Patent Publication Number: US-7903036-B2

Title: Antenna device and wireless communication apparatus using the same

Description:
RELATED APPLICATIONS 
     This application is a 371 of PCT/JP2007/000579 filed May 30, 2007, which claims priority under 35 U.S.C 119 to an application JAPAN 2005-152670 filed on May 31, 2006, the contents of which are incorporated herein by reference. 
     TECHNICAL FIELD 
     The present invention relates to an antenna device and more particularly to the antenna device that can be applied to a plurality of bands (transmitting/receiving bands) and a wireless communication apparatus using the antenna device. 
     BACKGROUND TECHNIQUE 
     Conventionally, as an example of an antenna device mounted in a wireless communication apparatus such as a mobile phone, a mobile information terminal or a like, for example, Patent Reference 1 discloses that a chip antenna of a dielectric material or a magnetic material is attached on a substrate and then an added conductor of a phosphor bronze is connected to the chip antenna. In this antenna device, not only mechanical reliability of the chip antenna is improved by attaching the chip antenna directly on the substrate but also the antenna device is made larger in electrical volume to improve its antenna gain in a single band by connecting one end of the added conductor to an upper portion of the chip antenna. 
     Patent Reference 1: Δn official gazette of Unexamined Japanese Patent Publication 73024/2005 
     DISCLOSURE OF THE INVENTION 
     Problem to be Solved by the Invention 
     In recent years, a wireless communication apparatus such as a mobile phone or a like has become widespread and various bands are used in communications. In a recently-available mobile phone called a dual-band, triple-band, or quad-band type mobile phone in particular, one mobile phone is made to operate in a plurality of bands (transmitting/receiving bands). In such a circumstance, hurried development of an antenna device making up antenna circuits that can be embedded in a mobile phone or a like being capable of operating in a plurality of bands (transmitting/receiving bands) described above is needed. It is thus necessary that, in order to respond to needs for further miniaturization of a wireless communication apparatus such as a mobile phone and for operations in multi-bands, despite a tendency of an increase in antenna components, the antenna device not only can achieve its miniaturization and high performance but also can have its mechanical reliability. For example, it is necessary that an antenna device suffers from no destruction, and the like, even if the apparatus is dropped or subjected to a little violent treatment. In the Patent Reference 1, the antenna device disclosed therein has an added conductor of metal. It must not be caused to occur that this metal conductor suffers from damage or destruction due to an external force, and the like. Besides, the antenna device disclosed in the Patent Reference 1 is such an antenna device for use in a single band, although the metal conductor is added to the antenna device. The antenna device could not be applied to a plurality of bands (transmitting/receiving bands). 
     The present invention has been made in view of the above described various problems. It is therefore an object of the present invention to realize an antenna device that can operate in wide bands (in a plurality of frequency bands) and can achieve an excellent antenna gain and maintain non-directivity of vertically polarized waves in each band in a space-saving manner, and also to improve mechanical and structural reliability of the antenna device. 
     Means for Solving the Problem 
     According to the present invention, an antenna device comprising: 
     an approximately U-shaped conductor antenna, on one end side of which a power feeding portion is provided and on the other end side of which an end portion is provided as an open end terminal, and which has a folded-back portion; 
     a base body made of an insulating material; 
     a substrate on which said conductor antenna and said base body are mounted; 
     conductor planes of said one end side and said the other end side of said conductor antenna constituted to be approximately perpendicular to each other; 
     said base body being fixed on said substrate; at least said one end side of said conductor antenna being fixed on said base body; and 
     said folded-back portion being fixed on said substrate. 
     Herein, said one end side of said conductor antenna may also be fixed on said substrate. 
