KR100418555B1 - Method for Calculating and Providing Stand-By Available Time Period of Mobile Communication Device - Google Patents

Abstract

The present invention relates to a method for calculating and providing a standby time of a mobile communication terminal, comprising: a current consumption sampling step of sampling a current consumption amount at a specific time in a standby state of a mobile terminal; The first filtering step of calculating the arithmetic mean of one current consumption amount, and the possible range in which the arithmetic mean value can be divided into one or more filtering ranges, and the median value of the filtering range to which the current consumption arithmetic mean in the first filtering step belongs. After the second filtering step of setting the final current consumption amount, the remaining capacity (RC) of the battery is measured, the remaining capacity value is divided by the final current consumption amount to calculate the standby time at the corresponding time point and output on the screen of the terminal. It is made up of the waiting time calculation and output stage.

According to the present invention, by providing the standby time of the mobile communication terminal accurately and reliably, the user can know the expected use time of the terminal battery and can accurately predict the charging time.

Description

Calculation and provision of waiting time of mobile communication terminal {Method for Calculating and Providing Stand-By Available Time Period of Mobile Communication Device}

The present invention provides a method for calculating and providing a standby time of a mobile communication terminal, and more particularly, applying filtering to a current consumption measured in a standby (Stand-By) state, and based on the accurate, stable and continuous operation of the terminal. The present invention relates to a method of calculating and providing waiting time information.

Recently, with the spread of mobile communication services, almost all citizens have one or more mobile communication terminals.

The battery of the mobile communication terminal has a high energy density, a high operating voltage, a lithium ion secondary battery having many advantages such as excellent retention and life characteristics are widely used. In addition, the terminal displays the remaining capacity (remain capacity) of the battery using a gauge image, etc. on the screen of the terminal so that the battery replacement time can be known.

The conventional display of the remaining capacity of the battery is greatly reduced in accuracy by predicting the remaining capacity of the battery by simply summing the amount of current flowing out, or measuring the output voltage and displaying the remaining capacity based on the relationship between the voltage and the discharge amount. That is, the consumption rate of the displayed battery is not constant, so the user often misses the time to replace or charge the battery.

In addition, only the current battery remaining capacity tells only the ratio (number of compartments of the gauge), the user has no idea how much time can be used (call or standby) with the current remaining capacity. In particular, since the remaining capacity or the output voltage is rapidly reduced after the discharge to some extent due to the discharge characteristics, power failure may occur suddenly. Therefore, it is inconvenient because the user cannot predict the usable time of the terminal at all.

The present invention focuses on this point, and after sampling the current consumption in the standby state, filtering the sampled standby current consumption in two stages, calculating the final current consumption, and then waiting time from the remaining capacity value and the final current consumption amount. To predict and provide.

An object of the present invention is to provide a method for calculating and displaying wait time information of a mobile communication terminal.

Another object of the present invention is to perform a two-stage filtering by sampling the current consumption in the standby state, and to calculate and output accurate, continuous and stable standby time information using the filtered current consumption and the measured residual capacity. To provide.

1 shows an example of the conventional battery remaining capacity display method.

2 is a graph illustrating a response of a filter for performing the second filtering according to the present invention, wherein the x-axis represents a current arithmetic mean value (I _ave [i]; input value) at each time point, and the y-axis represents a second graph thereof. Displays the final output current consumption (I _final [i]; output value) that is the filtering output.

3 is a flowchart illustrating the overall flow of a method for calculating and providing a waiting time according to the present invention.

In order to achieve the object as described above, the wait time calculation and providing method according to the present invention comprises the following steps.

A current consumption sampling step of sampling the current consumption amount I _N at a specific time point i = N in the standby state of the terminal;

A first filtering step of obtaining an arithmetic mean I _ave (N) of currently measured current consumption amount I _N and N-1 current consumption amounts I ₁ to I _N-1 sampled up to now;

The range of possible arithmetic mean values may be divided by one or more filtering ranges, and the intermediate value of the filtering range to which the current consumption arithmetic mean I _ave (N) in the first filtering step belongs is defined as I _final (N A second filtering step of setting to));

After measuring the remaining capacity (RC) of the battery, the remaining capacity value is divided by the final current consumption (I _final (N)) to determine the standby time (T _avail (N)) at that time (i = N) And calculating and outputting a waiting time for calculating and outputting the result on the screen of the terminal.

The above-described series of steps may be performed repeatedly at predetermined intervals, and the filtering range may be arbitrarily determined between 0.5 mA and 5 mA.

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

1 shows an example of the conventional battery remaining capacity display method.

As shown, conventionally, since only 3 to 4 levels of the battery gauge 111 displays the remaining battery capacity, the user may not know exactly how much (how many percent) the remaining capacity is, and the user may not know how much. It was inconvenient to know at all whether it was possible to use (wait or call) during the time.

