JP5992282B2 - Electronic device, control program, and battery abnormality determination method - Google Patents

Description

  The present invention relates to a technique for determining an abnormality of a battery.

  Conventionally, various techniques for electronic devices have been proposed. For example, Patent Document 1 describes an electronic device to which a battery is detachably attached.

  Patent Documents 2 and 3 disclose a technique for charging a battery.

JP2012-135155A JP-A-6-290816 Japanese Patent No. 311545

  In an electronic device in which a battery is detachably attached as described in Patent Document 1, if there is an abnormality in the battery, it cannot operate normally. Therefore, it is desired that the electronic device can determine whether the battery attached to the electronic device is abnormal.

  Therefore, the present invention has been made in view of the above-described points, and an object of the present invention is to provide a technique by which an electronic device can determine an abnormality of a battery attached to the electronic device.

One aspect of the electronic device according to the present invention is an electronic device in which a battery is detachably attached, and an input terminal to which an output signal of a battery-side temperature detection unit built in the battery attached to the electronic device is input And based on the presence or absence of a correlation between the device-side temperature detection unit, the first temperature specified from the signal input to the input terminal, and the second temperature detected by the device-side temperature detection unit, A battery abnormality determination unit that determines abnormality of a battery attached to the electronic device; and a communication unit that communicates with a communication partner device; when the battery abnormality determination unit determines abnormality, the communication unit is control to you without any communication.

  In the electronic device according to the aspect of the invention, the battery abnormality determination unit may correlate the first temperature and the second temperature based on a difference between the first temperature and the second temperature. Determine the presence or absence.

Further, one aspect of the control program according to the present invention is a battery detachably attached, an input terminal to which an output signal of a temperature detector built in the attached battery is input , an apparatus-side temperature detector, A control program for controlling an electronic device having a communication unit that communicates with a communication partner device , wherein the electronic device includes: (a) a first temperature specified from a signal input to the input terminal; A step of determining whether or not there is a correlation with the second temperature detected by the device-side temperature detection unit; and (b) a battery attached to the electronic device based on the determination result in the step (a). A step of determining an abnormality, and (c) a step of controlling the communication unit to stop communication when it is determined to be abnormal in the step (b) .

Further, according to one aspect of the battery abnormality determination method according to the present invention, a battery is detachably attached, an input terminal to which an output signal of a temperature detection unit built in the attached battery is input, and a device-side temperature detection unit And a battery abnormality determination method in an electronic device having a communication unit that communicates with a communication partner device, wherein: (a) a first temperature specified from a signal input to the input terminal; and the device-side temperature detection Determining whether there is a correlation with the second temperature detected by the unit, and (b) determining an abnormality of the battery attached to the electronic device based on the determination result in the step (a). A step, and (c) a step of controlling the communication unit and disabling communication when it is determined to be abnormal in the step (b) .

  ADVANTAGE OF THE INVENTION According to this invention, the said electronic device can determine abnormality of the battery attached to the electronic device.

It is a perspective view which shows the general | schematic external appearance of an electronic device. It is a figure which shows the structure of a battery. It is a figure which shows the structure of an electronic device. It is a figure which shows the structure of a power supply part. It is a figure which shows the charge control in an electronic device. It is a figure which shows the characteristic of the temperature detection part in a battery. It is a flowchart which shows operation | movement of an electronic device. It is a figure which shows the structure of a part of modification of an electronic device. It is a figure which shows an example of the calculation method of the change rate of 1st and 2nd temperature.

  FIG. 1 is a perspective view showing a schematic appearance of an electronic device 100 according to an embodiment. Electronic device 100 according to the present embodiment is, for example, a mobile phone, and has a substantially rectangular plate shape in plan view. A display surface 4 a on which various information is displayed is formed on the surface of the electronic device 100. A battery 200 called a “battery pack” is detachably attached to the back side of the electronic device 100. Hereinafter, the battery 200 is referred to as a “battery pack 200”.

  A charger 300 is connected to the electronic device 100. The charger 300 converts an AC voltage supplied from a commercial power source or a DC voltage supplied from a DC power source into a predetermined DC voltage and outputs the same. Thereby, the electronic device 100 can also correspond to a car adapter or a mobile battery. The DC voltage output from the charger 300 is, for example, 5V. The charger 300 is provided with a connection terminal 301 from which the generated DC voltage is output. The connection terminal 301 is connected to a connection terminal 8 described later included in the electronic device 100. As a result, a DC output voltage from the charger 300 is supplied to the electronic device 100. The connection terminal 301 has a plus terminal that outputs a DC output potential (plus potential) and a minus terminal that is grounded.

  FIG. 2 is a diagram showing a configuration of the battery pack 200. The battery pack 200 is a secondary battery that can be repeatedly charged and discharged, for example, a lithium ion battery, for example. The battery pack 200 includes a chargeable / dischargeable battery cell 201, a temperature detection unit 202 that detects the temperature of the battery pack 200, and a protection circuit 203. The battery pack 200 further includes a positive terminal 204a connected to the positive electrode of the battery cell 201, a negative terminal 204b connected to the negative electrode of the battery cell 201 and grounded, a temperature output terminal 204c, and a battery case 205. ing. The battery cell 201, the temperature detection unit 202, the protection circuit 203, the plus terminal 204a, the minus terminal 204b, and the temperature output terminal 204c are housed in a battery case 205. Further, the plus terminal 204a, the minus terminal 204b, and the temperature output terminal 204c are partially exposed from the battery case 205.

