JPH07218959A - Camera provided with shake correcting function - Google Patents

Abstract

PURPOSE:To prevent a picture with blurring from being taken because a shake correcting function is actuated by inhibiting shake correction when a shake correction inhibiting signal is outputted from a shake correction inhibiting signal generating means. CONSTITUTION:This camera is provided with shake correction means 6 9 and 13 for correcting the shake at the time of photographing, the shake correction inhibiting signal generating means 24, and a controller 1 for controlling to inhibit the actuation of the means 6, 9 and 13 in accordance with the shake correction inhibiting signal outputted from the means 24. Since the shake correction is inhibited when the means 24 outputs the shake correction inhibiting signal, the shake correction is inhibited when the shake correcting function is not desired to be actuated. Furthermore, the camera is provided with a photographing preparation starting means outputting an output signal when the photographing preparation of the camera is started, so that the actuation of the correction means 6, 9 and 13 is inhibited in accordance with the output signal from the photographing preparation start means and the shake correction inhibiting signal outputted from the means 211.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera having a shake correction function.

[0002]

2. Description of the Related Art Conventionally, there has been a technique relating to a shake correction control function for correcting camera shake during photographing.

[0003]

However, the prohibition of the shake correction control has not been found in the prior art. Therefore, there are the following problems when the photographer and the subject ride in the same vehicle to take a photograph. If the car shakes vertically during shooting, both the photographer and the subject will shake vertically. In this case, a shake-free photograph is taken unless the shake correction control is performed.

However, the conventional camera with the shake correction control function determines the shake of the vehicle as the shake of the photographer to perform the shake correction control. Therefore, there is a problem that a photograph with a shake is taken. Therefore, an object of the present invention is to provide a camera capable of prohibiting the shake correction function when the photographer does not want to activate the shake correction function.

[0005]

In order to achieve the above object, in the camera of the present invention, the shake correction means 6, 9, 13 for correcting the shake during photographing and the shake correction prohibition signal generating means 24 are provided.
And the control device 1 for controlling the operation of the shake correction means 6, 9 and 13 according to the shake correction prohibition signal output from the shake correction prohibition signal generating means 24.

[0006]

When the shake correction prohibition signal generating means outputs the shake correction prohibition signal, the shake correction is prohibited. Therefore, the shake correction can be prohibited when it is not desired to operate the shake correction function.

[0007]

1 is a circuit diagram of an embodiment of the present invention. The taking lens is composed of four lenses 11, 12, 13, and 14. Among them, the lens 13 is an X for camera shake correction.
This is a camera shake correction lens (hereinafter, referred to as "camera shake correction lens 13") that can be driven in the axis direction (camera longitudinal direction) and the Y axis direction (camera lateral direction).

The CPU 1 is a one-chip microcomputer, which is a control device for controlling the entire sequence of the camera. It is assumed that the CPU 1 has a counter function, a timer function for measuring time, an A / D conversion function, and the like.
The distance measuring circuit 2 is a circuit for measuring the distance to a subject. The photometric circuit 21 is a circuit for photometrically measuring the peripheral portion of the object field.
The shake indicator 22 displays the shake condition. The main switch 18 is a switch for starting the operation of the camera. The main switch 18 is a state switch having an ON position and an OFF position, and once the user sets the ON position to the ON position, the main switch 18 holds the ON position until it is returned to the OFF position again. The half-push switch 19 is a switch for starting preparation for photographing by half-pushing the shutter release button. The release switch 20 is a switch that is turned on by fully pressing the shutter release button. The shake correction control prohibition switch 24 is a switch 24 for prohibiting shake correction control. The shake correction control prohibition switch 24 is a switch that can be operated by the photographer. The nonvolatile memory 23 (hereinafter referred to as E ² PROM 23) is a writable and readable nonvolatile memory.

The angular velocity detection circuit 3 is a camera shake amount Y of the camera.
It is a circuit that detects the angular velocity in the X-axis direction about the axis. The angular velocity detection circuit 4 is a circuit that detects the angular velocity in the Y-axis direction around the X-axis. The motor drive circuit 5 is a circuit that controls the motor 8 that drives the shake correction lens 13 in the X-axis direction. The motor drive circuit 6 includes the shake correction lens 1
3 is a circuit for controlling a motor 9 for driving the motor 3 in the Y-axis direction. The motor drive circuit 7 is a circuit that controls the motor 10 that drives the focusing lens 14.

