KR101342709B1 - Setting method for setting digital photographing apparatus and digital photographing apparatus set by the same - Google Patents

Abstract

The present invention provides a method for setting a digital photographing apparatus for achieving a uniform aperture speed and stability, and a digital photographing apparatus set accordingly, the method comprising: (a) removing output data from a hall sensor in a state in which the aperture is set to the minimum opening; Confirming with 1 data; (b) increasing the iris control signal strength step by step and checking whether the output data from the hall sensor is different from the first data, and (c) the step; when the output data from the hall sensor differs from the first data in step (b), determining the aperture control signal strength at the immediately preceding stage as the minimum open control signal strength, and (d) the aperture to be at maximum opening. In one state, determining the output data from the Hall sensor as the second data, and (e) decreasing the iris control signal strength step by step. Checking whether the output data is different from the second data by comparing the output data with the second data, and (f) when the output data from the hall sensor differs from the second data in step (e), It provides a digital photographing apparatus setting method and the digital photographing apparatus set according to the above, characterized in that it comprises the step of determining the aperture control signal strength of the maximum open control signal strength.

Description

Setting method for setting digital photographing apparatus and digital photographing apparatus set by the same}

The present invention relates to a digital photographing apparatus setting method and a digital photographing apparatus set accordingly, and more particularly, to a digital photographing apparatus setting method and a digital photographing apparatus set accordingly so that the aperture speed and stability are uniform. .

In general, a digital photographing apparatus includes a lens unit, an imaging device in which light passing through the lens unit is incident, thereby generating data, an aperture for adjusting an amount of light passing through the lens unit, and incident on the imaging device; And a storage medium for storing data from the device. When taking a picture using such a digital photographing apparatus, the aperture is operated in consideration of the amount of light incident on the image pickup device. Accordingly, light passing through the aperture and the lens unit is incident on the image pickup device to generate data in the image pickup device.

In order to operate the aperture, an aperture control unit for controlling the aperture is required, and an actuator for moving the aperture under control of the aperture control unit is required. Typically, the aperture control unit applies a pulse width modulation (PWM) signal to the actuator, and the actuator moves the aperture according to the signal. The actuator has a galvanometer and a hall sensor. The galvanometer moves the aperture according to a signal from the controller to determine the opening degree of the aperture, and the hall sensor measures data according to the degree of movement of the aperture by the galvanometer. Output

Since the galvanometer has an electromagnet, the electromagnets provided in the plurality of galvanometers should ideally have the same properties but are not actually the same. Accordingly, the characteristics of each galvanometer are different, and even if the same control signal is applied to the plurality of galvanometers, there is a problem in that the degree of movement of the diaphragm moves by each galvanometer. This, in turn, causes a problem that the degree of opening of the aperture is different even when the same control signal is applied to the manufactured plurality of digital photographing apparatuses.

SUMMARY OF THE INVENTION The present invention has been made to solve various problems including the above problems, and an object thereof is to provide a digital photographing apparatus setting method and a digital photographing apparatus set accordingly so that the aperture operation speed and stability are uniform.

The present invention includes the steps of (a) determining the output data from the hall sensor as the first data in a state that the aperture is set to the minimum opening, and (b) increasing the aperture control signal strength step by step and outputting the output data from the hall sensor. Comparing the first data with the first data to determine whether the first data differs from the first data, and (c) when the output data from the hall sensor differs from the first data in step (b), Determining the control signal strength as the minimum open control signal strength, (d) determining the output data from the hall sensor as the second data with the aperture at the maximum opening, and (e) the aperture control signal. Comparing the output data from the Hall sensor with the second data to determine whether the second data differs from the second data, and (f) outputting the output from the Hall sensor in step (e). And when the data is different from the second data, determining the iris control signal strength at the immediately preceding step as the maximum open control signal strength.

According to another aspect of the present invention, step (b) is a step of checking whether the output data from the hall sensor is greater than the first data by comparing with the first data, and step (e) is from the hall sensor The output data may be compared with the second data to determine whether the output data is smaller than the second data.

According to another feature of the present invention, step (b) is a step of checking whether the output data from the hall sensor is smaller than the first data by comparing with the first data, and step (e) is performed from the hall sensor. The output data may be compared with the second data to determine whether the output data is larger than the second data.

