JP2011049902A - Mobile communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile communication device that prevents reduction in antenna gain while reducing an SAR even if the device has an antenna for transmitting or receiving signals of two or more resonant-frequencies. <P>SOLUTION: A cellular phone 1 includes: an operating unit side cabinet 2; an antenna 60 which is provided in the operating unit side cabinet 2, transmits or receives a signal of a first wavelength and transmits or receives a signal of a second wavelength shorter than the first wavelength; a reference potential unit 70 which is provided, in the operating unit side cabinet 2, for the antenna 60, and electrically connected to a reference potential; and a harmonic blocking filter 72 which is provided in the reference potential unit 70 and prevents transmission of the signal of the second wavelength. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a portable communication device having an antenna.

  2. Description of the Related Art In recent years, mobile communication devices having an antenna, such as a mobile phone, consider the influence on the human body due to electromagnetic waves radiated from the antenna, and consider SAR (Specific Absorption Rate) per unit time / unit mass absorbed by a specific part of the human body. Power) is required to be reduced.

  As a technique for reducing the SAR, for example, a technique such as Patent Document 1 has been proposed. Patent Document 1 discloses a first frequency at which a first antenna transmits and receives a total value of electrical lengths of a first antenna, a second antenna, a first feeding unit, and a second feeding unit. A technique has been proposed that reduces the SAR by dispersing the peak points of the high-frequency current flowing in the mobile phone by setting the wavelength longer than 1/2 wavelength to 1 wavelength or less.

  Another technique for reducing the SAR is to provide a part of the ground of the circuit board in the mobile phone between the antenna and the human body so that an electromagnetic wave radiated from the antenna by a part of the reference potential portion is generated. Techniques have been proposed for reducing SAR by absorption.

International Publication No. 2007/029741

  However, in the technique for reducing the SAR as described above, when a signal having a resonance frequency of 2 or more is transmitted or received, the length of the reference potential portion for absorbing the electromagnetic wave radiated from the antenna is the resonance frequency. It is known that it is different for each. For this reason, when the length of the reference potential portion is formed with a length corresponding to one resonance frequency, the electromagnetic wave having one resonance frequency radiated from the antenna is absorbed by the reference potential portion, and the SAR is reduced. However, signals of other resonance frequencies are also absorbed by the reference potential section, and the antenna gain at other resonance frequencies may be reduced.

  Accordingly, an object of the present invention is to provide a portable communication device that can reduce a decrease in antenna gain while reducing SAR even when an antenna that transmits or receives a signal having two or more resonance frequencies is provided. And

  In order to solve the above problems, a mobile communication device according to the present invention is provided in a housing, a first antenna that is provided in the housing and transmits or receives a signal having a first wavelength, and the housing. A second antenna that transmits or receives a signal of a second wavelength shorter than the first wavelength, and is provided in the housing corresponding to the first antenna and the second antenna, A reference potential portion electrically connected to a potential; and a suppression portion provided in the reference potential portion and suppressing transmission of a signal of the second wavelength.

  The reference potential unit is configured to have a length corresponding to a third wavelength, and the suppression unit is spaced apart from the end of the reference potential unit by a length corresponding to the second wavelength. Preferably, the reference potential portion is provided in the region.

  Moreover, it is preferable that an open end is formed at one end of the reference potential unit, and a power supply unit that supplies power to the reference potential unit is provided.

  The reference potential section is configured to be able to resonate with a signal having a third wavelength, and the wavelength obtained by dividing the third wavelength by a natural number and the second wavelength preferably overlap.

  Further, it is preferable that the length of the reference potential portion is shorter than a length obtained by multiplying the first wavelength by 1/4.

  ADVANTAGE OF THE INVENTION According to this invention, even if it has an antenna which transmits or receives the signal of 2 or more resonance frequency, it can provide the portable communication apparatus which can suppress the fall of an antenna gain, reducing SAR. .

It is a perspective view which shows the external appearance of the mobile telephone of one Embodiment of this invention. It is a front view which shows the open state of a mobile telephone typically.

