JP2009135692A - Portable communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable communication device which flexibly cope, even if substrate shapes are different, and by which suitable antenna characteristics are obtained. <P>SOLUTION: In an area where an antenna element 71 is formed, a plurality of independent conductive parts 71a are formed into a lattice shape. The conductive parts 71a are electrically connected to each other by a connection part 71b, and the antenna element 71 of a predetermined shape is formed. The antenna element 71 is electrically connected to a power feeding part 71c via the connection part 71b. The power feeding part 71c is connected to a signal processing part 72, which processes a signal transmitted or received by the antenna element 71. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a portable communication device having a configuration for transmitting or receiving a signal.

2. Description of the Related Art In recent years, a technique for transmitting or receiving signals using a single conductive region as an antenna element has been proposed in a portable wireless terminal such as a mobile phone (for example, see Patent Document 1). reference).
JP-A-6-85529

  However, when a change occurs in the shape and size of the portable wireless terminal due to a subsequent design change or the like, the signal transmission characteristic or reception characteristic in the conductive region also changes in accordance with the change. Then, it is necessary to adjust the transmission characteristic or reception characteristic of the conductive region in accordance with the signal to be transmitted or received. However, since the conductive region is composed of a single element, its length and shape can be easily adjusted. There is a problem that it cannot be changed, and thus adjustment of transmission characteristics or reception characteristics is not easy.

  The present invention has been made in view of the above-described problems, and one of its purposes is that a plurality of independent conductive regions are electrically connected by a connecting portion, and therefore, the posterior of the conductive regions. It is an object of the present invention to provide a portable communication device that can easily adjust various transmission characteristics or reception characteristics.

  In order to solve the above-described problem, a portable wireless device according to the present invention is provided with a plurality of independent conductive regions, a connection portion that electrically connects the plurality of independent conductive regions, and the connection portion. A plurality of independent conductive regions electrically connected to the plurality of independent conductive regions connected to each other, and the plurality of independent conductive regions electrically connected to the connection portions via the power supply unit And a signal processing unit for processing a signal transmitted or received by resonance of the plurality of independent conductive regions electrically connected by the connection unit. And

  In the portable wireless device, the connection unit is a wavelength adjustment unit configured by a member that adjusts a wavelength of a signal at which the plurality of independent conductive regions electrically connected by the connection unit resonate. Preferably there is.

  Moreover, in the said portable radio | wireless apparatus, it is preferable that it is a wavelength adjustment part comprised by the member which adjusts the wavelength of the signal which the said several independent electroconductive area | region electrically connected by the said connection part resonates long. .

  The portable wireless device includes an antenna that transmits and receives signals, a plurality of independent conductive regions, and a connection portion that electrically connects the plurality of independent conductive regions, and the connection portion. The plurality of independent conductive regions that are electrically connected to each other preferably have a length of a half or a quarter of a wavelength of a signal having a predetermined frequency. .

  Further, in the portable wireless device, a part of the plurality of independent conductive regions electrically connected by the connection portion is configured to be connected to an electrically grounded region. preferable.

  In the portable communication device according to the present invention, since a plurality of independent conductive regions are electrically connected by the connecting portion, the subsequent transmission characteristics or reception characteristics of the conductive regions can be easily adjusted.

  FIG. 1 is an external perspective view of a mobile phone device 1 that is an example of a mobile wireless device that communicates with an external device (base station) according to the present invention.

  The cellular phone device 1 includes an operation unit side body 2 composed of a front case 2a and a rear case 2b on the surface, and a display unit side body 3 composed of a front panel 3a and a rear panel 3b on the surface. It is prepared for. The operation unit side body unit 2 is configured such that the operation button group 11 and the voice input unit 12 to which the voice uttered by the user of the mobile phone device 1 is input are exposed on the surface of the front case 2a. The The operation button group 11 includes a function setting operation button 13 for operating various functions such as various settings, a telephone book function, and a mail function, and an input operation for inputting a telephone number and characters such as mail. The button 14 and a determination operation button 15 for performing determination and scrolling in various operations are configured. Further, a cap 16 that covers an interface for communicating with an external device (for example, a host device) is provided on the side surface of the operation unit side body 2.

  Further, the display unit side body unit 3 is configured such that a display 21 for displaying various information and an audio output unit 22 for outputting the voice of the other party of the call are exposed on the front panel 3a.

