JP6396680B2 - Communication terminal - Google Patents

Description

  The present invention relates to a communication terminal, and relates to a device that communicates with another communication terminal, such as a mobile router device.

  In recent years, there has been proposed a communication terminal that measures the temperature of a communication terminal during communication and suppresses the temperature rise when the measured temperature is equal to or higher than a threshold value.

  In the technique described in Patent Document 1, when the temperature of the device becomes equal to or higher than a threshold value, the temperature rise of the device is suppressed by controlling the charging current and the charging voltage to the secondary battery.

  In the technique described in Patent Literature 2, when any contact is detected with a touch sensor installed in a receiver unit of a mobile phone, charging of the mobile phone is stopped to suppress an increase in temperature of the mobile phone.

  In the technique described in Patent Document 3, a plurality of temperature threshold values inside the electronic device are set, and the temperature threshold value is switched based on the temperature inside the electronic device when contact with a human body is detected. And when the temperature inside an electronic device exceeds a temperature threshold value, the temperature rise inside an electronic device is suppressed by stopping charge of an electronic device.

  As a reference technique of the present invention, for example, a technique described in Patent Document 4 is disclosed.

JP 2006-230080 A JP 2007-166500 A JP 2010-124246 A JP 2011-114390 A

  However, in the techniques described in Patent Documents 1, 2, and 3, charging current or current voltage is controlled or charging is stopped as means for suppressing a temperature increase of the terminal (device).

  On the other hand, factors other than charging are also known as factors for the temperature rise of the terminal. For example, when viewing a moving image stream, the wireless unit operates continuously, and the processing of the control unit also increases. For this reason, the temperature of the terminal may rise. In this case, even if charging is stopped, the temperature of the terminal rises. For this reason, even if charging is stopped while the terminal is being operated, the terminal user may feel uncomfortable due to the temperature rise of the terminal.

  Further, since the technique described in Patent Document 1 is a technique for suppressing the temperature rise of the terminal by charging control, there is a problem that charging stops when the threshold value is exceeded even a little.

  Even in the technology described in Patent Document 2, if any touch is detected by a touch sensor provided in the receiver unit even for a short time, charging of the terminal is stopped even when the temperature of the terminal is relatively low. There was a problem. In other words, if the touch sensor detects any contact even a little, charging stops and there is a problem that the convenience for the user is impaired.

  In the technique described in Patent Document 3, in order to cope with the problem of the technique described in Patent Document 2, the temperature threshold is changed according to the detection time of the human sensor, and charging is stopped. Temperature rise is suppressed. However, in the technique described in Patent Document 3, the detection by the human sensor is performed only when the terminal is operated, for example, when viewing moving image streaming. For this reason, there was a problem that fine temperature control by the detection time of the human sensor could not be performed.

  This invention is made | formed in view of such a situation, The objective of this invention provides the communication terminal which can control the temperature rise of a communication terminal appropriately according to the use condition of a communication terminal. There is.

  The communication terminal of the present invention is preset with a communication unit that communicates information with other communication terminals, a temperature detection unit that detects a temperature inside the terminal, and a detected temperature detected by the temperature detection unit. A temperature comparison unit that compares the detected temperature threshold, a human body contact detection unit that detects that a part of the human body contacts the terminal surface, a comparison result by the temperature comparison unit, and a detection result by the human body contact detection unit And a control unit for controlling the operation of the communication unit.

  According to the communication terminal concerning this invention, the temperature rise of a communication terminal can be appropriately controlled according to the use condition of a communication terminal.

It is a block diagram which shows the structure of the communication terminal in the 1st Embodiment of this invention. It is an external view of the communication terminal in the 1st Embodiment of this invention. Fig.2 (a) is a top view which shows the surface of the communication terminal in the 1st Embodiment of this invention. FIG.2 (b) is a figure which shows the side surface of the communication terminal in the 1st Embodiment of this invention, Comprising: It is a figure which shows the arrow A of FIG. 2 (a). FIG.2 (c) is a figure which shows the back surface of the communication terminal in the 1st Embodiment of this invention, Comprising: It is a figure which shows the arrow C of Fig.2 (a). FIG.2 (d) is a figure which shows the side surface of the communication terminal in the 1st Embodiment of this invention, Comprising: It is a figure which shows the arrow B of Fig.2 (a). It is a figure which shows the operation | movement flow of the communication terminal in the 1st Embodiment of this invention. It is a figure which shows the operation | movement flow of the communication terminal in the 2nd Embodiment of this invention. It is a block diagram which shows the structure of the communication terminal in the 3rd Embodiment of this invention. It is a block diagram which shows the structure of the communication terminal in the 4th Embodiment of this invention. It is a figure which shows the operation | movement flow of the communication terminal in the 4th Embodiment of this invention.

<First Embodiment>
The configuration of communication terminal 1000 in the first embodiment of the present invention will be described.

  FIG. 1 is a block diagram showing a configuration of communication terminal 1000.

  The communication terminal 1000 is, for example, a router device, a mobile phone, or a portable information terminal. FIG. 1 illustrates a mobile router device. The communication terminal 1000 can be used not only in the hand, but also in a bag or on a desk. As a result, the communication terminal 1000 can also relay communication on the WAN (Wide Area Network) side to communication on the LAN (Local Area Network) side, as will be described later.

  As shown in FIG. 1, the communication terminal 1000 includes a WAN communication unit 110, a WAN communication antenna 120, a LAN communication unit 130, a LAN communication antenna 140, a temperature detection unit 150, and a temperature comparison unit 160. The human body contact detection unit 170, the memory unit 180, the display unit 190, and the control unit 200 are provided.