  The temperature detection unit 202 includes, for example, a thermistor whose resistance value changes according to temperature. The temperature detection unit 202 outputs a potential corresponding to the resistance value of the thermistor to the temperature output terminal 204 c as a battery temperature detection signal indicating the temperature of the battery pack 200.

  The protection circuit 203 is a circuit for protecting the battery cell 201. The protection circuit 203 detects the current flowing through the battery cell 201 and prevents the overcurrent from flowing through the battery cell 201 based on the detection result.

  FIG. 3 is a diagram illustrating an electrical configuration of the electronic device 100. As illustrated in FIG. 3, the electronic device 100 includes a system unit 1, a power supply unit 2 that supplies a power supply potential to the system unit 1, an operation unit 3, a display unit 4, a microphone 5, and a speaker 6. The imaging unit 7 is provided. Furthermore, the electronic device 100 includes a connection terminal 8 connected to the connection terminal 301 of the charger 300, a battery side positive terminal 9a, a battery side negative terminal 9b, and a temperature input terminal 9c.

  The system unit 1 controls the wireless processing unit 10 that performs wireless communication with a communication partner device such as a base station, and each element that configures the electronic device 100, and performs system control that comprehensively manages the operation of the electronic device 100. Part 11.

  The system control unit 11 includes a CPU (Central Processing Unit) 12, a DSP (Digital Signal Processor) 13, a storage unit 14, and the like. The storage unit 14 includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The storage unit 14 includes a main program 15 that is a control program for controlling the operation of the electronic device 100, specifically, the wireless processing unit 10 and the display unit 4 included in the electronic device 100, and a plurality of applications. A program 16 and the like are stored. In the storage unit 14, as the application program 16, for example, a voice call application program for performing a voice call, a browser for displaying a website, a mail application program for creating, browsing, and transmitting / receiving an e-mail, etc. It is remembered. Various functions of the system control unit 11 are realized by the CPU 12 and the DSP 13 executing various programs in the storage unit 14. In FIG. 3, only one of the plurality of application programs 16 stored in the storage unit 14 is shown in order to avoid the complexity of the drawing.

  The wireless processing unit 10 is connected to the antenna 17. The wireless processing unit 10 performs amplification processing and down-conversion on the reception signal received by the antenna 17 and outputs the result to the system control unit 11. The system control unit 11 performs demodulation processing or the like on the input reception signal and acquires various data included in the reception signal. The wireless processing unit 10 performs up-conversion and amplification processing on the transmission signal including various data generated by the system control unit 11 and wirelessly transmits the processed transmission signal from the antenna 17.

  The operation unit 3 includes a plurality of operation keys operated by the user. The plurality of operation keys include a power button. When the operation key is operated, the operation unit notifies the system control unit 11 to that effect. The display unit 4 includes, for example, a liquid crystal display panel or an organic EL panel. The display unit 4 has a display surface 4a shown in FIG. 1, and is controlled by the system control unit 11 to display various information such as characters, symbols, and figures on the display surface 4a. The display unit 4 has a touch panel function in addition to the display function. The display unit 4 detects a user operation on the display surface 4 a and outputs the detection result to the system control unit 11.

  The microphone 5 converts sound input from the outside of the electronic device 100 into an electrical sound signal and outputs the electrical sound signal to the system control unit 11. The speaker 6 converts an electrical sound signal from the system control unit 11 into sound and outputs the sound. The imaging unit 7 captures still images and moving images based on control by the system control unit 11. The still image and the moving image captured by the imaging unit 7 are input to the system control unit 11.

  The connection terminal 8 includes a charger-side plus terminal 8a and a charger-side minus terminal 8b that are respectively connected to the plus terminal and the minus terminal of the connection terminal 301 of the charger 300. The charger-side negative terminal 8 b is grounded by being connected to the ground conductor pattern of the electronic device 100.

  When the battery pack 200 is attached to the electronic device 100, the battery side plus terminal 9a, the battery side minus terminal 9b, and the temperature input terminal 9c are connected to the plus terminal 204a, the minus terminal 204b, and the temperature output terminal 204c of the battery pack 200, respectively. Is done. Therefore, when the battery pack 200 is attached to the electronic device 100, the output signal of the temperature detection unit 202 of the battery pack 200, that is, the battery temperature detection signal is input to the temperature input terminal 9c. The battery side negative terminal 9 b is grounded by being connected to the ground conductor pattern of the electronic device 100.

  FIG. 4 is a diagram showing the configuration of the power supply unit 2. As shown in FIG. 4, the power supply unit 2 includes a first control unit 21, a second control unit 22, and an A / D converter 23. In the power supply unit 2, the first control unit 21 and the second control unit 22 are attached to the electronic device 100 based on the power supplied from the outside of the electronic device 100, that is, the power supplied from the charger 300. A charging unit 20 that charges the battery pack 200 is configured.

