JP2003243917A - Mobile communication terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce interference between two wireless circuits, in particular, interference between antennas so as to prevent wireless characteristics caused by the interference from being deteriorated. <P>SOLUTION: A feeding point P1 to an antenna 11 is formed on a board 31 contained in an upper case 21. A feeding point P2 to an antenna 13 is formed on a board 32 contained in a lower case 22. Then the boards 31, 32 are contained respectively in the upper case 21 and the lower case 22 so that the feeding points P1, P2 are located at positions at which the feeding points P1, P2 are not confronted with each other in a folded state. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication terminal such as a mobile phone or a PHS (Personal Handy Phone), and more particularly to a mobile communication terminal capable of transmitting and receiving by two radios at the same time.

[0002]

2. Description of the Related Art Conventionally, mobile communication terminals such as mobile phone terminals usually belong to one communication system. Therefore, only one radio is provided.

There are also dual-mode terminals with two radios to accommodate two communication systems, but these radios are only used selectively.

As described above, conventionally, a plurality of wireless devices have not simultaneously transmitted and received at the same mobile communication terminal.

[0005]

By the way, in recent years, two radios are provided, and the line established between the base station and the first radio is connected to another communication terminal via the second radio. Development of a communication system that has made it possible is in progress. As an example of such a second wireless device, Bluetooth
There is a radio that is compatible with the system.

[0006] The Bluetooth system is a wireless communication system that complies with the short-range wireless communication standard. Blu
The etoth system uses radio waves in the 2.45 GHz band to realize wireless communication of approximately 10 m. Bluet
In the ooth system, up to eight terminal devices form a network called a piconet. One of the terminal devices in the piconet functions as a master device (master), and the other devices function as slave devices (slave). Terminal devices in the piconet are authenticated by a personal identification number called a PIN (Personal Identification Number) code.

[0007] In a terminal equipped with such a wireless device compatible with the Bluetooth system as a second wireless device, separately from the first wireless device compatible with a mobile communication system such as PDC, these two wireless devices are simultaneously provided. It will be sent and received. As a result, there is a risk of interference between wireless devices, which may cause deterioration of wireless characteristics.

As a specific example, in the case of a terminal device equipped with a PDC radio and a Bluetooth system radio, a transmission signal of the Bluetooth system interferes with an antenna and a receiving circuit of the PDC, and This will affect the received signal and cause a problem that the error rate deteriorates.

Interference between radios will be described below with reference to the drawings.

FIG. 10 is a schematic view of a printed circuit board on which two wireless devices are mounted.

As shown in FIG. 10, the printed circuit board 101
The first wireless circuit unit 12 is mounted on the. An antenna 11 is connected to the first wireless circuit unit 12. Antenna 11
The first wireless circuit unit 12 constitutes a first wireless device. In addition, the printed circuit board 101 has a second wireless circuit unit 1
4 has been implemented. The antenna 13 is connected to the second wireless circuit unit 14. The antenna 13 and the second wireless circuit unit 14 form a second wireless device.

The interference problem that occurs between the first radio device and the second radio device in such a configuration can be roughly classified into the following two types.

The first interference problem is spatial interference. FIG. 11A is a diagram schematically showing the mechanism of spatial interference. Spatial interference is a phenomenon in which a radio wave radiated from an antenna of one wireless device goes around to the other antenna and causes interference.

That is, as shown in FIG. 11A, the radio wave radiated from the antenna 11 of the first radio device to the space may wrap around the antenna 13 of the second radio device and interfere with it. Similarly, the radio wave radiated to the space from the antenna 13 of the second wireless device may wrap around the antenna 11 of the first wireless device and interfere with it.

The second interference problem is conducted interference. FIG. 11B is a diagram schematically showing the mechanism of conductive interference. Conducted interference is a phenomenon in which, on a printed circuit board on which two wireless devices are mounted, a current generated in one wireless device flows into the other wireless device via a wiring pattern and interferes with the other wireless device.

That is, as shown in FIG. 11B, the current generated in the wiring pattern on the printed circuit board 101 when the input end of the first wireless device is excited is conducted to the second wireless device and affects the second wireless device. Sometimes. Similarly, the current generated in the wiring pattern on the printed circuit board 101 when the input terminal of the second wireless device is excited may be conducted to the first wireless device and affect the first wireless device.

Next, the deterioration of the radio characteristics caused by the interference between the radios will be described.

First, as a first example of radio characteristic deterioration due to interference between radio devices, radio characteristic deterioration due to circuit saturation will be described.

The first radio circuit 101 includes an RF amplifier for amplifying the received RF signal.

FIG. 12 is a diagram showing general input / output characteristics (saturation characteristics) of the RF amplifier. In FIG. 12, the horizontal axis is the input level and the vertical axis is the output level.

In the region shown as the "linear region" in FIG. 12, that is, in the region until the input level reaches the "saturated input level", the input / output characteristic of the RF amplifier shows a linear characteristic.
However, in the "saturation region" where the input level exceeds the level shown as "saturation input level" in FIG. 12, the input / output characteristics of the RF amplifier deviate from the linear characteristics. In this saturation region,
Distortion occurs in the output of the amplifier, making it impossible to store necessary information for both the amplitude component and the phase component of the input signal. As a result, an error occurs in the demodulated signal from the amplifier output. That is, when the input signal to the RF amplifier exceeds the “saturation input level” and the RF amplifier operates in the saturation region, the radio characteristics are deteriorated.