  As shown in FIG. 1, the WAN communication unit 110 is connected to the WAN communication antenna 120 and the control unit 200. The WAN communication unit 110 communicates information with other communication terminals (not shown). More specifically, the WAN communication unit 110 is a communication method (for example, W-CDMA (Wideband Code Division Multiple Access), WiMAX (Worldwide Interoperability for Microwave) provided by a communication carrier (for example, NTT DoCoMo, Softbank, etc.). Access)) or a communication method (for example, WLAN) that performs communication via a wireless router from a high-speed communication network, communicates with another communication terminal (not shown).

  As shown in FIG. 1, the WAN communication unit 110 includes a distributor 111, a receiving unit 112, a power amplifier 113, and a WAN side modem unit 114. The WAN communication unit 110 corresponds to the communication unit of the present invention.

  The distributor 111 is connected to the WAN communication antenna 120, the receiving unit 112, and the power amplifier 113. The distributor 111 distributes information input to the WAN communication antenna 120 to the receiving unit 112. The distributor 111 distributes information input from the power amplifier 113 to the WAN communication antenna 120.

  The receiving unit 112 is connected to the distributor 111 and the WAN side modem unit 114. The receiving unit 112 receives information input to the WAN communication antenna 120. That is, the receiving unit 112 receives information from other communication terminals (not shown) via the WAN communication antenna 120. Then, the reception unit 112 outputs information from another communication terminal (not shown) to the WAN side modem unit 114.

  The power amplifier 113 is connected to the distributor 111 and the WAN side modem unit 114. The power amplifier 113 amplifies the information modulated by the WAN modem unit 114 and outputs the amplified information to the distributor 111.

  The WAN-side modem unit 114 is connected to the receiving unit 112 and the power amplifier 113. The WAN side modem unit 114 demodulates received data. Specifically, the WAN modem unit 114 demodulates information input by the receiving unit 112. Then, the WAN-side modem unit 114 outputs the demodulated information to the control unit 200. The WAN modem unit 114 modulates transmission data. Specifically, the WAN side modem unit 114 modulates information generated by the control unit 200. Then, the WAN-side modem unit 114 outputs the modulated information to the power amplifier 113.

  The WAN communication antenna 120 is connected to the distributor 111. The WAN communication antenna 120 converts radio waves including information transmitted from other communication terminals (not shown) into signals. The converted information is acquired by the receiving unit 112. The WAN communication antenna 120 places a radio wave on the information amplified by the power amplifier 113, and then outputs the radio wave including the information to another communication terminal (not shown).

  As shown in FIG. 1, the LAN communication unit 130 is connected to the LAN communication antenna 140 and the control unit 200. The LAN communication unit 110 communicates information with other communication terminals (not shown). The LAN communication unit 130 relays WAN-side communication to a communication terminal such as a personal computer or a smartphone using WLAN.

  The LAN communication unit 130 includes a distributor 131, a reception unit 132, a power amplifier 133, and a LAN side modem unit 134. The WAN communication unit 110 corresponds to the communication unit of the present invention.

  The distributor 131 is connected to the LAN communication antenna 140, the receiving unit 132, and the power amplifier 133. The distributor 131 distributes information input to the LAN communication antenna 140 to the receiving unit 132. The distributor 131 distributes information input from the power amplifier 133 to the LAN communication antenna 140.

  The receiving unit 132 is connected to the distributor 131 and the LAN side modem unit 134. The receiving unit 132 receives information input to the LAN communication antenna 140. That is, the receiving unit 132 receives information from other communication terminals (not shown) via the LAN communication antenna 140. Then, the reception unit 132 outputs information from another communication terminal (not shown) to the LAN side modem unit 134.

  The power amplifier 133 is connected to the distributor 131 and the LAN side modem unit 134. The power amplifier 133 amplifies the information modulated by the LAN modem unit 134 and outputs the amplified information to the distributor 111.

  The LAN side modem unit 134 is connected to the receiving unit 132 and the power amplifier 133. The LAN side modem unit 134 demodulates received data. Specifically, the LAN side modem unit 134 demodulates information input by the receiving unit 132. Then, the LAN side modem unit 134 outputs the demodulated information to the control unit 200. The LAN modem unit 134 modulates transmission data. Specifically, the LAN side modem unit 134 modulates information generated by the control unit 200. Then, the LAN side modem unit 134 outputs the modulated information to the power amplifier 133.

  The LAN communication antenna 140 is connected to the distributor 131. The LAN communication antenna 140 converts radio waves including information transmitted from other communication terminals (not shown) into signals. The converted information is acquired by the receiving unit 132. Further, the LAN communication antenna 140 places a radio wave on the information amplified by the power amplifier 133 and then outputs the radio wave including the information to another communication terminal (not shown).

  As shown in FIG. 1, the temperature detection unit 150 is connected to the control unit 200. The temperature detection unit 150 detects the temperature inside the communication terminal 1000 as the detection temperature TA. The temperature detection unit 150j is also called a temperature sensor.

  As shown in FIG. 1, the temperature comparison unit 160 is connected to the control unit 200. The temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with preset temperature thresholds (for example, T1 and T2). Here, the temperature threshold T1 is a temperature defined as a limit temperature in a predetermined standard. Here, as an example, the temperature threshold value T1 indicates a temperature defined as a standard in a standard (for example, IEC609950) of an electrical appliance. It is assumed that the communication terminal 1000 can perform high-speed communication until the detected temperature TA rises to the temperature threshold T1. The temperature threshold T2 is a temperature at which a part of the human body is felt uncomfortable. When the user of the communication terminal 1000 picks up the communication terminal 1000 and confirms the display content of the display unit 190 of the communication terminal 1000, if the temperature of the terminal surface of the communication terminal 1000 is increased, the user is uncomfortable. I may feel it. Assuming such a situation, the temperature threshold T2 is set. The temperature threshold T2 may be set according to the subjectivity of a specific person, or may be set according to an average value of temperatures at which a plurality of persons feel uncomfortable.

