JPH0784173A - Lens focusing device - Google Patents

Abstract

PURPOSE:To provide a lens focusing device capable of changing the driving amount of a focusing lens to the input amount of a focusing signal in accordance with a focusing state and easily performing focusing by manual operation by calculating the driving amount of the focusing lens to the focusing signal as the function of a focusing state signal. CONSTITUTION:A focusing state detecting device 13 receives a signal Y0 showing a focusing lens position from a focusing lens controller 11 and outputs a signal (y) showing a difference between a subject distance that focusing is attained at the focusing lens position at that time and an obtained subject distance to the controller 11. Based on a focusing signal (x) from a focusing lens signal input device 12 and the focusing state signal (y) inputted from the detecting device 13, the controller 11 generates a lens driving signal S4 including the lens driving amount, the driving speed and the driving direction of the focusing lens, and outputs the signal S4 to a DC motor driving circuit 14.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens focusing device used for optical equipment such as a video camera and a still camera, and more particularly to a lens focusing device capable of focusing by a manual operation of a photographer. .

[0002]

2. Description of the Related Art Conventionally, in this type of lens focusing device, the movement amount of the focus lens is always set to be constant with respect to the operation amount of the manual operation device. There is also known a device that adjusts the movement amount of the focus lens according to the photographer's preference by changing the movement amount of the focus lens with respect to the operation amount of the manual operation device.

[0003]

However, in the above-mentioned conventional technique, in the former lens focusing device, even when the focus is largely deviated from the in-focus position and rough adjustment is performed, fine adjustment is performed near the in-focus position. In this case, when the manual operation device has a constant operation amount, the focus lens movement amount is also constant. However, there is a problem that the focusing operation is difficult to perform because it has to be fine.

Further, even in the latter device capable of adjusting the movement amount of the focus lens, if fine adjustment is made possible, even if the focus is largely deviated from the in-focus position, the fine adjustment state is set. Therefore, many operations are required until the focus position is approached, and conversely, when coarse adjustment is possible, there is a problem that fine adjustment becomes difficult.

An object of the present invention is to solve the above-mentioned problems and to provide a lens focusing device capable of facilitating manual focusing.

[0006]

The present invention solves the above-mentioned problems by the following means for solving the problems. In addition, in order to facilitate understanding, the description will be given with the reference numerals corresponding to the embodiments, but the present invention is not limited thereto. That is, the first solution means of the lens focusing device according to the present invention is a photographing optical system having a focus lens (2) that can be moved in the optical axis direction to perform a focusing operation, and a focus signal for operating the focus lens. , A focus signal input means (12), a focus state detection means (13) for detecting a focus state of the photographing optical system and outputting a focus state signal, a focus signal from the focus signal input means and the focus. Focus lens control means (11) that generates a control signal including the drive amount, drive speed, and drive direction of the focus lens based on the focus state signal from the state detection means.
And a lens drive unit (14, 3) for driving the focus lens based on a control signal from the focus lens control unit, wherein the focus lens control unit includes the focus state detection unit. The drive amount of the focus lens with respect to the focus signal from the focus signal input means is calculated as a function of the focus state signal from.

According to a second solving means, in the lens focusing device of the first solving means, the focus lens control means is arranged so that the closer the focus state signal from the focus state detecting means is to the focus state, the focus signal The function is set so as to reduce the drive amount of the focus lens with respect to the focus signal from the input means.

According to a third solving means, in the lens focusing device of the first solving means, the focus lens control means is in a range where the focus state signal from the focus state detecting means is judged to be in focus. In this case, the drive of the focus lens is controlled to be stopped regardless of the focus signal of the focus signal input means.

According to a fourth solving means, in the lens focusing device of the first solving means, a coefficient adjusting means for changing the coefficient of a function used for calculating the drive amount of the focus lens with respect to the focus lens control means. (16) is provided.

According to a fifth solving means, in the lens focusing device of the first solving means, a range in which the focus state signal from the focus state detecting means is judged to be in focus by the focus lens control means. It is characterized by comprising a focus determination reference value adjusting means (17) for changing the reference value for determining whether or not

According to a sixth solution means, in the lens focusing device of the first solution means, the relationship between the focus signal from the focus signal input means and the drive amount of the focus lens is calculated with respect to the focus lens control means. A drive mode switching means (15) for switching to a constant value is provided.