The present invention also provides a method of controlling the output data from a hall sensor to a first data in a state in which the aperture is minimized, and (b) decreasing the aperture control signal strength step by step. Checking whether the output data is different from the first data by comparing the output data with the first data; and (c) when the output data from the hall sensor differs from the first data in step (b), Confirming the aperture control signal strength at the minimum open control signal strength, (d) determining the output data from the hall sensor as the second data while the aperture is at the maximum opening, and (e) the aperture control Increasing the control signal strength stepwise and comparing the output data from the hall sensor with the second data to determine whether it differs from the second data, and (f) in step (e) Output data is provided when the quality, the digital imaging device setting method for a diaphragm control signal strength at the last stage, characterized in that it comprises a step for deciding a maximum opening control signal strength, unlike the second data.

According to another aspect of the present invention, step (b) is a step of checking whether the output data from the hall sensor is greater than the first data by comparing with the first data, and step (e) is from the hall sensor The output data may be compared with the second data to determine whether the output data is smaller than the second data.

According to another feature of the present invention, step (b) is a step of checking whether the output data from the hall sensor is smaller than the first data by comparing with the first data, and step (e) is performed from the hall sensor. The output data may be compared with the second data to determine whether the output data is larger than the second data.

According to still another aspect of the present invention, (g) further comprising the step of setting the digital photographing apparatus using the smaller one of the minimum open control signal and the maximum open control signal as the minimum control signal and the other as the maximum control signal. can do.

According to another feature of the invention, (g) determining whether the difference between the minimum open control signal and the maximum open control signal is greater than a predetermined value, and (h) the minimum open in the step (g) When it is determined that the difference between the control signal and the maximum open control signal is greater than a predetermined value, the digital photographing apparatus is configured by setting the smaller of the minimum open control signal and the maximum open control signal as the minimum control signal and the other as the maximum control signal. It may further comprise the step of setting.

According to another feature of the invention, (i) in the step (g) further comprises the step of notifying the setter is defective when the difference between the minimum open control signal and the maximum open control signal is less than a predetermined value; It can be done.

The present invention also provides a digital photographing apparatus set according to the above setting method.

According to the digital photographing apparatus setting method and the digital photographing apparatus set according to the present invention made as described above, it is possible to implement the digital photographing apparatus setting method and the digital photographing apparatus set accordingly so that the aperture operation speed and stability are equalized. have.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a graph schematically showing the degree of opening of an aperture according to a voltage applied to a galvanometer. In the left part of FIG. 1, when a voltage is applied to a galvanometer to open an aperture, a first threshold value (OPEN voltage) exists and a voltage smaller than the first threshold value is applied to the galvanometer. This means that the diaphragm is not opened and the diaphragm is opened when a voltage having a magnitude greater than the first threshold is applied to the galvanometer. In the right part of FIG. 1, when a voltage is applied to the galvanometer to close the iris, a second threshold value (CLOSE voltage) is present and a voltage larger than the second threshold value is applied to the galvanometer. This means that the iris does not close and the iris is closed when a voltage having a magnitude smaller than the second threshold is applied to the galvanometer. Since the first threshold value and the second threshold value are different from each other, it is necessary to input the first threshold value and the second threshold value to a memory of the digital photographing apparatus. However, as described above, a problem may occur because the threshold is different depending on the galvanometer.

2 is a flowchart schematically showing a digital photographing apparatus setting method according to an embodiment of the present invention. Referring to FIG. 2, according to the method for setting a digital photographing apparatus according to the present embodiment, first, output data from a hall sensor is determined as first data in a state in which the aperture is minimized to open (S110). Thereafter, the iris control signal strength is increased step by step, and the output data from the hall sensor is compared with the first data to determine whether it is different from the first data. The intensity may refer to the magnitude and / or amount of various electrical signals such as the magnitude of voltage and / or the magnitude of current. To describe this step in detail, the aperture control signal strength is increased by one step (S112), and it is determined whether the output data from the hall sensor is different from the first data (S114). If the output data from the hall sensor is not different from the first data, the iris control signal strength is increased one step again (S112), and it is determined whether the output data from the hall sensor is different from the first data (S114). If the output data from the hall sensor is different from the first data in this process, the aperture control signal strength at the stage immediately before the stage of the aperture control signal strength at the time of the change is determined as the minimum open control signal strength (S116). That is, the minimum open control signal strength, when using the aperture control signal of one level higher than the intensity, the aperture starts to open in a more open state from the minimum open state, the minimum open control signal or less intensity When using the aperture control signal of the aperture is the strength that is no longer open in the minimum open state.