  The first control unit 21 controls the connection between the charger-side positive terminal 8 a, the second control unit 22, and the system unit 1. The first control unit 21 enters the connection operation state when the connection terminal 301 of the charger 300 is connected to the connection terminal 8, in other words, when the output voltage of the charger 300 is input to the connection terminal 8. Thus, the output potential from the charger 300 input to the charger side positive terminal 8a is stepped down and supplied to the second controller 22 and the system unit 1. When the output potential of the first control unit 21 is supplied, the system unit 1 operates using the output potential as a power supply potential. On the other hand, when the connection terminal 301 of the charger 300 is not connected to the connection terminal 8, in other words, the first control unit 21 does not input the output voltage of the charger 300 to the connection terminal 8. In such a case, the unconnected operation state is established, and the charger side positive terminal 8a, the second control unit 22, and the system unit 1 are not connected. The first control unit 21 can adjust the output potential under the control of the system control unit 11.

  The second control unit 22 controls connection between the battery side positive terminal 9 a and the system unit 1. When the 2nd control part 22 will be in a connection operation state, the battery side plus terminal 9a and the system part 1 will be connected. On the other hand, when the 2nd control part 22 will be in an unconnected operation state, battery side plus terminal 9a and system part 1 will be unconnected. When the battery pack 200 is attached to the electronic device 100, the second control unit 22 enters the connection operation state when the power is turned on by the power button included in the operation unit 3 in the unconnected operation state. When the power button is turned off by the power button in the connection operation state, the connection operation state is established.

  The A / D converter 23 converts the potential (analog value) at the charger side positive terminal 8a into a digital value and outputs the digital value to the system unit 1. Thereby, the system part 1 can recognize the value of the electric potential in the charger side plus terminal 8a. The A / D converter 23 converts the potential (analog value) at the battery side positive terminal 9 a into a digital value and outputs the digital value to the system unit 1. Thereby, the system part 1 can recognize the value of the electric potential in the battery side plus terminal 9a. Then, the A / D converter 23 converts the signal input to the temperature input terminal 9 c, that is, the battery temperature detection signal output from the battery pack 200 from the analog format to the digital format and outputs the converted signal to the system unit 1. As a result, the battery temperature detection signal in digital form is input to the system unit 1. A battery abnormality determination unit 110 provided in the system unit 1 determines abnormality of the battery pack 200 based on a digital battery temperature detection signal output from the A / D converter 23. The battery abnormality determination unit 110 is a functional block formed in the system control unit 11 when the CPU 12 of the system control unit 11 executes the main program 15 in the storage unit 14. The operation of the battery abnormality determination unit 110 will be described in detail later.

<Charging and discharging the battery pack>
Next, charging and discharging of the battery pack 200 will be described. When the charger 300 is connected to the electronic device 100, the charging unit 20 of the power supply unit 2 charges the battery pack 200 based on the power supplied from the charger 300.

  When the connection terminal 301 of the charger 300 is connected to the connection terminal 8 of the electronic device 100, the first control unit 21 enters the connection operation state. Then, the first control unit 21 steps down the output potential from the charger 300 and supplies it to the second control unit 22 and the system unit 1. When the output potential from the first control unit 21 is supplied (see the dashed line 500 in FIG. 4), the system unit 1 operates using the output potential as a power supply potential.

  When the system control unit 11 of the system unit 1 determines that the potential of the charger-side positive terminal 8a is greater than a predetermined value based on the output signal of the A / D converter 23, the charger 300 is connected to the electronic device 100. If it is determined that the second control unit 22 is connected, the second control unit 22 is controlled to set the second control unit 22 in the connected operation state. As a result, the first control unit 21 and the second control unit 22 are both in the connection operation state, and the output potential of the first control unit 21 is transmitted through the second control unit 22 as indicated by a broken line 501 in FIG. It is supplied to the battery side positive terminal 9a. The output potential of the first control unit 21 supplied to the battery side positive terminal 9 a is supplied to the battery cell 201 through the positive terminal 204 a of the battery pack 200. Thereby, the battery cell 201 is charged. When the battery cell 201 is charged, the output potential output from the first control unit 21 becomes the charging potential applied to the positive electrode of the battery cell 201.

  When the connection terminal 301 of the charger 300 is not connected to the connection terminal 8 of the electronic device 100, the first control unit 21 enters an unconnected operation state. Then, the output potential of the charger 300 is not output from the first control unit 21, and the output potential of the charger 300 is not supplied to the battery cell 201 of the battery pack 200. Thereby, the charge with respect to the battery cell 201 is complete | finished.

  When the charger 300 is not connected to the electronic device 100, the output potential of the battery cell 201 (the potential of the positive electrode of the battery cell 201) is changed between the plus terminal 204a of the battery pack 200 and the electronic device as shown by a one-dot chain line 510 in FIG. The power is supplied to the system unit 1 through the battery-side positive terminal 9a of the device 100 and the second control unit 22 in the connection operation state. The system unit 1 operates using the output potential of the battery cell 201 as a power supply potential. Thereby, the battery cell 201 is discharged.

