JP5433350B2 - Portable electronic devices - Google Patents

Description

  The present invention relates to a portable electronic device such as a mobile phone, a PDA, a portable game machine, a portable television, and a portable radio.

Patent Document 1 includes a battery pack and a backup battery that are normally used. The power of the battery pack is supplied to a main body power control unit through a switching diode. A portable electronic device supplied to the control unit is described.
Patent Document 1 describes a portable electronic device that is charged by a charging device using a battery pack as a power source.

Japanese Patent Laid-Open No. 08-149184

  However, in the portable electronic device described in Cited Document 1, when operating a plurality of circuits having different operating voltage thresholds, a power supply is provided for each of the plurality of circuits depending on whether or not a rechargeable battery is attached and whether or not charging is in progress. There is a problem that the system configuration must be configured and the circuit configuration becomes complicated.

  An object of the present invention is to provide a portable electronic device that can secure an operating voltage required for various circuit systems with a simple circuit configuration.

The portable electronic device according to the present invention includes the attached module, the electric power from the first power supply line capable of supplying electric power from the battery as an internal power source to the auxiliary module, and the electric power from the charging device as the external power source. A power supply means for supplying any power from the second power supply line that can be supplied to the module to the attached module, one end of the first power supply line, and one end of the second power supply line A field effect transistor that is connected to a power source and is maintained in an ON state when the battery is in a connected state, and is maintained in an OFF state when the battery is in a disconnected state; If the anda power control unit for performing stop control for stopping the power supply to the non-accessory module, the stop control is executed by the power control unit if it becomes less, the battery Power from is supplied to the auxiliary module via said first power supply line without passing through the field effect transistor,
Even if power supply from the battery or power from one of the charging devices is reduced or stopped, power can be supplied to the accessory module from the other.

Preferably, the first power supply terminal is connected to one end of the first power supply line and is connectable to the battery, and the second power supply terminal is connected to one end of the second power supply line and is connectable to the charging device. A power control unit that receives power from the second power supply line and controls power supply to the circuit system; and first power in the first power supply line that is set via the first power supply terminal the power of the high voltage of the second power set from the second power supply line, and closed a power supply unit corresponding to a power supply means for supplying to the auxiliary module via the power output portion, The field effect transistor is connected between one end of the first power supply line and one end of the second power supply line, and is maintained in an ON state when a battery is connected to the first power supply terminal. is, is held in the OFF state when unconnected

  Preferably, the second power supply line is connected between one end of the second power supply line and the second power supply terminal. When the charging device is connected to the second power supply terminal, the second power supply line is held in an ON state, and is not connected. A switching element that is held in an OFF state in some cases.

  Preferably, the power supply unit is disposed on the first power supply line, an anode is connected to the first power supply terminal, and a cathode is disposed on the power output unit, and the first diode A second diode disposed on the power supply line, having an anode connected to the switch element, and a cathode disposed on the power output unit, wherein the first diode and the second diode At least the forward voltage of the first diode is set lower than the forward voltage from the first power supply terminal of the field effect transistor toward the second power supply line.

  Preferably, the first diode and the second diode are Schottky barrier diodes.

  Preferably, it has a power supply control part which cancels | releases the said stop control, when the charge start by a charging device is detected.

  Preferably, an antenna for a non-contact type IC card is provided, and the accessory module is a circuit for a non-contact type IC card.

  According to the present invention, it is possible to provide a portable electronic device that can secure an operating voltage required for various circuit systems with a simple circuit configuration.

It is a perspective view which shows the external appearance of the mobile telephone which concerns on embodiment of this invention in an open state. It is sectional drawing in II-II of FIG. It is a block diagram which shows the signal processing system of the mobile telephone of FIG.1 and FIG.2. It is explanatory drawing of the supply circuit which supplies electric power to the various circuit systems of a mobile telephone. This is a first comparative example. It is a 2nd comparative example. FIG. 7 is a table summarizing the effects of the first comparative example, the second comparative example, and the embodiment of the present invention.

  FIG. 1 is a perspective view showing an external appearance of a mobile phone 1 according to an embodiment of the present invention in an open state.

The mobile phone 1 is configured as a foldable type.
The mobile phone 1 includes a first housing 2 and a second housing 3.
The first housing 2 includes a first housing front case 4 that constitutes a portion facing the second housing 3, and a first housing rear case 5 that constitutes a portion opposite to the second housing 3. Have.
The second housing 3 includes a second housing front case 6 that constitutes a portion facing the first housing 2 and a second housing rear case 7 that constitutes a portion opposite to the first housing 2. Have.

The first housing front case 4 and the first housing rear case 5 are fixed to each other with screws or the like, and various electronic members are formed in a space formed between the first housing front case 4 and the first housing rear case 5. A housing space for housing the container is configured.
The second casing front case 6 and the second casing rear case 7 are also fixed to each other by screws or the like, and various electronic members are formed in a space formed between the second casing front case 6 and the second casing rear case 7. A housing space for housing the container is configured.
The first casing front case 4, the first casing rear case 5, the second casing front case 6, and the second casing rear case 7 are made of resin, for example.