  As shown in FIG. 1, the human body contact detection unit 170 is connected to the control unit 200. Human body contact detection unit 170 detects that a part of the human body is in contact with the terminal surface of communication terminal 1000. The human body contact detection unit 170 is also called a touch sensor.

  Here, an installation example of the human body contact detection unit 170 will be described. FIG. 2 is an external view of the communication terminal 1000. FIG. 2A is a plan view showing the surface of the communication terminal 1000. FIG. 2B is a diagram illustrating a side surface of the communication terminal 1000, and is a diagram illustrating an arrow A in FIG. FIG. 2C is a diagram showing the back surface of the communication terminal 1000 and is a diagram showing an arrow C in FIG. FIG. 2D is a diagram showing a side view of the communication terminal 1000 and is a diagram showing an arrow B in FIG.

  As shown in FIGS. 2A to 2D, two human body contact detection units 170 are provided on the terminal surface of the communication terminal 1000. As shown in FIGS. 2A to 2D, the two human body contact detection units 170 are provided on the side surface of the communication terminal 1000 so as to extend on the front surface and the back surface of the communication terminal 1000. Display unit 190 is provided so as to be exposed on the surface of communication terminal 1000.

  Returning to FIG. 1, the memory unit 180 is connected to the control unit 200. The memory unit 180 stores installation values used in the communication terminal 1000. Specifically, the memory unit 180 stores a temperature threshold T1, a temperature threshold T2, and the like.

  As shown in FIG. 1, the display unit 190 is connected to the control 200. The display unit 190 provides information generated by the control unit 200 and the like. As shown in FIG. 2A, the display unit 190 is provided so as to be exposed on the surface of the communication terminal 1000.

  As shown in FIG. 1, the control unit 200 is connected to the WAN communication unit 110, the LAN communication unit 130, the temperature detection unit 150, the temperature comparison unit 160, the human body contact detection unit 170, the memory unit 180, and the display unit 190. Yes. The control unit 200 controls all the components included in the communication terminal 1000. In particular, the control unit 200 controls the operations of the WAN communication unit and the LAN communication unit 120 based on the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170. Further, the control unit 200 determines the communication speed according to the communication data amount and the communication environment. Whether the communication environment is good or bad is determined based on a reception level when a signal is received from another communication terminal (not shown, such as a smartphone) communicating with the communication terminal 1000. The higher the reception level, the better the communication environment, so high-speed communication is possible. If the communication environment is good, the communication terminal 1000 communicates at the maximum transmission rate. When the communication terminal 1000 is a movable mobile router, the communication terminal 1000 may communicate with a smart phone or a personal computer that relays communication at a short distance. Since communication at a short distance is also strong against external interference, the communication terminal 1000 communicates at the maximum transmission speed.

  The configuration of the communication terminal 1000 has been described above.

  Next, the operation of the communication terminal 1000 will be described.

  FIG. 3 is a diagram showing an operation flow of the communication terminal 1000.

  As shown in FIG. 3, after the communication terminal 1000 starts communication, the temperature detection unit 150 measures the temperature inside the communication terminal 1000 (S301).

  Next, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T1 (S302). As described above, the temperature threshold T1 is a temperature defined as a limit temperature in a predetermined standard. More specifically, the temperature threshold value T1 refers to a temperature defined as a standard in electrical equipment standards (for example, IEC609950).

  If the temperature comparison unit 160 determines that the temperature threshold T1 is not higher than the detected temperature TA (No in S302), the control unit 200 immediately stops the operations of both the WAN communication unit 110 and the LAN communication unit 130. As a result, the function is stopped (S307). Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T1. As a result, the danger that the communication terminal 1000 is damaged by heat can be avoided in advance.

  If the temperature comparison unit 160 determines that the temperature threshold T1 is higher than the detected temperature TA (Yes in S302), the human body contact detection unit 170 is activated by the control unit 200, and a part of the human body is a terminal of the communication terminal 1000. A contact with the surface is detected (S303).

  When the human body contact detection unit 170 does not detect that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (No in S303), the communication terminal 1000 returns to the process of S301 and repeats the processes after S301. . During this time, the communication terminal 1000 continues communication without any communication restriction.

  When the human body contact detection unit 170 detects that a part of the human body contacts the terminal surface of the communication terminal 1000 (S303, Yes), the human body contact detection unit 170 is stopped by the control unit 200, and the control unit 200 performs WAN communication. The communication control is performed by restricting the operation of the unit 110 or the LAN communication unit 130 (S304). Here, for example, the control unit 200 stops the operation of either the WAN communication unit 110 or the LAN communication unit 130. Alternatively, the control unit 200 may stop the operation of any one of the WAN communication unit 110 and the LAN communication unit 130. Furthermore, the control unit 200 may stop some operations of both the WAN communication unit 110 and the LAN communication unit 130. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the WAN communication unit 110, the LAN communication unit 130, and the control unit 200 is also suppressed.

  After the process of S304, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T2 (S305). As described above, the temperature threshold T2 is a temperature at which a part of the human body is felt uncomfortable.

  If the temperature comparison unit 160 determines that the detected temperature TA is not higher than the temperature threshold T2 (S305, No), the communication terminal 1000 repeats the processing from S303 onward.

  When the temperature comparison unit 160 determines that the detected temperature TA is higher than the temperature threshold T2 (S305, Yes), the human body contact detection unit 170 is activated again by the control unit 200, and a part of the human body is communicated with the communication terminal 1000. It is detected that the terminal surface is touched (S306).