  Further, in electronic device 100 according to the present embodiment, when charger 300 is connected to electronic device 100, charging of battery pack 200 is controlled based on the temperature of battery pack 200. FIG. 5 is a diagram for explaining charging control in the electronic device 100. The horizontal axis in FIG. 5 indicates the temperature of the battery pack 200, and the vertical axis in FIG. 5 indicates the output potential of the first control unit 21 when the battery pack 200 is charged, that is, the charging potential.

  As shown in FIG. 5, the electronic device 100 is configured to charge the battery pack 200 only when the temperature of the battery pack 200 is 0 ° C. or higher and 50 ° C. or lower. When the battery pack 200 is being charged, the system control unit 11 has a temperature (temperature of the battery pack 200) specified from the digital battery temperature detection signal output from the A / D converter 23 being 0. When the temperature is less than 0 ° C., the second control unit 22 is controlled to place the second control unit 22 in an unconnected operation state. Thereby, the output potential of the first control unit 21 is not supplied to the battery cell 201, and charging of the battery cell 201 is stopped. Further, when the system control unit 11 is charging the battery pack 200, the second temperature control unit 11 determines that the temperature specified from the battery temperature detection signal output from the A / D converter 23 is higher than 50 ° C. The controller 22 is controlled to place the second controller 22 in an unconnected operation state. Thereby, the charge with respect to the battery cell 201 stops.

  In addition, electronic device 100 according to the present embodiment sets the charging potential to, for example, 4.2 V when the temperature of battery pack 200 is 10 ° C. or higher and 45 ° C. or lower. The electronic device 100 sets the charging potential to 4.1 V, for example, when the temperature of the battery pack 200 is 0 ° C. or higher and lower than 10 ° C. or higher than 45 ° C. and lower than 50 ° C. When the temperature specified from the battery temperature detection signal output from the A / D converter 23 is 10 ° C. or higher and 45 ° C. or lower, the system control unit 11 controls the first control unit 21 to perform the first control. The unit 21 causes the output potential of the charger 300 (5 V in this example) to be stepped down to 4.2 V and output. Thereby, 4.2V is applied to the positive electrode of the battery cell 201 as a charging potential. In addition, the system control unit 11 determines whether the temperature specified from the battery temperature detection signal output from the A / D converter 23 is 0 ° C. or more and less than 10 ° C. or greater than 45 ° C. and 50 ° C. The first control unit 21 is controlled to cause the first control unit 21 to step down the output potential of the charger 300 to 4.1 V and output it. Thereby, 4.1V is applied to the positive electrode of the battery cell 201 as a charging potential.

  As described above, in electronic device 100 according to the present embodiment, since charging of battery pack 200 is controlled based on the temperature of battery pack 200, the temperature of battery pack 200 is in a range not suitable for charging. In addition, the charging of the battery pack 200 can be stopped and the battery pack 200 can be charged at a charging potential suitable for the temperature of the battery pack 200.

  In the present embodiment, electronic device 100 stops discharging battery pack 200 when the temperature of battery pack 200 reaches 68 ° C. or higher while battery pack 200 is discharging. The system control unit 11 specifies the battery temperature detection signal output from the A / D converter 23 when the battery pack 200 is discharged, in other words, when the charger 300 is not connected to the electronic device 100. When the temperature to be reached is 68 ° C. or higher, the second control unit 22 is controlled to bring the second control unit 22 into an unconnected operation state. As a result, the output potential from the plus terminal 204a of the battery pack 200 is not supplied to the system unit 1, and the discharge of the battery cell 201 is stopped. At this time, the electronic device 100 is shut down.

  Thus, when the temperature of the battery pack 200 becomes high, it is possible to prevent the battery pack 200 from being broken by stopping the discharge of the battery pack 200.

<About battery abnormality determination>
FIG. 6 is a diagram illustrating an example of temperature characteristics of the resistance value of the thermistor provided in the temperature detection unit 202 of the electronic device 100. 6 indicates the temperature of the thermistor included in the temperature detection unit 202, and the vertical axis in FIG. 6 indicates the resistance value indicated by the thermistor.

  As shown in FIG. 6, in the thermistor included in the temperature detection unit 202 according to the present embodiment, the resistance value decreases as the temperature increases. Therefore, the potential of the temperature output terminal 204c changes according to the temperature of the battery pack 200. As a result, the potential of the temperature input terminal 9 c of the electronic device 100, that is, the signal input to the temperature input terminal 9 c changes according to the temperature of the battery pack 200.

  Thus, when a normal battery pack 200 is attached to the electronic device 100, a signal input to the temperature input terminal 9c changes according to the temperature of the battery pack 200. The system control unit 11 of the electronic device 100 stores temperature characteristic information indicating the temperature characteristic shown in FIG. The system control unit 11 specifies the temperature of the battery pack 200 from the digital battery temperature detection signal output from the A / D converter 23 using the temperature characteristic information.

  On the other hand, an abnormal battery pack 200 may be attached to the electronic device 100 so that a signal input to the temperature input terminal 9c of the electronic device 100 hardly changes. For example, when an unauthorized battery pack 200 in which a fixed resistance element having a constant resistance value is used instead of the thermistor in the temperature detection unit 202 is attached to the electronic device 100, the signal input to the temperature input terminal 9c is Almost no change. In such a case, the system control unit 11 cannot specify the exact temperature of the battery pack 200 based on the signal input to the temperature input terminal 9c.

