JP4661513B2 - Mobile phone - Google Patents

Description

  The present invention relates to a mobile phone, and more particularly to a mobile phone equipped with a non-contact IC card module.

  In recent years, a large number of mobile phones having a non-contact IC card module and having a non-contact communication function have been on the market. The contactless IC card module is often a module that can perform contactless communication without the need for control other than power supply, and its operating voltage range can be operated at a voltage lower than the system operating voltage of the mobile phone. ing.

As a non-contact IC card mounted on a conventional mobile phone, for example, there is one described in Patent Document 1. The non-contact IC card described in the same document has a voltage detection means for detecting a voltage supplied from the mobile phone and a leak between the mobile phone when the voltage detected by the voltage detection means exceeds a predetermined value. A non-contact communication is maintained by receiving power supply by electromagnetic induction of the non-contact part communication antenna when the current cutoff circuit is operated.
JP 2002-279378 A

  However, the prior art described in the above document is configured to receive power supply by electromagnetic induction in order to maintain non-contact communication when power supply from the mobile phone is lost. In the case of a telephone, there is a risk that undesirably affecting the system will be caused by receiving power supply by electromagnetic induction, and there is a configuration in which power is supplied within the device without receiving power supply by external electromagnetic induction. desired.

  In the case of contactless IC card modules that operate with power supplied from the battery of a mobile phone, if contactless communication fails, it is determined on the spot whether the cause is a failure or simply due to insufficient battery capacity. It is hoped that it can be done. In the conventional cellular phone, there is no means for notifying the availability of non-contact communication in the non-contact IC card module, that is, the power supply state to the non-contact IC card module when the system operation of the cellular phone is disabled.

  Some conventional cellular phones use an LED indicator to notify the remaining capacity of a rechargeable battery by lighting and blinking when operating a key such as a call button. However, this is based on the premise that the mobile phone system is operating normally, and indicates whether or not power is available to make a call. The capacity is not notified.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power supply state to a non-contact IC card that can be operated by a power source supplied by a rechargeable battery of its own device as necessary. It is to provide a mobile phone that can be confirmed.

According to the present invention, there is provided a mobile phone including a system control unit that operates with power supplied from a rechargeable battery and a non-contact IC card unit,
In the state where the voltage value connected to the rechargeable battery and supplied from the rechargeable battery to the system control unit is less than the system operation threshold value at which the system control unit cannot operate, the non-contact from the rechargeable battery An IC operation detection unit that detects whether a voltage value supplied to the IC card unit is equal to or higher than an IC operation threshold at which the non-contact IC card unit is inoperable;
An IC operation notification unit for notifying that the non-contact IC card unit is operable when the IC operation detection unit detects that the voltage value is equal to or greater than the IC operation threshold;
A reception unit that receives an instruction to cause the IC operation notification unit to perform the notification;
Equipped with a,
The IC operation detection unit outputs an IC operation voltage detection signal when detecting that the voltage value is equal to or higher than the IC operation threshold value,
The IC operation notification unit
A display for notifying that the non-contact IC card unit is operable by lighting;
When the IC operation voltage detection signal is input from the IC operation detection unit and the reception unit receives the instruction, the operation state of the system control unit is interposed between the display and the rechargeable battery. A power control unit for supplying power from the rechargeable battery to the display without depending on
When the IC operating voltage detection signal is input to the power control unit and the receiving unit receives the instruction, the power control unit supplies power from the rechargeable battery to the display. The mobile phone is provided in which the display is turned on to notify that the non-contact IC card unit is in an operable state .

According to the present invention, even when the remaining capacity of the rechargeable battery of the mobile phone is in a range where the system operation is impossible, it is possible to check the operation state of the non-contact IC card, that is, the power supply state to the non-contact IC card module. This improves convenience.
Further, according to this configuration, even if the remaining capacity of the rechargeable battery of the mobile phone is in a range where the system operation is impossible, the operation state of the non-contact IC card, that is, the power supply state to the non-contact IC card is required. It can be confirmed accordingly, improving usability. Further, according to this configuration, it is possible to notify the power supply state to the non-contact IC card with a simple configuration.

In the mobile phone, the reception unit includes a switch pressed by a user, and the display includes an LED display having a cathode connected to the switch and an anode connected to the power control unit, When the switch is pressed in a state where power is supplied from the rechargeable battery to the anode of the LED display via the power control unit, the cathode of the LED display is grounded, and the LED In a state where the display is turned on and power is not supplied from the rechargeable battery to the anode of the LED display, the LED display can be kept off regardless of pressing of the switch.
In the mobile phone, a system operation detection unit that detects whether the voltage value supplied to the system control unit is equal to or higher than the system operation threshold value, and the voltage value is equal to or higher than the system operation threshold value by the system operation detection unit. A system operation notification unit that notifies that the system control unit is in an operable state, and the instruction received by the reception unit is sent to the system operation notification unit. The system operation detection unit outputs a system operation voltage detection signal when detecting that the voltage value is equal to or higher than the system operation threshold, and the system operation notification unit is turned on, The system controller may further include a second indicator for notifying that the system controller is operable, and The source control unit is interposed between the display unit and the second display unit and the rechargeable battery, and when the system operating voltage detection signal is input and the receiving unit receives the instruction, Without depending on the operating state of the system controller, power is supplied from the rechargeable battery to the second display, and the system operating voltage detection signal is input to the power controller, and When the receiving unit receives the instruction, the power control unit supplies power from the rechargeable battery to the second display, the second display is turned on, and the system control unit Ru can be notified that it is operable state.

