detached from the
camera body 11 and the wireless communication speed is low with
respect to the capacity of the main movie data 87c.
[0116] Next, a composition of thumbnail movie file 88 stored in
the recording medium 72 of the camera body 11 is explained. As shown
in FIG. 10, the thumbnail movie file 88 is composed of Tag information
88a, thumbnail still image data 88b and thumbnail movie data 88c.
[0117] The Tag information 88a has the same composition as the
Tag information 87a. The ID in the Tag information 88a corresponds
to the thumbnail still image data 88b and the thumbnail movie data
88c as a link. The thumbnail still image data 88b is of 160.times.120
pixels and compressed in JPEG format. The thumbnail movie data 88c
is of 160.times.120 pixels and compressed in Motion JPEG format.
The thumbnail still image data 88b is shown with an initial frame
of the thumbnail movie data 88c in the present embodiment. However,
other peculiar frame may be extracted as the thumbnail still image
data 88b.
[0118] The thumbnail movie file 88 is stored in the recording medium
72 of the camera body 11 when the lens unit 12 is detached from
the camera body 11 and the wireless communication speed is low with
respect to the capacity of the main movie data 87c.
[0119] As described above, when a movie is captured while the lens
unit 12 is detached from the camera body 11, the incomplete main
movie file 87 shown in FIG. 9 is stored in the recording medium
52 of the lens unit 12, and the thumbnail movie file 88 shown in
FIG. 10 is stored in the recording medium 72 of the camera body
11. Thereafter, when the lens unit 12 is attached to the camera
body 11, a synchronization process is performed, and a complete
main movie file 89 is stored in the recording medium 72 of the camera
body 11, as described later.
[0120] As shown in FIG. 11, the main movie file 89 is composed
of Tag information 89a, thumbnail still image data 89b (160.times.120
pixels/compressed in JPEG format), thumbnail movie data 89c (160.times.120
pixels/compressed in Motion JPEG format) and main movie data 89d
(compressed in MPEG format). When a movie is captured while the
lens unit 12 is attached to the camera body 11, the files 87 and
88 shown in FIGS. 9 and 10 respectively are not produced, but the
main movie file 89 is directly produced and stored in the recording
medium 72 of the camera body 11.
[0121] When a movie is captured while the lens unit 12 is detached
from the camera body 11, the main movie file 89 takes over the same
ID as the files 87 and 88 shown in FIGS. 9 and 10.
[0122] A data rate necessary for transferring the main image data
to the camera body 11 by the remote photographing is explained.
The data rate varies according to the number of pixels for movie,
number of pixels for still image, and memory mode (only for still
image capturing) as shown in Table 1 below. The selectable numbers
of pixels are shown in FIG. 4. The data rates for the still image
are the rates after the JPEG compression, and the data rates for
the movie are the rates after the MPEG compression. Note that the
values in parentheses indicate the volume of data which varies according
to the number of pixels and the memory mode. TABLE-US-00001 TABLE
1 Number Still image Movie of pixels FINE NORMAL (30 fps) 2400 .times.
1800 12.5 Mbps (2.5 MB) 7.5 Mbps (1.5 MB) -- 1920 .times. 1080 --
-- 20 Mbps 1600 .times. 1200 5 Mbps (1 MB) 3.5 Mbps (700 KB) --
1024 .times. 768 2 Mbps (400 KB) 1.25 Mbps (250 KB) -- 640 .times.
480 750 Kbps (150 KB) 500 Kbps (100 KB) 6 Mbps 320 .times. 240 --
-- 2 Mbps
[0123] The data rates shown in Table 1 are compared with effective
data transmission rates of the wireless I/Fs 49 and 63. When the
main image data can be sent, the main image data is transferred
from the lens unit 12 to the camera body 11. When the main image
data cannot be sent, thumbnail image data is produced and sent to
the camera body 11 by the wireless communication.
[0124] The data rate necessary for transferring the main still
image data is the speed for transferring the main still image data
within 0.2 seconds. In the present embodiment, the CCD 16 is capable
of reading out the data at the maximum speed of 0.2 seconds. In
order to perform the high speed continuous shooting, the transfer
of the main still image data has to be completed within 0.2 seconds,
or otherwise the high speed continuous shooting performance is deteriorated.
[0125] Next, a memory structure of the recording medium 72 of the
camera body 11 is explained. As shown in FIG. 12, in the recording
medium 72 of the camera body 11, a folder "DCIM" is formed
starting from a root directory "Root". In the folder "DCIM",
a folder "100ABCD" is formed.
[0126] In the folder "100ABCD", only main still image
files and main movie files are stored with serial file numbers (last
four digits of the file name) assigned thereto. An extension for
the main still image files is "JPG" and that for the main
movie file is "MPEG".