The lens position detection circuit 15 is a circuit for detecting the position (movement amount) of the shake correction lens 13 in the X-axis direction. The lens position detection circuit 16 is a circuit that detects the position (movement amount) of the shake correction lens 13 in the Y-axis direction. The lens position detection circuit 17 is a circuit that detects the position (movement amount) of the focus lens 14 in the optical axis direction. The angular velocity detection circuit 3 and the angular velocity detection circuit 4 are circuits for detecting camera shake. The output values of the angular velocity detection circuit 3 and the angular velocity detection circuit 4 change according to the angular velocity caused by camera shake. The CPU 1 A / D-converts this output value to detect the angular velocity of camera shake. The angular velocity detection circuit 3 detects the angular velocity in the X-axis direction around the Y-axis. The angular velocity detection circuit 4 detects the angular velocity in the Y-axis direction around the X-axis.

The motor drive circuit 5 duty-drives the motor 8. The motor drive circuit 6 duty-drives the motor 9. The CPU 1 outputs a drive direction signal to the motor drive circuits 5 and 6 to indicate the drive direction of the motors 8 and 9. Also C
PU1 outputs a drive duty signal to the motor drive circuits 5 and 6 to instruct the drive speed of the motors 8 and 9. The motor drive circuits 5 and 6 energize the motors 8 and 9 in a designated direction at an arbitrary duty according to these signals,
The shake correction lens 13 is controlled at an arbitrary speed.

The CPU 1 calculates the distance measurement data obtained by the distance measurement circuit 2. The CPU 1 gives an instruction to the motor drive circuit 7 according to the calculation result. The motor drive circuit 7 is C
By energizing the motor 10 in the direction specified by PU1,
The focus lens 14 is controlled at an arbitrary speed. The rotation of the motor 8 is converted into a linear motion by a correction lens drive mechanical system (not shown), and drives the shake correction lens 13 in the X-axis direction. The rotation of the motor 9 is converted into a linear motion by a correction lens drive mechanical system (not shown), and the shake correction lens 13
Are driven in the Y-axis direction. The rotation of the motor 10 is converted into a linear movement by a focus lens drive mechanical system (not shown), and drives the focus lens 14 in the optical axis direction.

The lens position detection circuit 15 outputs a pulse according to the amount of movement of the shake correction lens 13 in the X-axis direction.
The lens position detection circuit 16 outputs a pulse according to the amount of movement of the shake correction lens 13 in the Y-axis direction. The CPU 1 counts the number of these pulses to determine the X-axis and Y-axis.
Read the axial position and movement amount. Further, the CPU 1 calculates the moving speed in the X-axis and Y-axis directions by detecting the moving amount for a certain period of time. The lens position detection circuit 17 outputs a pulse according to the amount of movement of the focus lens 14 in the optical axis direction. The CPU 1 reads the position and movement amount of the focus lens 14 in the optical axis direction by counting the number of pulses.

The E ² PROM 23 is a non-volatile memory in which predetermined data necessary for photographing processing is written in advance. The CPU 1 reads the predetermined data from the E ² PROM 23 when it is necessary to carry out the predetermined sequence. The operation of the embodiment of the present invention will be described with reference to the flowcharts shown in FIGS. 2, 3, 4, and 5. The control of this flowchart is built in the CPU 1.

In the present embodiment, the distance measuring execution time of the distance measuring circuit 2 is 0 to 300 ms, and the light measuring execution time of the light measuring circuit 21 is 5 ms.
0 ms, drive time of focus lens 14 is 100 m
s, the circuit stabilization time of the angular velocity detection circuits 3 and 4 is 300 m
s, the shock avoidance time at release is 50 ms, the zero angular velocity detection time is 900 ms, and the run-up control time for stabilizing the camera shake correction control is 20 ms.