  Moreover, the upper end part of the operation part side housing | casing part 2 and the lower end part of the display part side housing | casing part 3 are connected via the hinge mechanism 4, as shown in FIG. In addition, the mobile phone device 1 moves the operation unit side body unit 2 and the display unit side body unit 3 connected to each other via the hinge mechanism 4 to display the operation unit side body unit 2 and the display. It can be in a state where the unit side body 3 is open to each other (open state), or the operation unit side body 2 and the display unit side body 3 are folded (folded state). In the present embodiment, the foldable mobile phone device 1 using the hinge mechanism 4 is described. However, the foldable mobile phone device 1 is not foldable. A slide type that is slid on the axis, a rotary type that is configured to rotate one casing around an axis along the overlapping direction, and a configuration in which both casings 2 and 3 are connected via a biaxial hinge, Furthermore, the operation unit side body 2 and the display unit side body 3 may be arranged in a single housing (so-called straight type).

  FIG. 2 is an exploded perspective view of members built in the operation unit side body 2.

  As shown in FIG. 2, the operation unit side body 2 has a front case 2a, a key sheet 40 that constitutes the operation button group 11 described above, a flexible printed board 50, a shield case 60, and a reference potential. And a circuit board 70 including various electronic components such as a signal processing unit 72 (RF (Radio Frequency) processing unit) for a mobile phone, a rear case 2b, a battery 80, and a battery lid 90. . In the operation unit side body 2, the front case 2a, the key sheet 40, the flexible printed board 50, the shield case 60, the circuit board 70, and the rear case 2b are arranged in a stacked manner. In addition, the battery 80 is detachably accommodated from the outside of the rear case 2 b and is covered with a battery lid 90.

  Further, the front case 2a and the rear case 2b are arranged so that their concave inner surfaces face each other, and are joined so that their outer peripheral edges overlap each other. Further, the key sheet 40, the flexible printed board 50, the shield case 60, and the circuit board 70 are built in between the front case 2a and the rear case 2b. That is, the shield case 60 is laminated so as to cover the circuit board 70, the flexible printed board 50 is laminated on the upper surface side of the shield case 60, and the key sheet 40 is laminated on the upper surface of the flexible printed board 50. Be placed.

  Moreover, the circuit board 70 and the shield case 60 are partially fixed in a detachable manner at a plurality of connecting portions.

  Various electronic components are arranged on the circuit board 70. Various electronic components form a plurality of circuit blocks by a predetermined combination. For example, various circuit blocks including a wireless circuit, a power supply circuit, a digital circuit, and the like are formed. Further, an antenna element 71 is formed on one end side of the circuit board 70 as will be described in detail later.

  The shield case 60 is a metal member having a shape in which one wide surface of a thin rectangular parallelepiped is opened. The shield case 60 may be made of a skeleton made of resin and a conductor film formed on the surface thereof, in addition to being made of metal.

  The flexible printed circuit board 50 has a plurality of key switches 51, 52, 53 on the surface on the front case 2 a side, and is placed on the flat plate portion 42 in the shield case 60. The key switches 51, 52, and 53 of the flexible printed circuit board 50 have a structure having a metal dome of a metal plate that is curved in a bowl shape and is three-dimensionally formed. When the apex of the bowl-shaped shape is pressed, the metal dome comes into contact with a switch terminal formed in an electric circuit (not shown) printed on the surface of the flexible printed board 50 and becomes electrically conductive. In addition, although mentioned later for details, the flexible printed circuit board 50 is a board | substrate which pinched wiring between several insulating films.

  The key sheet 40 is configured by attaching the operation button group 11 to the surface of a silicon rubber sheet 41 with an adhesive. The function setting operation button 13, the input operation button 14, and the determination operation button 15 constituting the operation button group 11 in the key sheet 40 are disposed at positions facing the key switches 51, 52, and 53 on the flexible printed circuit board 50. It arrange | positions so that it may expose from the key hole formed in the front case 2a mentioned later.

  A plurality of key holes are formed on the inner surface of the front case 2a facing the display 21 of the display unit side body 3 in a state in which the cellular phone device 1 is folded. From each of the plurality of key holes, the pressing surfaces of the function setting operation button 13, the input operation button 14 and the determination operation button 15 formed on the key sheet 40 are exposed. By pressing down the pressing surfaces of the function setting operation button 13, the input operation button 14 and the determination operation button 15 constituting the exposed operation button group 11, the metal dome in each of the corresponding key switches 51, 52 and 53 is pressed. The apex of (saddle-like shape) is pressed and comes into electrical contact with the switch terminal.

  Here, the antenna element 71 formed on one end side of the circuit board 70 will be described.