On the other hand, the maximum open control signal strength is also determined in a similar manner. First, in the state in which the aperture is at the maximum opening, the output data from the hall sensor is determined as the second data (S120). Thereafter, the iris control signal strength is decreased step by step and the output data from the hall sensor is compared with the second data to determine whether it is different from the second data. Specifically, the aperture control signal strength is decreased by one step (S122), and it is determined whether the output data from the hall sensor is different from the second data (S124). If the output data from the hall sensor is not different from the second data, the iris control signal strength is decreased by one step again (S122), and it is determined whether the output data from the hall sensor is different from the second data (S124). If the output data from the hall sensor is different from the second data in this process, the aperture control signal strength at the stage immediately before the stage of the aperture control signal strength at the time of the change is determined as the maximum open control signal strength (S126). That is, the maximum open control signal strength starts to become less open in the maximum open state when the aperture control signal having a strength smaller than that is used, and the maximum open control signal or greater intensity When the aperture control signal is used, the aperture is not tightened in the maximum open state.

In FIG. 2, the steps S110 to S126 are performed after the steps S110 to S116 until the minimum open control signal strength is determined, but the steps S120 to S126 until the maximum open control signal strength is determined. Various modifications are possible, such as after going through steps S120 to S126 to confirm S110 and going through steps S110 to S116 until determining the minimum open control signal strength.

When the maximum open control signal strength and the minimum open control signal strength are determined through the above steps, when controlling the digital photographing apparatus, between the maximum open control signal strength and the minimum open control signal strength to control the opening degree of the aperture. By using the aperture control signal having an intensity of, it is possible to stably control the opening degree of the aperture. That is, using an aperture control signal having a greater intensity than the greater of the maximum open control signal strength and the minimum open control signal strength, or an aperture control signal having a smaller intensity than the smaller of the maximum open control signal strength and the minimum open control signal strength. Even if the aperture stops unchanged. Therefore, in controlling the digital photographing apparatus, the aperture control can be stably controlled by using an aperture control signal having an intensity between the maximum open control signal strength and the minimum open control signal strength in order to control the opening degree of the aperture. Furthermore, the aperture speed is also equalized.

Of course, as shown in FIG. 3, which is a flowchart schematically illustrating a method for setting a digital photographing apparatus according to another exemplary embodiment of the present disclosure, the smaller of the minimum open control signal and the maximum open control signal may be the minimum control signal and the other. Of course, the step S132 of setting the digital photographing apparatus as the maximum control signal may be further roughened.

4 is a flowchart schematically showing a digital photographing apparatus setting method according to another embodiment of the present invention. The method of setting the digital photographing apparatus according to the present embodiment is different from the method of setting the digital photographing apparatus described above with reference to FIG. 2, which further passes the step of checking the band of the aperture control signal for controlling the aperture opening degree. That is, after determining whether the difference between the minimum open control signal and the maximum open control signal is greater than the predetermined value (S130), when determining that the difference between the minimum open control signal and the maximum open control signal is greater than the predetermined value. In step S132, the digital imaging apparatus is set by using the smaller of the minimum open control signal and the maximum open control signal as the minimum control signal and the other as the maximum control signal (S132). If the difference between the minimum open control signal and the maximum open control signal is smaller than a predetermined value, the setter is notified of failure (S134).

The aperture has a maximum open state and a minimum open state, and the aperture is divided into a plurality of stages, and if the difference between the minimum open control signal and the maximum open control signal is small, the aperture is opened in a plurality of stages. It is not easy to control the condition. Therefore, after determining whether the difference between the minimum open control signal and the maximum open control signal is greater than the predetermined value (S130), when the difference between the minimum open control signal and the maximum open control signal is smaller than the predetermined value, the setter is informed. By notifying (S134) that it is bad, it is possible to effectively prevent the generation of a digital photographing device that is not easy to adjust the opening state of the aperture.

