JP6303794B2 - Mobile terminal and power supply control method thereof - Google Patents

Description

  The present disclosure relates to a mobile terminal and a power supply control method thereof.

  In recent years, in the field of portable terminal devices, it is often the case that a lid for taking out a battery pack (battery pack) is not provided on a housing in response to a request for thinning. In this case, in the manufacturing process of the mobile terminal device, the battery pack is built in the housing, and a so-called “fitting” state is established. As a result, even when the power of the mobile terminal device is off, a current (called dark current) continues to flow to the load from the battery pack built in the housing, and the remaining battery level continues to gradually decrease. It becomes a state.

  Examples of conventional techniques for suppressing a decrease in the remaining battery level due to dark current include the following. The battery device built in the portable terminal includes a switching element that disconnects a power supply path that supplies power to the load device in accordance with a control signal from the switch unit. The switch unit generates a control signal for preventing dark current flowing from the battery device to the load device in accordance with the operation. As a part of the switch unit, a dummy SIM card (dummy card) having a conductor area is used, and when the dummy card is mounted in the socket, a short circuit is caused by contact between the conductor area and a pair of spring contacts. A signal is generated (for example, Patent Document 1).

Japanese Patent Laying-Open No. 2013-183634 (FIGS. 6, 8, 9, and 10) Japanese Patent Laid-Open No. 2001-237952

  However, the technique of Patent Document 1 has the following problems. That is, in Patent Document 1, the pair of spring contacts that come into contact with the conductor area of the dummy card are non-standard contacts of the SIM card. For this reason, the pair of spring contacts are arranged on the front side of the SIM card socket. On the other hand, the dummy card has a length dimension that is longer than the length dimension of the SIM card, and a conductor area that is brought into contact with a pair of spring contacts is formed at one end in the length direction of the dummy card. The conductor area is in contact with the pair of spring contacts when the dummy card is mounted in the socket.

  Due to the above configuration, in the technique of Patent Document 1, the mounting area is large in order to provide an installation space for the pair of spring contacts. Further, in consideration of the arrangement of the pair of spring contacts, there are design restrictions such as the SIM card socket arrangement position and the size of the SIM card insertion slot. Such a restriction can be a factor that hinders downsizing and thinning of the mobile terminal.

  An object of the present disclosure is to provide a technology that can reduce dark current using a connector and a signal line for an actual card.

One aspect of the present disclosure includes a battery that supplies power to a load;
One of a real card and a pseudo card different from the real card can be connected, and a connector to which a signal line for transmitting and receiving signals between the load and the real card is connected;
A cut-off circuit that cuts off power supply from the battery to the load in response to a control signal generated in the signal line when the pseudo card is connected to the connector;
It is a portable terminal containing.

  According to the present disclosure, the dark current can be reduced using the connector and signal line for an actual card.

FIG. 1 is a diagram illustrating a configuration example of a mobile terminal device (mobile terminal) in the embodiment. FIG. 2 shows a configuration example of a power supply control circuit included in the mobile terminal. FIG. 3 is a diagram illustrating a configuration example of the cutoff circuit, the disconnection circuit, and the pseudo SIM card illustrated in FIG. 2 and illustrates a state when the cutoff circuit is operated by connection of the pseudo SIM card. FIG. 4A is a diagram illustrating a terminal configuration example of a real SIM card. FIG. 4B is a diagram illustrating a terminal configuration example of the pseudo SIM card. FIG. 5 is a time chart showing an operation example of the mobile terminal shown in FIG. FIG. 6 is an explanatory diagram of the operation of the cutting circuit during use of the SIM card.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The configuration of the embodiment is an exemplification, and the present invention is not limited to the configuration of the embodiment.

<Configuration example of portable terminal device>
FIG. 1 is a diagram illustrating a configuration example of a mobile terminal device (mobile terminal) 10 in the embodiment, and FIG. 2 illustrates a configuration example of a power supply control circuit included in the mobile terminal 10. The mobile terminal 10 is a terminal (for example, a wireless terminal) having a dedicated or general-purpose communication function such as a feature phone, a smartphone, a tablet terminal, or a personal digital assistant (PDA).

