KR101957696B1 - Method and interface device for processing the weight data of scale - Google Patents

Abstract

The present invention relates to a scale weight data processing method, which can implement functions as an expensive electronic scale while an existing conventional scale is used as it is, and an interface device for processing scale weight data, which can be used simply by being connected to a scale. According to the present invention, the scale weight data processing method relates to a method for processing the weight data detected by a scale, comprising: a first step for setting a target weight; a second step for recognizing an instant weight change (hereinafter, ′instant change′) generated in the scale; a third step for calculating a weight change rate (hereinafter, ′section change rate′) generated for a first time interval after the instant change when the instant change is recognized; a fourth step for processing the instant change as noise if the section change rate is ′0′ as a result of the third step and discriminating the target weight proximity of the current weight measured by the scale if the section change rate is not ′0′; a fifth step for determining a collection frequency per unit time of the weight data detected by the scale on the basis of the proximity; and a sixth step for processing the weight data collected according to the collection frequency so as to transmit the same.

Description

[0001] METHOD AND INTERFACE DEVICE FOR PROCESSING THE WEIGHT DATA OF SCALE [0002]

The present invention relates to a method for processing and processing weight data, and more particularly, to a balance weight data processing method capable of efficiently processing and processing weight data detected by an balance to generate and display optimized weight data, And an interface device for processing the balance weight data.

It is common for a general electronic scale to measure the weight of an object at regular intervals and to drive the weight data generated thereby simply by transmitting it. That is, conventional electronic balances transmit weight data measured in a constant cycle without any consideration according to a related situation at the time of weight measurement, and thus unnecessary data is excessively generated and transmitted during the weight measurement process.

More specifically, when the user wants to measure the target weight of the object (for example, herbal medicine) through the electronic balance, the user lowers the herbal medicine little by little and places it on the electronic scale until the herbal medicine reaches the target weight .

However, even if the weight change of the medicinal herb on the electronic scale increases linearly, the weight data output by the electronic scale does not change linearly but exhibits hysteresis behavior.

5 is a view showing a hysteresis curve. Referring to FIG. 5, when the input value continuously increases even though the input values are the same, the change of the output does not show a linear behavior, but becomes a convex curve upwardly or downwardly, or a more complex curve, which is called a hysteresis curve do.

Such a hysteresis behavior is also applied to the weight measurement by the electronic balance. Therefore, the conventional electronic balance excessively generates unnecessary error data in the process of measuring the target weight of the object, and delivers it as it is.

This hysteresis behavior is one of the causes of the error of the electronic balance. In order to eliminate such an error, it is necessary to perform post-processing to refine the input data or to purchase an expensive electronic balance. There has been a problem that it is greatly increased.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a balance weight data processing method and a balance weight data processing method which can suppress generation of unnecessary data and acquire only necessary data while using an existing general electronic balance as it is, And to provide an interface device for the balance weight data processing.

Yet another object of the present invention is to provide a balance weight data processing method and an interface device for balance weight data processing that can be used simply by connecting them to an existing electronic balance.

According to an aspect of the present invention, there is provided a method of processing weight data detected by an instrument, the method comprising: a first step of setting a target weight; A second step of recognizing an instantaneous weight change (hereinafter referred to as 'instantaneous change') generated in the balance; A third step of calculating a weight change rate (hereinafter referred to as 'section change rate') generated during the first time interval after the instant change, upon recognizing the instant change; As a result of the third step, if the interval change rate is '0', the instantaneous change is treated as noise, and if the interval change rate is not '0', the target weight proximity of the current weight measured by the balance is discriminated A fourth step of: A fifth step of determining a collection frequency of the weight data detected by the balance unit per unit time based on the proximity; A sixth step of processing weight data collected according to the collection frequency; And a seventh step of transmitting the weight data processed by the sixth step.

Preferably, the degree of proximity of the fourth step is divided into N proximity sections consisting of a first proximity section, a second proximity section, ..., and an Nth proximity section with respect to the target weight, The second proximity section, the first proximity section, the proximity section, ..., the second proximity section, and the first proximity section.

In the fifth step, in determining the collection frequency per unit time, the proximity degree is determined as the first collection frequency in the first proximity interval, and the collection frequency in the second proximity interval is larger than the first collection frequency , And may be configured to determine the largest collection frequency in the Nth proximity section, if applicable.

According to the balance weight data processing method and balance weight data processing interface device according to the present invention, it is possible to implement functions such as an expensive electronic balance while using conventional conventional balances as they are.