As shown in FIG. 1, the display unit 8 is arranged in the first housing front case 4.
The display unit 8 is for displaying various information such as the state of the mobile phone 1, the user's operation content, the destination telephone number, the content of the e-mail, and the game screen.
The display unit 8 includes an LCD (liquid crystal display), an OLED (Organic light-emitting diode: organic EL), and the like.

  Further, as shown in FIG. 1, the input unit 10 is disposed in the surface direction of the second housing front case 6. When the user operates the input unit 10, an instruction, a character, or the like is input to the mobile phone 1.

  2 is a cross-sectional view taken along the line II-II in FIG.

The second housing front case 6 and the second housing rear case 7 are joined with their inner surfaces facing each other.
And the internal housing | casing 20 is arrange | positioned in the internal space formed by it. A battery housing portion 28 is formed in the rear surface direction of the internal housing 20.
A detachable battery 22 is disposed in the battery storage unit 28. The battery 22 supplies power to the mobile phone 1.
Furthermore, a battery cover 23 is arranged in the rear surface direction so that the battery 22 can be replaced.

The battery 22 is charged by being electrically connected to the charging device 76.
The battery 22 supplies electric power to various circuit systems mounted on the mobile phone 1 when the charging device 76 is not connected to operate.
When the mobile phone 1 is connected to the charging device 76, the mobile phone 1 is driven by the power supplied from the charging device 76 instead of the power of the battery 22.
The mobile phone 1 is driven by the electric power from the charging device 76 not only while the battery 22 is being charged but also after the battery 22 is fully charged.
That is, when the mobile phone 1 is electrically connected to the charging device 76 and the power consumption of the mobile phone 1 does not exceed the supply capability of the charging device 76, the battery 22 is mounted on the mobile phone 1. It does not supply power to various circuit systems.

A printed circuit board 21 on which the switch 26 is mounted is disposed in the surface direction of the inner housing 20. The printed circuit board 21 has a light emitting unit 27 mounted thereon.
The light emitting unit 27 is configured by, for example, an LED (Light Emitting Diode).

  The switch 26 includes, for example, a fixed contact 25 and a metal dome 24 that is a dome-shaped sheet metal.

  A key sheet 32 is arranged in the surface direction of the printed circuit board 21. The key sheet 32 includes a plurality of key tops 30 that are parts pressed by a user, and a rubber base 31 to which the plurality of key tops 30 are bonded.

The second casing front case 6 is formed with a plurality of key openings 35 into which the key tops 30 are inserted (arranged).
Around the key opening 35, a decorative sheet 34 having the purpose of protecting the second casing front case 6 and the purpose of improving the design of the mobile phone 1 is attached.

A light guide sheet 33 is disposed between the key sheet 32 and the switch 26 of the printed circuit board 21.
The light guide sheet 33 receives light from the light emitting unit 27, guides the light, and irradiates the key top 30 side with light.

As shown in FIG. 2, an antenna 60 for a non-contact IC card is arranged at a position inside the battery cover 23.
However, the position of the antenna 60 for the non-contact type IC card can be appropriately changed according to the assumed usage of the non-contact type IC card of the mobile phone 1. For example, it can be arranged inside the first housing rear case 5.
The non-contact type IC card has functions such as a personal identification card, entry / exit management, a prepaid card, and a credit card.
Particularly assumed in the present invention is a non-contact IC card having a prepaid card function. However, it is not intended to limit this function.

  FIG. 3 is a block diagram showing a signal processing system of the mobile phone 1 shown in FIGS.

  As shown in FIG. 3, the mobile phone 1 includes a control unit 57 that is the center of control and processing, a power supply control unit 50, a communication unit 51, an operation unit 52, a voice input / output unit 53, and a display unit. 8, a non-contact IC card circuit 59, and a storage unit 56 are commonly connected to a system bus 58 including a plurality of lines for address, data, and control.

The power manager IC 78 controls the supply of power to the circuit board or the like on which the display unit 8 and the control unit 57 are mounted in the mobile phone 1 when the mobile phone 1 is carried and used. Yes.
Moreover, the power supply control part 50 controls the charging device 76 described in FIG. 4 at the time of charge, and charges the battery 22 with the electric power from the charging device 76.
Specifically, the power supply control unit 50 controls the start and stop of charging, the speed of charging, and the like.
Further, the power manager IC 78 provides necessary power to various circuit systems (LED, LCD, CPU, non-contact IC card circuit 59, etc.) mounted on the mobile phone 1.
Furthermore, the power supply control unit 50 monitors the voltage of the battery 22 and performs control to stop power supply to other than the circuit 59 for the non-contact type IC card when the voltage is lower than a predetermined voltage.
This is because the non-contact type IC card often has various card functions and the like.
In other words, when the voltage is lower than the predetermined voltage, power supply to other than the contactless IC card circuit 59 is stopped to supply power preferentially to the important functions of the contactless IC card. Is possible.
Further, when power is supplied by the charging device 76, there is no concern about power, so the stop control that stopped power supply to other than the circuit 59 for the non-contact IC card is canceled.
Thus, the user can use various functions of the mobile phone 1 before the battery 22 is charged with sufficient power.

