JP4616094B2 - Mobile phone - Google Patents

Description

  The present invention relates to a mobile phone with a built-in wireless transmission antenna, and more particularly to a technique for controlling transmission output of a wireless transmission antenna in a mobile phone.

2. Description of the Related Art Conventionally, some mobile phone cases have a built-in wireless antenna. Especially, in recent years, with the increasing number of functions of mobile phones, not only antennas for performing mobile phone communication but also various other antennas for wireless communication are available. It has come to be mounted in a housing.
For example, there are an increasing number of mobile phones that can be mounted with a television receiving antenna to view a television broadcast and mobile phones that can be mounted with a radio receiving antenna to listen to a radio broadcast.

As described above, the antennas built in the casing of the mobile phone are collectively referred to as “built-in antennas”.
For example, Patent Document 1 discloses a mobile phone in which a plurality of built-in antennas are built in a housing corresponding to a plurality of different frequency bands.
Japanese Patent Publication No. 2004-254098

By the way, recent mobile phones are not only simple ones consisting of one case, but also two cases (generally referred to as “folding type”) connected to each other through a hinge so as to be opened and closed, There are some deformable ones such as one comprising two housings connected to each other so as to be opened and closed by providing a slide mechanism and sliding on each other (generally called “slide type”).
However, when these foldable and slide-type mobile phones are equipped with a built-in antenna for wireless transmission, when two connected casings are closed, appropriate radio wave radiation is disturbed in the immediate vicinity of the built-in antenna. The shield may be located, and the intensity of radio waves from the built-in antenna that can be received from the outside may be reduced.

  That is, for example, when a display unit such as an LCD (Liquid Crystal Display) is provided in one of two housings and a built-in antenna is mounted on the other, the two antennas are close to the built-in antenna when the two housings are closed. In some cases, the LCD covers and the magnesium alloy, which is the frame member of the LCD, is located in the immediate vicinity of the built-in antenna. In such a situation, the magnesium alloy absorbs radio waves radiated from the built-in antenna, and prevents proper radio wave radiation, thereby lowering the electric field intensity that can be received from the outside.

  In addition, some recent mobile phones include an earphone jack in a housing and can be viewed by attaching an earphone to a radio or the like. When such a mobile phone has a built-in antenna, When the cable is propagated by receiving the radio wave of the built-in antenna, it functions as an external antenna, and the electric field strength from the built-in antenna that can be received from the outside may be increased.

  As described above, in a mobile phone to which an external device such as a deformable mobile phone or an earphone can be attached and detached, the electric field strength that can be received from the outside may change in accordance with the deformation or attachment and detachment, but the electric field strength is reduced. If the transmission output of the built-in antenna is adjusted to be stronger in accordance with the condition, the transmission output becomes too strong in the state where the electric field strength is improved. The upper limit may be exceeded.

  Therefore, in view of the above-mentioned problems, the present invention provides a mobile phone in which a deformable mobile phone or a mobile phone in which an external device can be attached / detached does not exceed the upper limit value of the electric field strength stipulated by the law even if it is deformed or attached The purpose is to provide.

In order to solve the above problems, a mobile phone according to the present invention is a mobile phone that can be deformed between a plurality of forms, and attenuates a built-in antenna for radio transmission and a transmission output of the built-in antenna by a predetermined amount. An attenuation circuit and a switching unit that switches connection and disconnection between the built-in antenna and the attenuation circuit in accordance with the deformation of the mobile phone.
Here, the deformation is, for example, opening and closing in a foldable or slide type mobile phone.

  With the above configuration, according to the mobile phone according to the present invention, when the electric field strength from the built-in antenna that can be received from the outside in accordance with the deformation changes, the transmission output of the built-in antenna according to the state in which the electric field strength decreases. Even if the adjustment is made, it is possible to prevent the transmission output from becoming too strong due to the action of the attenuation circuit in a state where the electric field strength is improved. As a result, in both the state in which the electric field strength from the built-in antenna is reduced and the state in which the electric field strength from the built-in antenna is lowered and improved, the mobile phone can increase the transmission output as much as possible within the range that does not exceed the upper limit value of the electric field strength regulated by the law Can be designed.

