JPWO2010092994A1 - Information processing device - Google Patents

Abstract

After the temperature sensor measures the high temperature above the first threshold and prompts the application end operation related to the heat source (step S11-1b), the temperature sensor causes the high temperature above the second threshold to exceed the first threshold. Is measured (“second threshold or higher” in step S11-1c), a display notifying the end of the application is performed (step S11-1m), and the apparatus is rebooted (step S11-1o).

Description

  The present invention relates to an information processing apparatus, and more particularly, to processing for suppressing a temperature rise of the apparatus.

  High-functionality and high-performance of parts of devices intended for high-performance and high-performance of small information processing devices such as mobile communication devices are remarkable. As a result, it is impossible to ignore the possibility that the component malfunctions due to the temperature rise, and that the user of the apparatus feels unpleasant as a result of the malfunction. Here, the temperature rise of a part may be caused by heat generation of the part, heat generation of parts arranged around the part, or high outside air temperature.

  Therefore, in order to suppress the temperature rise of the part, when a temperature sensor is installed near the part (for example, camera) whose temperature rises due to the execution of the application, and the temperature sensor detects a temperature above a predetermined threshold A process is known in which all the operations of the application or only the operation that consumes a large amount of power is stopped (for example, see Patent Document 1).

  A temperature sensor is installed near the rechargeable battery. When the temperature sensor detects a temperature that is equal to or higher than a predetermined threshold, it is possible to execute a process for stopping power supply or charging, or a process for reducing power supply or charging current. Are known. Furthermore, a temperature sensor is installed near the CPU. Then, when the temperature sensor detects a temperature equal to or higher than a predetermined threshold, a process for reducing the CPU power consumption by reducing the operation clock of the CPU is known (see, for example, Patent Document 2). .)

JP 2007-28425 A (page 1-2, FIG. 3, FIG. 4) Japanese Patent Laying-Open No. 2003-223937 (pages 3, 9 and 9)

  However, in the method disclosed in Patent Document 1 described above, there is a possibility that the temperature of the component does not decrease even when control for stopping all operations of the application is performed. Further, in the method disclosed in Patent Document 2 described above, even if control is performed to reduce the power supply, the charging current, or the CPU operating clock, the component is not in a desired state, and the temperature is reduced. There was a possibility that it would not decrease.

  This is because there is a possibility that the component malfunctions or the task for controlling the component is not assumed (the task is not stopped) as the temperature rises. In such a state, even if the application is stopped, heat generation is not stopped. In general, a task that has a high possibility of falling into an unexpected state is a task that uses a program created by a user of the apparatus, and is often a task that operates in a privileged mode.

  The present invention has been made to solve the above-described problems, and provides an information processing apparatus capable of suppressing a temperature rise with high accuracy when the temperature rises above a preset threshold value. Objective.

  In order to achieve the above object, an information processing apparatus according to the present invention includes a temperature sensor and a control unit that reboots the apparatus when a temperature equal to or higher than a predetermined threshold is measured by the temperature sensor. .

  According to the present invention, there is provided an information processing apparatus capable of suppressing a temperature rise with high accuracy when the temperature rises above a preset threshold value.

FIG. 1 is a block diagram showing a configuration of a mobile communication apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram showing a detailed configuration of the photo taking unit shown in FIG. FIG. 3 is a block diagram showing a detailed configuration of the power supply unit shown in FIG. FIG. 4 is a flowchart for explaining the control operation of the temperature rise suppression function shown in FIG. FIG. 5 is a diagram illustrating an example of a state transition of the apparatus illustrated in FIG. FIG. 6 is a sequence diagram illustrating an example of an application of the device illustrated in FIG. 1 and a state transition of the device.

  Embodiments of an information processing apparatus according to embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a mobile communication apparatus to which an information processing apparatus according to an embodiment of the present invention is applied.

  The mobile communication device includes a control unit 11 that controls the entire device, an antenna 12a that transmits and receives radio waves between a base station (not shown) connected to the mobile communication network, and a mobile communication network communication unit 12b. A mobile communication network transmission / reception unit 13, a speaker 14a for outputting received voices, a microphone 14b for inputting transmission voices, a call unit 14c, and a display unit 15 for visually showing information to the user. The input unit 16 that receives an instruction from the person, the call control unit 21, the CPU temperature sensor 22 that measures the temperature of the CPU provided in the control unit 11, the photography unit 31, and the temperature of the camera provided in the photography unit 31. The camera temperature sensor 32 to measure, the power supply part 41, and the battery temperature sensor 42 which measures the temperature of the charging battery with which the power supply part 41 is provided are provided.

