JP4061002B2 - camera - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an improvement of a camera that can perform close-up photography, and more particularly to a camera that reduces an underexposure tendency in close-up photography mode.
[0002]
[Prior art]
In general, cameras that perform close-up shooting of subjects by adjusting the aperture opening and exposure time of the shutter are known, and in the case of the above-mentioned close-up shooting, the lens position is set and fixed at a short distance, and the shutter speed is increased. In addition to reducing the exposure time, the aperture of the shutter was made small, and the depth of field was increased to enable close-up photography.
Here, if the shutter speed is set to a small value so that the shutter is set to a small aperture, there is a possibility that the exposure will be underexposed. Therefore, in such a case, an underexposure is reduced by emitting a strobe light.
In addition, charging of the strobe is completed before the shooting operation, and when the release SW is pressed, if it is in an uncharged level, it is charged until the shooting permission charging level is reached, and when the shooting permission charging level is reached. The shooting operation is started. Normally, the photographing permission charge level at this time is set lower than the full charge level of the strobe, but this is for shortening the time lag from when the release is pressed until the photographing starts. Therefore, in this case, the charge level at the time of flash emission in close-up photography may be lower than the full charge level. If it becomes smaller, the GNo (guide number) will be lower, and as a result, the distance that the flash will reach will be shortened. Depending on the subject distance, there was a problem of under-photographing.
Therefore, in the negative film, the release permission charge level is determined so that the above-described underexposure falls within a correctable level. However, in the close-up shooting mode, the exposure by the shutter is a small aperture by high-speed control regardless of the subject brightness value, so depending on the subject, it tends to be far under compared to the normal shooting mode. However, if the GNo drops due to the low charging level of the strobe, the under tendency tends to be further spurred and the captured image becomes very dark.
[0003]
[Problems to be solved by the invention]
The present invention has been made to solve the conventional problems as described above, and an object thereof is to provide a camera that can reduce the under tendency in the close-up mode described above.
[0004]
[Means for Solving the Problems]
In order to achieve the above object, according to the first aspect of the present invention, when the EV value calculated based on the measured copy body brightness is equal to or less than a predetermined value, the strobe is caused to emit light and predetermined exposure control is performed. The camera has a normal shooting mode to be performed and a close-up shooting mode in which the strobe is always lit and the aperture is set to the minimum aperture, and the shooting-permitted charging voltage for allowing the shooting of the strobe when the close-up shooting mode is set is set to the normal shooting mode. When the close-up shooting mode is selected when the charging permission voltage of the electronic flash is set higher than the current flash speed, the high-speed second time control is performed such that the aperture is set to the minimum aperture, and the high-speed second time control is repeated a plurality of times .
According to the camera of the first aspect, the shooting permission charging voltage for permitting the shooting of the strobe at the time of the close-up shooting mode is set higher than the shooting permission charging voltage of the strobe at the time of setting the normal shooting mode. The decline can be suppressed and the under tendency can be reduced. Furthermore, when the close-up shooting mode is selected, the high-speed second time control in which the stop is the minimum stop is performed, and the high-speed second time control is repeated a plurality of times, thereby reducing the under tendency by increasing the exposure time.
The invention described in claim 2 is characterized in that the photographing permission charging voltage of the strobe in the close-up mode is a full charging voltage of the strobe charging voltage.
According to the camera of the second aspect, photographing can be performed with the maximum GNo of the strobe used by simple control.
According to a third aspect of the present invention, in a camera that performs a photometric operation in the first release on state and performs a photographing operation in the second release on state, the charging timing is in the first release on state. It is characterized by.
According to the camera of the third aspect, it is possible to perform photographing that can reduce an under tendency by charging before photographing.
According to a fourth aspect of the present invention, in a camera having a remote control function and performing a photometric operation after performing a photometric operation after receiving a remote control signal, the charging timing is after the photometric operation. .
According to the camera of the fourth aspect, it is possible to perform photographing that can reduce the under tendency by charging before photographing even during remote control photographing.
The invention described in claim 5 is characterized in that the photographing permission charging voltage can be changed.
According to the camera of the fifth aspect, adjustment to proper exposure can be performed by making it possible to change the photographing permission charging voltage.
[0005]
The invention according to claim 6 is characterized in that, when the strobe is used in the close-up mode, the flash emission timing is the first high-speed second time control among the plurality of high-speed second time controls.
According to the camera of the sixth aspect , an under tendency can be reduced by using a strobe and emitting light for the first time.
The invention described in claim 7 is characterized in that the number of times of the high-speed second time control can be changed.
According to the camera of the seventh aspect , by adjusting the number of times of high-speed second time control, adjustment to proper exposure can be performed.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the internal control configuration of a camera embodying the present invention.