Next, the manner in which the deterioration of the wireless characteristics due to the saturation of the RF amplifier is caused by the interference between the wireless devices will be described. In addition, here, the antenna 1 of the second radio device is used.
The signal transmitted from 3 is the RF of the first wireless circuit unit 101.
An example of deterioration of wireless characteristics caused when the amplifier interferes will be described.

When the signal transmitted from the antenna 13 of the second wireless device interferes with the antenna 11 of the first wireless device by spatial interference or conductive interference, the antenna 1
The signal transmitted from 3 is input to the first wireless circuit unit 12 via the antenna 11.

The signal input to the first radio circuit section 12 is
It is input to the duplexer included in the first wireless circuit unit 12. Since the signal input to the first wireless circuit unit 12 due to interference is outside the reception band of the first wireless circuit unit 12, the signal is attenuated in the duplexer. However, the signal is not completely attenuated, and the signal that is not completely attenuated is directly input to the RF amplifier. When the signal level interfering with the antenna 11 is large and the level after being attenuated by the duplexer exceeds the saturation input level of the RF amplifier, the RF amplifier operates in the saturation region. At this time, even if the antenna 11 receives a desired signal,
Since the RF amplifier operates in the saturation region, the amplitude and phase components of the desired signal are not amplified properly. Therefore, RF
The output signal of the amplifier is distorted.

As described above, when the interference between the two antennas is large, the RF amplifier is saturated and the radio characteristics are deteriorated.

The above is the first example in which the wireless characteristics are deteriorated due to the interference between the wireless devices.

Next, as a second example of radio characteristic deterioration, sensitivity deterioration due to an image signal will be described.

The first radio circuit section 12 has a mixer for down converting the frequency of the received signal.

FIG. 13 is a diagram showing the frequency relationship between the input and output signals of the mixer. The frequency f _{RF1 in} FIG. 13 is the reception frequency of the first radio, which is the desired wave. Frequency f
_LO1 is the local oscillator signal frequency of the first radio. Frequency f
_IF1 is the reception intermediate frequency of the first wireless device.

The mixer receives the signal of the reception frequency f _{RF1 and} the signal of the local oscillation signal frequency f _LO1 and generates an intermediate frequency signal having a frequency f _IF1 obtained by the following equation.

F _IF1 = f _LO1 −f _{RF1 In} this case, f _LO1 > f _RF1 .

As described above, the mixer outputs a signal having a frequency corresponding to the frequency difference between the input signal and the local oscillation signal. Therefore, when an undesired signal having a component of frequency f _IM for which the following relation holds between the reception intermediate frequency f _IF1 and the local oscillation signal frequency f _LO1 , is input, the mixer output outputs the component of frequency f _IF1 . It becomes a signal to have.

F _IM = f _LO1 + f _IF1 A signal having a component of frequency f _{IF 1} obtained by a mixer based on an undesired signal having a component of frequency f _IM is a desired signal regardless of being an unnecessary signal. Since it has the same frequency as, it will not be removed by subsequent filtering or the like. Therefore, the above signal reaches the demodulator and acts as noise during demodulation, causing an error. That is, a signal of frequency f _IM causes deterioration of wireless characteristics, and such a signal is called an image signal.

Next, the manner in which the deterioration of the wireless characteristic due to the image signal is caused by the interference between the wireless circuits will be described. Here, an example in which a signal transmitted from the antenna 13 interferes with the antenna 11 and an image signal is mixed in the input to the wireless circuit unit 12 will be described.

When the signal transmitted from the antenna 13 interferes with the antenna 11 by spatial interference or conductive interference, the signal transmitted from the antenna 13 becomes
It is input to the first wireless circuit unit 12 via the antenna 11.

The signal input to the first radio circuit section 12 is
It is input to the duplexer included in the first wireless circuit unit 12. Since the signal input to the first wireless circuit unit 12 due to interference is outside the reception band of the first wireless circuit unit 12, the signal is attenuated in the duplexer. However, the signal is not completely attenuated, and the signal that is not completely attenuated is directly input to the RF amplifier. Then, this signal is amplified by the RF amplifier and then input to the mixer for down conversion.

Here, the radio frequency band f _RF2 used by the second radio is the reception intermediate frequency f _IF1 used by the first radio,
When the following equation is satisfied between the local oscillation signal f _LO1 used by the first radio and the signal of the frequency band f _RF2 , an image signal is obtained.

F _RF2 = f _LO1 + f _IF1 Therefore, as described above, a noise component is generated from the interference signal from the second radio device, which causes an error during demodulation.

As described above, when the interference between the two antennas is large, a noise component due to the image signal is generated in the mixer output, and the radio characteristics are deteriorated.

The above is the second example in which radio characteristics are deteriorated due to interference between radio devices.

Such spatial interference and conductive interference both have strong distance dependence, and become more prominent as the distance between the interferer and the interfered object decreases. For this reason, in devices that require miniaturization, such as mobile communication terminals these days,
It is expected to become a serious problem.

The present invention has been made in view of the above points, and it is intended to reduce the interference between two radio circuits, especially the interference between antennas, and prevent the deterioration of radio characteristics due to this. The purpose is to provide a communication terminal.

[0043]

In order to achieve the above object, a first aspect of the present invention provides a first feeding point from a first wireless circuit section to a first antenna and a second wireless circuit section to a second antenna. The second feeding point to the first housing and the second housing having the folding structure are individually positioned so as not to face each other in the folded state.