In order to solve this inconvenience, a method of calculating and displaying the standby time from the measured current consumption per unit time has been proposed. In this method, however, the standby time information was calculated by calculating the average current consumption by harmonizing the current consumption values sampled at various time points and dividing the remaining capacity by the values.

However, using an arithmetic mean rather than a harmonic mean is preferable for the following reasons.

First, in the standby state, since the change in the current consumption is not large, the arithmetic mean and the harmonic mean are almost equal. That is, when each individual has the same value, the arithmetic mean and harmonic mean will be the same, so the arithmetic mean and harmonic mean for the current consumption in the standby state will be almost the same. Therefore, even if the arithmetic mean with a small amount of calculation is used, no large error occurs.

Second, the harmonic mean is calculated by calculating the reciprocal of the current consumption per unit time measured in the calculation process, summing them all up, and calculating the reciprocal again. Although mathematically simple, in-process calculations are much more complicated than the arithmetic mean of performing only the Add because of many divisions, especially when the current consumption is very close to zero. A large value can be calculated and an error can be increased, and when the current consumption is an absolute value of 0, an error occurs when the inverse is taken.

For the above reasons, the present invention uses an arithmetic mean value instead of the harmonic mean value of the current consumption.

When the current consumption amount I _N is measured at a specific time point (i = N), the value and the N-1 current consumption amounts (I ₁ to 1) measured at the previous N-1 time points (i = 1 to N-1). I _N-1 ) The arithmetic mean of the sample values is used to find the arithmetic mean value of current consumption (I _ave (N)) for N samples. Of course, the number N of performing an arithmetic mean may be arbitrarily determined. In the case of the above-described example, the current consumption amount (I ₁ ) of i = 1 when calculating the arithmetic mean is excluded from the target when measuring the current consumption at the time point i = N + 1. do.

The calculated arithmetic mean value will be almost the same at each time point. However, what is ultimately desired in the present invention is the standby time, which is set to a value obtained by dividing the residual capacity value RC by the average value of the current consumption. In general, the remaining capacity value is a large value of several hundred thousand to several million mA (that is, hundreds to thousands of mAh) and the current consumption is small, such as a few tens of mA, so even if there is a slight change in the arithmetic mean, there is a big difference in the waiting time. .

Therefore, the waitable time displayed to the user changes too much every cycle and thus does not give reliability. For example, assuming that a battery with a residual capacity of 1000 mAh, or 3600000 mA, sampling is performed every minute, the arithmetic mean current consumption at i = N is 25 mA, and the arithmetic mean current consumption at i = N + 1 is 24.67 mA. lets do it. The arithmetic mean value is almost unchanged, but when the waiting time is calculated, Equation 1 is calculated as in Equation 1 at i = N and Equation 2 at i = N + 1.

In this way, there is only a slight change in the arithmetic mean value of the current consumption, but there is a very big change in the standby time. In other words, as shown in the above calculation, the displayed wait time varies by about 30 minutes in one minute, which makes the user unreliable at all. In particular, in the above example, as time passes, the waiting time increases, which is more unreliable.

In order to prevent such a phenomenon, the present invention performs the following second filtering on the current consumption arithmetic average value obtained by the first filtering.

2 is a graph illustrating a response of a filter for performing the second filtering according to the present invention, wherein the x-axis represents a current arithmetic mean value (I _ave [i]; input value) at each time point, and the y-axis represents a second graph thereof. Displays the final output current consumption (I _final [i]; output value) that is the filtering output.

That is, dividing the area of the value that the current consumption arithmetic mean value can belong to by 2 or more filtering ranges, and converting the median value of the filtering range to which the current consumption arithmetic mean value I _ave [i] at each time point is the final current at that time Set to consumption (I _final [i]).

In this way, even if the arithmetic mean value of the current consumption values at various time points is minutely changed within one filtering range, the resultant final current consumption values will be the same, and the waiting time will be changed continuously. Of course, if the current consumption arithmetic mean value at a particular point in time is moved to another filtering range, there will be discontinuities in the final current consumption value and the wait time.

That is, the second filtering principle is a kind of low pass filter, which can provide a result value by removing a small data change. This low frequency filtering allows some information to be lost, but can provide a continuous and stable result value, thus solving the discontinuity of the wait time as described above.

In the above, the size of the filtering range may be set identically or differently according to the size of the input value. In addition, the size of the filtering range can be arbitrarily determined according to the need between accuracy and reliability. For example, if each filtering range is large, the continuity and reliability of the waiting time information increases, but the accuracy is low, and if the range is small, the opposite phenomenon occurs.

In FIG. 2, it is assumed that current consumption in a normal standby state is within a range of about 24 to 34 mA, and each filtering range is set to 1 mA.

Table 1 below is for illustrating an example of a process that the waiting time calculation according to the present invention is performed.

