JP2013030876A - Mobile communication terminal, communication system, and charger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible for a mobile communication terminal to prevent the transmission and reception efficiency in its communication from declining due to interaction between the mobile communication terminal and the wiring in a charger coming close to its built-in antenna in the state the mobile communication terminal is set to the charger because the mobile communication terminal is often under constraint on an arrangement position of the built-in antenna due to a relatively large number of electronic components packed in a relatively small case.SOLUTION: A mobile communication terminal uses the wiring in a charger as part of an antenna in the state in which the mobile communication terminal is set to the charger.

Description

  The present invention relates to a technique for a mobile communication terminal connected to a charger.

  Conventionally, for example, as described in Patent Document 1, a portable communication terminal that charges a built-in secondary battery with a current supplied from the charger in a state where the battery is set in an external charger is known. ing.

JP 2000-101893 A

Generally, in a mobile communication terminal, when a metal is brought close to a built-in antenna, transmission / reception efficiency in communication is reduced due to an interaction between an electromagnetic wave used for communication performed using the built-in antenna and the metal.
Since the mobile communication terminal has a relatively large number of electronic components incorporated in a relatively small casing, the arrangement position of the built-in antenna is often restricted. Thus, in a state where the mobile communication terminal is set in the charger, the built-in antenna of the mobile communication terminal and the wiring in the charger may have to be in a positional relationship close to each other. In such a mobile communication terminal, when the mobile communication terminal is set in the charger, the transmission / reception efficiency in the communication is reduced due to the interaction with the wiring in the charger close to the built-in antenna. Become.

  Therefore, the present invention has been made in view of such problems, and even when the mobile communication terminal is set in the charger, even if the built-in antenna and the wiring inside the charger are positioned close to each other. An object of the present invention is to provide a mobile communication terminal in which a decrease in transmission / reception efficiency in communication is less likely to occur than in the past.

  In order to solve the above problems, a mobile communication terminal according to the present invention is a mobile communication terminal that can be set in a charger and charge a built-in battery, and the mobile communication terminal is set in a charger. A pair of power receiving terminals provided to face the pair of power supply terminals on the charger side, a charging current supply path wired between the power receiving terminal and the built-in battery, a transmission / reception circuit driven by the built-in battery, A built-in antenna connected to the transmission / reception circuit, wherein one end of the built-in antenna is connected to one of a pair of power receiving terminals, and a filter is inserted in the charging current supply path.

  According to the present invention, in a state where the mobile communication terminal is set in the charger, even if the internal antenna and the wiring inside the charger are in a positional relationship close to each other, the transmission / reception efficiency in communication is higher than in the past. It is possible to provide a mobile communication terminal that is less likely to be lowered.

(A) Perspective view of mobile phone 100, (b) Perspective view of main structure inside mobile phone 100 (A) Side sectional view of the lower part of the mobile phone 100, (b) Front view showing the BT antenna 210 bonded to the inner wall of the casing 201. The circuit diagram which shows the connection relation of the main components of the mobile telephone 100 Circuit diagram showing main circuit configuration of BT LSI 122 Perspective view of charger 500 (A) Perspective view inside insertion hole 511, (b) Perspective view of substrate 650 The circuit diagram which shows the connection relation of the main components of the charger 500 Flow chart of connection processing Flow chart of separation process

<Embodiment>
<Overall configuration>
Hereinafter, as an embodiment of the mobile communication terminal according to the present invention, it has a function of wirelessly communicating with an external Bluetooth compatible device, and is built in by being physically connected (set) to an external charger 500 A mobile phone 100 that charges a battery to be used will be described.

  This cellular phone 100 has a built-in Bluetooth antenna (hereinafter referred to as a “BT (BlueTooth) antenna”), and when the mobile phone 100 is not set in the external charger 500, the BT antenna is compatible with the external Bluetooth. When used as an antenna for communication with a device and set in the charger 500, a conductor portion formed of a part of the internal wiring of the charger 500 and the BT antenna is used for communication with an external Bluetooth compatible device. Used as an antenna for

Hereinafter, details of the configuration of the mobile phone 100 and the charger 500 will be described with reference to the drawings.
<Detailed configuration>
<Mobile phone 100>
FIG. 1A is a perspective view of the mobile phone 100, and FIG. 1B is a perspective view of main components inside the mobile phone 100.

As shown in FIG. 1A, a mobile phone 100 includes an input key group 101 including a plurality of input keys, a display 102, a speaker hole 103, and a receiver hole 104 on a main surface thereof, and an anode on a lower side surface thereof. A power receiving terminal hole 111 and a cathode power receiving terminal hole 112 are provided.
As shown in FIG. 1B, the cellular phone 100 has a substrate 120, a battery 130, and an antenna assembly 140 built in the housing.