On the other hand, it is determined whether the output data from the Hall sensor is different from the first data in step S114 and whether the output data from the Hall sensor is different from the second data in step S124, the aperture is at least open. When the size of the output data from the hall sensor increases as the state is opened, the step S114 is a step of checking whether the output data from the hall sensor is larger than the first data by comparing the output data with the first data, and step S124. The step of checking whether the output data from the hall sensor is smaller than the second data is compared with the second data. Of course, when the size of the output data from the hall sensor is smaller as the aperture is opened in the minimum opening, step S114 checks whether the output data from the hall sensor is smaller than the first data by comparing the output data from the hall sensor with the first data. In operation S124, the output data from the hall sensor is compared with the second data to determine whether the second data is larger than the second data.

5 is a flowchart schematically showing a digital photographing apparatus setting method according to another embodiment of the present invention. In the method for setting the digital photographing apparatus according to the present embodiment, the correlation between the increase and decrease of the intensity of the aperture control signal applied to adjust the aperture opening degree and the opening or tightening of the aperture is described with reference to FIG. 2. Is different from the correlation in the digital photographing apparatus setting method. This is explained in detail as follows.

Referring to FIG. 5, according to the method for setting a digital photographing apparatus according to the present embodiment, first, output data from a hall sensor is determined as first data in a state in which the aperture is minimized (S210). Thereafter, the iris control signal strength is decreased step by step, and the output data from the hall sensor is compared with the first data to determine whether it is different from the first data. The intensity may refer to the magnitude and / or amount of various electrical signals such as the magnitude of voltage and / or the magnitude of current. In detail, the iris control signal strength is reduced by one step (S212), and it is determined whether the output data from the hall sensor is different from the first data (S214). If the output data from the hall sensor is not different from the first data, the iris control signal strength is decreased by one step again (S212), and it is determined whether the output data from the hall sensor is different from the first data (S214). If the output data from the hall sensor is different from the first data in this process, the aperture control signal strength at the stage immediately before the stage of the aperture control signal strength when the difference is different is determined as the minimum open control signal strength (S216). . That is, the minimum open control signal strength, when using the aperture control signal of one level smaller than the intensity, begins to open in a more open state when the aperture is in the least open state, the minimum open control signal or greater intensity When using the aperture control signal of the aperture is the strength that is no longer open in the minimum open state.

On the other hand, the maximum open control signal strength is also determined in a similar manner. First, in the state in which the aperture is at the maximum opening, the output data from the hall sensor is determined as the second data (S220). Thereafter, the iris control signal strength is increased step by step, and the output data from the hall sensor is compared with the second data to determine whether it is different from the second data. Specifically, the aperture control signal strength is increased by one step (S222), and it is determined whether the output data from the hall sensor is different from the second data (S224). If the output data from the hall sensor is not different from the second data, the iris control signal strength is increased by one step (S222), and it is determined whether the output data from the hall sensor is different from the second data (S224). If the output data from the hall sensor is different from the second data in this process, the aperture control signal strength at the stage immediately before the stage of the aperture control signal strength at the time of the change is determined as the maximum open control signal strength (S226). That is, the maximum open control signal strength starts to become less open from the maximum open state when the aperture control signal having a strength greater than that is used, and the maximum open control signal or less intensity is used. When the aperture control signal is used, the aperture is not tightened in the maximum open state.

In FIG. 5, the steps S220 to S226 until the maximum open control signal strength is determined after the steps S210 to S216 until the minimum open control signal strength is determined are shown. Various modifications are possible, such as after going through steps S220 to S226 until finalizing, and going through steps S210 to S216 until finalizing the minimum open control signal strength.

When the maximum open control signal strength and the minimum open control signal strength are determined through these steps, when controlling the digital photographing apparatus, the maximum open control signal strength and the minimum open control signal strength are controlled to control the opening degree of the aperture. By using the aperture control signal having an intensity of, it is possible to stably control the opening degree of the aperture. That is, using an aperture control signal having a greater intensity than the greater of the maximum open control signal strength and the minimum open control signal strength, or an aperture control signal having a smaller intensity than the smaller of the maximum open control signal strength and the minimum open control signal strength. Even if the aperture stops unchanged. Therefore, in controlling the digital photographing apparatus, the aperture control can be stably controlled by using an aperture control signal having an intensity between the maximum open control signal strength and the minimum open control signal strength in order to control the opening degree of the aperture. Furthermore, the aperture speed is also equalized.