  Further, the mobile phone includes two housings that are connected to each other by a connecting portion so as to be opened and closed, and an open / close detecting portion that detects an open / closed state of the two housings, and the switching portion includes the open / close detecting portion. When the open state is detected, the built-in antenna and the attenuation circuit are connected, and when the open / close detection unit detects the closed state, the built-in antenna and the attenuation circuit may be disconnected. .

  Thus, in general, mobile phones that can open and close two housings called “foldable” and mobile phones that can open and close two housings called “sliding” can be received from the outside as they are opened and closed. When the electric field strength from the built-in antenna changes, even if the transmission output of the built-in antenna is adjusted according to the state where the electric field strength is reduced, transmission is performed by the action of the attenuation circuit when the electric field strength is improved. It is possible to suppress the output from becoming too strong.

  In addition, the mobile phone according to the present invention includes a built-in antenna for wireless transmission, an attenuation unit that attenuates a transmission output of the built-in antenna by a predetermined amount, an attachment / detachment unit for attaching / detaching an external device including a metal member, and the attachment / detachment unit. When the attachment / detachment detection unit detects the attachment state, the built-in antenna and the attenuation circuit are connected, and the attachment / detachment detection unit does not detect the attachment state. And a switching unit that disconnects the built-in antenna and the attenuation circuit.

  With the above configuration, according to the mobile phone according to the present invention, when the electric field intensity from the built-in antenna that can be received from the outside as the external device is attached / detached changes, the built-in antenna is adapted to the state in which the electric field strength decreases. Even if the transmission output is adjusted, it is possible to suppress the transmission output from becoming too strong due to the action of the attenuation circuit when the electric field strength is improved. As a result, in both the state in which the electric field strength from the built-in antenna is reduced and the state in which the electric field strength from the built-in antenna is lowered and improved, the mobile phone can increase the transmission output as much as possible within the range that does not exceed the upper limit value of the electric field strength regulated by the law Can be designed.

In the mobile phone, when the detachable part and the external device are in an attached state, the metal member may be electrically connected to a circuit board provided with the built-in antenna via the detachable part. Good.
Thereby, even if the metal member electrically connected to the circuit board provided with the built-in antenna functions as one antenna together with the built-in antenna, the transmission output does not become too strong due to the action of the attenuation circuit. Can be limited to.

In the mobile phone, the external device may be an earphone having a cable, and the cable may include the metal member.
As a result, when the electric field intensity from the built-in antenna that can be received from the outside with the attachment / detachment of the earphone changes, the electric field strength can be adjusted even if the transmission output of the built-in antenna is adjusted according to the state in which the electric field intensity decreases. Therefore, the transmission output can be suppressed from becoming too strong due to the action of the attenuation circuit.

Furthermore, in the above mobile phone, the built-in antenna is an FM (Frequency Modulation) transmission antenna provided separately from the telephone antenna for the mobile phone, and the mobile phone includes a storage unit for storing data, and the storage unit And an FM transmitter that transmits the data stored in the internal antenna via the built-in antenna.
Thereby, when the electric field intensity from the FM transmitting antenna that can be received from the outside in accordance with the deformation changes, the electric field intensity can be adjusted even if the transmission output of the FM transmitting antenna is adjusted in accordance with the state where the electric field intensity decreases. Therefore, the transmission output can be suppressed from becoming too strong due to the action of the attenuation circuit.

<First Embodiment>
Hereinafter, as an example of a mobile phone according to the present invention, a mobile phone generally referred to as a “folding type” is taken as an example, and the first embodiment will be described with reference to the drawings.
<1-1. Configuration of mobile phone 100>
First, the configuration of a foldable mobile phone will be described.

FIG. 1 is a perspective view showing an appearance of a foldable mobile phone 100.
As shown in FIG. 1, the mobile phone 100 is configured such that the first casing 101 and the second casing 102 are connected via a connecting portion 103 so that both the casings 101 and 102 can be overlapped and folded. It is configured. As shown in FIG. 1, a state in which the housings are opened without being folded is referred to as an “open state”, and a state in which the housings are folded and closed, although not illustrated, is referred to as a “closed state”.