In a seventh solving means, in the lens focusing device of the first solving means, when the focus state signal from the focus state detecting means is in a range in which it is determined that the focus state is achieved, the focus state is brought into focus. Focus display means (1
8) is provided.

[0013]

According to the first solution, the focus lens control means calculates the drive amount of the focus lens with respect to the focus signal as a function of the focus state signal. The drive amount can be changed according to the focus state.

According to the second solving means, as the focus state signal is closer to the in-focus state, the function can be set so that the drive amount of the focus lens with respect to the input amount of the focus signal can be set to a smaller value. Up to, the focus lens can be moved at high speed, and fine adjustment can be performed in the vicinity of the in-focus position, enabling highly accurate focusing. Therefore, when focusing is performed manually, high-speed and highly accurate focusing can be performed.

According to the third solving means, when the focus state signal is in the range in which it is determined that the focus state is achieved, the drive of the focus lens can be stopped regardless of the input amount of the focus signal. , The focus will not be shifted again after passing the in-focus state. Therefore, it is possible to shorten the time required to reach the focused state.

According to the fourth solving means, since the coefficient of the function used for calculating the drive amount of the focus lens can be changed, it is possible to secure the operability that suits the photographer's preference.

According to the fifth solving means, it is possible to change the reference value for determining whether or not the focus state signal is within the range in which the focus state signal is determined to be in focus. Can be realized.

According to the sixth solving means, the relationship between the input value of the focus signal and the drive amount of the focus lens can be switched so as to be a constant value. Therefore, it is possible to immediately respond even when the photographer has set an unintended portion as the focus detection range, intentionally wants to shift the focus, or when the function according to the present invention is not required. it can.

According to the seventh means for solving the problems, when the focus state signal is within the range in which it is determined that the focus state is achieved, the focus state can be displayed so that the photographer can focus. It becomes possible to immediately recognize that it is in a state.

[0020]

【Example】

(First Embodiment) A first embodiment will be described in more detail below with reference to the drawings. FIG. 1 is a block diagram conceptually showing a first embodiment of a lens focusing device according to the present invention, and FIG. 2 is a block diagram showing a control system of the lens focusing device according to the first embodiment. In FIG. 1, 1 is a lens barrel, 2 is a focus lens, 3 is a DC motor, 4 is a drive gear for transmitting the power of the DC motor 3 to the focus lens 2, 5 is a potentiometer for detecting the rotation of the focus lens 2, and 6 is The focus signal input ring 7 is an encoder for detecting the rotation of the focus signal input ring 6.

The focus signal input ring 6 is used for the lens barrel 1.
It is attached so that it can rotate around the optical axis,
It is a member for inputting a focus signal for changing the focus state of the focus lens 2 by rotating the focus lens 2 according to the will of the photographer. In this embodiment, the focus signal input ring 6 is rotated in a certain direction to move the focus lens 2 so that the focus is focused on the near distance side, and is rotated in the opposite direction to focus on the far distance side. The focus lens 2 is moved so that

The encoder 7 includes a focus signal input ring 6
Is for detecting the rotation amount of. In FIG. 2, the focus signal input ring 6 and the encoder 7 are collectively referred to as a focus signal input device 12, and the detection signal of the focus signal input device 12, that is, the encoder 7 is connected to the focus lens control device 11. There is.
The focus state detection device 13 is a device for detecting the focus state of the focus lens 2, and is connected to the focus lens control device 11.

FIG. 3 is a diagram showing a focus state detecting device used in the lens focusing device according to the first embodiment. The focus state detection device 13 includes an infrared light emitting diode 21, a projection lens 22, a light receiving lens 23, a position sensor device (hereinafter referred to as PSD) 24, and the like. Infrared light emitted from the infrared light emitting diode 21 is projected onto a subject through the projection lens 22. The reflected infrared light projected on the subject passes through the light receiving lens 23 having an optical axis parallel to the light rays of the infrared light emitting diode 21,
An image is formed on D24, and the distance to the subject can be obtained from the image forming position on PSD24. Here, when the distance between the optical axis of the light receiving lens 23 and the image forming position on the PSD 24 is s, the distance between the optical axes of the projection lens 22 and the light receiving lens 23 is h, and the focal length of the light receiving lens 23 is f, The subject distance L can be calculated by the following equation. [Equation 1] L = h * f / s Since this distance s can be obtained by converting the output signal of the PSD 24, it is possible to calculate the subject distance L by [Equation 1].

