JPH06175195A - Signal detector - Google Patents

Abstract

PURPOSE:To provide a signal detector capable of detecting the position of a lens extension mechanism, or a diaphragm at a real time and also simplifying an actuation sequence. CONSTITUTION:A movable member 11 having a slit 11c whose width is successively changed and a shutter blade 14 having a comb-teeth shaped slit 14a are arranged between the light projecting unit 16a and the light receiving unit 16b of an optical sensor unit 16, and the position of the movable member 11 is detected from the absolute value of a detection current outputted from the optical sensor unit 16, and the position of the shutter blade 14 is detected from the variation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for detecting a position by an optical sensor in a camera shutter having a lens feeding mechanism or a diaphragm mechanism.

[0002]

2. Description of the Related Art Conventionally, a lens extension mechanism for integrally providing a lens barrel in a shutter block for automatic focus adjustment, and a diaphragm mechanism for adjusting a position of diaphragm blades to obtain an appropriate exposure value. In the shutters we have, in order to reduce the number of position detection sensors and downsize the device, the shutter blades are configured to interlock at the initial stage of operation of the lens drive ring and aperture ring, and the initial position detection is the shutter blade position. A sensor for detection is used in combination with a sensor for detection. In these types, only the initial position is detected, but not at each set stage (extending amount, aperture value).

Further, a stepping motor, an iris motor, a DC motor or the like is used as a drive source for these mechanisms. When a stepping motor is used as a drive source among these, position setting of each set stage is performed by open loop control. However, when an iris motor or a DC motor is used, open loop control cannot be performed. Therefore, the lens extension or diaphragm operation is intermittently operated by using, for example, a step mechanism to move the position of each set stage. I had to make settings.

[0004]

In the case of the above-mentioned conventional example, in order to detect that the lens and the diaphragm blade are at the initial position,
An operation sequence for position confirmation was required before the shutter operation. That is, all shutter operations had to be performed from the state where the lens and the diaphragm blade were in the initial position. Further, in a shutter using an iris motor or a DC motor as a drive source, a mechanism for intermittently operating the shutter is required, so that there is a problem that the structure of the shutter and the operation sequence become complicated.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to provide a shutter having a lens feeding mechanism or a diaphragm mechanism, in which a movable member of the mechanism is used. An object of the present invention is to provide a signal detection device that can perform position detection in real time and that can configure a shutter with a simple structure and operation sequence even when a motor that cannot perform open loop control is used as a drive source.

[0006]

A signal detecting apparatus according to the present invention is a shutter having a lens moving-out mechanism or an aperture mechanism, and has a first slit having a continuous opening corresponding to the lens moving-out position and a shutter blade position. A second slit having a corresponding intermittent opening, comprising an optical detection means passing between the light emitting element and the light receiving element,
It is characterized in that the delivery position or the diaphragm position is detected by the absolute value of the detection signal level of the detection means, and the position of the shutter blade is detected by the amount of change in the detection signal level of the detection means.

The principle of the present invention will be described with reference to FIG.
In the figure, 1a is a light projecting unit, 1b is a light receiving unit, 2 is a slit in which an opening 2a having a continuously changing width is formed,
Reference numeral 3 is a slit formed in a comb shape. Slit 2
And 3 are movably arranged between the light projecting unit 1a and the light receiving unit 1b. By changing the positions of these slits, the amount of light emitted from the light projecting unit 1a and received by the light receiving unit 1b is changed. It is like this. Further, the light receiving unit 1b photoelectrically outputs a current i having a magnitude corresponding to the amount of received light, and the detected current i is input to a circuit (not shown) that determines the absolute value of the current and a circuit that determines the amount of change in the current. It has become so.

In FIG. 1, from the position where the slit 2 is shown by a solid line in the drawing, that is, the position where the width of the opening 2a is the narrowest for the light emitted from the light projecting unit 1a and passing through the opening 2a,
The time t _{1 is} reached until the position indicated by the dotted line, that is, the position where the position becomes the widest.
2A, the current i output from the light receiving unit 1b changes as shown in FIG. 2A in response to the change in the amount of light received with the movement of the opening 2a. That is, in FIG. 2A, by measuring the absolute value | i | of the current signal from 0 to t ₁ , the position of the opening 2a changed to a light amount corresponding to that value, in other words, For example, the position of the slit 2 can be detected.

