JP3612881B2 - Digital camera - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital camera that photoelectrically converts a stationary object light image into an image signal and records the image signal on a recording medium such as a semiconductor memory, and particularly reproduces and displays a plurality of images recorded on the recording medium. The present invention relates to a digital camera provided with display means.
[0002]
[Prior art]
In general, in a digital camera, from the viewpoint of effective use of the memory capacity of a recording medium, a captured image is compressed by a predetermined compression method such as a JPEG (Joint Photographic Coding Experts Group) method and recorded on the recording medium. . Further, when a compressed image of a captured image is recorded on a recording medium, a thumbnail image that is used as an index image of the captured image recorded on the recording medium is generated and recorded on the recording medium together with the compressed image. . This thumbnail image is a small-sized uncompressed image generated by thinning out the number of data of captured images, and can be read / reproduced more quickly than a compressed image.
[0003]
Conventionally, a digital camera including an LCD (Liquid Crystal Display) display unit that functions as an electronic viewfinder is known. With this digital camera, it is possible to reproduce and display the captured images of a plurality of frames recorded on a recording medium on the LCD display unit, and the recorded images of each frame are displayed on the LCD by specifying the frames with a frame advance switch provided on the camera. It can be played back and confirmed.
[0004]
[Problems to be solved by the invention]
By the way, in the above digital camera, when the captured image of each frame recorded on the recording medium is reproduced on the LCD display unit and the recorded content is confirmed, the captured image of each frame is operated by continuously operating the frame advance switch. Needs to be reproduced on the LCD display device. In this case, if the compressed image of each frame is reproduced on the LCD display unit every time the frame is designated by the frame advance switch, it takes a long time to decompress the compressed image, and it is difficult to reproduce the captured image of each frame quickly. is there. When JPEG compressed images are played back and displayed on the LCD display unit, depending on the compression of the data capacity, for example, an image signal with 300,000 pixels is converted into 8-bit image data and the compression rate is 1/8. When compressed, it takes about 2 seconds to reproduce the compressed image.
[0005]
For this reason, if the desired frame number is far from the current frame number, it takes a very long time to reproduce the captured image of that frame, and it is very inconvenient if you just want to check the image contents. . In order to solve this problem, a method of sequentially reproducing the compressed image of each frame at regular intervals without reproducing all the compressed images of each frame is conceivable. However, in this method, only a part of the captured image of each frame is considered. It may not be played back, and it may be difficult to check the contents, which is not practical.
[0006]
The present invention has been made in view of the above problems, and provides a digital camera capable of promptly displaying and confirming a plurality of frames of captured images recorded on a recording medium on an LCD display unit. .
[0007]
[Means for Solving the Problems]
The present invention has display means for displaying an image, and each frame is composed of a first image and a second image having a longer processing time for reproduction to the display means than the first image. MultipleofA digital camera that sequentially reads out the captured images of each frame from the storage unit in which the captured images of the frames are stored, and reproduces and displays the images on the display unit, the instruction unit instructing the frame to be reproduced on the display unit; When the frames to be reproduced are instructed continuously at intervals within a predetermined time by the instruction means, the instruction is made this time after the display processing of the first image of the frame instructed last time on the display means is completed. First display control means for reproducing and displaying the first image of the displayed frame on the display means;Within the predetermined timeBy the above instruction meansRFrames to playButInstructedNotSecond display control for reproducing and displaying the second image of the frame on the display means after the display processing of the first image of the frame instructed last by the continuous instruction on the display means is completed. Means (Claim 1).
[0008]
According to the above configuration, the captured images of the plurality of frames recorded in the recording unit are reproduced and displayed on the display unit by designating the frame to be reproduced by the instruction unit. At this time, when the frames to be reproduced by the instructing means are continuously instructed at intervals within a predetermined time, the display of the first image of the first instructed last time is completed on the display means, and then the current instruction The first image of the selected frame is reproduced and displayed on the display means. That is, the first image having a short reproduction processing time for each frame is continuously reproduced and displayed on the display means.
[0009]
on the other hand,Within a given timeBy instruction meansRFrames to playButInstructedNotWhen the display processing of the first image of the last frame designated by the continuous instruction on the display means is completed, the second image of the frame is reproduced and displayed on the display means. That is, after the first image of each frame is continuously displayed on the display means for the continuously designated frame, the second image of the captured image of the last frame is reproduced and displayed on the display means.
[0010]
The present invention further includes display means for displaying an image, and each frame includes a first image and a second image having a longer processing time for reproduction on the display means than the first image. A digital camera that sequentially reads out the captured images of each frame from a storage unit in which captured images of a plurality of frames are stored, and reproduces and displays them on the display unit, the frame to be reproduced on the display unit The instruction means for designating and playback by the above instruction meansYouShouldNextWhen the first frame is instructed, the first image of the second frame is reproduced and displayed on the display means after the display processing of the first image of the first frame is completed, and should be reproduced next within a predetermined time. When the frame image is not instructed, the display control means for reproducing and displaying the second image of the first frame on the display means after the display processing of the first image of the first frame is completed. (Claim 2).
[0011]
According to the above configuration, the instruction unit instructs the next frame to be reproduced for a predetermined time.InsideIs performed, the first image of the next frame is reproduced and displayed, and the next frame is instructed for a predetermined time.InsideOtherwise, after the reproduction and display of the first image of the current frame is completed, the second image of the current frame is reproduced and displayed.To do.
[0012]
According to each configuration aboveSince the first image has a shorter processing time for reproduction than the second image, the captured content of each frame can be checked quickly and the frame can be quickly advanced to a desired frame position. This is possible.
[0013]
Note that the first image and the second image may be generated from a photographed image obtained by photographing the same subject.
[0014]
The first image may be a thumbnail image.
[0015]
The first image may be an image in which the captured image is stored in an uncompressed state in which the number of data is smaller than that of the second image.
[0016]
The second image may be an image obtained by storing a photographed image in a compressed state (claim 6).
[0017]
Further, the reproduction process may be a process of expanding a compressed image.
[0018]
The second image may be an image compressed by the JPEG method.
[0019]
The second image may be overwritten and displayed on a line basis with respect to the displayed first image.
[0020]
The storage means may be a recording medium removable from the camera.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
A digital camera according to the present invention will be described with reference to the drawings.
[0022]
FIG. 1 is a front view of a digital camera according to the present invention, and FIG. 2 is a rear view of the digital camera. 3 to 5 are a top view, a right side view, and a bottom view of the digital camera, respectively.
[0023]
The digital camera 1 is composed of a box-shaped camera body 2 and a rectangular parallelepiped imaging unit 3. The imaging unit 3 is detachably attached to the right side surface of the camera body unit 2 when viewed from the front, and is rotatably mounted in a plane parallel to the right side surface. The imaging unit 3 can be connected to the camera body 2 via a dedicated connection cable, as will be described later.
[0024]
When the imaging unit 3 has an end face (upper end face in FIG. 1) provided with a lens window as a front end, the front end is parallel to the upper surface of the camera body 2 (imaging position) as shown by an imaginary line in FIG. The position can be rotated in a range of approximately ± (90 + α) ° with reference to a position where the direction is the direction A in FIG. When the imaging unit 3 is directly connected to the camera body unit 2, the main power of the digital camera 1 is turned on / off by the rotation operation of the imaging unit 3, and the imaging unit 3 is set to the rotation reference position. (The state of FIGS. 1 to 5), the main power supply is turned off. This is a configuration in which the digital camera 1 is the most compact, and since the digital camera 1 is normally stored in this state, the main power supply is automatically turned off to facilitate the switch operation of the main power supply. It is what I did.
[0025]
The imaging unit 3 includes an imaging device including a photographic lens including a macro zoom and a photoelectric conversion element such as a CCD (Charge Coupled Device), and an optical image of a subject is converted into an image including an electric signal (photoelectrically converted by each pixel of the CCD). Converted into an image formed by a charge signal). On the other hand, the camera body 2 includes a display unit 10 formed of an LCD (Liquid Crystal Display), a mounting unit 17 for an IC card 18 (see FIG. 8), and a connection terminal 13 to which a personal computer is externally connected. The image signal captured by the unit 3 is subjected to predetermined signal processing, and thereafter, processing such as display on the LCD display unit 10, recording on the IC card 18, and transfer to a personal computer is performed.
[0026]
The imaging unit 3 is a vertically long rectangular parallelepiped imaging unit having a length dimension substantially the same as the height dimension of the camera body 2 and a dimension substantially the same as the width dimension of the camera body 2. A main body 3 </ b> A is provided, and a mounting portion 3 </ b> B for mounting the imaging portion 3 to the camera main body portion 2 projects from one side surface of the imaging portion main body 3 </ b> A. The imaging unit 3 has a rectangular parallelepiped shape with the imaging unit body 3A extending in one direction so that it can be set along the side surface of the camera body unit 2 during storage. A zoom lens that is long in the axial direction can be used. A mounting mechanism of the imaging unit 3 to the camera body 2 by the mounting unit 3B will be described later.
[0027]
As shown in FIG. 6, a macro zoom lens 301 is disposed inside the imaging unit main body 3 </ b> A, and an imaging circuit 302 including a CCD color area sensor 303 is provided at a proper position behind the macro zoom lens 301. ing. In addition, a dimming circuit 304 including a dimming sensor 305 that receives reflected light from the subject of flash light is provided at an appropriate position in the imaging unit 3. The light control sensor 305 is disposed at an appropriate position on the front end surface of the mounting portion 3B.
[0028]
On the other hand, on the outside of the imaging unit main body 3A, as shown in FIG. 2, the side surface is parallel to the rear surface of the camera main body unit 2 (the side surface that is the upper side when the imaging unit 3 is rotated + 90 ° from the rotation reference position). A zoom lever 306 for changing the zoom ratio of the macro zoom lens 301 and switching between zoom and macro is provided, and the imaging unit 3 is disengaged from the camera body 2 at a position diagonally to the right of the zoom lever 306. An unlock lever 307 is provided to enable the above.