  The communication unit 51 captures a wireless communication system, performs wireless communication with a base station connected to a communication network, and transmits and receives various data. The various types of data include file data downloaded from a download site on the web, voice data during a voice call, mail data during mail transmission / reception, web page data during web browsing, and the like.

The operation unit 52 receives user support input from the input unit 10 and other parts.
In the input unit 10, for example, keys to which various functions are assigned such as a power key, a call key, a numeric key, a character key, a direction key, a determination key, a call key, and a function key are arranged.
When these keys are operated by the user, a signal corresponding to the operation content is generated and output to the control unit 57 as a user instruction.

The audio input / output unit 53 performs input / output processing of an audio signal output from a speaker or an audio signal input from a microphone.
That is, the voice input / output unit 53 amplifies the voice input from the microphone, performs analog / digital conversion, further performs signal processing such as encoding, converts it into digital voice data, and outputs it to the control unit 57. .
The audio input / output unit 53 performs signal processing such as decoding, digital / analog conversion, and amplification on the audio data supplied from the control unit 57, converts the audio data into an analog audio signal, and outputs the analog audio signal to the speaker.

The display unit 8 is configured using, for example, an LCD or an OLED, and displays an image corresponding to the video signal supplied from the control unit 57.
The display unit 8 includes, for example, a telephone number of a transmission destination at the time of wireless transmission by the communication unit 51, a telephone number of a transmission source at the time of reception, contents of received mail and transmitted mail, date, time, remaining battery level, success / failure of transmission, standby Display the screen.
Furthermore, the display unit 8 has a function of displaying various states of the non-contact type IC card. For example, in a so-called wallet mobile phone function, it is information such as usage history and balance.

The storage unit 56 stores various data used for various processes of the mobile phone 1. The storage unit 56 includes, for example, a computer program executed by the control unit 57, an address book for managing personal information such as a telephone number and an e-mail address of a communication partner, a voice file for reproducing a ring tone and an alarm sound, and a standby screen Image files, various setting data, and temporary data used in the program processing.
Moreover, the memory | storage part 56 may memorize | store various information of a non-contact-type IC card.

A circuit 59 for a non-contact type IC card controls a non-contact type IC card function.
The non-contact IC card antenna 59 is electrically connected to the non-contact IC card circuit 59.

The control unit 57 comprehensively controls the overall operation of the mobile phone 1.
That is, in the control unit 57, various processes of the mobile phone 1 (voice calls performed via a circuit switching network, creation and transmission / reception of e-mails, browsing a download site on the Internet, etc.) The operation of each block described above (transmission / reception of signals in the communication unit 51, display of images on the display unit 8, etc.) is controlled so as to be executed according to an appropriate procedure accordingly.

  The control unit 57 also has a function of processing various information of the non-contact type IC card and displaying it on the display unit 8.

  FIG. 4 is an explanatory diagram of a supply circuit that supplies power to various circuit systems of the mobile phone 1.

As shown in FIG. 4, the cellular phone 1 includes a non-contact IC card circuit 59, a non-contact IC card antenna 60, an LDO regulator 61, a second power supply line 62, and a first Schottky. Barrier diode 63, second Schottky barrier diode 64, field effect transistor 65, first power supply line 66, first power supply line portion 67, charge control transistor 68, housing side terminal 72, battery 22, battery side terminal 82 And a power manager IC 78 is mounted.
The charging device 76 provided outside the mobile phone 1 includes an AC power source 75, an AC / DC converter 74, and a charging device side terminal 73.

A combination of the first power supply line 67 and the second power supply line 62 is referred to as a second power supply line 77.
The first Schottky barrier diode 63 and the second Schottky barrier diode 64 are referred to as a power supply unit 80.
As shown in FIG. 4, the contact on the cathode side of the first Schottky barrier diode 63 and the cathode side of the second Schottky barrier diode 64 is referred to as a power output unit 81.

The alternating current power supplied from the alternating current power source 75 is converted into direct current by the alternating current direct current converter 74.
Then, DC power is supplied to the mobile phone 1 from the housing side terminal 72 of the mobile phone 1 through the charging device side terminal 73.
The power supplied from the housing side terminal 72 is turned on / off by the charge control transistor 68.
ON / OFF of the charge control transistor 68 is controlled by the power supply control unit 50.
Specifically, when the charging device 76 is connected to the mobile phone 1, the charging control transistor 68 is turned on so that the power of the charging device 76 is supplied to the first power supply line unit 67. Yes.
When the charging device 76 is removed, the charging control transistor 68 is turned off.

The first power supply line unit 67 is a line for supplying power to the power manager IC 78. As a method of supplying power to this line, there are a method of supplying from the charging device 76 and a method of supplying from the battery 22.
The power of the charging device 76 or the battery 22 is supplied to the first power supply line unit 67. Then, power is supplied to the power manager IC 78 connected to the first power supply line unit 67.