  When the human body contact detection unit 170 does not detect that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (No in S306), the control unit 200 cancels the communication control performed in S304 (S308). . The communication terminal 1000 returns to the process of S301 after the process of S308, and repeats the process after S301. During this time, the communication terminal 1000 continues communication without any communication restriction.

  When the human body contact detection unit 170 detects that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (Yes in S306), the control unit 200 immediately determines both of the WAN communication unit 110 and the LAN communication unit 130. The operation is stopped by stopping the operation (S307). Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T2 considered uncomfortable when a part of human body contacts. As a result, even if a part of the human body touches the surface of the communication terminal 1000, the user of the communication terminal 1000 can be prevented from feeling uncomfortable.

  As described above, the communication terminal 1000 according to the first embodiment of the present invention includes the communication unit (WAN communication unit 110, LAN communication unit 120), temperature detection unit 150, temperature comparison unit 160, and human body contact detection unit. 170 and a control unit 200.

  The communication unit communicates information with other communication terminals. The temperature detection unit 150 detects the temperature inside the communication 1000. The temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with preset temperature thresholds T1 and T2. Human body contact detection unit 170 detects that a part of the human body is in contact with the surface of communication terminal 1000. The control unit 200 controls the operation of the communication unit based on the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170.

  In this way, by comparing the detected temperature TA with the temperature thresholds T1 and T2 by the temperature comparison unit 160, whether or not the temperature inside the communication terminal 1000 is higher than the preset temperature thresholds T1 and T2. Can be detected. Further, the human body contact detection unit 170 can detect whether a part of the human body has contacted the surface of the communication terminal 1000. The control unit 200 controls the operation of the communication unit based on the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170. A plurality of combinations of the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170 can be set, and various operation controls for the communication unit can be set for each of the plurality of combinations. As a result, according to the communication terminal 1000 of the present invention, the temperature increase of the communication terminal 1000 can be appropriately controlled according to various usage states of the communication terminal 1000. At this time, it is not necessary to change the communication protocol of the entire communication system (not shown) including the base station (not shown). That is, the communication terminal 1000 of the present invention can cope with all existing communication systems.

  In communication terminal 1000 according to the first embodiment of the present invention, temperature comparison unit 160 includes detected temperature TA detected by temperature detection unit 150, a first temperature threshold value T1 set in advance, and a preset value. The second temperature threshold value T2 (where T1> T2) is compared. The first temperature threshold value T1 is a temperature defined as a limit temperature by a predetermined standard, and the second temperature threshold value T2 is a temperature at which a part of the human body is felt uncomfortable.

  When the detected temperature TA is higher than the first temperature threshold value T1 (TA> T1), the control unit 200 operates the communication unit (WAN communication unit 110, LAN communication unit 120) when it is determined by the temperature comparison unit 160. Control to stop. Thereby, when the detected temperature TA is higher than the first temperature threshold T1, the operation of the communication unit can be completely stopped. And it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T1. As a result, the danger that the communication terminal 1000 is damaged by heat can be avoided in advance.

  When the detected temperature TA is higher than the first temperature threshold T2 and lower than the first temperature threshold T1 (T1> TA> T2), the temperature comparison unit 160 determines that the human body contact detection unit When 170 detects that a part of the human body has contacted the surface of the communication terminal 1000, the control unit 200 performs control to stop the operation of the communication unit. Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T2 considered uncomfortable when a part of human body contacts. As a result, even if a part of the human body touches the surface of the communication terminal 1000, the user of the communication terminal 1000 can be prevented from feeling uncomfortable.

  When the detected temperature TA is lower than the first temperature threshold value T1 (T1> TA), the temperature comparison unit 160 determines that the human body contact detection unit 170 is in contact with the surface of the communication terminal 1000. When the control unit 200 detects that the communication unit is detected, the control unit 200 performs control to limit the operation of the communication unit. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the communication unit and the control unit 200 is also suppressed.

  In the communication terminal 1000 according to the first embodiment of the present invention, the temperature comparison unit 160 compares the detected temperature TA with the first temperature threshold T1, and then compares the detected temperature TA with the second temperature threshold T2. Compare. Thereby, it can be detected earlier that the temperature inside the communication terminal 1000 has reached the second temperature threshold value T2. As a result, when the detected temperature TA becomes higher than the first temperature threshold T1, the operation of the communication unit can be completely stopped early. Thereby, it can suppress early that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T1. As a result, the danger that the communication terminal 1000 is damaged by heat can be avoided in advance.

  In communication terminal 1000 according to the first embodiment of the present invention, control unit 200 controls the operation of the communication unit based on the comparison result by temperature comparison unit 160 and the detection result by human body contact detection unit 170. The operation of the human body contact detection unit 170 is controlled. That is, in order to suppress an increase in temperature inside the communication terminal 1000, the control unit 200 not only stops or restricts the operation of the communication unit, but also stops the operation of the human body contact detection unit 170. Thereby, not only the heat generated by the operation of the communication unit, but also the heat generated by the operation of the human body contact detection unit 170 can be suppressed. As a result, the temperature rise of the communication terminal can be reduced more appropriately.

  In communication terminal 1000 according to the first embodiment of the present invention, human body contact detection unit 170 is provided so as to be exposed on the surface of communication terminal 1000. Thereby, the human body contact detection unit 170 can accurately detect that a part of the human body touches the surface of the communication terminal 1000.

<Second Embodiment>
The operation of communication terminal 1000 in the second embodiment of the present invention will be described. The configuration of communication terminal 1000 in the second embodiment is the same as that described with reference to FIGS.

  FIG. 4 is a diagram showing an operation flow of the communication terminal 1000 according to the second embodiment of the present invention.

