KR100659378B1 - Method for measuring voltage of battery in electric device and the electric device thereof - Google Patents

Abstract

A method for measuring a battery consumption state of electronic products and a device therefor are provided to measure a battery voltage by performing voltage compensation according to voltage sag generated in a driving each function module. A method for measuring a battery consumption state of electronic products includes the steps of: driving a certain function module(310); calculating a respective voltage compensation value based on a difference value between a first battery voltage value which is previously calculated before the function module is driven, and a second battery voltage value which is calculated after the function module is driven(360); calculating a third battery voltage value based on the measured inner voltage value and the respective voltage compensation value; and displaying a battery consumption state corresponding to the third battery voltage value.

Description

METHOD FOR MEASURED VOLTAGE OF BATTERY AND THE ELECTRIC DEVICE

1 is a functional block diagram showing the configuration of a mobile communication terminal for performing a method of measuring a battery consumption state according to an embodiment of the present invention.

2 is a voltage compensation table according to an embodiment of the present invention.

3 is a flowchart illustrating a process of displaying a battery consumption state by calculating a voltage compensation value corresponding to a function module being driven in a mobile communication terminal according to an exemplary embodiment of the present invention.

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

100: mobile communication terminal

110: power supply

120: voltage measuring unit

130: compensation value calculation unit

140: storage unit

150: display unit

160: control unit

170-1, ..., 170-m: function module

The present invention relates to battery voltage measurement, and more particularly, to a battery voltage measuring method and an electronic device having a natural voltage compensation.

In recent years, electronic devices such as multifunctional cellular phones equipped with various modules such as a camera module, an MP3 module, a CDMA communication module, a WCDMA communication module, a radio receiving module, a game module, and a digital multimedia broadcasting (DMB) receiving module have been provided. Moreover, a multifunctional mobile phone may not only perform one function but also allow to drive several function modules at once due to the multi-tasking function. Electronic devices such as multi-function cell phones consume a lot of battery power depending on the operation of various function modules, and when several functions are executed at the same time, a large voltage drop may occur due to excessive current consumption.

In general, the voltage supplied from the battery may cause a voltage drop so that the battery voltage actually measured inside the electronic device may be different from the actual voltage of the battery. Therefore, compensating (i.e., voltage compensating) for the dropped voltage must be made to measure the accurate battery consumption. According to the related art, in the state where a standard voltage compensation value is set in advance for each function module, when any function module is driven, the standard voltage compensation value corresponding to the corresponding function module being driven is compensated for the measured battery voltage value, thereby consuming battery Status measurements and / or indications.

However, if the standard voltage compensation value is uniformly applied, accurate voltage compensation is not possible for the functional module having a voltage drop of a different size according to each manufacturer or type of electronic device. In addition, when a plurality of function modules are driven at the same time, the sum of deviations between the standard voltage compensation value specified for each function module and the voltage compensation value to be actually compensated is not negligible so that the battery consumption state of the electronic device can be accurately measured. There was no problem. That is, although the current consumption of the functional modules and electronic devices of each manufacturer may vary according to driving, it may be more difficult to measure the battery consumption by applying a uniform standard voltage compensation value.

Due to the above reasons, it is not possible to measure the exact battery consumption of the electronic device, and as a result, the electronic device is powered off even when the battery capacity is large, or the battery is running while the battery capacity is low. Power may be turned off without storing data.

Accordingly, the present invention has been made to solve the above-described problems, and a method and method for measuring a battery consumption state that can measure the correct battery voltage by performing a voltage compensation according to the voltage drop generated when driving each functional module The purpose is to provide an electronic device to perform.

Another object of the present invention is to provide an accurate battery consumption state battery power state measurement method that can solve the problem of power off in the state of remaining battery capacity or power off in the state of not storing the data generated by driving the function module And an electronic device for performing the method.

Other objects of the present invention will become more apparent through the preferred embodiments described below.

According to an aspect of the present invention for achieving the above object, a battery consumption state measuring method in an electronic device, comprising: driving any functional module; Calculating an individual voltage compensation value by using a difference value W between a first battery voltage value calculated before the function module is driven and a second battery voltage value calculated after the function module is driven; And calculating a third battery voltage value by using the measured internal voltage value and the individual voltage compensation value.