In addition, simply connecting to an existing balance can be provided in a usable product form, ensuring the versatility and compatibility of the product.

Accordingly, it is possible to improve the balance performance at low cost without replacing the balance currently in use, and it is possible to adopt the present invention easily in all fields using the conventional general balance.

1 is a block diagram showing a configuration of an interface device for processing weight data according to the present invention;
FIG. 2 is a general process flow chart of a method for processing balance weight data according to the present invention; FIG.
3 illustrates a weight signal conversion process of the present invention.
4 illustrates a weight data filtering process of the present invention.
5 is a view showing a hysteresis behavior.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises" or "having" and the like refer to the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Also, in the present specification, the term " above or above " means to be located above or below the object portion, and does not necessarily mean that the object is located on the upper side with respect to the gravitational direction. It will also be understood that when a section of an area, plate, or the like is referred to as being " above or above another section ", this applies not only to the case where the other section is " And the like.

Also, in this specification, when an element is referred to as being " connected " or " connected " with another element, the element may be directly connected or directly connected to the other element, It should be understood that, unless an opposite description is present, it may be connected or connected via another element in the middle.

Also, in this specification, the terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

In the following, preferred embodiments, advantages and features of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing the configuration of an interface device for processing weight data according to the present invention, and FIG. 2 is a general processing flowchart of a method for processing balance data according to the present invention. Referring to FIGS. 1 and 2, a method for processing balance data according to the present invention includes a weight signal conversion step (S10), weight data filtering step (S20), and weight data processing step (S30).

(1) weight signal conversion step (S10)

3 is a flowchart illustrating a weight signal conversion process according to an embodiment of the present invention. Referring to FIG. 3, the weight signal conversion step S10 of the present invention is configured to convert a weight signal detected and transmitted (S1) by the balance 10 into a processable data form.

According to an exemplary embodiment, the weight signal conversion step S10 may be configured to convert the weight signal detected according to the load cell method or the reciprocal method into a form capable of A / D conversion and internal processing and converting the weight signal into a weight value.

In addition, the form that can be converted into the weight value can be a form of converting a weight signal input from the balance 10 into a TTL signal and outputting it, for example, a form of a serial UART TTL output.

(2) Weight data filtering step (S20)

4 is a view illustrating a weight data filtering process of the present invention. Referring to FIG. 4, the weight data filtering step S20 of the present invention recognizes an instantaneous change to be described later on the basis of the weight data converted by the step S10, calculates the rate of change of the input weight, And to determine the proximity of the weight.

The weight data filtering step (S20) is configured to inhibit the generation of unnecessary data and to perform efficient data management by giving weight data generation periods differently according to the determination result of the target weight proximity.

The weight data filtering step S20 includes the steps of recognizing the instantaneous change S21, calculating the interval change rate S22, proximity determination step S23, collecting frequency determination step S24, and transmitting weight data generation step S25, .

The instantaneous change recognition step (S21) of the present invention is a step of recognizing an instantaneous weight change (hereinafter referred to as 'instantaneous change') generated in the scale (10).

In the instantaneous change recognition step S21, 'instantaneous weight change generated in the scale 10' means a change in weight that occurs when the user places the object on the scale 10 to measure the target weight.

For example, assume that the user holds the herbal medicines contained in the herbal medicine dispenser and places them on the scale 10 in a state where no object is placed on the scale 10 at all. In this case, a weight value exceeding 0 g is instantaneously detected on the scale 10 as soon as the herbal medicine is loaded on the scale 10, and the instantaneous change described above occurs.

The weight data corresponding to the instantaneous change generated in the scale 10 is converted into data that can be processed and processed according to the above-described weight signal conversion step (S10), and then transmitted to the interface device 20 of the present invention.

The interval change rate calculation step S22 of the present invention is a step for adjusting the data generation interval according to the data change rate, and is configured to calculate the following change rate of the input weight when an instantaneous change occurs in step S21.

Specifically, the section change rate calculation step S22 is configured to calculate a weight change rate (hereinafter referred to as 'section change rate') generated during the first time interval after the instant change when recognizing the instant change according to step S21.

The 'first time interval' in the section change rate calculation step S22 need not be a specific range value and can be set to an arbitrary size. For example, the first time interval may be in units of seconds or minutes.

The proximity determination step S23 of the present invention determines whether or not the weight data input from the scale 10 is noise, and when the noise is not noise, it determines the target weight proximity of the input weight. The determination process of step S23 is performed using the interval change rate calculated through step S22.