  Here, FIG. 3 and FIG. 4 are compared. In FIG. 3, the detection result by the human body contact detection unit 170 has priority over the comparison result by the temperature comparison unit 160. For this reason, if a part of the human body contacts the surface of the communication terminal, the communication control is forcibly performed even if the detected temperature TA is lower than the second temperature threshold T2 (S304 in FIG. 3). On the other hand, in FIG. 4, the human body contact detection unit 170 does not detect that a part of the human body contacts the surface of the communication terminal 1000 until the detected temperature TA exceeds the second temperature threshold T2. In this respect, FIG. 3 and FIG. 4 are different from each other. That is, FIG. 4 differs from FIG. 3 in that the process of S410 is newly provided between the processes of S301 and S302.

  As shown in FIG. 4, after the communication terminal 1000 starts communication, the temperature detection unit 150 measures the temperature inside the communication terminal 1000 (S301).

  Next, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T2 (S410). As described above, the temperature threshold T2 is a temperature at which a part of the human body is felt uncomfortable.

  If the detected temperature TA is not higher than the temperature threshold value T2, if it is determined by the temperature comparison unit 160 (S410, No), the processing after S301 is repeated.

  If the temperature comparison unit 160 determines that the detected temperature TA is higher than the temperature threshold T2 (S410, Yes), the temperature comparison unit 160 compares the detected temperature TA with the temperature threshold T1 (S302).

  Next, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T1 (S302). As described above, the temperature threshold T1 is a temperature defined as a limit temperature in a predetermined standard. More specifically, the temperature threshold value T1 refers to a temperature defined as a standard in electrical equipment standards (for example, IEC609950).

  When the temperature comparison unit 160 determines that the temperature threshold T1 is not higher than the detected temperature TA (No in S302), the control unit 200 immediately stops the operations of the WAN communication unit 110 and the LAN communication unit 130. Thus, the function is stopped (S307). Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T1. As a result, the danger that the communication terminal 1000 is damaged by heat can be avoided in advance.

  If the temperature comparison unit 160 determines that the temperature threshold T1 is higher than the detected temperature TA (Yes in S302), the human body contact detection unit 170 is activated by the control unit 200, and a part of the human body is a terminal of the communication terminal 1000. A contact with the surface is detected (S303).

  When the human body contact detection unit 170 does not detect that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (S303, No), the process returns to the process of S301, and the processes after S301 are repeated. During this time, the communication terminal 1000 continues communication without any communication restriction.

  When the human body contact detection unit 170 detects that a part of the human body contacts the terminal surface of the communication terminal 1000 (S303, Yes), the human body contact detection unit 170 is stopped by the control unit 200, and the control unit 200 performs WAN communication. The communication control is performed by restricting the operation of the unit 110 or the LAN communication unit 130 (S304). Here, for example, the control unit 200 stops the operation of either the WAN communication unit 110 or the LAN communication unit 130. Alternatively, the control unit 200 may stop the operation of any one of the WAN communication unit 110 and the LAN communication unit 130. Furthermore, the control unit 200 may stop some operations of both the WAN communication unit 110 and the LAN communication unit 130. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the WAN communication unit 110, the LAN communication unit 130, and the control unit 200 is also suppressed.

  After the process of S304, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T2 (S305). As described above, the temperature threshold T2 is a temperature at which a part of the human body is felt uncomfortable.

  If the detected temperature TA is not higher than the temperature threshold value T2, if it is determined by the temperature comparison unit 160 (S305, No), the processing after S303 is repeated.

  When the temperature comparison unit 160 determines that the detected temperature TA is higher than the temperature threshold T2 (S305, Yes), the human body contact detection unit 170 is activated again by the control unit 200, and a part of the human body is communicated with the communication terminal 1000. It is detected that the terminal surface is touched (S306).

  When the human body contact detection unit 170 does not detect that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (No in S306), the control unit 200 cancels the communication control performed in S304 (S308). . The communication terminal 1000 returns to the process of S301 after the process of S308, and repeats the process after S301. During this time, the communication terminal 1000 continues communication without any communication restriction.

  When the human body contact detection unit 170 detects that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (S306, Yes), the control unit 200 immediately operates the WAN communication unit 110 and the LAN communication unit 130. The function is stopped by stopping (S307). Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T2 considered uncomfortable when a part of human body contacts. As a result, even if a part of the human body touches the surface of the communication terminal 1000, the user of the communication terminal 1000 can be prevented from feeling uncomfortable.

  Even with such a configuration, the same effects as those described in the first embodiment can be obtained.

  Moreover, in the communication terminal 1000 in the second embodiment of the present invention, the temperature comparison unit 160 compares the detected temperature TA with the second temperature before comparing the detected temperature TA with the first temperature threshold T1 (S302). The threshold value T2 is compared (S410). This also has the same effect as the contents described in the first embodiment. Further, it is possible to set so that the human body contact detection unit 170 does not detect that a part of the human body contacts the surface of the communication terminal 1000 until the detected temperature TA exceeds the second temperature threshold T2.

<Third Embodiment>
The configuration of communication terminal 1000A in the third embodiment of the present invention will be described.

  FIG. 5 is a block diagram showing a configuration of communication terminal 1000A. In FIG. 5, constituent elements that are equivalent to the constituent elements shown in FIGS. 1 to 4 are given the same reference numerals as those shown in FIGS. 1 to 4.

  The communication terminal 1000A is, for example, a router device, a mobile phone, or a portable information terminal. FIG. 5 illustrates a mobile router device having a WLAN (Wireless LAN) MINO (multiple-input and multiple-output) function. The communication terminal 1000A can be used not only in the hand, but also in a bag or on a desk.