According to this configuration, since notification can be made in stages according to the remaining capacity of the rechargeable battery of the mobile phone, it is possible to check whether the mobile phone system and the non-contact IC card can be operated, and convenience is improved.
Further, according to this configuration, even if the remaining capacity of the rechargeable battery of the mobile phone is in a range where the system operation is impossible, the operating state of the mobile phone system and the non-contact IC card, that is, the system control unit and the non-contact IC card It is possible to check the state of power supply to the device as needed, improving usability. Further, according to this configuration, it is possible to notify the power supply state to the system controller and the non-contact IC card with a simple configuration.

In the mobile phone, the reception unit includes a switch that is pressed by a user, and the second display unit includes a cathode connected to the switch and an anode connected to the power control unit. When the switch is pressed while the power is supplied from the rechargeable battery to the anode of the second LED indicator via the power control unit, the second LED In the state where the cathode of the indicator is grounded, the second LED indicator is lit, and power is not supplied from the rechargeable battery to the anode of the second LED indicator, regardless of the depression of the switch. The second LED indicator can be kept off .

  It should be noted that any combination of the above-described components, and a conversion of the expression of the present invention between a method and an apparatus are also effective as an aspect of the present invention.

  ADVANTAGE OF THE INVENTION According to this invention, the mobile telephone which can confirm the power supply state to the non-contact IC card which can operate | move with the power supplied with the rechargeable battery of an own machine as needed is provided.

  The embodiments of the present invention have been described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

(First embodiment)
FIG. 1 is a functional block diagram showing a configuration of a mobile phone according to an embodiment of the present invention. The cellular phone 1 according to the present embodiment includes a system control unit (cell phone system unit 10) that operates with power supplied from a rechargeable battery (battery 30) and a non-contact IC card unit (non-contact IC card module 20). In a state where the voltage value supplied from the rechargeable battery to the system control unit (cell phone system unit 10) is less than the system operation threshold at which the system control unit becomes inoperable, the rechargeable battery is connected to the contactless IC. An IC operation detection unit (IC operation voltage detection unit 22) that detects whether the voltage value supplied to the card unit is equal to or higher than an IC operation threshold at which the non-contact IC card unit cannot operate, and the IC operation detection unit sets the voltage value. An IC operation notification unit (LED display 32) for notifying that the non-contact IC card unit is operable when it is detected that the IC operation threshold is exceeded. That.

  In the following drawings, the configuration of parts not related to the essence of the present invention is omitted and is not shown.

  Specifically, the mobile phone 1 includes a mobile phone system unit 10, a non-contact IC card module 20, a battery 30, an LED display 32, a confirmation switch 34, and an LED power control circuit unit 36. Yes.

  The mobile phone system unit 10 includes a control unit 12, a signal processing unit 14, a radio unit 16, and an antenna 18. The control unit 12 controls the entire mobile phone system unit 10 together with each element of the mobile phone system unit 10. The control unit 12 operates by executing a program recorded in a memory (not shown). The signal processing unit 14 is controlled by the control unit 12 and controls input / output devices such as a dial key, a liquid crystal display device, and a speaker (not shown) to realize various functions mounted on the mobile phone system unit 10. The wireless unit 16 communicates with a base station (not shown) via the antenna 18 and provides a wireless communication function such as a call or information communication.

  The non-contact IC card module 20 performs non-contact communication with an external IC card reader / writer device (not shown). In the present embodiment, the non-contact IC card module 20 can operate without control from the mobile phone system unit 10.

  The battery 30 is a rechargeable battery and supplies power to the mobile phone system unit 10 and the non-contact IC card module 20. Further, the battery 30 supplies power to the LED display 32 described later via the LED power control circuit unit 36. In the present embodiment, according to the voltage range of the battery 30, the LED display 32 is turned on or off when the confirmation switch 34 is pressed, so that the power supply state notification to the non-contact IC card module 20 is made. Done. Here, in the mobile phone 1 of the present embodiment, the operation states of the mobile phone system unit 10 and the non-contact IC card module 20 according to the voltage range of the power supplied from the battery 30 will be described. FIG. 2 is a diagram for explaining the definition of the voltage range supplied by the battery 30 of the mobile phone 1 of the present embodiment.

  As shown in FIG. 2, the voltage ranges are classified into three voltage ranges, that is, a first voltage range A, a second voltage range B, and a third low voltage range C in order from the high voltage side. The voltage range A is a situation where the remaining capacity of the battery 30 is sufficient, and is a high voltage range in which both the mobile phone system unit 10 and the non-contact IC card module 20 can operate. Further, the voltage range A can be further divided into the following three stages according to voltage values as states that the cellular phone system unit 10 can take. In the first voltage range where the remaining capacity of the battery 30 is the largest, it is possible to turn on the power switch and accept the operation by the operation unit (not shown) of the mobile phone system unit 10, and the remaining capacity of the battery 30 is slightly reduced. In the voltage range, the power switch can be turned on, but the operation cannot be accepted by the operation unit of the mobile phone system unit 10. In the third voltage range where the remaining capacity of the battery 30 is further reduced, the power switch cannot be turned on.