  Even when a normal battery pack 200 is attached to the electronic device 100, the temperature detection unit 202 of the battery pack 200 fails and the signal input to the temperature input terminal 9c is almost changed. The battery pack 200 attached to the electronic device 100 may become abnormal from normal. Even in such a case, the system control unit 11 cannot specify the accurate temperature of the battery pack 200.

  As described above, when the battery pack 200 attached to the electronic device 100 is abnormal and the signal input to the temperature input terminal 9c of the electronic device 100 hardly changes, the electronic device 100 determines that the temperature of the battery pack 200 is low. Cannot be specified accurately. Therefore, in this case, it is necessary to stop the charging of the battery pack 200 or to shut down the electronic device 100 and stop the discharging of the battery pack 200.

  Therefore, in electronic device 100 according to the present embodiment, battery abnormality determination unit 110 of system control unit 11 provides electronic device 100 with a change in temperature specified from a signal input to temperature input terminal 9c. An abnormality of the attached battery pack 200 is determined. When the battery abnormality determination unit 110 determines that the battery pack 200 is abnormal, the electronic device 100 stops charging or shuts down the battery pack 200. This point will be described in detail below.

  FIG. 7 is a flowchart illustrating the operation of the electronic device 100 when the abnormality determination of the battery pack 200 is performed in the electronic device 100 while the battery pack 200 is being charged. As shown in FIG. 7, when the charger 300 is connected in the electronic device 100 in step s1 and the charging unit 20 starts charging the battery pack 200, the battery abnormality determination unit 110 in step s2 The amount of change in temperature specified from the input signal (hereinafter referred to as “temperature terminal signal”) of the digital temperature input terminal 9c output from the D converter 23 is obtained. Specifically, the battery abnormality determination unit 110 calculates the absolute value of the difference between the temperature specified from the temperature terminal signal at a certain time and the temperature specified from the temperature terminal signal at a later time than the certain time. This absolute value is used as the temperature change amount specified from the temperature terminal signal. Hereinafter, this amount of change is referred to as “battery temperature change amount”.

  If step s2 is performed, in step s3, the battery abnormality determination part 110 will determine whether the calculated | required battery temperature variation | change_quantity is below a threshold value. In step s3, if the battery temperature change amount is larger than the threshold value, battery abnormality determination unit 110 determines that battery pack 200 is normal in step s4. When charging of the battery pack 200 is started, the temperature of the battery pack 200 rises. Therefore, if the battery pack 200 is normal, the battery temperature change amount obtained in step s2 becomes large. Therefore, when the battery temperature change amount is larger than a threshold value (for example, 1 ° C.) in step s3, battery abnormality determination unit 110 determines that battery pack 200 is normal.

  On the other hand, when the battery temperature change amount is equal to or smaller than the threshold value in step s3, that is, when the temperature specified from the temperature terminal signal hardly changes, the battery abnormality determination unit 110 determines in step s5 that The battery pack 200 is determined to be abnormal. If it is determined in step s5 that the battery pack 200 is abnormal, the system control unit 11 controls the second control unit 22 to place the second control unit 22 in a disconnected operation state. Thereby, the output potential of the first control unit 21 is not supplied to the battery cell 201 of the battery pack 200, and charging of the battery pack 200 is stopped.

  After that, when the charger 300 is not connected to the electronic device 100, the first control unit 21 enters an unconnected operation state. Thereby, the power supply potential is not supplied to the system unit 1 and the electronic device 100 is shut down. Thereafter, when the power is turned on by the power button included in the operation unit 3, the second control unit 22 enters the connection operation state, and the output potential from the second control unit 22 is supplied to the system unit 1 as the power supply potential. Is done.

  Thus, when an abnormality of the battery pack 200, more specifically, an abnormality of the temperature detection function of the battery pack 200 is detected during the charging of the battery pack 200, the charging of the battery pack 200 is stopped. Even though the actual temperature of the battery pack 200 is low (less than 0 ° C.) or high (greater than 50 ° C.), the battery pack 200 can be prevented from being charged. Therefore, the occurrence of failure of the battery pack 200 can be suppressed.

  When an abnormality of the battery pack 200 is detected, charging of the battery 200 may be stopped and some functions of the electronic device 100 may be stopped. For example, the system control unit 11 may control the wireless processing unit 10 so that the wireless processing unit 10 does not perform wireless communication. Further, the system control unit 11 may control the display unit 4 to turn off the display of the display unit 4.

  In the example of FIG. 7 described above, the abnormality of the battery pack 200 is determined during the charging of the battery pack 200. However, when the charger 300 is not connected to the battery pack 200, that is, during the discharging of the battery pack 200. An abnormality of the battery pack 200 may be determined.