Further, in FIG. 1 and FIG. 2A, the light received by the light receiving unit 1b is temporarily blocked at time t ₂ as the slit 3 moves, and then is received again at time t _3. Suppose the amount of light has changed. Then, [d | i |
The change amount of the current i represented by / dt] is as shown in FIG. 2B, and the change amount per unit time from time t _{2 to} t ₃ is a significantly large value. That is, for example, if the reference value b (see the same figure) of the change amount of the current i is set in advance and only the change amount exceeding the reference value b is detected, the position of the slit 3 is changed from the change of the change amount of the light amount. Can be detected.

Therefore, by providing the slit 2 as a means for detecting the lens extension position or the diaphragm position and the slit 3 as a means for detecting the position of the shutter blade, the position of the movable member can be detected in real time. Since the position of the two movable members can be detected by one photo sensor, the shutter can be configured with a simple structure and operation sequence.

[0011]

Embodiments of the present invention will be described with reference to the drawings.
FIG. 3 shows an embodiment of the present invention in a shutter having a diaphragm, in which 11 is an opening 11a, a cam portion 11b for diaphragm blades, and a slit 11c having a continuously changing width.
A diaphragm drive ring 12 formed with a dowel 12a, 1 that can be driven by a drive source (not shown) via a transmission mechanism.
It is a diaphragm blade having 2b. The diaphragm blade 12 is a dowel 1.
It is rotatably supported by another member (not shown) by 2b, and the dowel 12a is attached to the diaphragm drive ring 11 by engaging with the cam member 11b. 13 and 14 are openings 1
1a is a shutter blade for opening and closing, 15 is an opening and closing lever for operating the shutter blades 13 and 14 via a dowel 15a, which is connected to a drive source (not shown) such as a DC motor or a stepping motor, and 16 is a light projecting unit 16a. The light receiving unit 16b is a built-in photo sensor unit.

The diaphragm blade 12 is mounted on the diaphragm drive ring 11 by engaging the dowel 12a with the cam portion 11a, and the diaphragm drive ring 11 rotates counterclockwise in FIG. 3 to move the dowel 12b. Opening 11 as fixed axis
It is designed to narrow down a. The slit 11c also moves as the diaphragm drive ring 11 rotates.
A comb tooth-shaped slit 14a is formed at one end of the shutter blade 14 along the line along which 1c moves. In addition, the light projecting unit 16a and the light receiving unit 16b of the optical sensor unit include the slit 14a and the slit 11a.
The slits 11c and 14a are arranged so as to sandwich the slits on the moving line of c, and the light receiving amount in the light receiving unit 16b is changed by changing the positions of the slits 11c and 14a. The light receiving unit 16b has a size corresponding to the light receiving amount. The current i is photoelectrically converted and output.

FIG. 4 shows a circuit block for receiving the detection current i output from the light receiving unit 16b and detecting and controlling the position of the diaphragm drive ring 11. In the figure, 17 is an absolute value signal level detection circuit for detecting and outputting the magnitude of the absolute value of the detection current i, and 18 is a preset absolute value signal of the target rotation amount of the diaphragm drive ring 11 and the detection circuit 17 An operation control circuit that detects the position of the diaphragm drive ring 11 by comparing the magnitude with a signal and controls the position at the same time, and 19 is a change amount signal level detection that detects the change amount of the detection current i per unit time. Circuit, 20
Is a trigger circuit that detects a state in which the amount of change detected by the detection circuit 19 exceeds a certain amount and uses this as a shutter trigger. Reference numeral 21 is an exposure amount control after the trigger signal from the trigger circuit 19 is input. This is an exposure amount control circuit.

