JP2012065127A - Portable apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control technique for eliminating the necessity of the active operation of a user when turning on/off the power source of an electronic apparatus to be used by the user by holding the apparatus in hand.SOLUTION: A portable apparatus 10 includes: a power source unit 14 for supplying power to respective parts of the portable apparatus 10; a temperature sensor 17; and a control unit 15 for controlling the power source unit 14 to turn on/off power supply to the respective parts of the portable apparatus 10, based on a detection result of the temperature sensor 17. The temperature sensor 17 is arranged at a part where a part of the body of a user abuts on or is adjacent to in the use state of the portable apparatus 10.

Description

  The present invention relates to an electronic device (hereinafter referred to as “portable electronic device”) that is mainly used by a user, such as a mobile phone, a portable game machine, a portable electronic notebook, a portable electronic book, a handheld PC, and a remote controller. In particular, the present invention relates to the power on / off control technology.

  Conventionally, portable device power on / off methods (including power saving mode return / transition methods) include: (1) detection of power switch depression, (2) touch on power icon displayed on touch panel And (3) detecting the open / closed state of a foldable portable device.

  An example of the prior art related to the present invention is Patent Document 1 (sensor phone).

Japanese Patent Laid-Open No. 5-347672

  Among the above-described power on / off methods, the methods (1) and (2) are different in the same process, and there is no essential difference between the two methods. Both methods require the user to perform an active operation (pressing or touching) to turn on / off the power. Therefore, for example, a user who wants to use a mobile device in a power-off state must first perform a power-on operation, and can perform a desired action (if a mobile phone is used, There was a problem that it was not possible to enter the phone book search.

  Of the above-described power on / off methods, the method (3) is such that the action for using the portable device (folding mechanism opening / closing operation) directly corresponds to the power on / off operation. This is an excellent technique in the sense that it does not require the user to perform an active operation for turning off. However, the method (3) is applicable only to a foldable mobile device, and cannot be applied to a bar-type mobile phone or a mobile device that is not generally a foldable device (such as a portable electronic book or a remote controller). There was a problem.

  The present invention has been made in view of the above problems found by the inventors of the present application, and an object of the present invention is to provide a portable device that does not require a user's active operation when the power is turned on / off.

  In order to achieve the above object, a portable device according to the present invention supplies a power supply to each part of the portable device, a temperature sensor, and power supply to each part of the portable device based on the detection result of the temperature sensor. And a control unit that controls the power supply unit so as to be turned on / off (first configuration).

  In the portable device having the first configuration described above, the temperature sensor is installed at a location where a part of the user's body is in contact with or in close proximity when the portable device is in use (second configuration). ).

  In the portable device having the second configuration, the temperature sensor may be installed on a side surface of the portable device (third configuration).

  In addition, the portable device having the second configuration further includes an operation unit that receives a user's operation, and the temperature sensor has a configuration (fourth configuration) installed in the operation unit or in the vicinity thereof. Good.

  Further, in the portable device having any one of the second to fourth configurations, the control unit supplies power to each part of the portable device when a temperature rise exceeding a predetermined rising gradient value is detected by the temperature sensor. On the contrary, when the temperature sensor detects a temperature decrease exceeding a predetermined decrease gradient value, the power supply unit is controlled to turn off the power supply to each part of the portable device (fifth) (Configuration).

  The portable device having the fifth configuration further includes an illuminance sensor, and the control unit is configured to detect the illuminance even when a temperature increase exceeding a predetermined increase gradient value is detected by the temperature sensor. If the illuminance detected by the sensor exceeds a predetermined threshold, the power supply unit may be controlled (sixth configuration) so that power supply to each part of the portable device is not turned on.

  The portable device having the fifth configuration further includes first and second illuminance sensors installed at different locations, and the control unit increases the temperature exceeding a predetermined increase gradient value by the temperature sensor. Even if the detection results obtained by the first and second illuminance sensors match, the power supply unit is set so that the power supply to each part of the portable device is not turned on. A configuration to be controlled (seventh configuration) is preferable.

  Further, in the portable device having the seventh configuration, the first illuminance sensor is installed at a location where a part of the user's body abuts or approaches in the use state of the portable device, The second illuminance sensor may have a configuration (eighth configuration) that is installed at a location where a part of the user's body does not contact or approach in the use state of the portable device.

  In addition, the portable device having the eighth configuration further includes a folding mechanism or a sliding mechanism, and the second illuminance sensor changes the light irradiation state according to the open / closed state of the folding mechanism or the sliding mechanism. It is good to make it the structure (9th structure) installed in the place to do.