Of course, the step of setting the digital photographing apparatus by using the smaller one of the minimum open control signal and the maximum open control signal as the minimum control signal and the other as the maximum control signal may be rough.

On the other hand, the inspection step for the band of the aperture control signal for controlling the aperture opening degree may be further subjected to. That is, after determining whether the difference between the minimum open control signal and the maximum open control signal is greater than the predetermined value, when determining that the difference between the minimum open control signal and the maximum open control signal is greater than the predetermined value, the minimum open value The digital photographing apparatus is set using the smaller of the control signal and the maximum open control signal as the minimum control signal and the other as the maximum control signal. If the difference between the minimum open control signal and the maximum open control signal is smaller than a predetermined value, the setter is notified of a failure.

The aperture has a maximum open state and a minimum open state, and the aperture is divided into a plurality of stages, and if the difference between the minimum open control signal and the maximum open control signal is small, the aperture is opened in a plurality of stages. It is not easy to control the condition. Therefore, the step of determining whether the difference between the minimum open control signal and the maximum open control signal is greater than the preset value is notified. If the difference between the minimum open control signal and the maximum open control signal is smaller than the preset value, the settingter is notified. In this way, it is possible to effectively prevent the occurrence of the digital photographing apparatus in which it is not easy to adjust the opening state of the stop.

On the other hand, it is determined whether the output data from the hall sensor is different from the first data in step S214 and whether the output data from the hall sensor is different from the second data in step S224, the aperture is at least open. When the size of the output data from the hall sensor increases as the state is opened, the step S214 is a step of checking whether the output data from the hall sensor is larger than the first data by comparing with the first data, and step S224. The step of checking whether the output data from the hall sensor is smaller than the second data is compared with the second data. Of course, if the size of the output data from the hall sensor is smaller as the aperture is opened in the minimum opening, step S214 determines whether the output data from the hall sensor is smaller than the first data by comparing the output data from the hall sensor with the first data. In operation S224, the output data from the hall sensor is compared with the second data to determine whether the second data is larger than the second data.

6 is a flowchart schematically showing a digital photographing apparatus according to another embodiment of the present invention.

The overall operation of the digital photographing apparatus is governed by the CPU 100. [ The digital photographing apparatus is provided with an operation unit 200 including a key for generating an electrical signal from the user. An electrical signal from the operation unit 200 is transmitted to the CPU 100 so that the CPU 100 can control the digital photographing apparatus in accordance with an electrical signal.

The CPU 100 recognizes the signal and controls the lens driving unit 11, the diaphragm driving unit 21, and the imaging device control unit 31 as an electrical signal from the user is applied to the CPU 100 , Thereby controlling the position of the lens 10, the degree of opening of the diaphragm 20, and the sensitivity of the imaging element 30, respectively. The imaging device 30 generates digital data from the input light, and the analog / digital converter 40 converts analog data output from the imaging device 30 into digital data. Of course, the analog-to-digital conversion section 40 may not be required depending on the characteristics of the imaging element 30. [

The data from the image pickup device 30 may be input to the digital signal processing unit 50 via the memory 60 or may be input to the digital signal processing unit 50 without going through the memory 60, (Not shown). Here, the memory 60 is a concept including ROM, RAM, and the like. The digital signal processing unit 50 can perform digital signal processing such as gamma correction and white balance adjustment as necessary.

The digital data output from the digital signal processor 50 is transmitted to the display controller 81 through the memory 60 or directly. The display control unit 81 controls the display unit 80 to display a digital image on the display unit 80. The digital data output from the digital signal processing unit 50 is input to the storage / reading control unit 71 through the memory 60 or directly. The storage / reading control unit 71 automatically or according to a signal from the user. The digital data is stored in the storage medium 70. Of course, the storage / reading control unit 71 reads data related to the digital data from the digital file stored in the storage medium 70 and inputs the data regarding the digital to the display control unit 81 through the memory 60 or through another path. 80 may be displayed in the digital display. The storage medium 70 may be removable or permanently attached to the digital photographing apparatus.

Such a digital photographing apparatus may be set according to a setting method according to any one of the above-described embodiments or modifications thereof. In such a case, the digital imaging apparatus receives data about a minimum open control signal and a maximum open control signal. That is, in the case of the digital photographing apparatus set according to the setting method according to any one of the above-described embodiments or modifications thereof, the memory 60 has data regarding a minimum open control signal and a maximum open control signal. do. In the case of the digital photographing apparatus, it is possible to effectively uniformize the aperture operation speed and stability in controlling the aperture.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1 is a graph schematically showing the degree of opening of an aperture according to a voltage applied to a galvanometer.