[0127] When two frames of still images and one scene of a movie
are captured while the recording medium 72 of the camera body 11
has the structure shown in FIG. 12, and the numbers of pixels (memory
mode) for both the main still image data and the main movie data
are set to those cannot be sent by the wireless communication, the
recording medium 72 comes to have a structure shown in FIG. 13.
[0128] As shown in FIG. 13, two thumbnail still image files (DSCF009.STH
and DSCF010.STH) and a thumbnail movie file (DSCF011.MTH) are stored
with serial file names assigned thereto. At this time, an extension
for the thumbnail still image files is "STH" and that
for the thumbnail movie file is "MTH". Accordingly, it
is easy to identify them from other main image files.
[0129] When the recording medium 72 of the camera body 11 has the
structure shown in FIG. 13, the recording medium 52 of the lens
unit 12 comes to have a structure shown in FIG. 14. Two main still
image files (DSCF009.JPEG and DSCF010.JPEG) corresponding to the
two thumbnail still image files (DSCF009.STH and DSCF010.STH) in
the recording medium 72, and an incomplete main movie file (DSCF011.MPG)
corresponding to the thumbnail movie file (DSCF011.MTH) in the recording
medium 72 are stored in the recording medium 52 with file names
identical to the corresponding files.
[0130] When the lens unit 12 is attached to the camera body 11
while the recording medium 72 of the camera body 11 has the structure
shown in FIG. 13, and the recording medium 52 of the lens unit 12
has the structure shown in FIG. 14, the synchronization process
is performed as described later. When the synchronization process
is performed, the two thumbnail still image files (DSCF009.STH and
DSCF010.STH) and the thumbnail movie file (DSCF011.MTH) are replaced
by the corresponding main image files (DSCF009.JPEG, DSCF010.JPEG,
DSCF011.MPG) in the recording medium 72, as shown in FIG. 15.
[0131] Next, an operation of the digital camera 10 is explained.
First of all, a production process of initialization information
is explained with referring to FIGS. 16 and 17. The process is to
decide which is sent from the lens unit 12 to the camera body 11
between the main image data and the thumbnail image data, and to
decide the number of pixels and the mode (YC signal without compression
or Motion JPEG compression) of the through image sent from the lens
unit 12 to the camera body 11.
[0132] The camera controller 60 recognizes as to which capture
mode is selected between the movie capture mode and the still image
capture mode. The camera controller 60 then recognizes setting contents
in the SETUP mode.
[0133] Thereafter, the camera controller 60 judges whether the
lens unit 12 is attached to the camera body 11 or not. When it is
judged that the lens unit 12 is attached to the camera body 11,
the camera controller 60 selects the serial drivers 48 and 62 as
a communication channel for the image data from the lens unit 12
to the camera body 11.
[0134] The camera controller 60 sets the through image data to
have the number of pixels of 640.times.480 and to be in YC signal
form without compression (640.times.480/YC signal without compression).
At the same time, the camera controller 60 sets that the main image
data is transferred from the lens unit 12 to the camera body 11.
Moreover, the camera controller 60 sets the image recording operation
in the lens unit 12 to off and finishes the production process of
initialization information.
[0135] When it is judged that the lens unit 12 is not attached
to the camera body 11, the camera controller 60 selects the wireless
communication (802.11b) as the communication channel for the image
data from the lens unit 12 to the camera body 11.
[0136] The camera controller 60 sets the through image data to
have the number of pixels of 160.times.120 and to be compressed
in Motion JPEG format (160.times.120/Motion JPEG compression), and
obtains a necessary data rate RA according to the current setting.
The data rate RA is obtained from the Table 1 based on the image
capture mode, the number of pixels and the memory mode.
[0137] Since communication speed of the wireless communication
(802.11b) changes among 11 Mbps, 5.5 Mbps, 2 Mbps and 1 Mbps depending
on the condition, the camera controller 60 obtains a current speed
mode MB of the wireless communication.
[0138] The camera controller 60 calculates an actual data rate
(effective data transmission rate) RC from the current speed mode
MB (11/5.5/2/1 Mbps) of the wireless communication. The wireless
I/Fs 49 and 63 send and receive the control signals as well as the
image data. Therefore, the actual data rate RC (=MB/4) is calculated
with a safety margin 4 times higher than the speed of the wireless
communication, in order to assure the data rate shown in Table 1.
[0139] The camera controller 60 judges whether the data rate RA
is equal to or less than the actual data rate RC. When the data
rate RA is equal to or less than the data rate RC, the camera controller
60 judges as to whether the capture mode is set to the still image
capture mode or not.
[0140] When it is judged that the still image capture mode is set,
the camera controller 60 sets that the main image data (JPEG compression)
is transferred to the camera body 11. Moreover, the camera controller
60 sets the image recording operation in the lens unit 12 to off
and finishes the production process of initialization information.