  In addition, the portable device having the fifth configuration further includes a proximity sensor, and the control unit uses the proximity sensor even when a temperature increase exceeding a predetermined rising gradient value is detected by the temperature sensor. If contact or proximity of a part of the body is not detected, the power supply unit may be controlled (tenth configuration) so that power supply to each part of the portable device is not turned on.

  The portable device having the fifth configuration further includes first and second proximity sensors installed at different locations, and the control unit increases the temperature exceeding a predetermined increase gradient value by the temperature sensor. Even if the detection results obtained by the first and second proximity sensors match, the power supply unit is set so that the power supply to each part of the portable device is not turned on. It is good to make it the structure (11th structure) to control.

  Further, in the portable device having the eleventh configuration, the first proximity sensor is installed at a location where a part of a user's body abuts or approaches in the use state of the portable device. The proximity sensor 2 may be configured to be installed at a location where a part of the user's body is not in contact with or in proximity in the usage state of the portable device (a twelfth configuration).

  The portable device having any one of the fifth to twelfth configurations further includes an acceleration sensor, and the control unit is when the temperature sensor detects a temperature rise exceeding a predetermined climb gradient value. However, if the acceleration detected by the acceleration sensor is below a predetermined threshold, the power supply unit is controlled so as not to turn on the power supply to each part of the portable device (13th configuration). Good.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the portable apparatus which does not require a user's active operation at the time of power ON / OFF.

The block diagram which shows one Embodiment of the portable apparatus which concerns on this invention Flow chart showing a first operation example of power on / off control Flowchart showing a second operation example of power on / off control Flowchart showing a third operation example of power on / off control Flowchart showing a fourth operation example of power on / off control Schematic diagram showing an example of application to a foldable mobile phone Schematic diagram showing an example of application to a slide-type mobile phone Schematic diagram showing an example of application to a bar-type mobile phone Schematic diagram showing an example of application to a portable game machine

<Block diagram>
FIG. 1 is a block diagram showing an embodiment of a portable device according to the present invention. As shown in FIG. 1, the mobile device 10 according to the present embodiment includes a display unit 11, an operation unit 12, a storage unit 13, a power supply unit 14, a control unit 15, a function unit 16, and a temperature sensor 17. And an illuminance sensor 18 and an acceleration sensor 19.

  The display unit 11 displays characters, graphics, and the like based on instructions from the control unit 15. As the display unit 11, a liquid crystal display, an organic EL display, or the like can be used.

  The operation unit 12 receives a user operation and transmits the contents to the control unit 15. As the operation unit 12, a button, a key, a touch panel, or the like can be used.

  The storage unit 13 is used as a storage area for programs executed by the control unit 15 and a temporary storage area for various data handled by the control unit 15. As the storage unit 13, a ROM [Read Only Memory], a RAM [Random Access Memory], or the like can be used.

  The power supply unit 14 supplies power to each unit of the mobile device 10 based on an instruction from the control unit 15. In the portable device 10, since a battery is used as the power source of the power supply unit 14, in order to extend the operation time of the portable device 10, an appropriate power on / off control (depending on the operating state of the portable device 10) It is important to perform control for reducing waste power.

  The control unit 15 comprehensively controls the operation of each unit of the mobile device 10. In particular, in the portable device 10 of the present embodiment, the control unit 15 turns on / off the power supply to each part of the portable device 10 based on the detection results of the temperature sensor 17, the illuminance sensor 18, and the acceleration sensor 19. Has a function of controlling the power supply unit 14. The power on / off control by the control unit 15 will be described in detail later with a specific example.

  The function unit 16 is a circuit block for realizing an original function as the mobile device 10. For example, if the mobile device 10 is a mobile phone, a line connection unit, a call unit (microphone, speaker), and the like are included in the function unit 16, and if the mobile device 10 is a portable game machine, a game A cartridge attaching / detaching unit and the like are included in the functional unit 16.

  The temperature sensor 17 detects the temperature of the installation location, generates an electrical signal corresponding to the temperature, and transmits the electrical signal to the control unit 15. The temperature sensor 17 may be installed at a location where a part of the user's body (such as a hand or a finger) comes into contact with or is close to the portable device 10 in use. By adopting such a configuration, when the user holds the portable device 10 with his / her hand, the temperature change of the part touched by the user's hand or finger is detected and reflected in the power on / off control described later. Is possible.