By taking such means, the first casing and the second casing are brought close to each other in the folded state, but in the folded state, the first feeding point and the second feeding point are different from each other. The first feeding point and the second feeding point
It is separated from the feeding point. Therefore, spatial interference between the vicinity of the first feeding point and the vicinity of the second feeding point is suppressed.

In order to achieve the above object, a second aspect of the present invention transmits a ground pattern to which a first antenna is connected and a ground pattern to which a second antenna is connected from the first antenna and the second antenna. It was decided to connect via a high frequency blocking means that blocks the frequency band of the signal to be passed and blocks the frequency band lower than that.

By taking such measures, the two ground patterns are electrically connected and form a common ground line, but with respect to the frequency band of the signals transmitted from the first antenna and the second antenna. Are separated. Therefore, signals in the radio frequency band are prevented from being transmitted via the ground pattern, and conducted interference is suppressed.

In order to achieve the above-mentioned object, a third aspect of the present invention arranges a first feeding point from the first radio circuit section to the first antenna in a null direction in a radiation characteristic of the second antenna,
Further, the second feeding point from the second wireless circuit section to the second antenna is arranged in the null direction in the radiation characteristic of the first antenna.

By taking such measures, the first
The power radiated from the antenna toward the vicinity of the second feeding point and the power radiated from the second antenna toward the vicinity of the first feeding point are suppressed to be small. Therefore, spatial interference between the vicinity of the first feeding point and the vicinity of the second feeding point is suppressed.

[0049]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

First, prior to describing a specific embodiment relating to the gist of the present invention, a communication system in which the mobile communication terminal of the present embodiment is used and a wireless device included in the mobile communication terminal of the present embodiment. The configuration will be described.

FIG. 1 is a diagram showing the configuration of a communication system using the mobile communication terminal of this embodiment.

The communication system shown in FIG. 1 includes a wired communication terminal 1, a public network 2, a wireless network 3, a base station 4, a mobile communication terminal 5, a base unit 6 and mobile communication terminals 7, 8 and 9. I'm out.

The mobile communication terminal 5 is, for example, a mobile phone or P
A communication terminal in which the present invention is applied to an HS or the like. The mobile communication terminal 5 includes two radio devices, a first radio device and a second radio device. The first wireless device performs wireless communication with the base station 4 using radio waves in a predetermined wireless frequency band. The second wireless device performs wireless communication with the mobile communication terminals 7 to 9 and the base device 6 using radio waves in a wireless frequency band different from that of the first wireless device. The first radio and the second radio can operate simultaneously.

As described above, the mobile communication terminal 5 is connected to the base station 4
The communication with the mobile communication terminals 7 to 9 and the communication with the master device 6 can be simultaneously performed. From this, for example, in the mobile communication terminal 5, a communication link is established with the communication terminal 1 via the public network 2, the wireless network 3, and the base station 4, and the mobile communication terminals 7 to 9 and the parent are connected. Establishing a communication link with the mobile device 6 and connecting these two communication links to each other to enable communication between the communication terminal 1 and the mobile communication terminals 7-9 and the master device 6. You can

FIG. 2A is a block diagram showing the configuration of the first wireless device. FIG. 2B is a block diagram showing the configuration of the second wireless device.

The first radio device is composed of an antenna 11 and a radio circuit section 12. In addition, in the wireless circuit unit 12,
Duplexer 12a, RF amplifier 12b, RF filter 12c, mixer 12d, IF filter 12e, IF amplifier 12f, demodulator 12g, modulator 12h, IF amplifier 1
2i, IF filter 12j, mixer 12k, RF filter 12m, RF amplifier 12n, local oscillator signal generation unit 12p,
A baseband processing unit 12r is provided.

The signal received at the antenna 11 is
It is input to the duplexer 12a. Duplexer 12a
Removes signal components outside the reception radio frequency band from the signal given from the antenna 11. The duplexer 12a is
The extracted reception radio frequency band signal is input to the RF amplifier 12b. The RF amplifier 12b amplifies the input signal to a desired level and then inputs it to the RF filter 12c.
The RF filter 12c removes a signal component outside the reception radio frequency band from the input signal, and inputs the extracted signal in the reception radio frequency band to the mixer 12d. The mixer 12d is
The received signal is converted to the reception intermediate frequency band by mixing the input signal and the local oscillation signal. The local signal is generated by the local signal generator 12p. The mixer 12d inputs the frequency-converted signal to the IF filter 12e. The IF filter 12e removes the signal component outside the reception intermediate frequency band of the input signal. The IF filter 12e inputs the extracted signal in the reception intermediate frequency band to the IF amplifier 12f. The IF amplifier 12f amplifies the input signal to a desired level and then inputs it to the demodulator 12g. Demodulator 1
2g demodulates the input signal and reproduces the baseband signal. The demodulator 12g inputs the reproduced baseband signal to the baseband processing unit 12r. The baseband processing unit 12r performs known baseband processing on the input baseband signal.