  The best mode for carrying out the present invention will be described below with reference to the drawings. With reference to FIG. 1, a basic structure of a mobile phone 1 as a mobile terminal according to a preferred embodiment of the present invention will be described. FIG. 1 is an external perspective view showing a state in which the mobile phone 1 is opened.

  As shown in FIG. 1, the mobile phone 1 includes an operation unit side body 2 (housing) and a display unit side body 3. The operation unit side body 2 and the display unit side body 3 are connected so as to be openable and closable via a connecting part 4 having a hinge mechanism. Specifically, the upper end portion of the operation unit side body 2 and the lower end portion of the display unit side body 3 are connected via a connecting portion 4. Thereby, the mobile phone 1 is configured to be able to form an open / closed state by relatively moving the operation unit side body 2 and the display unit side body 3 connected via a hinge mechanism.

  That is, the cellular phone 1 relatively rotates (rotates) the operation unit side body 2 and the display unit side body 3 connected via the connection unit 4, thereby The display unit side body 3 and the display unit side body 3 can be opened, or the operation unit side body 2 and the display unit side body 3 can be closed.

  The outer surface of the operation unit side body 2 includes a front case 2a and a rear case 2b. The operation unit side body 2 exposes the operation key group 11 and the microphone 12 as a voice input unit to which a voice uttered by the user of the mobile phone 1 is input on the front case 2a side. Configured.

  The operation key group 11 includes a function setting operation key 13 for operating various functions such as various settings, a telephone book function, and a mail function, and an input operation key 14 for inputting a telephone number and characters such as mail. And a determination operation key 15 as an operation member for performing determination in various operations, scrolling in the vertical and horizontal directions, and the like. Each key constituting the operation key group 11 has a predetermined function according to the open / closed state of the operation unit side body 2 and the display unit side body 3, various modes, or the type of the activated application. Assigned (key assignment). Then, when the user presses each key, an operation corresponding to the function assigned to each key is executed.

  The microphone 12 is arranged on the outer end (lower end) side opposite to the connecting portion 4 side in the longitudinal direction of the operation unit side body 2. That is, the microphone 12 is disposed on one outer end side in the open state of the mobile phone 1.

  An interface (not shown) for communicating with an external device (for example, a host device) is disposed on one side surface of the operation unit side body 2. A side key to which a predetermined function is assigned and an interface (not shown) through which an external memory is inserted and removed are arranged on the other side surface of the operation unit side body 2. The interface is covered with a cap. Each interface is covered with a cap when not in use.

  The outer surface of the display unit side body 3 includes a front case 3a and a rear case 3b. In the front case 3a of the display unit side body 3, a display unit 21 for displaying various kinds of information and a receiver 22 for outputting the voice of the other party on the other side of the call are arranged so as to be exposed. Here, the display unit 21 includes a liquid crystal panel, a drive circuit that drives the liquid crystal panel, a light source unit such as a backlight that emits light from the back side of the liquid crystal panel, and the like.

  Next, the internal structure of the operation unit side body 2 and the display unit side body 3 will be described with reference to FIG. FIG. 2 is a front view schematically showing the inside of the cellular phone 1 in the opened state. In FIG. 2, the circuit board 50, the reference potential 51, the antenna 60 (first antenna and second antenna), and the reference potential portion 70 are virtually shown as constituent members inside the operation unit side body 2. Only the circuit board 30 is shown as a component inside the display unit side body 3.

  Various electronic components are mounted (mounted) on the circuit board 30 and the circuit board 50. The circuit board 50 includes a reference potential 51.

  The reference potential 51 is formed on the circuit board 50 and is electrically connected to a ground portion (not shown) of the circuit board 50. As the reference potential 51, for example, a reference potential pattern layer formed on the circuit board 50 can be used.

