JP2024020945A - Electronic equipment and its control method and program - Google Patents

Abstract

An object of the present invention is to calculate the impedance of a battery pack and control the execution of functions of an electronic device. [Solution] In an electronic device, a battery pack has a temperature detection section and a memory that holds information for specifying the internal impedance of the battery pack with respect to the load time, which is the time when electricity is applied to the load, and the temperature. . The control unit 101 obtains a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than the load time corresponding to the function, and obtains a first impedance value based on the change in current and voltage from the battery pack, and calculates the temperature detected by the temperature detection unit and Based on the impedance information held in the holding unit, a second impedance value corresponding to a predetermined load time is acquired, and based on the first impedance value and the second impedance value, the load time of the function of the electronic device is determined. Obtains the internal impedance of the battery pack corresponding to the specified internal impedance, and controls the execution of functions based on the obtained internal impedance. [Selection diagram] Figure 1

Description

The present invention relates to an electronic device and a control method and program thereof.

Electronic devices such as digital cameras generally use battery packs of lithium-ion secondary batteries that can be repeatedly charged and discharged as power sources. The internal impedance of a lithium ion secondary battery has a characteristic that changes depending on the temperature and the amount of time the current is applied to the load. In many cases, the internal impedance is higher when the temperature is lower than room temperature, and when the current is applied for a longer time than when the current is applied for a short time.

When a battery pack of lithium ion secondary batteries is used in an electronic device, its voltage drops due to the steep load required to operate the electronic device. Therefore, it is necessary to control the voltage of the battery pack so that it does not fall below the threshold voltage or the operation prohibition voltage of the electronic device. Therefore, battery pack impedance detection is a necessary element for stable operation of electronic devices.

There is a method of flowing current from the battery pack through a pseudo load circuit and calculating the impedance of the battery pack from the changes in battery voltage and current at that time. However, this method has the problem that if the dummy load circuit is energized for a long time, a large amount of battery capacity is consumed, and that the user's operation is hindered during the time required for calculation. The effect of this problem can be reduced by shortening the energization time to the pseudo load circuit, but if the energization time to the dummy load circuit is shorter than the energization time to the load corresponding to the function, the impedance will increase due to the above battery characteristics. The value may be calculated before it becomes large, and it may not be possible to accurately detect the battery impedance that matches the functional load.

For example, Patent Document 1 discloses that when calculating the impedance of a battery by energizing a dummy load circuit, the duration of energization of the dummy load circuit is shortened based on the battery capacity within a range that does not reduce the accuracy of impedance detection. A state detection method is disclosed.

Further, Patent Document 2 discloses a charging control method in which charging conditions based on temperature and resistance value are stored in a table in advance in a charging device, and appropriate charging control is performed based on the current state of the battery.

Japanese Patent Application Publication No. 2001-188288 Japanese Patent Application Publication No. 2015-104225

However, in the technology disclosed in Patent Document 1, the impedance of a lithium ion secondary battery changes greatly depending on the energization time, for example, when the temperature is low. Therefore, there is a limit to shortening the energization time to the pseudo load circuit.

Further, in the technique disclosed in Patent Document 2, since the pseudo load circuit is not energized, there is no problem caused by a prolonged energization of the pseudo load circuit. However, if the current state of the battery pack has changed from the stored state, correct control may not be possible. Furthermore, it is impossible to deal with cases where the information stored in the battery pack is incorrect, or where there is a poor connection that was not intended by the designer when using the battery pack.

The present invention was made in view of the above problem, and calculates the impedance of a battery pack according to the time when the load is energized, corresponding to the function, in a time shorter than the time when the load is energized, corresponding to the function. , which aims to provide technology for controlling operations using battery packs.

In order to solve this problem, for example, the electronic device of the present invention has the following configuration. That is,
An electronic device that uses a battery pack as a power source, which has a temperature detection means and a holding means for holding information for specifying the internal impedance of the battery pack with respect to the load time, which is the time during which the load is energized, and the internal impedance of the battery pack. hand,
a first acquisition means for acquiring a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than a load time corresponding to the function;
a second acquisition means for acquiring a second impedance value corresponding to the predetermined load time based on the temperature detected by the temperature detection means and the impedance information held in the holding means;
The internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the first impedance value and the second impedance value, and the internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the acquired internal impedance. and control means for controlling execution.

According to the present invention, the impedance of the battery pack is calculated in accordance with the energization time to the load corresponding to the function in a shorter time than the energization time to the load corresponding to the function, and the operation using the battery pack is performed. It becomes possible to control.