  In FIG. 1, the mobile terminal 10 includes a battery pack (battery) 11 built in a housing and a load 12 that receives power supply from the battery 11. The load 12 includes a power supply unit 13 connected to the battery 11 and a control unit 14 connected to the power supply unit 13. The mobile terminal 10 also includes a socket 16 (a type of connector) for a Subscriber Identity Module (SIM) card (actual SIM card) connected via a signal line 15. The socket 16 is formed so that the SIM card 17A can be freely attached and detached. The socket 16 is an example of a “connector”.

The battery 11 includes a positive terminal (VBATT) and a negative terminal (GND), and supplies power to the load 12 by outputting the battery voltage VBATT. The power supply unit 13 includes a power supply circuit that performs power supply to the control unit 14 and power supply stop according to on / off of the power switch 18.

  The control unit 14 includes a device group provided in the mobile terminal 10. In the example illustrated in FIG. 1, as an example, the control unit 14 includes a central processing unit (CPU) 19, a memory 20, a display device 21, an input device 22, an audio input / output device 23, and a radio unit 24. Is included. Further, although not shown, the control unit 14 may include a camera, a sensor, a Global Positioning System (GPS) receiver, and the like.

The memory 20 includes a non-volatile memory (for example, Read Only Memory (ROM), flash memory, etc.) and a volatile memory (for example, Random Access Memory (RAM)). The memory 20 stores a program executed by the CPU 19 and data used when the program is executed. The memory 20 is used as a work area for the CPU 19.

  The display device 21 displays various information such as the execution result of the program by the CPU 19. The input device 22 includes at least one of a key, a button, a touch panel, and the like, and is used for a user to input information to the mobile terminal 10. The audio input / output device 23 includes a microphone, a speaker, and the like. The wireless unit 24 includes a baseband signal modulator / demodulator, an up-converter, a down-converter, an amplifier, a duplexer, a transmission / reception antenna, and the like, and manages wireless communication (transmission / reception of wireless signals) with other communication devices.

  The signal line 15 includes signal lines 15a to 15f (see FIG. 2). Each of the signal lines 15 a to 15 f is connected to one of electrical contacts (hereinafter referred to as “contacts”) 16 a to 16 f (FIG. 1) provided on the bottom surface of the socket 16. In FIG. 2, the socket 16 and the contacts 16a to 16f are schematically illustrated. The contacts 16a to 16f are, for example, spring contacts formed of a conductor.

  The signal line 15a is connected to the contact 16a, the signal line 15b is connected to the contact 16b, the signal line 15c is connected to the contact 16c, and the signal line 15d is connected to the contact 16d. The line 15e is connected to the contact 16e, and the signal line 15f is connected to the contact 16f.

  Each of the contacts 16a to 16f is formed in association with a plurality of terminals provided in the SIM card 17A. Each of the contacts 16a to 16f comes into contact with a corresponding terminal when the SIM card 17A is attached to the socket 16. The portable terminal 10 (the load 12 such as the control unit 14) and the SIM card 17A are electrically connected by contact between the terminal and the contact. Accordingly, the mobile terminal 10 (control unit 14) can supply operating power, read / write data, and the like to the SIM card 17A using the signal line 15.

<Configuration of power supply control circuit>
As shown in FIG. 2, the mobile terminal 10 includes a power supply control circuit that controls power supply from the battery 11 to the load 12 using a pseudo SIM card 17B different from the SIM card 17A.

  The power supply control circuit cuts off the dark current flowing from the battery 11 to the load 12 when the pseudo SIM card 17B is attached to the socket 16 (the mobile terminal 10 and the pseudo SIM card 17B are electrically connected). 30 is included. The power supply control circuit also includes a disconnect circuit 40 that disconnects the electrical connection between the shut-off circuit 30 and the SIM card 17 </ b> A connected to the socket 16. The SIM card 17A is an example of a “real card”, and the pseudo SIM card 17B is an example of a “pseudo card”.