     By configuring as above, said one end side and said open end terminal on the other end side of said conductor antenna are combined adjacently with the insulating base body of the dielectric material, the magnetic material, or the like. The antenna device thereby becomes capable of being operable in wide bands (in a plurality of frequency bands) and of achieving excellent antenna gain and of maintaining non-directivity of vertically polarized waves. At this time, the antenna device can be made smaller in height to achieve its miniaturization with a radiation area of the conductor antenna being saved. In addition to this, a plane perpendicular to the ground is formed with a certain distance being kept from a ground portion of the substrate. Thereby, planes each in which capacitive coupling occurs are decreased and then unnecessary capacitive couplings are decreased. This can further attribute to improvement of antenna gain and operability of the antenna device in a wider band of frequencies. Further, the conductor antenna has the folded-back portion, so that the conductor antenna is formed to be approximately U-shaped. However, since a conductor itself is comparatively long and plain panel-shaped, rigidity of the conductor itself is not enough. Accordingly, by supportively fixing this conductor on a substrate side except for the base body, load on the conductor can be disputed. Therefore, mechanical strength of the conductor is improved, so that reliability of the antenna device is also improved. Besides, the conductor antenna of the present invention is not limited to be U-shaped. It is enough for the conductor antenna of the present invention to have the folded-back portion. For example, the conductor antenna of the present invention can be formed to be approximately E-shaped with a plurality of folded-back portions being provided therein. These variations are totally called as the approximately U-shaped conductor antenna. 
     As regards supportively fixing the conductor antenna on the substrate in the present invention, it is desirable that a hook portion for fixing the conductor antenna on the substrate is provided in the conductor antenna while a notch portion corresponding to the hook portion is formed in the substrate, and so that both the conductor antenna and the substrate are jointly fixed by each flat plane on each other. Alternatively, it is also desirable that a projecting portion for fixing the conductor antenna on the substrate is provided in the conductor antenna while a hole portion corresponding to the projecting portion is formed in the substrate, and so that both the conductor antenna and the substrate are jointly fixed by fitting the projecting portion into the hole portion. Moreover, a combination of these fixing structures can also be used. 
     The antenna device according to the present invention may have said conductor antenna the one end side of which comprises a plate-shaped conductor consisting, for example, of a metal thin plate, and the other end side of which comprises a conductor pattern formed on a back surface of the substrate and consisting, for example, of a metal foil; an end portion of the plate-shaped conductor near the folded-back portion at the one end side being hooked into a hole portion or a notch portion formed on the substrate and being joined to said conductor pattern at the other end side; and the conductor antenna being fixed on the substrate. 
     By configuring as the above, the plate-shaped conductor at the one end side is supportively fixed on the base body and/or the substrate while a metal conductor pattern is connected to the other end side. Thereby, the approximately U-shaped conductor antenna is formed and, in addition, an antenna conductor can be attached and fixed on the substrate. Herein, the hole portion formed in the substrate also serves as a through hole by which not only electrical connection but also mechanical settlement are doubly implemented by the use of solder. Further, since the conductor pattern at the other end side is formed on the back surface of the substrate by printing means and the like, thickness of the substrate exists between the plate-shaped conductor at the one end side and the conductor pattern at the other end side. By the existing thickness of the substrate, capacitive coupling components are decreased, so that bandwidth of frequencies that the antenna device is operable can be enlarged. 
     In the antenna device according to the present invention, the one end side and the other end side of the conductor antenna may be located closely to each other through the base body, the open end terminal of the other end portion of the conductor antenna and the base body may be joined to each other, and thereby the conductor antenna may be supportively fixed by the substrate and the base body. 
     By configuring as the above, since the base body is located at a position of the open-end terminal where electric field strength of the U-shaped conductor antenna becomes larger, the antenna device can operate in each wide band and obtain excellent gain and maintain non-directivity of vertically polarized waves. Further, the other end portion of the conductor antenna is also connected on the base body in addition to the one end portion and the folded-back portion of the conductor antenna. Thereby, the conductor antenna can be supportively fixed on the substrate and the base body by the three points. Accordingly, a stable fixed condition can be obtained. At this time, the power feeding portion of the one end side and the open end terminal of the other end side of the conductor antenna can be directly connected, by solders, to the conductor pattern formed on the base body, so that power feeding can be implemented to the conductor pattern. Further, it is also possible that the power feeding portion and the open-end terminal of the conductor antenna are strongly fixed on the conductor pattern by adding binding materials. 
     Further, in the antenna device according to the present invention, the base body may be fixed on the substrate, the open end terminal of the other end side of the conductor antenna and the base body may be independently fixed on the substrate, respectively, in a condition that the open end terminal of the other end side and the base body are separated from each other. At this time, a first conductor pattern is provided on the substrate while a second conductor pattern is formed on the base body. The second conductor pattern and the open-end terminal of the other end side of the conductor antenna are connected to each other through the first conductor pattern. A third conductor pattern is formed on the base body while a fourth conductor pattern is provided on the substrate. Power is fed into the power-feeding portion of the conductor antenna through the third conductor pattern and the fourth conductor pattern. 