  The control unit 11 includes a CPU, and functions as an OS when the CPU executes a program. Moreover, the control part 11 is provided with the temperature rise suppression function 11-1. The call control unit 21 is a task executed by the CPU. The CPU temperature sensor 22, the camera temperature sensor 32, and the battery temperature sensor 42 are driven and controlled by a driver program (not shown) executed by the CPU.

  FIG. 2 is a block diagram showing a detailed configuration of the photo shooting unit 31. The photography unit 31 includes a photography control unit 31a connected to the control unit 11, a camera 31b, and a photography application unit 31c. The photography control unit 31a and the photography application unit 31c are tasks executed by the CPU, and these are realized as one task or as separate tasks.

  FIG. 3 is a block diagram illustrating a detailed configuration of the power supply unit 41. The power supply unit 41 includes a power supply control unit 41a connected to the control unit 11, a switch 41b connected to a charger and supplied with charging power, and a rechargeable battery 41c that supplies power to each unit. The power control unit 41a is a task executed by the CPU.

  Next, the configuration of each part of the mobile communication device will be described in detail with reference to FIGS. The temperature rise suppression function 11-1 reduces the temperature when a temperature equal to or higher than a predetermined threshold is measured by one or more of the CPU temperature sensor 22, the camera temperature sensor 32, and the battery temperature sensor 42. Notification is made to prompt the user to perform the operation. Further, the temperature rise suppression function 11-1 stops the operation of the device and reboots the device in order to lower the temperature. Here, the reboot is to stop the OS function by the control unit 11 and turn off the power of the device, and then turn on the device again to operate the OS function by the control unit 11 again. Upon reboot, the device is in the initial state.

  The mobile communication network communication unit 12 b outputs the high frequency signal received via the antenna 12 a to the mobile communication network transmission / reception unit 13. In addition, a high-frequency signal output from the mobile communication network transmitting / receiving unit 13 is radiated to the space through the antenna 12a.

  The mobile communication network transmission / reception unit 13 amplifies, converts and demodulates the high frequency signal from the mobile communication network communication unit 12b, thereby obtaining a digital audio signal, a control signal including an incoming signal, and the like. The digital audio signal is output to the call unit 14c. The control signal is output to the control unit 11. Furthermore, the digital audio signal output from the call unit 14c and the control signal including the calling signal output from the control unit 11 are modulated, frequency converted, and amplified, respectively, to obtain a high frequency signal. This high frequency signal is output to the mobile communication network communication unit 12b.

  The calling unit 14c converts the digital audio signal output from the mobile communication network transmitting / receiving unit 13 into an analog audio signal, amplifies the analog audio signal, and outputs the amplified audio from the speaker 14a. Further, the transmitted voice is converted into an analog voice signal by the microphone 14b, the call section 14c amplifies it, converts it into a digital voice signal, and outputs it to the mobile communication network transmitting / receiving section 13.

  The display unit 15 is a display unit using, for example, an LCD (Liquid Crystal Display), and is driven and controlled by the control unit 11 to display a display prompting the user to operate, a display of contents operated by the user, and an operation of the apparatus. A display operation such as a display indicating a state is performed.

  The input unit 16 includes a plurality of key switches such as keys used for inputting numbers and characters such as telephone numbers and function keys used for operating instructions such as turning on and off the power of the mobile communication device MS. The controller 11 is activated when an activation signal is given from the control unit 11, and when the user operates the key switch, a code signal for identifying the operated key switch is output to the control unit 11.

  The call control unit 21 is an application task that realizes a call function by controlling the mobile communication network communication unit 12b, the mobile communication network transmission / reception unit 13, and the call unit 14c. Further, the call control unit 21 designates the telephone number of the communication device as the call destination by operating a key of the input unit 16 or operates the input unit 16 in an address book (not shown). Specified by calling a stored phone number. In addition, when an incoming call signal is input to the control unit 11, the call control unit 21 notifies that an incoming call has occurred, and implements a call function according to the user's incoming call operation.