  The interruption circuit 30 includes a control line 31, a control circuit 32, and a switch SW1. The switch SW1 is inserted into the power line 11a that connects the VBATT terminal of the battery 11 and the power supply unit 13. The power line 11a includes a power line 11b that connects the battery 11 and the switch SW1, and a power line 11c that connects the switch SW1 and the power supply unit 13. Note that the GND terminal of the battery 11 and the power supply unit 13 are connected by a ground line 11d.

  With such a configuration, the power supply from the battery 11 to the load 12 is turned on / off as the switch SW1 is turned on / off. The switch SW1 is formed so as to receive an on / off signal from the control circuit 32 via the control line 33, and is turned on when the on signal is received and turned off when the off signal is received.

  The control line 31 includes a control line 31a that connects the control circuit 32 and the switch SW2 included in the cutting circuit 40, and a control line 31b that connects the switch SW2 and the signal line 15. The control line 31b connects the switch SW2 and one of the signal lines 15. In the example of FIG. 2, the control line 31b is connected to the signal line 15b.

  The control circuit 32 turns on and off the switch SW1 according to the presence or absence of a control signal generated on the control line 31a. The pseudo SIM card 17B is attached to the socket 16 (electrically connected to the mobile terminal 10) to generate a control signal on the signal line 15b. The control signal is supplied to the control line 31a via the switch SW2 (ON state). When receiving a control signal from the control line 31a, the control circuit 32 generates an off signal on the control line 33 and turns off the switch SW1.

  As described above, in the present embodiment, the pseudo SIM card 17B is configured to be used as a part of the cutoff circuit 30, and a part of the signal line 15b is used as a transmission path for the control signal. With the above configuration, when the pseudo SIM card 17B is attached to the mobile terminal 10, the control circuit 32 turns off the switch SW1 and cuts off the power supply from the battery 11 to the load 12. As a result, the dark current can be reduced, and a decrease in the remaining amount of the battery 11 can be suppressed.

  The cutting circuit 40 includes a control line 41 connected to the control unit 14, a control circuit 42, and a switch SW2. The switch SW2 is connected to the control circuit 42 via the control line 43. The switch SW2 is turned off when the pseudo SIM card 17B is not attached to the socket 16. On the other hand, the switch SW2 is turned on when the pseudo SIM card 17B is mounted in the socket 16, and transmits a control signal generated on the signal line 15b to the control line 31a. The control circuit 42 turns off the switch SW2 via the control line 43 when a control signal is generated on the control line 41.

  When the power switch 18 is turned on and power supply from the power supply unit 13 is started, the control unit 14 generates a system reset signal and outputs it to the control line 41. The system reset signal is a signal output from the CPU 19 when the CPU 19 is supplied with power and ready for operation. The control circuit 42 recognizes the system reset signal as a control signal and turns off the switch SW2. As a result, the cutoff circuit 30 is disconnected from the signal line 15b. The system reset signal continues to be output to the control line 41 while power is supplied to the control unit 14 (CPU 19).

  Therefore, when the SIM card 17A is used (when the signal line 15b is used), the blocking circuit 30 is disconnected from the signal line 15b. For this reason, it is avoided that one influences the other between the interruption | blocking circuit 30, the control part 14, and SIM card | curd 17A. As a result, the SIM card 17A and the control unit 14 can perform normal exchange.

  FIG. 3 is a diagram illustrating a configuration example of the cutoff circuit 30, the cutting circuit 40, and the pseudo SIM card 17B illustrated in FIG. In the example shown in FIG. 3, a p-channel field effect transistor (MOSFET) Tr1 (hereinafter referred to as “Tr1”) is applied as the switch SW1. The control circuit 32 includes an n-channel MOSFET Tr2 (hereinafter referred to as “Tr2”) and an n-channel MOSFET Tr3 (hereinafter referred to as “Tr2”). Tr1 is an example of a “switching element”.