[0029]
The zoom lever 306 is a lever that is slidable in the horizontal direction (perpendicular to the optical axis of the imaging unit 3). The zoom lever 306 is slid horizontally in the horizontal direction at the zoom position PZ to zoom the macro zoom lens 301. The ratio is changed. When the zoom lever 306 is slid rightward beyond the zoom position PZ and set to the macro position PM, the macro zoom lens 301 is switched to the macro lens. At the macro position PM, it is possible to photograph close to the subject up to about 50 cm.
[0030]
As shown in FIG. 1, a grip portion 4 is provided at an appropriate position at the left end portion, and a built-in flash 5 is provided at an upper appropriate position at the right end portion, as shown in FIG. Further, as shown in FIG. 3, switches 6 and 7 for frame advance when reproducing a recorded image are provided on the upper surface of the camera body 2 as shown in FIG. 3. The switch 6 is a switch (hereinafter referred to as an UP switch) for feeding a recorded image in a direction in which the frame number increases (in the shooting order direction), and the switch 7 is a direction in which the frame number decreases in the recorded image. This is a switch for frame-by-frame (hereinafter referred to as DOWN switch). Further, an erasing switch 8 for erasing an image recorded on the IC card 18 is provided on the left side of the DOWN switch 7 when viewed from the back side, and a shutter button 9 is provided on the upper right side of the UP switch 6.
[0031]
As shown in FIG. 2, an LCD display unit 10 is provided on the rear surface of the camera main unit 2 for displaying a captured image on a monitor (corresponding to a viewfinder) and reproducing a recorded image. It has been. In addition, an FL mode setting switch 11 for flash emission is provided at an upper position of the LCD display unit 10, and a compression rate K for image data recorded on the IC card 18 is switched and set at a lower position of the LCD display unit 10. A compression rate setting switch 12 and a connection terminal 13 to which a personal computer is externally connected are provided. The FL mode setting switch 11 is a push switch, and the compression rate setting switch 12 is a two-contact slide switch.
[0032]
In the digital camera 1, “automatic flash mode” in which the built-in flash 5 is automatically fired according to subject brightness as a mode related to flash emission, and “forced flash mode” in which the built-in flash 5 is forced to fire regardless of subject brightness. In addition, a “flash prohibition mode” for prohibiting the flash of the built-in flash 5 is provided, and each time the FL mode setting switch 11 is pressed, the “auto flash”, “forced flash” and “flash prohibit” modes are cyclically switched. Instead, one of the modes is selected and set. Also, the digital camera 1 can select and set two types of compression ratios K of 1/8 and 1/20. For example, when the compression ratio setting switch 12 is slid to the right, the compression ratio K = 1/8 is set. When sliding to the left, the compression ratio K = 1/20 is set. In this embodiment, two types of compression rates K can be selected and set, but three or more types of compression rates K may be selected and set.
[0033]
Furthermore, a shooting / playback mode setting switch 14 for switching between “shooting mode” and “playback mode” is provided at the upper right end on the back of the camera body 2. The shooting mode is a mode for taking a picture, and the playback mode is a mode for playing back and displaying the shot image recorded on the IC card 18 on the LCD display unit 10. The shooting / playback mode setting switch 14 is also a two-contact slide switch. For example, when it is slid to the right, the playback mode is set, and when it is slid to the left, the shooting mode is set.
[0034]
As shown in FIG. 8, a battery loading chamber 16 for the power battery E and a card loading chamber 17 for the IC card 18 are provided on the bottom surface of the camera body 2. As shown in FIG. 7, the clamshell type lid 15 is closed. The digital camera 1 according to the present embodiment uses a power source battery E formed by connecting four AA batteries E1 to E4 in series as a drive source, and the batteries E1 to E4 are located below the camera body 2. A battery loading chamber 16 in which four cylindrical loading chambers to be loaded are arranged in a row is disposed laterally at a position slightly shifted to the right side from the center of the lower surface. In addition, a card loading chamber 17 having a belt-shaped loading port is disposed in front of the battery loading chamber 16 in parallel with the battery loading chamber 16.
[0035]
Conductive connection pieces 15a for connecting the batteries E1 and E2 and the conductive elements for connecting the batteries E3 and E4 are located on the back surface of the lid 15 (the surface facing the loading chambers 16 and 17) facing the battery loading chamber 16. When the lid 15 is closed, the connection pieces 15a and 15b and the batteries E1 to E4 come into contact with each other so that the power supply battery E is configured.
[0036]
In the digital camera 1 according to the present embodiment, since the lid of the battery loading chamber 16 and the lid of the card loading chamber 17 are made common as described above, the arrangement of both loading chambers becomes compact, and the loading / unloading is performed. The IC card 18 can be reliably protected at the time. That is, when the IC card 18 is mounted, the power supply battery E is connected to the internal circuit by closing the lid 15 after the IC card is mounted. When the IC card 18 is removed, the lid 15 is opened before the IC card is removed. By doing so, the connection with the internal circuit of the power supply battery E is released, so that the IC card 18 can be reliably attached and detached with the power off.
[0037]
Note that the positional relationship between the battery loading chamber 16 and the card loading chamber 17 is not limited to that arranged in the width direction of the camera body 2 as shown in FIG. 8, and for example, as shown in FIG. 9 or FIG. A battery loading chamber 16 'and a card loading chamber 17 formed by arranging four cylindrical battery loading chambers in two rows may be arranged in the horizontal direction. In this case, it is preferable to use the example of FIG. 9 in which the battery loading chamber 16 ′ is on the right end side with respect to the card loading chamber 17. This is because the opening degree of the lid 15 increases toward the right end side of the camera body 2, so that the batteries E1 to E4 can be easily attached and detached.
[0038]
As shown in FIGS. 11 and 12, a friction member 20 made of rubber, resin, or the like is provided at an appropriate position on the inner wall of the battery loading chamber 16. The friction member 20 prevents the batteries E1 to E4 from dropping when the lid 15 is opened with the lower surface of the camera body 2 facing downward, and facilitates removal of the batteries E1 to E4. In place of the friction member 20 as a fall prevention member for the batteries E1 to E4, a spring member 21 may be provided as shown in FIG. 13, or a stopper mechanism by the friction ball 22 is provided as shown in FIG. Also good.
[0039]
The stopper mechanism shown in FIG. 14 is such that when the opening of the battery loading chamber 16 is upward (FIG. 14A), the friction ball 22 is on the bottom side of the conical ball holding portion 16a. Since a gap is formed between the battery E2 and the battery E2, the battery E2 can be easily pulled out. However, when the opening of the battery loading chamber 16 is downward (FIG. 5B), the friction ball 22 is attached to the ball holding portion 16a. It moves to the head side and is interposed between the ball holding portion 16a and the battery E2 to prevent the battery E2 from dropping.
[0040]
Next, a mechanism for mounting the imaging unit 3 to the camera body 2 will be described.
[0041]
As shown in FIG. 15, a connection plate 23 to which the image pickup unit 3 is detachably attached is provided on the right side surface of the camera body 2 as viewed from the front so as to be rotatable in a plane parallel to the right side surface. ing. By the rotation of the connection plate 23, the imaging unit 3 attached to the camera body 2 is rotated in a range of approximately ± (90 + α) ° with respect to the rotation reference position.
[0042]
As shown in FIG. 16, the mounting surface 308 of the mounting portion 3B is provided with a rectangular hole 309 in which four engagement claws 310a to 310d are projected at appropriate positions on the periphery, and the connection plate is connected to the hole 309. 23 is inserted so that the image pickup unit 3 is attached to the camera body 2.
[0043]
As shown in FIG. 17, a key member 311 that locks the connection plate 23 mounted on the mounting surface 308 protrudes from the back surface of the lock release lever 307. The lock release lever 307 is attached to the mounting portion 3B with the key member 311 passing through the side wall of the mounting portion 3B and facing the hole 309 side. The lock release lever 307 is attached so as to be movable in a direction in which the key member 311 is in contact with and away from the opening surface of the hole 309. By operating the lock release lever 307, the key member 311 is movable between a lock position provided on the opening surface side of the hole 309 and a lock release position provided on the back side from the opening surface. The lock release lever 307 is urged to the lock position by the spring 312. When the lock release lever 307 is moved to the lock release position against the urging force of the spring 312, the lock release lever 307 is attached to the camera body 2 via the connection plate 23. The imaging unit 3 can be detached.
[0044]
A plurality of connection terminals 234 are provided on the mounting surface of the connection plate 23, while a plurality of connection terminals (not shown) are provided in the holes 309 of the mounting portion 3B so as to face the connection terminals 234 on the mounting surface of the connection plate 23. ), And when the imaging unit 3 is attached to the camera body 2 via the connection plate 23, the imaging unit 3 and the camera body 2 are electrically connected via the connection terminal 234. It has become.
[0045]
The connection plate 23 is formed with rectangular recesses 231a and 231b at appropriate positions on both long sides, and one corner of one of the surfaces where the connection terminals 234 are not provided (hereinafter, this surface is referred to as the back surface). Engagement portions 232a, 232b, 232c, and 232d are formed at positions that are continuous with the recesses 231a and 231b, respectively, and engage with the engagement claws 310a to 310d of the mounting portion 3B. Further, on the surface provided with the connection terminal 234 (hereinafter, this surface is referred to as the surface), a groove is formed at an appropriate position on the long side where the recess 231a is formed, and the key member 311 of the mounting portion 3B is fitted. A mating portion 233 is provided.