FIG. 2 is a flow chart showing the main flow of the embodiment of the present invention. It is assumed that the power is already turned on, the main switch 18 is already on, and the process is started from S200. First, C in S201
Initialize the inside of PU1. Next, S202 and S203
And waits until the half-push switch 19 is turned on in S202 or the main switch 18 is turned off in S203. If the main switch 18 is off in S203,
The process proceeds to S205 and ends the process. Then, it waits for the main switch 18 to be turned on again. When the main switch 18 is turned on, the process is restarted from S200. S20
When the halfway press switch 19 is turned on in step 2, the process proceeds to step S204, and the photographing process is called.

FIGS. 3, 4 and 5 are flow charts showing the photographing process of the embodiment of the present invention. When it is confirmed that the half-push switch 19 is turned on, the process starts from S300 in FIG. First, in S301, the angular velocity detection circuit 3 and the angular velocity detection circuit 4 are activated. The angular velocity detection circuit 3 and the angular velocity detection circuit 4 started in S301 continue to operate until stopped in S516.

At the next step S302, a timer A (900 ms in the present embodiment, which is a zero angular velocity detection time) is started.
At 303, the flag A is set to 0. Next, in step S304, photometry processing is executed, and in step S305, distance measurement processing is executed. After that, in S306, the result of the photometric processing executed in S304 is
E calculation is performed, and in S307, FM calculation is performed using the result of the distance measurement processing executed in S305. In the next step S308, the wait time of T1 is waited, and then the process proceeds to step S309. The wait time of T1 is necessary to secure the circuit stabilization time of the angular velocity detection circuit. In the present embodiment, the angular velocity detection circuit stabilization time of 300 ms to the distance measurement time of 0 to 300 ms and the photometry time of 5
Since 0 is subtracted from 0 to 250 ms, 250 ms is set as T1. In S309, the focus lens 14 is driven to a predetermined drive destination according to the distance measurement value set in S305.

At the next step S310, it is confirmed whether the shake correction control prohibiting switch 24 is turned on. If the shake correction control prohibiting switch 24 is turned on, the flow advances to S311 to set the flag B to 1, and then in S312 the display of the shake display 22 is changed to the 8 Hz blinking display, and the flow proceeds to S401 in FIG.
This blinking display of 8 Hz is a display indicating that the shake correction control is not performed.

In step S310, the shake correction control inhibition switch 24
When it is confirmed that is turned off, the flag B is set to 0 in the next S313. Then, in next step S314, it is determined whether or not the output from the angular velocity detection circuits 3 and 4, that is, the shake amount is smaller than a predetermined value C. If it is determined that the shake amount is smaller than the predetermined value C in S314, the display of the shake indicator 22 is turned on in S315, and the process proceeds to S401 in FIG. The lit display of the shake indicator 22 indicates that the detected shake amount is within the correctable range.

If it is determined in S314 that the shake amount is larger than the predetermined value C, the display of the shake indicator 22 is changed to 2 in S316.
The display is changed to Hz blinking and the process proceeds to S401 in FIG. The 2 Hz blinking display of the shake indicator 22 indicates that the detected shake amount is large and it is not known whether shake correction can be performed. Figure 4
In S401, the flag A is confirmed. If the flag A executed in S303 is 0, the process proceeds to S402.

If it is determined that the flag A is set to 1 in S401, the process proceeds to S404. When it is confirmed in S402 that the timer A has timed up (when 900 ms has elapsed in the present embodiment for zero angular velocity detection time), S4 is determined.
After setting the flag A to 1 in 03, the process proceeds to S404.

In S404, it is confirmed that the release switch 20 is turned on, and if it is turned on, the process proceeds to S501 in FIG. S4
If the release switch 20 is off at 04, the next step S405
Confirm that the half-push switch 19 is on with. When it is confirmed that the half-push switch 19 is turned off in S405, the angular velocity detection circuits 3 and 4 are stopped in S406. After that, the flag A is checked in S407. If the flag is 1, the process proceeds to S409. If the flag is 0, the timer A is stopped in S408 and then S4.
I will proceed to 09. In step S409, the display of the shake display is turned off, and then the processing returns from step S410 to the flowchart of FIG. In this case, shooting is not performed.