FIG. 1 is a block diagram showing the configuration of main parts in an electronic device. A flowchart showing a processing procedure of an electronic device. A flowchart showing a processing procedure of an electronic device. A flowchart showing a processing procedure of an electronic device. The figure which shows the example of an impedance table.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. Note that the following embodiments do not limit the claimed invention. Although a plurality of features are described in the embodiments, not all of these features are essential to the invention, and the plurality of features may be arbitrarily combined. Furthermore, in the accompanying drawings, the same or similar components are designated by the same reference numerals, and redundant description will be omitted.

FIG. 1 is a block configuration diagram around a battery pack in an electronic device to which the embodiment is applied. Although the type of electronic device is not particularly limited, an example is a digital camera. However, even if the electronic device of the embodiment is applied to a digital camera, the configuration related to the original functions (imaging and recording) of the electronic device is not the main focus of the present embodiment, so the configuration is not illustrated.

Electronic device 100 houses battery pack 200 and operates using battery pack 200 as a power source. The electronic device 100 includes a control section 101, a connection section 102, a state detection section 103, a memory 104, and a notification section 105.

The battery pack 200 functions as a power source for the electronic device 100 and houses a battery that can be repeatedly charged and discharged. A battery that can be repeatedly charged and discharged is, for example, a lithium ion secondary battery. In the embodiment, the battery pack 200 can be easily attached and detached by the user from the electronic device 100 using a mounting and discharging mechanism (not shown).

The control unit 101 controls the entire electronic device 100 . The control unit 101 includes a CPU, a ROM that stores programs executed by the CPU, and a RAM that is used as a work area for the CPU.

The notification unit 105 is a display device such as a liquid crystal display. In order for the electronic device 100 to notify the user of various information, information such as characters and messages is displayed on the display unit 105, for example. Furthermore, the notification unit 105 may be configured with a plurality of LEDs, and may notify the user of information based on the lighting pattern and lighting color of the LEDs.

The connection section 102 electrically connects the electronic pack 200 and the electronic device 100. The connection section 102 has a plurality of connection terminals. These plural connection terminals include a + line terminal and a - line terminal for receiving power from the electronic pack 200, as well as a data line terminal for communicating between the electronic device 100 and the battery pack 200. Furthermore, the connection unit 102 may include a terminal for transmitting and receiving temperature information.

The state detection unit 103 communicates with the connected battery pack 200 via the control unit 101 and the connection unit 102. The state detection unit 103 also communicates with the control unit 101. Information exchanged between the state detection section 103 and the connection section 102 includes information regarding the state of the battery pack 200. Information regarding the state of the battery pack 200 includes information such as voltage, current, temperature, capacity, degree of deterioration, individual information, and function request commands of the battery pack 200, and impedance information held in the memory 204 of the battery pack 200. included. Further, the state detection unit 103 can obtain information regarding the load corresponding to the function of the electronic device 100, which is stored in the memory 104, via the control unit 101. In the embodiment, it is assumed that both the memories 104 and 204 are writable nonvolatile memories.

The state detection unit 103 in the embodiment includes a voltage detection unit, a current detection unit, and a pseudo load circuit in order to obtain the impedance of the battery pack 200. Under the control of the control unit 101, the state detection unit 103 detects changes in voltage and current when the power supplied from the power supply line from the battery pack 200 is supplied to the pseudo load circuit for a predetermined time τdet. By calculating, the impedance value Zcam of the battery pack 200 at the predetermined time τdet is obtained. In the following explanation, the time during which current flows through the load may be referred to as load time. In this way, when the pseudo load circuit is energized for a predetermined time τdet, if the change in voltage of the battery pack 200 is ΔV and the change in current is ΔI, the impedance value Zcam can be obtained by the following equation (1). It will be done.
Zcam = ΔV/ΔI…(1)

Note that as the impedance of the battery pack 200 corresponding to the predetermined load time τdet, an average value within a short period of time may be calculated, or values at a plurality of points may be calculated each time elapses.

The memory 104 stores information (load information) regarding the load corresponding to the function in the electronic device 100. This load information includes, for example, the time and size of the load required to implement each function. The load time is the time during which current is passed through the load necessary to realize a function, and the load size may be either electric power or current. In order to make it easier to judge the operation, it is preferable that the load information is saved as rectangular wave information simplified from the actual load waveform.

The battery pack 200 includes a control section 201, a battery cell 202, a temperature detection section 203, and a memory 204.

The control unit 201 controls the entire battery pack 200, and includes a CPU, a RAM that stores its program, and a RAM that is used as a work area. Note that the memory 204 may be part of the memory that the control unit 201 has.

