JPH07325246A - Camera focus control method - Google Patents

Abstract

(57) [Summary] [Object] To provide a focus control method capable of bringing a focus position to a focus position accurately and at high speed in a lens interchangeable range finder AF camera. [Constitution] When the interchangeable lens 2 is mounted and the main switch is turned on, lens type information is sent from the lens side circuit 18 to the CPU 12 as a voltage value. Also, a flange back correction signal is sent. When the lens data is read from the non-volatile memory 13 and the AF mode is used, distance measurement information is obtained from the passive distance measuring unit to calculate the number of pulses from the infinite position of the lens to the in-focus position, and the number of adjustment pulses by the flange back correction signal is calculated. to add. The motor drive circuit 14 is controlled to rotate the focus ring 20 of the lens. Encoder 1
The motor drive is stopped when the number of pulses from 5 and the number of added pulses match. This brings the lens to the in-focus position.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention allows interchangeable lenses,
The present invention relates to a focus control method for an AF camera that has a range finder adjusted to a magnification according to the type (angle of view) of an interchangeable lens and performs external distance measurement.

[0002]

2. Description of the Related Art A lens-interchangeable rangefinder AF camera is conceivable in which a taking lens is replaceable, a rangefinder is adjusted to a magnification according to the type of the interchangeable lens, and an AF passive range finding method is adopted. In an ordinary single-lens reflex camera, the light branched from the chief ray that passed through the interchangeable lens is received by the AF sensor, AF information is calculated based on the phase difference, etc., and the interchangeable lens is driven to focus. It is not necessary to obtain lens type information such as the focal length of the lens.

[0003]

However, in the lens interchangeable range finder AF camera described above, the distance measuring method is an external distance measuring method, and the amount of movement of the lens differs with respect to the amount of rotation of the drive motor for each interchangeable lens. Need to get Another problem is how to accurately bring the lens to the in-focus position for actual lens driving. An object of the present invention is to provide a focus control method capable of accurately and rapidly bringing a focus position to a focus position in an interchangeable lens range finder AF camera.

[0004]

In order to achieve the above object, a camera focus control system according to the present invention is a lens type indicating a type of focal length of the interchangeable lens in a interchangeable lens type range finder camera. A lens side circuit that outputs a signal and a signal indicating the lens start position is provided, and an external distance measuring unit that obtains distance information to the subject on the camera side and a focus dial that can arbitrarily set the distance to the subject when the MF mode is selected And calculates the number of pulses from the infinite reference of the lens to the in-focus position by inputting the lens type signal, the lens start position signal, the distance information to the subject or the setting value of the focus dial for calculation. A control circuit for driving the lens and performing focus control according to the pulse number is configured.

According to the present invention, in addition to the above configuration, the lens type signal is indicated by a voltage value from the lens side, and the control circuit is configured to obtain the focal length information of the lens by determining the voltage value. Has been done. Furthermore, in addition to the above configuration, the present invention provides a flange-back adjustment circuit with a volume for outputting a voltage value for flange-back adjustment in the lens, and adjusts the volume to adjust the flange-back correction voltage for each lens individually. By setting a value and reading the correction voltage value when the camera is started, the focus control with the flange back adjusted is performed.

[0006]

With the above arrangement, focus control can be performed at high speed and with high accuracy.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail below with reference to the drawings. FIG. 1 is a perspective view showing the external appearance of a lens interchangeable range finder AF camera adopting a focus control method according to the present invention. A focus dial 4 is arranged at the end of the upper surface of the camera body 1. An AF / MF switching button 4a is provided at the center of the focus dial 4. By pressing the AF / MF switching button 4a, the AF
The mode and the MF mode are switched, and the focus dial 4 is fixed in the AF mode. In the MF mode, the focus dial 4 can be rotated from near to infinity. In addition, a main switch 5 and a release button 6 are arranged on the upper surface of the camera body 1.

