KR101094835B1 - Step Determining Method of Variable Resistance Switch - Google Patents

Abstract

The present invention relates to a step determination method of a variable resistance switch capable of measuring an accurate step in a variable resistance switch having a step (Step). A first step of calculating a step average value averaging the difference between the voltage change value of each step of the variable resistor, the step change value is calculated by using the change amount of the voltage value of the variable resistor for each set sampling time and the total step change value accumulated up to now In a second step of calculating, the quotient and the remainder divided by the step average value are read by reading the current voltage value of the variable resistor on the basis of the voltage value when the variable resistor is the minimum value, and the quotient is the current step value of the variable resistor. A third step of correcting the current step value by setting and comparing the remaining value with a set reference value; And a fourth step of recalculating the current step value by repeating the third step if the difference between the accounting change value and the present step value calculated in the third step is different from each other. Since the product can be used without the need for classification, the vehicle development period can be shortened.

Potentiometer, switch, compensation, step, step, positioning, voltage

Description

Step Determining Method of Variable Resistance Switch

The present invention relates to a step determination method of a variable resistance switch, and more particularly, to a step determination method of a variable resistance switch capable of measuring an accurate step in a variable resistance switch having a step (Step).

Existing automotive products that use dial switches require accurate positioning for display devices. For example, in order to display the set temperature, the volume, the number of blowers, etc., it is required to display the position of the switch, which is the precise number of switches.

When the precise position display of the switch is required as described above, an encoder method is used. However, when a display output is not required, such as a temperature control device such as a manual air conditioner, a variable resistor is mainly used.

In the case of the variable resistor, since the change value of the resistance value is not constant for each step, and the resistance value is different for each product even in the same step, accuracy is a problem for an input device requiring display.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and an object thereof is to provide a step determination method of a variable resistance switch capable of accurate step display or position display using a variable resistor.

The step determination method of the variable resistance switch according to the present invention for solving the above problems is a first step of calculating a step average value averaging the difference in the voltage change value of each step of the variable resistor in step resistance, each set sampling time A second step of calculating a step change value by using a change amount of the voltage value of the variable resistor and calculating a total step change value accumulated up to the present; the current voltage of the variable resistor based on the voltage value when the variable resistor is a minimum value Reading a value and calculating a quotient and a remainder divided by the step average value, setting the quotient to the present step value of the variable resistor and comparing the remaining value with a set reference value to correct the present step value, the second step Comparing the total step change value calculated in step 2 with the current step value calculated in step 3, if it is different, repeats the step 3. To comprise a fourth step of recalculating the value of the current step.

The method may further include storing a voltage value when the variable resistor is the minimum, a voltage value when the maximum value, and the step average value after the first process in a memory.

Here, the second process is a first sub process of measuring the voltage change amount during the sampling time interval from the variable resistor at each set sampling time, and the second sub process of setting the quotient obtained by dividing the voltage change amount by the step average value as the step change value. A third sub process of obtaining a remainder obtained by dividing the voltage change amount by the step average value, a fourth sub process of increasing the step change value by one step when the remaining value is larger by comparing the remaining value with a set reference value; And a fifth subprocess of accumulating and adding a step change value to calculate a total step change value.

The third process may include a first sub-process of measuring a relative voltage value of the variable resistor based on a voltage value when the variable resistor is a minimum value, and quotient of dividing the voltage value by the step average value of the variable resistor. A second subprocess of setting a current step value, a third subprocess of obtaining a remainder obtained by dividing the voltage value by the step average value, and comparing the remaining value with a set reference value to determine the current step value; And a fourth sub process of increasing by one step.

Since the step determination method of the variable resistance switch according to the present invention configured as described above can accurately calculate the step of the variable resistance switch, and can be used in a device that requires accurate step measurement of the switch, the product requires cost reduction and distinction by vehicle type. Since the product can be used without it, the vehicle development period can be shortened.

Hereinafter, with reference to the accompanying drawings will be described specific details and embodiments of the present invention.

1 to 3 are flowcharts showing the sequence of the method of determining the stage of the variable resistance switch according to the present invention.

In particular, FIG. 1 is an overall flowchart, FIG. 2 is a flowchart illustrating a process for correcting the stage of the variable resistor, and FIG. 3 is a flowchart illustrating a method of calculating the stage of the current variable resistor.

Referring to FIG. 1, first, a step determination method of a variable resistance switch according to the present invention calculates a step average value delta_average of a variable resistor (S110). Here, the step average value delta_average refers to the average value of the voltage change amounts between the steps of the variable resistor.

In other words, the voltage change value of each step of the variable resistor is measured, and the average value of the voltage change values is calculated as the step average value (delta_average).

Next, the voltage value MIN when the variable resistor is minimum, the voltage value MAX when the maximum is maximum, and the step average value delta_average are stored in the memory (S120).

Next, the step change value dStep_delta is calculated using the change amount of the voltage value of the variable resistor at each set sampling time, and the total step change value Step_delta accumulated up to the present is calculated (S130).