The battery cell 202 is, for example, a rechargeable lithium ion secondary battery. The configuration of the battery cell 202 may be a single cell or a set of cells connected in multiple series or in multiple parallels. In the case of a cell set, the information of the battery cells 202 exchanged with the electronic device 100 via the connection unit 102 may be for each cell or may be information for the cell set.

Temperature detection unit 203 detects the temperature of battery cell 202 . The temperature detection method is not particularly limited, but there are, for example, a method in which a thermistor is brought into close contact with the battery cell 202 to obtain the temperature, and a method in which a thermistor is placed on a substrate near the battery cell 202 to obtain the temperature. When there are multiple battery cells 202, the temperature of each battery cell 202 may be measured and the temperature averaged, or the temperature of any battery cell 202 may be selected and used as the temperature of the battery cell 202. good.

Memory 204 stores impedance information regarding the internal impedance of battery pack 200. The impedance information is information indicating the correspondence between the state of the battery cell 202, the load time, and the internal impedance of the battery pack 200. Information indicating this correspondence relationship may be presented in a table, or may be expressed as the function formula itself or as a parameter of the function formula. Changes in impedance with respect to load time and temperature may be stored separately. Hereinafter, the internal impedance of the battery pack 200 may be simply referred to as the impedance of the battery pack 200. The impedance information may include the impedance information of the battery cell 202 and the impedance information of the circuits in the battery pack 200 other than the battery cell 202 separately, or may include them together. As information for specifying the impedance of the battery pack 200, FIG. 3 shows an example of a table showing the relationship between impedance and the temperature of the battery cell 202 and the load time. If it is held as a table, the impedance values corresponding to the load times of the main functions of the electronic device 100 can be used as they are. Moreover, the impedance can also be calculated using the impedance corresponding to the load time close to the desired load time among the load times included in the table. A typical temperature is stored as the temperature of the battery cell 202. When calculating the impedance corresponding to a desired temperature, it can be calculated from the impedance corresponding to a temperature close to the desired temperature from the temperatures stored in the table. For example, when the impedance value Zbat of the battery pack 200 is stored as a relational expression between the battery cell temperature Tbat and the load time τ as the impedance information of the battery pack 200, the function F is stored as shown in the following equation (2). There is.
Zbat=F(Tbat, τ)…(2)

Further, the impedance information in the memory 204 can be updated by the control unit 201. When it is necessary to change the impedance information of the battery pack 200 depending on the degree of deterioration and remaining capacity of the battery cell 202, or how the user uses it, memory The impedance information of 204 can be updated. The impedance information in the memory 204 may be updated based on the impedance of the battery pack 200 corresponding to the predetermined load time τdet calculated by the state detection unit 103. It is preferable to update the impedance information of the battery cell 202 and the impedance information of the circuits in the battery pack 200 other than the battery cell 202 separately according to the factors of change. Instead of updating the impedance information in the memory 204, it may be modified in accordance with a correction formula for deterioration of the battery cells 202.

2A to 2C, the method for detecting the impedance of the battery pack 200 by the control unit 101 on the electronic device 100 side and the control unit 201 on the battery pack 200 side, and the states of the electronic device 100 and the battery pack 200 will be described below. A method of making the determination and a control method based on the determination result will be explained.

FIG. 2A is a main operation flow diagram.

In S101, the control unit 101 controls the state detection unit 103 to detect the state of the battery pack 202. Specifically, under the control of the control unit 101, the state detection unit 103 causes the current from the power supply line from the battery pack 200 to flow through the pseudo load circuit for a predetermined time τdet, and detects the voltage and current at that time. By calculating the change in , the impedance value Zcam of the battery pack 200 corresponding to the predetermined load time τdet is obtained (calculated). Here, the predetermined load time τdet is a sufficiently short time with respect to the load time of the functions of the electronic device 100.

In S102, the control unit 101 transmits a temperature detection request command to the control unit 201 via the connection unit 102. In response to receiving this command, the control unit 201 controls the temperature detection unit 203 to detect the temperature Tbat of the battery cell 202.

In S103, the control unit 101 sends information on the predetermined load time τdet used in the impedance calculation performed in S101 to the control unit 201. The control unit 201 acquires the temperature Tbat of the battery cell 200 acquired in S102 and the impedance value ZbatA of the battery pack 200 corresponding to the predetermined load time τdet from the impedance information in the memory 204, and sends them to the control unit 101. Note that if there is no value that perfectly matches τdet or Tbat in the impedance information (table shown in FIG. 3) in the memory 204, Zbat is determined by linear interpolation.