On the other hand, the baseband processor 12r generates a baseband signal by a predetermined baseband process. The baseband processing unit 12r inputs the generated baseband signal to the modulator 12h. The modulator 12h modulates the input baseband signal and converts it into a signal in the transmission intermediate frequency band. The modulator 12h inputs the modulated signal to the IF amplifier 12i. The IF amplifier 12i amplifies the input signal to a desired level and then inputs it to the IF filter 12j. The IF filter 12j removes a signal component outside the transmission intermediate frequency band of the input signal. The IF filter 12j inputs the extracted signal in the transmission intermediate frequency band to the mixer 12k. The mixer 12k mixes the input signal and the local oscillation signal, and converts the transmission signal into a transmission radio frequency band. The local oscillator signal is generated by the local oscillator signal generator 12p. The mixer 12k inputs the frequency-converted signal to the RF filter 12m. R
The F filter 12m removes a signal component outside the transmission radio frequency band of the input signal. The RF filter 12m is
The signal of the extracted transmission radio frequency band is input to the RF amplifier 12n. The RF amplifier 12n amplifies the input signal to a desired level and then inputs the amplified signal to the duplexer 12a. The duplexer 12a removes the signal component outside the transmission radio frequency band of the input signal. Duplexer 12
a is the antenna 11 that receives the extracted signal in the transmission radio frequency band.
Supply to. The antenna 11 radiates the supplied signal to space.

The second radio has the same structure.
That is, the second wireless device includes the antenna 13 and the wireless circuit unit 1.
It is composed of 4 and. The wireless circuit unit 14 includes a duplexer 14a, an RF amplifier 14b, an RF filter 14c,
Mixer 14d, IF filter 14e, IF amplifier 14
f, demodulator 14g, modulator 14h, IF amplifier 12i,
IF filter 14j, mixer 14k, RF filter 14
m, an RF amplifier 14n, a local oscillator signal generator 14p, and a baseband processor 14r. In addition, this second
The transmission / reception operation of the wireless device is the same as that of the first wireless device, and thus the description thereof will be omitted.

The present invention is intended to prevent interference between radios in the case where such two radio circuits are provided, and some specific configurations will be described below. The form will be described.

(First Embodiment) FIGS. 3 to 5 are diagrams showing a configuration of a mobile communication terminal 5 in the present embodiment. 3 to 5, the same parts as those in FIG. 2 are designated by the same reference numerals.

The mobile communication terminal 5 has a folding structure. FIG. 3 shows the folded state viewed from two directions. FIG. 4 shows the open state as shown in FIG.
It shows the situation seen from the same direction as. FIG. 5 shows a perspective view of the open state.

As shown in FIGS. 1 to 5, the mobile communication terminal 5 has a structure in which an upper casing 21 and a lower casing 22 are rotatably connected by a hinge portion 23. Although not shown, the upper housing 21 is provided with, for example, a speaker and a display for receiving a voice. Although not shown, the lower housing 22 is provided with a microphone and a keypad for transmission.

A substrate 31 is housed in the upper housing 21. The wireless circuit unit 12 is mounted on the substrate 31. The mounting position of the wireless circuit unit 12 on the board 31 is shown in FIG.
As shown in (a), the position is close to the upper right corner on the mounting surface. The wireless circuit unit 12 is provided on the substrate 3
1 through the feeding pattern 41 formed on the antenna 1.
1 is connected. In FIG. 6A, the point indicated by reference numeral P1 is the feeding point to the antenna 11.
The feeding point P1 is also located near the corner where the wireless circuit section 12 is located. A monopole antenna is used as the antenna 11.

A substrate 32 is housed in the lower housing 22. The wireless circuit unit 14 is mounted on the substrate 32. The mounting position of the wireless circuit unit 14 on the board 32 is shown in FIG.
As shown in (b), it is located near the upper left corner of the mounting surface. The wireless circuit unit 14 is provided on the substrate 3
Antenna 1 via a feeding pattern 42 formed on
3 is connected. In FIG. 6B, a point indicated by reference numeral P2 is a feeding point to the antenna 13.
The feeding point P2 is also located near the corner where the wireless circuit section 14 is located. A monopole antenna is used as the antenna 13.

The board 31 and the board 32 are in an folded state so that the opposite surface of the mounting surface of the wireless circuit portion 12 and the opposite surface of the mounting surface of the wireless circuit portion 14 face each other in the folded state. Each of them is housed in the body 22. The board 31 is housed in the upper housing 21 in such a direction that the corners where the wireless circuit section 12 is close to are close to the end opposite to the side where the hinge 23 is provided. The substrate 32 is housed in the lower housing 22 in such an orientation that the corners where the wireless circuit unit 14 is close to are close to the end on the side where the hinge 23 is provided.

Thus, the feeding point P1 and the feeding point P2 do not face each other even in the folded state. Further, the feeding point P1 and the feeding point P2 are located with the substrate 31 and the substrate 32 sandwiched therebetween in the folded state.

As a result, the feeding point P1 and the feeding point P2 are sufficiently separated from each other even in the folded state. The amount of interference between antennas has a strong distance dependency, and decreases exponentially as the distance between objects increases. Therefore, the amount of interference between the feeding point P1 and the feeding point P2 in the folded state is suppressed.

Further, as described above, the feeding point P1 and the feeding point P2 are
Is sufficiently separated from the power feeding point P1.
11, the wireless circuit unit 12 and the power feeding pattern 41 disposed near the antenna 13, the antenna 13, the wireless circuit unit 14 and the power feeding pattern 42 disposed near the power feeding point P2.
Also do not face each other and are sufficiently separated.

By these, the first state in the folded state
Spatial interference between the radio and the second radio is sufficiently suppressed.