  For example, when the mobile device 10 is a folding mobile phone (FIG. 6), the mobile device 10 is a slide mobile phone (FIG. 7), or the mobile device 10 is a bar mobile phone (FIG. 8). In any case, when the user holds the mobile device 10 by hand, the user's finger is in contact with or close to the side surface of the mobile device 10 (for example, locations indicated by reference signs A11, A21, and A31). Therefore, it is desirable to install the temperature sensor 17 at such a position. Further, when the portable device 10 is a portable game machine (FIG. 9), when the user holds the portable device 10 by hand, the operation unit 12 of the portable device 10 or the vicinity thereof (for example, indicated by reference numeral A41) It is considered that the user's finger is often placed on the location), so it is desirable to install the temperature sensor 17 at such a position.

  The illuminance sensor 18 detects the illuminance at the installation location, generates an electrical signal corresponding to the illuminance, and transmits the electrical signal to the control unit 15. When only one illuminance sensor 18 is installed in the mobile device 10, the illuminance sensor 18 is located at a location where a part of the user's body (such as a hand or a finger) is in contact with or close to the mobile device 10. Install it. With such a configuration, when the user holds the mobile device 10 by hand, it is detected that the part touched by the user's hand or finger has become dark and is reflected in power-on / off control described later. It becomes possible.

  For example, when the mobile device 10 is a folding mobile phone (FIG. 6), the mobile device 10 is a slide mobile phone (FIG. 7), or the mobile device 10 is a bar mobile phone (FIG. 8). In any case, when the user holds the mobile device 10 by hand, the user's finger is in contact with or close to the side surface of the mobile device 10 (for example, locations indicated by reference numerals B11, B21, and B31). Therefore, it is desirable to install the illuminance sensor 18 in such a place. When the portable device 10 is a portable game machine (FIG. 9), when the user holds the portable device 10 by hand, the operation unit 12 of the portable device 10 or the vicinity thereof (for example, indicated by B41). It is considered that the user's finger is often placed on the location), so it is desirable to install the illuminance sensor 18 at such a location.

  Note that the mobile device 10 may be provided with a plurality of illuminance sensors 18 at different locations. When such a configuration is adopted, the first illuminance sensor 18-1 is installed at a location where a part of the user's body abuts or approaches in the use state of the mobile device 10, and the mobile device 10 In the state of use, it is desirable to install the second illuminance sensor 18-2 at a location where a part of the user's body does not contact or approach. For example, in the case where the mobile device 10 is a mobile phone or a portable game machine provided with the display unit 11 (FIGS. 6 to 9), when the user holds the mobile device 10 by hand, the display unit Since the user's finger is unlikely to come into contact with or close to 11 peripheral portions (for example, locations indicated by reference numerals B12, B22, B32, and B42), the second illuminance sensor 18- 2 may be installed. Thus, the detection result obtained by the 1st and 2nd illumination intensity sensors 18-1 and 2 by setting it as the structure which has the 1st and 2nd illumination intensity sensors 18-1 and 2 installed in a different location. Can be determined and reflected in power-on / off control described later.

  In particular, when the mobile device 10 is a foldable mobile phone (FIG. 6) or when the mobile device 10 is a slide mobile phone (FIG. 7), depending on the folding mechanism or the open / close state of the slide mechanism, What is necessary is just to install the 2nd illumination intensity sensor 18-2 in the location (for example, location shown by code | symbol B12, B22) where the irradiation state of light changes. By adopting such a configuration, it is possible to determine the open / closed state of the folding mechanism or the slide mechanism from the detection result of the second illuminance sensor 18-2 and reflect it in power-on / off control described later.

  The illuminance sensor 18 described above can be replaced with a proximity sensor 18 ′ that detects the proximity of the monitoring target, generates an electrical signal corresponding to the detected proximity sensor, and transmits the electrical signal to the control unit 15.

  The acceleration sensor 19 detects acceleration generated in the mobile device 10, generates an electrical signal corresponding to the acceleration, and transmits the electrical signal to the control unit 15. As the acceleration sensor 19, it is desirable to use a MEMS [Micro Electro Mechanical Systems] device suitable for mounting on the mobile device 10. By adopting such a configuration, it is possible to detect the acceleration that occurs when the user holds the mobile device 10 by hand and reflect it in power-on / off control described later.

<First operation example>
FIG. 2 is a flowchart showing a first operation example of power on / off control. The execution subject of each step included in this flowchart is the control unit 15, and power supply to each unit of the portable device 10 (excluding the control unit 15 and the temperature sensor 17) is turned off at the start of this flowchart. Shall. Moreover, since this flowchart is a structure which performs power supply ON / OFF control only according to the detection result of the temperature sensor 17, the illumination sensor 18 and the acceleration sensor 19 shown in FIG. 1 are not essential structural requirements.