  For example, the battery abnormality determination unit 110 obtains the battery temperature change amount when the wireless processing unit 10 is performing wireless communication with a communication counterpart device such as a base station while the battery pack 200 is being discharged. Then, battery abnormality determination unit 110 determines whether the obtained battery temperature change amount is equal to or less than a threshold value. The battery abnormality determination unit 110 determines that the battery pack 200 is normal when the battery temperature change amount is larger than the threshold value. When the wireless processing unit 10 performs wireless communication, the temperature of the battery pack 200 rises due to the influence of heat generated in the wireless processing unit 10, so that if the battery pack 200 is normal, the battery temperature changes The amount gets bigger. Therefore, battery abnormality determination unit 110 determines that battery pack 200 is normal when the battery temperature change amount is larger than a threshold value (for example, 1 ° C.).

  On the other hand, the battery abnormality determination unit 110 determines that the battery pack 200 is abnormal when the battery temperature change amount is equal to or less than the threshold value. If the battery abnormality determination unit 110 determines that the battery pack 200 is abnormal, the system control unit 11 controls the second control unit 22 to place the second control unit 22 in a disconnected operation state. Thereby, the power supply potential is not supplied to the system unit 1 and the electronic device 100 is shut down. Therefore, the discharge of the battery pack 200 is stopped.

  Thereafter, when the charger 300 is connected to the electronic device 100, the first control unit 21 enters the connection operation state, and the output potential of the first control unit 21 is supplied to the system unit 1 as a power supply potential. Alternatively, when the power is turned on by the power button included in the operation unit 3, the second control unit 22 enters the connection operation state, and the output potential from the second control unit 22 is supplied to the system unit 1 as the power supply potential. .

  Thus, when an abnormality of the battery pack 200 is detected during the discharge of the battery pack 200, the actual temperature of the battery pack 200 is extremely high (68) by stopping the discharge of the battery pack 200. However, the battery pack 200 can be prevented from being discharged. Therefore, the occurrence of failure of the battery pack 200 can be suppressed.

  As described above, in electronic device 100 according to the present embodiment, battery abnormality determination unit 110 that determines abnormality of battery pack 200 based on the amount of change in temperature specified from the signal input to temperature input terminal 9c. Therefore, when an unauthorized battery pack 200 having an abnormal temperature detection function, such as a fixed resistance element used in the temperature detection unit 202, is attached to the electronic device 100, the electronic device 100 can appropriately detect abnormality of the battery pack 200. Further, even when the temperature detection unit 202 of the battery pack 200 fails and the temperature detection function of the battery pack 200 becomes abnormal, the electronic device 100 can appropriately detect the abnormality of the battery pack 200. Therefore, it is possible to suppress the electronic device 100 from operating based on an erroneously detected temperature for the battery pack 200.

  In the above example, the battery abnormality determination unit 110 determines the abnormality of the battery pack 200 when the electronic device 100 is performing a predetermined process such as a charging operation or wireless communication. For example, the abnormality of the battery pack 200 may be determined once per hour.

<Modification>
FIG. 8 is a diagram showing a part of the configuration of a modified example of electronic apparatus 100 according to the present embodiment. As shown in FIG. 8, the electronic device 100 according to this modification is further provided with a temperature detection unit 120 that detects the temperature of the electronic device 100. The temperature detection unit 120 includes, for example, a thermistor whose resistance value changes according to temperature. The temperature detection unit 120 outputs a potential corresponding to the resistance value of the thermistor to the A / D converter 23 as a device temperature detection signal. The A / D converter 23 converts the device temperature detection signal output from the temperature detection unit 120 from an analog format to a digital format and outputs the converted signal to the system unit 1. For example, the temperature detection unit 120 is disposed in the vicinity of the power amplifier included in the wireless processing unit 10.

  The battery abnormality determination unit 110 according to the present modification includes an abnormality of the battery pack 200 attached to the electronic device 100 based on the temperature terminal signal and the digital device temperature detection signal output from the A / D converter 23. Determine. Hereinafter, battery abnormality determination processing in the electronic apparatus 100 according to the present modification will be described.

  Since the battery pack 200 is attached to the electronic device 100, there is a correlation between the temperature of the battery pack 200 and the temperature of the electronic device 100. For example, when the temperature of the battery pack 200 is 20 ° C., the temperature of the electronic device 100 becomes a value close to 20 ° C. Further, when the electronic device 100 generates heat by performing wireless communication or the like, the temperature of the electronic device 100 rises, and the temperature of the battery pack 200 rises due to the influence of heat generation in the electronic device 100.

  Thus, since there is a correlation between the temperature of the battery pack 200 and the temperature of the electronic device 100, if the battery pack 200 is normal, the temperature detected by the temperature detection unit 202 of the battery pack 200, There is a correlation between the temperature detected by the temperature detection unit 120 of the electronic device 100.

  Therefore, the battery abnormality determination unit 110 according to the present modification includes a temperature (hereinafter referred to as “first temperature”) specified from the temperature terminal signal (signal input to the temperature input terminal 9c), and an A / D converter. 23, based on the presence or absence of a correlation with the temperature specified by the digital device temperature detection signal output from 23, that is, the temperature detected by the temperature detection unit 120 (hereinafter referred to as “second temperature”), The abnormality of the battery pack 200 is determined. Specifically, the battery abnormality determination unit 110 determines whether there is a correlation between the first temperature and the second temperature, and determines that there is a correlation between the first temperature and the second temperature. It is determined that the pack 200 is normal. On the other hand, when battery abnormality determination unit 110 determines that there is no correlation between the first temperature and the second temperature, it determines that battery pack 200 is abnormal. In the electronic device 100 according to this modification, such a battery abnormality determination process is periodically performed. For example, the battery abnormality determination process is performed once per hour.