The battery 130 is, for example, a lithium ion secondary battery, and supplies power to the electronic components that constitute the mobile phone 100. However, in a state where the mobile phone 100 is set in the charger 500, electric power is supplied from the charger 500 to the electronic components constituting the mobile phone 100.
The antenna structure 140 is a structure including a communication antenna 141 for transmitting and receiving a 2 GHz band signal used for communication performed by the mobile phone 100 with an external base station.

The communication antenna 141 is a monopole antenna having an electrical length of a length (about 37.5 mm) that is a quarter of the wavelength of an electromagnetic wave in the 2 GHz band used for communication with an external base station. It is made of a metal (for example, copper) thin film and is adhered to the surface of the antenna structure 140.
The board 120 is a printed board on which electronic components and the like are mounted, and has a system LSI (Large Scale Integration) 121, a BT LSI 122, a charging IC (Integrated Circuit) 123, an inductor 124, a magnetic sensor 125, and a calling LSI 126 on the surface. The anode power receiving terminal 150, the cathode power receiving terminal 160, the first spring pin 127, and the second spring pin 128 are attached.

The anode power receiving terminal 150 is an anode side terminal of a pair of Yin Yang receiving a DC current supply from the charger when the mobile phone 100 is set in the charger 500 for charging the battery 130. The metal thin film (for example, stainless steel) is mounted at a position facing the anode power receiving terminal hole 111 on the lower side surface of the mobile phone.
The cathode power receiving terminal 160 is a cathode side terminal of a pair of Yin Yang receiving a DC current supply from the charger when the mobile phone 100 is set in the charger 500 for charging the battery 130. It is made of a metal (for example, stainless steel) thin film and is mounted at a position facing the cathode power receiving terminal hole 112 on the lower side surface of the mobile phone.

  Each of the first spring pin 127 and the second spring pin 128 is a movable probe pin whose tip is expanded and contracted by a spring, has conductivity, and the substrate 120 is built in the casing of the mobile phone 100. 2 is in contact with a BT antenna 210 (not shown in FIG. 1 and described in detail later) made of an L-shaped metal (for example, copper) thin film bonded to the inner surface of the housing. Become.

  FIG. 2A shows a mobile phone in which each of the first spring pin 127 and the second spring pin 128 is in contact with the BT antenna 210 bonded to the inner surface of the casing of the mobile phone 100. It is sectional drawing in the case of seeing 100 from the side. FIG. 2B is a front view when viewed from the main surface of the mobile phone 100, showing that each of the first spring pin 127 and the second spring pin 128 is in contact with the BT antenna 210. The first spring pin 127, the second spring pin 128, and the BT antenna 210 that are actually visible from the outside of the mobile phone 100 are virtually visible from the outside of the mobile phone 100. It is expressed as something that can be done.

The BT antenna 210 is a monopole antenna for transmitting and receiving a 2.4 GHz band electromagnetic wave signal used for communication conforming to the Bluetooth standard, and has a length that is ¼ of the wavelength of the 2.4 GHz band electromagnetic wave. It has an electrical length of (about 31.2 mm), is bonded to the inner surface of the housing 201, and is connected to the first spring pin 127 and the second spring pin 128.
FIG. 3 is a circuit diagram showing a connection relationship of main components of the mobile phone 100.

  As shown in the figure, the mobile phone 100 includes an input key group 101, a display 102, a system LSI 121, a BT LSI 122, a charging IC 123, an inductor 124, a magnetic sensor 125, a calling LSI 126, a battery 130, and a calling antenna 141. The system includes an anode power receiving terminal 150, a cathode power receiving terminal 160, a BT antenna 210, a memory 310, a speaker 320, and a receiver 330. Further, the system LSI 121 includes a processor 300 therein.

The input key group 101 is connected to the system LSI 121 and controlled by the processor 300, and has a function of receiving a key operation from a user and a function of converting the received key operation into an electric signal and sending it to the processor 300.
The display 102 is, for example, a liquid crystal display, is connected to the system LSI 121, is controlled by the processor 300, and has a function of displaying an image, a character string, and the like.

The magnetic sensor 125 is connected to the system LSI 121 and is controlled by the processor 300 to detect the magnetism, and to send a signal indicating that the magnetism is detected to the processor 300 during the magnetism detection period. Have
The speaker 320 is connected to the system LSI 121, is controlled by the processor 300, converts the electrical signal sent from the system LSI 121 into sound, and outputs the sound.