When it is confirmed at S405 that the half-push switch 19 is turned on, at next S411, the shake correction control inhibition switch 2
Check if 4 is on, and if it is on, S41
The flag B is reset to 1 in 2 and the display of the shake indicator 22 is changed to 8 Hz blinking display in S413, and the process returns to S401. When it is confirmed in S411 whether the shake correction control prohibiting switch 24 is off, the flag B is reset to 0 in S414, and in the next S415, the output from the angular velocity detection circuits 3 and 4, that is, the shake amount is a predetermined value C. Is greater than. If it is determined in S415 that the shake amount is smaller than the predetermined value C, the display of the shake display 22 is turned on in S416, and the process returns to S401.

If it is determined in S415 that the shake amount is larger than the predetermined value C, the display of the shake display 22 is changed to 2 in S417.
The display is changed to Hz blinking and the process returns to S401. In S501 of FIG. 5, it is determined whether the self mode or not, and if YES, S505.
Then, after the self-timer (for example, 10 seconds) has elapsed, the process proceeds to S506. In the case of NO in S501, it is determined in the next S502 whether it is the red-eye mode or not. In the case of NO in S502, the wait time of T2 (the shock avoidance time at the time of release, which is 50 ms in this embodiment) is waited in S504, and then the process proceeds to S506.

In S506, S312, S315, S3
The display of the shake indicator 22 displayed in S16, S413, S416, or S417 is turned off, and the process proceeds to S507. S507
Checks the state of flag A, and if it is 1, S509
Proceed to. If it is 0 in the determination of S507, S is performed in the next S508.
It waits until the timer A started at 302 times up, and after the time has elapsed, the process proceeds to S509.

In step S509, the center of the shake correction lens 13 is moved from the initial reset position to the center position of the optical axis. Flag S in the next S510
Check the status of. When the flag B is 1 in S510, the shake correction control prohibit mode is recognized, and the process proceeds to S513. S
When the flag B is 0 in 510, it is recognized as a mode for performing the shake correction control, and the shake correction process is started in the next S511. After the camera shake correction process is started, the wait time of T3 (the run-up control time for stabilizing the camera shake correction control, which is 20 ms in this embodiment) is waited in S512, and then the process proceeds to S513.

In step S513, the shutter starts to open. The camera shake correction process continues from S511 before the shutter starts to open to S515 immediately after the shutter has completely closed. In step S513, the EV value according to the AE calculation value obtained in step S306 is opened for a predetermined time. After that, S514
In step S515, the shutter closing process is executed, and in step S515, the camera shake correction process is stopped. Next, in S516, the angular velocity detection circuit 3,
Stop 4 Next, in step S517, the shake correction lens 13 is returned to the initial position, and in step S518, the focus lens 14 is driven to a predetermined reset position. Next, in step S519, film winding processing is performed. Then, the process returns from S520 to the flowchart of FIG.

In addition to the half-press switch, the switch for preparing to start photographing is a touch sensor for detecting that a part of the photographer's body touches, or an approach detection for detecting that the photographer is approaching the camera. A sensor or a sensor that detects the line of sight of the photographer may be used. The angular velocity detection circuit 3 and the angular velocity detection circuit 4 started in S301 continue to operate until stopped in S516. That is, the angular velocity detection circuit 3 and the angular velocity detection circuit 4 do not stop even when the shake correction is prohibited.

Therefore, it is not necessary to take the circuit stabilization time of the angular velocity detection circuit 3 and the angular velocity detection circuit 4 one by one. Therefore, even if the shake correction is prohibited once, the shake correction can be performed immediately without waiting for the circuit stabilization time of the angular velocity detection circuit 3 and the angular velocity detection circuit 4.

[0031]

As described above, according to the present invention, the shake correction is prohibited when the shake correction prohibition signal generating means outputs the shake correction prohibition signal. Therefore, by using the technical idea provided by the present invention, it is possible to prevent a photograph with a shake from being produced because the shake correction function is activated.

[Brief description of drawings]

FIG. 1 is a circuit diagram of an embodiment of the present invention.

FIG. 2 is a main flowchart of an embodiment of the present invention.

FIG. 3 is a flowchart showing a photographing process according to an embodiment of the present invention.

FIG. 4 is a flowchart showing a photographing process according to an embodiment of the present invention.

FIG. 5 is a flowchart showing a photographing process according to an embodiment of the present invention.