  The photography control unit 31a is an application task executed by the control unit 11 (CPU), and controls each part of the photography unit 31 in an integrated manner. Specifically, the photography control unit 31a operates the camera 31b and the photography application unit 31c, and ends the operation. The operation and the operation end of the camera 31b are performed by supplying power to the camera 31b and stopping the power supply.

  The camera 31b is a digital camera using an image sensor using a CCD (Charge-Coupled Device), a CMOS (Complementary Metal Oxide Semiconductor), or the like, and converts reflected light from a subject (not shown) into an electrical signal. Thus, the subject is imaged. The photographing application unit 31c is application software executed by the control unit 11, and performs image processing to obtain image data by encoding an electrical signal output from the camera 31b. Image data obtained by this image processing is recorded in a storage unit (not shown). The image data handled here may be a still image or a moving image. The video imaged by the camera 31b is displayed on the display unit 15 by the control unit 11, and the display unit 15 functions as a viewfinder. The image data recorded in the storage unit is decoded by a photo reproduction unit (not shown) and displayed on the display unit 15 in response to a user request through the input unit 16.

  The power supply control unit 41a is an application task executed by the control unit 11 (CPU), and performs control to appropriately charge the rechargeable battery 41c. That is, the power supply control unit 41a turns on the switch 41b intermittently at a predetermined time interval to supply power to the rechargeable battery 41c for charging, and turns off the switch 41b for charging when charging is stopped. Measurement of the voltage of the battery 41 c and the detected temperature from the battery temperature sensor 42 are acquired. Then, when the measured voltage is greater than a predetermined threshold voltage, the power supply control unit 41a determines that the rechargeable battery 41c is fully charged. When the battery is fully charged or when the temperature measured by the battery temperature sensor 42 is equal to or higher than a predetermined threshold temperature, the power supply controller 41a turns off the switch 41b and stops charging. In addition, the said threshold temperature is set to temperature lower than the threshold value of the temperature at the time of temperature rise suppression by the temperature rise suppression function 11-1.

  That is, only when the measured voltage of the rechargeable battery 41c is smaller than a predetermined threshold voltage and the rechargeable battery 41c is not fully charged and the temperature measured by the battery temperature sensor 42 is lower than the predetermined threshold temperature. The power supply control unit 41a turns on the switch 41b and charges the rechargeable battery 41c. In FIG. 3, the flow of power is indicated by a thick arrow.

  Next, the control operation for suppressing the temperature increase by the temperature increase suppressing function 11-1 in the mobile communication device having the above configuration will be described. FIG. 4 is a flowchart for explaining a control operation for suppressing the temperature increase of the temperature increase suppressing function 11-1.

  The temperature rise suppression function 11-1 is the temperature shown in FIG. 4 when the temperature equal to or higher than the first threshold is measured by at least one of the CPU temperature sensor 22, the camera temperature sensor 32, and the battery temperature sensor 42. The control operation for suppressing the rise is started (step S11-1a). Here, the first threshold value may be set to a different value for each temperature sensor. That is, the first threshold value is set according to the resistance to the temperatures of the CPU, camera 31b, and rechargeable battery 41c, and whether the temperature of the measurement target is easily recognized by the user of the apparatus. Similarly, different values may be set for each temperature sensor for a second threshold value and a third threshold value to be described later. In the following description, a temperature equal to or higher than the first threshold is referred to as a high temperature.

  Here, by the operation of the call control unit 21 or the photography unit 31, the CPU temperature sensor 22 detects a higher temperature than when they are not operating. Also, the camera temperature sensor 32 detects a higher temperature by the operation of the photography unit 31 than when it is not operating. Furthermore, when the power supply control unit 41a is charging, the battery temperature sensor 42 detects a higher temperature than when charging is not being performed.

  The temperature rise suppression function 11-1 causes the display unit 15 to display a message that prompts the user to perform an operation for ending the application that operates the heat source (measurement target) corresponding to the temperature sensor that has measured the high temperature (step S11-1b). ). Note that the termination operation for charging is to disconnect the charger from the apparatus. Here, the message is displayed on the display screen of the display unit 15 at a position where it can be easily seen by the user. For example, when the temperature of the camera 31b is high, a message “Please terminate the camera application because the terminal is hot” is displayed on the display screen used as a viewfinder. In addition, not only a display but an audio | voice may be loudly output and you may alert | report to a user.