  In step S101, it is determined whether or not the temperature sensor 17 has detected a temperature increase exceeding a predetermined increase gradient value. If the determination is yes, the flow proceeds to step S102, and the power supply unit 14 is controlled to turn on the power supply to each unit of the mobile device 10. On the other hand, if a negative determination is made, the flow is returned to step S101, and the temperature rise is continuously monitored.

  After power supply to each part of the portable device 10 is turned on in step S102, in step S103, it is determined whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S104, the power supply unit 14 is controlled to turn off the power supply to each unit of the mobile device 10, and then the flow returns to step S101. It is. On the other hand, if a negative determination is made, the flow is returned to step S103, and monitoring of the temperature decrease is continued.

  According to the power on / off control based on the first operation example, when the user starts using the mobile device 10, when the user holds the mobile device 10 with his / her hand, the temperature rise of the part touched by the user's hand or finger is detected. Thus, the power supply to each part of the mobile device 10 can be turned on. In addition, according to the power on / off control based on the first operation example, when the user releases the portable device 10 from the hand when the use of the portable device 10 is finished, a portion that has been touched by the user's hand or finger until then. It is possible to turn off the power supply to each part of the portable device 10 by detecting the temperature drop.

  That is, according to the power on / off control based on the first operation example, power is supplied to each part of the mobile device 10 without requiring the user to perform an active operation (press or touch) for power on / off. Can be appropriately turned on / off.

  Note that, as shown in step S101 and step S103, in the first operation example, not based on the absolute value of the temperature detected by the temperature sensor 17, but on the primary differential value (that is, the temperature change per unit time). Thus, power on / off control is performed. With such a configuration, it is possible to reduce the measurement time and improve the determination accuracy. Further, by detecting only a temperature rise exceeding a predetermined rise gradient value and a temperature drop exceeding a predetermined fall gradient value, even if a moderate temperature rise / temperature drop caused by a change in outside air temperature or room temperature occurs, It is possible to avoid unintended power on / off associated with this.

<Second operation example>
FIG. 3 is a flowchart showing a second operation example of the power on / off control. The execution subject of each step included in this flowchart is the control unit 15, and power supply to each unit of the portable device 10 (excluding the control unit 15 and the temperature sensor 17) is turned off at the start of this flowchart. Shall.

  In step S201, it is determined whether or not the temperature sensor 17 has detected a temperature increase exceeding a predetermined increase gradient value. If the determination is yes, the flow proceeds to step S202, and the power supply unit 14 is controlled to turn on the power supply to the illuminance sensor 18 and the acceleration sensor 19. On the other hand, if a negative determination is made, the flow returns to step S201, and the temperature rise is continuously monitored.

  After power supply to the illuminance sensor 18 and the acceleration sensor 19 is turned on in step S202, in step S203, it is determined whether or not the illuminance obtained by the illuminance sensor 18 satisfies a predetermined illuminance condition. Here, if a yes determination is made, the flow proceeds to step S204, and if a no determination is made, the flow proceeds to step S209.

  If only one illuminance sensor 18 is installed in the mobile device 10, whether or not the illuminance obtained by the illuminance sensor 18 is below a predetermined threshold in step S203, in other words, the mobile device 10 It is only necessary to determine whether or not the incident light on the illuminance sensor 18 is blocked as a result of the illuminance sensor 18 being covered with the user's hand or finger holding the illuminance. By making such a determination, the illuminance sensor 18 is not covered with the user's hand or finger even when the temperature sensor 17 detects a temperature rise exceeding a predetermined ascending gradient value. If the illuminance detected at 18 exceeds a predetermined threshold value, the power supply unit 14 can be controlled so that the power supply to each part of the portable device 10 is not turned on. It becomes possible to raise.

  When the first and second illuminance sensors 18-1 and 18-2 are installed at different locations of the mobile device 10, in step S203, the first and second illuminance sensors 18-1 and 18-2 are respectively used. Whether or not the obtained illuminances are inconsistent with each other, in other words, as a result of only the first illuminance sensor 18-1 being covered by the user's hand or finger holding the mobile device 10, the first illuminance sensor 18- It may be determined whether only the incident light to 1 is blocked. By making such a determination, even when the temperature sensor 17 detects a temperature rise exceeding a predetermined rise gradient value, the temperature sensor 17 obtains the first and second illuminance sensors 18-1 and 18-2, respectively. If the detection results match each other, the power supply unit 14 can be controlled so that the power supply to each part of the mobile device 10 is not turned on, so that the accuracy of the power on / off control can be improved. .