The output sound is transmitted to the outside of the mobile phone 100 through the speaker hole 103.
The receiver 330 is connected to the system LSI 121, controlled by the processor 300, converts audio input through the receiver hole 104 into an electrical signal, and sends the converted electrical signal to the processor 300.

The anode power receiving terminal 150 is connected to the inductor 124 and the BT antenna 210, and the cathode power receiving terminal 160 is connected to the charging IC 123.
The inductor 124 is, for example, a 50 nH coil, and is connected to the anode power receiving terminal 150 and the charging IC 123 to attenuate a 2.4 GHz band signal.
Battery 130 is connected to charging IC 123.

The charging IC 123 is connected to the inductor 124, the cathode power receiving terminal 160, and the battery 130. When an external charger is set in the mobile phone 100, the charging IC 123 is connected to the charger IC via the anode power receiving terminal 150 and the cathode power receiving terminal 160. It has a function of charging the battery 130 using the supplied direct current.
The memory 310 includes a RAM (Random Access Memory), a ROM (Read Only Memory), and a nonvolatile memory. The memory 310 is connected to the system LSI 121 and stores a program that defines the operation of the processor 300 and data used by the processor 300. Remember.

The call antenna 141 is connected to the call LSI 126.
The call LSI 126 is connected to the system LSI 121 and the call antenna 141, controlled by the processor 300, and has a function of communicating with an external base station using a 2 GHz band electromagnetic wave using the call antenna 141.
The BT antenna 210 is connected to the BT LSI 122 and the anode power receiving terminal 150.

The BT LSI 122 is connected to the BT antenna 210 and the system LSI 121, is controlled by the processor 300, and has the following two functions.
Function 1: A function of communicating with an external Bluetooth compatible device using a 2.4 GHz band electromagnetic wave using the BT antenna 210 or the expansion antenna 700 (described later).
Function 2: A function of switching the input impedance at the connection portion with the BT antenna 210 to either one of (1) a state matching the BT antenna 210 and (2) a state matching the expansion antenna 700 .

FIG. 4 is a circuit diagram showing a main circuit configuration of the BT LSI 122.
As shown in the figure, the BT LSI 122 includes a matching circuit 410, an impedance switching circuit 420, a transmission / reception switching switch 430, a reception circuit 440, a demodulation circuit 450, a transmission circuit 460, and a modulation circuit 470.
The matching circuit 410 is connected to the BT antenna 210, the impedance switching circuit 420, and the transmission / reception switching switch 430, and includes a first capacitor 411, a first inductor 412, and a second capacitor 413. The matching circuit 410 is connected to the BT antenna 210. A function of adjusting the input impedance in the unit.

  Here, the capacitance value of the first capacitor 411, the inductance value of the first inductor 412, and the capacitance value of the second capacitor 413 are for BT when a switch 421 (described later) of the impedance switching circuit 420 is in an OFF state. The input impedance at the connection with the antenna 210 is determined so as to match the BT antenna 210.

  The impedance switching circuit 420 is connected to the matching circuit 410 and the system LSI 121, and is controlled by the processor 300. The impedance switching circuit 420 includes a switch 421, a second inductor 422, and a third capacitor 423, and the switch 421 is in the (1) ON state. (2) By switching between the OFF state, the input impedance at the connection with the BT antenna 210 is matched with (1) the state matching the BT antenna 210 and (2) the expansion antenna 700. It has a function to switch to any one of the states.

The impedance switching circuit 420 is controlled by the processor 300 so that the switch 421 is turned on when the mobile phone 100 is activated.
Here, each of the inductance value of the second inductor 422 and the capacitance value of the third capacitor 423 is such that the input impedance at the connection portion with the BT antenna 210 matches the expansion antenna 700 when the switch 421 is on. It is determined to be in a state of being.

The transmission / reception changeover switch 430 is connected to the matching circuit 410, the reception circuit 440, and the transmission circuit 460, and has a function of switching the transmission path from the transmission circuit 460 and the reception path to the reception circuit 440 in a time division manner.
The reception circuit 440 is connected to the transmission / reception selector switch 430 and the demodulation circuit 450, and has a function of receiving a 2.4 GHz band signal transmitted from an external Bluetooth-compatible device and a function of transmitting a reception signal to the demodulation circuit 450. Have.