Next, the operation sequence of this embodiment will be described. Before performing the exposure amount control, the aperture blade control is performed.
First, the target rotation amount of the diaphragm drive ring 11 is set in advance in the operation control circuit 18. As the diaphragm drive ring 11 rotates, the diaphragm blade 12 narrows the opening 11a, and at the same time, the slit 11c changes its position, so that the amount of light received by the light receiving unit 16b changes. That is, the diaphragm blade 1
2 is a detection current i having a magnitude corresponding to the amount of narrowing the opening 11a.
Is input to the detection circuit 17. The detection circuit 17 detects the absolute value | i |
Output to 8. The operation control circuit 18 compares the signal from the detection circuit 17 with the absolute value signal of the target rotation amount of the diaphragm drive ring 11, and the magnitude of the signal from the detection circuit 17 determines the magnitude of the absolute value signal of the target rotation amount. The aperture driving ring 11 is rotated until the same as the above, and the position is controlled.

After the position of the diaphragm blade 12 is set, in order to detect the position of the shutter trigger, the sequence moves to a sequence for detecting the amount of change in the detected current i. In this case, the change amount [d | i | / d] of the detection current i per unit time in the detection circuit 19
However, if the shutter blades 3 and 4 are actuated to change their positions and the slit 4a once blocks the light received by the light receiving unit 16b, the amount of change becomes significantly large. The amount of change at this time is detected by the trigger circuit 20, and the control timing signal St is sent to the exposure amount control circuit 21.
Is output. In the exposure amount control circuit 21, the exposure amount control is started by using the input signal from the trigger circuit 20 as a trigger.

Since the present embodiment is configured as described above, the position of the aperture cam ring 11 can always be detected in real time, and the sequence is operated by open loop control regardless of the type of the motor driving the aperture cam ring 11. be able to. Further, since the position of the two movable members can be detected by one photo sensor, the shutter can be configured with a simple structure and operation sequence.

FIG. 5 shows an embodiment in which the present invention is applied to a lens feeding mechanism. In this case, the width of the slit 31a of the lens feeding cam 31 is continuously changed similarly to the slit 11c of the diaphragm drive ring 11 described above, and the slit 14a formed on the shutter blade 14 moves inside the optical sensor unit. By passing, the same action and effect can be obtained in the same operation sequence as that of the above embodiment. In the above-described embodiment, an example in which only the shutter trigger position detection is performed has been shown, but the number of slits may be increased to perform the blade position detection for aperture F value detection during strobe tuning.

[0018]

As described above, according to the present invention, in a shutter having a lens extension mechanism or an aperture blade mechanism, the position of the lens extension position or the aperture position can be detected in real time, and an iris motor or a DC motor is used as a drive source. If so, the sequence can be operated by open loop control. Further, since the position of the two movable members can be detected by one photo sensor, the shutter can be configured with a simple structure and operation sequence.

[Brief description of drawings]

FIG. 1 is a diagram for explaining an operating principle of a signal detection device of the present invention.

FIG. 2 is a diagram showing how a signal obtained from a circuit for determining an absolute value of a current changes by moving a slit 2 shown in FIG.

3 is a diagram showing how a signal obtained from a circuit that determines the amount of change in current by changing the slit 3 in FIG. 1 is changed.

FIG. 4 is an exploded perspective view of a shutter of an embodiment of the signal detection device of the present invention.

FIG. 5 is a diagram showing the shapes of a lens payout cam and a shutter blade of another embodiment of the signal detection device of the present invention.

[Explanation of symbols]

1a, 16a ... Projection unit 1b, 16b ...
Light receiving unit 2, 3 ... Slit 11 ... Aperture driving ring 12 ... Aperture blade 13, 14 ... Shutter blade 15 ... Open / close lever 16 ... Optical sensor unit 31 ... Lens feeding cam

Claims (1)

[Claims] 1. A shutter having a lens extension mechanism or diaphragm mechanism, wherein a first slit having a continuous opening corresponding to a lens extension position and a second slit having an intermittent opening corresponding to a shutter blade position are provided. Equipped with an optical detection means that passes between the light emitting element and the light receiving element,
A signal detecting apparatus characterized in that the feeding position or the diaphragm position is detected by the absolute value of the detection signal level of the detecting means, and the position of the shutter blade is detected by the amount of change in the detection signal level of the detecting means.