  The drain and the source of Tr1 are inserted into a power line connecting the battery 11 and the power supply unit 13. That is, the source of Tr1 is connected to the power line 11a on the battery side, and the drain of Tr1 is connected to the power line 11b on the power supply unit 13 side. The gate of Tr1 is connected to the drain of Tr3.

The source of Tr2 is connected (grounded) to the ground, and the drain is connected to the source of Tr3. The gate of Tr2 is connected to the recording line 11a, and a voltage by the battery voltage VBATT is applied. A load impedance 35 is connected to the gate of Tr2 and the gate of Tr1.

  The source of Tr3 is connected to the battery 11 via the load impedance 36, and the battery voltage VBATT is applied. A load impedance 37 is connected between the terminal on the battery 11 side of the load impedance 36 and the control line 31a. The gate of Tr3 is connected to the control line 31a, and a voltage based on the battery voltage VBATT is applied to the gate of Tr3 via the control line 31a.

  Further, an n-channel MOSFET Tr4 (hereinafter referred to as “Tr4”) is applied as the switch SW2. The source of Tr4 is connected to the control line 31b, and the drain is connected to the control line 31a. The gate of Tr4 is connected to the control line 43. Tr4 is an example of a “switching element for cutting”.

The control circuit 42 includes an n-channel MOSFET Tr5 (hereinafter referred to as “Tr5”), a load impedance 44, and a load impedance 45. The source of Tr5 is grounded, and the drain is connected to the control line 43. One end of the load impedance 44 is connected to the control line 41, and the other end is grounded. The control line 43 is connected to the battery 11 via the load impedance 45, and the battery voltage VBATT is applied to the control line 43.

<SIM card and pseudo SIM card>
4A is a diagram illustrating a configuration example of the SIM card 17A, and FIG. 4B is a diagram illustrating a configuration example of the pseudo SIM card 17B. FIG. 4A schematically shows a plurality of terminals (pins) T1 to T6 exposed on the back surface of the SIM card 17A.

The terminal T1 is a Vcc terminal and is used for power input. The terminal T2 is a reset terminal and is used for inputting a reset signal from an external device (the control unit 14 of the mobile terminal 10). The terminal T3 is a clock terminal and is used for inputting a clock or a timing signal. The terminal T4 is a ground (GND) terminal and is used for grounding.

The terminal T5 is a terminal for inputting a program voltage (Vpp). The terminal T5 is used for providing a voltage for programming (changing) or erasing the contents of a nonvolatile memory (not shown) built in the SIM card 17A. The terminal T6 is used as a data input / output terminal for an integrated circuit (IC) built in the SIM card 17A.

  The terminal T1 corresponds to the contact 16a and the signal line 15a, the terminal T2 corresponds to the contact 16b and the signal line 15b, and the terminal T3 corresponds to the contact 16c and the signal line 15c. The terminal T4 corresponds to the contact 16d and the signal line 15d, the terminal T5 corresponds to the contact 16e and the signal line 15e, and the terminal T6 corresponds to the contact 16f and the signal line 15f.

  Each terminal T1 to T6 comes into contact with a corresponding contact 16a to 16f and is electrically connected when the SIM card 17A is attached to the socket 16. Each signal line 15a, 15b, 15c, 15e, 15f is connected to the control unit 14, and various signals (power signal, reset signal, voltage signal, data signal) between the control unit 14 and the SIM card 17A. Used to send and receive. On the other hand, the signal line 15d is used as a ground line and is grounded.

  The pseudo SIM card 17B has the same external shape (dimensions in the width, length, and thickness directions) as the SIM card 17A, except that the terminal configuration formed on the plane (rear surface) is different from that of the SIM card 17A. be able to. Further, the pseudo SIM card 17B is different from the SIM card 17A in that an IC or a non-volatile memory does not need to be incorporated.