  Thereafter, with a predetermined waiting time, the temperature rise suppression function 11-1 determines again the temperature measured by the sensor that measured the temperature equal to or higher than the first threshold value in step S11-1a (step S11-1c). ). Here, when the measured temperature is less than the first threshold, the temperature rise suppression function 11-1 deletes the display of the message prompting the end operation of the application displayed in step S11-1b (step S11- 1d) The control operation for suppressing the temperature rise is terminated (step S11-1e).

  On the other hand, when the measured temperature is equal to or higher than the first threshold value and lower than the second threshold value, the temperature rise suppression function 11-1 shifts to Step S11-1b to display a message for prompting an application end operation. Continue to display. Note that the second threshold is a value equal to or greater than the first threshold.

  On the other hand, when the measured temperature is equal to or higher than the second threshold, the temperature rise suppression function 11-1 determines whether or not the temperature rise is inevitable (step S11-1f). Inevitable is the case where the temperature rise is caused by an emergency call and the measured temperature is less than the third threshold value. Here, the emergency call is a call with a communication device having a predetermined telephone number, and is set by the police (phone number 110), fire department (phone number 119), or a user in advance. A telephone number (for example, the home telephone number of the user of the device or the telephone number of the family of the user of the device). The third threshold value is a value that is equal to or greater than the second threshold value, and is a temperature at which it is determined that it is necessary to immediately perform a process for lowering the temperature.

  When it is determined that the temperature rise is unavoidable, the temperature rise suppression function 11-1 proceeds to step S11-1f again and determines whether the temperature rise is unavoidable. On the other hand, when it is not determined that it is unavoidable, the temperature rise suppression function 11-1 determines whether only the measurement result of the CPU temperature sensor 22 is high (step S11-1g).

  When it is determined in step S11-1g that only the measurement result of the CPU temperature sensor 22 is high, the temperature rise suppression function 11-1 reduces the operation clock speed of the CPU (step S11-1h) and waits for a predetermined time. After a certain time, it is determined whether or not the temperature measured by the CPU temperature sensor 22 is less than the first threshold (step S11-1i). If the measured temperature is equal to or higher than the first threshold value, the process proceeds to step S11-1i again, and after waiting for a predetermined waiting time, the temperature measured by the CPU temperature sensor 22 is determined.

  On the other hand, when the measured temperature is less than the first threshold, the temperature rise suppression function 11-1 deletes the message displayed in step S11-1b (step S11-1j), and the operation clock speed of the CPU Is restored to the normal speed (step S11-1k), and the control operation is terminated (step S11-1e). The operation for deleting the message display in step S11-1j is the same as the operation in step S11-1d.

  In addition, when the operation of step S11-1i is repeated, the temperature measured by the CPU temperature sensor 22 continues to rise, and / or the temperature above the second threshold by a temperature sensor other than the CPU temperature sensor 22 May be measured, it may be made to shift to Step S11-1m.

  In step S11-1g, if it is determined that a temperature other than the CPU temperature sensor 22 is being measured, the temperature rise suppression function 11-1 is an application that operates a heat source (measurement target) corresponding to the temperature sensor that has measured the high temperature. A message indicating that the (photographing control unit 31a and / or power supply control unit 41a) is to be terminated is displayed on the display unit 15 (step S11-1m). Here, not only the display but also the voice may be outputted and notified to the user.

  Then, the temperature rise suppression function 11-1 ends the corresponding application (step S11-1n) and reboots the device (step S11-1o). Rebooting is a function of the control unit 11, and no application is operating in the initial state after the device reboots. The power supply control unit 41a also does not operate until it is activated by the control unit 11 regardless of whether or not the input unit 16 is operated by a key.

  Here, it is not always necessary to end the corresponding application and reboot the apparatus in this order, and usually only one of them may be performed. Which one is to be performed may be set in advance depending on whether or not the heat generation of the component whose temperature has risen is suppressed by termination of the corresponding application.

  As a case where there is a possibility that the heat will continue, there is a case where an application that operates using a program created by a user of the apparatus is used. As the application, the call control unit 21, the photography control unit 31a, and The power supply control unit 41a is conceivable and has been described above as an example. In the operation of reducing the operation clock speed of the CPU in steps S11-1h to S11-1k, no reboot is performed. The reason is that this operation clock is related to a lot of hardware, and even if the speed of the operation clock is reduced, there is little possibility of heat generation. However, these are matters that should be appropriately set according to the implementation of the apparatus. The necessity of reboot may be set depending on whether or not a program used by the application is created by the user of the apparatus.

