KR940007800Y1 - Electromagnetic driving circuit for camera - Google Patents

Abstract

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Description

Electromagnet driving circuit for camera

1 is an electromagnet driving circuit for a camera according to a conventional embodiment.

2 is an electromagnet driving circuit for a camera according to an embodiment of the present invention.

3 is a flowchart of operations performed in a microcontroller.

4 is an application diagram of an electromagnet driving circuit for a camera according to an embodiment of the present invention.

This invention relates to an electromagnet driving circuit for a camera for driving an electromagnet embedded in the camera to automatically adjust the focus of the camera.

Referring to FIG. 1 of the accompanying drawings, a description will be made of an electromagnet driving circuit for a camera which has been conventionally used. The conventional electromagnet driving circuit for a camera detects infrared rays reflected from an unillustrated object by a light receiving element and divides the output terminals into short, medium, or long distances according to the amount of current output in proportion to the incident angle of the reflected infrared rays. A distance measuring device 10 for outputting values to (A, B, C), a contact switch unit 20 for contacting a corresponding output terminal of the distance measuring device 10, and the contact switch unit 20 It consists of an electromagnet portion 40 for driving the electromagnet according to the output value in accordance with the value applied to the output terminal (D) of.

Of the electromagnetic portion 40 configuring the connection switch unit 20, an output terminal (D) of the base terminal is connected and the emitter terminal and the transistor (Q ₁₎ that is grounded and the transistor (Q ₁₎ of the A bias applying resistor R1 connected between the base terminal and the power supply VCC, a coil connected to the power supply VCC and one terminal, and a collector terminal and the other terminal of the transistor Q ₁ connected to the power supply VCC. It consists of (L1).

The operation of the conventional electromagnet driving circuit for the camera made as described above is as follows. It outputs a corresponding amount of current according to the angle of infrared rays reflected from an unillustrated subject, and according to the output value, it is classified into short, medium, or long distances according to the output value. Outputs the low level value to the corresponding output terminal among the output terminals A, B, and C in the distance measuring device 10 using the IC (Integrated Circuit), H2152, which outputs the low level "L" value). .

In the electromagnet unit 40, since the voltage VCC is applied to the base terminal of the transistor Q ₁ through the resistor R1, the transistor Q ₁ is turned on so that a current is applied to the coil L1 to the electromagnet. It is.

Therefore, when the distance measured by the distance measuring device 10 is determined to be a short distance when the contact switch 21 moves downward along the fixed pattern 22 with the operation of the shutter (not shown), the short distance terminal A Low level is applied to the low level through the contact switch 20 by applying the low level value to the low level and the high level value to the remaining terminals and moving to the lower side. The low level is applied to the base terminal of the transistor Q ₁ of 40.

Therefore, since the transistor Q ₁ is turned off and no current is applied to the coil L1, the electromagnet is turned off and the focusing device (not shown) operated by the electromagnet operates at a short distance. Will stop.

Therefore, the camera automatically focuses at that distance.

In the middle distance, a low level value is applied to the middle distance terminal B, and a high level value is applied to the remaining two terminals, so that the high level value is applied to the short distance terminal A when the contact switch 21 moves downward. Since the high level is continuously applied to the base terminal of the transistor Q ₁ of the electromagnet portion 40, the electromagnet remains on and the low level is applied to the terminal B when the contact switch 21 is moved to the intermediate distance terminal B. FIG. Since the low level is applied to the base terminal of the transistor Q ₁ of the electromagnet portion 40, the electromagnet is turned off. Therefore, the electromagnet is turned off at a position corresponding to the intermediate distance so that the above-described focusing device (not shown) is adjusted. Even in the long distance, the distance is controlled by the same operation.

However, in the conventional electromagnet driving circuit for cameras operating as described above, the mechanical tolerances are kept as tight as possible when attaching and wiring necessary elements on a PCB (Printed Circuit Board), but at least when wiring elements to a board. Because there are tolerances to be made, the tolerances that the PCB actually has become larger than they were originally designed. Therefore, the case where the position of the contact switch 21 is not exactly matched with the pattern 22 designed as the copper plate on the PCB, and the inconvenience of having to reassemble the assembled elements occurs. In addition, the tolerance of the pattern originally designed on the PCB may be too large to be out of the connection range to which the contact switch can be connected, so that it may not be used, and other contact patterns may be used to move the contact switch 21 to the corresponding connection pattern. Chattering, which occurs when passing through or when a switch is connected to a corresponding connection pattern, can lead to poor performance due to poor chattering.