In S104, the control unit 101 acquires the power path impedance information of the electronic device 100 and, if there is a device connected between the electronic device 100 and the battery pack 200, the power path impedance information of that device. Then, the control unit 101 corrects the impedance of the power supply path other than the battery pack 200 with respect to the received impedance value ZbatA. Specifically, the impedance of the power path from the electronic device 100 to the battery pack 200 is calculated by adding other power path impedances to ZbatA, which is the impedance of only the battery pack 200. Conversely, the impedance of only the battery pack may be calculated by subtracting the impedance of other power supply paths from Zcam.

In S105, the control unit 101 calculates the difference (absolute value) between Zcam and ZbatA, and determines whether the calculated difference is less than a predetermined value. If the control unit 101 determines that the difference is less than a predetermined value, the process proceeds to S106; otherwise (if the difference is greater than or equal to the predetermined value), the process branches to S108. If a plurality of values of impedance at a predetermined time have been obtained, the average value of the differences between the plurality of values may be used, or the value with the largest difference may be used for determination. Regarding the calculation of the difference, a ratio may be calculated, or any method that determines the deviation may be used. The impedance Zcam of the battery pack 200 determined by the state detection unit 103 is determined based on the voltage and current from the battery pack 200, and indicates the impedance corresponding to the current state of the battery pack 200. Therefore, through the determination process in S105, it is determined whether the impedance of the battery pack 200 obtained based on the impedance information stored in the memory 204 of the battery pack 200 is not significantly different from the current state of the battery pack 200. ing.

In S<b>106 , the control unit 101 obtains the function load time τcam from the function load information 104 and sends it to the control unit 201 . In S105, since it is determined that the impedance information in the memory 204 of the battery pack 200 is not significantly different from the current state of the battery pack 200, the impedance information in the memory 204 of the battery pack 200 is used for control. The control unit 201 obtains an impedance value ZbatB of the battery pack 200 corresponding to the temperature Tbat of the battery cell 202 and the functional load time τcam obtained in S102 from the impedance information in the memory 204, and sends it to the control unit 101.

In S107, the control unit 101 controls the operation of the electronic device 100 based on the impedance value ZbatB. The impedance value ZbatB may be corrected using other power path impedances used in S104. Specifically, by adding the impedance of other power supply paths to ZbatB, the impedance of the power supply path that matches the load time τcam of the function when the electronic device 100 operates and receives power from the battery pack 200 is determined. It can be calculated. Based on the impedance of the power supply path that matches the load time and the magnitude of the load on the function obtained from the function load information 104, before using a certain function of the electronic device 100, the system including the battery pack 200 determines whether the function is It is possible to determine whether it is in a usable condition. Specifically, before using a certain function, the electronic device 100 can check whether the voltage of the battery pack 200 will not drop to a threshold value due to current flowing through the load for realizing that function. can. As a result of the confirmation, if it is determined that the voltage of the battery pack 200 will not drop to the threshold value due to current flowing through the load for realizing the function, if the execution of the function is instructed as is, control to perform a function; On the other hand, if it is determined that the voltage of the battery pack 200 will drop to the threshold value due to current flowing through the load for realizing the function, the user will be notified of this and the Control the function from being executed.

On the other hand, when the process proceeds to S108, the control unit 101 determines the state of the battery pack 200, and determines the operation of the electronic device 100 based on the determination result. In S105, the control unit 101 determines that the impedance indicated by the impedance information stored in the memory 204 of the battery pack 200 has a large difference from the value corresponding to the current state of the battery pack 200. Therefore, it is considered inappropriate to directly use the impedance information stored in the memory 204 of the battery pack 200 to control the electronic device 100. Further, Zcam is an impedance corresponding to a predetermined load time τdet, and not an impedance corresponding to a function load time τcam. Therefore, the control unit 101 determines the state of the battery pack 200 and corrects the impedance value based on the determination result. Furthermore, the control unit 101 notifies the user of the state of the battery pack 200. Functions may be restricted depending on the deviation rate between Zcam and ZbatA (the greater the degree of deviation, the larger the value) and the operating mode of the electronic device 100. Details are shown in FIGS. 2B and 2C.

FIG. 2B is a detailed operational flow diagram of S108 in FIG. 2A.

In S201, the control unit 101 determines the magnitude of Zcam and ZbatA. When the control unit 101 determines that ZbatA is larger than Zcam, the process branches to S202, and when it determines that ZbatA is not larger than Zcam, the process branches to S204.