As described above, in the situation where the first radio device and the second radio device simultaneously communicate, the mobile communication terminal 5
Plays a role of relaying communication between other terminals. Therefore, in this situation, the mobile communication terminal 5 is convenient to use in the folded state. In the present embodiment, as described above, spatial interference in the folded state is sufficiently suppressed,
It is possible to satisfactorily perform communication in the above situation.

In the open state, the upper casing 21 and the lower casing 22 are separated from each other, and the first radio device is located near the end of the upper casing 21 opposite to the hinge portion 23. Since the first wireless device and the second wireless device are located sufficiently apart from each other, they are sufficiently separated from each other. Therefore, the spatial interference in the open state is sufficiently suppressed. Therefore, even when the communication is performed in the open state in the above situation, the communication can be favorably performed.

FIG. 7 is a diagram showing radiation characteristics of the antenna 11 and the antenna 13. FIG. 7A shows an open state and FIG. 7B shows a folded state. In FIG. 7, the same parts as those in FIGS. 2 to 6 are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 7, the radiation characteristics of the antenna 11 and the antenna 13 show the pattern of the broken line with reference numeral 51. The feeding points P1 and P2 are both located in the null direction in the radiation characteristic 51.
That is, the feeding point P1 is located in the null direction in the radiation characteristic of the antenna 13. The feeding point P2 is located in the null direction of the radiation characteristic of the antenna 11.

Furthermore, the antenna 11, the radio circuit section 12, and the feeding pattern 41 arranged near the feeding point P1.
Is also located in the null direction in the radiation characteristic of the antenna 13. Antenna 1 arranged near the feeding point P2
3, the wireless circuit unit 14, and the feeding pattern 42 are also located in the null direction in the radiation characteristic of the antenna 11.

The above positional relationship is shown in FIG. 7 (a) and FIG.
As is clear from (b), there is no change in either the open state or the folded state.

Thus, in both the open state and the folded state, the feeding point P from the antenna 13 is reached.
1, the electric power radiated toward the antenna 11, the wireless circuit unit 12, and the feeding pattern 41 is relatively small. In addition, from the antenna 11 to the feeding point P2, the antenna 13, the wireless circuit unit 1
4 and the power supply pattern 42 are radiated with relatively little power. Therefore, the spatial interference between the first wireless device and the second wireless device is suppressed.

FIG. 8 shows the mobile communication terminal 5 according to this embodiment.
It is a figure which shows the electric constitution of. In FIG. 7, the same parts as those in FIGS. 2 to 7 are designated by the same reference numerals, and detailed description thereof will be omitted.

In FIG. 8, reference numerals 61 and 62 are used.
Is a wireless circuit unit 12, 1 mounted on the substrates 31, 32.
4 shows a circuit portion including 4. The circuit portions 61 and 62 are connected to each other via a cable 71 that connects the substrates 31 and 32.

Ground patterns 63 and 64 are formed on the substrates 31 and 32. These ground patterns 63 and 64 are also connected to each other via the cable 71. The ground pattern 64 is grounded. Antennas 11 and 13 and circuit parts 61 and 6
2 is grounded by being connected to the ground patterns 63 and 64.

A coil 72 is inserted in the line connecting the ground patterns 63 and 64 in the cable 71. The coil 72 has a characteristic of blocking a signal in the radio frequency band handled by the radio circuit units 12 and 14 from passing therethrough and passing a signal of a frequency lower than that.

Thus, the ground patterns 63, 64
The signal in the radio frequency band that has flowed to the coil is blocked by the coil 72 and does not flow to the other ground pattern. That is, the ground pattern 63 and the ground pattern 6
4 is separated from the radio frequency band. As a result,
Conducted interference between the first and second radios is suppressed. It should be noted that, for a high frequency signal such as a radio frequency band, there is no problem even if the ground patterns 63 and 64 themselves act as grounds and are separated from each other.

As described above, according to the present embodiment, the interference between the first radio device and the second radio device is suppressed by the following three means.

(1) The feeding point P1 to the antenna 11 is formed on the substrate 31 housed in the upper casing 21. The board 3 in which the feeding point P2 to the antenna 13 is housed in the lower housing 22
Form on 2. Then, the boards 31 and 32 are arranged in the upper housing 21 and the lower housing 22 so that the feeding points P1 and P2 are located at positions not facing each other in the folded state.

(2) The feeding point P2 to the antenna 13 is located in the null direction of the antenna 11. In addition, the antenna 13
The feed point P1 to the antenna 11 is located in the null direction of.

(3) Ground pattern 63 on the substrate 31
And the ground pattern 64 of the substrate 32 are connected via a coil 72 having a characteristic of blocking the passage of signals in the radio frequency band.

Then, each of these means can suppress the interference between the first radio device and the second radio device. As a result, it is possible to perform good communication by operating both the first wireless device and the second wireless device at the same time.

The present invention is not limited to the above embodiment. For example, as shown in FIG. 9, one wireless device may be optionally attached as a separate external module 81. In this case, for example, if the second wireless device is mounted in the external module 81, the lower housing 24 having the slot 82 for receiving the external module as shown in FIG. 9 is provided instead of the lower housing 22. . In the slot 82, the feeding point P2, the antenna 13, the wireless circuit unit 14 and the feeding pattern 42 in the mounted external module 81 are located at the positions described above with respect to the feeding point P1, the antenna 11, the wireless circuit unit 12 and the feeding pattern 41. It is provided in a state of being in a relationship.