  In the voltage range B, the remaining capacity of the battery 30 decreases, the voltage value supplied to the mobile phone system unit 10 and the non-contact IC card module 20 becomes low, and the mobile phone system unit 10 becomes inoperable due to the low voltage. In addition, the non-contact IC card module 20 is set to an operable middle voltage range. In the voltage range C, the remaining capacity of the battery 30 further decreases, the voltage value supplied to the mobile phone system unit 10 and the non-contact IC card module 20 further decreases, and the mobile phone system unit 10 and the non-contact IC card module 20 Both are in a low voltage range where operation is disabled.

  Returning to FIG. 1, the non-contact IC card module 20 includes an IC operating voltage detector 22. The IC operating voltage detection unit 22 detects whether the voltage value supplied from the battery 30 to the non-contact IC card module 20 is equal to or higher than an IC operating threshold value, and outputs an IC operating voltage detection signal 24 if the voltage value is equal to or higher than the threshold value. When the supply voltage value is greater than or equal to the threshold value, the IC operation voltage detection signal 24 is at a high level, and when it is less than the threshold value, the IC operation voltage detection signal 24 is at a low level.

  The LED indicator 32 notifies the power supply state to the non-contact IC card module 20, and notifies that it is in a voltage range in which non-contact communication in the non-contact IC card module 20 is possible. The LED display 32 is supplied from the battery 30 with power controlled by the LED power control circuit unit 36. The LED display 32 has a cathode connected to a confirmation switch 34 described later, and an anode connected to the LED power supply control circuit unit 36. The LED display 32 is turned on when the confirmation switch 34 is pressed and the cathode is grounded with the power controlled by the LED power supply control circuit 36 being supplied to the anode of the LED display 32. Yes.

  The confirmation switch 34 receives an instruction to cause the LED display 32 to perform notification. When the user presses the confirmation switch 34, the LED display 32 displays the power supply state to the non-contact IC card module 20. . The confirmation switch 34 may use one of operation keys (not shown) provided in the mobile phone system unit 10. The confirmation switch 34 enables notification by the LED display 32 at any scene expected by the user.

  Specifically, when the user depresses the confirmation switch 34, the confirmation switch 34 is turned on, and the cathode of the LED display 32 is grounded. The LED indicator 32 is turned on when the confirmation switch 34 is turned on in a state where the power from the battery 30 is supplied via the LED power control circuit unit 36.

  The LED power supply control circuit unit 36 is interposed between the battery 30 and the LED indicator 32, and receives the IC operation voltage detection signal 24 output from the IC operation voltage detection unit 22, and according to the IC operation voltage detection signal 24 The power supply from the battery 30 to the LED display 32 is controlled. Accordingly, the LED indicator 32 is controlled to be turned on / off according to the voltage value of the battery 30, and the LED indicator 32 can notify the power supply state to the non-contact IC card module 20.

  Specifically, when power is supplied from the battery 30 to the anode of the LED display 32 via the LED power control circuit unit 36, the LED display 32 is turned on when the confirmation switch 34 is pressed, and the battery 30 is turned on. If power is not supplied to the anode of the LED display 32, the LED display 32 remains off regardless of whether the confirmation switch 34 is pressed. In this embodiment, the LED power supply control circuit unit 36 receives the IC operating voltage detection signal 24 output from the IC operating voltage detection unit 22 without depending on the operation availability state of the mobile phone system unit 10 as an input. Power supply control to the display device 32 can be performed.

  FIG. 3 shows a circuit diagram of the IC operating voltage detector 22 of this embodiment. As shown in FIG. 3, the IC operating voltage detector 22 is a general voltage detector, and includes a resistor R1, a resistor R2, a reference voltage circuit Vref, an operational amplifier OPAmp1, and a transistor Tr1. The operating characteristics are determined by the values of the resistor R1, the resistor R2, and the reference voltage circuit Vref. The output of the transistor Tr1 of the IC operating voltage detection unit 22 is output as the IC operating voltage detection signal 24. In the present embodiment, the operating characteristics of the IC operating voltage detector 22 are determined so that the IC operating voltage detection signal 24 functions as a signal for determining the voltage range C described above.

  FIG. 4 shows an example of a peripheral circuit of the LED display 32 including the LED power control circuit unit 36. The LED power control circuit unit 36 is configured not to depend on whether the mobile phone system unit 10 is operable. The LED power supply control circuit unit 36 includes a resistor R11, a resistor R12, a transistor Tr11, and a transistor Tr12. The resistor R11 is a pull-down resistor for the case where the IC operating voltage detection signal 24 input from the IC operating voltage detection unit 22 becomes unstable. The resistor R12 is a current limiting resistor for preventing unnecessary current consumption. In the present embodiment, a resistor R10 is provided between the LED display 32 and the confirmation switch 34.