[0141] When it is judged that the movie capture mode is set, the
camera controller 60 sets that the main image data (MPEG compression)
is transferred to the camera body 11. Similarly to the still image
capture mode, the camera controller 60 sets the image recording
operation in the lens unit 12 to off and finishes the production
process of initialization information.
[0142] When the data rate RA is more than the data rate RC, the
camera controller 60 judges as to whether the capture mode is set
to the still image capture mode or not.
[0143] When it is judged that the still image capture mode is set,
the camera controller 60 sets that the thumbnail image data (JPEG
compression) is transferred to the camera body 11. Moreover, the
camera controller 60 sets the image recording operation in the lens
unit 12 to on and finishes the production process of initialization
information.
[0144] When it is judged that the movie capture mode is set, the
camera controller 60 sets that the thumbnail image data (MPEG compression)
is transferred to the camera body 11. Moreover, the camera controller
60 sets the image recording operation in the lens unit 12 to on
and finishes the production process of initialization information.
[0145] The initialization information is produced at the time of
the initialization after the power being turned on, at the time
of the attachment/detachment of the lens unit 12 to/from the camera
body 11 in the image capture mode, at the time of changing the mode
to the image capture mode from other modes, and the like.
[0146] An image capturing process in the still image capture mode
when the lens unit 12 is detached from the camera body 11 is explained
with referring to a flow chart in FIGS. 18 and 19.
[0147] First of all, a process in the lens unit 12 is explained.
When the lens unit 12 is turned on by the power operating section
56, the lens controller 40 judges whether connection is requested
by the camera body 11 over the wireless communication (802.11b).
When it is judged that the connection is not requested, the lens
controller 40 stays in a standby state until the connection is requested.
[0148] When it is judged that the connection is requested by the
camera body 11, the lens controller 40 sends a signal in response
to the connection request to the camera body 11 over the wireless
communication (802.11b). Thereafter, the lens controller 40 judges
whether a command for requesting initialization is received or not.
When it is judged that the initialization is not requested, the
lens controller 40 stays in a standby state until the initialization
is requested.
[0149] When it is judged that the initialization is requested from
the camera body 11, the initialization is executed based on the
command received from the camera body 11 over the wireless communication
(802.11b). This command corresponds to the setting contents determined
in the production process of initialization information.
[0150] After the initialization, the lens controller 40 sends a
signal indicating the completion of the initialization to the camera
body 11. The lens controller 40 gets in a state of waiting for a
next command from the camera body 11, and then judges whether a
through image is requested from the camera body 11 or not. When
it is judged that the through image is not requested, the lens controller
40 stays in a standby state until the through image is requested.
[0151] When it is judged that the through image is requested from
the camera body 11, the lens controller 40 controls each part of
the lens unit 12 to perform image capturing by the CCD 16. The lens
controller 40 also controls each part to apply resizing, various
image processing, JPEG compression and the like to the image captured
by the CCD 16. The lens controller 40 then sends this through image
to the camera body 11 over the wireless communication (802.11b).
The through image sent from the lens unit 12 to the camera body
11 is in Motion JPEG format in which each frame is compressed in
JPEG format.
[0152] Thereafter, the lens controller 40 judges whether a shutter
signal S1 is obtained or not. When it is judged that the shutter
signal S1 is not obtained, the lens controller 40 stays in a standby
state until the shutter signal S1 is obtained.
[0153] When it is judged that the shutter signal S1 is obtained,
the lens controller 40 controls each part of the lens unit 12 based
on the AE and AF detection values detected by the AE/AF detector
46 to perform AE/AF processing. When the processing is completed,
the lens controller 40 sends a signal indicating the completion
of the AE/AF processing to the camera body 11.
[0154] When receiving the request for a through image from the
camera body 11, the lens controller 40 controls each part of the
lens unit 12 to perform through image capturing by the CCD 16. The
lens controller 40 also controls each part to apply resizing, various
image processing, JPEG compression and the like to the image captured
by the CCD 16. The lens controller 40 then sends the through image
to the camera body 11 over the wireless communication (802.11b).
[0155] The lens controller 40 judges whether a shutter signal S2
is obtained or not. When it is judged that the shutter signal S2
is not obtained, the lens controller 40 stays in a standby state
until the shutter signal S2 is obtained. When it is judged that
the shutter signal S2 is obtained, on the other hand, the lens controller
40 controls each part of the lens unit 12 to perform image capturing
for recording by the CCD 16. The lens controller 40 also controls
each part to produce main image data by applying JPEG compression
to the image captured by the CCD 16. Moreover, the lens controller
40 adds an ID, which is automatically produced, to this main image
data.
[0156] In addition, the lens controller 40 controls each part of
the lens unit 12 to produce thumbnail image data compressed in JPEG
format, and assigns the ID to the thumbnail image data. The lens
controller 40 then controls the wireless I/F 49 to send the thumbnail
image data to the camera body 11 over the wireless communication
(802.11b). Thereafter, a file name and a folder name of a thumbnail
image file are sent from the camera body 11 over the wireless communication.