Here, ZbatA being larger than Zcam means that the impedance corresponding to the current state of the battery pack 200 is smaller than the impedance stored in the memory 204 of the battery pack 200. As a characteristic of a secondary battery, the impedance of the battery pack 200 basically increases as charging and discharging are repeated, due to deterioration. Therefore, the impedance stored in the memory 204 of the battery pack 200 may be erroneously stored as a large value, or the internal temperature of the battery cell 202 may rise due to power supply to the electronic device 100, causing the actual battery cell It is presumed that the temperature 202 is different from the temperature Tbat acquired by the temperature detection unit 203. In any case, it is determined that the calculated current impedance value Zcam is more in line with the actual situation than ZbatA, which is based on the acquired temperature Tbat and the impedance information in the memory 204. Conversely, when Zcam is larger, the battery cell 202 has deteriorated, the electronic device 100 and the battery pack 200 have poor contact, or the impedance 204 stored in the memory 204 of the battery pack 200 has erroneously shown a small value. etc. are possible.

In S202, the control unit 101 corrects Zcam to an impedance value corresponding to the function load time τcam based on the impedance information in the memory 204 of the battery pack 200. Zcam is an impedance corresponding to a predetermined load time τdet, and not an impedance corresponding to a function load time τcam. By referring to how the impedance value stored in the memory 204 changes depending on the predetermined load time τdet used to calculate Zcam and the function load time τcam, Zcam can be calculated based on the function load time τcam. can be corrected to an impedance value corresponding to For example, the amount and rate of change in impedance corresponding to the load time τcam of the function with respect to the impedance corresponding to the predetermined load time τdet acquired from the impedance information in the memory 204 is determined. Then, by correcting Zcam based on the amount and rate of change, the impedance corresponding to the load time τcam of the function is obtained. Even if the impedance information in the memory 204 is erroneously stored as a small or large value overall, if the rate of change in impedance with the load time is correct, it is possible to obtain the impedance value corresponding to the load time τcam of the function. can.

In S203, the control unit 101 controls the operation of the electronic device 100 based on the Zcam corrected in S202. From Zcam and the size of the function load obtained from the function load information 104, before the electronic device 100 uses the function, it is determined whether the system including the battery pack 200 is in a state where the function can be used. It is possible to determine whether

On the other hand, when the process proceeds to S204, the control unit 101 acquires the degree of deterioration of the battery cell 202. For example, the control unit 202 can transmit information on the degree of deterioration to the control unit 101 as information on the battery cells 200 stored in the memory 204. Further, the control unit 101 may calculate the degree of deterioration of the battery pack 200 from information such as the number of times the battery pack 200 has been used.

Then, in S205, the control unit 101 determines whether the degree of deterioration of the battery cell 200 is greater than or equal to a predetermined value. When Zcam is larger than ZbatA by more than a predetermined value, if the degree of deterioration is more than the predetermined value, it is determined that the main factor is deterioration of the battery cell 202, and if not, it is determined that the main factor is something other than deterioration. The control unit 101 branches the process to S206 when the degree of deterioration is equal to or higher than a predetermined value, and branches the process to S208 otherwise.

In S206, the control unit 101 updates the impedance information in the memory 204 of the battery pack 200 via the control unit 201. The control unit 101 calculates the impedance value to be updated based on the degree of deterioration and Zcam, and rewrites the impedance information in the memory 204 using the calculated impedance. The control unit 101 uses the degree of deterioration and Zcam to calculate the impedance value to be updated according to a predetermined calculation formula. Alternatively, the impedance value to be updated may be calculated by correcting the impedance information in the memory 204 based on the ratio of Zcam and ZbatA.

In S207, the control unit 101 notifies the user via the notification unit 105 that the battery cell 202 has deteriorated. The content of the notification may be to display the degree of deterioration of the battery cell 202 itself based on the degree of deterioration, or simply to indicate that the battery cell 200 is suspected of deterioration, or to indicate that the battery pack 200 is fully demonstrating its performance. The user may be notified that this may not be possible. If the degree of deterioration is greater than a reference threshold, a message may be displayed to prompt replacement of the battery pack 200 or to stop using it.

Note that the process in S202 after the process in S207 is based on the impedance information updated in S206.

In S208, the control unit 101 determines the state of the battery pack 200, and determines the operation of the electronic device 100 based on the determination result. Although the impedance information in the memory 204 of the battery pack 200 is significantly different from the current state of the battery pack 200 and Zcam is larger, it is assumed that the main cause is not deterioration of the battery cells 202. Determine the state when the system is activated and decide on control. Details of this S208 will be explained below.

FIG. 2C is a detailed operational flow diagram of S208 in FIG. 2B.

In S301, the control unit 101 records the ID of the battery pack 200, Zcam, and current time (date and time when Zcam was acquired) in the nonvolatile memory (for example, memory 104) of the electronic device 100.

In S302, the control unit 101 checks past data stored in the nonvolatile memory. Then, the control unit 101 refers to data recorded from the current time up to a predetermined period of time out of the usage time of the battery pack 200 having the same ID as the ID of the currently installed battery pack.