Therefore, the object of the present invention is to solve the above-mentioned conventional problems, and eliminates the inconvenience caused by the minimum tolerance problem between the elements when connecting and wiring the switch on the PCB. To solve the ring.

In order to achieve the above object, the constitution of the present invention is a distance measuring device that outputs a value to a corresponding output terminal by dividing it into short distance, medium distance, or long distance according to the amount of current output in proportion to the incident angle of infrared light reflected from an unillustrated object A microcontroller connected to an output terminal of the distance measuring device and executing a program according to a corresponding distance, an electromagnet driving unit outputting an output value to an output terminal according to a value input and connected to an output terminal of the microcontroller; The electromagnet is composed of an electromagnet for operating the electromagnet according to the output value connected to the output terminal of the electromagnet driver.

Hereinafter, an operation according to an embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 2 is an electromagnet driving circuit for a camera according to an embodiment of the present invention, FIG. 3 is a flowchart of a program executed in a microcontroller, and FIG. 4 is an application diagram of an electromagnet driving circuit for a camera according to an embodiment of the present invention.

According to FIG. 2, the present invention distinguishes between short distance, medium distance, and long distance according to the angle of incidence of infrared rays reflected from an unillustrated object, and outputs a value to corresponding terminals A, B, and C. A microcontroller 20 connected to the output terminals A, B and C of the distance measuring device 10 to output one output terminal, and a single output connected to the output terminal of the microcontroller 20. It consists of an electromagnet drive unit 30 for outputting a terminal, and an electromagnet unit 40 connected to the electromagnet drive unit 30.

The configuration of the electromagnet portion 40 includes a transistor Q ₁ having an output terminal E and a base terminal connected to the electromagnet driver 30 and an emitter terminal grounded, and a base of the transistor Q ₁ . A bias application resistor R1 connected between the terminal and the power supply VCC, a coil connected to the power supply VCC and one terminal, and a collector terminal of the transistor Q ₁ and the other terminal connected thereto ( L1).

The distance measuring device 10 uses an IC of H2152 and the electromagnet driver 30 uses an IC of LB1638, but it is not limited to the IC.

The operation of the present invention configured as described above will be described.

The distance measuring device 10 was implemented using an integrated circuit (IC) which is H2152. The IC measures the angle of incidence of infrared light reflected from the subject and calculates the distance based on the magnitude of the measured angle. If the calculated distance falls within one of short, medium, or long ranges, the voltage is output to the output terminals A, B, and C of the corresponding distance.

When the output value is output to the output terminal of the distance measuring device 10, the value is entered into the microcontroller 20. The microcontroller 20 then executes the built-in program. Looking at the operation of the built-in program with reference to the accompanying Figure 3, the micro-controller 20 checks all the output terminals (A, B, C) output from the distance measuring device 10.

Therefore, if the output terminal of the distance measuring device 10 is input to the microcontroller 20 to the terminal A corresponding to a short distance, the program is terminated immediately without executing the program.

And if the input to the medium-distance terminal (B) is applied to the output terminal (D), the high level "H" and after a certain time, the low level "L" is applied to the output terminal (D) again. Therefore, when the distance between the subject and the lens of the camera corresponds to the medium distance, the "H" and "L" signals are output to the output terminal D of the microcontroller. However, when it is input to the long distance terminal C, the program applies the high level "H" signal to the output terminal D. After a delay, the low level "L" signal and a fixed time are applied to the output terminal D again. After the delay, the "H" signal is again applied to the output terminal D, and when a predetermined time passes, the low level "L" signal is applied to the output terminal D again, and the signal output to the output terminal D is "H", "L". "," "H" and "L" signals are output one after another, and the program is terminated.