  As shown in FIG. 5, the communication terminal 1000A includes a pair of LAN communication units 130, a pair of LAN communication antennas 140, a temperature detection unit 150, a temperature comparison unit 160, a human body contact detection unit 170, and a memory. Unit 180, display unit 190, and control unit 200. The LAN communication unit 130 corresponds to the communication unit of the present invention.

  Here, FIG. 1 and FIG. 5 are compared. In FIG. 1, the communication terminal 1000 includes a WAN communication unit 110 and a LAN communication unit 130 as communication units. In contrast, in FIG. 5, the communication terminal 1000 </ b> A includes a pair of LAN communication units 130 as communication units. In this respect, FIGS. 1 and 5 are different from each other.

  In FIG. 1, the communication terminal 1000 includes the WAN antenna 120 connected to the WAN communication unit 110. In contrast, in FIG. 5, the communication terminal 1000 </ b> A does not include the WAN antenna 120. Instead, the communication terminal 1000A includes a pair of LAN antennas 140. Also in this respect, FIG. 1 and FIG. 5 are different from each other.

  As shown in FIG. 5, each of the pair of LAN communication units 130 is connected to the control unit 200 and the LAN antenna 140.

  The specific functions of the components shown in FIG. 5 are the same as those described in the first embodiment.

  The configuration of the communication terminal 1000A has been described above.

  Next, the operation of communication terminal 1000A will be described.

  The operation flow of the communication terminal 1000A is the same as that shown in FIGS.

  On the other hand, the operation of the communication terminal 1000A is different from the first embodiment in the processing contents of S304 and S307, and will be described below.

  In S304, the human body contact detection unit 170 is stopped by the control unit 200, and the control unit 200 performs communication control by restricting the operations of the pair of LAN communication units 130. Here, for example, the control unit 200 stops one operation of the pair of LAN communication units 130. Alternatively, the control unit 200 may stop the operation of one part of the pair of LAN communication units 130. Furthermore, the control unit 200 may stop some operations of both of the pair of LAN communication units 130. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the LAN communication unit 130 and the control unit 200 is also suppressed. In particular, when communicating with a communication carrier using W-CDMA or the like, since the communication route and the like are controlled by the base station, it is necessary to set only for WLAN connection.

  In S307, the control unit 200 immediately stops functioning by stopping the operations of both the pair of LAN communication units 130 (S307). Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T1. As a result, the danger that the communication terminal 1000 is damaged by heat can be avoided in advance.

  As described above, the communication terminal 1000A according to the third embodiment of the present invention includes a pair of communication units (LAN communication unit 130). The pair of communication units communicate information with other communication terminals. The control unit 200 controls the operation of one or both of the pair of communication units based on the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170.

  When a pair of communication units (LAN communication unit 130) operate at the same time, twice as much heat is generated as compared with the case where one communication unit operates. Therefore, the control unit 200 controls the operation of one or both of the pair of communication units based on the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170. At this time, a plurality of combinations of the comparison result by the temperature comparison unit 160 and the detection result by the human body contact detection unit 170 can be set, and various operation controls for the communication unit can be set for each of the plurality of combinations. As a result, according to the communication terminal 1000A of the present invention, the temperature rise of the communication terminal 1000A can be appropriately controlled according to the usage state of the communication terminal 1000A.

  Further, in communication terminal 1000A according to the third embodiment of the present invention, temperature comparison unit 160 has a detected temperature TA detected by temperature detection unit 150, a first temperature threshold T1 set in advance, and a preset value. The second temperature threshold value T2 (where T1> T2) is compared. The first temperature threshold value T1 is a temperature defined as a limit temperature by a predetermined standard, and the second temperature threshold value T2 is a temperature at which a part of the human body is felt uncomfortable.

  When the detected temperature TA is higher than the first temperature threshold value T1 (TA> T1), when the temperature comparison unit 160 determines that the control unit 200 performs the operations of both the pair of communication units (LAN communication unit 120). Control to stop. Thereby, when the detected temperature TA is higher than the first temperature threshold T1, the operations of all the communication units can be completely stopped. Thereby, it can suppress that the temperature inside communication terminal 1000A becomes higher than temperature threshold value T1. As a result, the danger that the communication terminal 1000A is damaged by heat can be avoided in advance.

  When the detected temperature TA is higher than the first temperature threshold T2 and lower than the first temperature threshold T1 (T1> TA> T2), the temperature comparison unit 160 determines that the human body contact detection unit When 170 detects that a part of the human body has contacted the surface of the communication terminal 1000, the control unit 200 performs control to stop the operations of both the pair of communication units. Thereby, it can suppress that the temperature inside the communication terminal 1000 becomes higher than the temperature threshold value T2 considered uncomfortable when a part of human body contacts. As a result, even if a part of the human body touches the surface of the communication terminal 1000, the user of the communication terminal 1000 can be prevented from feeling uncomfortable.

  When the detected temperature TA is lower than the first temperature threshold value T1 (T1> TA), the temperature comparison unit 160 determines that the human body contact detection unit 170 is in contact with the surface of the communication terminal 1000. When it is detected that the control has been performed, the control unit 200 performs control to limit the operation of at least one of the pair of communication units. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the communication unit and the control unit 200 is also suppressed.

  Here, when the communication terminal 1000 is a movable mobile router, the communication terminal 1000 may communicate with a smart phone or a personal computer that relays communication at a short distance. Since communication at a short distance is also strong against external interference, the communication terminal 1000 communicates at the maximum transmission speed. For example, when communication terminal 1000A wants to connect to another communication terminal (not shown) by MIMO communication, both of the pair of radio units operate. Thereby, the temperature inside communication terminal 1000 rises. For this reason, as described above, a method of forcibly stopping one of the pair of radio units can be used. Furthermore, when the communication terminal 1000A is performing short-range wireless communication with another communication terminal (not shown), stable communication can be maintained even if the transmission output of the communication terminal 1000A is reduced, compared to the long-range wireless communication. . For this reason, it is possible to reduce the current consumption of the power amplifier of the wireless unit by reducing the transmission output and suppress the heat generation of the wireless unit.