     By configuring as the above, different from the above-described structure, the base body and the conductor antenna are fixed to each other in a condition that the base body and the conductor antenna are separated from each other. Therefore, even if one of the base body and the conductor antenna is subjected to an external force, and the like, the one of the base body and the conductor antenna does not transfer the external force, and the like, to another one thereof. Accordingly, the base body and the conductor antenna can be fixed on the substrate in order that the base body and the conductor antenna may not be influenced by each other. 
     In the antenna device according to the present invention, it is desirable that a conductor pattern for adjusting transmitting and receiving frequencies is formed on the base body and/or the substrate. This conductor pattern for adjusting transmitting and receiving frequencies may be formed on a reverse side surface of the substrate opposite to a surface thereof on which the base body is formed. Further, the conductor pattern for adjusting transmitting and receiving frequencies may be provided near the one end side of the conductor antenna. 
     By configuring as the above, an adjustment of frequencies, for example, of GSM band can be implemented by readily chipping this conductor pattern for adjusting transmitting and receiving frequencies. Alternatively, the conductor pattern for adjusting transmitting and receiving frequencies may be provided near the folded-back portion of the conductor antenna. In this case, an adjustment of frequencies, for example, of DCS/PCS/UTMS bands can be implemented by chipping this conductor pattern. Thus, since an adjustment of transmitting and receiving frequencies can be implemented only by chipping the conductor pattern, the adjustment of the frequencies can be readily implemented, after the antenna device has been assembled. 
     Further, it is desirable that the substrate is a sub-substrate connected to a main substrate. By configuring as the above, assembling and production of the antenna device can be implemented separately and independently from a main substrate portions. Accordingly, not only a process management can be treated more easily but also an efficiency of operations can be improved. 
     Moreover, a cable connector may be mounted on the sub-substrate while the base body may be mounted on an end portion of the cable connector side at the longitudinal direction on the sub-substrate. Thereby, in the antenna device according to the present invention, since the base body is located at the end portion of the power feeding side, a shape of the conductor antenna on the substrate is not limited by a shape of the base body. 
     Furthermore, according to the present invention, the antenna device having the configurations described above is embedded in a wireless communication apparatus. Owing to this, it is made possible to save space for an antenna circuit embedded in the wireless communication apparatus and to increase a degree of freedom of arrangement (layout) of the antenna device in the wireless communication apparatus and to achieve the miniaturization of the wireless communication apparatus. 
     EFFECTS OF THE INVENTION 
     According to the present invention, it is made possible to realize a small-sized antenna device which can operate in a wide band (in a plurality of bands) and obtain excellent gain in every band and maintain non-directivity of vertically polarized waves and which also has excellent mechanical strength and reliability. Therefore, when the antenna device is applied to a wireless communication apparatus such as a mobile phone, and the like, space for the embedded antenna circuit can be saved, thus increasing a degree of freedom of arrangement (layout) which facilitate miniaturization of the wireless communication apparatus. Moreover, an adjustment of transmitting and receiving frequencies can be readily implemented. It therefore becomes possible to adjust the transmitting and receiving frequencies more easily in correspondence with an apparatus using the antenna device. Subsequently, it is possible to improve reliability of a wireless communication apparatus such as a mobile phone, and the like. 
    
    
     BEST MODE FOR CARRYING OUT THE INVENTION 
     Referring to the drawings, description will be made about embodiments of the present invention. Besides, the inventions as claimed in CLAIMS will not be limited by the embodiments described hereunder. All of the combined features described in the embodiments are not always required essentially to establish the present invention. 
     Referring to the drawings, a detailed description will be made as regards antenna devices according to embodiments of the present invention. At first, the description is made about a first embodiment of the present invention with reference to  FIGS. 1 through 4 .  FIG. 1  is a diagram showing a basic configuration of an antenna device according to the first embodiment of the present invention.  FIG. 2  is a diagram illustrating an equivalent circuit thereof while  FIG. 3  is a diagram illustrating a detail of the antenna device according to the first embodiment.  FIG. 4  is a diagram for illustrating assembly manners of the antenna device according to the first embodiment. 