The power manager IC 78 uses the power supplied from the first power supply line unit 67 as a voltage necessary for various circuit systems (LCD, CPU, LED, camera unit, communication unit, etc.) mounted on the mobile phone 1. The power is converted into
In the present invention, in particular, power is supplied to the circuit 59 for the non-contact type IC card.
The power supplied from the power manager IC 78 to the circuit 59 for the non-contact IC card is not necessarily required to drive the non-contact IC card. If there is power from the LDO regulator 61 described later, the power is not contacted. The function of the IC card can be exhibited.
When the power from the power manager IC 78 is supplied to the non-contact IC card circuit 59, the balance information of the non-contact IC card is displayed on the display unit 8 in addition to the function of the non-contact IC card. The usage history can be displayed.
That is, the power from the power manager IC 78 is not necessarily required for the circuit 59 of the non-contact type IC card, but if it is present, more advanced functions can be used.

A field effect transistor 65 is mounted between the battery 22 and the first power supply line portion 67.
The field effect transistor 65 is turned on to supply power from the battery 22 to the power manager IC 78 via the first power supply line 67 when the mobile phone 1 is not connected to the charging device 76.
Conversely, when the mobile phone 1 is connected to the charging device 76, the field effect transistor 65 is the first power supplied from the charging device 76 when sufficient power is not stored in the battery 22. The connection with the supply line unit 67 is turned ON.
Further, when the mobile phone 1 is connected to the charging device 76, the field effect transistor 65 is a first power supply line portion to which power is supplied from the charging device 76 when sufficient power is stored in the battery 22. The connection with 67 is turned off.
The power supply controller 50 also controls the field effect transistor 65.

The second power supply line unit 62 is electrically connected to the first power supply line unit 67 and the LDO regulator 61.
Further, the first power supply line 66 is electrically connected to the battery 22 and the LDO regulator 61.
The LDO regulator 61 has a function of outputting a constant voltage of power even when the input changes.
Therefore, as long as a certain amount of power is supplied to the LDO regulator 61, the non-contact IC card circuit 59 is supplied with the power of the required voltage.
If the power from the LDO regulator 61 is supplied, the function as a non-contact IC card can be exhibited even if the power from the power manager IC 78 is not supplied.

A second Schottky barrier diode 64 having an anode connected to the first power supply line 67 and a cathode connected to the LDO regulator 61 is mounted on the second power supply line 62.
A first Schottky barrier diode 63 is mounted on the first power supply line 66. The first Schottky barrier diode 63 has an anode connected to the battery 22 side and a cathode connected to the LDO regulator 61 side.
As described above, the presence of the second Schottky barrier diode 64 allows the power of the battery 22 to be supplied only to the LDO regulator 61 and not to be supplied to the power manager IC 78.
In addition, since the first Schottky barrier diode 63 is provided, the power supplied by the charging device 76 is supplied only to the LDO regulator 61 and can be prevented from being supplied to the battery 22.
Note that if the electric power from the charging device 76 is connected without a switch such as the field effect transistor 65, the life of the battery 22 is remarkably shortened. Therefore, the first Schottky barrier diode 63 is disposed to prevent this. The
Here, the reason why the first Schottky barrier diode 63 is not a simple diode but a Schottky barrier diode is to reduce the voltage drop as much as possible before the power supplied from the battery 22 reaches the LDO regulator 61.
That is, even if the first power supply line 66 is provided with a simple diode to avoid the field effect transistor 65 and supply power to the LDO regulator 61, it is meaningless if there is a large voltage drop due to the diode. Because.

The circuit configuration configured as described above will be described in comparison with the circuit configurations shown in FIGS.
FIG. 5 is a first comparative example.
FIG. 6 is a second comparative example.

In the circuit configuration of FIG. 5, the first power supply line 66 is eliminated. In this case, when power is supplied from the charging device 76, no problem arises because sufficient power is supplied to the power manager IC 78 and the LDO regulator 61.
On the other hand, even when the charging device 76 is not connected, a problem does not occur in the same manner even when sufficient power is stored in the battery 22.
On the other hand, a problem arises when the charging device 76 is not connected and when sufficient electric power is not stored in the battery 22.
In this case, when sufficient power is not stored in the battery 22, the power manager IC 78 stops supplying power to the various circuit systems and the circuit 59 for the non-contact IC card. Further, the power supply control unit 50 turns off the field effect transistor 65.
Even in this state, during a certain amount of power to the battery 22, even if the field effect transistor 65 is turned off, the field effect transistor is in the same state as having the parasitic diode 79 due to its structure. Therefore, although the voltage drop of about 0.6V occurs, the first power supply line 67 can still be supplied with power. The electric power can be supplied to the non-contact IC card circuit 59 via the LDO regulator 5.
However, if the power of the battery 22 is further consumed and there is a voltage drop of 0.6 V, the power required for the circuit for the non-contact IC card is not supplied and the non-contact IC card function cannot be used. End up.
In other words, the power reduction of 0.6 V makes it impossible to use the non-contact IC card function even though the battery still has a power margin of 0.6 V.
Such a situation is not desirable because the function of the non-contact type IC card often exhibits a very important function, and it is desirable to make it usable for as long a time as possible.