<First Configuration Example of Antenna Element 71>
As shown in FIG. 3, a plurality of independent conductive portions 71a (conductive regions) are formed in a lattice shape in the region where the antenna element 71 is formed. The size and number of the conductive portions 71a are arbitrary, and the formation pattern of the conductive portions 71a is not limited to the lattice shape shown in FIG.

  Further, the plurality of independent conductive portions 71a are electrically connected to each other by a connection portion 71b so as to have a predetermined shape, and, for example, an antenna element 71 having a predetermined shape is formed as shown in FIG. The Further, the antenna element 71 is electrically connected to the power feeding unit 71c via the connection unit 71b. The power feeding unit 71 c is connected to a signal processing unit 72 that processes a signal transmitted or received by the antenna element 71. 3 to 9, the signal processing unit 72 is illustrated as being disposed in the vicinity of the antenna element 71, but the position where the signal processing unit 72 is disposed is not limited thereto.

  Here, a specific example of the connecting portion 71b will be described. As a first specific example, the connecting portion 71b is configured by a 0Ω resistor (jumper resistor). With this configuration, an arbitrary antenna element pattern can be formed so that predetermined characteristics can be obtained by connecting the conductive portions 71a with a 0Ω resistor.

  As a second specific example, the connection portion 71b is configured by a member (for example, a coil or a capacitor) that adjusts the wavelength of a signal that resonates with a plurality of independent conductive portions 71a to be connected. Moreover, the connection part 71b may be comprised by the member (for example, a coil, a capacitor | condenser, etc.) which adjusts the wavelength of the signal which the several independent electroconductive part 71a used as the connection object resonates long.

  With this configuration, the connection unit 71b has a function as a wavelength adjustment unit that adjusts the wavelength, and can apply a predetermined wavelength shortening rate (for example, several tens of percent). It can be carried out. Therefore, even if it is the shape of the same antenna element, a different frequency characteristic can be given by selecting the connection part 71b suitably.

  The antenna element 71 may be configured using a 0Ω resistor, a coil, and a capacitor as the connection portion 71b.

  In addition, the shape of the antenna element 71 is preferably configured by a length of one-half or one-fourth of the wavelength of a signal having a predetermined resonance frequency fc. With this configuration, it is possible to perform suitable communication with other communication devices.

<Second Configuration Example of Antenna Element 71>
Further, as shown in FIG. 4, a part of the antenna element 71 is preferably configured as a parasitic element 71d. With this configuration, the radiation direction can be adjusted by the antenna element 17 and the gain can be improved. The shape of the parasitic element 71d is arbitrary, and is determined by the shape, arrangement distance, and the like of the antenna element 71.

<Third Configuration Example of Antenna Element 71>
Further, as shown in FIG. 5, a part of the antenna element 71 is configured as a ground pattern 71e connected to an electrically grounded area (a ground pattern 70a formed on the circuit board 70). Is preferred. By being configured in this way, it is possible to adjust the impedance and adjust the resonance frequency to be a suitable resonance frequency fc. The shape of the ground pattern 71e is arbitrary, and is determined by the shape of the antenna element 71, the arrangement distance, and the like. In the present embodiment, the connection portion 71b constituting the ground pattern 71e is constituted by a 0Ω resistor, but is not limited thereto.

<Fourth Configuration Example of Antenna Element 71>
Further, by forming a via hole 71f in a part of the conductive portion 71a and electrically connecting the front surface and the back surface of the circuit board 70, an antenna element is also formed on the back surface of the circuit board 70 as shown in FIG. It is preferable that it is comprised. With this configuration, the length of the antenna element 71 can be adjusted. 6A shows a part of the front surface of the circuit board 70, and FIG. 6B shows a part of the back surface of the circuit board 70.

<Fifth Configuration Example of Antenna Element 71>
In addition, as shown in FIG. 7, the antenna element 71 is preferably configured by changing the surface area of the conductive portion 71 a and appropriately selecting a connection portion 71 b that electrically connects the conductive portions 71 a. . In this configuration, for example, it is useful when the shape of the antenna element 71 can be predicted, the number of parts can be reduced, and the cost can be reduced.

  Specifically, for example, in the stage where the conductive portion 71a is formed on the circuit board 70, a connection portion 71b having an outer dimension of 1.6 mm × 0.8 mm (so-called so-called) , 1608 size chip), the conductive portion 71a of a size that can be connected is formed, and the tip portion X that becomes the open end of the antenna element 71 needs fine adjustment, so the outer dimension is 0.6 mm. A conductive portion 71a having a size capable of being connected is formed by a connection portion 71b (so-called 0603 size chip) having a size of 0.3 mm. According to such a configuration, the number of parts can be reduced and the cost can be reduced.