[0046]
The mounting portion 3B of the imaging unit 3 is attached to the connection plate 23 of the camera body 2 in the following procedure. That is, first, the mounting surface 308 of the mounting portion 3B is arranged in parallel with the connection plate 23 so that the engaging claws 310c and 310d of the hole 309 face the recesses 231a and 231b of the connection plate 23, respectively, and then the mounting portion 3B. Is pressed against the connection plate 23. At this time, the engaging claws 310c and 310d are fitted into the recesses 231a and 231b of the connection plate 23, respectively, while the key member 311 is pushed by the surface of the connection plate 23 to be in the unlocked position against the urging force of the spring 312. The mounting portion 3B moves and is pressed until the back surface of the connection plate 23 becomes the same as the mounting surface 308 of the mounting portion 3B. Thereafter, when the mounting portion 3B is moved to the rear end side (B direction in FIG. 16), the engaging claws 310a to 310d of the mounting portion 3B engage with the engaging portions 232a to 232d of the connection plate 23, respectively. The portion 3B is attached to the connection plate 23 so as not to be detached, and the key member 311 is moved to the lock position by the urging force of the spring 312 and is fitted into the engagement portion 233 so that the imaging portion 3 is attached to the connection plate 23. Is locked.
[0047]
To remove the image pickup unit 3 from the connection plate 23, the key member 311 is moved to the lock release position by operating the lock release lever 307 in a direction away from the mounting surface 308 (direction C in FIG. 17). In this state, the mounting portion 3B is moved relative to the connection plate 23 in the direction opposite to the B direction, and then the mounting portion 3B is separated from the connection plate 23. This is done by moving it.
[0048]
Next, a structure for attaching the connection plate 23 to the camera body 2 will be described.
[0049]
FIG. 18 is an exploded perspective view showing the structure of the connection plate unit. The connection plate unit includes a connection plate 23, a substrate 24, a reinforcing plate 25, a sliding ring 26, a rotation support member 27, and a click member 28.
[0050]
A recess 235 is provided on the back surface of the connection plate 23, and the substrate 24 on which the connection terminal 234 and the signal line connected to the connection terminal 234 are formed is accommodated in the recess 235. Further, on the back surface of the connecting plate 23, a columnar female screw having a partly cut side surface at a position eccentrically downward on the central axis in the longitudinal direction and a female screw (not shown) formed on the central axis. A portion 236 is projected.
[0051]
The side cut portion of the female screw portion 236 is provided to provide a space for guiding the signal line into the camera body portion 2. Further, the position of the female screw portion 236 on the connection plate 23 is decentered downward from the center when the digital camera 1 is placed on a desk or the like with the imaging unit 3 rotated from the rotation reference position. This is also to ensure the stability of the camera posture.
[0052]
That is, in FIG. 22, when the imaging unit 3 is at the rotation reference position, if the gravity center positions of the imaging unit 3 and the camera body are substantially on the center line M in the vertical direction of the camera body unit, for example, the imaging unit 3 is rotated. When rotated to a position rotated by + 90 ° from the reference position (hereinafter, this position is referred to as a front imaging position), the center-of-gravity position G of the imaging unit 3 moves from the center line M to the front of the camera in the width direction of the camera. A moment that rotates forward about the bottom surface of the camera body 2 as a fulcrum acts on the camera body 2.
[0053]
The female screw portion 236 of the connection plate 23 serves as a rotation axis of the imaging unit 3 connected to the camera body 2. As shown in FIG. 23, the position N ′ of this rotation axis is used as a fulcrum of the moment. The closer to the bottom surface of the camera body portion 2, the smaller the moment and the higher the stability. Therefore, in this embodiment, the female screw portion 236 of the connection plate 23 is placed in the longitudinal direction of the right side surface of the camera body portion 2 as much as possible. The center position N is shifted downward.
[0054]
In the present embodiment, since the imaging unit 3 has a rectangular parallelepiped shape in the vertical direction and uses an imaging optical system that is long in the optical axis direction, the moment is larger than that in which an imaging optical system that is short in the optical axis direction is used. Become. Therefore, with the above configuration, the camera posture can be stably maintained even when the digital camera 1 is placed on a desk or the like with the imaging unit 3 set to the front imaging position.
[0055]
Returning to FIG. 18, the reinforcing plate 25 seals the concave portion 235 of the connection plate 23 in which the substrate 24 is accommodated, and reinforces the connection plate 23. A through hole 251 through which the female screw portion 236 of the connection plate 23 penetrates is formed at an appropriate position of the reinforcing plate 25, and is protruded from the flange portion 262 of the sliding ring 26 at an appropriate position below the through hole 251. An engagement hole 252 that engages with the engagement protrusion 264 is formed.
[0056]
The sliding ring 26 regulates the rotation angle in the rotation operation of the connection plate 23. The sliding ring 26 is made of a disc-shaped ring member having a flange 262 having a step at one end of the side surface. Assuming that the stepped side of the sliding ring 26 is the surface, a notch 261A is formed at an appropriate position on the surface side of the ring portion 261 at the center of the sliding ring 26, and this notch 261A is used as a reference. As shown, a C-shaped groove 263 is formed in the flange portion 262 along the side surface of the ring portion 261 over an angle of ± (90 + α). The notch 261A is engaged with an engaging protrusion provided on a click member 28 described later. The groove 263 is a guide groove in which a guide pin 275 provided on the rotation support member 27 described later is loosely fitted.
[0057]
In addition, a notch 262A is formed on the surface of the peripheral portion of the flange 262 in the same direction as the notch 261A, and a notch 262B is formed in the + 90 ° direction by shifting the position from the notch 262A to the center O side. Yes. The notch 262A is for detecting that the imaging unit 3 attached to the connection plate 23 is set at the rotation reference position and turning off the main power supply. The notch 262B is attached to the connection plate 23. This is for detecting that the imaging unit 3 is set at the front imaging position and that the imaging (optical axis) direction is parallel to the light emission (optical axis) direction of the built-in flash 5. In addition, an engagement protrusion 264 that engages with the engagement hole 252 of the reinforcing plate 25 is provided at an appropriate position on the back surface of the flange 262 in the direction opposite to the notch 261A.
[0058]
The rotation support member 27 is a member for supporting the rotation of the connection plate 23 and attaching the connection plate unit to the right side surface of the camera body 2. The rotation support member 27 is formed by forming rectangular plate-shaped attachment portions 272 and 272 'on the upper and lower sides of the disk-shaped support portion 271, and screwing the four corners of the attachment portions 272 and 272'. Is attached to the right side surface of the camera body 2. When the upper direction (direction D in FIG. 18) of the longitudinal center axis of the rotation support member 27 passing through the center of the support portion 271 is set as a reference direction, the rotation support member 27 has the image pickup portion 3 with respect to the camera body 2 as the reference direction. Is attached to the camera main body 2 so as to coincide with the rotation reference direction (A direction in FIG. 4).
[0059]
A hole 273 through which the ring portion 261 of the sliding ring 26 passes is formed in the support portion 271 of the rotation support member 27. An annular edge portion 274 protrudes around the hole 273 on the surface of the support portion 271 facing the inside of the camera body 2 (the left surface in FIG. 18, hereinafter referred to as an inner surface). A concave portion (not visible in FIG. 18) into which the flange portion 262 of the sliding ring 26 is fitted is formed on a surface facing the outside (hereinafter referred to as an outer surface).
[0060]
U-shaped small grooves 274a to 274c are formed at positions in the ± 90 ° direction and the 180 ° direction with respect to the reference direction of the outer peripheral surface of the edge portion 274. The small grooves 274a to 274c are for temporarily stopping the rotation operation of the imaging unit 3 attached to the connection plate 23 at the rotation reference position and the position rotated ± 90 ° with respect to the rotation reference position.
[0061]
The connection plate 23 is in the same direction as the rotation support member 27 in the reference direction on the inner surface of the support portion 271 (the central axis direction in the longitudinal direction of the connection plate 23 (direction E in FIG. 18) is the D direction of the rotation support member 27. And a switch 30 for detecting that the connection plate 23 is rotated by + 90 ° with respect to the rotation support member 27. The position where the connection plate 23 is in the same direction as the rotation support member 27 is a position where the imaging unit 3 mounted on the connection plate 23 is set at the rotation reference position, and the connection plate 23 is +90 with respect to the rotation support member 27. The rotated position is a position where the imaging unit 3 attached to the connection plate 23 is set at the front imaging position.
[0062]
Accordingly, the switch 29 turns off the main power supply when the imaging unit 3 is set at the rotation reference position, and turns on the main power supply when the imaging unit 3 is set at a position other than the rotation reference position. The switch 30 is a switch that detects that the imaging unit 3 is set at the front imaging position.
[0063]
In addition, a guide pin 275 that is loosely fitted in the groove 263 of the sliding ring 26 is provided at a proper position in the reference direction of the recess formed on the outer surface of the support portion 271.
[0064]
Here, the position detection operation of the switches 29 and 30 will be briefly described.
[0065]
FIG. 20 is a main part sectional view showing a position detection state of the switch 29, and FIG. 21 is a main part sectional view showing a position detection state of the switch 30.
[0066]
The switches 29 and 30 are momentary push switches. In a state where the sliding ring 26 is fitted in the recess of the rotation support member 27, the lever 29A of the switch 29 is positioned on a track (see TR1 in FIG. 19) passing through the notch 262A of the flange 262 of the sliding ring 26. The lever 30A of the switch 30 is positioned on a track (see TR2 in FIG. 19) passing through the notch 262B of the flange 262 of the sliding ring 26.
[0067]
When the connection plate 23 is in a position other than the rotation reference position, the switch 29 is in the ON state because the lever 29A is immersed in the switch main body 29B by the flange 262 (see FIG. 21), but the connection plate 23 is rotated. When the lever 29A is moved to the reference position, the lever 29A is inserted into the notch 262A and protrudes from the switch body 29B, so that the lever 29A is turned off (see FIG. 20). The switch 29 is provided on the supply line of the main power supply (power supply battery E), opens the power supply line in the on state to supply power, and closes the power supply line in the off state to cut off the power supply.