Therefore, in the present invention, as shown in FIG. 4, the first power supply line 66 is used to supply power to the LDO regulator 61 without going through the field effect transistor 65.
By doing in this way, even if the electrical storage amount of the battery 22 falls and a voltage falls, the function of a non-contact-type IC card can be used to the limit.

Although it seems that this problem can be solved by removing the field effect transistor 65, another problem arises this time.
If the field effect transistor 65 is not present, it is good when the charging device 76 is charging and the power is full and the battery is fully charged. Immediately, power is supplied from the charging device 76 and the battery is charged.
This means that the charging is performed little by little. When such charging is performed, the battery 22 is damaged very quickly.
Therefore, it is necessary to provide a field effect transistor 65 between the battery 22 and the first power supply line portion 67 so that the number of times of charging does not increase excessively.
This control is performed by the power supply controller 50.
Therefore, the field effect transistor 65 cannot be removed.

Next, with the circuit configuration of FIG. 6, it seems that the voltage of the battery 22 can be supplied to the LDO regulator 61 without a voltage drop caused by the field effect transistor 65.
However, problems arise if the battery 22 is removed while the charging device 76 is attached.
First, the charging device 76 supplies power to the first power supply line unit 67, and the first power supply line unit 67 supplies power to the power manager IC 78.
The power manager IC 78 supplies power to the non-contact IC card circuit 59 and various circuit systems.
That is, the power from the power manager IC is supplied to the circuit 59 for the non-contact type IC card.
However, the power supply control unit 50 automatically turns off the field effect transistor 65 when the battery 22 is removed.
Then, the power supply from the LDO regulator 61 to which power is not supplied from the battery 22 is not supplied to the circuit 59 of the non-contact IC card.
Then, although the electric power from the power manager IC is supplied to the circuit 59 for the non-contact type IC card, the electric power is not supplied from the LDO regulator 61. That is, inconsistency occurs.
Then, the circuit of the non-contact type IC card is not driven, and such mismatching damages the IC of the circuit 59 for the non-contact type IC card.
Therefore, in the present invention, the second power supply line portion 62 is provided as shown in FIG.

The operation of the present invention in FIG. 4 will be described below.
At the time of charging, that is, when power is supplied from the charging device 76, the charge control transistor 68 is turned on, and power is supplied from the charging device 76 to the first power supply line unit 67.
The power is also supplied to the power manager IC 78 connected to the first power supply line unit 67. The power manager IC 78 supplies power to various circuit systems and a circuit 59 for a non-contact IC card.
Further, since the first power supply line unit 67 is also connected to the second power supply line unit 62, the power from the charging device 76 is also supplied to the LDO regulator 61.
Further, when the battery 22 is not fully charged, the field effect transistor 65 is turned on by the power supply control unit 50 and is electrically connected to the first power supply line unit 67. As a result, the battery 22 is charged by the charging device 76. When the battery 22 is fully charged, the field effect transistor 65 is turned off by the power supply controller 50.
Since the voltage of the battery 22 is lower than the voltage of the charging device 76, the second power is supplied between the second power supply line unit 62 from the charging device 76 and the first power supply line 66 from the battery 22. The supply line unit 62 is prioritized.
Therefore, when the charging device 76 is connected, the power of the battery 22 is not used.
In this state, the mobile phone 1 can use the non-contact IC card function and additional functions such as its balance, and all other functions of the other mobile phone 1.

Next, the case where the charging device 76 is removed but the battery capacity is sufficient will be described.
First, the field effect transistor 65 is turned on by the power supply control unit 50, and power is supplied to the first power supply line unit 67. The power manager IC 78 is also supplied with power from the battery 22. The power manager IC 78 supplies power to various circuit systems and a circuit 59 for a non-contact type IC card.
Further, the power of the battery 22 is supplied to the LDO regulator 61 through the first power supply line 66.
Note that the power of the battery 22 is not supplied to the LDO regulator 61 via the second power supply line unit 62. This is because the power from the second power supply line unit 62 passes through the field effect transistor 65 and thus has a lower voltage than the power through the first power supply line 66.
In this state, the mobile phone 1 can use the non-contact IC card function and additional functions such as its balance, and all other functions of the other mobile phone 1.

Finally, the case where the charging device 76 is removed but the battery capacity is reduced will be described.
In this case, the power supply control unit 50 turns off the field effect transistor 65.
If it does so, the electric power of the battery 22 will not be supplied to the 1st electric power supply line part 67 and the power manager IC78.
Then, since power is not supplied from the power manager IC 78 to the circuit 59 for the non-contact type IC card, balance inquiry, usage history, etc. which are additional functions among the functions of the non-contact type IC card cannot be used.
On the other hand, since power is supplied to the LDO regulator 61 from the first power supply line 66, the power via the LDO regulator 61 is supplied to the circuit 59 for the non-contact IC card.
Thereby, the function of the non-contact type IC card can be used continuously.
In this state, since the electric power from the battery 22 is supplied only to the circuit 59 for the non-contact type IC card, the battery remaining amount of the battery 22 is saved, and the non-contact type IC card function is maintained for a longer time. Can be used.
Since the first Schottky barrier diode 63 is mounted on the first power supply line 66, the voltage effect is small, and appropriate power is supplied to the circuit 59 for the non-contact IC card for a longer period. Can continue to supply.