  The antenna element 71 may be configured by selectively using all or part of the first to fifth configuration examples described above.

  In addition, a part of the ground pattern 71e shown in the third configuration example described above is formed in a lattice shape, and the flow of the high-frequency current flowing on the antenna element 71 is adjusted by changing the connection of the 0Ω resistor. And suitable communication with an external device can be performed.

<Sixth Configuration Example of Antenna Element 71>
Further, the antenna element 71 may be configured to be used as an auxiliary pattern for a built-in antenna such as a molded antenna as shown in FIG. In the case of such a configuration, a pad portion 71g for feeding a molded antenna is formed in a part of the antenna element 71.

<Seventh Configuration Example of Antenna Element 71>
Further, as shown in FIG. 9, the antenna element 71 may be configured by only the conductive portion 71a so as to have a predetermined shape. In the final substrate of the mass production version, the cost can be reduced by forming (printing) the shape of the antenna element 71 in consideration of the required characteristics without using a 0Ω resistor or the like by the conductive portion 71a. .

  Further, as a seventh configuration example of the antenna element 71, only the vicinity of the open end of the antenna element 71 may be left with a 0Ω resistance connection. According to such a configuration, the circuit board 70 can flexibly fine-tune the resonance frequency fc even when the shape of the casing itself changes.

  Further, the grid shape printed on the circuit board 70 may be not only a quadrangular shape but also a triangular shape or other shapes.

  In this manner, in the mobile phone device 1 according to the present invention, the plurality of independent conductive portions 71a (conductive regions) are formed in a lattice shape, and the antenna element 71 is conductive so as to have a predetermined shape. Since the connecting portions 71a are electrically connected to each other by the connecting portion 71b, the shape and size of the antenna element 71 can be arbitrarily formed in a state after the circuit board 70 is completed. In the cellular phone device 1 according to the present invention, the reworkability when adjusting the resonance frequency fc by changing the length of the antenna element 71 is excellent. Further, in the cellular phone device 1 according to the present invention, the conductive portions 71a are electrically connected to each other by soldering a 0Ω resistor as the connecting portion 71b. It can be kept low. Further, the cellular phone device 1 according to the present invention can be manufactured at a lower cost than a cellular phone device having a built-in antenna such as a molded antenna.

It is a perspective view which shows the external appearance of the mobile telephone apparatus which concerns on this invention. It is a disassembled perspective view of the member incorporated in the operation part side housing | casing part. It is a figure which shows typically the 1st structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 2nd structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 3rd structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 4th structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 5th structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 6th structural example at the time of an antenna element being formed on a circuit board. It is a figure which shows typically the 7th structural example at the time of an antenna element being formed on a circuit board.

Explanation of symbols

1 Cellular phone device 71 Antenna element 71a Conductive part (conductive region)
71b Connecting portion 71c Feeding portion 71d Parasitic element 71e Ground pattern 71f Via hole 71g Pad portion 72 for feeding the molded antenna Signal processing portion

Claims (5)

A plurality of independent conductive regions;
A connecting portion for electrically connecting the plurality of independent conductive regions;
A power feeding part electrically connected to the plurality of independent conductive regions electrically connected by the connection part;
The plurality of independent conductive regions electrically connected to the plurality of independent conductive regions that are electrically connected to each other through the power supply unit and the plurality of independent units that are electrically connected to each other through the connection unit. And a signal processing unit that processes a signal transmitted or received due to resonance of the conductive region.   The said connection part is a wavelength adjustment part comprised by the member which adjusts the wavelength of the signal which the said several independent electroconductive area | region electrically connected by the said connection part resonates. 1. The mobile communication device according to 1.   The connection section is a wavelength adjustment section configured by a member that adjusts the wavelength of a signal that resonates between the plurality of independent conductive regions electrically connected by the connection section. Item 1. A mobile communication device according to Item 1. An antenna for transmitting and receiving signals;
A plurality of independent conductive regions;
A connection part for electrically connecting the plurality of independent conductive regions,
The plurality of independent conductive regions that are electrically connected by the connection portion are configured with a length of one-half or one-fourth of a wavelength of a signal having a predetermined frequency. A portable communication device characterized by that.   5. The part of the plurality of independent conductive regions electrically connected by the connection portion is configured to be connected to a region that is electrically grounded. 6. Mobile communication device.

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