     An antenna device  100  comprises a base body  110 , a conductor antenna  120 , a conductor line  130 , a cable connector  131 , and the like, which are mounted on a sub-substrate  140 . In this sub-substrate  140 , attaching portions  140   a ,  140   b  are provided on both ends of longitudinal direction of the sub-substrate. A cable connector  131  is mounted on the side of the attaching portions  140   a  in the sub-substrate  140 . 
     Further, the antenna device  100  comprises a main substrate  150  at a position separated from the sub-substrate  140 . The main substrate  150  is made of glass epoxy resin, or the like, and constitutes a Printed Circuit Board [PCB] embedded in a mobile phone, as will be described later as an wireless communication apparatus according to an embodiment of the present invention. A power feeding port  151  is provided in the main substrate  150 . A coaxial cable  141  is provided between the power feeding port  151  and the cable connector  131 . Connecting portions  141   a ,  141   b  are provided on the coaxial cable  141 . By connecting the connecting portion  141   b  of the coaxial cable  141  to the power feeding port  151  and the connecting portion  141   a  of the coaxial cable  141  to the cable connector  131 , the power feeding port  151  is electrically connected to the conductor line  130 . Power is fed to the conductor antenna  120  through these conducting members. 
     The base body  110  is made, for example, of at least one of dielectric and magnetic materials among insulating materials to form a rectangular solid shape, and is fixed directly on the sub-substrate  140 . An antenna-fixing electrode  111  is provided on an upper surface of the base body  110  while an antenna-fixing electrode  112  is provided on one side surface of the base body  110 . The base body  110  is joined over between an end portion  121   a  of one end side conductor  121  of the conductor antenna  120  and an end portion  122   a  of the other end side conductor  122  of the conductor antenna  120 , as will later be described. Thereby, the end portions  121   a  and  122   a  of the conductors  121  and  122  opposite to each other are capacitively coupled by way of the base body  110 . In other words, a capacitance Cd is interposed between inductances Lan and Lbn. Besides, the end portion  122   a  of the other end side conductor  122  does not need to be joined on the base body but has only to be located closely to the end portion  121   a.    
     The base body  110  is made of ceramics including a dielectric material, such as aluminum, silica, magnesium, and the like and having low loss characteristic at high frequencies. In a case that the dielectric material is used, an antenna characteristic is greatly influenced by a dielectric constant and a dielectric loss. Further, the base body  110  in the first embodiment is fabricated to have a size of 5.5 mm×3 mm×2 mm. 
     Alternatively, the base body  110  may be made of a magnetic material other than the dielectric material. In this case, the material may be hexagonal ferrite, such as z-type, y-type, and the like, called prana, and a complex material including these ferrite materials. However, it is preferable that the material is a ferrite sintering body and in particular that the y-type ferrite is used. Since the ferrite sintering body has a high volume specific resistance, the ferrite sintering body has an advantage for insulating the base body with a conductor. By using the ferrite sintering body having a high volume specific resistance, an insulating cover between the base body and the conductor becomes unnecessary. The Y-type ferrite maintains its magnetic permeability up to high frequencies not less than 1 GHz and has a little magnetic loss in a frequency band up to 1 GHz. The Y-type ferrite sintering body is not limited to a single phase one of Y-type ferrite but may include the other phases of Z-type, W-type, or the like. As regards configuration and size thereof, the base body  110  is made to form a rectangular solid shape, similarly to that of dielectric material. The base body of the ferrite sintering body may be fabricated to have a size, for example, of 5.5 mm×3 mm×2 mm, similarly to that of the dielectric material. 
     Further, electrodes for fixing antenna  111 ,  112  of the base body  110  are formed on a joined surface of the base body  110  with the conductor antenna  120  by screen-printing of electrodes. The electrodes for fixing antenna  111 ,  112  may be joined with the conductor antenna  120  by using a solder. An adhesive may also be used together with the solder for firmer joining. 
