KR20050075537A - Battery capacity monitoring and method and device - Google Patents

Abstract

The present invention relates to a configuration and algorithm of an apparatus for effectively monitoring and correcting a battery capacity with a low cost configuration in a battery powered small electronic device.

The device of the present invention comprises a sensing circuit portion comprising a system under load, a battery cell for supplying power to the system, a passive element located between the system and the battery cell, and a sensing circuit portion electrically connected to the sensing circuit portion. And a measurement circuit unit for measuring a voltage and a current flowing through the unit, and a measurement control circuit unit for monitoring a charge amount of the battery through the voltage measured by the measurement circuit unit.

The algorithm comprises measuring the voltage of the battery when the system is on; Determining whether the voltage is in a suspended region; Calculating cumulative charges if the suspension area is not in the step; Measuring the current of the battery; And correcting the state of charge of the battery.

Description

Battery capacity monitoring and method and device

The present invention relates to a battery capacity monitoring method and apparatus, and more particularly, to a configuration and algorithm of a device for effectively monitoring and correcting the capacity of a battery in a low-cost configuration in a battery-powered small electronic device.

Due to the development of wireless communication environment, the use of portable electronic devices such as notebooks, PDAs, and mobile phones is increasing day by day, and effective power management for increasing mobility has become an important issue.

In general, such a portable electronic device is driven by a battery in an environment without a power supply device such as an AC adapter.

Most portable electronic devices are applying a secondary battery with high energy density for light and small size, and lithium polymer series batteries are widely used at present.

Therefore, a lot of research has been conducted on the development and research of the lithium polymer series battery and how to monitor the battery effectively so that the system can operate stably.

Various monitoring systems using smart batteries and dedicated chips that monitor the voltage and current of the battery in the battery module and record the capacity directly have been proposed.

However, there is a problem in that the cost of the system is increased because most of the memory devices have to be added to the battery module to use the incorrect remaining amount correction table or to store the capacity of the battery when the battery module is separated from the system.

An object of the present invention devised to solve the above problems is to provide an effective battery monitoring circuit and algorithm that can be implemented at low cost.

In addition, another object of the present invention is to propose a method of increasing the precision of battery monitoring without additional memory or dedicated chip by using the discharge characteristics of the battery.

The present invention for achieving the above object, the sensing circuit portion consisting of a system under load, a battery cell for supplying power to the system, a passive element located between the system and the battery cell, and the sensing circuit portion and It is connected to the battery capacity monitoring device including a measurement circuit unit for measuring the voltage and current flowing in the detection circuit unit, and a measurement control circuit unit for monitoring the charge amount of the battery through the voltage measured by the measurement circuit unit.

The measurement circuit unit preferably further includes an analog-to-digital converter (ADC), an amplifier circuit, and a level converter.

Another invention for achieving the above object, a) measuring the voltage (V _s ) of the battery when the system (on); b) the V _s when it is determined that the suspended region, and V _s is the suspend area set the charge state to the suspend and exit; c) calculating cumulative charges if V _s is not a suspension region in step b; d) measuring the current of the battery; And e) correcting a state of charge of the battery.

In the step c) of c1) the step of moving the V _s is greater than when it is determined that the level A, wherein V _s is greater than a level A set amount of charge accumulated in the reference value A, and in the step d); c2) do not exceed V _s is the level A in step c1, when V _s is the level less than that the determination and the V _s, the level is less than B B, and set the accumulated charge amount to the reference value B, moving to step d) step; And c3) if V _s is not less than level B in step c2), calculating a cumulative charge of the battery.

In the above step e), e1) determining whether the battery is in a charged state or a discharged state; e2) reducing and accumulating the cumulative charge amount in the discharge state in step e1); e3) determining whether it is a suspended area; And e4) moving to step d if the suspension region is not in step e3).