  Further, when the mobile device 10 is a foldable mobile phone or a slide-type mobile phone, and the second illuminance sensor 18-2 is installed at a location indicated by reference sign B12 in FIG. 6 or reference sign B22 in FIG. In step S203, whether or not the illuminance obtained by the second illuminance sensor 18-2 exceeds a predetermined threshold value, in other words, whether the folding mechanism or the slide mechanism of the portable device 10 is open. The determination of whether or not may be additionally performed. By making such a determination, it is possible to further improve the accuracy of the power on / off control.

  If the determination in step S203 is yes, in step S204, it is determined whether or not the acceleration obtained by the acceleration sensor 19 satisfies a predetermined acceleration condition (for example, whether or not the acceleration exceeds a predetermined threshold). Determination) is performed. If the determination is yes, the flow proceeds to step S205, and the power supply unit 14 is controlled to turn on the power supply to each unit of the mobile device 10. On the other hand, if a negative determination is made, the flow proceeds to step S209. By making such a determination, even when the temperature sensor 17 detects a temperature increase exceeding a predetermined increase gradient value, if the acceleration detected by the acceleration sensor 19 is below a predetermined threshold value, Since the power supply unit 14 can be controlled so that the power supply to each part of the mobile device 10 is not turned on, the accuracy of the power on / off control can be improved.

  After power supply to each part of the portable device 10 is turned on in step S205, in step S206, it is determined whether or not a state in which no operation is accepted for a predetermined period is continued. If the determination is yes, the flow proceeds to step S207. On the other hand, if a negative determination is made, the flow returns to step S206, and the standby for the operation is continued.

  If the determination in step S206 is YES, in step S207, it is determined whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S208, and after the power supply unit 14 is controlled to turn off the power supply to each part of the mobile device 10, the flow returns to step S201. It is. On the other hand, if a negative determination is made, the flow is returned to step S206, and the standby for the operation is continued.

  On the other hand, if a negative determination is made in either step S203 or step S204, it is determined in step S209 whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S210, and the power supply unit 14 is controlled to turn off the power supply to the illuminance sensor 18 and the acceleration sensor 19, and then the flow proceeds to step S210. The process returns to S201. On the other hand, if a negative determination is made, the flow returns to step S203, and satisfaction monitoring of the illuminance condition and the acceleration condition is continued.

  According to the power on / off control based on the second operation example, when the user starts using the mobile device 10, the temperature of the portion touched by the user's hand or finger increases as the user holds the mobile device 10 by hand. It is possible to detect that the portion touched by the user's hand or finger has become dark and that acceleration has occurred in the mobile device 10 and turn on the power supply to each part of the mobile device 10. Become. In addition, according to the power on / off control based on the second operation example, when the use of the mobile device 10 is ended, as in the first operation example, when the user releases the mobile device 10 from the hand, It is possible to turn off the power supply to each part of the mobile device 10 by detecting the temperature drop of the part touched by the hand or finger.

  That is, according to the power on / off control based on the second operation example, as in the first operation example described above, the user is requested to perform an active operation (press or touch) for power on / off. In addition, the power supply to each part of the mobile device 10 can be appropriately turned on / off with higher accuracy than the power on / off control based on the first operation example described above.

<Third operation example>
FIG. 4 is a flowchart showing a third operation example of the power on / off control, and shows an operation when the illuminance sensor 18 of FIG. 1 is replaced with a proximity sensor 18 ′. The execution subject of each step included in this flowchart is the control unit 15, and power supply to each unit of the portable device 10 (excluding the control unit 15 and the temperature sensor 17) is turned off at the start of this flowchart. Shall.

  In step S301, it is determined whether or not the temperature sensor 17 has detected a temperature increase exceeding a predetermined increase gradient value. If the determination is yes, the flow proceeds to step S302, and the power supply unit 14 is controlled to turn on the power supply to the proximity sensor 18 'and the acceleration sensor 19. On the other hand, if a negative determination is made, the flow is returned to step S301, and monitoring of the temperature rise is continued.

  After power supply to the proximity sensor 18 ′ and the acceleration sensor 19 is turned on in step S302, in step S303, it is determined whether or not the detection result obtained by the proximity sensor 18 ′ satisfies a predetermined proximity condition. Is done. Here, if a yes determination is made, the flow proceeds to step S304, and if a no determination is made, the flow proceeds to step S309.

  If only one proximity sensor 18 ′ is installed in the mobile device 10, it is determined in step S303 whether the proximity sensor 18 ′ detects contact or proximity of the user's hand or finger. Can be done. By making such a determination, even when the temperature sensor 17 detects a temperature rise exceeding a predetermined rising gradient value, the proximity sensor 18 ′ detects the contact or proximity of the user's hand or finger. If not, the power supply unit 14 can be controlled so that the power supply to each part of the portable device 10 is not turned on, so that the accuracy of the power on / off control can be improved.