  The transistor Tr11 and the transistor Tr12 of the LED power supply control circuit unit 36 are, for example, FETs (Field Effect Transistors). In the transistor Tr11, the battery 30 is connected to the source via the resistor R12, and the drain is grounded. The IC operating voltage detection signal 24 output from the IC operating voltage detector 22 is input to the gate of the transistor Tr11, and the on / off state of the transistor Tr11 is controlled by the IC operating voltage detection signal 24. FIG. 5 shows a state truth value in the LED power supply control circuit unit 36 according to the state of the IC operating voltage detection signal 24 of the present embodiment. As shown in FIG. 5, the transistor Tr11 is turned on when the IC operating voltage detection signal 24 input to the gate of the transistor Tr11 is at a high level, and is turned off when the signal is at a low level.

  Returning to FIG. 4, the transistor Tr12 has a battery 30 connected to the source and an LED display 32 connected to the drain. The input to the gate of the transistor Tr12 is low level when the transistor Tr11 is on, and the transistor Tr12 is on. When the transistor Tr11 is off, the input is high and the transistor Tr12 is off.

  Therefore, as shown in FIG. 5, when the IC operating voltage detection signal 24 is at a high level, the transistor Tr12 is turned on, and power is supplied from the battery 30 to the LED display 32 via the transistor Tr12. On the other hand, when the IC operating voltage detection signal 24 is at the low level, the transistor Tr12 is turned off and the power supply from the battery 30 to the LED display 32 is cut off.

  The LED indicator 32 is lit by the voltage supplied from the battery 30 when the confirmation switch 34 is pressed. The transistor Tr12 of the LED power supply control circuit unit 36 is interposed between the battery 30 and the LED display 32. The power supply to the LED display 32 is controlled according to the on / off state of the transistor Tr12, and the LED display 32 is turned on. The unlit state changes. When the confirmation switch 34 is pressed while the transistor Tr12 is on, power is supplied to the LED display 32, the LED display 32 is lit, and when the transistor Tr12 is off, the confirmation switch 34 is depressed. Regardless, the power supply to the LED display 32 remains cut off, and the LED display 32 remains off.

  The operation at the time of notification of the operation status of the non-contact IC card module 20 of the mobile phone 1 configured as described above will be described below. FIG. 6 shows the state of the LED display 32 when the confirmation switch 34 is pressed according to the voltage state of the battery 30 in the mobile phone 1 of the present embodiment. This will be described below with reference to FIGS.

  First, in the voltage range A in which the mobile phone system unit 10 is operable, the supply voltage value to the non-contact IC card module 20 is equal to or greater than the threshold value, so that the IC operation voltage detection signal output from the IC operation voltage detection unit 22 24 becomes High level, and as shown in FIG. 5, the transistor Tr11 of the LED power supply control circuit section 36 is turned on, and the transistor Tr12 is turned on. Accordingly, when the confirmation switch 34 is pressed in this state, the LED display 32 is turned on, and when the confirmation switch 34 is opened, the LED display 32 is turned off. Thus, when the confirmation switch 34 is pressed, the LED indicator 32 is lit, so that the user can confirm that the voltage range is within the contactless IC card module 20 in which contactless communication is possible.

  Next, in the voltage range B in which the mobile phone system unit 10 becomes inoperable, the supply voltage value to the non-contact IC card module 20 is equal to or greater than the threshold value, so that the IC operating voltage detection is performed as in the case of the voltage range A described above. The IC operating voltage detection signal 24 output from the unit 22 is at a high level. Therefore, the LED display 32 is turned on when the confirmation switch 34 is pressed, and the LED display 32 is turned off when the confirmation switch 34 is opened. Therefore, even when the mobile phone system unit 10 is inoperable, the user can It can be confirmed that the voltage range allows contact communication.

  Next, in the voltage range C in which the non-contact IC card module 20 is inoperable, the supply voltage value to the non-contact IC card module 20 is less than the threshold value, so the IC operation voltage output from the IC operation voltage detection unit 22 The detection signal 24 becomes a low level, and as shown in FIG. 5, the transistor Tr11 of the LED power supply control circuit unit 36 is turned off and the transistor Tr12 is turned off. Accordingly, when the confirmation switch 34 is pressed in this state, the LED indicator 32 remains off. Thereby, even when the cellular phone system unit 10 is in an inoperable state, the user can confirm that the non-contact communication in the non-contact IC card module 20 is in a voltage range that is impossible.

  As described above, in the voltage range A and the voltage range B, the LED indicator 32 is turned on when the user presses the confirmation switch 34, and when the confirmation switch 34 is pressed in the voltage range C, the LED indicator 32 remains off. By not lighting it, it is possible to notify the desired non-contact communication availability state, that is, the power supply state to the non-contact IC card module.

  As described above, according to the mobile phone 1 of the present embodiment, the contactless IC card module 20 even if the remaining capacity of the battery 30 of the mobile phone 1 is the voltage range B and the voltage range C incapable of system operation. By pressing the confirmation switch 34 as necessary, the state of power supply to the LED can be confirmed by the on / off state of the LED display 32, which improves convenience.