First, an example is shown in which sampling is performed every minute and the current consumption Ii measured at each time point is 25, 26, 25, 25, 28, 28, 25, 24 mA. The number N of arithmetic averages was 5 and the filtering range was 1 mA. The remaining capacity is assumed to be 1000mAh at 2 minutes.

Item Sampling Time 1 minute 2 minutes 3 minutes 4 minutes 5 minutes 6 minutes 7 minutes 8 minutes Current consumption Ii (mA) 25 26 25 25 28 28 25 24 Arithmetic Mean (I _ave [i]) - 25.5 25.33 25.25 25.8 26.4 26.2 26.4 Final current consumption (I _final [i]) - 25.5 25.5 25.5 25.5 26.5 26.5 26.5 Wait time based on current consumption at each point (Hour) 38.46 39.98 39.96 35.67 35.65 39.91 41.54 Waiting time by primary filtering (Hour) 39.22 39.46 39.57 38.71 37.81 38.09 37.78 Wait time by secondary filtering (Hour) 39.22 39.2 39.18 39.16 37.67 37.65 37.63

The analysis results of the above table are as follows.

1) Prediction of waiting time using current consumption sampling value at each time point (line 4)

When predicting the waiting time based on the current consumption measured at each time point, the deviation was too severe as shown in the fourth row of the table.

2) Estimation of waiting time using arithmetic mean (first filtering) (5th row)

When the waiting time is estimated using the arithmetic mean value of the current consumption at five time points by the first filtering, the deviation is not as severe as in the case of 1) above, but it is about ± 0.5 hour (about 30 minutes). Deviation of. From the user's point of view, if the waiting time information displayed at an interval of one minute varies by 30 minutes, it is difficult to trust it. In particular, the waiting time displayed at the 3, 4, and 7 minute time points becomes larger than the value displayed at the previous time point. The wait time should be shorter over time, so it will not be more reliable.

3) Estimation of waiting time using final current consumption (second filtering result) (line 6)

It is displayed continuously with almost no such deviation. That is, it is displayed continuously at 2353 minutes (39.22 hours) at 1 minute, 2352 minutes (39.20 hours), etc. at 2 minutes. However, a relatively large deviation occurs when the time goes from 5 minutes to 6 minutes, which is a cumulative change in the current consumption amount (+ deviation), which is an accurate value that reflects the actuality to some extent. In the absence of, this large deviation will not appear.

3 is a flowchart illustrating the overall flow of a method for calculating and providing a waiting time according to the present invention.

First, the sampling unit of the terminal or the battery checks whether the terminal is in the standby state (S311), and then, during the standby state, samples the current consumption amount I _N at a specific time point (i = N) every predetermined period, for example, every minute. (S312). Next, a first filtering step of calculating an arithmetic mean I _ave [N] of the current measured current consumption Ii and the N-1 current consumption amounts I ₀ to I _{N-1 that have} been sampled before is performed. (S313).

When the arithmetic mean value is obtained by the first filtering, the intermediate value of the possible range to which the arithmetic mean I _ave (N) belongs is set by the second filtering to the final current consumption amount I _final (N) (S34).

Next, after measuring the remaining capacity of the battery (S315), by dividing the residual capacity value (RC) by the final current consumption (I _final (N)), the standby time (T) at that time (i = N) _{The avail} (N)) is calculated and output on the terminal screen (S316). This series of processes may be repeatedly performed every predetermined period T (S317).

As described above, the method according to the present invention can accurately and reliably provide the standby time of the mobile communication terminal.

In other words, it is possible to measure the amount of current consumption at a particular point in time, apply two levels of filtering to that value, and provide an accurate and continuous wait time based on the resulting amount of current consumption and the remaining capacity of the battery. Therefore, the user can know the estimated usage time of the terminal battery and can accurately predict the time of charging.

Claims (3)

A current consumption sampling step of sampling the current consumption amount I _N at a specific time point i = N in the standby state of the terminal; A first filtering step of obtaining an arithmetic mean I _ave (N) of currently measured current consumption amount I _N and N-1 current consumption amounts I ₁ to I _N-1 sampled up to now; The range of possible arithmetic mean values may be divided by one or more filtering ranges, and the median value of the filtering range to which the arithmetic mean I _ave (N) belongs in the first filtering step may be the final current consumption amount (I _final (N). A second filtering step of setting to)); After measuring the remaining capacity (RC) of the battery, the remaining capacity value is divided by the final current consumption (I _final (N)) to determine the standby time (T _avail (N)) at that time (i = N) Calculating and providing a standby time for outputting the calculated standby time on the screen of the terminal; and calculating and providing the standby time of the mobile communication terminal. The method of claim 1, A method for calculating and providing a standby time of a mobile communication terminal, characterized by repeating the sampling step, the waiting time calculation and the output step every predetermined period (T). The method according to claim 1 or 2, And a filtering range in the second filtering step is arbitrarily determined between 0.5 mA and 5 mA.