  Note that the battery abnormality determination unit 110 determines whether or not there is a correlation between the first temperature and the second temperature a plurality of times, and continuously determines that there is no correlation between the first temperature and the second temperature. Only when the number of times is determined, the battery pack 200 may be determined to be abnormal.

  As described above, the abnormality of the battery pack 200 can be appropriately determined by determining the abnormality of the battery pack 200 based on the presence or absence of the correlation between the first temperature and the second temperature.

  When it is determined that the battery pack 200 is abnormal as a result of the determination of the abnormality of the battery pack 200 during charging of the battery pack 200, the system control unit 11 controls the second control unit 22 as described above. Thus, the second control unit 22 is set to the disconnected operation state. Thereby, the output potential of the first control unit 21 is not supplied to the battery cell 201, and the charging of the battery pack 200 is stopped. The subsequent operation of the electronic device 100 is the same as described above.

  Further, when it is determined that the battery pack 200 is abnormal as a result of the determination of the abnormality of the battery pack 200 during the discharge of the battery pack 200, the system control unit 11 controls the second control unit 22 to 2 The control unit 22 is set in a non-connection operation state. Thereby, the power supply potential is not supplied to the system unit 1 and the electronic device 100 is shut down. Therefore, the discharge of the battery pack 200 is stopped. The subsequent operation of the electronic device 100 is the same as described above.

<Method for determining the presence or absence of correlation>
Next, a method for determining whether or not there is a correlation between the first temperature and the second temperature will be described. Here, two determination methods will be described.

<First judgment method>
In the first determination method, whether or not there is a correlation between the first temperature and the second temperature is determined based on a difference between the first temperature and the second temperature. Specifically, the battery abnormality determination unit 110 acquires the first temperature and the second temperature at the same time based on the temperature terminal signal and the device temperature detection signal output from the A / D converter 23. Then, the battery abnormality determination unit 110 obtains the absolute value of the difference between the acquired first temperature and second temperature, and determines whether the absolute value is smaller than the threshold value.

  The battery abnormality determination unit 110 determines that there is a correlation between the first temperature and the second temperature when the obtained absolute value is smaller than the threshold value. When the battery pack 200 is normal, since the absolute value of the difference between the temperature detected by the battery pack 200 and the temperature detected by the electronic device 100 is small, the battery abnormality determination unit 110 performs the same operation at the same time. When the absolute value of the difference between the first temperature and the second temperature is smaller than a threshold value (for example, 10 ° C.), it is determined that there is a correlation between the first temperature and the second temperature. On the other hand, the battery abnormality determining unit 110 determines that there is no correlation between the first temperature and the second temperature when the obtained absolute value is equal to or greater than the threshold value.

  As described above, the abnormality of the battery pack 200 is determined by determining the presence or absence of the correlation between the two based on the difference between the first temperature and the second temperature and determining the abnormality of the battery pack 200 based on the determination result. Can be accurately determined.

<Second determination method>
In the second determination method, the presence / absence of a correlation between the first temperature and the second temperature is determined based on the ratio between the change rate of the first temperature and the change rate of the second temperature. Specifically, the battery abnormality determination unit 110 first obtains the first and second temperature change rates at the same time based on the temperature terminal signal and the device temperature detection signal output from the A / D converter 23. . Here, the change rate of the first temperature is α1, and the change rate of the second temperature is α2.

  Next, the battery abnormality determination unit 110 obtains the absolute value β of the ratio between the change rate α1 of the first temperature and the change rate α2 of the second temperature at the same time. The absolute value β is expressed by the following formula (1), for example.

β = | α2 / α1 | (1)
Next, the battery abnormality determination unit 110 determines whether or not the absolute value β satisfies the following expression (2).

R1 <β <R2 (2)
However, R1 and R2 of Formula (2) are constants, and R1 <R2.

  The battery abnormality determination unit 110 determines that there is a correlation between the first temperature and the second temperature when the absolute value β satisfies Expression (2). When the battery pack 200 is normal, the temperature detected by the battery pack 200 and the temperature detected by the electronic device 100 change in the same manner, so that the change rate α1 of the first temperature and the second temperature The absolute value β of the ratio with the change rate α2 falls within a predetermined range. Therefore, the battery abnormality determination unit 110 determines that there is a correlation between the first temperature and the second temperature when the absolute value β satisfies Expression (2).

  Note that the rate of change in temperature detected by the normal battery pack 200 and the rate of change in temperature detected by the electronic device 100 in accordance with the positional relationship between the battery pack 200 and the temperature detection unit 120 of the electronic device 100. The constants R1 and R2 depend on the positional relationship between the battery pack 200 and the temperature detection unit 120 of the electronic device 100.

  FIG. 9 is a diagram for explaining an example of a method for calculating the change rate α1 of the first temperature and the change rate α2 of the second temperature. Graphs 501 and 502 in FIG. 9 show examples of temporal changes in the first and second temperatures, respectively.