[Explanation of symbols]

1 CPU 2 Distance measuring circuit 3 Angular velocity detection circuit (X axis direction) 4 Angular velocity detection circuit (Y axis direction) 5 Motor drive circuit (X axis direction) 6 Motor drive circuit (Y axis direction) 7 Motor drive circuit (AF) 8 Motor (X-axis direction) 9 Motor (Y-axis direction) 10 Motor (AF) 11 Photographing lens 12 Photographing lens 13 Shake correction lens 14 Focusing lens 15 Lens position detection circuit (X-axis direction) 16 Lens position detection circuit (Y-axis direction) ) 17 Lens position detection circuit (AF) 18 Main switch 19 Half-press switch 20 Release switch 21 Photometric circuit 22 Shake state indicator 23 Non-volatile memory (E ² PROM)

Claims (17)

[Claims] 1. A shake correction means for correcting shake during photographing, a shake correction prohibition signal generation means, and an operation of the shake correction means in response to a shake correction prohibition signal output from the shake correction prohibition signal generation means. A camera having a shake correction function, the camera having a control device for performing prohibition control. 2. A shooting preparation starting means for outputting an output signal when starting preparation for shooting of a camera, further comprising: an output signal of the shooting preparation starting means and a shake correction prohibiting signal outputted from the shake correction prohibiting signal generating means. The camera having a shake correction function according to claim 1, wherein the control device performs control for prohibiting the operation of the shake correction means in response to the above. 3. A camera having a shake correction function according to claim 1, further comprising shake correction control prohibition display means for displaying information according to the shake correction prohibition signal. 4. A camera having a shake correcting function according to claim 1, further comprising shake-state detecting means and shake-state displaying means for displaying information according to an output signal from the shake-state detecting means. . 5. A shake correction control prohibition display means for displaying information according to the shake correction prohibition signal, a shake state detection means, and a shake state display for displaying information according to an output signal from the shake state detection means. 2. A camera having a shake correction function according to claim 1, further comprising: means for controlling the display so that the display of the shake state display means is prohibited while the shake correction control prohibition display is being displayed. . 6. The camera having a shake correction function according to claim 5, wherein the shake state display means is a display means which is also used as the shake correction control prohibition display means. 7. The camera having a shake correction function according to claim 1, wherein the shake correction prohibition signal generating means is a switch for generating the correction prohibition signal in response to an external operation. 8. A photographing start signal from said photographing start means, comprising: photographing start means and an exposure control device; and said shake correction prohibition signal generating means for generating said correction prohibition signal during an external operation. 2. The camera having a shake correction function according to claim 1, wherein the exposure control device is controlled in a state in which the operation of the shake correction means is prohibited according to the output. 9. According to the output of the shake correction prohibition signal,
2. The camera having a shake correcting function according to claim 1, wherein the control unit controls the shake correcting unit to a predetermined position. 10. A camera having a shake correction function according to claim 2, wherein the photographing preparation starting means is a half-press switch of a shutter release button. 11. A camera having a shake correcting function according to claim 2, wherein the photographing preparation starting means is a touch sensor switch for detecting that a part of a photographer's body is touched. 12. The camera having a shake correction function according to claim 2, wherein the photographing preparation starting means is an approach detection sensor for detecting that a photographer has approached the camera. 13. A camera having a shake correction function according to claim 2, wherein the photographing preparation starting means is a sensor for detecting the line of sight of the photographer. 14. A camera having a shake correcting function according to claim 4, wherein the shake detecting unit operates even when a shake correction prohibiting signal is output from the shake correcting prohibition signal generating unit. 15. The camera having a shake correction function according to claim 8, wherein the photographing start means is a full-press switch of a shutter release button. 16. Even if a shake correction prohibition signal is output from the shake correction prohibition signal generation means after the shooting start signal is output from the shooting start means, the control means prohibits the operation of the shake correction means. 9. A camera having a shake correction function according to claim 8, wherein the camera has no shake. 17. Even if the output of the shake correction prohibition signal from the shake correction prohibition signal generation means is released after the shooting start signal is output from the photographing start means, the control means operates the shake correction means. 9. A camera having a shake correction function according to claim 8, wherein the camera has a shake correction function.