These file name and folder name are assigned to the main image,
and thereby producing the main still image file 85 shown in FIG.
7. The lens controller 40 controls the media controller 51 to store
the main still image file 85 in the recording medium 52.
[0157] After the main still image file 85 is stored, the lens controller
40 controls the wireless I/F 49 to send a signal, which indicates
completion of storing of the main still image file 85, to the camera
body 11, and finishes the process of storing.
[0158] Next, a process in the camera body 11 is explained. When
the still image capture mode is set after the camera body 11 is
turned on by the power operation button 28, the camera controller
60 controls the wireless I/F 63 to send the connection request to
the lens unit 12 over the wireless communication (802.11b).
[0159] The camera controller 60 then judges whether the connection
response is received or not. When it is judged that the connection
response is not received, the lens controller 60 stays in a standby
state until the connection response is received. When it is judged
that the connection response is received, the lens controller 60
executes the above described production process of initialization
information.
[0160] The camera controller 60 controls the wireless I/F 63 to
send the command for requesting initialization corresponding to
the produced initialization information to the lens unit 12. The
camera controller 60 confirms completion of the initialization when
receiving the signal indicating the completion from the lens unit
12.
[0161] After confirming the completion of the initialization, the
camera controller 60 controls the wireless I/F 63 to request a through
image to the lens unit 12. The camera controller 60 then controls
each part of the camera body 11 to receive the through image data.
The camera controller 60 also controls each part to decompress the
through image data and display the through image on the LCD 29.
[0162] Thereafter, the camera controller 60 judges whether the
shutter button 25 is depressed halfway or not. When it is judged
that the shutter button 25 is not depressed halfway, the camera
controller 60 stays in a standby state until the shutter button
25 is depressed halfway.
[0163] When it is judged that the shutter button 25 is depressed
halfway, the camera controller 60 controls the wireless I/F 63 to
send the shutter signal S1 to the lens unit 12. The camera controller
60 then judges whether image capture preparation is completed or
not. This judgment is made based on whether the signal indicating
the completion of the AE/AF processing is obtained from the lens
unit 12.
[0164] When it is judged that the image capture preparation is
not completed, the camera controller 60 stays in a standby state
until the preparation is completed. When it is judged that the image
capture preparation is completed, the camera controller 60 controls
the wireless I/F 63 to send the signal requesting a through image
to the lens unit 12.
[0165] When the through image data is received, the camera controller
60 controls each part of the camera body 11 to decompress the through
image data and display it on the LCD 29. Thereafter, the camera
controller 60 judges whether the shutter button 25 is fully depressed
or not. When the shutter button 25 is not fully depressed, the camera
controller 60 stays in a standby state until the shutter button
25 is fully depressed.
[0166] When it is judged that the shutter button 25 is fully depressed,
the camera controller 60 controls the wireless I/F 63 to send the
shutter signal S2 to the lens unit 12. The camera controller 60
then judges whether the thumbnail image data is received or not.
When it is judged that the thumbnail image data is not received,
the camera controller 60 stays in a standby state until the thumbnail
image data is received.
[0167] When it is judged that the thumbnail image data is received,
the camera controller 60 controls the LCD driver 65 and displays
the received image on the LCD 29. This thumbnail image data is assigned
with the ID in the lens unit 12. The camera controller 60 gives
a file name to the thumbnail image data, and thereby producing the
thumbnail still image file 86 shown in FIG. 8. The camera controller
60 controls the media controller 66 to store the thumbnail still
image file 86 in a predetermined folder in the recording medium
72.
[0168] Thereafter, the camera controller 60 controls the wireless
I/F 63 to send the file name and the folder name of the thumbnail
still image file 86 to the lens unit 12. The camera controller 60
then judges whether the storing of the main still image file 85
is completed or not. This judgment is made based on whether the
signal indicating the completion of the storing is obtained from
the lens unit 12.
[0169] When it is judged that the storing is not completed, the
camera controller 60 stays in a standby state until the storing
is completed. When it is judged that the storing is completed, the
camera controller 60 judges whether the power of the camera body
11 is turned off or not.
[0170] When it is judged that the power of the camera body 11 is
not turned off, the camera controller 60 goes back to the process
of requesting the through image to the lens unit 12, the process
right after the completion of the initialization. When it is judged
that the power of the camera body 11 is turned off, the camera controller
60 finishes the process.
[0171] As described above, the file name of the thumbnail still
image file 86 stored in the camera body 11 is sent to the lens unit
12, and the main still image file 85 stored in the lens unit 12
is assigned with the identical file name. Owing to this, it is possible
to identify the correspondence between the thumbnail still image
file 86 and the main still image file 85 only by checking their
file names.