  In addition, after terminating the application or restarting the apparatus by rebooting, the temperature sensor that has measured the high temperature again measures the temperature equal to or higher than the first threshold, and the temperature rise suppression function 11-1 There is a high possibility that the control operation shown in FIG. 4 is performed again. In particular, when the temperature equal to or higher than the third threshold value is measured, the reboot operation in step S11-1o is again performed wastefully.

  Therefore, at the time of rebooting, it is desirable that the temperature rise suppression function 11-1 perform any one of the following first to fifth processes or a plurality of processes. According to these processes, the device does not operate for a predetermined time and / or the applications that operate for the predetermined time are limited, so that the device returns to a normal operation state.

  As a first process, the reboot in step S11-1o is a process of turning on the apparatus again after a predetermined time after the apparatus is turned off. Here, the predetermined time is set in advance according to the temperature sensor that measures the high temperature and the mounting of the apparatus. As a second process, when rebooted in step S11-1o, the temperature rise suppression function 11-1 does not perform all or part of the control operation over a predetermined time. For example, even when the measured temperature is equal to or higher than the second threshold, only the control operation that allows the operation is performed.

  As a third process, the temperature rise suppression function 11-1 stores the identification information of the temperature sensor that has measured the high temperature before starting the reboot of step S11-1o (not shown) in the control unit 11. To record. After the reboot, if the temperature measured by the temperature sensor in which the identification information is recorded in the internal storage unit is equal to or higher than a predetermined threshold (for example, the second threshold), the apparatus is shut down again for a predetermined time. After the time elapses, the apparatus is turned on, and the temperature measured by the temperature sensor is again compared with the predetermined threshold. If the temperature measured by the temperature sensor is lower than the predetermined threshold value, the operation of the apparatus is continued. If the temperature is equal to or higher than the predetermined threshold value, the apparatus is shut down again and the same operation is repeated.

  As a fourth process, the temperature rise suppression function 11-1 stores the identification information of the temperature sensor that measured the high temperature and the temperature measured by the temperature sensor before starting the reboot of step S11-1o. To record. After the reboot, if the temperature measured by the temperature sensor whose identification information is recorded in the internal storage unit is equal to or higher than the temperature recorded in the internal storage unit, the apparatus is shut down again and a predetermined time is exceeded. After the lapse of time, the apparatus is turned on, and the temperature measured by the temperature sensor is again compared with the recorded temperature. If the temperature measured by the temperature sensor is lower than the recorded temperature, the operation of the apparatus is continued. If the temperature is equal to or higher than the predetermined threshold value, the apparatus is shut down again and the same operation is repeated.

  As a fifth process, the temperature rise suppressing function 11-1 stores the identification information of the temperature sensor that has measured the high temperature and the temperature measured by the temperature sensor before starting the reboot in step S11-1o. To record. After the reboot, even if the temperature measured by the temperature sensor at least the identification information recorded in the internal storage unit is equal to or higher than a predetermined threshold (for example, the second threshold), it is recorded in the internal storage unit. If the temperature is less than the predetermined temperature, the temperature rise suppression function 11-1 does not perform the control operation for a predetermined time and / or the temperature measured by the temperature sensor for the predetermined time or Until the temperature becomes high, the activation of the application that operates the heat source (measurement target) corresponding to the temperature sensor is suppressed.

  Which of the first to fifth processes is performed may be selectively executed depending on which temperature sensor is used to measure the high temperature. For example, when a high temperature is measured by the battery temperature sensor 42, the apparatus is started after a predetermined time has elapsed after the apparatus is turned off. This is because the user of the device is not aware that the charging operation is an application, and the device is stopped for a predetermined time to reliably cool the device.

  Further, which of the first to fifth processes is performed may be selectively executed according to the temperature measured after the reboot. Furthermore, it may be selectively executed according to an application started after reboot. For example, if the temperature measured by the CPU temperature sensor 22 is less than the third threshold, only the emergency call may be operated.