The method may further include displaying a battery consumption state corresponding to the third battery voltage value.

The individual voltage compensation value may be a sum of W and a standard voltage compensation value corresponding to the function module. The second battery voltage value may be a sum of the measured internal voltage value and the standard voltage compensation value.

In addition, the first battery voltage value is an average value of the battery voltage value calculated m times immediately before the function module is driven, the second battery voltage value of the battery voltage value calculated n times immediately after the function module is driven. It may be an average value.

The method may further include storing the individual voltage compensation value and the third battery voltage value.

The method may further include determining whether a difference value between the measured internal voltage value and the previously measured internal voltage value is greater than or equal to a predetermined value.

According to another aspect of the invention, the electronic device having at least one functional module, comprising: a voltage measuring unit for measuring an internal voltage value; Compensation value calculation unit for calculating the individual voltage compensation value by using the difference value (W) between the first battery voltage value calculated before any function module is driven and the second battery voltage value calculated after the function module is driven. ; And a controller configured to calculate a third battery voltage value using the measured internal voltage value and the individual voltage compensation value.

The display device may further include a display configured to display a battery consumption state corresponding to the third battery voltage value.

The individual voltage compensation value may be a sum of W and a standard voltage compensation value corresponding to the function module.

The electronic device may further include a storage configured to store the first battery voltage value, the second battery voltage value, the individual voltage compensation value, and the third battery voltage value.

The function module may be at least one of an MP3 module, a camera module, a game module, a radio receiving module, and a digital multimedia broadcasting (DMB) module.

In addition, the first battery voltage value is an average value of the battery voltage value calculated m times immediately before the function module is driven, the second battery voltage value of the battery voltage value calculated n times immediately after the function module is driven. It may be an average value.

Hereinafter, a battery consumption state measuring method and an electronic device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings, and in the following description with reference to the accompanying drawings, the same or corresponding components regardless of reference numerals Denotes the same reference numerals and duplicate description thereof will be omitted.

In addition, in describing an electronic device for performing a battery consumption state measuring method according to the present invention, the electronic device includes a mobile communication terminal such as a personal digital assistant (PCS), a PDA, a portable multimedia player (PMP), It is obvious that all electronic devices such as game phones, digital multimedia broadcasting (DMB) phones, digital cameras, and car navigation devices will be included. However, for convenience of description, the following description will be made with reference to a mobile communication terminal among electronic devices, but in addition to the above-described electronic devices, the same will also be apparent through the following description.

1 is a functional block diagram showing a configuration of a mobile communication terminal for performing a battery consumption state measuring method according to an embodiment of the present invention, Figure 2 is a voltage compensation table according to an embodiment of the present invention.

Referring to FIG. 1, the mobile communication terminal 100 according to the present invention includes a power supply unit 110, a voltage measuring unit 120, a compensation value calculating unit 130, a storage unit 140, a display unit 150, and a control unit ( 160 and at least one functional module 170-1,..., 170-m, hereinafter referred to collectively as 170. The function module 170 may include at least one of an MP3 module, a camera module, a game module, a radio receiving module, a digital multimedia broadcasting (DMB) module, and the like, and is mounted on the mobile communication terminal 100 to perform a specific function. Any module that can be applied can be applied without restriction. Here, some components (for example, the voltage measuring unit 120, the compensation value calculating unit 130, etc.) shown in FIG. 1 do not necessarily have to be a hardware configuration, and are implemented in software to form a mobile communication terminal ( It is apparent that the same operation may be performed by being installed at 100).

The power supply unit 110 provides driving power to the mobile communication terminal 100. The power supply unit 110 may be implemented as any power supply device that generates a voltage such as a 1.5V battery or a mobile phone battery. When the power supply device is implemented independently of the mobile communication terminal 100, the power supply unit 110 may perform an interface function with the power supply device.

The voltage measuring unit 120 measures the internal voltage applied to the mobile communication terminal 100 according to a preset period (for example, a 10 second period) while the mobile communication terminal 100 is turned on (on state). do. In general, the internal voltage value measured by the voltage measuring unit 120 may be smaller than the voltage applied by the power supply unit 110 due to a voltage drop generated by a circuit inside the mobile communication terminal 100. In addition, when any of the provided function module 170 is driven, a voltage drop by the function module 170 may occur.