[0172] Next, an image capturing process in the still image capture
mode when the lens unit 12 is detached from the camera body 11 is
explained with referring to a flow chart in FIG. 20. At this time,
the data rate RA necessary for sending the main image data is equal
to or less than the actual data rate RC, and therefore the main
image data can be transferred from the lens unit 12 to the camera
body 11 right after the image capturing. Since the process until
the shutter button 25 is fully depressed is the same as shown in
the flow chart of the FIGS. 18 and 19, processes of the lens unit
12 and the camera body 11 after the shutter button 25 is fully depressed
are only explained.
[0173] First of all, the process in the lens unit 12 is explained.
The lens controller 40 judges whether a shutter signal S2 is obtained
or not. When it is judged that the shutter signal S2 is not obtained,
the lens controller 40 stays in a standby state until the shutter
signal S2 is obtained. When it is judged that the shutter signal
S2 is obtained, on the other hand, the lens controller 40 controls
each part of the lens unit 12 to perform image capturing for recording
by the CCD 16. The lens controller 40 also controls each part to
produce main image data by applying JPEG compression to the image
captured by the CCD 16.
[0174] Thereafter, the lens controller 40 controls the wireless
I/F 49 to send the main image data to the camera body 11. When the
transmission of the main image data is completed, the lens controller
40 controls the wireless I/F 49 to send a signal indicating the
completion of sending of the main image data to the camera body
11.
[0175] Next, the process in the camera body 11 is explained. The
camera controller 60 judges whether the shutter button 25 is fully
depressed or not. When it is judged that the shutter button 25 is
not fully depressed, the camera controller 60 stays in a standby
state until the shutter button 25 is fully depressed.
[0176] When it is judged that the shutter button 25 is fully depressed,
the camera controller 60 controls the wireless I/F 63 to send the
shutter signal S2 to the lens unit 12. The camera controller 60
then judges whether the main image data is received or not. When
it is judged that the main image data is not received, the camera
controller 60 stays in a standby state until the main image data
is received.
[0177] When it is judged that the main image data is received,
the camera controller 60 controls each part of the camera body 11
to decompress the main image data and display it on the LCD 29.
The camera controller 60 controls the media controller 66 to store
the main still image file 85, which is the main image data with
a file name, in the recording medium 72.
[0178] The camera controller 60 then judges whether the storing
of the main still image file 85 is completed or not. This judgment
is made based on whether the signal indicating the completion of
the sending of the main image data is obtained from the lens unit
12.
[0179] When it is judged that the storing is not completed, the
camera controller 60 stays in a standby state until the storing
of the main still image file 85 is completed. When it is judged
that the storing is completed, the camera controller 60 judges whether
the power of the camera body 11 is turned off or not.
[0180] When it is judged that the power of the camera body 11 is
not turned off, the camera controller 60 goes back to the process
of requesting the through image to the lens unit 12, the process
right after the completion of the initialization. When it is judged
that the power of the camera body 11 is turned off, the camera controller
60 finishes the process.
[0181] As described above, through image data is sent from the
lens unit 12 to the camera body 11 in the same manner as the flow
chart shown in FIGS. 18 and 19. However, the image data is not stored
in the recording medium 52 of the lens unit 12, and therefore the
file name and the folder name need not be sent to the lens unit
12 by the wireless communication after the shutter button 25 is
fully depressed.
[0182] Next, an image capturing process in the still image capture
mode when the lens unit 12 is attached to the camera body 11 is
explained with referring to a flow chart in FIGS. 21 and 22.
[0183] First of all, a process in the lens unit 12 is explained.
The lens unit 12 is automatically turned on when the camera body
11 is turned on. The lens controller 40 judges whether connection
is requested by the camera body 11 over the wireless communication
(802.11b). When it is judged that the connection is not requested,
the lens controller 40 stays in a standby state until the connection
is requested.
[0184] When it is judged that the connection is requested by the
camera body 11, the lens controller 40 sends a signal in response
to the connection request to the camera body 11 over the wireless
communication (802.11b). Thereafter, the lens controller 40 judges
whether initialization is requested from the camera body 11 or not.
When it is judged that the initialization is not requested, the
lens controller 40 stays in a standby state until the initialization
is requested.
[0185] When it is judged that the initialization is requested from
the camera body 11, the initialization is executed based on the
command received from the camera body 11. After the initialization,
the lens controller 40 sends a signal indicating the completion
of the initialization to the camera body 11. The lens controller
40 gets in a state of waiting for a next command from the camera
body 11, and then judges whether a through image is requested from
the camera body 11 or not. When it is judged that the through image
is not requested, the lens controller 40 stays in a standby state
until the through image is requested.
[0186] When it is judged that the through image is requested from
the camera body 11, the lens controller 40 controls each part of
the lens unit 12 to perform image capturing by the CCD 16. The lens
controller 40 also controls each part to apply resizing, various
image processing and the like to the image captured by the CCD 16.