  If the first and second proximity sensors 18-1 ′ and 2 ′ are installed at different locations of the mobile device 10, the first and second proximity sensors 18-1 ′ and 2 are set in step S303. It is determined whether or not the detection results obtained in each are inconsistent with each other, in other words, whether the user's hand or finger holding the mobile device 10 is in contact with or in proximity to only the first proximity sensor 18-1 ′. It may be determined whether or not. By making such a determination, the first and second proximity sensors 18-1 ′ and 2 ′ can obtain the temperature sensor 17 even when the temperature sensor 17 detects a temperature rise exceeding a predetermined climb gradient value. If the detected results match each other, the power supply unit 14 can be controlled so that the power supply to each part of the mobile device 10 is not turned on, so the accuracy of the power on / off control can be improved. It becomes.

  If the determination in step S303 is yes, in step S304, it is determined whether or not the acceleration obtained by the acceleration sensor 19 satisfies a predetermined acceleration condition (for example, whether or not the acceleration exceeds a predetermined threshold). Determination) is performed. If the determination is yes, the flow proceeds to step S305, and the power supply unit 14 is controlled to turn on the power supply to each unit of the mobile device 10. On the other hand, if a negative determination is made, the flow proceeds to step S309. By making such a determination, even when the temperature sensor 17 detects a temperature increase exceeding a predetermined increase gradient value, if the acceleration detected by the acceleration sensor 19 is below a predetermined threshold value, Since the power supply unit 14 can be controlled so that the power supply to each part of the mobile device 10 is not turned on, the accuracy of the power on / off control can be improved.

  After power supply to each part of the mobile device 10 is turned on in step S305, in step S306, it is determined whether or not a state in which no operation is accepted for a predetermined period is continued. If the determination is yes, the flow proceeds to step S307. On the other hand, if a negative determination is made, the flow returns to step S306, and the standby for the operation is continued.

  If the determination in step S306 is YES, in step S307, it is determined whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S308, and the power supply unit 14 is controlled to turn off the power supply to each unit of the mobile device 10, and then the flow returns to step S301. It is. On the other hand, if a negative determination is made, the flow returns to step S306, and the standby for the operation is continued.

  On the other hand, if a negative determination is made in either step S303 or step S304, in step S309, it is determined whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S310, and the power supply unit 14 is controlled to turn off the power supply to the proximity sensor 18 ′ and the acceleration sensor 19, and then the flow It returns to step S301. On the other hand, if a negative determination is made, the flow is returned to step S303, and satisfaction monitoring of the proximity condition and the acceleration condition is continued.

  According to the power on / off control based on the third operation example, when the user starts using the mobile device 10, the temperature of the portion touched by the user's hand or finger increases as the user holds the mobile device 10 by hand. And detecting that the user's hand or finger is in contact with or close to the mobile device 10 and that acceleration has occurred in the mobile device 10 to turn on the power supply to each part of the mobile device 10. It becomes possible. Further, according to the power on / off control based on the third operation example, when the use of the mobile device 10 ends, the user releases the mobile device 10 from the hand, as in the first operation example and the second operation example described above. In addition, it is possible to detect a temperature drop in a portion that has been touched by the user's hand or finger until then, and turn off the power supply to each part of the mobile device 10.

  That is, according to the power on / off control based on the third operation example, as in the first operation example and the second operation example described above, an active operation (press or touch) for power on / off is performed. It is possible to appropriately turn on / off the power supply to each part of the mobile device 10 without requesting the user and with higher accuracy than the power on / off control based on the first operation example described above.

<Fourth operation example>
FIG. 5 is a flowchart showing a fourth operation example of the power on / off control, and shows an operation when the illuminance sensor 18 is always turned on as the main sensor, not the temperature sensor 17 is always turned on as the main sensor. It is a thing. The execution subject of each step included in this flowchart is the control unit 15, and power supply to each unit of the portable device 10 (excluding the control unit 15 and the illuminance sensor 18) is turned off at the start of this flowchart. Shall.

  In step S401, it is determined whether or not the illuminance obtained by the illuminance sensor 18 satisfies a predetermined illuminance condition. If the determination is yes, the flow proceeds to step S402, and the power supply unit 14 is controlled to turn on the power supply to the temperature sensor 17 and the acceleration sensor 19. On the other hand, if a negative determination is made, the flow returns to step S401, and the satisfaction monitoring of the illuminance condition is continued.