As shown in FIG. 1, this camera has a CPU 1 as a central processing unit. The CPU 1 includes a photometry IC 3, an AFIC (multi-range IC) 5, a strobe unit 7, an LCD 9, an EEPROM 11, and a lens barrel unit. 13, a feeding unit 15 is connected, and is controlled by the CPU 1 in accordance with instruction signals inputted from a plurality of switches SW1 to SW6 similarly connected to the CPU 1.
The CPU 1 is connected to a power source (battery) 17 and a clock signal generator 19.
Next, the operation of the camera shown in FIG. 1 will be described with reference to the flowcharts of FIGS.
First, FIGS. 2 and 3 are shooting process flowcharts in the normal shooting mode.
First, the CPU 1 performs operation control corresponding to the switches SW1 to SW6 in response to inputs of the switches SW1 to SW6. The switch SW1 is a first release switch. When an instruction signal from the first release switch SW1 is input to the CPU 1, the CPU 1 enters a first release on process as shown in FIG.
As shown in FIG. 2, in the first release-on process, a battery check operation is performed in step 101. Here, when the battery 17 is NG (when the battery 17 is below a predetermined value: NO in step 103) ) Ends the processing here. That is, the release lock is set.
[0007]
Next, if the battery is OK in step 103, the photometry operation is performed by the photometry IC 3 (step 105), and then the multi-range measurement operation is started by the multi-range IC (AFIC) 5 as the AF operation (step 107). In the multi-ranging operation, the 7 zones are measured and the nearest zone is adopted. Next, in steps 109 and 111, AF calculation processing and AE calculation processing are performed from the photometry results and distance measurement results to determine the aperture, shutter speed, shutter opening time, strobe light emission time, and light emission timing.
Next, in step 113, it is determined whether or not the flash unit is in the strobe use mode based on whether or not the EV value calculated based on the measured copy body brightness is equal to or less than a predetermined value. The charging state is confirmed, and if the charging level is low, the charging operation is started up to the photographing permission charging level (steps 115 and 117).
Next, in step 119, focus calculation processing for converting the distance data obtained from the AF calculation processing into the number of feeding steps for the focus operation is performed, and then in step 121, the focus operation is performed. Here, the first release on process is ended, and the second release SW2 is waited or the first release SW1 is turned off.
When the first release SW1 is turned off, the first release off process is executed. In the first release-off process, the display LED is turned off, and the lens (lens barrel) position is returned to the standby position.
[0008]
Next, FIG. 3 shows a flow of the second release on process. When the input of the second release SW2 is detected in the first release on state, the second release on process is started.
In the second release-on process, the release prohibition determination is performed in step 123. If the release is permitted, the shutter operation and strobe use are performed using the shutter opening time calculated from the AE calculation process in step 125. At the time, the strobe light emission control is performed based on the light emission time and the light emission timing time. Thereafter, the lens (lens barrel) is returned to the standby position, and the film feeding operation is performed (steps 127 and 129).
Next, the switch SW3 is a photographing mode switch that allows the photographer to arbitrarily set the mode depending on the photographing scene. Normally, it is a multi-AF low-brightness automatic flash mode (normal mode), but each time the shooting mode switch SW3 is pressed, the single AF mode, the distant view mode, the proximity mode, and the shooting mode are updated. When the switch SW3 is pressed, the mode returns to the multi-AF low brightness automatic light emission mode (normal mode) (see FIG. 4).
That is, as shown in FIG. 4, in the mode selection process, when the shooting mode switch SW3 is pressed, it is determined in step 131 whether or not the previous mode is the normal mode. When the single AF mode is set and the previous normal mode is not set in step 131, it is determined in step 135 whether or not the previous single AF mode is set. If the previous time is the single AF mode in step 135, the distant view mode is set in step 137. If the previous time is not the single AF mode in step 135, it is determined in step 139 whether the previous is the far view mode. .
When the previous mode is the distant view mode in step 139, the proximity mode is set in step 141, and the lens is moved in step 143. If the previous mode is not the distant view mode in step 139, the normal mode is set in step 145, and the lens is returned to the standby position in step 147.
That is, when the proximity mode is set in step 141, the lens position is moved to the close-capturing possible position (equivalent to 35 cm extension) in step 143, and the shooting mode switch SW3 is pressed from the proximity mode to normal. When the mode is updated, the lens position is moved to the standby position in step 147.
8A to 8D are LCD displays in the respective modes. 8A is an LCD display in the normal mode, FIG. 8B is an LCD display in the single AF mode, and FIG. 8C is an LCD display in the distant view mode. FIG. 8D shows the LCD display in the proximity mode. FIG. 8E shows the LCD display in the full display state.