With the above configuration, it is possible to supply necessary power to the circuit 59 for the non-contact type IC card while protecting various electrical components constituting the circuit system with a simple configuration.
Further, even if the voltage of the battery 22 decreases, power can be supplied to the circuit 59 for the non-contact type IC card.
Furthermore, even when the battery 22 is removed during charging, overvoltage to the circuit 59 for the non-contact IC card can be prevented.

  FIG. 7 is a table summarizing the effects of the first comparative example, the second comparative example, and the embodiment of the present invention.

FIG. 7A is a table showing whether the non-contact IC card function can be used even when the power is turned off.
FIG. 7B is a table showing whether or not the IC of the circuit 59 for the non-contact type IC card is damaged.

This will be described from the viewpoint of whether a non-contact IC card can be used.
(1) in FIG. 7A will be described.
(1) in FIG. 7A is a state in which the battery 22 is mounted and the charging device 76 is mounted.
At this time, in the circuit of the first comparative example (FIG. 5), even when the voltage of the battery 22 is in a sufficient state (4.2 V to 3.3 V), it is less than that (3.3 V or less). However, the same operation is possible.
On the other hand, the circuit of the second comparative example (FIG. 6) can be operated if the voltage of the battery 22 is sufficient (4.2 V to 3.3 V), but the voltage of the battery 22 is insufficient. When it is (3.3V or less), it cannot operate.
That is, even if power is sufficiently supplied to the circuit 59 of the non-contact type IC card via the power manager IC 78, the capacity of the battery 22 is reduced and the circuit of the non-contact type IC card via the LDO regulator 61 is reduced. If the power supply to 59 becomes insufficient, the circuit 59 for the non-contact type IC card cannot be operated.
However, the non-contact IC card function can be used until the power supply to the circuit 59 of the non-contact IC card via the LDO regulator 61 becomes insufficient.
Therefore, the second comparative example is a triangle mark.
On the other hand, in the embodiment of the present invention, since it can be used in any state, it is a circle.

(2) in FIG. 7A is a state where the battery 22 is mounted but the charging device 76 is not mounted.
In this state, in the circuit of the first comparative example (FIG. 5), when the voltage of the battery 22 is sufficient (4.2 V to 3.3 V), sufficient power is shared with the non-contact type IC card. Is operable.
However, in a state lower than that (3.3 V or lower), the power dropped by the field effect transistor 65 is supplied to both the power manager IC 78 and the LDO regulator 61, and thus cannot be used.
On the other hand, in the circuit of the second comparative example (FIG. 6), the non-contact IC card function can be used when the battery 22 has sufficient power (4.2 to 3.3 V). All the functions of the non-contact type IC card cannot be used when the power of the non-contact type IC card is reduced (3.3 V or less).
That is, power is supplied to the power manager IC 78 via the field effect transistor 65. Then, since the voltage that has been dropped is supplied to the power manager IC 78, power is not supplied from the power manager IC 78 to the circuit 59 for the non-contact IC card.
However, power can be supplied from the battery 22 to the circuit 59 for the non-contact type IC card via the LDO regulator 61.
Then, the expanded functions (balance inquiry, usage history inquiry, etc.) of the non-contact type IC card cannot be used, but the minimum functions as the non-contact type IC card can be used.
Therefore, it is a triangle mark.
Even in the configuration of the second comparative example, it goes without saying that even if the voltage of the battery 22 further decreases, the minimum functions as the non-contact type IC card cannot be used.
Since the second comparative example and the embodiment of the present invention perform exactly the same operation, they are the same as the second comparative example. Therefore, it is also a triangle mark.

(3) in FIG. 7A is a state where the battery 22 is not attached but the charging device 76 is attached.
In the first comparative example and the embodiment of the present invention, all the functions of the non-contact type IC card can be used when the charging device 76 as an external power source is attached.
However, in the second comparative example, if the battery 22 is removed, the power via the LDO regulator is not supplied to the circuit 59 of the non-contact IC card, so the function of the non-contact IC card is not used at all. Will not be able to.
Therefore, a cross mark is described.

(4) in FIG. 7A is a state where the battery 22 is not attached and the charging device 76 is not attached.
In this state, any circuit configurations of the embodiment of the present invention, the first comparative example, and the second comparative example cannot be used at all.
Therefore, it cannot be compared.

This will be described from the viewpoint of inconsistency in the IC of the non-contact type IC card.
(5) in FIG. 7B will be described.
(5) in FIG. 7B is a state in which the battery 22 is mounted and the charging device 76 is mounted.
At this time, in the circuit of the first comparative example (FIG. 5), even when the voltage of the battery 22 is in a sufficient state (4.2 V to 3.3 V), it is less than that (3.3 V or less). However, the same operation is possible. Therefore, it is a circle.
On the other hand, in the circuit of the second comparative example (FIG. 6), the circuit of the second comparative example (FIG. 6) can operate if the voltage of the battery 22 is sufficient (4.2V to 3.3V). However, it cannot operate when the voltage of the battery 22 is insufficient (3.3 V or less).
That is, power is supplied to the circuit 59 of the non-contact IC card via the power manager IC 78 regardless of how much the voltage of the battery 22 decreases.
However, when the capacity of the battery 22 is reduced, it becomes impossible to supply power to the circuit 59 of the non-contact IC card via the LDO regulator 61.
Then, mismatch occurs in the IC of the circuit 59 for the non-contact type IC card.
However, the function of the non-contact type IC card can be used until the capacity of the battery 22 is still present and power cannot be supplied to the circuit 59 of the non-contact type IC card via the LDO regulator 61.
Therefore, it is a triangle mark.
On the other hand, in the embodiment of the present invention, since it can be used in any state, it is a circle.