The value output from the microcontroller 20 is input to the electromagnet driver 30. The electromagnet drive unit 30 is composed of an LB1638 IC. This IC has the characteristic of outputting the same value as the input value to the input terminal. In this design, one of two input terminals and two output terminals is selected and used. Therefore, when the short distance is not output any value from the microcontroller 20, when the medium distance is the value output from the micro-controller 20 "H" and "L" is outputted in sequence so that the output of the electromagnet drive unit 30 In the value output from the terminal E, the signals "H" and "L" are sequentially output. If it belongs to a long distance, the input values are input to the input terminal "H", "L", "H", "L" sequentially, so the output values are sequentially "H", "L", "H" , "L" is output to the output terminal (E).

In the operation of the electromagnet unit 40, when a shutter (not shown) is operated, a high level value is applied to the base terminal of the transistor Q ₁ through the resistor R1 so that the current flows while the capacitor C3 is turned on. do. Therefore, since a current is applied to the coil L1, a magnetic field is generated so that the electromagnet is turned on and is set for use in a short range by a mechanical device (not shown). In this case, the resistor R1 is a bias application resistor.

Therefore, since there is no value output from the electromagnet driver 30 at a short distance, the base terminal of the transistor Q ₁ becomes a high impedance state and does not perform any operation. Keep it. However, when the object is located in the range of long-range high-level and low-level to the base terminal of the transistor (Q ₁₎ in the electromagnetic portion 40 it is therefore caught in sequence beating a single pulse having a period of time as specified by the microcontroller . Therefore, the electromagnet is turned on by the pulse width to match the lens distance as much as the middle distance.

In the long distance, the high level and the low level are sequentially output to the output terminal E twice, and are applied to the base terminal of the transistor Q ₁ in the electromagnet portion 40, so that the pulse having the period specified by the microcontroller is twice. I will run. Therefore, the electromagnet is turned on by the pulse width, such as the middle distance, and the distance of the lens is adjusted as much as the long distance.

Referring to FIG. 4, an example in which this design is applied will be described. An electromagnet lever 4 adsorbed on the adsorption piece of the electromagnet 7 is fixed by a spring 5 and is positioned on the electromagnet 7, and a lock lever which is interlocked by an operation of the electromagnet lever 4. The lever 2 is also fixed to the spring 3 and is caught by the groove between the projections projecting on the AF cam 1 about the AF cam 1. Number 6, not explained, is a spring with tension.

Therefore, when a current is applied to the electromagnet 7 and the electromagnet is turned on, the electromagnet lever 4 is turned on to the electromagnet 7, so that one side of the electromagnet lever 4 moves downward. Therefore, the other side of the electromagnet lever 4, which is fixed between the protrusions of the AF cam 1, moves upwards, and the other side of the electromagnet lever 4 moves upward, so that one side of the lock lever 2 also moves upward. Will move upward together. The other side of the lock lever 2, which is fixed between the other protrusions of the AF cam 1, moves upward due to the operation of the spring 3, so that the AF cam 1 is moved by the tension of the spring 6. ) Rotates clockwise as much as the time the electromagnet is turned on, so it is fixed between the protrusions at the corresponding distances at the middle and long distances to adjust the distance.

The effect of this design, which operates as described above, is to remove the PCB pattern and the contact switch and drive the electromagnet using the microcontroller to solve the problem that occurs in the part that performs the mechanical operation by calculating the autofocus. By doing so, it is possible to eliminate the chattering problem that occurs when using the contact switch and to solve the problem of tolerance that occurs when using the contact switch as a PCB pattern, thereby enabling the electromagnet to perform an accurate operation. And since the contact switch is removed and an easy-to-use IC is used, PCB fabrication can be made very easy.

Claims (1)

A distance measuring device 10 for dividing the short distance or the medium distance or the long distance according to the amount of current output in proportion to the incident angle of the infrared rays reflected from the subject and outputting a value to a corresponding output terminal; A microcontroller 20 connected to an output terminal of the distance measuring device and executing a program according to a corresponding distance; Electromagnet drive unit 30 for outputting an output value to the output terminal in accordance with the input value is connected to the output terminal of the micro-controller, and an electromagnet unit 40 is operated in accordance with the output value connected to the output terminal of the electromagnet drive unit Electromagnet drive circuit for a camera, characterized in that consisting of.