     The conductor antenna  120  is formed to be approximately U-shaped by a metal plate. In addition, the conductor antenna  120  is folded at the folded-back portion  124  so that a flat plane of one end side conductor  121  illustrated in a lower side and a flat plane of the other end side conductor  122  illustrated in an upper side opposite to each other may become substantially perpendicular to each other. Subsequently, the end portion  121   a  of one end side conductor  121  becomes a power feeding side to be connected to the power feeding port  151 . On the other hand, the end portion  122   a  of the other end side conductor  122  becomes an open-end terminal side to be connected to a part of the electrode for fixing antenna  111  of the base body  120 . Herein, not the end portion  121   a  but the end portion  122   a  may become the power feeding side. This is similarly applied to the following embodiments. In such a case, the end portion  122   a  is connected to the power feeding port  151  through the electrode for fixing antenna  111 . Further, the end portion  121   a  of the one end side conductor  121  becomes an open-end terminal side. Furthermore, the one end side conductor  121  is separated from the other end side conductor  122 . A belt-shaped space  123  is formed between the one end side conductor  121  and the other end side conductor  122 . Moreover, a part of the end portion  122   a  is folded in the conductor antenna  120  so that the other end side conductor  122 , when the conductor antenna  120  is fixed, may be located in parallel or substantially in parallel to the sub-substrate  140  at a distance more separated than the base body  110  from the view point of the sub-substrate  140 . 
     The folded-back portion  124  comprises a first folded-back portion  124   a  and a second folded-back portion  124   b . The first folded-back portion  124   a  has the same flat surface as that of the one end side conductor  121  and is extending perpendicular toward the other end side conductor  122 . The second folded-back portion  124   b  has the same flat surface as that of the other end side conductor  122  and is extending perpendicular toward the one end side conductor  121 . Both the first and the second folded-back portions  124   a  and  124   b  are joined to each other to make a right angle at a position to which both are made extending respectively. Thus, the one end side conductor plane and the other end side conductor plane of the conductor antenna  120  are made substantially perpendicular to each other. In addition, the end portion  121   a  is joined to the electrode for fixing antenna  112  of the base body  110  while the other end portion  122   a  is joined to the electrode for fixing antenna  111  (However, the other end portion  122   a  may not be joined thereto). Accordingly, among the conductor antennas, the one end side conductor  121  not only exists at a position remote from the ground portion of the main substrate  150  but also is formed to be a conductor plane perpendicular to the ground portion thereof. Capacitive coupling planes can therefore be reduced and then unnecessary capacitive coupling can be reduced. As a result, a bandwidth of the antenna device can be enlarged. 
     The conductors  121  and  122  are capacitively coupled through the space  123 . Namely, capacitances Ca 1 , Ca 2 , . . . , Ca(n−1) are interposed between inductances La 1  and Lb 1 , La 2  and Lb 2 , . . . , Lan and Lbn, respectively. Therefore, the space  123  has such an interval that, at least, capacitive coupling can be considered. Besides, capacitances Cb 1 , Cb 2 , Cb 3 , . . . , Cbn, Cb(n+1) are interposed between the conductor  121  and the ground, the conductor  122  and the ground, respectively. This conductor antenna  120  is made of a metal plate consisting, for example, of a phosphor bronze, a copper,  42  nickel, or the like. However, a gold plating or a silver plating may be applied on a surface of the conductor antenna  120  in order that the conductor antenna  120  may have a large antenna gain and a low loss by making a resistance value thereof be small. 
     The sub-substrate  140  is fixed on a non-illustrated housing by attaching portions  140   a  and  140   b  being screwed in the housing. The sub-substrate  140  is adjusted to be conductive by connecting the attaching portion  140   a  to the ground of the housing. Further, a conductor line  130  and a cable connector  131  are mounted at a side of the attaching portion  140   a  on the sub-substrate  140 . Then, the base body  110  and the conductor antenna  120  will be mounted on the sub-substrate  140 , as mentioned above. 