The demodulation circuit 450 is connected to the reception circuit 440 and the system LSI 121 and has a function of demodulating the reception signal sent from the reception circuit 440 and a function of sending the demodulated signal to the processor 300.
Modulation circuit 470 is connected to transmission circuit 460 and system LSI 121, and has a function of modulating a signal sent from the processor into a 2.4 GHz band signal and a function of sending the modulated signal to transmission circuit 460. .

The transmission circuit 460 is connected to the transmission / reception changeover switch 430 and the modulation circuit 470, and has a function of transmitting a signal transmitted from the modulation circuit 470 to an external Bluetooth compatible device.
Returning to FIG. 3 again, the description of the main components of the mobile phone 100 will be continued.
The system LSI 121 is connected to the input key group 101, the display 102, the BT LSI 122, the magnetic sensor 125, the calling LSI 126, the memory 310, the speaker 320, and the receiver 330, and the built-in processor 300 is stored in the memory 310. By executing the program, the input key group 101, the display 102, the BT LSI 122, the magnetic sensor 125, the calling LSI 126, the memory 310, the speaker 320, and the receiver 330 are controlled to realize various functions in the mobile phone 100. Has the function of

  Here, in addition to the functions (for example, a call function, an internet browsing function, a communication function with a Bluetooth compatible device, etc.) that a general Bluetooth compatible mobile phone has, (1) magnetic A function of turning on the switch 421 while the sensor 125 is detecting magnetism and turning off the switch 421 while the magnetic sensor 125 is not detecting magnetism; (2) a switch when the mobile phone 100 is activated; For example, there is a function of turning 421 on.

<Charger 500>
FIG. 5 is a perspective view of a charger 500 that is used by being set in the mobile phone 100.
As shown in the figure, the charger 500 includes a charger body 510, a cord 520, and an AC plug 530. Then, in a state where the AC plug 530 is inserted into the household power outlet, the lower portion of the mobile phone 100 is inserted (set) into an insertion hole 511 (described later) of the charger main body 510, so that the mobile phone 100 A direct current for charging the battery 130 is supplied.

The charger main body 510 has a substantially rectangular parallelepiped shape, and an insertion hole 511 into which a lower portion of the mobile phone 100 is inserted is opened on the main surface, and a magnet 512 and a substrate 650 (not shown in FIG. 5, which will be described later). ) And built-in.
The magnet 512 is a magnet built in the position of the side surface of the insertion hole 511, and is close to the magnetic sensor 125 when the mobile phone 100 is inserted into the insertion hole 511.

FIG. 6A is a perspective view of the inside of the insertion hole 511.
As shown in the figure, the insertion hole 511 is a substantially rectangular parallelepiped hole, and an anode feeding terminal hole 610 and a cathode feeding terminal hole 620 are further opened on the bottom surface.
The anode power supply terminal hole 610 is a substantially rectangular hole opened at a position facing the anode power receiving terminal hole 111 when the mobile phone 100 is inserted into the insertion hole 511, and is lower than the bottom surface of the insertion hole 511. A protruding anode feeding terminal 630 made of metal (for example, made of stainless steel) having a substantially rectangular parallelepiped shape mounted on a substrate 650 (described later) built in is protruded.

The cathode power supply terminal hole 620 is a substantially rectangular hole opened at a position facing the cathode power receiving terminal hole 112 when the mobile phone 100 is inserted into the insertion hole 511, and is lower than the bottom surface of the insertion hole 511. The protruding cathode feeding terminal 640 made of metal (for example, made of stainless steel) having a substantially rectangular parallelepiped shape mounted on a substrate 650 (to be described later) disposed on the protruding portion protrudes.
When the mobile phone 100 is inserted into the insertion hole 511, that is, when the mobile phone 100 is set in the charger 500, the protruding anode feeding terminal 630 is in contact with the anode receiving terminal 150, and the protruding cathode The power feeding terminal 640 comes into contact with the cathode power receiving terminal 160.

FIG. 6B is a perspective view of the substrate 650 built in the charger 500 at a position below the bottom surface of the insertion hole 511.
As shown in the figure, a substrate 650 is a printed circuit board on which electronic components and the like are mounted, and has a protruding anode feeding terminal 630, a protruding cathode feeding terminal 640, a wiring 660, an inductor 670, and a power supply IC 680 on the main surface. And are attached.

FIG. 7 is a circuit diagram showing a connection relationship of main components of charger 500 in a state where mobile phone 100 is set.
As shown in the figure, the charger 500 includes a cord 520, an AC plug 530, a protruding anode feeding terminal 630, a protruding cathode feeding terminal 640, a power supply IC 680, a wiring 660, and an inductor 670.