The first housing 101 is provided with a speaker 105 and a display unit 106 so as to be visually recognized, and a magnet 113b is built therein.
The speaker 105 converts an audio signal into a sound and emits the sound. For example, when making a call with another mobile phone, the speaker 105 emits a sound emitted by a communication partner or receives an incoming call to the mobile phone 100. Releasing a ringtone for notification.

The display unit 106 is a display device configured by an LCD (Liquid Crystal Display) or the like, and displays various information necessary for using the mobile phone 100.
The magnet 113b, together with a Hall IC (Integrated Circuit) 113a described later, constitutes an open / close detection unit 113 that detects the open / closed state of the first housing 101 and the second housing 102.
In addition, the second housing 102 is provided with a radio / TV receiving antenna 104, a microphone 107, an operation unit 108, and an earphone jack 112 so as to be visually recognized, and includes an FM transmission antenna 109, a CDMA (Code Division Multiple Access). A main antenna 110, a CDMA sub antenna 111, and a Hall IC 113a are incorporated.

The radio / TV antenna 104 is a whip antenna capable of receiving FM radio waves and TV broadcast waves.
The microphone 107 collects sound and converts it into an audio signal. For example, when making a call with another mobile phone, the microphone 107 collects sound emitted by the user of the mobile phone 100.
The operation unit 108 is an input device including a group of keys that can be pressed and printed with alphanumeric characters, kanji characters, and the like, and is used by the user to operate the mobile phone 100.

The earphone jack 112 is an attachment / detachment part for attaching a removable earphone provided as an external device.
The FM transmission antenna 109 is a transmission antenna that performs transmission in an arbitrary FM frequency band, and is an antenna for transmitting an electrical signal transmitted from the FM transmission unit 116 described later.

The CDMA main antenna 110 is an antenna that performs transmission / reception in the CDMA system, and performs diversity reception with the CDMA sub-antenna 111 during reception.
The CDMA sub-antenna 111 is an antenna that performs reception using the CDMA scheme, and performs diversity reception with the CDMA main antenna 110.
The Hall IC 113a is an IC that detects magnetism, and is arranged so that the magnetism of the magnet 113b can be detected when the first housing 101 and the second housing 102 are folded. The Hall IC 113a and the magnet 113b constitute an open / close detection unit 113, and the detection result is used for, for example, ON / OFF control of the backlight of the display unit 106.

Next, FIG. 2 and FIG. 3 show a cross-sectional view of the mobile phone 100 in the AA ′ plane of FIG.
FIG. 2 is a cross-sectional view taken along the line AA ′ in FIG. 1 and shows the opened state of the mobile phone 100.
FIG. 3 is a cross-sectional view taken along the line AA ′ in FIG. 1 and shows the closed state of the mobile phone 100.

As shown in FIG. 2, in the second housing 102, the FM transmission antenna 109 is disposed in the upper part near the outer wall of the second housing 102 and very close to the operation unit 108. On the other hand, the CDMA main antenna 110 and the CDMA sub antenna 111 are spaced apart from each other in the lower portion of the second housing 102.
The reason why the antennas 109 to 111 are arranged apart from each other in this manner is to suppress as much as possible interference between antennas that can act on each other.

The circuit board 120 is a board on which necessary components for the mobile phone 100 are mounted. The CDMA main antenna 110 and the CDMA sub antenna 111 are also mounted on the circuit board 120.
Here, in the cellular phone 100 in the open state as shown in FIG. 2, the first housing 101 is folded on the second housing 102 via the connecting portion 103, so that the closed state as shown in FIG. 3 is obtained. And transition.

As shown in FIG. 3, by closing the mobile phone 100, the first housing 101 and the second housing 102 overlap with each other, and the display unit 106 and the operation unit 108 come close to each other. In this state, the FM transmission antenna 109 is also very close to the display unit 106, so that the gain of the FM transmission antenna 109 is deteriorated.
That is, the display unit 106 includes an outer frame 106a. Since the outer frame 106a is made of a magnesium alloy, the display unit 106 has a characteristic of absorbing radio waves. Therefore, when the outer frame 106a is very close to the FM transmission antenna 109, radio waves radiated from the FM transmission antenna 109 may be absorbed. In such a case, the electric field from the FM transmission antenna 109 that can be received from the outside may be absorbed. The strength will decrease.