In S303, the control unit 101 determines whether the number of times of attachment is equal to or greater than a predetermined number of times based on the usage record data of the battery pack 200 referred to in S302. Through this determination, it is determined whether the user has inserted and removed the same battery pack 200 from the electronic device 100 a predetermined number of times or more since the current predetermined period. If the control unit 101 determines that the number of times the battery pack 200 has been attached is equal to or greater than the predetermined number of times, the process branches to S304, and if it determines that the number of times that the battery pack 200 has been attached is less than the predetermined number of times, the process branches to S311.

In S304, the control unit 101 determines whether the change in Zcam is greater than or equal to a predetermined first value based on the usage record of the battery pack 200 referred to in S302. Here, it is determined whether the maximum value and the minimum value of Zcam recorded from now until a predetermined period of time ago are greater than or equal to a first value. Alternatively, changes in Zcam may be determined by evaluating variations in Zcam recorded from the current time up to a predetermined period of time. The control unit 101 branches the process to S305 when the change in Zcam is equal to or greater than a predetermined first value, and otherwise branches the process to S309. Note that if the Zcam recorded from the current time to a predetermined period ago changes significantly each time the battery pack is attached, it is considered that a contact failure between the battery pack 200 and the electronic device 100 has occurred. On the other hand, if there is no significant change, there is no problem with the contact between the battery pack 200 and the electronic device 100 and the degree of deterioration is not large. It is thought that there is a discrepancy in the information. For example, there may be a situation where a small value is erroneously stored in the impedance information of the memory 204 of the battery pack 200 even though the degree of deterioration is not large.

In S305, the control unit 101 notifies the user via the notification unit 105 that there is a suspicion of poor contact. The user may be prompted to reinstall the battery pack 200, or the user may be simply notified that there is a suspicion of poor contact and that the battery pack 200 may not be able to fully demonstrate its performance.

In S306, the control unit 101 sets the largest Zcam among the Zcams recorded after the current predetermined period as the current Zcam, based on the usage record of the battery pack 200 referred to in S302. . With this process, the operation is controlled in S202 and S203 using a large Zcam, so it is easy to deal with the case where the path impedance increases due to poor contact between the battery device 100 and the battery pack 200 while the battery device 100 is in use. Become.

In S307, the control unit 101 corrects Zcam based on the impedance information in the memory 204 of the battery pack 200 in accordance with the functional load information 104. Zcam is an impedance at a predetermined load time τdet, and as it is, it is not an impedance corresponding to the function load time τcam. Here, as explained in S202, Zcam is corrected so that it becomes the impedance corresponding to the load time τcam of the function.

In S308, the control unit 101 controls the operation of the electronic device 100 based on Zcam, as in S107. Based on the Zcam and the size of the function load obtained from the function load information 104, before the electronic device 100 uses a certain function, the system including the battery pack 200 must be in a state where the function can be used. You can determine whether there is.

In S<b>309 , the control unit 101 notifies the user via the notification unit 105 that there is a suspicion of battery abnormality. You may prompt the user to check whether the battery pack 200 in use is compatible with the electronic device 100, or simply indicate that there is a suspicion that the battery is abnormal and that the battery pack 200 may not be able to fully demonstrate its performance. The user may be notified of this fact.

In S310, the control unit 101 adds correction to the value of Zcam. Processing such as adding or integrating a predetermined value to the Zcam value may be performed, or it may be changed to a preset value. Since it is considered that there is an abnormality in the battery pack 200, it is preferable to correct Zcam to a value larger than the pre-calculated value so as to be able to cope with a sudden increase in the internal impedance of the battery pack 200.

In S311, the control unit 101 displays, via the notification unit 105, a message prompting the user to remove the battery pack 200, check the connection terminals, and reinstall the battery pack 200. Since there is a suspicion of poor contact in the connection part 102, ask the user to remove the battery pack 200 from the electronic device 100 and check that there is no dirt attached to the connection terminals and that the terminals are properly engaged. Encourage them to do so. If dust or the like is attached to the connection terminals or if the connection terminals are not properly engaged, the impedance of the power supply path will increase, and the voltage supplied from the battery pack 100 may drop significantly while the electronic device 100 is in use. It will be done. Therefore, it is preferable that the electronic device 100 prohibit or restrict operations other than notifications until the user reinstalls the battery pack 200. Alternatively, the value of Zcam may be corrected to be larger and the operation may be controlled based on Zcam.

Although the embodiment has been described above, it is not limited to the above, and various modifications and changes can be made within the scope of the gist.

For example, S102 and S103 in FIG. 2 may be performed as follows.