[0009]
Next, the operation in the close-up shooting mode will be described.
5 and 6 are imaging process flows in the proximity imaging mode state.
First, in the first release-on process, a battery check operation is performed in step 201. If the battery 17 is NG (NO in step 203), the process ends here. That is, the release lock is set. Next, when the battery is OK in the above step 203, the photometry operation is performed by the photometry IC 3 (step 205), and then the multi-range operation is started by the multi-range IC 5 as the AF operation (step 207). In this multi-ranging operation, 7 zones are measured and the closest zone is adopted.
Next, in steps 209 and 211, AF calculation processing and AE calculation processing are performed from the photometry results and the distance measurement results, and the shutter opening time, strobe light emission time, and light emission timing are determined. Note that, in the shutter opening time in the AE calculation process of step 211, the high-speed second time data is set so that the aperture is minimized regardless of the photometric value. Also, the strobe light emission timing is set to the timing at which the minimum aperture can be set regardless of the subject distance.
Next, in step 213, it is determined whether or not the distance measuring operation is OK. If the distance measuring operation is OK, the process proceeds to determination of whether or not the proximity mode is selected (step 215). If the distance measuring operation is not OK, step 217 is performed. The AFLED (alarm light) is blinked at 8 Hz. Next, when it is determined in the above-described step 215 that the proximity mode is selected, the process proceeds to step 219, where distance data is calculated from the distance measurement result and determination within the depth of field is performed. In step 219, if the depth of field is within the depth of field, the AFLED is turned on (step 221). If it is outside the depth of field, the AFLED blinks 2 Hz (step 223), and the prohibition information is set in the release prohibition status. RL prohibition information is set (step 225).
If it is not in the proximity mode in step 215, it is determined in step 227 whether or not it is within the shooting range. If it is within the shooting range, the AFLED is turned on (step 229), and if it is out of the shooting range, the AFLED flashes at 2 Hz. The prohibition information is set in the release prohibition status, and the RL prohibition information is set (steps 231 and 233).
[0010]
Next, in step 235, it is determined whether or not the camera is in the proximity mode. If the camera is in the proximity mode, the charge level is calculated in step 237. In this embodiment, the full charge level is set to a value higher than the charge level. Next, in step 239, it is determined whether or not the charge level has reached the close-up mode photographing permission charge level. If not, in step 241, a charging operation is performed, and then focus is performed. Calculation and focus operations are performed (steps 243 and 245).
Next, when it is determined in step 235 that the camera is not in the proximity mode, charging is determined in step 247, but the photographing permission charge level here is lower than the proximity photographing mode photographing permission charging level (full charge level). The charging level is a predetermined level (specifically, it is the same level as the photographing permission charging level in step 115 in FIG. 2). Note that this close-up mode shooting permission charge level may be variable.
If it is determined in step 247 that charging is necessary, a charging operation is performed in step 249.
Next, as shown in FIG. 6, in the second release on process, when the second release switch SW2 is pressed, a release prohibition determination is performed in step 251, and prohibition information is set in the release prohibition status. In the case (prohibited in step 251), the release 2 process (photographing operation) is prohibited, and in the case where prohibition information is not set (permitted in step 251), the shutter operation is performed in step 253. In this case, it is determined whether or not the camera is in the proximity mode (step 255). In the case of the proximity mode, the shutter opening / closing operation is performed in a high-speed second so that the minimum aperture is obtained, and the shutter operation is within 1/30 seconds. The shutter operation is performed a plurality of times (six times) (steps 257, 259, 261, and 263). Also, strobe light is emitted during the first shutter operation. At this time, a sync signal is output at a timing at which the strobe emission timing is also set to the minimum aperture. The number of times of the high-speed second control can be made variable.
[0011]
Next, in step 265, it is determined whether or not the camera is in the proximity mode. Since the lens position is fixed in the proximity mode, the film feeding operation is performed without performing the standby position movement operation of the lens barrel (step 269). . If it is determined in step 265 that the mode is not the proximity mode, in step 267, a standby position moving operation of the lens barrel is performed.
Further, the clock (calendar) display setting of the LCD 9 can be changed by the fourth to sixth SW4 to SW6. The fourth SW 4 is a display mode change, and can be switched from year / month / day / month / day / year / day / month / year / date / time / year / month / day to each input.
That is, as shown in FIG. 7, when the timepiece mode switch SW4 (fourth switch) is turned on, it is determined at step 271 whether or not it is the previous year / month / day mode. In step 273, the year / month / day mode is displayed. If the previous year / month / day mode is not set in step 271, it is determined in step 275 whether or not the mode is the previous month / day / year mode.