Wherein step e1), e11) if the state of charge in the step e1), the step of increasing and correcting the cumulative charge; e12) determining whether the battery is in a fully charged state, and setting the cumulative charge amount as the reference value A if the battery is in the fully charged state, and moving to step d); And e13) moving to step d) if it is not fully charged in step e12).

In the above step, e3), if the suspense region in step e3), it is preferable to further include the step of setting the state of charge to the suspension and ending.

The calculation of the accumulated charge amount of the battery is preferably calculated by a numerical approximation function whose V _s is obtained from the discharge characteristic curve of the battery as a variable.

The numerical approximation function above

f (V _s ) = a ₁ (V _s ) ³ + a ₂ (V _s ) ² + a ₃ (V _s ) + a ₄

In the above, it is preferable that the unknown coefficients a ₁ , a ₂ , a ₃ , a ₄ be obtained from the discharge characteristic curve of the battery.

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

1 is a block diagram showing the configuration of a battery monitoring apparatus of the present invention.

As the current flows, the battery is divided into a charging state in which the current is supplied from the AC power source 60 to the battery cell 10, and a discharge state in which the current is supplied from the battery cell 10 to the system 50.

In addition, the sensing circuit unit 40 is positioned between the battery cell 10, the system 50, and the AC power supply 60, and all current flows through the sensing circuit unit 40.

In general, the sensing circuit unit 40 is composed of a passive element such as a resistor.

The measurement circuit unit 30 reads the current flowing through the sensing circuit unit 40 and the voltage generated by the current into a circuit such as an ADC.

Preferably, the passive element is a resistor, and the measurement circuit unit is an analog-to-digital converter (ADC).

In addition, the measurement circuit unit may further include an amplifier circuit and a level converter for amplifying a signal in addition to the ADC.

The measurement control circuit unit is preferably a controller or a main CPU of the system that manages the battery.

The voltage and current are transmitted to the measurement control circuit unit 30 to monitor the charge amount and state of the battery.

2 is a discharge characteristic curve of a lithium polymer battery having high energy density and high stability and being widely used as a secondary battery.

Lithium polymer batteries experience a dramatic change in voltage when the battery is nearing full charge and nearing a full discharge.

Therefore, in the present invention, a mathematical approximation is extracted for the selective region in consideration of the operating characteristics of the system from the discharge characteristics as shown in FIG. 2 without using the correction table used in the conventional method.

In general, battery capacity distribution of a battery powered system may be divided into a battery active area in which the system is normally driven and a suspension area for holding a memory device such that data stored in the system is stored for a predetermined time or more.

It should be noted that when the suspend region is excluded, the discharge characteristic is easily approximated mathematically in a section excluding a part of the full charge region. Can be extracted

In the present invention, attention is paid to the battery capacity calculation region in which the characteristic curve is easily extracted from the characteristic curve as shown in FIG.

The discharge characteristics of this region can be obtained by the third equation as shown in the following equation when numerically approximating the measured voltage (V _s ).

f (V _s ) = a ₁ (V _s ) ³ + a ₂ (V _s ) ² + a ₃ (V _s ) + a ₄

Fig. 3 is a very effective approximation of the results obtained by deriving the unknown coefficients a ₁ , a ₂ , a ₃ , a ₄ through the best approximation based on the measured data including noise, and comparing the results with the measured data.

Therefore, by extracting the characteristic curve function f (V _s ) in the present invention, it is possible to calculate the current charge capacity of the battery only by measuring the voltage of the ADC.

Of course, in addition to the above equation, it is also possible to approximate numerically in other forms.

4 shows a flowchart of a battery monitoring algorithm.

When the system is turned on, the initial part calculates the current charge through voltage sensing.

At this time, when voltages above Level A and below Level B are measured, the area is forced to reference value A when level A is exceeded and level B when level B is below level B, in consideration of the accuracy of charge calculation.

The level A is the highest voltage value of the battery capacity calculation area, and the level B is the lowest voltage value of the battery capacity calculation area.

The reference value A may be set at 95%, the reference value B at 5%, and the like.