Therefore, the compensation value calculator 130 calculates a voltage compensation value for compensating the voltage value measured by the voltage measuring unit 120. It is important to calculate a more accurate voltage compensation value in order to accurately measure the battery consumption state and provide it to the user (eg, display through the display unit 150). In particular, the compensation value calculator 130 calculates a voltage compensation value (hereinafter, referred to as an “individual voltage compensation value”) corresponding to each of the provided function modules 170.

The compensation value calculating unit 130 calculates the individual voltage compensation value by using the battery voltage value calculated before the arbitrary function module 170 is driven and the battery voltage value after being driven to calculate the individual voltage compensation value. can do. Alternatively, the average value of each battery voltage value may be used to calculate a more accurate individual voltage compensation value. For example, the compensation value calculator 130 calculates an average voltage compensation value corresponding to the currently driven function module 170, and calculates an average value of the battery voltage values calculated until the function module 170 is driven. Alternatively, the average value of m times until immediately before the function module is driven) and the average value of the battery voltage values calculated n times since the function module 170 is driven may be used. Hereinafter, when one function module 170 is operated in a state in which no function module 170 is operated (hereinafter, referred to as an "initial state"), an individual voltage compensation value and a battery voltage value are calculated. It will be described assuming. In the calculation of the individual voltage compensation value, an example of using an average value of the battery voltage values before and after driving the function module 170 will be described.

Referring to FIG. 2, a process of calculating the voltage compensation value by the compensation value calculator 130 using the voltage compensation table will be described.

The battery voltage value to be calculated to measure the battery consumption state is referred to as D, and the internal voltage value measured by the voltage measuring unit 120 will be referred to as A.

As shown in FIG. 2, the standard voltage compensation value (B, hereinafter referred to as 'B') is preset for each function module, and the corresponding function module is driven by a preset n (natural number) times so that the individual voltage compensation value is increased. Until calculated, the standard voltage compensation value is used. In addition, as shown in FIG. 2, B may include B _ini applied in an initial state in which no function module is driven, and B _cam applied in a state in which a camera module of the function module 170 is driven.

A process of calculating an average battery voltage value E _ini (hereinafter referred to as 'E _ini ') in the initial state will be described as an example.

The value from D0 to Dm is calculated by using D = A + B _ini according to a predetermined period as m preset times. Therefore, it can be calculated as "E _ini = (D0 + D1 + D2 + D3 ... Dm) / m". Assuming that the specific function module 170 is driven, for example, the camera module is driven, the A value and the standard voltage compensation value B _cam measured for a preset number of times after the camera module is driven are similarly calculated. The average value of the summed D values becomes an E _cam value, and may be calculated as "E _cam = (D0 + D1 + D2 + D3 ... D) / n". Of course, m and n can be set the same or differently. All of the calculated E values are stored in the storage 140. Here, m and n are preferably set to a size that can be performed for a time such that the battery does not consume much. That is, if m and n are too large, the battery may be consumed while calculating the average value, and a large deviation may be calculated. If the value is too small, it is difficult to obtain a more accurate average value. For example, m and n may be set to 1 to 10. In addition, when the difference is greater than a predetermined level (for example, the Y value) compared to D or A immediately calculated among D or measured internal voltage values A calculated for m and n times, it is determined not to be a valid value. Remove For example, calculate D3, and remove "D3" if "D3-D2>Y". This is because an internal voltage value A measured by the voltage measuring unit 120 may be incorrectly measured.

Thereafter, the compensation value calculator 130 uses the individual battery compensation value C _cam (“C _cam ”) by using E _ini , which is an average battery voltage value in an initial state, and E _cam , which is calculated after driving the camera module. Will be referred to as). E _ini minus E _cam is called W. For example, if the camera module is running, the individual voltage compensation value is "C _cam = B _cam + W" where W = E _ini -E _cam ). Therefore, a more accurate battery voltage value can be calculated as "D = A + C" using the calculated individual voltage compensation value. C _cam is stored as a voltage compensation value corresponding to the camera module, so that C _cam can always be applied as a voltage compensation value according to the camera module. Of course, even after the C _cam is calculated, it is natural that the average battery voltage value and the new C may be calculated and applied.