If the previous month / day / year mode is selected in step 275, the month / day / year mode is displayed in step 277. If not the previous month / date / year mode in step 275, it is determined in step 279 whether or not the previous date / month / year mode is selected. Is done. If the previous date / month / year mode is selected in step 279, the date / month / year mode is displayed in step 281. If not the previous date / month / year mode in step 279, the date / time mode is displayed in step 283.
The fifth and sixth switches SW5 and SW6 are selected when an item (year or month or date or hour or minute) to be corrected is selected by the correction SW on the clock (calendar) display. The display blinks. The sixth switch SW6 is effective in this blinking state, and the blinking display value is incremented by +1 for each input. The LCD 9 can display a clock, a film counter, a shooting mode mark, a battery mark, and the like (see FIG. 8E).
The EEPROM 11 is a non-volatile storage element that stores adjustment values before camera shipment and the like, as well as charge determination values when the first and second release switches SW1 and SW2 are pressed in the close-up mode, The number of times of control during high-speed seconds is also stored. The lens barrel unit 13 includes a motor for operating the lens barrel (lens), a position detection SW for detecting the current position, a movement detection SW for detecting the movement, and a shutter for operating the shutter. A trigger SW for detecting the trigger of the motor and shutter is incorporated. The feeding unit 15 includes a motor for feeding the film and a detection SW for detecting the moving amount of the film.
In addition, the present invention includes a receiving unit that receives a remote control signal from the outside, a decoding unit that decodes the received remote control signal, and a determination unit that determines whether the decoded result is a correct remote control signal. If the remote control signal is correct, it can also be applied to a camera that performs a photometric operation after performing a photometric operation. In this case, the timing for performing the charging control is after the photometric operation.
[0012]
【The invention's effect】
According to the present invention, when the photographing permission charging voltage for allowing the photographing of the strobe when the close-up mode is set is higher than the photographing permission charging voltage for the strobe when the normal photographing mode is set , The under-trend can be reduced by increasing the exposure time by repeating the high-speed second control a plurality of times and using the high-speed second control with minimum aperture .
[Brief description of the drawings]
FIG. 1 is a block diagram showing an internal control configuration of a camera embodying the present invention.
FIG. 2 is a shooting process flowchart in a normal shooting mode.
FIG. 3 is a shooting process flowchart in a normal shooting mode.
FIG. 4 is a flowchart showing an operation according to the embodiment of the present invention.
FIG. 5 is a flowchart of a photographing process in the proximity photographing mode state.
FIG. 6 is a flowchart of a photographing process in the proximity photographing mode state.
FIG. 7 is a flowchart showing an operation according to the embodiment of the present invention.
FIG. 8 is a diagram showing an LCD display in each mode of the present invention.
[Explanation of symbols]
1 ... CPU, 3 ... photometry IC,
5 ... AFIC (multi-range IC), 7 ... Strobe unit,
9 ... LCD, 11 ... EEPROM,
13 ... barrel unit, 15 ... feeding unit,
17 ... Battery, 19 ... Clock signal generator,
SW1 to SW6 ... first to sixth switches

Claims (7)

When the EV value calculated based on the measured copy body brightness is less than or equal to a predetermined value, the strobe is fired to perform a predetermined exposure control, and a normal shooting mode in which the strobe is always lighted, and the strobe is always lighted and the aperture is set to the minimum aperture. A camera having a close-up mode,
Set the shooting permission charging voltage that allows shooting with the flash when the close-up mode is set to be higher than the charging permission charging voltage of the flash when the normal shooting mode is set .
A camera characterized in that, when the close-up mode is selected, the high-speed second control is performed such that the diaphragm is set to the minimum diaphragm, and the high-speed second control is repeated a plurality of times .   The camera according to claim 1, wherein the charging permission charging voltage of the strobe in the close-up mode is a full charging voltage of the charging voltage of the strobe.   2. The camera according to claim 1, wherein the photometric operation is performed in the first release-on state and the charging is performed in the first release-on state in a camera that performs the photographing operation in the second release-on state. Camera.   2. The camera according to claim 1, wherein the camera has a remote control function and performs a photographing operation after performing a photometric operation after receiving a remote control signal, and charging is performed after the photometric operation.   The camera according to claim 1, wherein the photographing permission charging voltage is changeable. 2. The camera according to claim 1 , wherein when the strobe is used in the close-up mode, the strobe light emission timing is the first high-speed second time control among the plurality of high-speed second time controls. The camera according to claim 1 , wherein the number of times of the high-speed second time control is changeable.

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