When the antenna is provided on the external module side as described above, it is possible to insert the coil 72 in the signal line connecting the ground pattern of the external module and the ground pattern of the mobile communication terminal side.

When the external module can be arbitrarily mounted as described above, only the wireless circuit section may be mounted on the external module and the antenna may be provided on the side of the mobile communication terminal.

It is also possible to use another electric element or electric circuit having the same characteristics as the coil 72 as the high-frequency blocking means.

Further, the above-mentioned three means adopted in the above-mentioned embodiment can suppress the interference individually, and can also be adopted independently.

The antenna may be of a type different from a monopole antenna such as an inverted F antenna and a microstrip antenna. The antenna may be mounted either internally or externally.

Besides, various modifications can be made without departing from the scope of the present invention.

[0095]

EFFECTS OF THE INVENTION To reduce interference between wireless circuits, particularly interference between antennas when two wireless circuits capable of transmitting and receiving at the same time are provided, and to prevent deterioration of wireless characteristics due to the interference. It is an object of the present invention to provide such a mobile communication terminal.

[0096]

According to the first aspect of the present invention,
The first feeding point from the first wireless circuit unit to the first antenna and the second feeding point from the second wireless circuit unit to the second antenna are individually provided in the first housing and the second housing having the folding structure. In addition, since they are positioned so as not to face each other in the folded state, it is possible to suppress spatial interference between the vicinity of the first feeding point and the vicinity of the second feeding point.
It is possible to reduce interference between two wireless circuits, particularly interference between antennas, and prevent deterioration of wireless characteristics due to this.

According to the second aspect of the present invention, the ground pattern to which the first antenna is connected and the ground pattern to which the second antenna is connected are set to the frequencies of the signals transmitted from the first antenna and the second antenna. Since it was decided to connect via a high-frequency blocking device that blocks the band and blocks the frequency band lower than that, the signal in the radio frequency band is prevented from being transmitted through the ground pattern and conducted. The interference between the two radio circuits can be suppressed, and as a result, the interference between the two radio circuits, especially the interference between the antennas can be reduced,
It is possible to prevent the deterioration of wireless characteristics due to this.

According to the third aspect of the present invention, the first feeding point from the first radio circuit section to the first antenna is arranged in the null direction in the radiation characteristic of the second antenna, and the first radio circuit section is arranged in the null direction. Since the second feeding point to the two antennas is arranged in the null direction in the radiation characteristic of the first antenna,
Spatial interference between the vicinity of the feeding point and the vicinity of the second feeding point can be suppressed, and as a result, the interference between the two wireless circuits, especially the interference between the antennas can be reduced, and the resulting wireless characteristics It is possible to prevent deterioration of the.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a communication system using a mobile communication terminal according to an embodiment of the present invention.

FIG. 2 is a block diagram showing configurations of a first wireless device and a second wireless device.

FIG. 3 is a diagram showing a state where the mobile communication terminal 5 is viewed from two directions in a folded state.

FIG. 4 is a diagram showing a state where the mobile communication terminal 5 is viewed from one direction in an open state.

FIG. 5 is a diagram showing a perspective view of a mobile communication terminal 5 in an open state.

FIG. 6 is a diagram showing mounting positions of antennas 11 and 13 and radio circuit units 12 and 14 on substrates 31 and 32;

FIG. 7 is a diagram showing radiation characteristics of the antenna 11 and the antenna 13.

FIG. 8 is a diagram showing an electrical configuration of the mobile communication terminal 5.

FIG. 9 is a diagram showing a perspective view of a modified configuration example of a mobile communication terminal in an open state.

FIG. 10 is a diagram illustrating a conventional technique, and is a schematic diagram of a printed circuit board on which two wireless devices are mounted.

FIG. 11 is a diagram for explaining a conventional technique, showing how interference occurs between two wireless devices.

FIG. 12 is a diagram illustrating a conventional technique, showing a general input / output characteristic (saturation characteristic) of an RF amplifier.

FIG. 13 is a diagram for explaining a conventional technique, showing a frequency relationship of input / output signals of a mixer.

[Explanation of symbols]

5 ... Mobile communication terminal 11, 13 ... Antenna 12, 14 ... Wireless circuit section 21 ... Upper housing 22 ... Lower housing 23 ... Hinge part 24 ... Lower housing 31, 32 ... Substrate 41, 42 ... Feeding pattern 63, 64 ... Ground pattern 72 ... Coil 81 ... External module 82 ... slot P1, P2 ... Feeding point

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04M 1/02 H04M 1/02 C 5K067 1/21 1/21 Z H04Q 7/32 H04B 7/26 V F Term (reference) 5J021 AA02 AA06 AB02 AB06 CA06 DA02 DA04 DA05 FA17 FA24 FA26 GA08 HA05 HA06 HA10 5J046 AA02 AA04 AA12 AB06 AB10 AB13 DA02 UA02 5J047 AA02 AA04 AA12 AB01 AB05 AB01 AB05 AB02 AB01 AC12 AB01 AB02 AB01 AB01 AB12 AB01 AB12 AB01 AB12 AB01 AB01 AB01 AB01 AB12 AB01 AB12 AB01 AB12 AB01 AB01 AB12 AB01 AB12 AB01 MM00 5K067 AA06 BB04 EE02 KK03 KK17

Claims (21)