  An example of how the state of the application or the apparatus changes by the control operation of the temperature rise suppression function 11-1 described above will be described. FIG. 5 shows an example of a state transition diagram of the apparatus by the control operation of the temperature rise suppression function 11-1.

  When the temperature measured by the temperature sensor becomes equal to or higher than the first threshold, the apparatus in the normal operation state transitions to a message display state (corresponding to step S11-1b) prompting the application to end. And when the temperature is not less than the second threshold and the temperature rise is unavoidable (corresponding to “NO” in step S11-1f), or the temperature is not less than the third threshold (step In the case of “NO” in S11-1f, the application is terminated (corresponding to step S11-1n) and rebooted (corresponding to step S11-1o) is performed.

  When a message prompting the end of the application is displayed, when the measured temperature falls below the first threshold value, transition to the normal operation state (corresponding to the case of “less than the first threshold value” in step S11-1c). ) And the above display is terminated. In addition, after the application is terminated and rebooted, when the measured temperature falls below the first threshold value, a transition is made to a normal operation state.

  An example of a sequence of how the state of the application or the apparatus transitions by the control operation of the temperature rise suppression function 11-1 described above will be described. FIG. 6 shows an example of the state transition sequence. The sequence shown in this figure exemplifies a case where the user of the apparatus does not perform the end operation although the message prompting the end operation of the application is displayed because the high temperature is measured by the camera temperature sensor 32.

  When the camera temperature sensor 32 measures a temperature that is equal to or higher than the first threshold value and lower than the second threshold value, the temperature rise suppression function 11-1 is an operation for ending the application that operates the photography unit 31 including the heat source. Display a message prompting However, in spite of the display, the user of the apparatus is used as it is without ending the application.

  Eventually, the temperature further rises, the camera temperature sensor 32 measures a temperature equal to or higher than the second threshold, and the temperature rise suppression function 11-1 terminates the application and reboots the apparatus.

  In the above description, the temperature rise suppression function 11-1 monitors all measured temperatures by the CPU temperature sensor 22, the camera temperature sensor 32, and the battery temperature sensor 42, and collectively performs a process of suppressing the temperature rise. However, it is not limited to this.

  For example, the camera temperature sensor 32 may be performed by the photography control unit 31a instead of the temperature rise suppression function 11-1. That is, the camera temperature sensor 32 may be connected to the photography control unit 31a, and when the camera temperature sensor 32 measures a high temperature, the photography control unit 31a may perform the control shown in FIG. Further, the battery temperature sensor 42 may be performed by the power supply control unit 41a instead of the temperature rise suppression function 11-1. That is, the battery temperature sensor 42 may be connected to the power supply control unit 41a, and when the battery temperature sensor 42 measures a high temperature, the power supply control unit 41a may perform the control shown in FIG. As described above, the individually controlled configuration is suitable when a plurality of temperature sensors are unlikely to measure a high temperature at the same time.

  In the above, the case where the present invention is applied to a mobile communication device has been described as an example. However, the present invention is not limited to this, and other information processing devices such as a personal computer, a PDA, a television receiver, and the like. The present invention can be applied to a music playback device or the like. The present invention is not limited to the above configuration, and various modifications are possible.

DESCRIPTION OF SYMBOLS 11 Control part 11-1 Temperature rise suppression function 12b Mobile communication network communication part 13 Mobile communication network transmission / reception part 15 Display part 16 Input part 21 Call control part 22 CPU temperature sensor 31 Photographing part 31a Photographing control part 31b Camera 31c Photographing application Unit 32 camera temperature sensor 41 power source unit 41a power source control unit 41b switch 41c rechargeable battery 42 battery temperature sensor

Claims (4)

A temperature sensor;
An information processing apparatus comprising: control means for rebooting the apparatus when a temperature equal to or higher than a predetermined threshold is measured by the temperature sensor. A communication means for performing communication via a communication network;
The said control means does not reboot an apparatus, when the temperature measured by the said temperature sensor is the said predetermined threshold value, and is communicating with the communication apparatus preset by the said communication means. The information processing apparatus according to 1.   The information processing apparatus according to claim 1, wherein, when rebooting, the control unit turns on the power after a predetermined time elapses after the power is turned off.   The control means stores the temperature measured by the temperature sensor before rebooting, and turns off the power when the temperature measured by the temperature sensor is higher than the stored temperature after rebooting. The information processing apparatus according to claim 1.

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