  That is, when the remaining capacity of the battery 30 attached to the mobile phone 1 is in a low voltage state where the mobile phone system unit 10 cannot be turned on or cannot operate, the power supply voltage supplied to the contactless IC card module 20 is contactless. Since it has a notification means for determining whether or not the voltage range is communicable, when the user uses the non-contact communication function, it can be easily determined that it can be used, and if the non-contact communication fails, This has the effect of clarifying that the factor is due to insufficient battery capacity. Further, since the notification can be confirmed by a user operation of pressing the confirmation switch 34, the state of the remaining battery capacity necessary for non-contact communication can be notified under a necessary situation.

(Second embodiment)
FIG. 7 is a diagram showing a configuration of the mobile phone 101 according to the embodiment of the present invention. The mobile phone 101 of the present embodiment is further provided with a notification unit for notifying the power supply state to the mobile phone system unit 110, which is different from the mobile phone 1 of the above embodiment, and the power supply state from the battery 30 in the mobile phone is The difference is that notification can be made in stages. The mobile phone 101 of this embodiment includes a mobile phone system unit 110 and an LED power supply control circuit unit 120 in place of the mobile phone system unit 10 and the LED power supply control circuit unit 36 of the mobile phone 1 of the above embodiment, and further includes an LED display. A container 122 is provided.

  The mobile phone 101 of this embodiment includes a system control unit (mobile phone system unit 110) that operates with power supplied from a rechargeable battery (battery 30) and a non-contact IC card unit (non-contact IC card module 20). The voltage supplied to the non-contact IC card unit from the rechargeable battery in a state where the voltage value supplied from the rechargeable battery to the system control unit is less than the system operation threshold at which the system control unit cannot operate. An IC operation detection unit (IC operation voltage detection unit 22) that detects whether the value is equal to or higher than an IC operation threshold at which the non-contact IC card unit cannot operate, and an IC operation detection unit determines that the voltage value is equal to or higher than the IC operation threshold. If detected, an IC operation notification unit (LED display 32) for notifying that the non-contact IC card unit is operable is supplied to the system control unit. A system operation detection unit (system operation voltage detection unit 130) that detects whether the voltage value is equal to or higher than a system operation threshold; and the system operation detection unit detects that the voltage value is equal to or higher than the system operation threshold, A system operation notification unit (LED display 122) for notifying that the system control unit is in an operable state.

  In the present embodiment, the mobile phone system unit 110 includes a system operating voltage detection unit 130. The system operating voltage detection unit 130 detects whether the voltage value supplied from the battery 30 to the mobile phone system unit 110 is equal to or higher than the system operating threshold value, and outputs a system operating voltage detection signal 132 if the voltage value is equal to or higher than the threshold value. When the supply voltage value is greater than or equal to the threshold value, the system operating voltage detection signal 132 is at a high level, and when it is less than the threshold value, the system operating voltage detection signal 132 is at a low level. In the present embodiment, the operating characteristics of the system operating voltage detector 130 are determined so that the system operating voltage detection signal 132 output from the system operating voltage detector 130 functions as a signal for determining the voltage range A described above. It shall be.

  The LED display 122 notifies a power supply state to the mobile phone system unit 110, and notifies that the mobile phone system unit 110 is in an operable state by lighting. A power source controlled by the LED power source control circuit unit 120 is supplied from the battery 30 to the LED display 122. The LED display 122 has a cathode connected to the confirmation switch 34 and an anode connected to the LED power supply control circuit unit 120. In a state where the power controlled by the LED power supply control circuit unit 120 is supplied to the anode of the LED display 122, when the confirmation switch 34 is pressed and the cathode is grounded, the LED display 122 is turned on. Yes.

  In the present embodiment, the LED display 32 has a cathode connected to the confirmation switch 34 and an anode connected to the LED power supply control circuit unit 120. In a state where the power controlled by the LED power control circuit unit 120 is supplied to the anode of the LED display 32, when the confirmation switch 34 is pressed and the cathode is grounded, the LED display 32 is turned on. Yes.

  The LED power supply control circuit unit 120 is interposed between the battery 30, the LED display 32 and the LED display 122, and the IC operation voltage detection signal 24 and the system operation voltage detection unit 130 output from the non-contact IC card module 20. The system operating voltage detection signal 132 output from the battery 30 is input, and the power supply from the battery 30 to the LED display 32 and the LED display 122 is controlled according to the IC operating voltage detection signal 24 and the system operating voltage detection signal 132, respectively. To do. Thereby, the LED display 32 and the LED display 122 can notify the power supply state to the non-contact IC card module 20 and the mobile phone system unit 110, respectively.

  Specifically, when the confirmation switch 34 is pressed in a state where power is supplied from the battery 30 to the anode of the LED display 32 and the LED display 122 via the LED power control circuit unit 120, the LED display 32 and Each of the LED indicators 122 is lit and when the power is not supplied from the battery 30, the LED indicator 32 and the LED indicator 122 are kept off regardless of whether the confirmation switch 34 is pressed. In the present embodiment, the LED power supply control circuit unit 120 receives the system operating voltage detection signal 132 output from the system operating voltage detection unit 130 without depending on the operation availability state of the mobile phone system unit 110 as an input. Power supply control to the display 32 and the LED display 122 can be performed.