  The antenna 60 is provided in the vicinity of the microphone 12 side of the operation unit side body 2. The antenna 60 has a resonance frequency fa (for example, 800 MHz) and transmits or receives a signal having a wavelength λa (first wavelength). The antenna 60 also has a resonance frequency fb (for example, 5 GHz) that is higher than the resonance frequency fa, and transmits or receives a signal having a wavelength λb that is shorter than the wavelength λa. Therefore, the antenna 60 is formed to have a length La corresponding to at least a quarter wavelength of the wavelength λa and a length Lb corresponding to at least a quarter wavelength of the wavelength λb. For example, when the length La is a quarter wavelength of the wavelength λa, the antenna 60 functions as a monopole antenna or a dipole antenna using a mirror image effect by the reference potential unit 70. As described above, since the wavelength λa is longer than the wavelength λb (λa> λb), the length of the antenna 60 has a relationship of La> Lb. In this embodiment, the antenna 60 is formed to have the resonance frequency fa and the resonance frequency fb. However, the present invention is formed to have the antenna formed to have the resonance frequency fa and the resonance frequency fb. You may be comprised so that an antenna may be provided separately.

A power feeding unit 61 that feeds power to the antenna 60 is electrically connected to the antenna 60.
The power feeding unit 61 has one end connected to the antenna 60 and the other end electrically connected to the circuit board 50.

  The reference potential unit 70 is provided on the front case 2 a side of the operation unit side body 2 so as to correspond to the antenna 60 than the antenna 60, and is electrically connected to the reference potential 51. Further, the reference potential portion 70 has an L shape. An open end 70 a is formed at one end of the reference potential unit 70 (side not connected to the reference potential 51).

  The reference potential unit 70 also functions as an antenna having a length L (third antenna). In this case, the reference potential unit 70 transmits or receives a signal having a resonance frequency fc (for example, 2.5 GHz) and a wavelength λc (third wavelength). That is, the reference potential unit 70 is configured to have a length corresponding to the wavelength λc. Further, since the length La of the antenna 60 is formed by at least the length obtained by multiplying the wavelength λa by 1/4, the length L of the reference potential portion 70 is obtained by multiplying the wavelength λa by 1/4. It is formed so as to be shorter than a given length.

  The reference potential unit 70 is provided with a power feeding unit 71 and a high frequency blocking filter 72. The power supply unit 71 supplies power to the reference potential unit 70. One end of the power feeding unit 71 is electrically connected to the other end (side connected to the reference potential 51) side of the reference potential unit 70 with respect to the high frequency blocking filter 72, and the other end is electrically connected to the circuit board 50. ing.

  The high frequency blocking filter 72 is provided in the reference potential unit 70 and suppresses transmission of a signal having a resonance frequency fb (wavelength λb). The high-frequency blocking filter 72 is composed of, for example, beads or an LC circuit that absorbs a signal having a resonance frequency fb (wavelength λb), and is separated from the other end (end portion) of the reference potential unit 70 by a distance (length) L ′. Provided in the region. Here, L ′ is a length formed to have a relationship of L: L ′ = λa: λb. That is, the reference potential unit 70 is a ratio between the length L of the reference potential unit 70 corresponding to the resonance frequency fa (wavelength λa) and the length L ′ of the reference potential unit 70 corresponding to the resonance frequency fb (wavelength λb). Is formed so as to substantially match the ratio between the wavelength λa and the wavelength λb.

  As a result, as described above, since the resonance frequencies fa, fb, and fc have a relationship of fa <fc <fb, the reference potential unit 70 includes the resonance frequency fa (wavelength λa) and the resonance frequency fb. A ground corresponding to each signal (wavelength λb) is formed.

  Next, operations of the antenna 60 and the reference potential unit 70 when receiving signals of the resonance frequency fa (wavelength λa), the resonance frequency fb (wavelength λb), and the resonance frequency fc (wavelength λc) will be described.

  First, the operation when receiving a signal having the resonance frequency fa (wavelength λa) will be described. When the signal of the resonance frequency fa is received by the entire antenna 60 having the length La, the reference potential unit 70 and the reference potential 51 are electrically connected (short-circuited), so that the reference potential unit 70 has the resonance frequency fa. It functions as a ground having a length L with respect to the signal.

  Therefore, since the electromagnetic wave radiated from the antenna 60 is absorbed by the reference potential unit 70 functioning as a ground having a length L, the mobile phone 1 can reduce the SAR caused by the signal having the resonance frequency fa (wavelength λa). it can.