The power supply IC 680 is connected to the cord 520, the protruding cathode power supply terminal 640, and the inductor 670, and converts the AC voltage of 100 V supplied from the household outlet through the AC plug 530 and the cord 520 to the direct current of 4.2 V. It has the function of converting to and outputting.
The power supply IC 680 operates as a DC constant voltage source with a potential difference of 4.2 V in a state where the AC plug 530 is inserted into a household power outlet.

The inductor 670 is, for example, a 50 nH coil, and is connected to the power supply IC 680 and the wiring 660 and has a function of attenuating a 2.4 GHz band signal. Here, the connection to the power supply IC 680 is a connection to an anode side terminal as a DC voltage source.
The protruding cathode power supply terminal 640 is a metal (for example, stainless steel) electrode having a substantially rectangular parallelepiped shape, for example, and is connected to the power supply IC 680. Here, the connection to the power supply IC 680 is a connection to a cathode side terminal as a DC voltage source.

The protruding cathode power supply terminal 640 is further connected to the cathode power receiving terminal 160 in a state where the mobile phone 100 is set in the charger 500.
The protruding anode power supply terminal 630 is a metal (for example, stainless steel) electrode having a substantially rectangular parallelepiped shape, for example, and is connected to the wiring 660.
The protruding anode power supply terminal 630 is further connected to the anode power receiving terminal 150 in a state where the mobile phone 100 is set in the charger 500.

The wiring 660 is made of an L-shaped metal (for example, copper) thin film formed on the substrate 650, is connected to the inductor 670 and the protruding anode feeding terminal 630, and is 1/2 of the wavelength of the electromagnetic wave in the 2.4 GHz band. It has an electrical length of 2 (about 62.5 mm).
<Enlarged antenna 700>
The wiring 660, the protruding anode feeding terminal 630, the anode receiving terminal 150, and the BT antenna 210 are connected to each other in a state where the mobile phone 100 is set in the charger 500, thereby forming an enlarged antenna 700. .

The expansion antenna 700 is a monopole antenna for transmitting and receiving a 2.4 GHz band electromagnetic wave signal used for communication conforming to the Bluetooth standard, and has a length (3/4) of the wavelength of the 2.4 GHz band electromagnetic wave ( It has an electrical length of about 93.7 mm) and is connected to the BT LSI 122, the inductor 124, and the inductor 670.
Hereinafter, operations performed by the mobile phone 100 having the above-described configuration and the charger 500 will be described with reference to the drawings.

<Operation>
Here, a connection process and a separation process, which are characteristic operations among the operations performed by the mobile phone 100 and the charger 500, will be described.
<Connection process>
The connection process is a process performed by the activated mobile phone 100, and the mobile phone 100 in which the switch 421 (see FIG. 4) is not set in the charger 500 and is in the off state is inserted into the insertion hole 511. Is inserted into the BT LSI 122, the input impedance of the BT LSI 122 is switched from (1) a state matching the BT antenna 210 to (2) a state matching the expansion antenna 700.

FIG. 8 is a flowchart of the connection process.
The connection process is started when the mobile phone 100 that is not set in the charger 500 and in which the switch 421 is turned off is inserted into the insertion hole 511.
As an example of the case where the switch 421 is turned off in a state where the mobile phone 100 is not set in the charger 500, (1) when the mobile phone 100 which is not set in the charger 500 is activated, (2) When the activated mobile phone 100 set in the charger 500 is separated from the charger 500 (in this case, the operation of turning off the switch 421 will be described later in section <Separation Processing>). Will be described in detail.).

When the mobile phone 100 is inserted into the insertion hole 511, the magnet 512 (see FIG. 5) and the magnetic sensor 125 are in close proximity to each other, so the magnetic sensor 125 detects the magnetism of the magnet 512 (step S810). Then, the magnetic sensor 125 sends a signal indicating that magnetism is detected to the processor 300.
When receiving the signal indicating that the magnetism is detected from the magnetic sensor 125, the processor 300 controls the switch 421 to change from the off state to the on state (step S820).

When the switch 421 is changed to the ON state, the input impedance of the BT LSI 122 at the connection portion with the BT antenna 210 is changed from (1) matching the BT antenna 210 to (2) the expansion antenna 700. The state is switched to the matching state (step S830).
When the process of step S830 ends, the mobile phone 100 ends the connection process.

<Separation process>
The separation process is a process performed by the activated mobile phone 100, and when the mobile phone 100 in which the switch 421 is turned on in the state set in the charger 500 is separated from the charger 500. This is a process of switching the input impedance of the BT LSI 122 from (1) a state matching the expansion antenna 700 to (2) a state matching the BT antenna 210.