  In the communication terminal 1000A according to the third embodiment of the present invention, each of the pair of communication units (LAN communication unit 120) corresponds to the MIMO function. Accordingly, the communication terminal 1000A can have a MIMO function.

<Fourth embodiment>
The configuration of communication terminal 1000B in the fourth embodiment of the present invention will be described.

  FIG. 5 is a block diagram showing a configuration of communication terminal 1000B. In FIG. 6, constituent elements that are equivalent to the constituent elements shown in FIGS. 1 to 5 are assigned the same reference numerals as those shown in FIGS. 1 to 5.

  The communication terminal 1000B is, for example, a router device, a mobile phone, or a portable information terminal. FIG. 6 illustrates a mobile router device having a WLAN MINO function. The communication terminal 1000B can be used not only in the hand, but also in a bag or on a desk.

  As shown in FIG. 6, the communication terminal 1000A includes a pair of LAN communication units 130, a pair of LAN communication antennas 140, a temperature detection unit 150, a temperature comparison unit 160, a human body contact detection unit 170, and a memory. Unit 180, display unit 190, control unit 200, and WLAN communication mode detection unit 210. The LAN communication unit 130 corresponds to the communication unit of the present invention. The WLAN communication mode detection unit 210 corresponds to the communication mode detection unit of the present invention.

  Here, FIG. 5 and FIG. 6 are compared. 6 is different from FIG. 5 in that the communication terminal 1000B includes a WLAN communication mode detection unit 210.

  As shown in FIG. 6, the WLAN communication mode detection unit 210 is connected to the control unit 200.

  The WLAN communication mode detection unit 210 detects a communication mode in which different communication speeds are set and the communication terminal 1000B is communicating.

  Here, the communication mode of the WLAN is defined by IEEE (The Institute of Electrical and Electronics Engineers, Inc.). In this embodiment, it is assumed that three modes of 11b mode, 11g mode, and 11n mode are set. The 11b mode is a mode corresponding to IEEE 801.11b. The 11g mode is a mode corresponding to IEEE801.11g. The 11n mode is a mode corresponding to IEEE801.11n.

  The configuration of the communication terminal 1000B has been described above.

  Next, the operation of the communication terminal 1000B will be described. FIG. 7 is a diagram showing an operation flow of the communication terminal 1000B.

  As shown in FIG. 7, after the communication terminal 1000B starts communication, the WLAN communication mode detection unit 210 confirms the communication mode in which the communication terminal 1000B is communicating (S501). Of the three modes, 11b mode, 11g mode, and 11n mode, the mode with the largest current consumption is the 11n mode. When the communication terminal 1000B is operated in the 11n mode, the temperature inside the communication terminal 1000B is higher than in other modes. Therefore, here, the WLAN communication mode detection unit 210 determines whether or not the 11n mode is set (S502).

  When the WLAN communication mode detection unit 210 determines that the 11n mode is not set (S502, No), the communication terminal 1000B repeats the processing after S501.

  If the WLAN communication mode detection unit 210 determines that the 11n mode is set (S502, Yes), the human body contact detection unit 170 is activated by the control unit 200, and a part of the human body is on the surface of the communication terminal 1000. Is detected (S303).

  When the human body contact detection unit 170 does not detect that a part of the human body is in contact with the terminal surface of the communication terminal 1000 (S303, No), the communication terminal 1000 returns to the process of S501 and repeats the processes after S301. . During this time, the communication terminal 1000B continues communication without any communication restriction.

  When the human body contact detection unit 170 detects that a part of the human body contacts the terminal surface of the communication terminal 1000 (S303, Yes), the human body contact detection unit 170 is stopped by the control unit 200, and the control unit 200 performs WAN communication. The communication control is performed by restricting the operation of the unit 110 or the LAN communication unit 130 (S304). Here, for example, when the communication terminal 1000B communicates using MIMO, the control unit 200 stops the operation of one of the pair of LAN communication units 130. Alternatively, the control unit 200 changes the communication mode to a mode other than 11n (for example, 11g mode). Alternatively, the control unit 200 may stop the operation of any one of the pair of LAN communication units 130. Furthermore, the control unit 200 may stop some operations of both of the pair of LAN communication units 130. Thereby, the temperature rise in the communication terminal 1000 is suppressed. Further, heat generation of electronic components such as the LAN communication unit 130 and the control unit 200 is also suppressed. Here, although communication control has been described as a method for suppressing the temperature inside communication terminal 1000B from rising, a method for stopping charging of communication terminal 1000B may be employed.

  After the process of S304, the temperature comparison unit 160 compares the detected temperature TA detected by the temperature detection unit 150 with the temperature threshold T2 (S505). As described above, the temperature threshold T2 is a temperature at which a part of the human body is felt uncomfortable.

  If the temperature comparison unit 160 determines that the temperature threshold T2 is not higher than the detected temperature TA (S505, No), the communication terminal 1000B repeats the processing from S303 onward.

  When the temperature comparison unit 160 determines that the temperature threshold T2 is higher than the detected temperature TA (S505, Yes), the control unit 200 cancels the communication control performed in S304 (S308). Thereafter, the communication terminal 1000B continues communication without any communication restriction.

  Next, the WLAN communication mode detection unit 210 confirms again the communication mode in which the communication terminal 1000B is communicating (S509). Here again, the WLAN communication mode detection unit 210 determines whether or not the 11n mode is set (S510).