A range finder section 3 that is adjusted to a magnification corresponding to the interchangeable lens 2 and a passive distance measuring section 7 are arranged on the upper part of the front surface of the camera. The passive distance measuring unit 7 obtains the light receiving position information of the light from the subject incident from the reference side lens and the reference side lens whose optical axes are distant from the base line, and calculates the distance to the subject. At the bottom of the mount 22 of the camera body 1, the camera side electric contact pin 9
However, the lens drive coupler 8 is arranged on the lower right side. The interchangeable lens 2 is mounted on the mount 22 with the electric contact pad 24 and the coupler 21 (see FIG. 2) facing the camera side electric contact pin 9 and the lens driving coupler 8, and a part of the interchangeable lens 2 is rotated by a certain angle. To fit. It should be noted that the portions not denoted by the reference numerals in FIG.

FIG. 2 is a circuit diagram showing an embodiment of a focus control system circuit according to the present invention. A CPU (control circuit) 12 performs arithmetic processing and the like for focus control and performs other necessary control for the camera. A sliding resistance substrate 11 is fixed to the shaft of the focus dial 4, and a resistance pattern is formed on the upper surface of the sliding resistance substrate 11. A contact piece 23 is installed on the upper surface of the sliding resistance substrate 11, and in the MF mode, the sliding resistance value changes according to the rotation amount of the focus dial 4 (the distance setting to the subject). Further, in the AF mode, a signal indicating AF is output.

FIG. 3 shows the relationship between the AF position of the focus dial and the voltage value output by the resistance value of the sliding resistance substrate 11 with respect to infinity to the closest distance of the MF. A
At the F position, the voltage V _A is output. In the MF, V ∞ is output at an infinite position, and V _M is output at a close range.
Sent to 2. A lens side circuit 18 is provided in the interchangeable lens 2. As shown in FIG. 4, the lens side circuit 18 includes a lens type determination signal output circuit 18a and a flange back correction signal output circuit 18b. The lens type determination signal output circuit 18a outputs a voltage corresponding to the focal length (angle of view) of the interchangeable lens. For example, wide-angle lens,
Standard lens, a telephoto lens and outputs a voltage value of the pre when prepared to have a lens type determination signals of the respective lenses output circuit 18a respectively _{V S, V N, V T} .

Flange back correction signal output circuit 18b
Is composed of a flange-back adjustment circuit IC with a volume and outputs a flange-back correction signal during focus control. The flange back is corrected by rough adjustment and fine adjustment. The rough adjustment is performed by a single lens, and is adjusted by a mechanical method such as sandwiching a washer. The fine adjustment is performed by the flange back correction signal output from the flange back correction signal output circuit 18b, and the flange back correction signal is set by adjusting the volume when the lens is assembled. Even with interchangeable lenses having the same angle of view, this flange back correction is individually adjusted.

The lens type determination signal and the flange back correction signal are sent to the CPU 12 via the lens side electric contact pad 24 and the camera side electric contact pin 9. CPU12
Determines which type of interchangeable lens is attached based on the voltage value of the lens type determination signal, and reads out the lens information corresponding to the interchangeable lens from the nonvolatile memory 13.
The CPU 12 is a motor drive pulse number for bringing the focus ring 20 from the infinite code pattern edge (see FIG. 6) to the in-focus position based on the distance measurement information from the passive distance measuring unit 7 in the AF mode, the lens information and the flange back correction signal. To calculate. In the MF mode, the number of motor drive pulses is similarly calculated based on the distance information set by the focus dial 4 instead of the distance measurement information from the passive distance measuring unit 7.

The CPU 12 controls the motor drive circuit 14 to rotate the motor 16. The rotation of the motor 16 is reduced by the reduction gear group 17, and the focus ring 20 is rotated through the lens driving coupler 8 and the coupler 21 to move the lens back and forth. An encoder 15 is provided in the reduction gear group 17.
Is provided, and the encoder 15 outputs a pulse waveform with a ¼λ phase shift using a two-phase photocoupler. The rotation direction can also be discriminated by the timing difference between these two pulse waveforms. Lens code board 1 for interchangeable lens 2
9 is provided, and the lens brush is configured to come into contact with and slide on the code pattern of the lens code substrate 19 as the focus ring 20 rotates.