2 is a flowchart schematically showing a digital photographing apparatus setting method according to an embodiment of the present invention.

3 is a flowchart schematically showing a digital photographing apparatus setting method according to another embodiment of the present invention.

4 is a flowchart schematically showing a digital photographing apparatus setting method according to another embodiment of the present invention.

5 is a flowchart schematically showing a digital photographing apparatus setting method according to another embodiment of the present invention.

6 is a flowchart schematically showing a digital photographing apparatus according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: lens 11:

20: Aperture 21: Aperture drive unit

30: Imaging element 31: Imaging element controller

40: A / D converter 50: digital signal processor

60: Memory 71: Storage /

70: Storage medium 81: Display control unit

80: display unit 100: CPU

200:

Claims (10)

(a) determining output data from the hall sensor as first data in a state in which the aperture is minimized; (b) increasing the iris control signal strength step by step and comparing the output data from the hall sensor with the first data to determine whether it is different from the first data; (c) when the output data from the hall sensor differs from the first data in step (b), determining the aperture control signal strength at the immediately preceding step as the minimum open control signal strength; (d) determining output data from the hall sensor as second data in a state in which the iris is opened to the maximum; (e) decreasing the iris control signal strength step by step and comparing the output data from the hall sensor with the second data to determine whether it is different from the second data; And (f) when the output data from the hall sensor differs from the second data in step (e), determining the iris control signal strength at the previous stage as the maximum open control signal strength; (g) determining whether a difference between the minimum open control signal and the maximum open control signal is greater than a predetermined value; And (h) when it is determined in step (g) that the difference between the minimum open control signal and the maximum open control signal is greater than a predetermined value, the smaller of the minimum open control signal and the maximum open control signal is the minimum control signal, Setting a digital photographing apparatus using the other as the maximum control signal; Comprising a digital photographing apparatus setting method. The method of claim 1, Step (b) is a step of checking whether the output data from the hall sensor is greater than the first data by comparing with the first data, The step (e) is a step of checking whether the output data from the hall sensor is smaller than the second data by comparing with the second data. The method of claim 1, Step (b) is a step of checking whether the output data from the hall sensor is smaller than the first data by comparing with the first data, And (e) comparing the output data from the hall sensor with the second data and checking whether the output data is larger than the second data. (a) determining output data from the hall sensor as first data in a state in which the aperture is minimized; (b) decreasing the iris control signal strength step by step and comparing the output data from the hall sensor with the first data to determine whether it is different from the first data; (c) when the output data from the hall sensor differs from the first data in step (b), determining the aperture control signal strength at the immediately preceding step as the minimum open control signal strength; (d) determining output data from the hall sensor as second data in a state in which the iris is opened to the maximum; (e) increasing the aperture control signal strength stepwise and comparing the output data from the hall sensor with the second data to determine whether it is different from the second data; (f) when the output data from the hall sensor differs from the second data in step (e), determining the iris control signal strength at the previous stage as the maximum open control signal strength; (g) determining whether a difference between the minimum open control signal and the maximum open control signal is greater than a predetermined value; And (h) when it is determined in step (g) that the difference between the minimum open control signal and the maximum open control signal is greater than a predetermined value, the smaller of the minimum open control signal and the maximum open control signal is the minimum control signal, Setting a digital photographing apparatus using the other as the maximum control signal; Comprising a digital photographing apparatus setting method. 5. The method of claim 4, Step (b) is a step of checking whether the output data from the hall sensor is greater than the first data by comparing with the first data, The step (e) is a step of checking whether the output data from the hall sensor is smaller than the second data by comparing with the second data. 5. The method of claim 4, Step (b) is a step of checking whether the output data from the hall sensor is smaller than the first data by comparing with the first data, And (e) comparing the output data from the hall sensor with the second data and checking whether the output data is larger than the second data. delete delete Claim 9 has been abandoned due to the setting registration fee. 7. The method according to any one of claims 1 to 6, (i) when the difference between the minimum open control signal and the maximum open control signal in step (g) is smaller than a predetermined value, informing the setter of the failure. . delete

Images