[0068]
Similarly, when the connection plate 23 is located at a position other than the front imaging position, the switch 30 is in the ON state because the lever 30A is immersed in the switch body 30B by the flange 262 (see FIG. 20). When 23 is moved to the front imaging position, the lever 30A is inserted into the notch 262B and protrudes from the switch body 30B, so that it is turned off (see FIG. 21), and the connection plate 23 is at the front imaging position due to this off signal. Detected.
[0069]
In the present embodiment, a mechanical switch is used as the detection element for the front imaging position of the connection plate 23, but the rotational position of the connection plate 23 may be detected using an optical sensor or a magnetic sensor. Moreover, you may make it detect the arbitrary rotation positions of the connection board 22 with an encoder.
[0070]
Referring back to FIG. 18, the click member 28 supports the connection plate 23 and the sliding ring 26 on the support portion 271 of the rotation support member 27 so as to be rotatable. The click member 28 is formed of a cylindrical member, and an engagement protrusion 281 that engages with the notch 261A of the sliding ring 26 is provided on the periphery of one end, and a connection plate is provided at a position opposite to the engagement protrusion 281. When 23 is set as the rotation reference position and the front imaging position, a protrusion 282 is provided that immerses in the small grooves 274a to 274c provided in the support portion 271 of the rotation support member 27 to give a click feeling. In addition, a wiring holding portion 283 having a U-shaped cross section is formed on the side surface of the cylindrical body where the protruding portion 282 is provided. The wiring holding portion 283 guides and holds the signal line wired from the camera body 2 to the connection plate 23 through the hole 273 of the rotation support member 27, the ring portion 261 of the sliding ring 26, and the through hole 251 of the reinforcing plate 25. Is to do.
[0071]
The through hole 284 of the click member 28 is provided with a step 284a in the vicinity of one end thereof, and the screw 31 fitted into the through hole 284 is screwed into the female screw portion 236 of the connection plate 23 to connect the click member 28 and the connection plate. 23 is fixed.
[0072]
In the above-described configuration, the connection plate 23 in which the substrate 24 is disposed in the recess 235 and the reinforcing plate 25 is attached allows the female screw portion 236 to pass through the ring portion 261 and the engagement protrusion 264 to the engagement hole 252. The sliding ring 26 is attached by being engaged. Further, in this state, the ring portion 261 of the sliding ring 26 is fitted into the hole 273 so that the guide pin 275 of the supporting portion 271 penetrates the groove 263, thereby supporting the rotation. It is attached to the outer surface of the member 27.
[0073]
The engaging protrusion 281 is engaged with the notch 261A of the sliding ring 26 through the hole 273 on the inner surface of the rotation support member 27, and the protrusion 282 is brought into contact with the outer peripheral surface of the edge 274 of the support 271. In this state, the screw 31 is inserted into the through hole 284, and the screw 31 is screwed into the female screw portion 236 of the connection plate 23 so that the click portion 28 and the connection plate 23 are integrated with the rotation support member 27. The connection plate unit is completed by being fixed in a rotatable manner. The connecting plate unit is attached to the right side surface of the camera body 2 when viewed from the front by screwing both corners of the mounting portions 272 and 272 ′ of the rotation support member 27.
[0074]
When the connection plate 23 is in the rotation reference position with the connection plate unit attached to the right side surface of the camera body 2, the switch 29 is turned off as described above, so that the imaging unit 3 is set to the rotation reference position. The main power supply is automatically turned off by setting, and the main power supply is automatically turned on by setting the imaging unit 3 to a position other than the rotation reference position.
[0075]
When the imaging unit 3 is rotated from the rotation reference position, the connection plate 23, the sliding ring 26, and the click member 28 rotate integrally. When the imaging unit 3 reaches a position rotated ± 90 ° from the rotation reference position, the protrusion 282 of the click member 28 is obtained. Is immersed in the small groove 274a or the small groove 274b of the rotation support member 27, and the imaging unit 3 is held at that position.
[0076]
In this way, the free rotation of the imaging unit 3 is stopped at the rotation reference position and the position rotated by ± 90 °, and the stopped state is maintained, so that the self-timer photographing at the time of storage or at the front imaging position can be performed. The posture of the digital camera 1 can be kept stable.
[0077]
When the image pickup unit 3 is rotated to the front image pickup position, an off signal is output from the switch 30 as described above. Therefore, the image pickup direction of the image pickup unit 3 coincides with the light emission direction of the built-in flash 5 by the off signal. Is detected. As will be described later, the output signal from the switch 30 is used for light emission control of the built-in flash 5 of the digital camera 1, and when an off signal is output from the switch 30 (that is, the imaging direction of the imaging unit 3 is the built-in flash 5. When the built-in flash 5 is allowed to emit light and an ON signal is output (that is, when the imaging direction of the imaging unit 3 is set in a direction different from the emission direction of the built-in flash 5). ), The flash of the built-in flash 5 is prohibited.
[0078]
The reason why the built-in flash 5 is forcibly prohibited when the imaging unit 3 is not set to the front imaging position is that the camera body 2 is provided with the built-in flash 5 in this embodiment. If the direction and the flash direction do not match, the imaged area and the flash area will be misaligned, so the subject in the shooting area cannot be illuminated with flash light evenly. This is because it becomes impossible to perform suitable flash photography.
[0079]
When the imaging unit 3 is rotated by a predetermined angle α ° beyond ± 90 ° from the rotation reference position, the guide pins 275 of the rotation support member 27 come into contact with both ends of the groove 263 of the sliding ring 26 and the connection plate 23 The rotation operation is restricted, and thus the imaging unit 3 can be rotated within the range of the rotation reference position ± (90 + α) °.
[0080]
In the present embodiment, the imaging unit 3 is attached to the right side surface of the camera body unit 2, but may be attached to the left side surface of the camera body unit 2.
[0081]
By the way, although the above-mentioned description was a structure in case the imaging part 3 is directly mounted | worn with the camera main-body part 2, the imaging part 3 can be connected to the camera main-body part 2 via a dedicated connection cable. it can.
[0082]
FIG. 24 is an external view of a connection cable for connecting the connection unit 3 to the camera body 2.
[0083]
The connection cable 32 is provided with a connection part 322 having the same connection structure as that of the connection plate 23 at one end of a cable 321 having a cable length of 1 m to several m, and the same as the mounting part 3B of the imaging unit 3 at the other end. A connection portion 323 having a connection structure is provided. In the connection part 322 connected to the attachment part 3B of the attachment part 3 and the connection part 323 connected to the connection plate 23, as shown in FIG. For example, an amplifier circuit 34 with a gain of 6 dB is provided. The buffer amplifier 33 and the amplifier circuit 34 are supplied with driving power from a power supply line for supplying power from the camera body 2 to the imaging unit 3. The resistors R1 and R2 are impedance matching resistors.
[0084]
The buffer amplifier 33 performs impedance conversion of the output of the image pickup unit 3 to reduce waveform distortion of the image pickup signal during transmission through the cable 321, and the amplifier circuit 34 compensates for attenuation of the image pickup signal due to impedance matching. Is. That is, when the buffer amplifier 33 is not provided, the imaging signal S at the output end of the cable 321 as shown in FIGS._G2Is the imaging signal S at the input end of the cable 321._G1The waveform is remarkably distorted and attenuated as compared with the above. However, by providing the buffer amplifier 33 and the amplifier circuit 34, the waveform distortion is reduced and the level drop is compensated. The image pickup signal at S in FIG._G2It can be improved like ′. As a result, A / D conversion and other signal processing of the image pickup signal in the camera main body 2 are made easy and accurate, and the deterioration of the image quality of the picked-up image is prevented.
[0085]
Note that either or both of the buffer amplifier 33 and the amplifier circuit 34 may be provided inside the imaging unit 3 and the camera main body 2, respectively. As the circuit configuration increases, power is supplied to the buffer amplifier 33 and the amplifier circuit 34 regardless of the presence or absence of the connection cable, and power is unnecessarily consumed. Therefore, the connection cable is preferably used as in this embodiment. It is better to have it inside.
[0086]
FIG. 27 is a block diagram of the digital camera 1.
[0087]
FIG. 2 is a block diagram when the camera body 2 and the imaging unit 3 are connected by the connection cable 32. In the figure, the same members as those shown in FIGS. 1 to 8 and 15 are denoted by the same reference numerals.
[0088]
The macro zoom lens 301 in the imaging unit 3 is provided with a diaphragm member (fixed diaphragm) having a fixed aperture. The signal processing circuit 313 and the timing generator (T · G) 314 are components of the imaging circuit 34. A CCD area sensor 303 (hereinafter abbreviated as “CCD 303”) is an image pickup element composed of a CCD color area sensor. The light image of the subject formed by the macro zoom lens 301 is converted into R (red), G (green), It is photoelectrically converted into an image signal of B (blue) color component (a signal comprising a signal sequence of pixel signals received by each pixel) and output. The timing generator 314 generates various timing pulses for controlling the driving of the CCD 303.
[0089]
The exposure control in the imaging unit 3 is performed by adjusting the exposure amount of the CCD 303, that is, the charge accumulation time of the CCD 303 corresponding to the shutter speed, since the aperture is a fixed aperture. If the appropriate shutter speed cannot be set when the subject brightness is low, the inappropriate exposure due to insufficient exposure is corrected by adjusting the level of the image signal output from the CCD 303. That is, when the luminance is low, exposure control is performed by combining the shutter speed and gain adjustment. The level adjustment of the image signal is performed in the gain adjustment of the AGC circuit in the signal processing circuit 313 described later.