For reference, the 'target weight' in the proximity determination step S23 means a target weight of a user. For example, suppose that 20 grams of A drug is specified in the preparation instructions. In this case, the dispenser takes the A medicament off the medicinal herb and places it on the scale 10, the process proceeding until the weight measured by the scale 10 indicates 20 g, where " A medicament 20 g " It corresponds to the target weight.

The target weight value may be set and changed by the user. In this case, the target weight setting is preferably performed in the weight signal conversion step (S10). For example, before the target weight measurement (i.e., (Before placing the object).

Specifically, the proximity determination step S23 is configured to process the input weight data or the instantaneous change of the step S21 as noise when the section change rate calculated through the step S22 is '0'. In other words, in the absence of the interval conversion ratio, the weight data input from the balance 10 or the momentary change data of the step S21 recognized by the input weight data is regarded as noise and filtered (i.e., weight data ratio is generated).

The degree of proximity of the current weight measured by the balance 10 to the target set weight (hereinafter, referred to as " proximity degree ") is set to zero Quot;).

The proximity of the present invention means that the higher the value, the closer the current weight measured by the balance 10 to the target weight. The current weight for determining the proximity is selected by selecting any one of the weight data transmitted from the balance 10 at the time of determining proximity or calculating the interval change rate, Can be configured to discriminate the degree of the obstacle.

According to one embodiment, the proximity may be configured to be stepwise separated into a plurality of proximity sections. For example, the proximity may be divided into N proximity sections including a first proximity section, a second proximity section, ..., and an Nth proximity section with respect to the target weight. In this case, the N proximity sections are configured to be closer to the target weight in the Nth proximity section, ..., the second proximity section, and the first proximity section.

According to another embodiment, the proximity may be configured such that the proximity also increases linearly in proportion to the current weight measured by the balance 10 approaching the target weight.

The collection frequency determination step (S24) of the present invention is a step of determining the collection frequency per unit time of the weight data detected by the balance (10) based on the proximity obtained in step S23.

The collection frequency per unit time in step S24 means the number of cycles or the number of times of collecting the weight data detected by the balance 10. In other words, it may mean the number of cycles or the number of times that weight data to be transmitted to the electric / electronic device 30 is generated. Therefore, as the collection frequency per unit time increases, the number of times of collecting and generating transmission weight data per unit time increases.

Specifically, when the proximity is configured to be stepwise divided into a plurality of proximity sections, in step S24, in determining the collection frequency per unit time, the degree of proximity is determined as the first collection frequency in the first proximity section, The first collection frequency is determined to be larger than the first collection frequency in the second proximity interval, and the largest collection frequency is determined in the Nth proximity interval.

If the proximity is configured to increase linearly, the collection frequency determined in step S24 may be configured to increase linearly in proportion to the proximity increase in step S23.

The transmission weight data generation step (S25) of the present invention is a step of generating weight data (hereinafter, transmission weight data) to be transmitted to the electric / electronic device (30).

Specifically, the transmission weight data generation step S25 is configured to collect and generate weight data according to the collection frequency per unit time determined by step S24.

The weight data processing method of the present invention is characterized in that when the target weight proximity determined in step S23 corresponds to any of the N proximate intervals, the weight change data detected by the balance 10 after the collection frequency determination step (S24) Can be configured to continue collecting weight data at a second collection frequency even if there is no. Here, the second collection frequency is a value smaller than the first collection frequency described above.

The weight data processing method of the present invention may further include a step of determining an interval change rate.

If the target weight proximity determined in step S23 is less than the first proximity interval, the step of determining the interval re-change rate may be performed based on the weight change rate (hereinafter referred to as' Quot; change rate ").

The interval recalculation rate determination step is configured to process the weight data input from the balance 10 or the interval change rate data of step S22 as noise when the calculated interval recurrence rate is '0'.

If the interval change rate is not '0', the above-described collection frequency determination step S24 is performed. At this time, the collection frequency determination step S24 is configured to determine a collection frequency smaller than the first collection frequency in determining the collection frequency per unit time of the weight data.

Hereinafter, the processing method of the proximity determination step (S23) and the collection frequency determination step (S24) of the present invention will be described in more detail.

For example, if you want to measure herbal medicine B to 100g, the target weight is 100g. Assuming that the proximity section is divided into two sections and the range of 20% of the target weight is set, the proximity section is 80 to 100 g, and the first proximity section is 80 to 90 g in detail. 90 to 100 g.