  Therefore, in the present embodiment, even when in the closed state, the transmission of the FM transmitting antenna 109 is performed so as to be received from the outside as well as possible within a range that does not exceed the upper limit value of the electric field strength determined by the state or the law. The output is adjusted based on the closed state. For example, the Radio Law in Japan stipulates that “the electric field intensity observed at a position 3 m away from the antenna is within 54 dBμ / m” for FM transmission at the FM frequency. Therefore, in this embodiment, the FM transmission antenna 109 has its transmission output adjusted so that an electric field strength of 49 dBμ / m can be obtained when observed at a position 3 m away so as not to exceed 54 dBμ / m in the closed state. Yes.

However, in this state, when the cellular phone 100 is in the open state and is no longer affected by the outer frame 106a of the display unit 106, the electric field strength of the FM transmitting antenna 109 when observed at a position 3 m away exceeds 49 dBμ / m. Further, it may exceed 54 dBμ / m.
Therefore, the cellular phone 100 is provided with an attenuation circuit for suppressing the transmission output of the FM transmission antenna 109. When the cellular phone 100 is in the closed state, the FM transmission antenna 109 and the attenuation circuit are disconnected and opened. In some cases, the FM transmitting antenna 109 and the attenuation circuit are connected to adjust the electric field strength of 49 dBμ / m from the outside in any state.

In this embodiment, it is assumed that the influence of the outer frame 106a of the display unit 106 is 11 dBμ / m, and the electric field strength changes by 11 dBμ / m with the transition between the closed state and the open state.
FIG. 4 is a functional block diagram showing the main part of the mobile phone 100.
As shown in FIG. 4, the cellular phone 100 includes a CDMA communication unit 114, a radio / TV receiving unit 115, an FM transmitting unit 116, an attenuation circuit 117, a storage unit 118, and a control unit 119 in addition to the components described above. It is equipped.

The CDMA communication unit 114 is a communication unit for telephone calls, and performs modulation of electric signals and demodulation of radio waves by the CDMA method.
The radio / TV receiver 115 demodulates FM radio waves and TV waves received by the radio / TV receiving antenna 104.
The FM transmitter 116 converts data into an electrical signal and modulates it into an FM wave. The data is, for example, music data stored in the storage unit 118, which will be described later, and performs modulation to transmit such data from the FM transmission antenna 109.

Although the specific configuration will be described later, the attenuation circuit 117 is disposed so as to be connectable to the FM transmission antenna 109, and is adjusted to attenuate the transmission output of the FM transmission antenna 109 by 11 dBμ / m.
The storage unit 118 is a memory and stores various data used by the mobile phone 100 based on user instructions. For example, music data or image data desired by the user can be stored.

The control unit 119 is a CPU (Central Processing Unit) and controls other components. In particular, an attenuation circuit switching unit 119a and an earphone wearing detection unit 119b are included.
The attenuation circuit switching unit 119a switches connection / disconnection between the attenuation circuit 117 and the FM transmission antenna 109 by switching application / non-application of a voltage to a connection unit between the attenuation circuit 117 and the FM transmission antenna 109.

In addition, the earphone attachment detection unit 119b detects the attachment of the earphone by detecting a potential difference generated at the terminal of the earphone jack 112 when the earphone is attached to the earphone jack 112.
<1-2. Configuration of Attenuation Circuit 117>
Here, an example of a specific configuration of the attenuation circuit 117 will be described.

FIG. 5 is a circuit diagram schematically showing the configuration of the attenuation circuit 117.
As shown in FIG. 5, the attenuation circuit 117 includes a capacitor 117a and resistors 117b and 117c, and is arranged so as to be connectable to the subsequent stage of the amplification amplifier 109a of the FM transmission antenna 109 via the switch 121.
The attenuation circuit 117a is adjusted so that the transmission output of the FM transmission antenna 109 is reduced by 11 dBμ / m.