[0090]
The timing generator 314 generates a drive control signal for the CCD 303 based on the reference clock CLK 0 transmitted from the camera body 2 via the connection cable 32 or the connection plate 23. The timing generator 314 generates, for example, a clock signal such as a timing signal for integration start / end (exposure start / end), a read control signal (horizontal synchronization signal, vertical synchronization signal, transfer signal, etc.) of the light reception signal of each pixel, Output to the CCD 303.
[0091]
The signal processing circuit 313 performs predetermined analog signal processing on the image signal (analog signal) output from the CCD 303. The signal processing circuit 313 includes a CDS (correlated double sampling) circuit and an AGC (auto gain control) circuit. The CDS circuit reduces the noise of the image signal and adjusts the gain of the AGC circuit to thereby generate the image signal. Adjust the level. Note that the gain of the AGC circuit is automatically set by the control unit 211 via the connection cable 32 or the connection plate 23.
[0092]
The light control circuit 304 controls the light emission amount of the built-in flash 5 in flash photography to a predetermined light emission amount set by the control unit 211 via the connection cable 32 or the connection plate 23. In flash photography, the flash light reflected from the subject is received by the light control sensor 305 simultaneously with the start of exposure, and when this light reception amount reaches a predetermined light emission amount, the light control circuit 304 connects the connection cable 32 or the connection plate 23. The light emission stop signal STP is output to the FL control circuit 214 provided in the camera main body 2 via. The FL control circuit 214 forcibly stops the light emission of the built-in flash 5 in response to the light emission stop signal STP, whereby the light emission amount of the built-in flash 5 is controlled to a predetermined light emission amount.
[0093]
Switch S_MACROIs a switch for detecting that the macro zoom lens 301 is switched to the macro lens. Switch S_MACROIs turned on when the zoom lever 306 is set to the macro position PM.
[0094]
Switch S_MAINIs a power switch of the digital camera 1 and corresponds to the switch 29 described above. Switch S_MAINIs turned off when the imaging unit 3 is set to the rotation reference position, and turned on when the imaging unit 3 is set to a position other than the rotation reference position.
[0095]
Switch S_CPOSIs a switch that detects that the imaging unit 3 is set to the front imaging position, and corresponds to the switch 30. Switch S_CPOSIs turned on when the imaging unit 3 is set to the front imaging position. Switch S_MAIN, S_MACRO, S_CPOSThe detection signal is input to the control unit 211 via the connection cable 32 or the connection plate 23.
[0096]
The connection cable 32 is provided with a grounded connection terminal f1. This connection terminal f <b> 1 is for inputting a connection signal of the connection cable 32 to the control unit 211. That is, the terminal d to which the connection terminal f1 of the control unit 211 is connected is set to a high level when power is supplied to the control unit 211, and the connection cable 32 is connected to the camera body unit 2. Then, a low level connection signal is input. The control unit 211 identifies the connection of the connection cable 32 according to the low level state of the terminal d.
[0097]
In the camera main body 2, the A / D converter 205 converts each pixel signal of the image signal input from the imaging unit 3 via the connection cable 32 into a 10-bit digital signal. The A / D converter 205 converts each pixel signal (analog signal) into a 10-bit digital signal based on the A / D conversion clock CLK2 input from the A / D clock generation circuit 203.
[0098]
In the camera body 2, a reference clock generation circuit 201 that generates a reference clock CLK 0, a T / G clock generation circuit 202 that generates a clock CLK 1 for the timing generator 314, and an A that generates a clock CLK 2 for the A / D converter 205. A / D clock generation circuit 203 is provided. Further, the A / D clock generation circuit 203 includes a delay circuit 204 therein.
[0099]
Driving of the reference clock generation circuit 201, the T / G clock generation circuit 202, and the A / D clock generation circuit 203 is controlled by the control unit 211. The TG clock generation circuit 202 generates a clock CLK1 based on the reference clock CLK0, and outputs the cook CLK1 to the timing generator 314 in the imaging unit 3 via the connection plate 23 or the connection cable 32.
[0100]
The A / D clock generation circuit 203 generates an A / D conversion clock CLK2 based on the reference clock CLK0 when the imaging unit 3 is connected to the camera body 2 via the connection plate 23. When the clock CLK2 is output to the A / D converter 205 and the imaging unit 3 is connected to the camera body 2 via the connection cable 32, the A / D clock generation circuit 203 generates a clock based on the reference clock CLK0. A clock CLK2 ′ delayed from the CLK2 by a predetermined time Δt is generated, and this clock CLK2 ′ is output to the A / D converter 205. Information on the presence / absence of the connection cable 32 is input from the control unit 211 to the A / D clock generation circuit 203, and the A / D clock generation circuit 203 generates either the clock CLK2 or CLK2 ′ based on this information.
[0101]
The delay time Δt is the image signal S input to the A / D converter 205 when there is no connection cable 32._G2(Image signal S output from the imaging unit 3_G1Image signal S input to the A / D converter 205 when the connection cable 32 is present._G2'And the time corresponding to the phase difference. Since the delay time Δt is constant if the length of the connection cable 32 is constant, the delay time Δt is preset in the delay circuit 204.
[0102]
Accordingly, when the imaging unit 3 is connected to the camera body 2 via the connection cable 32, as shown in FIG. 28, the image signal S input to the A / D converter 205 when there is no connection cable 32._G2And an image signal S input to the A / D converter 205 when the connection cable 32 is present._G2A phase difference θ occurs between the clock signal CLK and the image signal S by delaying the clock CLK2 ′ by θ from the clock CLK2._G2'Is synchronized with each pixel signal of the image signal S_G2A / D conversion can be performed accurately and reliably.
[0103]
In FIG. 28, g (i) (i = 1, 2,...) Indicates each image signal constituting the image signal. The A / D conversion is performed at the rising timings of the clocks CLK2 and CLK2 ′. The clocks CLK2 and CLK2 ′ are sent to the A / D converter 205 so that the rising timing is substantially at the center of each pixel signal g (i). Entered.
[0104]
The present embodiment is for a case where the cable length is one type, but when a plurality of connection cables 32 having different lengths are prepared, the phase difference θ differs for each connection cable 32. A plurality of delay times Δt corresponding to the connection cable 32 may be stored in the delay circuit 204, and the delay time Δt of the delay circuit 204 may be selectively set according to the connected connection cable 32. In this case, each connection cable 32 is provided with two or more connection terminals f1, f2,..., Partially or entirely grounded, and the type of connection cable 32 connected from the ground information of the connection terminals f1, f2,. The delay time Δt of the delay circuit 204 may be automatically set to a predetermined time corresponding to the connected connection cable 32. For example, when two connection terminals f1 and f2 are provided, if the ground side of the connection terminal (f1, f2) is represented by “1” and the open side is represented by “0”, (f1, f2) = (1, 0) , (0, 1) and (1, 1) are conceivable, so the three types of connection cables 32 having different lengths are identified from the ground information of the connection terminals (f1, f2), and the connection terminals ( The delay time Δt corresponding to the connection cable 32 used can be automatically set based on the ground information of f1, f2).
[0105]
In this embodiment, the clock CLK2 is delayed to generate the clock CLK2 ′. However, the clock CLK2 may be shifted in phase to generate the clock CLK2 ′. The clock CLK2 ′ may be directly generated by controlling the frequency division timing.
[0106]
The black level correction circuit 206 corrects the black level of the A / D converted pixel signal (hereinafter referred to as pixel data) to a reference black level. The WB circuit 207 performs level conversion of pixel data of each of R, G, and B color components so that the white balance is also adjusted after γ correction. The WB circuit 207 uses the level conversion table input from the control unit 211 to convert the pixel data levels of the R, G, and B color components. Note that the conversion coefficient (characteristic gradient) of each color component in the level conversion table is set for each captured image by the control unit 211.
[0107]
The γ correction circuit 208 corrects the γ characteristic of the pixel data. The γ correction circuit 208 has six types of γ correction tables with different γ characteristics, and performs γ correction of pixel data using a predetermined γ correction table according to the shooting scene and shooting conditions. The γ correction table includes γ = 0.45 and γ = 0.55. When the captured image is displayed on the LCD display unit 10 in the release standby state, the γ correction circuit 208 When the γ correction of the captured image is performed with the γ characteristic of γ = 0.45 and the released captured image is recorded on the IC card 18, the γ correction of the captured image is performed with the γ characteristic of γ = 0.55. . This is because the LCD display unit 10 has a γ characteristic of γ = 2.2, whereas the recorded image of the IC card 18 usually has a γ characteristic of γ = 1.8. This is because the image quality is suitable for the display device on which the captured image is reproduced.
[0108]
In this γ correction process, 10-bit pixel data is converted into 8-bit (256 gradation) pixel data. The reason why the image data before γ correction processing is 10-bit data is to prevent image quality deterioration when γ correction is performed with a highly nonlinear γ characteristic.
[0109]
The image data of each color component of R, G, B is subjected to predetermined level conversion by the WB circuit 207, and γ correction and WB adjustment are performed by γ-correcting these image data with the γ correction table. Are performed simultaneously.
[0110]
The image data of each color component of R, G, B is subjected to predetermined level conversion by the WB circuit 207, and γ correction and WB adjustment are performed by γ-correcting these image data with the γ correction table. Are performed simultaneously.
[0111]
The image memory 209 is a memory that stores pixel data output from the γ correction circuit 208. The image memory 209 has a storage capacity for one frame. That is, the image memory 209 has a storage capacity of pixel data for n × m pixels when the CCDC 3 has pixels of n rows and m columns, and each pixel data G (i, j) (i = 1). , 2... N, 1, 2,... M) are stored in the corresponding pixel positions (i, j).
[0112]
The image memory 210 is a buffer memory for image data reproduced and displayed on the LCD display unit 10. The image memory 210 has a storage capacity for image data corresponding to the number of pixels of the LCD display unit 10.