  In this example, the battery abnormality determination unit 110 changes the first temperature between time t and time (t + Δt) delayed by Δt as the change rate α1 of the first temperature at a certain time t. The amount ΔTe1 (see FIG. 9) is adopted. That is, the change rate α1 of the first temperature at time t is expressed by the following equation (3), where Te1a is the first temperature at time t and Te1b is the first temperature at time (t + Δt). .

α1 = ΔTe1 = Te1b−Te1a (3)
Similarly, the battery abnormality determination unit 110 changes the second temperature between time t and time (t + Δt) delayed by Δt as the second temperature change rate α2 at a certain time t. The quantity ΔTe2 is adopted. That is, the change rate α2 of the second temperature at time t is expressed by the following equation (4), where Te2a is the second temperature at time t and Te2b is the second temperature at time (t + Δt). .

α2 = ΔTe2 = Te2b−Te2a (4)
In this example, Equation (3) and Equation (4) are used to obtain the change rate α1 of the first temperature and the change rate α2 of the second temperature at the same time.

  Thus, based on the ratio between the change rate of the first temperature and the change rate of the second temperature, the presence or absence of a correlation between the first temperature and the second temperature is determined, and the battery pack is determined based on the determination result. By determining the abnormality of 200, the abnormality of the battery pack 200 can be accurately determined.

  In the second determination method, the abnormality determination of the battery pack 200 uses the rate of change of the first and second temperatures, so that the battery abnormality occurs in a situation where the temperature of the battery pack 200 and the electronic device 100 does not change. When the determination process is performed, there is a possibility that the abnormality of the battery pack 200 cannot be accurately determined.

  Therefore, when using the second determination method, the battery abnormality determination unit 110 desirably determines abnormality of the battery pack 200 in a situation where the temperatures of the battery pack 200 and the electronic device 100 change greatly. For example, the battery abnormality determination unit 110 determines an abnormality of the battery pack 200 when the battery pack 200 is charged, or determines an abnormality of the battery pack 200 when the wireless processing unit 10 performs wireless communication. Is desirable. Thereby, abnormality of the battery pack 200 can be determined more accurately.

  In addition, the battery abnormality determination unit 110 acquires the second temperature for each Δt, and when the difference between the two acquired second temperatures is equal to or greater than a predetermined value, that is, when the second temperature changes greatly, The abnormality of the battery pack 200 may be determined using the two second temperatures (Te2a and Te2b). Thus, since the battery abnormality determination process can be performed in a situation where the temperature of the battery pack 200 and the electronic device 100 is changing, the abnormality of the battery pack 200 can be determined more accurately.

  As described above, when the temperature detection unit 120 is disposed near the heat generating component such as the power amplifier of the wireless processing unit 10, the temperature of the heat generating component may be detected using the temperature detection unit 120. it can. In this case, the electronic device 100 may be shut down when the temperature detected by the temperature detection unit 120 becomes equal to or higher than a predetermined value, that is, when the temperature of the heat generating component becomes very high.

  Further, in the above example, the case where the present invention is applied to a mobile phone has been described as an example. However, the present invention is applicable to an electronic device other than a mobile phone as long as it is an electronic device that can be operated by a battery. Can be applied.

9c Temperature input terminal 10 Wireless processing unit 15 Main program 20 Charging unit 100 Electronic device 110 Battery abnormality determination unit 200 Battery 202 Temperature detection unit

Claims (4)

An electronic device to which a battery is detachably attached,
An input terminal to which an output signal of a battery side temperature detection unit built in a battery attached to the electronic device is input;
A device side temperature detector,
Based on the presence or absence of correlation between the first temperature specified from the signal input to the input terminal and the second temperature detected by the device-side temperature detection unit, the battery attached to the electronic device A battery abnormality determination unit for determining abnormality;
A communication unit for communicating with a communication partner device,
An electronic device that controls the communication unit to stop communication when the battery abnormality determination unit determines that there is an abnormality. The electronic device according to claim 1 ,
The battery abnormality determination unit is an electronic device that determines whether or not there is a correlation between the first temperature and the second temperature based on a difference between the first temperature and the second temperature. An electronic device having an input terminal to which an output signal of a temperature detection unit built in the attached battery is input, an apparatus side temperature detection unit, and a communication unit that communicates with a communication partner device. A control program for controlling
In the electronic device,
(A) determining whether or not there is a correlation between a first temperature specified from a signal input to the input terminal and a second temperature detected by the device-side temperature detection unit;
(B) based on the determination result in the step (a), determining the abnormality of the battery attached to the electronic device;
(C) A control program for executing the step of controlling the communication unit and disabling communication when it is determined to be abnormal in the step (b). An electronic device having an input terminal to which an output signal of a temperature detection unit built in the attached battery is input, an apparatus side temperature detection unit, and a communication unit that communicates with a communication partner device. A battery abnormality determination method at
(A) determining whether or not there is a correlation between a first temperature specified from a signal input to the input terminal and a second temperature detected by the device-side temperature detection unit;
(B) based on the determination result in the step (a), determining the abnormality of the battery attached to the electronic device;
(C) A battery abnormality determination method comprising: a step of controlling the communication unit and disabling communication when it is determined as abnormal in the step (b).

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