  Next, an operation when receiving a signal having the resonance frequency fb (wavelength λb) will be described. When the signal having the resonance frequency fb is received by the part having the length Lb of the antenna 60, the reference potential unit 70 and the reference potential 51 are electrically connected (short-circuited), and the reference potential unit 70 has a high frequency. Since the blocking filter 72 is provided in a region separated by a distance (length) L ′ from the other end (end portion) of the reference potential unit 70, the signal of the resonance frequency fb is blocked at a high frequency by the high frequency blocking filter 72. The In this case, the reference potential unit 70 functions as a ground having a length L ′ with respect to the signal having the frequency fb.

  Therefore, since the electromagnetic wave radiated from the antenna 60 is absorbed by the reference potential unit 70 functioning as the ground having the length L ′, the mobile phone 1 efficiently performs the SAR by the signal having the resonance frequency fb (wavelength λb). Can be reduced.

  Next, an operation when receiving a signal having a resonance frequency fc (wavelength λc) will be described. When receiving a signal having a resonance frequency fc, the reference potential unit 70 functions as an antenna. In this case, the reference potential unit 70 and the power feeding unit 71 function as a so-called inverted F antenna. At this time, the high frequency blocking filter 72 provided in the reference potential unit 70 suppresses transmission of the signal having the resonance frequency fb, but does not suppress transmission of the signal having the resonance frequency fc. Thereby, when receiving the signal of the resonance frequency fc, the reference potential unit 70 can function as an inverted F antenna without reducing the antenna gain.

  As shown in FIG. 2, when the antenna 60 and the reference potential unit 70 functioning as an inverted-F antenna are arranged close to each other, the wavelength obtained by dividing the wavelength λc by the natural number n and the wavelength λb overlap. In other words, in the case of fb = n × fc (n is a natural number and n = 2 in the present embodiment), the signal of the resonance frequency fb is generated by the harmonic of the resonance frequency fc that is n times the resonance frequency fc. There is a possibility that the gain of the antenna 60 when receiving is reduced. However, the cellular phone 1 according to the present embodiment has the frequency fb, that is, the harmonic of the resonance frequency fc (wavelength obtained by dividing the natural number n by the wavelength λc) by the high frequency blocking filter 72 provided in the reference potential unit 70. Since signal transmission is suppressed, it is possible to suppress a decrease in the gain of the antenna 60 due to harmonics of the resonance frequency fc.

  As described above, the cellular phone 1 according to the present embodiment is provided corresponding to the antenna 60 in the operation unit side body 2 and electrically connected to the reference potential, and the reference potential unit 70. And a high-frequency blocking filter 72 that suppresses transmission of a signal having the second wavelength.

  As a result, the reference potential unit 70 functions as a ground having a length L when receiving a signal having the resonance frequency fa (wavelength λa), and the high-frequency blocking filter 72 applies the signal having the resonance frequency fb (wavelength λb) to the high frequency side. Shut off. Therefore, the cellular phone 1 reduces the SAR due to the electromagnetic wave radiated from the antenna 60 when receiving the signal having the resonance frequency fa (wavelength λa), and the reference when receiving the signal having the resonance frequency fb (wavelength λb). Since the potential portion 70 appears to be shorter than L, it is possible to suppress a decrease in gain of the antenna 60 with respect to the signal having the resonance frequency fb.

  Further, the reference potential unit 70 is a ratio between the length L of the reference potential unit 70 corresponding to the resonance frequency fa (wavelength λa) and the length L ′ of the reference potential unit 70 corresponding to the resonance frequency fb (wavelength λb). Is formed so as to substantially match the ratio between the wavelength λa and the wavelength λb. As a result, the reference potential unit 70 forms grounds corresponding to the signals of the resonance frequency fa (wavelength λa) and the resonance frequency fb (wavelength λb) received by the antenna 60, and therefore has the resonance frequency fb (wavelength λb). SAR caused by electromagnetic waves radiated from the antenna 60 when receiving a signal can be efficiently reduced.

  In addition, the mobile phone 1 of the present embodiment has an open end 70 a formed at one end of the reference potential unit 70, and has a power supply unit 71 that supplies power to the reference potential unit 70. For this reason, when transmitting or receiving a signal having the resonance frequency fc (wavelength λc), the reference potential unit 70 functions as an antenna. Therefore, since the reference potential unit 70 can function not only as a ground but also as an antenna, the mobile phone 1 can effectively use the reference potential unit 70.