When a voltage is applied to the switch 121 according to an instruction from the attenuation circuit switching unit 119a, the FM transmission antenna 109 and the attenuation circuit 117 are brought into conduction, and the transmission output of the FM transmission antenna 109 is reduced by 11 dBμ / m.
<2. Operation>
Next, focusing on the attenuation circuit switching unit 119a, the operation of the mobile phone 100 will be described.

FIG. 6 is a flowchart showing the operation of the mobile phone 100.
When the mobile phone 100 drives the FM transmitter 116, the mobile phone 100 executes FM transmission control for switching connection / disconnection between the FM transmission antenna 109 and the attenuation circuit 117 according to the open / close state of the mobile phone 100.
First, the user operates the operation unit 108, drives the FM transmission unit 116, and activates a mode for transmitting data stored in the storage unit 118 to the outside, thereby starting FM transmission control.

Next, the control unit 119 determines whether or not the mobile phone 100 is in a closed state based on the detection result of the open / close detection unit 113 (S100). That is, if the Hall IC 113a detects the magnetic force of the magnet 113b, it is determined that the Hall IC 113a is in the closed state, and if it is not detected, it is determined that the Hall IC 113a is in the open state.
When it is determined that the control unit 119 is in the “closed state” (S100: YES), the attenuation circuit switching unit 119a does not apply a voltage, and the FM transmission antenna 109 and the attenuation circuit 117 are kept in a disconnected state (S101). ). The transmission output of the FM transmission antenna 109 is 49 dBμ / m as adjusted.

  On the other hand, when the control unit 119 determines that it is in the “open state” (S100: NO), the attenuation circuit switching unit 119a applies a voltage to the switch 121, thereby connecting the FM transmission antenna 109 and the attenuation circuit 117. (S102). The transmission output of the FM transmitting antenna 109 is expressed by the equation “49 dBμ / m + (change in electrolytic intensity due to opening from the closed state: 11 dBμ / m) − (attenuation amount by the attenuation circuit 117: 11 dBμ / m) = 49 dBμ / m , 49 dBμ / m is maintained.

By performing FM transmission control in this way, when transmitting data via the FM transmission antenna 109, the cellular phone 100 is within the upper limit value range of electric field strength determined by the state in both the open state and the closed state. It can be designed to obtain as high electrolytic strength as possible.
<Second Embodiment>
<1. Difference from First Embodiment>
Next, the mobile phone 100 according to the second embodiment of the present invention will be described.

In the second embodiment, the operation of the first embodiment is changed. The same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
In the first embodiment, attention is paid to a change in electric field strength that can be received from the outside due to opening and closing of the first housing 101 and the second housing 102, but the second embodiment is provided as an accessory of the mobile phone 100. We focused on the change in electric field strength due to the attachment / detachment of removable external devices.

FIG. 7 is a perspective view showing a state where the earphone 200 is attached to the earphone jack 112 of the mobile phone 100.
The earphone 200 is an external device provided as a genuine accessory of the mobile phone 100.
Here, when the earphone 200 is attached to the earphone jack 112, the metal wire in the cable 200a of the earphone 200 may be propagated by receiving radio waves radiated from the FM transmitting antenna 109, and may function as an external antenna. In this case, the electric field strength from the FM transmitting antenna 109 that can be received from the outside becomes stronger when the earphone 200 is worn than when the earphone 200 is detached.

  Therefore, in this embodiment, even when the earphone is disconnected, the FM transmitting antenna 109 can receive the signal from the outside as well as possible within a range that does not exceed the upper limit value of the electrolytic strength determined by the state or the law. The transmission output of is adjusted based on the earphone disconnected state. Therefore, in this embodiment, the FM transmission antenna 109 has its transmission output adjusted so as to obtain an electric field strength of 49 dBμ / m when observed at a position 3 m away so as not to exceed 54 dBμ / m in the earphone disconnected state. Yes.

However, in this state, when the mobile phone 100 is in an earphone-mounted state and the cable 200a functions as an external antenna, the electric field strength of the FM transmitting antenna 109 when observed at a position 3 m away exceeds 49 dBμ / m, and further 54 dBμ / m may be exceeded.
Therefore, the cellular phone 100 is provided with an attenuation circuit for suppressing the transmission output of the FM transmission antenna 109. When the mobile phone 100 is in the earphone detached state, the FM transmission antenna 109 and the attenuation circuit are disconnected and the earphone is attached. In this case, the FM transmitting antenna 109 and the attenuation circuit are connected so that an electric field strength of 49 dBμ / m is obtained from the outside in any state.