FIG. 9 is a flowchart of the separation process.
The separation process is started when the mobile phone 100 in which the switch 421 is turned on, which is set in the charger 500, is separated from the charger 400.
As an example of the case where the switch 421 is turned on while the mobile phone 100 is set in the charger 500, there is a case where the process of step S830 in the above connection process is executed.

  When the mobile phone 100 is separated from the charger 500, the magnet 512 and the magnetic sensor 125 are not in a state of being close to each other, so that the magnetic sensor 125 does not detect the magnetism of the magnet 512 (step S910). Then, the magnetic sensor 125 does not send a signal to the processor 300 indicating that the magnetism sent to the processor 300 is detected.

When the signal indicating that the magnetism is detected is not transmitted from the magnetic sensor 125, the processor 300 controls the switch 421 to change from the on state to the off state (step S920).
When the switch 421 is changed to the off state, the input impedance at the connection portion of the BT LSI 122 with the BT antenna 210 is changed from (1) the state where it matches the expansion antenna 700 to (2) the BT antenna 210. The state is switched to the matching state (step S930).

When the process of step S930 ends, the mobile phone 100 ends the separation process.
<Discussion>
When the mobile phone 100 is not set in the charger 500, the mobile phone 100 communicates with an external Bluetooth device using the built-in BT antenna 210. In this case, the input impedance of the connection portion of the BT LSI 122 with the BT antenna 210 is matched with the BT antenna 210.

When the mobile phone 100 is set in the charger 500, an enlarged antenna 700 (see FIG. 7) including the wiring 660, the protruding anode feeding terminal 630, the anode receiving terminal 150, and the BT antenna 210 is formed. The input impedance at the connection portion of the LSI for LSI 122 with the BT antenna 210 is in a state matched with the expansion antenna 700.
Therefore, when the mobile phone 100 is connected to the charger 500, the mobile phone 100 can communicate with an external Bluetooth compatible device using the formed expansion antenna 700.

  As described above, when the mobile communication terminal of the present embodiment is set in the charger, the wiring inside the charger is used as a part of the antenna. For this reason, even if the built-in antenna and the wiring inside the charger are in a positional relationship close to each other in a state where the mobile communication terminal is set in the charger, the wiring inside the charger is connected to the transmission / reception efficiency in communication. Does not decrease.

Therefore, according to this portable communication terminal, even when the built-in antenna and the wiring inside the charger are close to each other in a state where the portable communication terminal is set in the charger, communication is performed more than ever before. The transmission / reception efficiency is less likely to decrease.
<Supplement>
As described above, as an embodiment of the mobile communication terminal according to the present invention, the mobile phone 100 has been described as an example in the embodiment. However, the present invention can be modified as follows, and the present invention can be modified as described above. Of course, it is not limited to street mobile communication terminals.
(1) In the embodiment, an example of a configuration in which the mobile phone 100 communicates with an external device by performing communication conforming to the Bluetooth standard with the built-in BT antenna 210 has been described. If it is possible to communicate with an external device, it is not always necessary to have a configuration for communicating with an external device by incorporating an antenna used for communication conforming to the Bluetooth standard and performing communication conforming to the Bluetooth standard. For example, an antenna used for communication conforming to the WiFi (Wireless Fidelity) standard may be incorporated to communicate with an external device by performing communication conforming to the WiFi standard.
(2) In the embodiment, the example of the configuration in which the switching between the built-in antenna and the expansion antenna is applied to the BT antenna 210 has been described. However, if the built-in antenna is used for communication with the outside, the BT is not necessarily used. The configuration is not limited to the configuration applied to the communication antenna, and may be configured to be applied to the call antenna 141, for example.
(3) In the embodiment, the example in which the electrical length of the BT antenna 210 is ¼ of the carrier wave used for communication has been described. However, the BT antenna 210 functions efficiently as an antenna used for communication. It is not always necessary that the electrical length is ¼ of the carrier used for communication. For example, the length of ¾ of the carrier used for communication is 5/4, The length may be 1/2, 3/8, or the like.

However, by setting the electrical length of the BT antenna 210 to ¼ of the carrier wave used for communication, the BT antenna 210 can be made relatively compact and have relatively good reception efficiency.
Furthermore, if it is allowed to sacrifice the efficient functioning of the antenna, the electrical length of the BT antenna 210 is determined by other factors (for example, restrictions on the arrangement space). It is also possible that the length is limited.
(4) In the embodiment, the example in which the electrical length of the expansion antenna 700 is 3/4 the length of the carrier wave used for communication has been described. However, the expansion antenna 700 functions efficiently as an antenna used for communication. However, it is not always necessary that the length is 3/4 of the carrier used for communication. For example, the length is 5/4, 1/2, 3 or 3 of the carrier used for communication. The length may be / 8.