[Claims] 1. A first substrate, a first wireless circuit unit mounted on the first substrate, and a first feeding point on the first substrate via a first feeding line formed on the first substrate. A first antenna connected to the first wireless circuit unit, a first housing that accommodates the first substrate, a second substrate that is separate from the first substrate, and a second substrate A second antenna connected to the second wireless circuit unit at a second feeding point on the second substrate via a mounted second wireless circuit unit and a second feeding line formed on the second substrate. And a second housing that can form a folded state together with the first housing, and that accommodates the second substrate at a position where the second feeding point does not face the first feeding point in the folded state. A mobile communication terminal comprising a housing. 2. The second housing includes the second feeding point, the second wireless circuit, the second feeding line and the second antenna, the first feeding point, the first wireless circuit, and the first wireless circuit. The mobile communication terminal according to claim 1, wherein the second substrate is housed in a position that does not face the power supply line and the first antenna. 3. The first feeding point is formed on the surface of the first substrate opposite to the surface facing the second substrate in the folded state, and the one of the surfaces of the second substrate is formed. The mobile communication terminal according to claim 1, wherein the second feeding point is formed on a surface opposite to a surface facing the first substrate in the folded state. 4. A mobile communication terminal in which a separate external module having a second wireless circuit unit can be inserted and removed, a first substrate, a first wireless circuit unit mounted on the first substrate, and A first antenna connected to the first wireless circuit at a first feeding point on the first substrate via a first feeding line formed on the first substrate, and a first casing for housing the first substrate. A body, a second substrate separate from the first substrate, and a second feeding point on the second substrate via a second feeding line formed on the second substrate in the second wireless circuit unit. A second antenna connected with the first housing, and a slot capable of forming a folded state together with the first housing, and a slot for receiving the external module. In the folded state, the second feeding point has the second feeding point. The first wireless circuit that accommodates the second wireless circuit at a position that does not face the first feeding point Mobile communication terminal and a housing. 5. In the second housing, the second wireless circuit section in the external module mounted in the second feeding point, the second feeding line, the second antenna, and the slot has the first feeding. The mobile communication terminal according to claim 4, wherein the slot is provided at a position that does not face the point, the first wireless circuit, the first feed line, and the first antenna. 6. A detachable external module having a second radio circuit section and a second antenna connected to the second radio circuit at a predetermined second feeding point via a second feeding line can be inserted and removed. In a mobile communication terminal, a substrate, a first wireless circuit unit mounted on the substrate, and a first power feeding point formed on the substrate via a first power feeding line, the first wireless point at the first power feeding point on the substrate. A first antenna connected to the circuit; a first housing for accommodating the substrate; and a slot capable of forming a folded state together with the first housing, the slot for receiving the external module, and The mobile communication terminal, wherein the slot comprises a second housing arranged at a position where the second feeding point of the mounted external module is not opposed to the first feeding point in the folded state. 7. The second housing has the second feeding point, the second wireless circuit, the second feeding line, and the second antenna in the external module mounted in the slot, the first feeding point. The mobile communication terminal according to claim 6, wherein the slot is provided at a position that does not face the first wireless circuit, the first feed line, and the first antenna. 8. A mobile communication terminal capable of wireless communication using a predetermined second wireless circuit section, comprising: a first substrate having a first ground pattern formed thereon; and a first substrate mounted on the first substrate. And a first wireless circuit portion, and a first power feeding line formed on the first substrate, connected to the first wireless circuit portion at a first feeding point on the first substrate, and A first antenna grounded to a ground pattern; a first housing that houses the first substrate; a second substrate that is separate from the first substrate and has a second ground pattern formed thereon; A second antenna connected to the second wireless circuit section at a second feeding point on the second substrate via a second feeding line formed on two boards, and grounded to the second ground pattern; Forming a folded state together with the first housing And a second housing that houses the second substrate, and is interposed between the first ground pattern and the second ground pattern, and the first antenna and the second antenna A mobile communication terminal comprising: a high-frequency blocking unit that blocks a frequency band of a transmitted signal and blocks a frequency band lower than that. 9. A second substrate on which a second ground pattern is formed, a second wireless circuit section mounted on the second substrate, and a predetermined second wireless circuit connected to the second wireless circuit via a second feed line. In a mobile communication terminal capable of inserting and removing a separate external module having a second antenna connected at a feeding point and having a second antenna grounded to the second ground pattern, a first ground pattern is formed. A substrate, a first wireless circuit unit mounted on the first substrate, and a first feeding circuit formed on the first substrate, and connected to the first wireless circuit at a first feeding point on the substrate And is grounded to the first ground pattern
An antenna, a first housing for accommodating the first substrate, a body separate from the first substrate and the second substrate, and a third
A second housing that can form a folded state together with a third board having a ground pattern and the first housing, and that accommodates the third board and has a slot that receives the external module. And a signal that is inserted between the first ground pattern and the third ground pattern or between the second ground pattern and the third ground pattern and transmitted from the first antenna and the second antenna. Mobile communication terminal comprising: high frequency blocking means for blocking the passage of the frequency band of, and passing the lower frequency band. 10. A first substrate, a first wireless circuit unit mounted on the first substrate, and a first feeding point on the first substrate via a first feeding line formed on the first substrate. A first antenna connected to the first wireless circuit unit, a first housing that accommodates the first substrate, a second substrate that is separate from the first substrate, and a second substrate A second antenna connected to the second wireless circuit unit at a second feeding point on the second substrate via a mounted second wireless circuit unit and a second feeding line formed on the second substrate. And, it is possible to form a folded state together with the first housing, and at least in the folded state,