If a specific function module (a camera module is used as an example) is being driven while it is not in the initial state, a process of calculating a battery voltage value when another function module (a radio reception module is used as an example) is explained. Let's do it. As described above, the battery voltage value while the camera module is being driven is calculated as "D = A + C _cam ". When the radio receiving module is driven in this state, a new individual voltage compensation value C 'is calculated. The camera module obtains the average value E 'of the battery voltage value after the driving _cam with the average value E and the radio reception module, the battery voltage value D while driving. That is, the average value of the battery voltage after the radio receiver module is driven together may be obtained as "E '= (D0 + D1 + D2 + D3 ... Dn) / n". Therefore, the new individual voltage compensation value can be calculated as "C '= B _rad + (E12-E _cam )", and thus the battery voltage value when the camera module and the radio receiving module are driven together is "D = A + C '"to indicate more accurate battery consumption.

Hereinafter, a process in which the compensation value calculator 130 calculates a voltage compensation value when two or more functional modules 170 are driven simultaneously in an initial state will be described. It is assumed that the functional module is a camera module and a radio receiving module.

First, the battery voltage value before the individual voltage compensation value C is calculated is calculated as "D = A + B _cam + B _rad ". Thereafter, an average battery voltage value E ₁₂ (average battery voltage value for a predetermined number of times when the camera module and the radio receiving module are driven) according to n voltage measurements may be calculated. When E ₁₂ is calculated, the individual voltage compensation value is calculated as "C = B1 + B2 + (E ₁₂ -E _ini )". Thereafter, the mobile communication terminal 100 calculates a battery voltage value using the calculated individual voltage compensation value to display a battery consumption state. As described above, even when a plurality of functional modules are driven, the voltage compensation value may be calculated in the same manner.

Here, the average battery voltage value E corresponding to each function module 170 illustrated in FIG. 2 assumes only that each function module 170 is driven in an initial state, and at least one function module 170. Of course, the average battery voltage value when the other arbitrary function module 170 is driven may be included in the voltage compensation table. In addition, it will be apparent that the calculated voltage compensation table C may be included in the voltage compensation table.

Referring back to FIG. 1, the storage 140 stores a data necessary for the compensation value calculator 130 to calculate a voltage compensation value. In particular, the storage 140 stores the previously calculated battery voltage values D and the average battery voltage value E so that the compensation value calculator 130 can calculate the current voltage compensation value. And the like, and store the newly calculated individual voltage compensation value (C).

The display unit 150 displays a battery consumption state corresponding to a battery voltage value obtained by adding the internal voltage value measured by the voltage measuring unit 120 and the individual voltage compensation value calculated by the compensation value calculating unit 130. . For example, the display unit 150 may be a liquid crystal.

The controller 160 measures the voltage value from time to time, calculates and stores an average battery voltage value, calculates an individual voltage compensation value C, and calculates a more accurate battery voltage value to display a battery consumption state. In order to do so, the power supply unit 110, the voltage measuring unit 120, the compensation value calculating unit 130, and the storage unit 140 and the display unit 150 are controlled. In addition, the controller 160 controls driving of each function module 170.

Hereinafter, a process of displaying a battery consumption state by measuring a voltage from time to time by the mobile communication terminal 100 and calculating a voltage compensation value corresponding to the function module 170 to be driven will be described.

3 is a flowchart illustrating a process of displaying a battery consumption state by calculating a voltage compensation value corresponding to a function module being driven in a mobile communication terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 3, in operation 310, any function module 170 of the mobile communication terminal 100 is driven. In step 320 and step 330, the mobile communication terminal 100 measures the voltage value A and calculates a battery voltage value. Here, as the voltage compensation value, if C value has been calculated previously, C is used, and if C is not calculated, B is used as the standard voltage compensation value. That is, the battery voltage value D is "A + C" or "A + B".