  FIG. 8 shows an example of a peripheral circuit of the LED display 122 including the LED power supply control circuit unit 120. Note that the LED power supply control circuit unit 120 is configured not to depend on whether the mobile phone system unit 110 can operate. The LED power supply control circuit unit 120 includes a resistor R21, a resistor R22, a resistor R23, a resistor R24, a transistor Tr21, a transistor Tr22, a transistor Tr23, a transistor Tr24, and an exclusive OR circuit Gate21. The resistors R21 and R23 are pull-down resistors when the system operating voltage detection signal 132 becomes indefinite, and the resistors R22 and R24 are current limiting resistors for preventing unnecessary current consumption. In the present embodiment, a resistor R20 and a resistor R30 are provided between the LED indicator 32 and the LED indicator 122 and the confirmation switch 34, respectively.

  In the LED power supply control circuit unit 120, the transistor Tr21 has the source connected to the battery 30 via the resistor R2, and the drain grounded to ground. The system operating voltage detection signal 132 output from the system operating voltage detector 130 is input to the gate of the transistor Tr 21, and the on / off state of the transistor Tr 21 is controlled by the system operating voltage detection signal 132. FIG. 9 shows state truth values in the LED power supply control circuit unit 120 according to the states of the IC operating voltage detection signal 24 and the system operating voltage detection signal 132 of the present embodiment. As shown in FIG. 9, the transistor Tr21 is turned on when the system operating voltage detection signal 132 input to the gate of the transistor Tr21 is at a high level, and turned off when the signal is at a low level.

  Returning to FIG. 8, in the transistor Tr21, the battery 30 is connected to the source, and the system operating voltage detection signal 132 is connected to the drain. The input to the gate of the transistor Tr22 is low level when the transistor Tr21 is on, and the transistor Tr22 is on. When the transistor Tr21 is off, the input is high and the transistor Tr22 is off.

  Further, the system operation voltage detection signal 132 and the IC operation voltage detection signal 24 are input to the exclusive OR circuit Gate21. As shown in FIG. 9, when the IC operating voltage detection signal 24 and the system operating voltage detection signal 132 are both at the high level or the low level, the output of the exclusive OR circuit Gate21 becomes the low level, and the IC operating voltage detection signal 24 When the system operating voltage detection signal 132 is at the low level at the high level, the signal is at the high level.

  The output of the exclusive OR circuit Gate21 is input to the gate of the transistor Tr23 and is controlled to be turned on / off. In the transistor Tr23, the battery 30 is connected to the source via the resistor R24, and the drain is grounded. As shown in FIG. 9, the transistor Tr23 is turned on when the output of the exclusive OR circuit Gate21 input to the gate of the transistor Tr23 is at a high level, and is turned off when the output is at a low level.

  Returning to FIG. 8, in the transistor Tr24, the battery 30 is connected to the source, and the LED display 32 is connected to the drain. The input to the gate of the transistor Tr24 is low level when the transistor Tr23 is on, and the transistor Tr24 is on. When the transistor Tr23 is off, the input is high and the transistor Tr24 is off.

  Therefore, as shown in FIG. 9, when both the IC operating voltage detection signal 24 and the system operating voltage detection signal 132 are at a high level, the transistor T22 is turned on, and power is supplied from the battery 30 to the LED display 122 via the transistor Tr22. At the same time, the transistor Tr24 is turned off, and the power supply from the battery 30 to the LED display 32 is cut off.

  On the other hand, when the IC operating voltage detection signal 24 is at a high level and the system operating voltage detection signal 132 is at a low level, the transistor Tr22 is turned off, the power supply from the battery 30 to the LED display 122 is shut off, and the transistor Tr24 The power is supplied from the battery 30 to the LED display 32 via the transistor Tr24.

  Further, when both the IC operating voltage detection signal 24 and the system operating voltage detection signal 132 are at the low level, both the transistor Tr22 and the transistor Tr24 are turned off, and the power supply from the battery 30 to the LED display 122 and the LED display 32 is cut off. Is done.

  The LED indicator 122 is lit by the voltage supplied from the battery 30 when the confirmation switch 34 is pressed. The transistor Tr22 of the LED power supply control circuit unit 120 is interposed between the battery 30 and the LED display 122, and the power supply to the LED display 122 is controlled according to the on / off state of the transistor Tr22, and the LED display 122 is turned on. The unlit state changes. When the confirmation switch 34 is pressed while the transistor Tr22 is on, power is supplied to the LED display 122, the LED display 122 is lit, and when the confirmation switch 34 is pressed when the transistor Tr22 is off. Accordingly, the power supply to the LED display 122 remains cut off, and the LED display 122 remains off.

  In the present embodiment, the transistor Tr24 of the LED power control circuit unit 120 is interposed between the battery 30 and the LED display 32, and the power supply to the LED display 32 is controlled according to the on / off state of the transistor Tr24. The on / off state of the LED indicator 32 changes. When the confirmation switch 34 is pressed while the transistor Tr24 is on, power is supplied to the LED display 32, the LED display 32 is lit, and when the transistor Tr24 is off, the confirmation switch 34 is depressed. Accordingly, the power supply to the LED display 32 remains cut off, and the LED display 32 remains off.