The second feeding point is positioned in the null direction in the radiation characteristic of the first antenna, and the second antenna is positioned such that the first feeding point exists in the null direction in the radiation characteristic. A mobile communication terminal comprising: a second housing containing two substrates. 11. The second housing has the second feeding point located in a null direction in a radiation characteristic of the first antenna even when the first housing and the second housing are opened. 11. The mobile communication terminal according to claim 10, wherein the second antenna accommodates the second substrate so that the first feeding point exists in the null direction of the radiation characteristic of the second antenna. 12. In the second housing, at least in the folded state, the second feeding point, the second wireless circuit, the second feeding line, and the second antenna have radiation characteristics of the first antenna. The second antenna is located in the null direction, and the second antenna is in a position in which the first feeding point, the first wireless circuit, the first feeding line, and the first antenna are present in the null direction in the radiation characteristic. The mobile communication terminal according to claim 10, which holds the second substrate, the second wireless circuit, and the second antenna. 13. The second casing, the second feeding point, the second wireless circuit, the second feeding line, and the second feeding point even when the first casing and the second casing are opened. The second antenna is located in the null direction in the radiation characteristic of the first antenna, and the second antenna is in the null direction in the radiation characteristic, the first feeding point, the first wireless circuit, and the first feeding line. The mobile communication terminal according to claim 12, wherein the second substrate, the second wireless circuit, and the second antenna are held so that the second antenna and the first antenna are located at the same position. 14. A mobile communication terminal in which a separate external module having a second wireless circuit unit can be inserted and removed, a first substrate, a first wireless circuit unit mounted on the first substrate, and A first antenna connected to the first wireless circuit at a first feeding point on the first substrate via a first feeding line formed on the first substrate, and a first casing for housing the first substrate. A body, a second substrate separate from the first substrate, and a second feeding point on the second substrate via a second feeding line formed on the second substrate in the second wireless circuit unit. A second antenna connected to the first housing and a second antenna, which is capable of forming a folded state together with the first housing, and has a slot for receiving the external module, and at least in the folded state, the second feeding point. Is the null in the radiation characteristics of the first antenna And a second housing that holds the second substrate and the second antenna such that the second antenna is located at the position where the first feeding point exists in the null direction. Communication terminal. 15. The second casing has the second feeding point located in a null direction in a radiation characteristic of the first antenna even when the first casing and the second casing are opened. And the second antenna has the first antenna in the null direction.
The mobile communication terminal according to claim 14, wherein the second substrate and the second antenna are held so that a position where a power feeding point exists. 16. The second radio in the external module mounted on the second feeding point, the second feeding line, the second antenna, and the slot in the second housing at least in the folded state. A circuit is located in the null direction in the radiation characteristic of the first antenna, and the second antenna is in the null direction in the radiation characteristic, the first feeding point, the first wireless circuit, the first feeding line, and the The mobile communication terminal according to claim 14, wherein the second substrate and the second antenna are held so that the first antenna is located at the position. 17. The second housing has the second feeding point, the second feeding line, the second antenna, and the slot even when the first housing and the second housing are open. The second radio circuit in the external module mounted on the first antenna is located in the null direction in the radiation characteristic of the first antenna, and the second antenna is in the null direction in the radiation characteristic in the first feeding point, the The mobile communication terminal according to claim 16, wherein the second substrate and the second antenna are held so that the first wireless circuit, the first feed line, and the first antenna are located. 18. A detachable external module having a second radio circuit section and a second antenna connected to the second radio circuit via a second feed line at a predetermined second feed point can be inserted and removed. In a mobile communication terminal, a substrate, a first wireless circuit unit mounted on the substrate, and a first power feeding point formed on the substrate via a first power feeding line, the first wireless power feeding point on the substrate A first antenna connected to the circuit; a first housing for accommodating the substrate; and a slot capable of forming a folded state together with the first housing, the slot for receiving the external module, and at least In the folded state, the second feeding point is positioned in the null direction in the radiation characteristic of the first antenna, and the second antenna is positioned such that the first feeding point exists in the null direction. Mobile communication terminal and a second housing, wherein the slots are arranged so as to position the external module. 19. The second housing has the second feeding point located in a null direction in a radiation characteristic of the first antenna even when the first housing and the second housing are opened. ,
The mobile communication terminal according to claim 18, wherein the second antenna holds the second substrate and the second antenna such that the second antenna is located at a position where the first feeding point exists in a null direction in its radiation characteristic. 20. The second housing, at least in the folded state, includes the second feeding point, the second wireless circuit, the second feeding line, and the second feeding point in the external module mounted in the slot. The external module in which the antenna is located in the null direction in the radiation characteristic of the first antenna, and the first feeding point, the first wireless circuit, the first feeding line, and the first antenna are mounted in the slot. The mobile communication terminal according to claim 18, wherein the slot is arranged so as to be located in a null direction in the radiation characteristic of the second antenna in. 21. The second housing, wherein the second power feeding point of the external module mounted in the slot and the second housing are provided even when the first housing and the second housing are opened. The wireless circuit, the second feeding line and the second antenna are located in the null direction in the radiation characteristic of the first antenna, and the first feeding point, the first wireless circuit, the first feeding line and the first feeding point. 21. The mobile communication terminal according to claim 20, wherein the slot is arranged so that one antenna is located in a null direction in a radiation characteristic of the second antenna in the external module mounted in the slot.