In this case, when the prescriber first places 82g of the herbal medicine material B on the scale 10, the instantaneous change of the step S21 is recognized. After that, immediately after the herbal medicine material B 5g is further placed, the interval change rate of the step S22 is calculated. At this time, since the interval change rate is a value other than '0', the target weight proximity measured by the balance 10 is determined.

In this case, the current weight is measured as 87 g, the target weight proximity corresponds to the first proximity interval, and thus the weight data is collected and generated at the first collection frequency.

In this case, since the current weight is in the state of being in the proximity section, weight data is collected even if there is no change in weight after the current weight is 87 g. However, in this case, the data collection frequency may be less than the first collection frequency.

Then, when 5 g of the medicinal herb B is further placed on the preparer, the current weight is measured to be 92 g, the target weight proximity corresponds to the second proximity interval, and thus the second collection frequency, which is the number of times higher than the first collection frequency The weight data is collected and generated.

In the meantime, since the weight does not correspond to 20% of the target weight, that is, until the weight reaches 80 g, it is not processed in the proximity interval. Therefore, the weighted data is processed as a noise signal when there is no change in weight data. So that unnecessary data collection is suppressed.

(3) Weight data processing step (S30)

The weight data processing step S30 of the present invention is configured to convert the transfer weight data collected and generated according to the collection frequency determined in step S24, and then to transfer it to the object. Here, the object receiving the processed weight data may be an electric electronic device 30 having an output unit for displaying the weight.

Specifically, the weight data processing in step S30 is configured to change the weight data selected through the weight data filtering step S20 to a keyboard signal and deliver it.

According to a preferred embodiment, the step S30 is configured to convert the transfer weight data collected in the step S25 into character string data, and the character string may be an ASCII code.

According to step S30, the filtered weight data signal can be converted into a USB signal, so that the versatility and compatibility of the device can be realized.

The processed weight data converted into the keyboard signal by the step S30 is input to the electric / electronic device 30 (S40), and the corresponding weight is displayed through its output unit.

The above-described balance weight data processing method can be implemented in the form of an interface device as follows.

Referring to FIG. 1, the weight data processing interface device 20 of the present invention is connected between a balance and an electric / electronic device 30 to filter and process weight data detected from the balance 10, To the device (30).

The balance (10) can be constituted by an electronic balance as an apparatus for measuring a target weight of an object. The electronic balance may be composed of, for example, a load cell type electronic balance or a zero method electronic balance.

The balance 10 may further include a connection terminal connected to the interface device 20 of the present invention. The connection terminal may be preferably a USB terminal or a Micro-USB terminal. In this case, the interface device 20 of the present invention may be configured to be connected to the connection terminal to transmit and receive weight data to and from the balance 10.

The electric / electronic device 30 receives the weight data filtered by the interface device 20 of the present invention and outputs it to the outside.

According to one embodiment, the electrical < / RTI > electronic device 30 may comprise a computer device having at least an output and having a memory, a central processing unit and a connection terminal.

In this case, the output unit may be constituted by a display device (e.g., an LED and an LCD, etc.) capable of visually displaying weight information. The interface device 20 of the present invention may be connected to a connection terminal and configured to transmit and receive weight data to and from the computer device.

The interface device 20 of the present invention includes a weight setting unit 21 for setting a target weight, an arithmetic processing unit 22 for filtering weight data detected by the balance 10, data for processing the collected weight data A processing section 23 and a data transfer section 24. [

The arithmetic processing unit 22 has a first function for recognizing an instantaneous weight change (hereinafter referred to as an 'instantaneous change') generated in the scale 10 and a second function for recognizing the instantaneous change, And a second function of calculating a weight change rate (hereinafter referred to as a " section change rate ").

As a result of the calculation by the second function, the operation processing unit 22 processes the instantaneous rate of change as noise when the rate of change of the interval is '0'. When the rate of change of the interval exceeds 0, And a third function of determining the target weight proximity of the current weight to be measured.

The operation processing unit 22 is further configured to perform a fourth function of determining the collection frequency of the weight data detected by the balance 10 per unit time based on the proximity according to the third function.

The proximity of the third function of the arithmetic processing unit 22 can be divided into N proximity sections including a first proximity section, a second proximity section, ..., and an Nth proximity section with respect to the target weight, Described proximity determination step S23.

The size of the collection frequency of the fourth function of the calculation processing section 22 can be configured to be determined in the same manner as the collection frequency determination step S24 described above.