However, when the electrical length of the BT antenna 210 is 1/4 of the carrier wave used for communication, the electrical length of the expansion antenna 700 is set to 3/4 of the carrier wave used for communication. Thus, the expansion antenna 700 can be made relatively compact and have a relatively good reception efficiency.
Furthermore, if it is allowed to sacrifice the efficient functioning of the antenna, the electrical length of the expansion antenna 700 is determined by other factors (for example, space constraints). It is possible that the length is too long.
(5) In the embodiment, the example of the configuration in which each of the BT antenna 210 and the expansion antenna 700 is a monopole antenna has been described. However, if the antenna can be used for communication, the monopole antenna is not necessarily used. It is not limited to a certain configuration.
(6) In the embodiment, the example of the configuration in which the detection of the state where the mobile phone 100 is set in the charger 500 is realized by the magnetic sensor 125 detecting the magnetism from the magnet 512 has been described. If a mechanism capable of detecting the state where the telephone 100 is set in the charger 500 is provided, the magnetic sensor 125 does not necessarily have to be realized by detecting the magnetism from the magnet 512. As an example, the charging IC 123 has a function of detecting a potential difference between the anode power receiving terminal 150 and the cathode power receiving terminal 160, and detects that the potential difference between the anode power receiving terminal 150 and the cathode power receiving terminal 160 is larger than a predetermined value. (7) In the embodiment, the example in the case where the mobile communication terminal is a mobile phone has been described. The mobile terminal is not necessarily limited to a mobile phone as long as it has a function. For example, it may be a PDA (Personal Digital Assistant) having a communication function, a portable music player having a communication function, or the like. .
(8) Hereinafter, the configuration of the mobile communication terminal according to the embodiment of the present invention, its modification, and each effect will be described.
(A) A mobile communication terminal according to an embodiment of the present invention is a mobile communication terminal that can be set in a charger and charge a built-in battery, and the mobile communication terminal is set in a charger. A pair of power receiving terminals provided to face the pair of power supply terminals on the charger side, a charging current supply path wired between the power receiving terminal and the built-in battery, a transmission / reception circuit driven by the built-in battery, A built-in antenna connected to the transmission / reception circuit, wherein one end of the built-in antenna is connected to one of a pair of power receiving terminals, and a filter is inserted in the charging current supply path.

  When the mobile communication terminal according to the present embodiment having the above-described configuration is set in the charger, the wiring inside the charger is used as a part of the antenna. For this reason, even if the built-in antenna and the wiring inside the charger are in a positional relationship close to each other in a state where the mobile communication terminal is set in the charger, the wiring inside the charger is connected to the transmission / reception efficiency in communication. Does not decrease.

Therefore, according to this portable communication terminal, even when the built-in antenna and the wiring inside the charger are close to each other in a state where the portable communication terminal is set in the charger, communication is performed more than ever before. The transmission / reception efficiency is less likely to decrease.
(B) In addition, a detection circuit that detects whether or not the own terminal is set in the charger is provided, and the transmission / reception circuit does not detect the setting of the own terminal to the charger. In addition, when the input impedance at the connection portion with the built-in antenna is matched with the state where the portable communication terminal is not set in the charger, and the detection circuit detects the setting of the own terminal to the charger, A matching switching circuit for matching the input impedance at the connection portion with the built-in antenna to a state where the mobile communication terminal is set in the charger may be provided.

As a result, the transmission / reception circuit can efficiently communicate with an external device regardless of whether the mobile communication terminal is set in the charger or the mobile communication terminal is not set in the charger. Can communicate.
(C) Also, the electrical length of the built-in antenna when the mobile communication terminal is not set in the charger, and the electrical power of the built-in antenna that is substantially enlarged when the mobile communication terminal is set in the charger Each of the lengths may be a length for a transmission / reception frequency band of the transmission / reception circuit.

As a result, the transmission / reception circuit can efficiently communicate with an external device regardless of whether the mobile communication terminal is set in the charger or the mobile communication terminal is not set in the charger. Can communicate.
(D) The built-in antenna is a monopole antenna, and the electric length of the built-in antenna in a state where the portable communication terminal is not set in the charger is an abbreviation of the wavelength of the electromagnetic wave in the transmission / reception frequency band of the transmission / reception circuit. The electrical length of the built-in antenna that is substantially expanded in a state where the mobile communication terminal is set in the charger is approximately a quarter of the wavelength of the electromagnetic wave in the transmission / reception frequency band of the transmission / reception circuit. It may be 3.