  When only one illuminance sensor 18 is installed in the mobile device 10, it may be determined in step S401 whether or not the illuminance obtained by the illuminance sensor 18 is below a predetermined threshold. In addition, when the first and second illuminance sensors 18-1 and 18-2 are installed in different places of the mobile device 10, respectively, in step S401, the first and second illuminance sensors 18-1 and 18-2 are used. It may be determined whether or not the obtained illuminances are inconsistent with each other. Further, when the mobile device 10 is a foldable mobile phone or a slide-type mobile phone, and the second illuminance sensor 18-2 is installed at a location indicated by reference sign B12 in FIG. 6 or reference sign B22 in FIG. In step S401, it may be additionally determined whether or not the illuminance obtained by the second illuminance sensor 18-2 exceeds a predetermined threshold value. By making such a determination, it is possible to further improve the accuracy of the power on / off control.

  After power supply to the temperature sensor 17 and the acceleration sensor 19 is turned on in step S402, in step S403, it is determined whether or not the temperature sensor 17 has detected an increase in temperature exceeding a predetermined increase gradient value. Here, if a yes determination is made, the flow proceeds to step S404, and if a no determination is made, the flow proceeds to step S409.

  If YES is determined in step S403, in step S404, it is determined whether or not the acceleration obtained by the acceleration sensor 19 satisfies a predetermined acceleration condition (for example, whether or not the acceleration exceeds a predetermined threshold). Determination) is performed. If the determination is yes, the flow proceeds to step S405, and the power supply unit 14 is controlled to turn on the power supply to each unit of the mobile device 10. On the other hand, if a negative determination is made, the flow proceeds to step S410.

  After power supply to each part of the mobile device 10 is turned on in step S405, it is determined in step S406 whether or not an operation is not accepted for a predetermined period. If the determination is yes, the flow proceeds to step S407. On the other hand, if a negative determination is made, the flow returns to step S406, and the standby for the operation is continued.

  If the determination in step S406 is yes, in step S407, it is determined whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S408, and after the power supply unit 14 is controlled to turn off the power supply to each unit of the mobile device 10, the flow returns to step S401. It is. On the other hand, if a negative determination is made, the flow is returned to step S406, and the standby for the operation is continued.

  On the other hand, if a negative determination is made in step S403, a determination is made in step S409 as to whether a predetermined time has elapsed since the positive determination was made in step S401. If the determination is yes, the flow proceeds to step S411, and after the power supply unit 14 is controlled to turn off the power supply to the temperature sensor 17 and the acceleration sensor 19, the flow proceeds to step S411. It returns to S401. On the other hand, if a negative determination is made, the flow is returned to step S403, and monitoring of the temperature rise is continued.

  If no determination is made in step S404, it is determined in step S410 whether or not the temperature sensor 17 has detected a temperature decrease exceeding a predetermined decrease gradient value. If the determination is yes, the flow proceeds to step S411, and after the power supply unit 14 is controlled to turn off the power supply to the temperature sensor 17 and the acceleration sensor 19, the flow proceeds to step S411. It returns to S401. On the other hand, if a negative determination is made, the flow is returned to step S404, and the satisfaction monitoring of the acceleration condition is continued.

  According to the power on / off control based on the fourth operation example, when the user starts using the mobile device 10, the temperature of the portion touched by the user's hand or finger increases as the user holds the mobile device 10 by hand. It is possible to detect that the portion touched by the user's hand or finger has become dark and that acceleration has occurred in the mobile device 10 and turn on the power supply to each part of the mobile device 10. Become. Further, according to the power on / off control based on the fourth operation example, when the use of the mobile device 10 is ended, as in the first operation example, when the user releases the mobile device 10 from the hand, It is possible to turn off the power supply to each part of the mobile device 10 by detecting the temperature drop of the part touched by the hand or finger.

  That is, according to the power on / off control based on the fourth operation example, an active operation (pressing or touching) for power on / off is performed as in the first to third operation examples. It is possible to appropriately turn on / off the power supply to each part of the mobile device 10 without requesting the user and with higher accuracy than the power on / off control based on the first operation example described above.

  Although not shown again, the illuminance sensor 18 in the fourth operation example can be replaced with the proximity sensor 18 ′, as in the relationship between the second operation example and the third operation example.

<Other variations>
The configuration of the present invention can be variously modified in addition to the above-described embodiment without departing from the gist of the invention. That is, the above-described embodiment is an example in all respects and should not be considered as limiting, and the technical scope of the present invention is not the description of the above-described embodiment, but the claims. It should be understood that all modifications that come within the meaning and range of equivalents of the claims are included.

  For example, in the second embodiment, in the second operation example to the fourth operation example of the power on / off control, only the power supply to the main sensor is always turned on, and the power supply to other than the main sensor is appropriately turned on / off as necessary. Although the description has been given by taking the configuration to be turned off as an example, the configuration of the present invention is not limited to this, and the power supply to all sensors may be always turned on. When the latter configuration is adopted, steps S202 and S210 in FIG. 3, steps S302 and S310 in FIG. 4, and steps S402 and S411 in FIG. 5 are all unnecessary.