FIG. 7B (6) shows a state in which the battery 22 is attached but the charging device 76 is not attached.
When the charging device 76 is not mounted, no mismatch occurs in any of the embodiment of the present invention, the first comparative example, and the second comparative example.
Therefore, both are circles.

FIG. 7B (7) shows a state in which the battery 22 is not attached but the charging device 76 is attached.
In the first comparative example and the embodiment of the present invention, when the charging device 76 that is an external power supply is attached, mismatching to the circuit of the non-contact type IC card cannot occur.
However, in the second comparative example, if the battery 22 is removed, the power via the LDO regulator is not supplied to the circuit 59 of the non-contact type IC card. There is consistency.
Therefore, a cross mark is described.

FIG. 7B (8) shows a state in which the battery 22 is not attached and the charging device 76 is not attached.
In this state, any circuit configurations of the embodiment of the present invention, the first comparative example, and the second comparative example cannot be used at all.
Therefore, it cannot be compared.

According to the above embodiment, the cellular phone 1 of the present invention has the circuit 59 for the non-contact type IC card.
Further, the power from the first power supply line 66 that can supply the power from the battery 22 as the internal power source to the circuit 59 for the non-contact type IC card and the power from the charging device 76 as the external power source are the non-contact type. And a power supply unit 80 that supplies any of the power from the second power supply line 77 that can be supplied to the IC card circuit 59 to the contactless IC card circuit 59. .
Furthermore, even if power supply from the battery 22 or power from one of the charging devices 76 is reduced or stopped, power can be supplied from the other to the circuit 59 for the non-contact IC card.
By adopting such a configuration, it is possible to supply power to the circuit for the non-contact type IC card even when the voltage of the battery 22 decreases.

A first power supply terminal 82 connected to one end of the first power supply line 66 and connectable to the battery 22; a second power supply terminal 72 connected to one end of the second power supply line 77 and connectable to the charging device 76; And a power control unit 78 that receives power from the second power supply line 77 and controls power supply to the circuit system.
Further, it is connected between one end of the first power supply line 66 and one end of the second power supply line 77, and is held in the ON state when the battery is connected to the first power supply terminal 82, and is not connected. And a field effect transistor 65 which is held in an OFF state in the case of the state.
Then, the power output unit outputs a high-voltage power among the first power in the first power supply line 66 set via the first power supply terminal 82 and the second power set from the second power supply line 77. And a power supply unit 80 corresponding to a power supply means for supplying power to the circuit 59 for the non-contact type IC card.
With such a configuration, power can be supplied to the circuit for the non-contact type IC card even when the voltage of the battery 22 decreases.
Furthermore, even when the battery 22 is removed during charging, overvoltage to the circuit 59 for the non-contact IC card can be prevented.

Connected between one end of the second power supply line 77 and the second power supply terminal 72, is held in the ON state when the charging device 76 is connected to the housing side terminal 72, and is OFF in the non-connected state And a charge control transistor 68 held in the memory.
With such a configuration, when the charging device 76 is connected, charging and power supply to the mobile phone 1 are automatically performed.

The power supply unit 80 is disposed on the first power supply line 66, has a first Schottky barrier diode 63 having an anode connected to the battery-side terminal 82 and a cathode provided on the power output unit 81, and a second A second Schottky barrier diode 64 disposed on the power supply line 77, having an anode connected to the charge control transistor 68 and a cathode disposed on the power output unit 81.
The forward voltage of at least the first Schottky barrier diode 63 of the first Schottky barrier diode 63 and the second Schottky barrier diode 64 is supplied from the battery side terminal 82 of the field effect transistor 65 by the second power supply. It is set lower than the forward voltage toward the line 77.
With such a configuration, it is possible to selectively supply power from the battery 22 or the charging device 76 to the circuit 59 for the non-contact type IC card, and it is possible to prevent a voltage drop of the power from the battery 22. .

The first diode 63 and the second diode 64 are Schottky barrier diodes.
With such a configuration, the voltage drop of the power from the battery 22 can be prevented.

The power supply control unit 50 that performs stop control to stop power supply to the circuits other than the circuit 59 for the non-contact type IC card when the voltage of the battery 22 is monitored and becomes a predetermined voltage or less.
With such a configuration, even when the charge amount of the battery 22 is reduced, it is possible to use a particularly important non-contact IC card function for a longer time.

When the start of charging by the charging device 76 is detected, the power supply control unit 50 for canceling the stop control is provided.
With such a configuration, when the charging device 76 is connected, the user can use all the functions of the mobile phone 1 even when the battery 22 is not present or the battery 22 is discharged.