  As shown in FIG. 4B, the pseudo SIM card 17B has only a terminal T41 used as a ground (GND) terminal. The terminal T41 is formed by joining (integrating) the terminal T2 (ground terminal) in the SIM card 17A and a predetermined other terminal. In the present embodiment, as an example, the terminal T41 is formed by joining the terminal T2 (reset terminal) to the terminal T4 (ground terminal).

  The terminal T41 contacts the contact 16b and the contact 16d when the pseudo SIM card 17B is mounted in the socket 16, and short-circuits the contact 16b and the contact 16d. As a result, the signal line 15b is grounded via the terminal T41 (see FIG. 3), and the signal level of the control line 31a connected to the signal line 15b via the switch SW2 is low (L) level. It becomes. This L level signal acts as a control signal for the control circuit 32. Note that a short circuit to the ground using the terminal T41 is performed with a low impedance. For example, the impedance can be reduced by increasing the area of the terminal T41.

  A diode D is inserted into the signal line 15b with the direction from the control unit 14 toward the socket 16 as the forward direction. The diode D is provided in order to prevent the voltage generated on the source side of Tr4 from entering the control unit 14 via the signal line 15b. However, the diode D is not necessarily an essential configuration.

<Operation example>
FIG. 5 is a time chart showing an operation example of the mobile terminal 10 shown in FIG. The time chart shows an on / off state of power supply to the battery voltages VBATT, Tr1 (SW1), Tr2, Tr3, Tr4 (SW2), Tr5, and the power supply unit 13 (load 12).

  In a state where the battery 11 is not mounted on the portable terminal 10 (no battery pack), the battery voltage VBATT is zero, so that each of Tr1 to Tr5 is off and power supply to the power supply unit 13 is not performed.

  When the battery 11 is mounted in a state in which neither the SIM card 17A nor the pseudo SIM card 17B is mounted in the socket 16, application of the battery voltage VBATT is started, and the following operation is performed in the cutoff circuit 30, and the power supply unit Power supply to 13 is started.

That is, as shown in FIG. 3, Tr2 is turned on by application of the battery voltage VBATT, and the battery voltage VBATT applied to the source of Tr3 is short-circuited to the source side of Tr2.
As a result, a ground potential is generated on the source side of Tr3, and the signal level on the source side becomes L level. On the other hand, the battery voltage VBATT is applied to the control line 31a, and the signal level of the control line 31a becomes the high (H) level. As a result, Tr3 is turned on.

  The signal level on the source side (power line 11b) of Tr1 becomes H level by the battery voltage VBATT, while the signal level on the gate side of Tr1 becomes L level when Tr3 is turned on. Accordingly, Tr1 is turned on, and power is supplied from the battery 11 to the power supply unit 13 through the power line 11a.

However, at this time, the power switch 18 is off, and power supply from the power supply unit 13 to the control unit 14 is not performed. Tr5 is turned on by the output of the reset signal while the signal level of the control line 41 is at the H level. In a state where power is not supplied to the control unit 14, Tr5 is off. For this reason, Tr4 is turned on upon receiving battery voltage VBATT at its gate. A drain current flows from the drain to the source of Tr4. However, since the contact 16b is opened, the voltage on the source side of Tr4 becomes the battery voltage VBATT in a very short time, and Tr4 is turned off. As a result, the signal level (H) of the control line 31a is maintained.

  Thereafter, when the pseudo SIM card 17B is inserted into the socket 16, the terminal T41 comes into contact with the contact 16b and the contact 16d. As a result, the contact 16b and the contact 16d are short-circuited, and the signal line 15b is grounded. Then, since a ground potential is applied to the source of Tr4 (the signal level on the source side becomes L level), Tr4 is turned on, and the signal level of the control line 31a changes from H level to L level. This L level signal becomes a control signal for the cutoff circuit 30 (control circuit 32).

  Tr3 is turned off when the gate voltage decreases, and the gate voltage of Tr1 increases. As a result, Tr1 is turned off, and power supply from the battery 11 to the power supply unit 13 is turned off. That is, the dark current is reduced (see FIG. 3).