In the present embodiment, it is assumed that the influence of the earphone 200 is 11 dBμ / m, and the electric field strength changes by 11 dBμ / m with the transition between the earphone detached state and the earphone wearing state.
<2. Operation>
FIG. 7 is a flowchart showing the operation of the mobile phone 100.

When the FM transmitter 116 is driven, the mobile phone 100 executes FM transmission control for switching connection / disconnection between the FM transmission antenna 109 and the attenuation circuit 117 according to the attachment / detachment state of the earphone 200.
First, the user operates the operation unit 108, drives the FM transmission unit 116, and starts a mode for transmitting data stored in the storage unit 118 to the outside, thereby starting FM transmission control.

  Next, the earphone attachment detection unit 119b determines whether the earphone 200 is attached based on the potential difference generated at the terminal of the earphone jack 112 when the earphone 200 is attached (S200). That is, if there is a potential difference at the terminal of the earphone jack 112, it is determined that the earphone is attached, and if there is no potential difference, it is determined that the earphone is disconnected.

When the earphone wearing detection unit 119b determines that the “earphone leaving state” is determined (S200: NO), the attenuation circuit switching unit 119a does not apply a voltage, and the FM transmission antenna 109 and the attenuation circuit 117 are disconnected. Keep (S201). The transmission output of the FM transmission antenna 109 is 49 dBμ / m as adjusted.
On the other hand, when the earphone wearing detection unit 119b determines that the “earphone wearing state” is set (S200: YES), the attenuation circuit switching unit 119a applies a voltage to the switch 121, so that the FM transmission antenna 109 and the attenuation circuit 117 Are connected (S202). The transmission output of the FM transmission antenna 109 is expressed by the equation “49 dBμ / m + (change in electric field strength due to the earphone being detached from the earphone wearing state: 11 dBμ / m) − (attenuation amount by the attenuation circuit 117: 11 dBμ / m) = 49 dBμ / m ”maintains 49 dBμ / m.

By performing FM transmission control in this way, when data is transmitted via the FM transmission antenna 109, the upper limit value range of the electric field strength determined by the state when the mobile phone 100 is in both the earphone wearing state and the earphone detached state. It can be designed to obtain as high an electric field strength as possible.
<Supplement>
As described above, the mobile phone according to the present invention has been described based on the first and second embodiments, but the present invention is not limited to these. Hereinafter, the modification is demonstrated.
(1) In the first embodiment, it has been described that the influence of the outer frame 106a of the display unit 106 is 11 dBμ / m, and the change in the electric field strength is 11 dBμ / m with the transition between the closed state and the open state. However, the present invention is not limited to this. That is, the value of 11 dBμ / m is merely an example of a value based on the observed value in the present embodiment, and actually depends on the size of the mobile phone 100, the arrangement position of each component, and the like.

Accordingly, the attenuation amount of the attenuation circuit 117 is not limited to 11 dBμ / m, but depends on the degree of influence exerted by the outer frame 106a of the display unit 106 described above.
(2) In the second embodiment, it has been described that the influence of the cable 200a of the earphone 200 is 11 dBμ / m, and the change in the electric field strength is 11 dBμ / m with the transition between the earphone detached state and the earphone wearing state. However, the present invention is not limited to this. That is, the value of 11 dBμ / m is merely an example of a value based on the observed value in the present embodiment, and actually depends on the length of the cable 200, the arrangement position of each component, and the like.

Along with this, the attenuation amount of the attenuation circuit 117 is not limited to 11 dBμ / m, but depends on the degree of influence of the cable 200a of the earphone 200 described above.
(3) In the first and second embodiments, an example in which a transistor is used as the switch 121 for switching connection / disconnection with the FM transmission antenna 109 attenuation circuit 117 has been described. However, the present invention is not limited to this. For example, it may be a diode that functions as a switch according to ON / OFF of the voltage.
(4) In the second embodiment, an example in which the earphone 200 is mounted as an external device has been described. However, the present invention is not limited to this, and various modifications are possible. For example, a charger may be attached and detached as an external device. In this case, a metal wire in the charger cable affects the electric field strength of the built-in antenna received from the outside.
(5) In the first and second embodiments, as a mobile phone that can be deformed between two forms, a foldable mobile phone that can be opened and closed by folding two housings has been described as an example. However, the present invention is not limited to this. However, various modifications are possible.