The antenna 60 for a non-contact type IC card is provided, and the attached module 59 is a circuit 59 for the non-contact type IC card.
With such a configuration, even when the charge amount of the battery 22 is reduced, it is possible to use a particularly important non-contact IC card function for a longer time.

  The present invention is not limited to the above embodiment, and may be implemented in various aspects.

The mobile electronic device is not limited to the mobile phone 1. For example, the portable electronic device may be a notebook computer, a PDA, a game machine, or a camera. The portable electronic device is not limited to a foldable type. The case may be configured integrally (only one case).
Further, the accessory module of the present invention is not limited to the circuit 59 for a non-contact type IC card. For example, a circuit system such as a clock function, a television function, a GPS function, or a music playback function may be used.

DESCRIPTION OF SYMBOLS 1 ... Mobile phone, 2 ... 1st housing | casing, 3 ... 2nd housing | casing, 4 ... 1st housing | casing front case, 5 ... 1st housing | casing rear case, 6 ... 2nd housing | casing front case, 7 ... 2nd Housing rear case, 8 ... display unit, 9 ... hinge unit, 10 ... input unit, 11 ... right side surface, 12 ... left side surface, 20 ... internal housing, 21 ... printed circuit board, 22 ... battery, 23 ... battery cover, 24 ... Metal dome, 25 ... Fixed contact, 26 ... Switch, 27 ... Light emitting part, 28 ... Battery storage part, 30 ... Key top, 31 ... Rubber base, 32 ... Key sheet, 33 ... Light guide sheet, 34 ... Decoration sheet 35 ... Key opening, 50 ... Power supply control unit, 51 ... Communication unit, 52 ... Operation unit, 53 ... Audio input / output unit, 55 ... Imaging unit, 56 ... Storage unit, 57 ... Control unit, 59 ... Non-contact type Circuit for IC card, 60 ... Antenna for non-contact type IC card 61 ... LDO regulator, 62 ... second power supply line section, 63 ... first Schottky barrier diode (first diode), 64 ... second Schottky barrier diode (second diode), 65 ... field effect transistor, 66 ... 1st power supply line, 67 ... 1st power supply line part, 68 ... Transistor for charge control (switch element), 72 ... Housing side terminal (2nd power supply terminal), 73 ... Charging apparatus side terminal, 74 ... AC DC converter, 75 ... AC power supply, 76 ... charging device, 77 ... second power supply line, 78 ... power manager IC (power control unit), 79 ... parasitic diode, 80 ... power supply unit (power supply means), 81 ... Power output unit, 82 ... Battery side terminal (first power supply terminal)

Claims (7)

Attached module,
From the first power supply line that can supply power from the battery that is an internal power source to the attached module, and from the second power supply line that can supply power from the charging device that is an external power source to the attached module Power supply means for supplying any one of the power to the accessory module;
Connected between one end of the first power supply line and one end of the second power supply line, held in the ON state when the battery is connected, and held in the OFF state when not connected A field effect transistor,
A power control unit that monitors the voltage of the battery and performs stop control to stop power supply to other than the attached module when the voltage becomes a predetermined voltage or lower, and
When the stop control is performed by the power supply control unit, power from the battery is supplied to the attached module via the first power supply line without passing through the field effect transistor,
A portable electronic device capable of supplying power to an attached module from the other even when power supply from the battery or power from one of the charging devices is reduced or stopped. A first power supply terminal connected to one end of the first power supply line and connectable to the battery;
A second power supply terminal connected to one end of the second power supply line and connectable to a charging device;
A power control unit that receives power from the second power supply line and controls power supply to the circuit system;
A high voltage power among the first power in the first power supply line set via the first power supply terminal and the second power set from the second power supply line via the power output unit. have a, a power supply unit corresponding to a power supply means for supplying to the auxiliary module Te,
The field effect transistor is connected between one end of the first power supply line and one end of the second power supply line, and is maintained in an ON state when a battery is connected to the first power supply terminal. The portable electronic device according to claim 1, wherein the portable electronic device is held in an OFF state in a non-connected state . Connected between one end of the second power supply line and the second power supply terminal, held in the ON state when the charging device is connected to the second power supply terminal, and OFF in the non-connected state The portable electronic device according to claim 2. The power supply unit
A first diode disposed on the first power supply line, an anode connected to the first power supply terminal, and a cathode disposed on the power output unit;
A second diode disposed on the second power supply line, having an anode connected to the switch element, and a cathode disposed on the power output unit;
Of the first diode and the second diode, at least the forward voltage of the first diode is a forward voltage from the first power supply terminal of the field effect transistor toward the second power supply line. The portable electronic device of Claim 3. The portable electronic device according to claim 4, wherein the first diode and the second diode are Schottky barrier diodes. When detecting the charge start by the charging device, a portable electronic device according to any one of claims 1-5 having a power control unit for releasing said stop control. It has an antenna for non-contact type IC card,
Portable electronic device of the accessory module according to claim 1-6 any one is a circuit for non-contact type IC card.

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