  In addition, without providing a master-slave relationship between the temperature sensor 17, the illuminance sensor 18, and the acceleration sensor 19, when all the sensors satisfy a predetermined power-on condition, power is supplied to each part of the mobile device 10. Even when the power on / off control is performed by the control unit 15 so that the power supply to each part of the portable device 10 is turned off when the power on condition is not satisfied by at least one sensor. I do not care.

  INDUSTRIAL APPLICABILITY The present invention can be usefully used as a technique for improving the convenience of a mobile device (a mobile phone, a portable game machine, a portable electronic notebook, a remote controller, etc.).

DESCRIPTION OF SYMBOLS 10 Mobile device 11 Display part 12 Operation part 13 Memory | storage part 14 Power supply part 15 Control part 16 Function part 17 Temperature sensor 18, 18-1, 18-2 Illuminance sensor 18 ', 18-1', 18-2 'Proximity sensor 19 Acceleration sensor A11, A21, A31, A41 Location of temperature sensor B11, B21, B31, B41 Location of first illuminance sensor B12, B22, B32, B42 Location of second illuminance sensor

Claims (13)

A power supply for supplying power to each part of the mobile device;
A temperature sensor;
A control unit that controls the power supply unit to turn on / off the power supply to each unit of the mobile device based on the detection result of the temperature sensor;
A portable device characterized by comprising:   The portable device according to claim 1, wherein the temperature sensor is installed at a location where a part of a user's body abuts or approaches in the use state of the portable device.   The portable device according to claim 2, wherein the temperature sensor is installed on a side surface of the portable device. It further has an operation unit that receives user operations,
The portable device according to claim 2, wherein the temperature sensor is installed at or near the operation unit.   The control unit turns on the power supply to each part of the portable device when a temperature rise exceeding a predetermined rising gradient value is detected by the temperature sensor, and conversely, a temperature exceeding a predetermined decreasing gradient value by the temperature sensor. The portable device according to any one of claims 2 to 4, wherein the power supply unit is controlled so that power supply to each part of the portable device is turned off when a decrease is detected. An illuminance sensor,
Even when the temperature sensor detects a temperature increase exceeding a predetermined rising gradient value, the control unit is directed to each part of the mobile device if the illuminance detected by the illuminance sensor exceeds a predetermined threshold value. The portable device according to claim 5, wherein the power supply unit is controlled so as not to turn on the power supply. It further has first and second illuminance sensors installed at different locations,
Even when the control unit detects a temperature increase exceeding a predetermined increase gradient value by the temperature sensor, if the detection results obtained by the first and second illuminance sensors match, The portable device according to claim 5, wherein the power supply unit is controlled so that power supply to each part of the portable device is not turned on. The first illuminance sensor is installed at a location where a part of the user's body abuts or approaches in the use state of the portable device,
The mobile device according to claim 7, wherein the second illuminance sensor is installed at a location where a part of the user's body is not in contact with or in close proximity when the mobile device is in use. It further has a folding mechanism or a sliding mechanism,
The portable device according to claim 8, wherein the second illuminance sensor is installed at a place where a light irradiation state changes according to an open / close state of the folding mechanism or the slide mechanism. A further proximity sensor,
Even when the temperature sensor detects a temperature increase exceeding a predetermined rising gradient value by the temperature sensor, if the proximity sensor does not detect a contact or proximity of a part of the user's body, The portable device according to claim 5, wherein the power supply unit is controlled so that power supply to each part of the portable device is not turned on. A first proximity sensor and a second proximity sensor installed at different locations;
Even if the temperature rise exceeding a predetermined rising gradient value is detected by the temperature sensor, the control unit, if the detection results obtained by the first and second proximity sensors match, The portable device according to claim 5, wherein the power supply unit is controlled so that power supply to each part of the portable device is not turned on. The first proximity sensor is installed at a location where a part of the user's body abuts or approaches in the use state of the portable device,
The mobile device according to claim 11, wherein the second proximity sensor is installed at a location where a part of the user's body does not come into contact with or close to the mobile device when the mobile device is in use. An acceleration sensor;
Even when the temperature sensor detects a temperature increase exceeding a predetermined rising gradient value, the control unit is directed to each part of the portable device if the acceleration detected by the acceleration sensor is below a predetermined threshold value. The portable device according to any one of claims 5 to 12, wherein the power supply unit is controlled so as not to turn on the power supply.

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