That is, in the first embodiment, it may be deformable, and may be a so-called “sliding” mobile phone that can be opened and closed by sliding two housings in parallel with each other, or via a rotating shaft. The mobile phone may be opened and closed by rotating the two housings relative to each other.
In the second embodiment, an external device may be detachable, and a so-called “straight type” mobile phone including a single housing may be used.
(6) Further, in a mobile phone that is deformed in three forms, if the intensity of the radio wave from the built-in antenna that can be received from the outside changes in each form, this is suitable on the basis of when the electric field strength is minimum. The transmission output may be adjusted so as to obtain the output amount, and an attenuation circuit having an attenuation amount corresponding to each of the other two forms may be selectively connected according to each form.

In addition, by selectively applying a plurality of attenuation circuits corresponding to the respective attenuation amounts in this way, the present invention can be applied to a mobile phone in which the intensity of radio waves changes not only in three forms but also in other forms. It is.
Similarly, even if a mobile phone can have a plurality of external devices detachable, if the strength of the radio wave changes with the attachment / detachment of each external device, when the electric field strength is minimal (install any external device). The transmission output is adjusted so that it becomes a suitable output amount on the basis of when the external device is not used), and a plurality of attenuation circuits corresponding to the attenuation amounts corresponding to the respective mounted state of each external device are selectively connected. It may be.

  Furthermore, you may combine the selection of the attenuation circuit according to each of the several form mentioned above, and the selection of the attenuation circuit according to each of a some external apparatus.

1 is a perspective view showing an appearance of a mobile phone 100 according to a first embodiment of the present invention. 4 is a cross-sectional view showing an open state of the mobile phone 100. FIG. 4 is a cross-sectional view showing a closed state of the mobile phone 100. FIG. 4 is a functional block diagram showing a main part of the mobile phone 100. FIG. 3 is a circuit diagram showing a configuration of an attenuation circuit 117. FIG. 3 is a flowchart showing the operation of the mobile phone 100 in the first embodiment. 1 is a perspective view showing an appearance when an earphone 200 is attached to a mobile phone 100. FIG. 6 is a flowchart illustrating an operation of the mobile phone 100 according to the second embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Mobile phone 101 1st housing | casing 102 2nd housing | casing 103 Connection part 104 Radio / TV antenna 105 Speaker 106 Display part 107 Microphone 108 Operation part 109 FM transmission antenna 110 CDMA main antenna 111 CDMA subantenna 112 Earphone jack 113 Opening / closing detection part 114 CDMA communication unit 115 Radio / TV reception unit 116 FM transmission unit 117 Attenuation circuit 118 Storage unit 119 Control unit

Claims (4)

A built-in antenna for wireless transmission,
An attenuation unit for attenuating the transmission output of the built-in antenna by a predetermined amount;
An attachment / detachment part for attaching / detaching an external device including a metal member;
An attachment / detachment detection unit that detects the attachment state of the attachment / detachment unit and the external device, and when the attachment / detachment detection unit detects the attachment state, the built-in antenna and the attenuation circuit are connected, and the attachment / detachment detection unit A mobile phone comprising: a switching unit that disconnects the built-in antenna and the attenuation circuit when not detected. When said detachable portion and the external device is in a mounted state, wherein the metal member of claim 1, wherein the connecting the detachable part the internal antenna equipped circuit board and electrically via Mobile phone. The external device is an earphone with a cable, cellular phone according to claim 1, characterized in that it contains the metal member to the cable. The built-in antenna is an FM (Frequency Modulation) transmission antenna provided separately from the telephone antenna for the mobile phone,
The mobile phone includes a storage unit for storing data;
The mobile phone according to claim 1, further comprising: an FM transmitter that transmits data stored in the storage unit via the built-in antenna.

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