     The antenna device  100  operates in transmitting and receiving frequency bands each being different from one another. More specifically, a (folded-back) total length portion (¼λ of GSM band) of the conductor antenna  120  operates in a GSM band (900 MHz band), a half length portion (substantially ¼λ of DCS band and PCS band) of the conductor antenna  120  in a DCS band (1700 MHz band) and a PCS band (1800 MHz band), and in an UMTS band (2200 MHz band), thereby achieving the quad-band type antenna device  100 . Thus, the total length portion (¼λ of GSM band) of the conductor antenna  120  has the GSM band as its transmitting and receiving frequency band of frequencies being the lowest band of frequencies. The half length portion (substantially ¼λ of DCS band and PCS band) of the conductor antenna  120  has the DCS band and the PCS band as its two transmitting and receiving frequency bands which are different from each other but are near each other. Moreover, the base body  110  portion including the end portion  121   a  of the one end side conductor  121  and the end portion  122   a  of the other end side conductor  122  of the conductor antenna  120  has the UMTS band as its transmitting and receiving frequency band being higher than those in the DCS/PCS bands. 
     Besides, the conductor antenna  120  according to the first embodiment is made of the metal plate having a thickness of 0.3 mm and consisting of a phosphor bronze, or the like. Further, the gold plating, or the like is applied on the surface of the conductor antenna  120  in order that the conductor antenna  120  may have a large antenna gain and a low loss by making a resistance value thereof be small. The wider a sum of the widths of a width of the one end side conductor  121  and a width of the other end side conductor  122  is, the higher a radiation efficiency of the antenna device is to have a wide band of frequencies. However, if the width is made too large, an area opposite to the ground is too increased. Consequently, a substantial distance becomes near, so that band width (BW) and an antenna gain are decreased in turn. Accordingly, it is desirable that the widths of conductors are adjusted within a range where the band width (BW) does not become too narrow and the antenna gain is not decreased. For example, herein, since the width of the one end side conductor  121  is formed to be narrower than the width of the other end side conductor  122 , the antenna gain becomes high in lower frequency side, such as the GSM band (900 MHz band), and the like. On the other hand, if it is hoped that the antenna gains becomes high in higher frequency side, such as the DCS band (1700 MHz band), the PCS band (1800 MHz band), the UMTS band (2200 MHz band), and the like, the width of the one end side conductor  121  should be formed to be wider than the width of the other end side conductor  122 . Thus, the widths of the one end side conductor  121  and the other end side conductor  122  should be determined so that deflection of the antenna gain may not be produced between the lower frequency side and the higher frequency side. 
     Next, referring to  FIG. 4 , description will proceed to a fixing structure of the conductor antenna. When the antenna device  100  is assembled, at first, the base body  110  is directly fixed on the sub-substrate  140  by soldering through a conductor foil formed on the joined surface of the base body  110 . Notch portions  142   a  and  142   b , that are antenna-fixing portions for fixing the conductor antenna  120  are provided in the sub-substrate  140 . On the other hand, the end portion  121   a  of the conductor antenna  120  is formed as a projecting portion  121   aa  fitting into the notch portion  142   a . Further, a hook portion  124   aa  hooking into the notch portion  142   b  of the sub-substrate side is formed at the lower end side of the first folded-back portion  124   a  of the conductor  121 . 
     Then, the conductor antenna  120  has been attached to the sub-substrate  140  by adjusting and inserting the projecting portion  121   aa  and the hook portion  124   aa  of the conductor antenna  120  into the notch portions  142   a  and  142   b  from the illustrated front side. Further, the projecting portion  121   aa  and the hook portion  124   aa  of the conductor antenna  120  are joined to the notch portions  142   a  and  142   b , respectively, by soldering. Both the one end side and the folded-back portion of the conductor antenna  120  have been fixed on the sub-substrate  140 . Furthermore, in this example, the end portion  122   a  of the other end side conductor  122  is joined by soldering to the electrode for fixing antenna  111  that has already fixed on the base body  110 . The conductor antenna  120  has thereby been fixed on the sub-substrate  140  firmly. Besides, the projecting portion  121   aa  is in a manner that the projecting portion  121   aa  comes into contact with and is joined to the electrode for fixing antenna  112  of the base body  110  and the conductor line  130 , when the projecting portion  121   aa  has been joined to the notch portion  142   a.    