  Therefore, for example, if the battery 11 is mounted on the casing and the pseudo SIM card 17B is mounted in the assembly operation of the mobile terminal 10 in the manufacturing factory of the mobile terminal 10, the dark current is reduced and the remaining battery level is reduced. In this state, packing and shipping can be performed.

  Thereafter, the portable terminal 10 is transported to the store and stored with the pseudo SIM card 17B attached. When the mobile terminal 10 is purchased by a consumer, the pseudo SIM card 17B is removed from the socket 16 and the SIM card 17A is attached.

  When the pseudo SIM card 17B is removed from the socket 16, the contact 16b is opened, so that Tr4 is turned off again. As a result, the signal level of the control line 31a becomes H level again, so that Tr3 is turned on and Tr1 is turned on. Thereby, power supply from the battery 11 to the power supply unit 13 is resumed.

  When the SIM card 17A is attached to the socket 16, the SIM card 17A is connected to the control unit 14 via the signal lines 15a to 15c, 15e, and 15f. However, the power switch 18 is off, and no power is supplied from the power supply unit 13 to the control unit 14. For this reason, the state of Tr1-Tr5 is not different from the state when the pseudo SIM card 17B is removed.

  FIG. 6 shows a state when the power switch 18 is turned on when the SIM card is connected. When an operation to turn on the power switch 18 is performed, power supply from the power supply unit 13 to the control unit 14 is started. Then, the control unit 14 generates a system reset signal.

  The system reset signal is output to the control line 41. By the output of the system reset signal, the signal level of the control line 41 becomes H level, and Tr5 is turned on. When Tr5 is turned on, the battery voltage VBATT is short-circuited to the ground, the signal level of the control line 43 becomes L level, and Tr4 (SW2) is turned off.

  As a result, the control line 31a, that is, the cutoff circuit 30 is disconnected from the signal line 15b (in FIG. 6, the disconnected state is illustrated by showing the source side of Tr4 (control line 31b) with a broken line). Accordingly, the cutoff circuit 30 affects the control unit 14 and the SIM card 17A via the signal line 15b, and a signal sent from the control unit 14 to the SIM card 17A affects the cutoff circuit 30 via the signal line 15b. Is avoided.

Specifically, while the system reset signal is output to the control line 41, Tr4 is turned off, so the SIM card 17 in which the voltage resulting from the battery voltage VBATT flows through the signal line 15b.
It is possible to avoid the noise of the reset signal for A. Thus, the signal line 15b is disconnected from the cutoff circuit 30 by the disconnection circuit 40 during use of the signal line 15b. For this reason, the reset signal for the SIM card 17A is appropriately sent to the SIM card 17A through the signal line 15b, and the SIM card 17 can perform a normal reset operation.

  Thereafter, when the SIM card 17A attached to the mobile terminal 10 is replaced with a pseudo SIM card 17B, Tr1 is turned off, and power supply from the battery 11 to the power supply unit 13 (load 12) is stopped. For this reason, for example, when the mobile terminal 10 is stored for a long period of time, if the pseudo SIM card 17B is attached, it is possible to reduce the decrease in the remaining battery level.

<Effects of Embodiment>
According to the mobile terminal 10 according to the embodiment, the power supply from the battery 11 to the load 12 can be stopped by mounting the pseudo SIM card 17B. Thereby, the power consumption of the battery 11 can be suppressed by reducing the dark current, and the decrease amount of the remaining battery level can be reduced. In the example of the embodiment, when Tr1 is on, a dark current of about 100 μA flows, whereas the dark current can be reduced to about 1 μA by turning off Tr1. The amount of dark current reduction depends on the values of the load impedances 34 and 35.

  Further, according to the mobile terminal 10, the switch SW1 is turned off while the pseudo SIM card 17B is connected to the socket 16, so that the mobile terminal 10 can be normally used when the pseudo SIM card 17B is not attached. it can.