FIG. 5 is a schematic front view showing an embodiment of the lens code substrate. The lens code substrate 19 has an annular shape, a ground pattern 28 is formed along the annular portion, and a near-field code pattern 26 and an infinite code pattern 27 are formed in parallel at both ends of the ground pattern. . The lens brush 25 includes two contact pieces 25a and 25a.
b are arranged side by side, and the contact piece 25b is on the ground pattern 28,
The contact piece 25a moves on the pattern so that the contact code pattern 26 and the infinite code pattern 27 come into contact with each other. A flange back correction signal output circuit 18b is provided on the lower right side of the annular portion.
However, the lens side electrical contact pad 24 is installed in the lower part.

FIG. 6 shows a linearly extended pattern. This figure is the case where FIG. 5 is viewed from the rear side, and the near side code pattern and the infinite side code pattern are in opposite positions. This will be described below with reference to FIGS.
Infinite mechanical stop position A and close mechanical stop position G
Is a position where the lens brush 25 is mechanically stopped because it cannot move further outward. The lens initial position B is a position where the lens first waits when performing focus control. The infinite code pattern edge C is the position where the counting of encoder pulses is started. The optical infinite position D is a position where the lens is focused on the infinite position. The closest code pattern edge E indicates a fixed position before reaching the optical closest position F. Optical closest position F
Is the position where the lens is focused to the closest position.

The lens reference position SW is the lens brush 25.
When the contact piece of the lens brush 25 reaches the infinite code pattern 27, the contact piece and the infinite code pattern 27 are electrically connected to each other to be turned on and infinite. The code signal is output. On the other hand, when the lens brush 25 reaches the closest code pattern 26, the closest code pattern is output. At the time of focusing, the lens is brought between the optical infinity position D and the optical closest position F.

7 and 8 are flow charts for explaining the focus control operation of the present invention. First,
When the main switch 5 is turned on, the control circuit part in the camera is activated (S ₁ ). When the main switch 5 is turned on, the CPU 12 starts the control operation. CPU12 lens lock switch (not shown) is turned on or not is determined (S _2). The lens lock switch does not turn on when the interchangeable lens is not attached. When the lens lock switch is determined to be ON state, the lens reference position switch is turned on or not is determined (S _3). When the lens reference position switch is on, it is determined that the lens brush 25 is stopped at the lens initial position B. In this case S
Proceed to ₇ . However, when the lens reference position switch is off, since it is located away from the infinite code pattern 27, the CPU 12 controls the motor drive circuit 14 to drive the motor 16 to rotate in the infinite direction (S ₄ ).

Then, it is determined whether or not the lens reference position switch has been turned on (S ₅ ). When the lens reference position switch is turned on, the lens driving is stopped (S
₆ ). As a result, since the lens brush 25 is brought into the lens initial position B, then the process proceeds to S _7. CPU in S ₇
12 reads the interchangeable lens corresponding voltage value from the lens type determination signal output circuit 18a, to determine which type of the interchangeable lens than the voltage value (S _7). Based on the determination result, and accesses the non-volatile memory 13, it reads the lens corresponding lens information (S _8). Then taking the voltage value of the flange back correction signals from the flange-back correction signal output circuit 18b (S _9).

From the lens information and the voltage value of the flange back correction signal, the CPU 12 calculates the infinite position adjustment amount pulse number for adjusting the infinite position with respect to the optical infinite position D (S ₁₀ ). This adjustment amount range is within the range of the flange back adjustment width 29. Next, it is determined whether or not the release button 6 has been pressed for shooting (S ₁₁ ). Where A
When the AF mode is designated by the F / MF switching button 4a, the distance measuring information is sent from the passive distance measuring unit 7 and the CPU
12 calculates the distance to the subject (S ₁₂ ). And
The number of lens driving pulses to the in-focus position is calculated with reference to the infinite code pattern edge (infinite reference) C (S ₁₃ ), and S ₁₀
In adding the lens drive pulse number calculated in infinite position adjustment amount pulse number and S ₁₃ calculated (S _14). This added pulse number becomes the pulse number up to the in-focus position.