On the other hand, as shown in FIG. 2, the focus state detection device 13 receives a signal y ₀ indicating the focus lens position from the focus lens control device 11 and focuses at the position of the focus lens 2 at that time. A difference d between the subject distance L ₀ and the obtained subject distance L is calculated, and a signal y indicating the difference d is output to the focus lens controller 11.

The focus lens control device 11 uses the focus signal x from the focus signal input device 12 and the focus state signal y input from the focus state detection device 13 to drive the lens drive amount z and drive speed of the focus lens 2. , A lens driving signal including the driving direction, and the signal S4 is output to the DC motor driving circuit 6.

The lens drive signal s4 from the focus lens controller 11 is connected to the DC motor drive circuit 14, and the DC motor 3 is controlled by the DC motor drive circuit 14 to rotate. The rotation of the DC motor 3 is driven by the drive gear 4
Is transmitted to the focus lens 2, and the focus lens 2 rotates. The focus lens 2 is provided on the lens barrel 1 so as to be movable in the optical axis direction by rotating around the optical axis. Potentiometer 5
Detects the rotation angle of the focus lens 2 and feeds it back to the DC motor drive circuit 14.

Next, the features of the lens focusing device of this embodiment will be described in more detail. The focus lens control device 11 uses a predetermined function G for generating the lens drive amount z.
Based on the focus signal x input from the focus signal input device 12 and the focus state signal y from the focus state detection device 13 according to the function G.
Is calculated. [Equation 2] z = α * G (x, y) In this embodiment, the function G is set to increase as the amount of shift in the focus state increases. Also,
α is a coefficient described later.

The coefficient adjusting device 16 is a device for changing the coefficient α of the function G used for calculating the drive amount of the focus lens 2 with respect to the focus lens control device 11. As the coefficient adjusting device 16, for example, a variable resistor can be used, and by operating this variable resistor to change the resistance value, the resistance value is converted into a coefficient.

FIG. 4 is a diagram for explaining a coefficient adjusting device used in the lens focusing device according to the first embodiment. In FIG. 4, the horizontal axis indicates the focus state. Focusing on the in-focus state, the focus is on the right side, the focus is on the rear side of the subject (rear focus state), and the left side is on the focus side. This shows that the subject is in focus (front focus state) in front of the subject. On the other hand, the vertical axis represents the ratio of the focus lens drive amount to the input amount of the focus signal (hereinafter referred to as the conversion value). The relationship between the horizontal axis and the vertical axis is the same in FIGS. 5 and 6 described later.

The curve shown in FIG. 4 shows a function G for determining the drive amount of the focus lens 2 with respect to the focus signal from the focus signal input device 12 with respect to the signal from the focus state detection device 13. By changing the coefficient α to be multiplied to the function G set in advance like the curve 4-1-1 shown in FIG. 4, the curve 4-1-2, 4-1 By changing the function like 3, 4-1-4, it is possible to change the rotation amount of the focus signal input ring 7 required to drive the focus lens 2 from the out-of-focus state to the in-focus state. There is. Further, as shown in FIG. 4, when the focus state is within the reference range for determining in-focus, the conversion value is 0 so that the focus lens 2 is not driven regardless of the input amount of the focus signal. .

The focus lens control device 11 is set with a reference value for determining whether or not it is within the range in which the focus state is determined, and compares the reference value with the reference value to determine the focus from the focus state detection device 13. If the focus signal is on the in-focus side,
Regardless of the state of the focus signal from the focus signal input device 12, the drive of the focus lens 2 is controlled to be stopped.

The reference value adjusting device 17 is a device for adjusting the reference value set in the focus lens control device 11 for the focus determination. This reference value adjusting device 17
As, for example, a variable resistor or the like can be used, and by changing the resistance value of this variable resistor,
A reference value corresponding to the resistance value is set in the focus lens control device 11.