The lens controller 40 then sends the through image to the camera
body 11 by the serial driver 48.
[0187] Then, the lens controller 40 judges whether a shutter signal
S1 is obtained or not. This shutter signal S1 is directly sent from
the camera body 11 to the lens controller 40 through a signal line
used only for this purpose. When it is judged that the shutter signal
S1 is not obtained, the lens controller 40 stays in a standby state
until the shutter signal S1 is obtained.
[0188] When it is judged that the shutter signal S1 is obtained,
the lens controller 40 controls each part of the lens unit 12 based
on the AE and AF detection values detected by the AE/AF detector
46 to perform AE/AF processing. When the processing is completed,
the lens controller 40 sends a signal indicating the completion
of the AE/AF processing to the camera body 11 by the wireless communication
(802.11b).
[0189] When receiving the request for a through image from the
camera body 11, the lens controller 40 controls each part of the
lens unit 12 to perform through image capturing by the CCD 16. The
lens controller 40 also controls each part to apply resizing, various
image processing and the like to the image captured by the CCD 16.
The lens controller 40 then sends the through image data to the
camera body 11 by the serial driver 48.
[0190] The lens controller 40 judges whether a shutter signal S2
is obtained or not. Similarly to the shutter signal S1, this shutter
signal S2 is also directly sent from the camera body 11 to the lens
controller 40 through the signal line used only for this purpose.
When it is judged that the shutter signal S2 is not obtained, the
lens controller 40 stays in a standby state until the shutter signal
S2 is obtained.
[0191] When it is judged that the shutter signal S2 is obtained,
the lens controller 40 controls each part of the lens unit 12 to
perform image capturing for recording by the CCD 16. The lens controller
40 also controls each part to produce main image data (YC signal)
by applying various image processing to the image captured by the
CCD 16. The lens controller 40 sends the main image data (YC signal
without compression) to the camera body 11 by the serial driver
48. When the transmission of the main image data is completed, the
lens controller 40 sends a signal indicating the completion of sending
of the main image data to the camera body 11 by the wireless communication
(802.11b).
[0192] Next, a process in the camera body 11 is explained. When
the still image capture mode is set after the camera body 11 is
turned on by the power operation button 28, the camera controller
60 controls the wireless I/F 63 to send the connection request to
the lens unit 12 over the wireless communication (802.11b).
[0193] The camera controller 60 judges whether the connection response
is received or not. When it is judged that the connection response
is not received, the lens controller 60 stays in a standby state
until the connection response is received. When it is judged that
the connection response is received, the lens controller 60 executes
the above described production process of initialization information.
[0194] The camera controller 60 sends the command for requesting
initialization to the lens unit 12 by the wireless communication
(802.11b), based on the produced initialization information. The
camera controller 60 confirms completion of the initialization when
receiving the signal indicating the completion from the lens unit
12.
[0195] The camera controller 60 controls the wireless I/F 63 to
send a signal requesting a through image to the lens unit 12. The
camera controller 60 controls the serial driver 62 to receive the
through image data, and controls the LCD driver 65 to display the
through image on the LCD 29.
[0196] The camera controller 60 judges whether the shutter button
25 is depressed halfway or not. When it is judged that the shutter
button 25 is not depressed halfway, the camera controller 60 stays
in a standby state until the shutter button 25 is depressed halfway.
[0197] When it is judged that the shutter button 25 is depressed
halfway, the camera controller 60 sends the shutter signal S1 to
the lens unit 12 through the signal line used only for this purpose.
The camera controller 60 judges whether image capture preparation
is completed or not. This judgment is made based on whether the
signal indicating the completion of the AE/AF processing is obtained
from the lens unit 12.
[0198] When it is judged that the image capture preparation is
not completed, the camera controller 60 stays in a standby state
until the preparation is completed. When it is judged that the image
capture preparation is completed, the camera controller 60 controls
the wireless I/F 63 to send the signal requesting a through image
to the lens unit 12.
[0199] The camera controller 60 controls the serial driver 62 to
receive the through image data, and controls the LCD driver 65 to
display the through image on the LCD 29. The camera controller 60
judges whether the shutter button 25 is fully depressed or not.
When the shutter button 25 is not fully depressed, the camera controller
60 stays in a standby state until the shutter button 25 is fully
depressed.
[0200] When it is judged that the shutter button 25 is fully depressed,
the camera controller 60 sends the shutter signal S2 to the lens
unit 12 through the signal line used only for this purpose. The
camera controller 60 judges whether the main image data is received
by the serial driver 62 or not. When it is judged that the main
image data is not received, the camera controller 60 stays in a
standby state until the main image data is received.
[0201] When it is judged that the main image data is received by
the serial driver 62, the camera controller 60 controls each part
of the camera body 11 to apply JPEG compression to the main image
data and display it on the LCD 29. Thereafter, the camera controller
60 assigns a file name to the main image data and stores it as the
main still image file 85 in the recording medium 72 of the camera
body 11.