In S102 of FIG. 2, the control unit 101 transmits a temperature acquisition request command to the control unit 201 via the connection unit 102. In response to receiving this command, the control unit 201 controls the temperature detection unit 203 to detect the temperature Tbat of the battery cell 202 and transmits the detected temperature Tbat to the control unit 101.

At 103, the control unit 101 requests the control unit 201 to transmit impedance information of the memory 204, and obtains the impedance information. Then, the control unit 101 obtains the temperature Tbat of the battery cell 200 obtained in S102 and the impedance value ZbatA of the battery pack 200 corresponding to the predetermined load time τdet from the obtained impedance information.

Further, the battery pack 200 may include a temperature sensor corresponding to the temperature detection section 203 and a memory 204, and these may be directly accessed by the control section 101 of the electronic device 100 via the connection section 102. . In this case, the battery pack 200 can eliminate the need for the control section 201.

(Other examples)
The present invention provides a system or device with a program that implements one or more of the functions of the embodiments described above via a network or a storage medium, and one or more processors in the computer of the system or device reads and executes the program. This can also be achieved by processing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

The disclosure of this specification includes the following electronic device, its control method, and program.
(Item 1)
An electronic device that uses a battery pack as a power source, which has a temperature detection means and a holding means for holding information for specifying the internal impedance of the battery pack with respect to the load time, which is the time during which the load is energized, and the internal impedance of the battery pack. hand,
a first acquisition means for acquiring a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than a load time corresponding to the function;
a second acquisition means for acquiring a second impedance value corresponding to the predetermined load time based on the temperature detected by the temperature detection means and the impedance information held in the holding means;
The internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the first impedance value and the second impedance value, and the internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the acquired internal impedance. An electronic device comprising: a control means for controlling execution; and a control means for controlling execution.
(Item 2)
When the difference between the first impedance value and the second impedance value is smaller than a predetermined value, the control means adjusts the load time of the function of the electronic device based on the information held by the holding means. The electronic device according to item 1, characterized in that the internal impedance of the corresponding battery pack is acquired.
(Item 3)
The control means, in the case where the difference between the first impedance value and the second impedance value is not smaller than the predetermined value,
When the first impedance value is smaller than the second impedance value Zbat, the first impedance value is corrected based on the impedance information held by the holding means, thereby reducing the load time of the function of the electronic device. The electronic device according to item 2, characterized in that the internal impedance of the battery pack corresponding to is acquired.
(Item 4)
The control means, in the case where the difference between the first impedance value and the second impedance value is not smaller than the predetermined value,
If the first impedance value is not smaller than the second impedance value, obtain the degree of deterioration of the battery pack, and if the degree of deterioration is greater than or equal to a predetermined threshold, obtain the degree of deterioration of the battery pack. The electronic device updates the impedance information held by the holding means with the impedance value acquired based on the first impedance value, and corrects the first impedance value based on the updated impedance information. The electronic device according to item 3, wherein the internal impedance of the battery pack corresponding to the load time of the function is acquired.
(Item 5)
5. The electronic device according to item 4, wherein the control means notifies the user that the battery pack has deteriorated when the degree of deterioration is greater than or equal to the predetermined threshold.
(Item 6)
The electronic device according to item 4, wherein the control means determines the state of the battery pack when the degree of deterioration is not equal to or higher than the predetermined threshold, and controls the operation of the electronic device based on the determination result. device.
(Item 7)
The control means is configured to reduce the voltage of the battery pack to a threshold value by causing a current to flow through a load for realizing the function, before using the function, based on the acquired internal impedance of the battery pack. The electronic device according to any one of items 1 to 6, wherein the electronic device according to any one of items 1 to 6 is configured to control the battery pack so as not to execute the function if it is determined that the voltage of the battery pack has decreased to a threshold value. device.
(Item 8)
The first acquisition means has a pseudo load means, and the amount of change in voltage and the current in the pseudo load means when a current is caused to flow from the battery pack for the predetermined load time to the pseudo load means. 8. The electronic device according to any one of items 1 to 7, wherein the first impedance value is acquired based on the amount of change in .
(Item 9)
The second acquisition means acquires the above-mentioned information based on the temperature detected by the temperature detection means, the impedance information held in the holding means, and the impedance value in the power supply path from the battery pack to the pseudo load means. The electronic device according to item 8, characterized in that the second impedance value is acquired.
(Item 10)
Control of an electronic device that uses a battery pack as a power source, which has a temperature detection means and a holding means that holds information for specifying the internal impedance of the battery pack with respect to the load time, which is the time when the load is energized, and the temperature. A method,
a first acquisition step of acquiring a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than a load time corresponding to the function;
a second acquisition step of acquiring a second impedance value corresponding to the predetermined load time based on the temperature detected by the temperature detection means and the impedance information held in the holding means;
The internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the first impedance value and the second impedance value, and the internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the acquired internal impedance. A control method for an electronic device, comprising: a control step for controlling execution.
(Item 11)
A program that, when read and executed by a computer, causes the computer to function as a means included in any one of the devices of items 1 to 9.