The focus display device 18 comprises the focus state detecting means 1
When the focus state signal from 3 becomes the reference value for determining the in-focus state, it is a device for notifying the photographer of the in-focus state, for example, in a viewable place inside the viewfinder. An LED or the like is provided so that the LED is turned on when a focused state is achieved.

The drive mode switching device 15 is 4-2 in FIG.
As described above, a driving method (conventional driving method) in which the relationship between the focus signal from the focus signal input device 12 and the movement amount of the focus lens 2 driven according to the focus signal becomes constant, and the focus signal input Focus lens 2 for the focus signal from device 12
Is a device for switching between the driving method (the driving method of the present invention) for calculating the driving amount of (4) as a function of the focus state signal from the focus state detecting device 13. That is, the drive mode switching device 15 is used in the focus lens control device 1
The focus lens 2 is driven by the present invention when it is on, and when it is off, the signal from the focus signal input device 12 by the focus lens control device 11 and the movement amount of the driven focus lens 2 are connected. The relationship is maintained constant. By operating the drive mode switching device 15, when the photographer intends to focus on a portion other than the portion detected by the focus state detection device 13, the object recognized by the focus state detection device 13 is detected. Focusing is finely adjusted in the vicinity of the distance, and coarsely adjusted in other places, which causes inconvenience for the focus operation to the part where the photographer originally wants to focus. This is effective in the case of performing a focus operation with the same feeling as in the conventional case, or in the case of driving the focus lens 2 which is not intended for focusing.

Since the lens focusing device of this embodiment is configured as described above, the moving amount of the focus lens with respect to the input amount of the focus signal input by the photographer can be changed according to the focus state. Therefore, the focus lens can be moved at high speed up to the vicinity of the in-focus position,
Further, since fine adjustment can be performed in the vicinity of the in-focus position, highly accurate focusing becomes possible. Therefore, when focusing is performed manually, high-speed and highly-accurate focusing is possible.

(Second Embodiment) FIG. 5 is a diagram for explaining the operation of the coefficient adjusting device used in the lens focusing device according to the second embodiment. Since each embodiment described below has the same basic configuration as that of the first embodiment shown in FIGS. 1 to 3, parts having similar functions are designated by the same reference numerals, and Overlapping description will be omitted as appropriate.

The coefficient adjusting device 16 of the second embodiment is a coefficient of a function for determining the movement amount of the focus lens 2 with respect to the signal from the focus signal input device 12 with respect to the signal from the focus state detecting device 13. Is adjusted as follows. In the three states of focus at positions A, B, and C, the photographer changes the conversion value of the driving amount of the focus lens 2 with respect to the signal from the focus signal input device 12 in each of the positions A, B, and C, respectively. It is determined by operating the variable resistor of the coefficient adjusting device 16 provided for each set position. As shown by the curve 5-1-1, the coefficient adjusting device 1
The conversion value corresponding to the resistance value of the variable resistor of 6 is set,
Furthermore, the conversion value in the focus state other than the set positions A, B, and C is obtained by spline interpolation and extension of the data at the three positions A, B, and C. The function value on the front focus side is set so that the function value on the rear focus side is symmetrical with respect to the in-focus state. It should be noted that the position A is the focus state set by the reference value for focus determination.

In the vicinity of the in-focus position, a reference value for determining in-focus is set, and when the focus state is within the reference value, driving of the focus lens 2 is stopped.
For this reason, when the set value of the position A is large, the moving speed of the focus lens 2 immediately before the reference value is high, so that the focus lens 2 is stopped immediately after the focus state falls within the reference value. May be difficult in terms of driving mechanism. Further, if the focus lens 2 cannot be stopped immediately after it is within the reference value, it may be deviated from the reference value again while the focus lens 2 moves until it stops. Therefore, the following conditions are set in the conversion value setting range at the position A. At the position A where the reference value for determining the in-focus is set, the focus lens speed can be stopped immediately, or the focus lens 2 can be stopped within the reference value without being stopped immediately. The upper limit of the conversion value is set so that Further, even if the photographer operates the variable resistor of the coefficient adjusting device 16 that determines the conversion value of the position A and sets it to a value equal to or higher than the upper limit, the conversion value of the position A is set as the upper limit value. . The upper limit of the conversion value is determined by the relationship between the moving speed of the focus lens 2 that can stop within the range of the set focus reference value and the focus signal input to the focus signal input device 12.