The CPU 12 controls the motor drive circuit 14 to drive the motor in the close-up direction (S ₁₅ ), and detects the position where the lens reference position switch is turned off (S ₁₆ ). That is, the infinite code pattern edge C is detected. When the infinite code pattern edge C is detected, the counting of the number of pulses sent from the encoder 15 is started from that point (S ₁₇ ). While continuing to count the number of pulses, the number of pulses calculated in S ₁₄ is compared with the count value of the number of pulses from the encoder, and it is detected whether the two match (S ₁₈ ). If they match, the drive of the motor 16 is stopped (S ₁₉ ) and the pulse counting is stopped (S ₂₀ ). With the above, the lens is brought to the in-focus position,
After the shutter is controlled, the process returns to S ₁ and the operation is executed again up to S ₁₀ . In S ₁₂ , the distance information from the passive distance measuring unit 7 is received in the AF mode, but the distance information set by the focus dial 4 is obtained in the MF mode.

[0021]

As described above, according to the present invention,
In the lens interchangeable range finder AF camera, there is an effect that it is possible to realize a focus control method that can bring the focus position accurately and at high speed.

[Brief description of drawings]

FIG. 1 is a perspective view showing an appearance of a lens interchangeable range finder AF camera adopting a focus control method according to the present invention.

FIG. 2 is a circuit diagram showing an embodiment of a focus control system circuit according to the present invention.

FIG. 3 is a diagram showing a relationship between a focus position by a focus dial and a voltage.

FIG. 4 is a circuit diagram showing details of a lens side circuit.

FIG. 5 is a schematic front view showing an embodiment of a lens code substrate.

FIG. 6 is a diagram showing a positional relationship when the lens code pattern of FIG. 5 is extended in a linear direction.

FIG. 7 is a flowchart for explaining the operation until the main switch is turned on and the release button is pressed.

FIG. 8 is a flowchart for explaining an operation from when a release button is turned on to when shutter control is performed.

[Explanation of symbols]

 1 ... Camera body 2 ... Interchangeable lens 3 ... Viewfinder section 4 ... Focus dial 5 ... Main switch 6 ... Release button 7 ... Passive distance measuring section 8 ... Lens drive coupler 9 ... Camera side electrical contact pin 10 ... Lens attach / detach button 11 ... Sliding Dynamic resistance board 12 ... CPU (control circuit) 13 ... Non-volatile memory 14 ... Motor drive circuit 15 ... Encoder 16 ... Motor 17 ... Reduction gear group 18 ... Lens side circuit 19 ... Lens code board 20 ... Focus ring 21 ... Coupler 22 ... Mount 24 ... Lens side electric contact pad 25 ... Lens brush 26 ... Close code pattern 27 ... Infinite code pattern 28 ... Ground pattern 29 ... Flange back adjustment width 30 ... Focus range

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Internal reference number FI Technical display location G03B 17/14 (72) Inventor Akira Oda 2-14-9 Tamagawadai, Setagaya-ku, Tokyo Kyocera Tokyo Yoga Co., Ltd. (72) Inventor Keikazu Kobayashi 2-14-9 Tamagawadai, Setagaya-ku, Tokyo Kyocera Corporation Tokyo Yoga Works (72) Inventor Masao Tsujimura 2-chome Tamagawadai, Setagaya-ku, Tokyo No. 9 Inside Kyocera Corporation Tokyo Yoga Works

Claims (3)

[Claims] 1. A lens interchangeable range finder camera, wherein a lens side circuit for outputting a lens type signal indicating a type of a focal length of the lens and a signal indicating a lens start position is provided on the interchangeable lens side, and the camera side includes: An external distance measuring unit that obtains distance information to the subject and a focus dial that can arbitrarily set the distance to the subject when the MF mode is selected, and the lens type signal, the lens start position signal, and the distance information to the subject, or A control circuit for inputting a set value of the focus dial to perform calculation, calculating the number of pulses from the infinite reference of the lens to the in-focus position, and driving the lens according to the calculated number of pulses to perform focus control is characterized. Camera focus control method. 2. The camera according to claim 1, wherein the lens type signal is indicated by a voltage value from the lens side, and the control circuit obtains the focal length information of the lens by determining the voltage value. Focus control method. 3. A flange back adjustment circuit with a volume for outputting a voltage value for flange back adjustment is provided in the lens, and a flange back correction voltage value for each lens is set by adjusting the volume. ,
The focus control system for a camera according to claim 1, wherein the focus control with the flange back adjusted is performed by reading the correction voltage value when the camera is activated.