  The operation at the time of notification of the operation status of the mobile phone system unit 110 and the non-contact IC card module 20 of the mobile phone 101 of this embodiment configured as described above will be described below. FIG. 10 shows the states of the LED display 122 and the LED display 32 when the confirmation switch 34 is pressed according to the voltage state of the battery 30 in the mobile phone 101 of the present embodiment. Hereinafter, a description will be given with reference to FIGS.

  First, in the voltage range A in which the mobile phone system unit 110 can operate, the voltage value supplied from the battery 30 is not less than the system operation threshold value and not less than the IC operation threshold value. The system operating voltage detection signal 132 and the IC operating voltage detection signal 24 output from the unit 22 are both at a high level, and the transistor Tr22 of the LED power supply control circuit unit 120 is turned on and the transistor Tr24 is turned off as shown in FIG. Accordingly, as shown in FIG. 10, when the confirmation switch 34 is pressed in this state, the LED indicator 122 is turned on, the LED indicator 32 is kept off, and when the confirmation switch 34 is opened, the LED indicator 122 is turned on. Is turned off, and the LED indicator 32 remains off. As described above, when the confirmation switch 34 is pressed, the LED indicator 122 is lit and the LED indicator 32 is kept off, so that the user can maintain the remaining capacity of the battery 30 within the voltage range in which the mobile phone system unit 110 can operate. I can confirm that there is.

  Next, in the voltage range B in which the mobile phone system unit 110 becomes inoperable, the supply voltage from the battery 30 is less than the system operation threshold and greater than or equal to the IC operation threshold. Therefore, as shown in FIG. The system operation voltage detection signal 132 output from the detection unit 130 is at a low level, and the IC operation voltage detection signal 24 output from the IC operation voltage detection unit 22 is at a high level. At this time, the transistor Tr22 of the LED power supply control circuit unit 120 is turned off and the transistor Tr24 is turned on. Therefore, as shown in FIG. 10, when the confirmation switch 34 is pressed in this state, the LED indicator 122 remains off, the LED indicator 32 is lit, and when the confirmation switch 34 is opened, the LED indicator 122. Maintains the extinguished state, and the LED indicator 32 is extinguished. Thus, when the confirmation switch 34 is pressed, the LED indicator 32 is lit and the LED indicator 122 is kept off, so that the user cannot operate the mobile phone system unit 110 with the remaining amount of the battery 30. In addition, it can be confirmed that the non-contact IC card module 20 is in a voltage range in which non-contact communication is possible.

  Next, in the voltage range C in which the non-contact IC card module 20 is not operable, the voltage value supplied from the battery 30 is less than the system operation threshold and less than the IC operation threshold. The system operating voltage detection signal 132 and the IC operating voltage detection signal 24 output from the IC card module 20 are both at the low level, and as shown in FIG. 9, both the transistor Tr22 and the transistor Tr24 of the system operating voltage detection unit 130 are off. It becomes. Therefore, in this state, the LED indicator 122 and the LED indicator 32 remain off regardless of whether the confirmation switch 34 is pressed. As a result, even when the cellular phone system unit 110 is in an inoperable state, the user can use the remaining capacity of the battery 30 so that the cellular phone system unit 110 cannot operate and the non-contact IC card module 20 cannot perform non-contact communication. It can be confirmed that it is in range.

  Thus, when the user presses the confirmation switch 34 in the voltage range A, the LED indicator 122 is lit, and when the user presses the confirmation switch 34 in the voltage range B, the LED indicator 32 is lit. When the confirmation switch 34 is pressed in the voltage range C, the LED indicator 32 and the LED indicator 122 are kept off and not turned on, so that the desired system operation and non-contact communication enabled / disabled state, that is, the mobile phone The power supply state can be notified to the system unit 110 and the non-contact IC card module 20.

  As described above, according to the mobile phone 101 of the present embodiment, notification can be made in stages according to the remaining capacity of the rechargeable battery 30 of the mobile phone 101. It is possible to confirm whether the IC card can be operated, and convenience is further improved.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are the illustrations of this invention, Various structures other than the above are also employable.

  For example, in the above embodiment, the confirmation switch 34 is provided as a notification instruction for the LED display 32 or the LED display 122, but the present invention is not limited to this. The confirmation switch 34 may not be provided. In this case, the display of the LED display 32 or the LED display 122 is always controlled according to the power supply state to the non-contact IC card module 20 or the mobile phone system unit, for example, The light is turned on in the operable voltage range, and the light is turned off in the inoperable voltage range.

  Moreover, in the said embodiment, although the LED indicator 32 was set as the structure lighted only in the said voltage range B, it is not limited to this. The LED indicator 32 may be configured to light up even in the voltage range A. According to this configuration, in the voltage range A in which the mobile phone system unit 110 can operate, both the LED display 122 and the LED display 32 are lit. According to this configuration, when the mobile phone system unit 110 is in the operable voltage range A, two LEDs are lit, and when the non-contact IC card module 20 is in the operable voltage range B, one LED is lit. In the voltage range C where both the mobile phone system unit 110 and the non-contact IC card module 20 are inoperable, all the LEDs remain off, so the remaining capacity of the battery 30 can be determined intuitively visually. There is an advantage that it becomes easy to do.