Furthermore, according to the mobile terminal 10, since Tr4 (SW2) is turned off while the system reset signal is output to the control line 41, the blocking circuit 30 is connected to the signal line 15b regardless of whether the SIM card 17A is attached or detached. It can be in a disconnected state. Thereby, it is possible to avoid the battery voltage VBATT flowing through the signal line 15b and adversely affecting the SIM card 17A.

  In the mobile terminal 10 according to the embodiment, a pseudo SIM card 17B having a terminal T41 in which a terminal T4 (GND terminal) included in the SIM card 17A and another terminal T2 are integrated is used. Further, the terminal T41 is brought into contact with the contacts 16b and 16d for the SIM card 17A, and the signal line 15b is short-circuited to the ground. At this time, an L level signal generated in the control line 31 via the signal line 15 b is used as a control signal to the cutoff circuit 30. As described above, in the mobile terminal 10, on / off of the switch SW <b> 1 (power supply to the load, power supply stop) is controlled using the connector (socket 16) and the signal line 15 for the actual SIM card 17 </ b> A.

  By adopting this configuration, it is possible to avoid providing a pair of spring contacts (nonstandard) different from the SIM card contacts as in the prior art. Further, unlike the prior art, it is not necessary to make the dummy card longer than the SIM card and provide the dummy card with a conductor area corresponding to a pair of spring contacts. Therefore, the external shape of the pseudo SIM card 17B can be the same as the external shape of the real SIM card 17A. In other words, the pseudo SIM card 17B can be prevented from becoming larger than the SIM card 17A.

  For this reason, according to the portable terminal 10, it is possible to avoid an increase in the mounting area around the socket 16 due to the use of the pseudo SIM card 17B. In addition, since the pseudo SIM card 17B is used around the socket 16, such as the installation position (layout) of the socket 16 and the shape and size of the SIM card outlet, it is possible to avoid design restrictions. Therefore, at least one of avoiding an increase in the size of the mobile terminal 10, improving design, and avoiding an increase in the number of parts for reducing dark current can be achieved.

  Further, since the pseudo SIM card 17B and the SIM card 17A can be made the same size, the method of detaching the pseudo SIM card 17B from the socket 16 and the feeling of use related to the detachment can be made the same as the SIM card 17A. That is, the seller or user (purchaser) of the mobile terminal 10 can handle the pseudo-SIM card 17B and the SIM card 17A in the same sense.

<Modification>
The embodiment can be modified as follows. For example, in the embodiment, the switch SW1 (Tr1) is inserted in the power line 11a. Instead, the switch SW1 may be inserted in the ground line 11d. Moreover, the cutting circuit 40 may be omitted from the mobile terminal 10 according to the embodiment.

  In the embodiment, the reset terminal (terminal T2) is joined to the GND terminal (terminal T4). However, any of the other terminals T1, T3, T5, and T6 may be used instead of the terminal T2. Further, a plurality of terminals may be joined to the terminal T4 to form the terminal T41.

  Unlike the embodiment, when a terminal different from the reset terminal (terminal T2) is used to form the GND terminal (terminal T41) of the pseudo SIM card 17B, the control line 31b is connected to the signal line corresponding to the terminal. . Further, the control line 41 is modified so that a control signal for turning on the Tr 5 is output while the signal line is being used.

  The control unit 14 can be modified to turn off the switch SW2 while detecting the connection of the SIM card 17A to the socket 16. As a result, the influence of the blocking circuit 30 can be avoided during use of the SIM card 17A.

  In the embodiment, an example is shown in which MOSFETs are used as Tr1 to Tr5, but bipolar transistors may be applied as Tr1 to Tr5. Alternatively, other switching elements can be applied.

  In the embodiment, a SIM card is used as an example of the card. However, the card is not limited to a SIM card. For example, any card may be used as long as it is detachable from the portable terminal and is electrically connected to the portable terminal. For example, various cards such as a memory card (for example, an SD memory card) and an IC card may be used.