[0113]
In the shooting standby state, each pixel data of an image captured every 1/30 (seconds) by the imaging unit 3 is subjected to predetermined signal processing by the A / D converter 205 to the γ correction circuit 208, and then the image The data is stored in the memory 209, transferred to the image memory 210 via the control unit 211, and displayed on the LCD display unit 10. As a result, the photographer can visually recognize the subject image from the image displayed on the LCD display unit 10. In the reproduction mode, the image read from the IC card 18 is subjected to predetermined signal processing by the control unit 211, then transferred to the image memory 210, and reproduced and displayed on the LCD display unit 10.
[0114]
The card I / F 212 is an interface for writing image data to the IC card 18 and reading image data. Further, the communication I / F 213 is an interface compliant with, for example, the RS-232C standard for externally connecting the personal computer 19 so as to allow communication.
[0115]
The FL control circuit 214 is a circuit that controls light emission of the built-in flash 5. The FL control circuit 214 controls the presence / absence of light emission, the light emission amount, the light emission timing, and the like of the built-in flash 5 based on the control signal of the control unit 211, and the light emission input from the light control circuit 304 via the cable 32 or the connection plate 23. Based on the stop signal STP, the light emission amount of the built-in flash 5 is controlled.
[0116]
Switch S_UP, Switch S_DOWNAnd switch S_DELAre switches corresponding to the UP switch 6, the DOWN switch 7, and the erase switch 8, respectively. Switch S_RELIs a switch for detecting the release operation of the shutter button 9, and the switch S_FL, Switch S_COMPAnd switch S_{P / R}Are switches corresponding to the FL mode setting switch 11, the compression rate setting switch 12, and the shooting / playback mode setting switch 14, respectively.
[0117]
The control unit 211 includes a microcomputer, and organically controls driving of each member in the imaging unit 3 and the camera main body 2 described above, thereby comprehensively controlling the photographing operation of the digital camera 1.
[0118]
The control unit 211 includes a luminance determination unit 211a and a shutter speed setting unit 211b for setting an exposure control value (shutter speed (SS)).
[0119]
The luminance determination unit 211a determines the brightness of the subject using an image captured every 1/30 (seconds) by the CCD 303 in the shooting standby state. That is, the luminance determination unit 211a determines the brightness of the subject using image data stored in the image memory 209 in an update manner.
[0120]
The luminance determination unit 211a divides the storage area of the image memory 209 into nine blocks, and pixel data G of G (green) color component included in each block B, for example._RIs calculated as luminance data representing the block. Then, the brightness of the subject is determined using the nine pieces of luminance data.
[0121]
In addition, pixel data G of each color component of R, G, B_R, G_G, G_BThe luminance data representing each block may be calculated using. That is, the pixel data G of each color component of R, G, B at each pixel position (i, j)_R, G_G, G_BIs a predetermined ratio (for example, G_RG_GG_B= 4: 5: 1) and luminance data BV (i, j) (= 0.4G) at the pixel position (i, j)_R+ 0.5G_G+ 0.1G_B) And the average value of these luminance data BV (i, j) may be calculated to calculate the luminance data of each block.
[0122]
The shutter speed setting unit 211b sets the shutter speed (integration time of the CCD 303) based on the determination result of the brightness of the subject by the luminance determination unit 211a. The shutter speed setting unit 211b has a table of shutter speed SS.
[0123]
The shutter speed SS is initially set to a predetermined value (for example, 1/128 (seconds)) when the camera is activated. In the shooting standby state, the shutter speed setting unit 211b responds to the determination result of the brightness of the subject by the luminance determination unit 211a. Change the setting from the initial value to the high speed side or low speed side one step at a time.
[0124]
As a result, when the brightness of the subject first determined based on the image captured at the initial shutter speed SS is too bright, for example, the shutter speed SS is increased by one step (for example, 1/144). The next image is taken (set to (seconds)), and the brightness of the subject is determined again based on this image. If this determination result is still too clear, for example, the shutter speed SS is further increased by one step (for example, set to 1/161 (seconds)), and the next image is captured. The appropriate shutter speed SS is set after a lapse of time in which the brightness determination and the resetting of the shutter speed SS are alternately repeated.
[0125]
When the photographing is instructed by the shutter button 9 in the photographing mode, the control unit 211 uses the thumbnail image of the image taken into the image memory 209 after the photographing instruction and the compression rate K set by the compression rate setting switch 12 as JPEG ( A compressed image compressed by the Joint Photographic Coding Experts Group) is generated, and both images are stored in the IC card 18 together with index information (frame number, exposure value, shutter speed, compression rate K, etc.) regarding the captured image. .
[0126]
As shown in FIG. 29, the storage area of the IC card 18 is mainly divided into three areas: a TAG area AR1, a thumbnail image area AR2, and a main image area AR3. In the TAG area AR1, the thumbnail image area AR2, and the main image area AR3, index information, thumbnail images, and compressed images regarding the captured images of the respective frames are recorded.
[0127]
The thumbnail image is a small image obtained by thinning the pixel data of the photographed image to reduce the resolution. For example, assuming that the total number of pixel data constituting the photographed image is 480 × 640, the thumbnail image is generated by reducing the number of pixels to 1/8 both vertically and horizontally. Therefore, the number of pixels constituting the thumbnail image is 1/64 of the original captured image. In addition, since the original photographed image is compressed with the number of data actually recorded on the IC card 18, the number of thumbnail image data is not 1/64 of the compressed image. For example, when the compression rate K = 1/8, the number of thumbnail image data is 1/8 (= 8/64) of the compressed image. When the compression rate K = 1/20, the number of thumbnail image data is compressed. This is 1 / 3.2 (= 20/64) of the image.
[0128]
The control unit 211 includes a filter unit 211c that performs a filtering process and a recorded image generation unit 211d that generates a thumbnail image and a compressed image in order to perform the recording process of the captured image, and the image recorded on the IC card 18 is recorded. In order to reproduce on the LCD display unit 10, a reproduction image generation unit 211e that generates a reproduction image is provided.
[0129]
The filter unit 211c corrects the image quality related to the contour by correcting the high frequency components of the image to be recorded by the digital filter. The filter unit 211c includes a digital filter that performs standard contour correction for each of the compression ratios K = 1/8 and 1/20, and two types of digital filters that enhance the contour with respect to this standard contour correction. A total of five types of digital filters including two types of digital filters that weaken the contour are provided.
[0130]
The above five types of digital filters are prepared for each of the compression ratios K = 1/8 and 1/20 because the JPEG method is an irreversible conversion, and a reproduced image with a compression ratio k = 1/20 High-frequency components are reduced compared to a reproduced image with a compression rate K = 1/8, and the image is slightly out of focus. Therefore, when filtering is performed with a digital filter having the same filter coefficient, the compression rate k = 1. This is to prevent such an adverse effect since a stripe pattern may appear in the reproduced image of / 20.
[0131]
The recorded image generation unit 211d reads out pixel data from the image memory 209 and generates a thumbnail image and a compressed image to be recorded on the IC card 18. The recorded image generation unit 211d reads out pixel data for every 8 pixels in both the horizontal direction and the vertical direction while scanning from the image memory 209 in the raster scanning direction, and sequentially transfers them to the thumbnail image area AR2 of the IC card 18. Thus, a thumbnail image is generated and recorded on the IC card 18.
[0132]
Further, the recorded image generation unit 211d reads out all pixel data from the image memory 209, and performs predetermined compression processing by JPEG method such as two-dimensional DCT conversion and Huffman coding on the pixel data to obtain the image data of the compressed image. The compressed image data is generated and recorded in the main image area AR 3 of the IC card 18. The index information is generated by an index information generation unit (not shown), and is recorded in the TAG area AR1 before or after the thumbnail image and main image recording processing.
[0133]
The reproduction image generation unit 211e reads out image data from the IC card 18 and generates a thumbnail image and a main image to be reproduced and displayed on the LCD display unit 10. Since the image recorded on the IC card 18 is γ-corrected with the monitor TV γ coefficient (= 0.55), when the recorded image is reproduced on the LCD display unit 10 as it is, the γ coefficient and the LCD display are displayed. Since the inconsistency with the γ coefficient (= 0.45) results in strong and strong image quality, the reproduction image generation unit 211e regenerates the γ characteristics of the reproduction image when generating the thumbnail image and the reproduction image of the main image. to correct.
[0134]
That is, the reproduction image generation unit 211e adds γ characteristics of γ = 0.82 (= 0.45 / 0.55) to the image data read while scanning in the raster scanning direction from the thumbnail image area AR2 of the IC card 18. After the γ correction is performed in, pixel data for display (pixel data obtained by interpolating the deficient pixel data) is generated in units of horizontal lines based on the image data, and sequentially transferred to the image memory 210 to display thumbnail images. Playback display on the LCD display unit 10 is performed.
[0135]
Further, the reproduction image generation unit 211e generates pixel data for display by expanding the pixel data of the compressed image read out from the main image area AR3 of the IC card 18 in units of horizontal lines, and γ = After performing γ correction with a γ characteristic of 0.82, the image is sequentially transferred to the image memory 210 to reproduce and display the main image on the LCD display unit 10.
[0136]
Next, operation control in the shooting / playback mode of the digital camera 1 will be described.
[0137]
FIG. 30 is a main routine for controlling the operation of the digital camera 1. When the main power is turned on, the state of the shooting / playback mode setting switch 14, that is, the switch S_{P / R}When the mode setting state is discriminated (# 2) and the mode setting state is the reproduction mode (YES in # 2), the “reproduction mode” shown in FIGS. The reproduction mode processing is performed in accordance with the subroutine "-", and if the photographing mode is selected (NO in # 2), the imaging mode processing is performed in accordance with the subroutine "imaging mode" shown in FIG. .