When the reference value adjusting device 17 changes the reference value to the in-focus side, the function is changed as shown by the curve 5-1-2. Further, when the control for stopping the driving of the focus lens 2 is not performed when the focus state is within the reference value, the position A is indicated by a curve 5-2.
It is not necessary to place a limit on the conversion value in.

(Third Embodiment) FIG. 6 is a diagram for explaining the operation of the coefficient adjusting device used in the lens focusing device according to the third embodiment. The coefficient adjusting device 16 of the third embodiment increases the conversion value of the drive amount of the focus lens 2 with respect to the signal from the focus signal input device 12 as the focus state is closer to the blur side in order to bring the focus state closer to the in-focus state faster. It was done like this.

In FIG. 6, the conversion value in the state of position D is fixed or set by the photographer using the variable resistor of the coefficient adjusting device 16. At this time, the upper limit is set for the conversion value of D for the same reason as in the second embodiment. The positions E and F are also set by the variable resistor of the coefficient adjusting device 16 similarly to the second embodiment, but the difference from the second embodiment is that the set values of the positions E and F are the positions respectively. In FIG. 6, which is treated as the difference between D and E,
S and T are input values of the photographer at the positions E and F.

(Modification) The present invention is not limited to the above-described embodiments, but various modifications and changes are possible, and these are also included in the present invention. For example, the focus signal input ring 6 is a member rotatable about the optical axis, but the present invention is not limited to this, and the focus signal input ring 6 has a structure in which the photographer can input the direction in which the focus state is changed and the amount of change. I wish I had it. Further, in the present embodiment, the distance to the subject is measured, and by comparing with the state of the focus lens, the description has been given by the method of calculating the shift amount of the focus. However, the focus state detection device adopted in the present invention is The method is not limited to this method, and may be any configuration capable of measuring or calculating the amount of focus shift.

Further, in the present embodiment, the lens for driving the front lens of the lens to focus is described.
This may be a lens that drives the entire lens or a lens that is not the front lens, and even if the lens driving mechanism is different, if the focus lens is driven according to the signal from the focus lens control device 11, The mechanism of this embodiment can be replaced. Furthermore, the focus display device 18 is not limited to the lighting of the LED, and may display a focus state on the finder screen. In addition to the camera, the present invention can be preferably used for optical equipment such as binoculars, telescopes, microscopes, etc. that require focusing.

In the coefficient adjusting device 17 of the first to third embodiments, the function value on the front focus side is set so that the function value on the rear focus side is symmetrical with respect to the in-focus state. The function need not necessarily be symmetrical, and the function may be changed on the front pin side and the rear pin side. In the second and third embodiments, it is possible to arrange the setting variable resistors of the coefficient adjusting device 17 on the front pin side and the rear pin side respectively and set them independently.
In the adjusting devices of the second and third embodiments, the states set by the photographer are the three states of positions A, B, C and positions D, E, F, but if the setting is four states or more, it will depend on the state. It is possible to make fine settings, and it is also possible to form a function by setting two states. Further, the conversion value may be fixed in an arbitrary part of the focus state, and only the inclination of the function may be set by the photographer. Further, in the coefficient adjusting device 17, the means for the photographer to input the set value is the variable resistor, but this is not limited to the variable resistor, and the photographer can input the set value. It only needs to be provided and may be replaced with another input device.

[0045]

As described above, according to the present invention,
There are various effects as follows. According to claim 1, the focus lens control means, as a function of the focus state signal,
Since the drive amount of the focus lens with respect to the focus signal is calculated, there is an effect that the drive amount of the focus lens with respect to the input amount of the focus signal can be changed according to the focus state.

According to the second aspect, it is possible to set the function such that the closer the focus state signal is to the in-focus state, the smaller the drive amount of the focus lens with respect to the input amount of the focus signal, and the focus up to the vicinity of the in-focus position. The lens can be moved at high speed, and fine adjustment can be performed near the in-focus position, enabling highly accurate focusing, so when performing manual focusing, high-speed and highly accurate focusing is possible. The effect is that you can.