The invention is not limited to the embodiments described above, and various changes and modifications can be made without departing from the spirit and scope of the invention. Therefore, the following claims are hereby appended to disclose the scope of the invention.

DESCRIPTION OF SYMBOLS 100... Electronic device, 101... Control part, 102... Connection part, 103... State detection part, 104... Memory (load information of function), 105... Notification part to user, 200... Battery pack, 201... Control part, 202 ...Battery cell, 203...Temperature detection unit, 204...Memory (impedance information)

Claims (11)

An electronic device that uses a battery pack as a power source, which has a temperature detection means and a holding means for holding information for specifying the internal impedance of the battery pack with respect to the load time, which is the time during which the load is energized, and the internal impedance of the battery pack. hand,
a first acquisition means for acquiring a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than a load time corresponding to the function;
a second acquisition means for acquiring a second impedance value corresponding to the predetermined load time based on the temperature detected by the temperature detection means and the impedance information held in the holding means;
The internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the first impedance value and the second impedance value, and the internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the acquired internal impedance. An electronic device comprising: a control means for controlling execution; and a control means for controlling execution. When the difference between the first impedance value and the second impedance value is smaller than a predetermined value, the control means adjusts the load time of the function of the electronic device based on the information held by the holding means. The electronic device according to claim 1, wherein the internal impedance of the corresponding battery pack is acquired. The control means, in the case where the difference between the first impedance value and the second impedance value is not smaller than the predetermined value,
When the first impedance value is smaller than the second impedance value Zbat, the first impedance value is corrected based on the impedance information held by the holding means, thereby reducing the load time of the function of the electronic device. The electronic device according to claim 2, wherein an internal impedance of the battery pack corresponding to the internal impedance of the battery pack is acquired. The control means, in the case where the difference between the first impedance value and the second impedance value is not smaller than the predetermined value,
If the first impedance value is not smaller than the second impedance value, obtain the degree of deterioration of the battery pack, and if the degree of deterioration is greater than or equal to a predetermined threshold, obtain the degree of deterioration of the battery pack. The electronic device updates the impedance information held by the holding means with the impedance value acquired based on the first impedance value, and corrects the first impedance value based on the updated impedance information. The electronic device according to claim 3, wherein the internal impedance of the battery pack corresponding to the load time of the function is acquired. 5. The electronic device according to claim 4, wherein the control means notifies a user that the battery pack has deteriorated when the degree of deterioration is equal to or greater than the predetermined threshold. 5. The control means determines the state of the battery pack when the degree of deterioration is not equal to or greater than the predetermined threshold, and controls the operation of the electronic device based on the determination result. Electronics. The control means is configured to reduce the voltage of the battery pack to a threshold value by causing a current to flow through a load for realizing the function, before using the function, based on the acquired internal impedance of the battery pack. 7. The control apparatus according to any one of claims 1 to 6, wherein control is performed so as not to execute the function if it is determined that the voltage of the battery pack has decreased to a threshold value. Electronics. The first acquisition means has a pseudo load means, and the amount of change in voltage and the current in the pseudo load means when a current is caused to flow from the battery pack for the predetermined load time to the pseudo load means. The electronic device according to any one of claims 1 to 6, wherein the first impedance value is acquired based on the amount of change in . The second acquisition means acquires the above-mentioned information based on the temperature detected by the temperature detection means, the impedance information held in the holding means, and the impedance value in the power supply path from the battery pack to the pseudo load means. The electronic device according to claim 8, wherein a second impedance value is acquired. Control of an electronic device that uses a battery pack as a power source, which has a temperature detection means and a holding means that holds information for specifying the internal impedance of the battery pack with respect to the load time, which is the time when the load is energized, and the temperature. A method,
a first acquisition step of acquiring a first impedance value based on changes in current and voltage from the battery pack during a predetermined load time shorter than a load time corresponding to the function;
a second acquisition step of acquiring a second impedance value corresponding to the predetermined load time based on the temperature detected by the temperature detection means and the impedance information held in the holding means;
The internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the first impedance value and the second impedance value, and the internal impedance of the battery pack corresponding to the load time of the function of the electronic device is acquired based on the acquired internal impedance. A control method for an electronic device, comprising: a control step for controlling execution. A program for causing the computer to execute each step of the method according to claim 10, when the computer reads and executes the program.

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