[0138]
In the playback mode, first, after the initial value of the counter for counting the number of frames n is set to “1” (# 10), the thumbnail image of the first frame is displayed on the LCD display unit 10 (# 12- # 16). That is, the thumbnail image of the first frame is read from the thumbnail image area AR2 of the IC card 18 (# 12), the thumbnail image is γ-corrected with the γ characteristic of γ = 0.82, and the display size of the LCD display unit 10 is displayed. (# 14), the thumbnail image is transferred to the image memory 210 and the thumbnail image is displayed on the LCD display unit 10 (# 16).
[0139]
Thereafter, an image compressed by the JPEG method in the first frame (hereinafter referred to as a main image) is displayed on the LCD display unit 10. That is, after reading the main image of the first frame from the main image area AR3 of the IC card 18 in units of lines (# 18), this line image is expanded and γ corrected with γ characteristics of γ = 0.82 (# 20) The image is transferred to the image memory 210 and the main image is displayed on the LCD display unit 10 (# 22).
[0140]
As described above, the digital camera 1 displays the main image after displaying the thumbnail image in the reproduction display of the recorded image of each frame on the LCD display unit 10. As described above, the thumbnail image is displayed before the main image is displayed. The display processing of the thumbnail image is about 0.5 seconds while the display processing of the entire main image requires about 2 seconds. Therefore, by displaying the thumbnail image before the entire main image is displayed, the waiting time of the user in the reproduction process is reduced.
[0141]
Further, the display of the main image is performed in units of lines, and as shown in FIG. 33, the thumbnail image is replaced with the main image in units of lines so that the user can know the progress of the reproduction process of the main image.
[0142]
In the figure, (a) shows a state in which a thumbnail image is displayed, (b) shows a state in which the thumbnail image is changed to the main image in line units, and (c) shows the entire main image. The displayed state is shown. The recorded image of each frame is displayed together with information such as a frame number, a title, and a shooting date, and the information is displayed in an information display area 40 provided above the display area of the LCD display unit 10. It has become. For example, the frame number is displayed at the left end of the information display area 40, and the shooting date is displayed at the right end of the information display area 40.
[0143]
Subsequently, the ON / OFF state of the UP switch 6, the DOWN switch 7, and the erase switch 8 is sequentially determined (# 24 to # 28). If the UP switch 6 is ON (YES in # 24), the number of frames n Is incremented by 1 (# 32), and the DOWN switch 7 is ON (YES in # 26), the frame number n is decremented by 1 (# 34), the process proceeds to # 38, and the nth frame thumbnail An image is displayed on the LCD display unit 10 (# 38 to # 42).
[0144]
On the other hand, if the erase switch 8 is on (YES in # 28), the image data of the frame number displayed is erased according to the "image erase" subroutine shown in FIG. 34 (# 36), and the UP switch 6 If both the DOWN switch 7 and the erasure switch 8 are OFF (NO in # 28), it is determined whether or not the playback mode is maintained (that is, whether or not the shooting / playback mode setting switch 14 is operated). ) Is determined (# 30), and the playback mode is switched to the shooting mode (NO in # 30), the process returns to exit the playback mode process. If the playback mode is maintained, the process returns to # 24. , Display of the current frame number on the LCD display unit 10 is continued until any of the UP switch 6, DOWN switch 7 and erasure switch 8 is operated (# 24 to # 3). Of the loop).
[0145]
In # 38 to # 42, similarly to the thumbnail image of the first frame, reading of the thumbnail image of the nth frame from the thumbnail image area AR2 of the IC card 18 (# 38), γ correction and enlargement processing (# 40) are performed. Thus, the thumbnail image is displayed on the LCD display unit 10.
[0146]
Subsequently, after a waiting time of 0.5 seconds (# 43), the ON / OFF state of the UP switch 6 or the DOWN switch 7 is sequentially determined during the display processing of the n-th thumbnail image (# 44, # 46) If the UP switch 6 is ON (YES in # 44), the frame number n is incremented by 1 (# 48), and if the DOWN switch 7 is ON (YES in # 46), the frame number n is 1. (# 50), the process proceeds to # 38, and the thumbnail image of the (n + 1) -th frame or (n-1) -th frame is displayed on the LCD display unit 10 (# 38- # 43).
[0147]
The processing of # 38 to # 50 is processing when the UP switch 6 or the DOWN switch 7 is operated before the main image is displayed, and it takes about 0.5 seconds for the thumbnail image display processing. When the UP switch 6 or the DOWN switch 7 is continuously operated, the thumbnail images of the respective frames are displayed approximately every second.
[0148]
If neither the UP switch 6 nor the DOWN switch 7 is operated during display processing of the nth frame thumbnail image (# 46), display processing of the currently displayed nth frame main image on the LCD display unit 10 is performed. Is performed (# 52 to # 58).
[0149]
In # 52 to # 58, similarly to the thumbnail image of the first frame, the compressed image of the nth frame is read from the main image area AR3 of the IC card 18 (# 52), decompression and γ correction processing (# 54). This is performed in units of lines, and the main image is displayed on the LCD display unit 10.
[0150]
The determination of # 58 is for performing processing when the UP switch 6 or the DOWN switch 7 is operated during display processing of the main image in units of lines, and the entire main image is displayed on the LCD display unit 10. If not (NO in # 58), the process returns to # 44 to determine the operation state of the UP switch 6 or the DOWN switch 7. If the UP switch 6 or the DOWN switch 7 is operated during the main image display processing in units of lines by the loop of # 44 to # 58, the main image display processing is stopped, and # 38 to # 42. Thus, the thumbnail image of the (n + 1) -th frame or the (n-1) -th frame is displayed on the LCD display unit 10.
[0151]
On the other hand, when the display of the entire main image on the LCD display unit 10 is completed (YES in # 58), the process returns to # 24, and the display image is displayed in accordance with the operation of the UP switch 6, the DOWN switch 7, and the erase switch 8. The frame number is updated or the display image is erased.
[0152]
Next, the image erasing process of # 36 will be described with reference to the flowchart of FIG.
[0153]
First, the on / off state of the erasure switch 8 is determined (# 60). If the erasure switch 8 is on (YES in # 60), the display image on the LCD display unit 10 is erased line by line from the top (# 62). That is, the image data stored in the image memory 210 is erased in units of one line from the top.
[0154]
Subsequently, it is determined whether or not the display image on the LCD display unit 10 has been completely erased (# 66). If the display image is being erased, the process proceeds to # 60, unless the erase switch 8 is turned off. The display image erasing process is continued (loop of # 60 to # 66).
[0155]
On the other hand, if the erasure switch 8 is turned off during the erasure processing of the display image (NO in # 60), the erasure of the display image on the LCD display unit 10 is stopped, and the already erased portion of the image is redisplayed on the LCD display unit 10. Displayed (# 64) and returns.
[0156]
When the display image on the LCD display unit 10 is completely erased (YES in # 66), the image data corresponding to the current display image recorded in the main image area AR3 of the IC card 18 is erased ( # 68) Return.
[0157]
As described above, when the deletion of the image data is instructed by the deletion switch 8, the image data in the IC card 18 is deleted after the image displayed on the LCD display unit 10 is deleted. This is to prevent the image data in the IC card 18 from being accidentally erased due to an operation mistake of the erase switch 8.
[0158]
Further, the reason why the display image on the LCD display unit 10 is erased in units of lines is to provide a grace time for the above-mentioned operation error and to use this grace time to visually erase the image data to the user. This is for notification. The user can confirm that the image data erasing process is being performed based on the line-by-line erasure state of the display image on the LCD display unit 10, and in the case of an operation error, turn off the erasure switch 8. Thus, it is possible to easily avoid erroneous erasure of image data.
[0159]
Next, the shooting mode process of # 6 will be described with reference to the flowchart of FIG.
[0160]
In the shooting mode, the image is picked up by the CCD 303 (# 70), and while the picked-up image is subjected to predetermined image processing in the camera body 2, the image pickup unit 3 is in front of the camera 30 based on the detection signal from the switch 30. It is determined whether or not the imaging position is set (# 72). If the imaging unit 3 is set to the front imaging position (YES in # 72), the captured image is displayed on the LCD display unit 10 (# 74), and if the imaging unit 3 is not set to the front imaging position (# 74). In step # 72, NO is displayed, and the captured image is displayed on the LCD display unit 10 and a warning is displayed indicating that the built-in flash 5 is prohibited from emitting light (# 76).
[0161]
FIG. 36 shows a display example of the LCD display unit 10 when the imaging unit 3 is set to the front imaging position, and FIG. 37 illustrates the LCD display unit 10 when the imaging unit 3 is not set to the front imaging position. It is a figure which shows the example of a display.
[0162]
In the information display area 40 provided above the display area of the LCD display unit 10, information such as the frame number and the shooting date and time is displayed, and the flash emission mode is displayed as a symbol mark of a light emitting arrow. The flash emission mode is displayed at the center of the information display area 40, and the shooting date and time is displayed at the right end of the information display area 40. The shooting date and time display area also serves as the warning display area.
[0163]
Therefore, when the image pickup unit 3 is not set to the front image pickup position, as shown in FIG. 37, a “light emission impossible” mark M in which a light emitting arrow and a character “OFF” are combined is displayed in the shooting date and time display area. A warning is displayed.
[0164]
In this embodiment, a warning is given by display, but a warning may be given by a warning sound such as a buzzer, or a warning may be given by both sound and display.
[0165]
Next, release switch S_RELIs determined to be on (# 78), the release switch S_RELIs OFF (NO in # 78), the process returns to # 70, and the display of the above-described captured image or flash emission prohibition warning on the LCD display unit 10 is continued (loop of # 70 to # 78). This display state is a shooting standby state, in which the LCD display unit 10 is operating as an electronic viewfinder.