According to the third aspect, when the focus state signal is in the range in which it is determined that the focus state is achieved, the drive of the focus lens can be stopped regardless of the input amount of the focus signal. Since the focus does not shift again after passing through the state, there is an effect that the time to reach the focused state can be shortened.

According to the fourth aspect, since the coefficient of the function used for calculating the drive amount of the focus lens can be changed, there is an effect that the operability suitable for the photographer can be secured. .

According to the fifth aspect, the reference value for determining whether or not the focus state signal is within the range for determining the in-focus state can be changed, so that the in-focus accuracy matched to the photographing condition is realized. There is an effect that can be done.

According to the sixth aspect, since the relationship between the input value of the focus signal and the drive amount of the focus lens can be switched so as to be a constant value, a portion not intended by the photographer is set as the focus detection range. In case of accident, when it is desired to intentionally defocus, or when the function according to the present invention is not required, it is possible to immediately respond,
There is an effect.

According to the seventh aspect, when the focus state signal is within the range in which the focus state signal is determined to be the in-focus state, it is possible to display the in-focus state. There is an effect that it is possible to immediately recognize that there is something.

[Brief description of drawings]

FIG. 1 is a configuration diagram conceptually showing a first embodiment of a lens focusing device according to the present invention.

FIG. 2 is a block diagram showing a control system of the lens focusing device according to the first embodiment.

FIG. 3 is a diagram showing a focus state detection device used in the lens focusing device according to the first embodiment.

FIG. 4 is a diagram for explaining a coefficient adjusting device used in the lens focusing device according to the first embodiment.

FIG. 5 is a diagram for explaining a coefficient adjusting device used in the lens focusing device according to the second embodiment.

FIG. 6 is a diagram for explaining a coefficient adjusting device used in a lens focusing device according to a third embodiment.

[Explanation of symbols]

 1 Lens barrel 2 Focus lens 3 DC motor 4 Drive gear 5 Potentiometer 6 Focus signal input ring 7 Encoder 11 Focus lens control device 12 Focus signal input device 13 Focus state detection device 14 DC motor drive circuit 15 Drive mode switching device 16 Coefficient adjustment Device 17 Reference value adjusting device 18 Focusing display device

Claims (7)

[Claims] 1. A photographing optical system having a focus lens that can be moved in the optical axis direction to perform a focusing operation, a focus signal input unit for inputting a focus signal for operating the focus lens, and a focus of the photographing optical system. A focus state detection unit that detects a state and outputs a focus state signal, and a drive amount and drive speed of the focus lens based on the focus signal from the focus signal input unit and the focus state signal from the focus state detection unit. And a lens driving unit that drives the focus lens based on a control signal from the focus lens control unit. The control means is operable as a function of the focus condition signal from the focus condition detecting means. Lens focusing system and calculates a driving amount of the focus lens for focus signal from carcass signal input means. 2. The lens focusing device according to claim 1, wherein the focus lens control unit is configured to focus from the focus signal input unit as a focus state signal from the focus state detection unit is closer to the focus state. A lens focusing device, wherein the function is set to reduce the driving amount of the focus lens with respect to a signal. 3. The lens focusing device according to claim 1, wherein the focus lens control unit is configured to detect the focus state signal from the focus state detection unit in a range in which the focus state signal is determined to be in focus. A lens focusing device, which controls to stop driving of the focus lens regardless of a focus signal from a focus signal input means. 4. The lens focusing device according to claim 1, further comprising a coefficient adjusting unit for changing the coefficient of a function used for calculating the drive amount of the focus lens with respect to the focus lens control unit. Characterizing lens focusing device. 5. The lens focusing device according to claim 1, wherein whether or not the focus state signal from the focus state detecting means to the focus lens control means is in a range in which it is determined that the focus state is in focus or not. A lens focusing device comprising a focusing determination reference value adjusting means for changing a reference value for determining. 6. The lens focusing device according to claim 1, wherein the focus lens control means sets a relationship between a focus signal from the focus signal input means and a drive amount of the focus lens to a constant value. A lens focusing device comprising a drive mode switching means for switching to. 7. The lens focusing device according to claim 1, wherein when the focus state signal from the focus state detecting means is in a range in which the focus state signal is determined to be in focus, it is in focus. A lens focusing device comprising a focusing display means for displaying.