[0202] The camera controller 60 judges whether the storing of the
main still image file 85 in the recording medium 72 is completed
or not. This judgment is made based on whether the signal indicating
the completion of the sending of the main image data is obtained
from the lens unit 12.
[0203] When it is judged that the storing is not completed, the
camera controller 60 stays in a standby state until the storing
of the main still image file 85 is completed. When it is judged
that the storing is completed, the camera controller 60 judges whether
the power of the camera body 11 is turned off or not.
[0204] When it is judged that the power of the camera body 11 is
not turned off, the camera controller 60 goes back to the process
of requesting the through image to the lens unit 12, the process
right after the completion of the initialization. When it is judged
that the power of the camera body 11 is turned off, the camera controller
60 finishes the process.
[0205] As described above, the lens unit 12 and the camera body
11 send and receive the control signals by the wireless communication
(802.11b), and transfer the image data from the lens unit 12 to
the camera body 11 at high speed by the serial drivers 48 and 62.
[0206] In the lens unit 12, image data is obtained by the CCD 16,
and YC conversion is applied to the image data. The YC signal is
then transferred to the camera body 11 and compressed in JPEG format.
In this way, processes are executed separately by the lens unit
12 and the camera body 11, and therefore, heat given off from the
IC circuits can be diversified in the digital camera 10.
[0207] For the explanation of the image capturing process, the
still image capturing process is explained as an example. However,
the same process is executed for capturing movies, and therefore
the explanation thereof is omitted.
[0208] Next, the synchronization process is explained with referring
to a flow chart in FIGS. 23 and 24. First of all, a process in the
lens unit 12 is explained. When the lens unit 12 receives a request
for a main image file from the camera body 11 while the lens unit
12 is waiting for a command, the lens controller 40 searches for
the main image file with corresponding ID.
[0209] The lens controller 40 then judges whether the main image
file with the corresponding ID is found or not. When it is judged
that the main image file with the corresponding ID is found, the
lens controller 40 sends this main image file to the camera body
11, and finishes the process.
[0210] When it is judged that the main image file with the corresponding
ID is not found, the lens controller 40 sends an error signal, indicating
that the file does not exist, to the camera body 11, and finishes
the process.
[0211] Next, a process in the camera body 11 is explained. The
camera controller 60 judges whether the lens unit 12 is attached
to the camera body 11 or not. When it is judged that the lens unit
12 is not attached, the camera controller 60 stays in a standby
state until the lens unit 12 is attached.
[0212] When it is judged that the lens unit 12 is attached, the
camera controller 60 obtains a first file name from top of a File
Allocation Table (FAT). Note that the FAT is a table which manages
the storage of the image files in the recording medium 72.
[0213] Thereafter, the camera controller 60 judges whether the
extension of the image file is "STH" or not. When it is
judged that the extension is not "STH", the camera controller
60 moves on to a process of judging whether the extension is "MTH"
or not.
[0214] When it is judged that the extension is "STH",
the camera controller 60 reads Tag information of the image file
and obtains the ID given as link information. The camera controller
60 then controls the wireless I/F 63 to send the request for acquisition
of the main image file corresponding to the obtained ID to the lens
unit 12.
[0215] The camera controller 60 judges whether the signal received
from the lens unit 12 by the wireless communication carries the
main still image file 85 or not. When it is judged that the received
signal does not carry the main still image file 85, that is, when
it is judged that the error signal is received, the camera controller
60 moves on to the process of judging whether the extension of the
image file is "MTH" or not.
[0216] When it is judged that the received signal carries the main
still image file 85, the camera controller 60 replaces the thumbnail
still image file 86 by the main still image file 85. The camera
controller 60 then judges whether the extension of the image file
is "MTH" or not. When it is judged that the extension
is not "MTH", the camera controller 60 moves on to a process
of judging whether there is a next image file in the recording medium
72 or not.
[0217] When it is judged that the extension is "MTH",
the camera controller 60 reads Tag information of the image file
and obtains the ID given as link information. The camera controller
60 then controls the wireless I/F 63 to send the request for acquisition
of the main image file corresponding to the obtained ID to the lens
unit 12.
[0218] The camera controller 60 judges whether the signal received
from the lens unit 12 by the wireless communication carries the
incomplete main movie file 87 or not. When it is judged that the
received signal does not carry the main movie file 87, that is,
when it is judged that the error signal is received, the camera
controller 60 moves on to the process of judging whether there is
a next image file in the recording medium 72 or not.
[0219] When it is judged that the received signal carries the incomplete
main movie file 87, the camera controller 60 adds the thumbnail
movie data 88c stored in the thumbnail movie file 88 to the main
movie file 87, thereby producing the complete main movie file 89.