  Thereby, a portable communication terminal and a charger can each be made compact.

  The present invention can be widely used for portable communication terminals connected to a charger.

100 Mobile phone 121 System LSI
122 BT LSI
123 Charging IC
124 Inductor 125 Magnetic sensor 126 Communication LSI
130 Battery 141 Telephone Antenna 150 Anode Power Receiving Terminal 160 Cathode Power Receiving Terminal 210 BT Antenna 300 Processor 500 Charger 630 Protruding Anode Feeding Terminal 640 Protruding Cathode Feeding Terminal 650 Power Supply IC
660 Wiring 670 Inductor 700 Expanding antenna

Claims (6)

A mobile communication terminal that can be set in a charger and charge the internal battery,
In a state where the mobile communication terminal is set in the charger, a pair of power receiving terminals provided to face the pair of power feeding terminals on the charger side,
A charging current supply path wired between the power receiving terminal and the built-in battery;
A transmission / reception circuit driven by a built-in battery;
A built-in antenna connected to the transceiver circuit;
With
One end of the built-in antenna is connected to one of a pair of power receiving terminals, and a filter is inserted in the charging current supply path. It has a detection circuit that detects whether the terminal is set in the charger,
The transmission / reception circuit has an input impedance at a connection portion with the built-in antenna when the detection circuit does not detect the setting of the terminal on the charger, and the portable communication terminal is not set on the charger. When the detection circuit detects that the terminal is set to the charger, the input impedance at the connection with the built-in antenna is set to the state where the portable communication terminal is set to the charger. The mobile communication terminal according to claim 1, further comprising a matching switching circuit for matching. The electrical length of the built-in antenna when the mobile communication terminal is not set to the charger and the electrical length of the built-in antenna that is substantially enlarged when the mobile communication terminal is set to the charger are respectively The mobile communication terminal according to claim 1, wherein the length is for a transmission / reception frequency band of the transmission / reception circuit. The built-in antenna is a monopole antenna,
The electrical length of the built-in antenna in a state where the portable communication terminal is not set in the charger is approximately a quarter of the wavelength of the electromagnetic wave in the transmission / reception frequency band of the transmission / reception circuit,
The electrical length of the built-in antenna that is substantially enlarged in the state where the portable communication terminal is set in the charger is approximately three-fourths of the wavelength of the electromagnetic wave in the transmission / reception frequency band of the transmission / reception circuit. The mobile communication terminal according to claim 3. A portable communication terminal comprising a pair of power receiving terminals, a transmission / reception circuit, and a built-in antenna connected to the transmission / reception circuit, wherein one end of the built-in antenna is connected to one of the pair of power receiving terminals. A charger for supplying a charging current to
In a state where the mobile communication terminal is set in the charger, a pair of power supply terminals provided to face the pair of power reception terminals on the mobile communication terminal side,
One end is connected to a power supply terminal opposite to a power receiving terminal to which one end of the built-in antenna is connected, and a charging wiring for flowing the charging current;
With
In the state where a filter is inserted in the charging wiring and the mobile communication terminal is set in a charger, the charging wiring is connected to the built-in antenna, and the antenna length of the built-in antenna that is substantially enlarged is predetermined. A battery charger characterized by having an antenna length of. A communication system comprising a charger and a portable communication terminal that can be set in the charger and charge the internal battery,
Mobile communication terminals
In a state where the mobile communication terminal is set in the charger, a pair of power receiving terminals provided to face the pair of power feeding terminals on the charger side,
A charging current supply path wired between the power receiving terminal and the built-in battery;
A transmission / reception circuit driven by a built-in battery;
A built-in antenna connected to the transmission / reception circuit and having one end connected to one of a pair of power receiving terminals;
With
A first filter is inserted into the charging current supply path,
The charger
In a state where the mobile communication terminal is set in the charger, a pair of power supply terminals provided to face the pair of power reception terminals on the mobile communication terminal side,
One end of the built-in antenna is connected to a power supply terminal opposite to a power receiving terminal to which the built-in antenna is connected, and charging wiring for supplying a charging current to be supplied to the mobile communication terminal;
With
In the state where the second filter is inserted in the charging wiring and the mobile communication terminal is set in the charger, the charging wiring is connected to the built-in antenna, and the antenna length of the built-in antenna is substantially enlarged. Is a configuration having a predetermined antenna length.

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