  In the mobile phone 1 of the present embodiment, the wavelength obtained by dividing the natural number by the wavelength λc and the wavelength λb overlap. Thereby, in the mobile phone 1, it is possible to suppress interference with a signal having the resonance frequency fb (wavelength λb) due to a harmonic signal having the resonance frequency fc (wavelength λc).

  In the mobile phone 1 of the present embodiment, the length L of the reference potential unit 70 is shorter than the length obtained by multiplying the wavelength λa by ¼. Therefore, the reference potential unit 70 suppresses the gain reduction of the antenna 60 when receiving the signal of the resonance frequency fa (wavelength λa), and the resonance frequency fa of the signal of the resonance frequency fc (wavelength λc) and its harmonic signal. Interference with the signal of (wavelength λa) can be suppressed.

  As mentioned above, although embodiment of this invention was described, this invention is not restrict | limited to embodiment mentioned above, It can change suitably. For example, in the embodiment described above, the position of the antenna 60 is set in the vicinity of the microphone 12 in the operation unit side body 2. However, the present invention is not limited to this, and the antenna 60 may be connected to the operation unit side body 2 or the display unit. What is necessary is just to be provided in the side housing | casing 3. FIG. In the above-described embodiment, the antenna 60 and the reference potential unit 70 when receiving signals of the wavelength λa, the wavelength λb, and the wavelength λc have been described. However, the antenna 60 and the reference potential unit 70 of the present invention have the wavelength λa, The present invention can also be applied when transmitting signals of wavelength λb and wavelength λc.

  In the above-described embodiment, the high-frequency blocking filter 72 that cuts off the signal having the resonance frequency fb (wavelength λb) at a high frequency is used. However, the present invention is not limited to this. For example, instead of the high-frequency blocking filter 72, A band pass filter or the like that transmits only the signal of the resonance frequency fc (wavelength λc) and suppresses the transmission of the signal of the resonance frequency fb or other resonance frequency may be used. In the present embodiment, since the other end of the reference potential unit 70 is connected to the reference potential 51, the high frequency blocking filter 72 is located in a region separated by a distance (length) L ′ from the other end of the reference potential unit 70. In the case where one end of the reference potential unit 70 is connected to the reference potential 51, the high frequency blocking filter 72 is separated from the one end (end) of the reference potential unit 70 by a distance (length) L ′. It may be provided in the area.

  In the above embodiment, the mobile phone 1 has been described. However, the present invention is not limited to the mobile phone. For example, a PHS (Personal Handyphone System), a PDA (Personal Digital Assistant), a portable navigation device, a notebook computer, and the like. It can be applied to any mobile terminal.

1 Mobile phone (mobile communication equipment)
2 Operation unit side case (case)
51 Reference potential 60 Antenna (first antenna, second antenna)
61 Power Supply Unit 70 Reference Potential Unit 71 Power Supply Unit 72 High Frequency Blocking Filter (Suppression Unit)

Claims (5)

A housing,
A first antenna provided in the housing for transmitting or receiving a signal of a first wavelength;
A second antenna that is provided in the housing and transmits or receives a signal having a second wavelength shorter than the first wavelength;
A reference potential portion provided corresponding to the first antenna and the second antenna in the housing and electrically connected to a reference potential;
A portable communication device comprising: a suppression unit that is provided in the reference potential unit and suppresses transmission of a signal of the second wavelength. The reference potential portion is configured to have a length corresponding to the third wavelength,
2. The mobile communication device according to claim 1, wherein the suppression unit is provided in a region of the reference potential unit that is spaced apart from an end of the reference potential unit by a length corresponding to the second wavelength. At one end of the reference potential portion, an open end is formed,
The portable communication device according to claim 1, further comprising a power feeding unit that feeds power to the reference potential unit. The reference potential unit is configured to be able to resonate with a signal having a third wavelength,
The portable communication device according to claim 3, wherein a wavelength obtained by dividing the third wavelength by a natural number and the second wavelength overlap each other.   4. The mobile communication device according to claim 3, wherein a length of the reference potential portion is shorter than a length obtained by multiplying the first wavelength by ¼.

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