It is a functional block diagram which shows the mobile telephone which concerns on embodiment of this invention. It is a figure for demonstrating the definition of the voltage range which the battery of the mobile telephone of this embodiment supplies. FIG. 2 is a circuit diagram of an IC operating voltage detection unit of the mobile phone of FIG. 1. It is a circuit diagram which shows an example of the LED display peripheral circuit containing the LED power supply control circuit part of the mobile telephone of FIG. The state truth value in the LED power supply control circuit part according to the state of the IC operating voltage detection signal in the mobile phone of FIG. 1 is shown. The state of the LED indicator when the confirmation switch is pressed according to the voltage state of the battery in the mobile phone of FIG. 1 is shown. It is a functional block diagram which shows the mobile telephone which concerns on embodiment of this invention. It is a circuit diagram which shows an example of the LED display peripheral circuit containing the LED power supply control circuit part of the mobile telephone of FIG. The state truth value in the LED power supply control circuit part according to the state of the system operating voltage detection signal and IC operating voltage detection signal in the mobile phone of FIG. 7 is shown. The state of the LED indicator when the confirmation switch is pressed according to the voltage state of the battery in the mobile phone of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cellular phone 10 Cellular phone system part 12 Control part 14 Signal processing part 16 Radio | wireless part 18 Antenna 20 Non-contact IC card module 22 IC operation voltage detection part 24 IC operation voltage detection signal 30 Battery 32 LED indicator 34 Confirmation switch 36 LED power supply Control circuit unit 101 Mobile phone 110 Mobile phone system unit 120 LED power supply control circuit unit 122 LED display unit 130 System operation voltage detection unit 132 System operation voltage detection signal

Claims (4)

A mobile phone including a system control unit and a non-contact IC card unit that is powered and operated from a rechargeable battery,
In the state where the voltage value connected to the rechargeable battery and supplied from the rechargeable battery to the system control unit is less than the system operation threshold value at which the system control unit cannot operate, the non-contact from the rechargeable battery An IC operation detection unit that detects whether a voltage value supplied to the IC card unit is equal to or higher than an IC operation threshold at which the non-contact IC card unit is inoperable;
An IC operation notification unit for notifying that the non-contact IC card unit is operable when the IC operation detection unit detects that the voltage value is equal to or greater than the IC operation threshold;
A reception unit that receives an instruction to cause the IC operation notification unit to perform the notification;
Equipped with a,
The IC operation detection unit outputs an IC operation voltage detection signal when detecting that the voltage value is equal to or higher than the IC operation threshold value,
The IC operation notification unit
A display for notifying that the non-contact IC card unit is operable by lighting;
When the IC operation voltage detection signal is input from the IC operation detection unit and the reception unit receives the instruction, the operation state of the system control unit is interposed between the display and the rechargeable battery. A power control unit for supplying power from the rechargeable battery to the display without depending on
When the IC operating voltage detection signal is input to the power control unit and the receiving unit receives the instruction, the power control unit supplies power from the rechargeable battery to the display. The mobile phone is characterized in that the display is turned on to notify that the non-contact IC card unit is operable .   The mobile phone according to claim 1,
  The reception unit includes a switch that is pressed by the user.
  The indicator comprises an LED indicator having a cathode connected to the switch and an anode connected to the power control unit,
  When the switch is pressed in a state where power is supplied from the rechargeable battery to the anode of the LED display via the power control unit, the cathode of the LED display is grounded, and the LED A cellular phone characterized in that, when the display is turned on and power is not supplied from the rechargeable battery to the anode of the LED display, the LED display is kept off regardless of pressing of the switch. The mobile phone according to claim 1 or 2 ,
A system operation detection unit that detects whether the voltage value supplied to the system control unit is equal to or greater than the system operation threshold;
A system operation notification unit for notifying that the system control unit is in an operable state when the system operation detection unit detects that the voltage value is equal to or greater than the system operation threshold;
Further comprising
The instruction received by the reception unit further includes an instruction for causing the system operation notification unit to perform the notification,
The system operation detection unit outputs a system operation voltage detection signal when detecting that the voltage value is equal to or higher than the system operation threshold value,
The system operation notification unit further includes a second indicator that notifies that the system control unit is in an operable state by lighting,
further,
The power control unit
When the system operating voltage detection signal is input and the reception unit receives the instruction, the system control unit is interposed between the display and the second display and the rechargeable battery. Power is supplied from the rechargeable battery to the second display without depending on the operating state,
When the system operating voltage detection signal is input to the power supply control unit and the reception unit receives the instruction, the power supply control unit supplies power from the rechargeable battery to the second display. And the second display is turned on to notify that the system control unit is in an operable state .   The mobile phone according to claim 3, wherein
  The reception unit includes a switch that is pressed by the user.
  The second indicator comprises a second LED indicator having a cathode connected to the switch and an anode connected to the power control unit,
  When the switch is pressed while power is being supplied from the rechargeable battery to the anode of the second LED display via the power control unit, the cathode of the second LED display is In the state where the second LED indicator is lit and the rechargeable battery is not supplied with power to the anode of the second LED indicator, the second LED indicator is displayed regardless of pressing of the switch. A cellular phone characterized in that the device is kept off.

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