The camera controller 60 then replaces the thumbnail movie file
88 by the main movie file 89. Owing to this, the complete main movie
file 89 can be efficiently produced without producing the thumbnail
movie data 88c in the lens unit 12.
[0220] The camera controller 60 judges whether there is a next
image file in the recording medium 72 or not. When it is judged
that there is a next image file, the next file name is obtained.
The camera controller 60 then goes back to the process of judging
whether the extension of the image file is "STH" or not.
When it is judged that there is no next image file in the recording
medium 72, the camera controller 60 finishes the synchronization
process.
[0221] Although the synchronization process is explained to be
executed at the time of the attachment of the lens unit 12 to the
camera body 11, it is not limited to this. The synchronization process
can be executed when the camera body 11 is turned on regardless
of whether the image capture mode is set or not.
[0222] Next, a digital camera 100 according to a second embodiment
is explained. As shown in FIG. 25, the digital camera 100 is composed
of a camera body 101 and a lens unit 102. The lens unit 102 is removably
attached to the camera body 101. In the digital camera 10, the high-speed
serial communication devices which transmit data through the connection
contacts are used as one-way communication devices. In the digital
camera 100, however, infrared communication devices which are short
range optical communication devices are used instead of the high-speed
serial communication devices.
[0223] Unlike the digital camera 10 according to the first embodiment,
a lens 103 is disposed on the front surface of the mount lid 22
of the camera body 101 in the digital camera 100. Behind the lens
103, an infrared light receiving element 104 (see FIG. 26) is disposed.
Behind the lens side mount portion 14 of the lens unit 102 are provided
an infrared light emitting element 105 (see FIG. 26) and a lens
106 (see FIG. 26). The lens 106 collects the infrared light emitted
from the infrared light emitting element 105.
[0224] As shown in FIG. 26, the lens unit 102 has an infrared sending
I/F 110 instead of the serial driver 48 of the lens unit 12. The
infrared sending I/F 110 is connected to the data bus 41.
[0225] The infrared light emitting element 105 is connected to
the infrared sending I/F 110. The infrared light emitting element
105 emits an infrared laser beam under the control of the infrared
sending I/F 110. As the infrared light emitting element 105, for
example, a Vertical Cavity Surface Emitting Laser (VCSEL) which
is a surface emitting laser is used.
[0226] Image data obtained by the CCD 16 is sent on the infrared
laser beam from the infrared light emitting element 105 toward the
camera body 101 by the infrared sending I/F 110. The lens 106 disposed
in front of the infrared light emitting element 105 collects the
laser beam, and thus the laser beam is efficiently eradiated toward
the camera body 101.
[0227] The camera body 101 has an infrared receiving I/F 111 instead
of the serial driver 62 of the camera body 11. The infrared I/F
111 is connected to the data bus 61. The infrared light receiving
element 104 is connected to the infrared receiving I/F 111. As the
infrared light receiving element 104, for example, a GaAs PIN photodiode
or the like is used. The lens 103 disposed in front of the infrared
light receiving element 104 collects the infrared laser beam.
[0228] Unlike the lens unit 12, the lens unit 102 is not provided
with the media controller 51, and therefore images cannot be stored
in the recording medium 52. Accordingly, the images are stored in
a flash memory 113 provided in the lens unit 102. Note that the
configuration of the digital camera 100 is identical to the configuration
of the digital camera 10 besides the components explained above.
Therefore, the components identical to those of the first embodiment
are denoted by the same reference numerals, and descriptions thereof
are omitted.
[0229] In the digital camera 100, when the lens unit 102 is attached
to the camera body 101, YC conversion is applied in the lens unit
to the image data obtained by the CCD 16, and the image data is
sent on the infrared laser beam to the camera body 101 unlike the
digital camera 10 which uses the serial drivers.
[0230] In the digital camera 100, the synchronization process is
performed as in the case of the digital camera 10. In the lens unit
102, however, since the image file is stored in the flash memory
113, it is preferable that the image stored in the flash memory
113 is deleted after the completion of the synchronization process
in order to assure capacity for the next shooting. Note that other
operations of the digital camera 100 are same as that of the digital
camera 10, and therefore descriptions thereof are omitted.
[0231] In the above embodiments, the wireless LAN device (802.11b)
is used for the wireless communication between the lens unit and
the camera body, but the present invention is not limited to this.
For example, other standard for the wireless LAN, such as IEEE802.11g
or IEEE802.11a may be used, or Bluetooth may be used.
[0232] In the above embodiments, the CCD image sensor is used as
the solid state imaging device, but the present invention is not
limited to this. For example, a CMOS image sensor may be used.
[0233] In the above embodiments, the present invention is applied
to the digital still camera. However, the present invention is also
applicable to digital video cameras. Moreover, the present invention
can be applied to TV phones and personal computers with cameras.
[0234] Various changes and modifications are possible in the present
invention and may be understood to be within the present invention. |