  When the WLAN communication mode detection unit 210 determines that the 11n mode is not set (S510, No), the communication terminal 1000B repeats the processes after S501.

  When the WLAN communication mode detection unit 210 determines that the 11n mode is set (S510, Yes), the communication terminal 1000B performs the processing after S303.

  The operation of communication terminal 1000B has been described above.

  As described above, the communication terminal 1000B according to the fourth embodiment of the present invention includes the WLAN communication mode detection unit 210 that detects communication modes in which different communication speeds are set. The control unit 200 controls the operation of the communication unit (LAN communication unit 130) based on the comparison result by the temperature comparison unit 160, the detection result by the WLAN communication mode detection unit 210, and the detection result by the human body contact detection unit 170. To do. Thereby, the communication control including the difference (communication speed) of the communication mode can be performed, and the rise in the temperature inside the communication terminal 1000B can be suppressed.

  The present invention has been described above based on the embodiment. The embodiment is an exemplification, and various modifications, increases / decreases, and combinations may be added to the above-described embodiments without departing from the gist of the present invention. It will be understood by those skilled in the art that modifications to which these changes, increases / decreases, and combinations are also within the scope of the present invention.

1000, 1000A, 1000B Communication terminal 110 WAN communication unit 111 Distributor 112 Receiving unit 113 Power amplifier 114 WAN side modem unit 120 WAN communication antenna 130 LAN communication unit 131 Distributor 132 Receiving unit 133 Power amplifier 134 LAN side modem unit 140 LAN Communication antenna 150 Temperature detection unit 160 Temperature comparison unit 170 Human body contact detection unit 180 Memory unit 190 Display unit 200 Control unit 210 WLAN communication mode detection unit

Claims (6)

A communication unit for communicating information with other communication terminals;
A temperature detector that detects the temperature inside the terminal;
A temperature comparison unit that compares the detected temperature detected by the temperature detection unit with a preset temperature threshold;
A human body contact detection unit for detecting that a part of the human body contacts the terminal surface;
A control unit for controlling the operation of the communication unit based on the comparison result by the temperature comparison unit and the detection result by the human body contact detection unit ;
The temperature comparison unit compares the detected temperature TA detected by the temperature detection unit with a preset first temperature threshold value T1 and a preset second temperature threshold value T2 (where T1> T2). And
The first temperature threshold value T1 is a temperature defined as a limit temperature in a predetermined standard, and the second temperature threshold value T2 is a temperature at which a part of the human body is felt uncomfortable,
When the detected temperature TA is higher than the first temperature threshold T1 (TA> T1), when the temperature comparing unit determines that the control unit performs control to stop the operation of the communication unit,
When the detected temperature TA is higher than the second temperature threshold T2 and lower than the first temperature threshold T1 (T1>TA> T2), the temperature comparison unit determines that When the human body contact detection unit detects that a part of the human body has contacted the terminal surface, the control unit performs control to stop the operation of the communication unit,
When the detected temperature TA is lower than the first temperature threshold value T1 (T1> TA), the temperature comparison unit determines that the human body contact detection unit has a part of the human body surface of the terminal. A communication terminal that performs control to limit the operation of the communication unit when it is detected that the contact has been made . A communication unit for communicating information with other communication terminals;
A temperature detector that detects the temperature inside the terminal;
A temperature comparison unit that compares the detected temperature detected by the temperature detection unit with a preset temperature threshold;
A human body contact detection unit for detecting that a part of the human body contacts the terminal surface;
A control unit for controlling the operation of the communication unit based on the comparison result by the temperature comparison unit and the detection result by the human body contact detection unit ;
The communication unit is paired with another communication unit that communicates information with other communication terminals,
The control unit controls the operation of one or both of the pair of communication units based on the comparison result by the temperature comparison unit and the detection result by the human body contact detection unit,
The temperature comparison unit compares the detected temperature TA detected by the temperature detection unit with a preset first temperature threshold value T1 and a preset second temperature threshold value T2 (where T1> T2). And
The first temperature threshold value T1 is a temperature defined as a limit temperature in a predetermined standard, and the second temperature threshold value T2 is a temperature at which a part of the human body is felt uncomfortable,
When the detected temperature TA is higher than the first temperature threshold value T1 (TA> T1), the control unit controls to stop the operations of both the pair of communication units when determined by the temperature comparison unit. And
When the detected temperature TA is higher than the second temperature threshold T2 and lower than the first temperature threshold T1 (T1>TA> T2), the temperature comparison unit determines that When the human body contact detection unit detects that a part of the human body is in contact with the terminal surface, the control unit performs control to stop the operation of both the pair of communication units,
When the detected temperature TA is lower than the first temperature threshold value T1 (T1> TA), the temperature comparison unit determines that the human body contact detection unit has a part of the human body surface of the terminal. A communication terminal that performs control to limit at least one operation of one of the pair of communication units. The communication terminal according to claim 2 , wherein each of the pair of communication units corresponds to a MIMO function. The control unit controls the operation of the communication unit and the operation of the human body contact detection unit based on a comparison result by the temperature comparison unit and a detection result by the human body contact detection unit. Or the communication terminal of Claim 2 . The human body contact detection unit, a communication terminal according to any one of claims 1 to 4 provided so as to expose the terminal surface. A communication mode detection unit for detecting a communication mode in which different communication speeds are set;
Wherein the control unit includes a comparison result of the temperature comparison section, and the detection result of the communication mode detection section, on the basis of the detection result of the human body contact sensing unit, according to claim 1 or claim for controlling the operation of the communication unit Item 3. The communication terminal according to Item 2 .

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