The embodiment described above discloses the following supplementary notes. Appendices can be combined as appropriate. (Supplementary note 1) a battery for supplying power to the load;
One of a real card and a pseudo card different from the real card can be connected, and a connector to which a signal line for transmitting and receiving signals between the load and the real card is connected;
A cut-off circuit that cuts off power supply from the battery to the load in response to a control signal generated in the signal line when the pseudo card is connected to the connector;
Including mobile devices. (1)

(Additional remark 2) Before the transmission / reception of the signal through the said signal wire is performed between the said real card connected to the said connector, and the said load, the cutting circuit which cut | disconnects between the said interruption | blocking circuit and the said signal wire is further provided The mobile terminal according to Supplementary Note 1, including: (2)

(Supplementary note 3) The portable circuit according to Supplementary note 1 or 2, wherein the cutoff circuit releases a cutoff state of power supply from the battery to a load when both the real card and the pseudo card are not connected to the connector. Terminal. (3)

(Additional remark 4) The said interruption | blocking circuit is a portable terminal as described in any one of additional remark 1 to 3 which receives the control signal which arises when the said signal wire | line is earth | grounded by the connection of the said pseudo card to the said connector. (4)

(Supplementary Note 5) The connector includes a first contact connected to the signal line and a second contact connected to the ground, and the first contact and the second contact are the pseudo card. The portable terminal according to appendix 4, which contacts a terminal that short-circuits between the first contact and the second contact provided on the terminal. (5)

(Additional remark 6) The said interruption | blocking circuit is inserted in the electric power supply line between the said battery and the said load, and includes the switch turned on / off according to the presence or absence of the said control signal. Mobile device.

(Supplementary Note 7) The disconnection circuit is disposed between the signal line and the cutoff circuit, and is turned on when the control signal is generated, while being transmitted from the load to the real card via the signal line. The mobile terminal according to any one of appendices 1 to 6, including a disconnection switch that is turned on when a signal is generated.

(Supplementary Note 8) A signal line for connecting a battery for supplying power to a load, one of a real card and a pseudo card different from the real card, and transmitting and receiving a signal between the load and the real card A power supply control method for a mobile terminal including a connector connected to
Connecting the pseudo card to the connector;
In response to a control signal generated in the signal line due to the connection between the connector and the pseudo card, a cutoff circuit cuts off power supply from the battery to the load.
A power supply control method for a portable terminal.

SW1, SW2 ... switch 11 ... battery 12 ... load 13 ... power supply unit 14 ... control unit 15 ... signal line 16 ... socket (connector)
17A ... SIM card 17B ... pseudo SIM card
30 ... Cutoff circuit 40 ... Cutting circuit

Claims (6)

A battery for supplying power to the load;
One of a real card and a pseudo card different from the real card can be connected, and a connector to which a signal line for transmitting and receiving signals between the load and the real card is connected;
A cut-off circuit that cuts off power supply from the battery to the load in response to a control signal generated in the signal line when the pseudo card is connected to the connector;
Including mobile devices. The circuit further includes a disconnection circuit for disconnecting between the interrupting circuit and the signal line before transmission / reception of a signal through the signal line between the actual card connected to the connector and the load. The portable terminal as described in. The portable terminal according to claim 1 or 2, wherein the cutoff circuit releases a cutoff state of power supply from the battery to a load when both the real card and the pseudo card are not connected to the connector. 4. The mobile terminal according to claim 1, wherein the blocking circuit receives a control signal generated when the signal line is grounded by connection of the pseudo card to the connector. 5. The connector includes a first contact connected to the signal line and a second contact connected to the ground, and the first contact and the second contact are provided on the pseudo card. The portable terminal according to claim 4, wherein the portable terminal is in contact with a terminal that short-circuits between the first contact and the second contact. A battery for supplying power to the load can be connected to one of a real card and a pseudo card different from the real card, and a signal line for transmitting and receiving signals between the load and the real card is connected. A power supply control method for a portable terminal including a connector,
Connecting the pseudo card to the connector;
In response to a control signal generated in the signal line due to the connection between the connector and the pseudo card, a cutoff circuit cuts off power supply from the battery to the load.
A power supply control method for a portable terminal.

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