After the process of calculating the capacity (charge) of the battery, the charging or discharging state of the battery is determined through current sensing.

Then, the charge amount converted into charge amount is continuously updated and the current capacity information of the battery is maintained.

The variable charge amount ΔQ of the battery is calculated by the integral formula for the time t, but can be expressed by the following formula if the current sensing is performed at a constant period (T). G (t) is the amount of current flowing at time t.

△ Q = ∫g (t) dt = ∑g (nT) T

Coulomb counting is obtained by adding? Q to f (V _s ) in the charged state and subtracting it in the discharge state.

Accumulation of charge amount may occur over time, so when the measured voltage reaches the previous voltage and the current flow approaches zero, the battery is assumed to be fully charged, and the charge amount is forcibly corrected to the reference value A. Ensure accurate battery monitoring.

Through the present invention as described above, it is possible to effectively perform battery monitoring and correction with a simple configuration.

The present invention is also applicable to most electronic devices driven by batteries.

1 is a block diagram of a battery monitoring circuit;

2 is a discharge characteristic of a typical lithium polymer battery

3 is an approximation of discharge characteristics of FIG. 2.

4 is a battery monitoring flowchart

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

10: battery cell 20: measurement circuit unit

30: measurement control circuit 40: detection circuit

50: system 60: AC power

Claims (9)

A sensing circuit portion comprising a system under load, a battery cell for supplying power to the system, a passive element positioned between the system and the battery cell, and a voltage and current flowing in the sensing circuit portion electrically connected to the sensing circuit portion. A battery capacity monitoring device including a measurement circuit unit for measuring and a measurement control circuit unit for monitoring the charge amount of the battery through the voltage measured by the measurement circuit unit. The apparatus of claim 1, wherein the measurement circuit unit further comprises an analog-to-digital converter (ADC), an amplifier circuit, and a level converter. a) measuring the voltage (V _s ) of the battery when the system is on; b) the V _s when it is determined that the suspended region, and V _s is the suspend area set the charge state to the suspend and exit; c) calculating cumulative charges if V _s is not a suspension region in step b; d) measuring the current of the battery; And e) correcting the state of charge of the battery. The method of claim 3, wherein step c) c1) the step of moving the V _s is greater than when it is determined that the level A, wherein V _s is greater than a level A set amount of charge accumulated in the reference value A, and in the step d); c2) do not exceed V _s is the level A in step c1, when V _s is the level less than that the determination and the V _s, the level is less than B B, and set the accumulated charge amount to the reference value B, moving to step d) step; And c3) calculating the accumulated charge of the battery if V _s is not less than level B in step c2). The method of claim 3, wherein step e) e1) determining whether the battery is in a charged state or a discharged state; e2) reducing and accumulating the cumulative charge amount in the discharge state in step e1); e3) determining whether it is a suspended area; And e4) moving to step d if the suspension area is not in step e3). The method of claim 5, wherein step e1) e11) if the state of charge in step e1), increasing and correcting the accumulated charge amount; e12) determining whether the battery is in a fully charged state, and setting the cumulative charge amount as the reference value A if the battery is in the fully charged state, and moving to step d); And e13) if it is not fully charged in step e12), further comprising the step of moving to step d). The method of claim 5, wherein step e3) e31) the battery capacity monitoring method further comprising the step of setting the charge state to the suspension and ending if the suspension area in step e3). The method of claim 4, wherein the calculation of the cumulative amount of charge of the battery, the battery capacity monitoring characterized in that the value calculated by the approximate function to the V _s as determined from a discharge curve of the battery as a variable. 9. The numerical approximation function according to claim 8 f (V _s ) = a ₁ (V _s ) ³ + a ₂ (V _s ) ² + a ₃ (V _s ) + a ₄ Wherein the unknown coefficients a ₁ , a ₂ , a ₃ , a ₄ are obtained from a discharge characteristic curve of the battery.