     Thus, not only the conductor antenna  120  is joined to the base body  110  but also the projecting portion  121   aa  and the hook portion  124   aa  are fixed on the sub-substrate  140  in the antenna device  100  according to the first embodiment. The conductor antenna  120  is therefore supported by three points on the sub-substrate  140 . Further, in this example, since the end portion  122   a  of the conductor antenna  120  is fixed on the base body  110 , a load of the conductor antenna  120  is applied on the base body  110 . At this time, since the other two points of the conductor antenna  120  is fixed on the sub-substrate  140 , it can be considered that the other end side conductor  122  of the conductor antenna  120  is a cantilever having the side of the folded-back portion  124  as a fixed end and the end portion  122   a  as a free end. In this case, the end portion  122   a  is folded from the other end side conductor  122  toward the base body  110 . Therefore, the load applied on the base body  110  turns out to be a power pushing the base body  110  downward, namely toward the sub-substrate  140 . In the antenna device  100  according to the first embodiment, the base body  110  and the conductor antenna  120  are thereby fixed stably and firmly so that the base body  110  and the conductor antenna  120  may not easily removed. Mechanical reliability of the antenna device  100  is thus improved. 
     In addition, as illustrated in  FIG. 5 , in the antenna device  100  according to the first embodiment, the electrode for fixing antenna  111  of the base body  110  is in a manner that the electrode for fixing antenna  111  is joined only by a part thereof to the end portion  122   a  of the conductor antenna  120 . With the manner, even if the base body  110  is being fixed on the sub-substrate  140 , a part of the electrode for fixing antenna  111  formed on the base body  110  can be processed, for example, be chipped, and the like, as shown by a broken line in  FIG. 5 . Accordingly, the transmitting and receiving frequencies of the antenna device  100  especially in the GSM band can be adjusted only by chipping the electrode for fixing antenna  111 . 
     Next, referring to  FIGS. 6 through 11 , description is made about a performance of the antenna device  100  according to the first embodiment.  FIG. 6  is a diagram illustrating an antenna characteristic of the antenna device  100  in a GSM band while  FIG. 7  is a diagram illustrating an antenna characteristic of the antenna device  100  in DCS-UMTS bands. Further,  FIGS. 8 through 11  are diagrams illustrating antenna gain directivity characteristics of the antenna device  100  at the central frequency of transmitting band and receiving band in GSM, DCS, PCS, UMTS bands, respectively. 
       FIG. 6(   a ), ( b ), ( c ) show antenna directivity stereoscopically among antenna characteristics of the antenna device according to the first embodiment in the GSM band, and two-dimensionally showing the antenna directivity expressed by curves obtained by plotting the distribution from the central point respectively at cross sections of an XY plane, YZ plane, and ZX plane using the three-dimensional X, Y, and Z axes as a reference axis. Namely, E2-plane shown in  FIG. 6(   a ) is XY plane, E1-plane shown in  FIG. 6(   b ) is YZ plane, and H-plane shown in  FIG. 6(   c ) is ZX plane. 
     These drawings show that, when the distribution expressed by the curve from the central point is the larger from the central point toward a direction of a diameter, the directivity is the higher, that is, the gain is the higher and when the distribution is uniform from the central point toward a direction of a diameter and the curve become a circle the more, a drop in the directivity, that is, in the gain is the less and the more uniform. As the directivity of an antenna to be mounted, for example, on a mobile phone terminal, the antenna directivity on the ZX plane shown in  FIG. 6(   c ) among the cross-sectional planes is important and it is desirable that the gain becomes maximum at the ZX plane and uniform gain and directivity are obtained at the ZX plane. This means that the uniform gain and directivity can be obtained in a direction orthogonal to a plane of the above-described sub-substrate  140 . 
     That is, this means that how much the uniform gain and directivity can be obtained in a circumferential direction relative to the sub-substrate  140 . In the mobile phone terminal, the sub-substrate  140  and a main substrate  150  connected to the sub-substrate  140  for the antenna device is mounted along a longitudinal direction of a cabinet of the thin and long mobile phone terminal and, therefore, how uniform gain and directivity can be obtained in the circumferential direction of the cabinet of the mobile phone terminal is of importance. If the uniform gain and directivity in the circumferential direction of the cabinet of the mobile phone terminal, the directivity can be easily controlled depending on arrangements of metal portions in the cabinet. As a result, uniformity (non-directivity) of directivity of vertically polarized waves on the ZX plane becomes important. Therefore, it is desirable that the distribution expressed by a curve representing directivity of vertically polarized waves in the ZX plane is uniform from a central point toward a direction of a diameter and that the curve become near to a (true) circle. In the data on the ZX plane shown in  FIG. 6(   c ), the curve (Vertical) representing directivity of vertically polarized waves becomes a uniform circle (true circle) at about 0.00. Further, a drop in gain in the illustrated X direction is not observed. It is therefore understood that the uniform directivity and gain can be obtained. 