[0166]
In the shooting standby state, the release switch S_RELIs turned on (YES in # 78), it is sequentially determined whether or not shooting is performed by flash emission and whether or not the imaging unit 3 is set to the front imaging position (# 80 and # 82), and flash emission is performed. If there is no shooting (NO in # 80) or the imaging unit 3 is not set to the front imaging position (NO in # 82), imaging is performed without emitting the built-in flash 5 (# 86). If shooting is performed with flash emission and the imaging unit 3 is set to the front imaging position (YES in # 80 and # 82), the built-in flash 5 is emitted to perform imaging (# 84).
[0167]
Subsequently, the captured image is subjected to predetermined image processing for display in the camera body 2 and then displayed on the LCD display unit 10 (# 88), while predetermined image processing for recording is performed. Thereafter, it is recorded on the IC card 18 (# 90), thereby completing one photographing operation. Then, the process returns to # 70 to capture the next image.
[0168]
【The invention's effect】
As described above, according to the present invention, each frame is composed of the first image and the second image having a longer time for playback processing on the display means than the first image.ButConfigured, multipleofA digital camera that sequentially reads out the captured images of each frame from the storage means storing the captured images of the frames, and reproduces and displays them on the display means, and the frames to be reproduced by the instruction means are continuous at intervals within a predetermined time. The first image of the designated frame is continuously reproduced on the display means,Within the predetermined timeInstructedWhen there was not,With continuous instructionsSince the second image of the last designated frame is reproduced on the display means, for example, when the captured image of each frame is composed of a high-quality compressed image and an uncompressed thumbnail image, Is continuously displayed, thumbnail images can be continuously displayed to quickly confirm the captured content of each frame and to quickly advance to a desired frame position (claim 1).
[0169]
Further, the present invention includes display means for displaying an image, and each frame is composed of a first image and a second image having a longer processing time for reproduction to the display means than the first image. A digital camera that sequentially reads captured images of each frame from a storage unit configured to store captured images of a plurality of frames, and reproduces and displays them on the display unit. Instruction means for instructing and playback by the above instruction meansYouShouldNextWhen the first frame is instructed, the first image of the second frame is reproduced and displayed on the display means after the display processing of the first image of the first frame is completed, and should be reproduced next within a predetermined time. When the frame image is not instructed, the display control means for reproducing and displaying the second image of the first frame on the display means after the display processing of the first image of the first frame is completed. The instruction means gives a playback instruction for the next frame for a predetermined time.InsideIs performed, the first image of the next frame is reproduced and displayed, and the next frame is instructed for a predetermined time.InsideOtherwise, after the reproduction and display of the first image of the current frame is completed, the second image of the current frame is reproduced and displayed, and the first image is compared to the second image. Since the processing time for reproduction is short, the captured content of each frame can be quickly confirmed, and the frame can be quickly advanced to a desired frame position.
[0170]
Further, according to the present invention, when the second image is reproduced and displayed, the first image currently displayed is overwritten and displayed on a line-by-line basis. The state can be notified (claim 9).
[0171]
Further, according to the present invention, since the storage means is a recording medium removable from the camera, the convenience of handling is increased (claim 10).
[Brief description of the drawings]
FIG. 1 is a front view of a digital camera according to the present invention.
FIG. 2 is a rear view of the digital camera according to the present invention.
FIG. 3 is a top view of the digital camera according to the present invention.
FIG. 4 is a right side view of the digital camera according to the present invention.
FIG. 5 is a bottom view of the digital camera according to the present invention.
FIG. 6 is a diagram illustrating an internal light image of an imaging unit.
FIG. 7 is a diagram showing a state in which the lid of the power battery and the IC card is opened.
FIG. 8 is a diagram showing a first example of the arrangement of the loading chambers for the power battery and the IC card.
FIG. 9 is a diagram showing a second example of the arrangement of the power battery and IC card loading chamber.
FIG. 10 is a diagram showing a third example of the arrangement of the power cell and IC card loading chamber.
FIG. 11 is a longitudinal sectional view of a main part of a battery loading chamber provided with a friction member for preventing the battery from dropping.
FIG. 12 is a cross-sectional view of a main part of a battery loading chamber in which a friction member is provided.
FIG. 13 is a longitudinal sectional view of a main part of a battery loading chamber provided with a spring member for preventing the battery from dropping.
FIG. 14 is a longitudinal sectional view of a main part of a battery loading chamber provided with a stopper mechanism using a friction ball for preventing the battery from dropping.
FIG. 15 is a perspective view of a camera body.
FIG. 16 is a perspective view for explaining a connection mechanism between an imaging unit and a connection plate.
FIG. 17 is a cross-sectional view of the main part showing the structure of the lock release lever.
FIG. 18 is an exploded perspective view showing the structure of the connection plate unit.
FIG. 19 is a plan view of a sliding ring.
FIG. 20 is a cross-sectional view of an essential part showing a detection state of a switch that detects that the connection plate is at the rotation reference position and turns off the main power supply.
FIG. 21 is a cross-sectional view of a main part showing a detection state of a switch for detecting that the connection plate is at the front imaging position.
FIG. 22 is a right side view showing the position of the rotation axis of the imaging unit with respect to the camera body.
FIG. 23 is a front view showing the position of the rotation axis of the imaging unit with respect to the camera body.
FIG. 24 is an external view of a connection cable that connects an imaging unit and a camera body.
FIG. 25 is a diagram illustrating a circuit configuration in an imaging unit of a connection cable.
26A and 26B are diagrams illustrating a waveform of an image signal, where FIG. 26A is a waveform diagram of an image signal at an input end of a connection cable, and FIG. 26B is a waveform diagram of an image signal at an output end of a connection cable having a buffer circuit;
(C) is a waveform diagram of an image signal at the output end of a connection cable having no buffer circuit.
FIG. 27 is a block diagram of a digital camera according to the present invention.
FIG. 28 is a waveform diagram of an image signal and an A / D conversion clock input to the A / D converter when the cable is connected and when the cable is not connected.
FIG. 29 is a diagram showing a configuration of a storage area of an IC card.
FIG. 30 is a main flowchart showing control of photographing / reproducing operation of the digital camera according to the present invention.
FIG. 31 is a flowchart showing control of playback mode processing;
FIG. 32 is a flowchart showing control of playback mode processing;
FIGS. 33A and 33B show a display example when a recorded image is reproduced and displayed on the LCD display unit. FIG. 33A is a diagram showing a state in which a thumbnail image is displayed. FIG. (C) is a diagram showing a state in which thumbnail images are displayed.
FIG. 34 is a flowchart showing control of image erasure processing.
FIG. 35 is a flowchart illustrating control of shooting mode processing.
FIG. 36 is a diagram showing a state in which a subject image is displayed on a monitor on an LCD display unit.
FIG. 37 is a diagram illustrating a state in which a warning for prohibiting flash emission is displayed on the lCD display unit based on a mismatch between the flash emission direction and the imaging direction.
[Explanation of symbols]
1 Digital camera
2 Camera body
211 control unit (first and second display control means)
3 Imaging unit
4 Grip part
5 Built-in flash
6 UP switch (instruction means)
7 DOWN switch (instruction means)
8 Erase switch
9 Shutter button
10 LCD display section (display means)
11 FL mode setting switch
12 Compression rate setting switch
13 Connection terminal
14 Shooting / playback mode setting switch
15 lid
16 Battery compartment
17 Card loading room
18 IC card (memory means)
19 Personal computer
23 Connection board
29 switches
30 switches
32 Dedicated cable
S_MACRO, S_MAIN, S_CPOS  switch
S_REL, S_{P / R}, S_UP, S_DOWN, S_FL, S_DEL, S_COMP  switch

Claims (10)

A plurality of frames, each having a display means for displaying an image, each frame being constituted by a first image and a second image having a longer processing time for reproduction to the display means than the first image. A digital camera that sequentially reads out the captured images of each frame from the storage means storing the captured images of the frames, and reproduces and displays them on the display means,
Instruction means for instructing the display means on the frame to be reproduced;
When the frames to be reproduced are instructed continuously at intervals within a predetermined time by the instruction means, the display of the first image of the frame instructed last time is completed and the instruction is made this time. First display control means for reproducing and displaying the first image of the displayed frame on the display means;
When the frame to be reproduced Ri by the said instruction means within the predetermined time has not instructed, after the display processing to the display unit of the first image of the instruction to end in a continuous indication frame has been completed, the A digital camera comprising: second display control means for reproducing and displaying a second image of a frame on the display means. A plurality of frames having display means for displaying an image, each frame being constituted by a first image and a second image having a longer processing time for reproduction to the display means than the first image; A digital camera that sequentially reads out the captured images of each frame from the storage means storing the captured images of the frames, and reproduces and displays them on the display means,
Instruction means for instructing the display means on the frame to be reproduced;
When the next frame to be reproduced is instructed by the instruction means, after the first image display processing of the first frame is completed, the first image of the second frame is reproduced and displayed on the display means. Display control for reproducing and displaying the second image of the first frame on the display means after the display processing of the first image of the first frame is completed when the next frame to be reproduced is not designated within the time And a digital camera. 3. The digital camera according to claim 1, wherein the first image and the second image are generated from a photographed image obtained by photographing the same subject. 3. The digital camera according to claim 1, wherein the first image is a thumbnail image. 3. The digital camera according to claim 1, wherein the first image is an image in which a photographed image is stored in an uncompressed state in which the number of data is smaller than that of the second image. 6. The digital camera according to claim 1, wherein the second image is an image obtained by storing a photographed image in a compressed state. The digital camera according to claim 6, wherein the reproduction process is a process of expanding a compressed image. The digital camera according to claim 1, wherein the second image is an image compressed by a JPEG method. 9. The digital camera according to claim 1, wherein the second image is displayed by being overwritten on the displayed first image in units of lines. The digital camera according to claim 1, wherein the storage unit is a recording medium removable from the camera.

Images