This process is described in more detail with reference to FIG. 2 as follows.

First, the voltage change amount delta_value is measured at every sampling time (S131). That is, the difference value obtained by subtracting the voltage value measured at the previous sampling time from the voltage value measured at the current sampling time is calculated.

Next, the step change value (dStep_delta) is calculated (S132). Here, the step change value dStep_delta is the quotient of dividing the voltage change amount delta_value by the step average value delta_average.

Next, the remainder obtained by dividing the voltage change amount (delta_value) by the step average value (delta_average) is calculated (S133).

When the remainder is larger, the phase change value dStep_delta is increased by one step by comparing the residual value of the store with a predetermined reference value (S134).

Here, the reference value is a value between 0.5 and 1, more preferably may be set to any value between 0.5 and 0.9.

That is, if the remainder is larger than a certain reference value, it is increased by one step.

Next, the total step change value Step_delta obtained by accumulating the step change value dStep_delta calculated above is obtained (S136).

This process takes place every sampling time.

Next, the current step value STEP of the variable resistor is calculated using the step average value delta_average.

That is, the current voltage value (current_value) of the variable resistor is read based on the voltage value when the variable resistor is the minimum value, the quotient and remainder divided by the step average value (delta_average) are calculated, and the quotient is the current of the variable resistor. By setting the step value STEP and comparing the remaining value with the set reference value, the current step value STEP is corrected (S140).

Referring to this process in more detail with reference to Figure 3 as follows.

First, the current voltage value (current_value) of the variable resistor is measured (S141).

Next, a current step value STEP of the variable resistor is obtained. The current step value STEP is a quotient obtained by dividing the current voltage value current_value by the step average value delta_average (S142).

Next, the remainder obtained by dividing the current voltage value (current_value) by the step average value (delta_average) is calculated (S143).

When the remainder is larger, the current step value STEP is increased by one step (S144).

Here, the reference value is a value between 0.5 and 1, more preferably may be set to any value between 0.5 and 0.9. This is the same value as the reference value when calculating the step change value dStep_delta.

Next, when the calculated total step change value (Step_delta) and the current step value (STEP) are different from each other, the steps S141 to S145 are repeated to calculate the current step value (STEP) again. That is, the process of the above S131 to S146 is a process for increasing the accuracy by checking whether the value obtained in the process S141 to S145 is correct.

As described above, the step determination method of the variable resistance switch according to the present invention has been described with reference to the illustrated drawings. However, the present invention is not limited by the embodiments and the drawings disclosed herein, and the application is within the scope of the technical idea. Can be.

1 is a flow chart showing the sequence of the step determination method of the variable resistance switch according to the present invention;

2 is a flowchart showing a process for correcting the step of the variable resistor;

3 is a flowchart illustrating a method of calculating a current step of a variable resistor.

Claims (5)

A first step of calculating a step average value (delta_average) obtained by averaging the difference between voltage change values of each step of the variable resistor in which the resistance changes in steps; A second step of calculating a step change value (dStep_delta) by using a change amount of the voltage value of the variable resistor at each set sampling time and calculating a total step change value (Step_delta) accumulated up to now; Read the current voltage value of the variable resistor based on the voltage value when the variable resistor is the minimum value, calculate the quotient and remainder divided by the step average value (delta_average), and share the quotient to the current step value (STEP) of the variable resistor. A third step of setting and correcting the current step value by comparing the remaining value with the set reference value; And The total step change value (Step_delta) calculated in the second process and the current step value (STEP) calculated in the third process are compared with each other, and the third step is repeated to obtain the current step value (STEP). And a fourth step of recalculating. The method according to claim 1, And storing the voltage value MIN when the variable resistor is the minimum, the voltage value MAX when the maximum, and the step average value delta_average after the first process in a memory. Step determination method of The method according to claim 1, The second process may include a first sub process of measuring a voltage change amount (delta_value) during a sampling time interval from the variable resistor at each set sampling time; A second sub process of setting a quotient obtained by dividing the voltage change amount (delta_value) by the step average value (delta_average) as a step change value (dStep_delta); A third subprocess of obtaining a residual value obtained by dividing the voltage change amount (delta_value) by the step average value (delta_average); A fourth sub-process of increasing the step change value dStep_delta by one step by comparing the remaining value with a set reference value; And And a fifth sub process of accumulating and adding the step change value dStep_delta to calculate a total step change value Step_delta.  The method of claim 3, The third process may include: a first sub process of measuring a relative voltage value (current_value) of the variable resistor based on a voltage value when the variable resistor is a minimum value; A second sub-process of setting the quotient of dividing the voltage value (current_value) by the step average value (delta_average) to the current step value (STEP) of the variable resistor; A third subprocess of obtaining a residual value obtained by dividing the voltage value (current_value) by the step average value (delta_average); And And a fourth subprocess of increasing the current step value (STEP) by one step when the remaining value is larger than the set reference value. The method according to any one of claims 1 to 4, And said reference value is a value of 0.5 or more and 0.9 or less.

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