The data processing section 23 functions to process the weight data collected according to the collection frequency by the fourth function of the calculation processing section 22. [

According to a preferred embodiment, the data processing unit 23 may be configured to convert the weight data collected through the filtering of the arithmetic processing unit 22 into character string data, and the character string may be an ASCII code.

The data transfer unit 24 may be configured as a wired / wireless communication module for transmitting the weight data processed by the data processing unit 23 to the electric /

While the preferred embodiments of the present invention have been described and illustrated above using specific terms, such terms are used only for the purpose of clarifying the invention, and it is to be understood that the embodiment It will be obvious that various changes and modifications can be made without departing from the spirit and scope of the invention.

For example, in the case of the embodiment of FIG. 1, the interface device of the present invention is described and shown as a separate device physically separated from and connected to the balance 10 and the electric electronic device 30, But may be integrally mounted on the scale 10 or the electric / electronic device 30. [

Such modified embodiments should not be understood individually from the spirit and scope of the present invention, but should be regarded as being within the scope of the claims of the present invention.

10: Balance 20: Interface device
21: Weight setting section 22: Operation processing section
23: Data processing unit 24: Data transfer unit
30: Electric and electronic devices

Claims (9)

CLAIMS What is claimed is: 1. A method of processing weight data detected by an instrument,
A first step of setting a target weight;
A second step of recognizing instantaneous weight change (hereinafter referred to as 'instantaneous change') generated in the balance;
A third step of calculating a weight change rate (hereinafter, referred to as 'section change rate') generated during the first time interval after the instant change when recognizing the instant change;
As a result of the third step, the input weight data is processed as noise when the section change rate is '0', and the target weight proximity of the current weight measured by the balance is determined when the section change rate is not '0' Step 4;
A fifth step of determining a collection frequency of the weight data detected by the balance unit per unit time based on the proximity; And
And a sixth step of processing the weight data collected according to the collection frequency.
The method according to claim 1,
The proximity is divided into N proximity sections including a first proximity section, a second proximity section, ..., and an Nth proximity section with respect to the target weight,
The N proximity sections are closer to the target weight in the Nth proximity section, ..., the second proximity section, and the first proximity section,
In the fifth step, in determining the collection frequency per unit time,
Determining a collection frequency that is greater than the first collection frequency when the proximity degree corresponds to the first proximity section and a second collection frequency when the proximity degree corresponds to the first proximity section; And determining the largest collection frequency.
3. The method of claim 2,
If the target weight proximity determined by the fourth step corresponds to one of the N proximate intervals, the weight data is continuously collected at the second collection frequency even if there is no weight change after the fifth step Characterized in that the weighing data processing method comprises the steps of:
The method of claim 3,
Wherein the second collection frequency is less than the first collection frequency.
3. The method of claim 2,
If the proximity determined by the fourth step is less than the first proximity section,
The input weight data is treated as noise when the interval recalculation rate is '0' after calculating the weight change rate (hereinafter referred to as 'interval recurrence rate') generated during the second time interval, and when the interval recalculation rate is '0' Otherwise, the fifth step is performed,
Wherein the fifth step determines that the collection frequency per unit time is smaller than the first collection frequency.
The method according to claim 1,
In the sixth step,
And converting the collected weight data into character string data.
The method according to claim 6,
Wherein the character string is an ASCII code.
A scale for detecting weight information of the object; And an output unit, and transmits the weight data detected by the balance to the electric / electronic apparatus after processing, the apparatus comprising:
A weight setting unit for setting a target weight; An arithmetic processing unit for processing weight data detected by the balance; A data processing unit for processing the collected weight data; And a data transfer unit,
Wherein the arithmetic processing unit comprises:
A first function for recognizing instantaneous weight change (hereinafter referred to as 'instantaneous change') generated in the balance;
A second function of calculating a weight change rate (hereinafter, referred to as 'section change rate') generated during the first time interval after the instant change when recognizing the instant change;
Wherein when the interval change rate is 0, the instantaneous rate of change is treated as noise, and when the interval change rate is not 0, the target weight of the current weight measured by the balance, A third function for discriminating the degree;
And a fourth function of determining a collection frequency per unit time of the weight data detected by the balance, based on the proximity,
Wherein the data processing unit comprises:
Processing the weight data collected according to the collection frequency by the fourth function of the calculation processing unit,
Wherein the data transfer unit comprises:
And transmits the weight data processed by the data processor to the electric / electronic apparatus.
9. The method of claim 8,
Wherein the data processing unit converts the collected weight data into character string data.

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