It is determined whether the battery voltage value calculated in step 340 is a valid value. That is, if the difference between the immediately calculated battery voltage value and the currently calculated battery voltage value is greater than a predetermined value, the controller determines that the value is invalid and proceeds to step 320. If the value is valid, the previous battery voltage value is determined in step 350. The average battery voltage value E is calculated by using the following methods. The calculated average battery voltage value is stored together with information on which function module 170 is driven. That is, in the case of a camera module, it is stored as a value of E _cam (see FIG. 2). Here, steps 320 and 340 may be performed until the average of battery voltage values is calculated according to a predetermined number of times. That is, when the average value of five battery voltage values is set to be obtained, steps 320 to 340 are performed until D is measured five times, and when D is measured five times, the average battery voltage value is calculated in step 350.

In operation 360, the mobile communication terminal 100 calculates the individual voltage compensation value C ′ by using the difference between the calculated average battery voltage value and the average battery voltage value of the initial state immediately before the function module 170 is driven. Save it.

The battery voltage value is calculated (D = A + C ′) by compensating the voltage value measured in step 310 with the individual voltage compensation value in step 370, and displays a corresponding battery consumption state.

Therefore, a voltage compensation value corresponding to the driving function module 170 may be calculated to provide a more accurate battery consumption state. Here, in the present embodiment, it is assumed that only one function module 170 is driven. However, even when a plurality of function modules 170 are driven, voltage compensation values corresponding to the respective function modules 170 are respectively calculated. Applicability will be apparent from the foregoing descriptions.

The method of the present invention as described above may be implemented in a program and stored in a computer-readable recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto-optical disk, etc.).

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

As described above, according to the present invention, a method for measuring a battery consumption state and an electronic device for performing the method may be used to measure a battery voltage accurately by performing voltage compensation according to a voltage drop generated when driving each function module. There is an effect that can be provided.

In addition, by providing an accurate battery consumption state, there is an effect that can be solved the problem that the power off in the state of remaining battery capacity or the power off in a state that can not save the data generated by driving the function module.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art that various modifications of the present invention without departing from the spirit and scope of the invention described in the claims below And can be changed.

Claims (13)

In the method of measuring battery consumption in an electronic device, Any function module is driven; Calculating an individual voltage compensation value by using a difference value W between a first battery voltage value calculated before the function module is driven and a second battery voltage value calculated after the function module is driven; And And calculating a third battery voltage value by using the measured internal voltage value and the individual voltage compensation value. The method of claim 1, And displaying a battery consumption state corresponding to the third battery voltage value. The method of claim 1, The individual voltage compensation value is the sum of the standard voltage compensation value corresponding to the function module and the W value of the battery consumption state in the electronic device. The method of claim 3, wherein And the second battery voltage value is a value obtained by adding the measured internal voltage value to the standard voltage compensation value. The method of claim 1, The first battery voltage value is an average value of battery voltage values calculated m times immediately before the function module is driven, and the second battery voltage value is an average value of battery voltage values calculated n times immediately after the function module is driven. Method for measuring battery consumption in an electronic device, characterized in that. The method of claim 1, And storing the individual voltage compensation value and the third battery voltage value. The method of claim 1, And determining whether a difference value between the measured internal voltage value and a previously measured internal voltage value is equal to or greater than a predetermined predetermined value. In an electronic device provided with at least one functional module, A voltage measuring unit measuring an internal voltage value; Compensation value calculation unit for calculating the individual voltage compensation value by using the difference value (W) between the first battery voltage value calculated before any function module is driven and the second battery voltage value calculated after the function module is driven. ; And And a controller configured to calculate a third battery voltage value using the measured internal voltage value and the individual voltage compensation value. The method of claim 8, And a display configured to display a battery consumption state corresponding to the third battery voltage value. The method of claim 8, The individual voltage compensation value is an electronic device, characterized in that the sum of the W and the standard voltage compensation value corresponding to the functional module. The method of claim 8, And a storage unit which stores the first battery voltage value, the second battery voltage value, the individual voltage compensation value, and the third battery voltage value. The method of claim 8, The functional module is at least one of an MP3 module, a camera module, a game module, a radio receiving module, and a digital multimedia broadcasting (DMB) module. The method of claim 8, The first battery voltage value is an average value of battery voltage values calculated m times immediately before the function module is driven, and the second battery voltage value is an average value of battery voltage values calculated n times immediately after the function module is driven. Electronic device, characterized in that.

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