       FIG. 7(   a ), ( b ), ( c ) show antenna directivity stereoscopically (three-dimensionally) among antenna characteristics of the antenna device  100  according to the first embodiment in the DCS-UMTS bands, similarly to those shown in  FIG. 6(   a ), ( b ), ( c ). In the data on the ZX plane shown in  FIG. 7(   c ), the curve (Vertical) representing directivity of vertically polarized waves substantially becomes a circle. Further, a drop in gain is a little. It is therefore understood that necessary and sufficient directivity and gain for practical use can be obtained. 
       FIG. 8  shows antenna gain and directivity at the center frequencies of transmitting and receiving bands in the GSM band among gain directivities of the antenna device  100  according to the first embodiment. Herein,  FIG. 8(   a ), ( b ), ( c ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in GSM-Tx (center frequency of transmitting band in the GSM band), respectively.  FIG. 8(   d ), ( e ), ( f ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in GSM-Rx (center frequency of receiving band in the GSM band), respectively. Besides, in the first embodiment, the center frequency of the transmitting band in the GSM band is 895.5 MHz while the center frequency of the receiving band in the GSM band is 940.5 MHz. 
     In the data on the H-plane shown in  FIG. 8(   c ), ( f ), the curve (Vertical) representing directivity of vertically polarized waves becomes a uniform circle (true circle) at about 0.00. Further, a drop in gain in the illustrated X direction is not observed. Namely, in the antenna device  100 , it is understood that the uniform directivity and gain can be obtained even in the transmitting and the receiving bands in the GSM band. 
       FIG. 9  shows antenna gain and directivity at the center frequencies of transmitting and receiving bands in the DCS band among gain directivities of the antenna device  100  according to the first embodiment. Herein,  FIG. 9(   a ), ( b ), ( c ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in DCS-Tx (center frequency of transmitting band in the DCS band), respectively.  FIG. 9(   d ), ( e ), ( f ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in DCS-Rx (center frequency of receiving band in the DCS band), respectively. Besides, in the first embodiment, the center frequency of the transmitting band in the DCS band is 1747.5 MHz while the center frequency of the receiving band in the DCS band is 1842.6 MHz. 
     In the data on the H-plane shown in  FIG. 9(   c ), ( f ), the curve (Vertical) representing directivity of vertically polarized waves partially has a so-called null point (point of the drop in gain). However, the curve (Horizontal) representing directivity of horizontally polarized waves compensates for the point. Thereby, both combined Vertical and Horizontal substantially becomes a circle. Further, a drop in gain in the illustrated X direction is a little. Namely, in the antenna device  100 , it is understood that necessary and sufficient directivity and gain for practical use can be obtained even in the transmitting and the receiving bands in the DCS band. 
       FIG. 10  shows antenna gain and directivity at the center frequencies of transmitting and receiving bands in the PCS band among gain directivities of the antenna device  100  according to the first embodiment. Herein,  FIG. 10(   a ), ( b ), ( c ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in PCS-Tx (center frequency of transmitting band in the PCS band), respectively.  FIG. 10(   d ), ( e ), ( f ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in PCS-Rx (center frequency of receiving band in the PCS band), respectively. Besides, in the first embodiment, the center frequency of the transmitting band in the PCS band is 1880 MHz while the center frequency of the receiving band in the PCS band is 1960 MHz. 
     In the data on the H-plane shown in  FIG. 10(   c ), ( f ), the curve (Vertical) representing directivity of vertically polarized waves partially has a null point (point of the drop in gain). However, the curve (Horizontal) representing directivity of horizontally polarized waves compensates for the point. Thereby, both combined Vertical and Horizontal substantially becomes a circle. Further, a drop in gain in the illustrated X direction is a little. Namely, in the antenna device  100 , it is understood that necessary and sufficient directivity and gain for practical use can be obtained even in the transmitting and the receiving bands in the PCS band. 
       FIG. 11  shows antenna gain and directivity at the center frequencies of transmitting and receiving bands in the UMTS band among gain directivities of the antenna device  100  according to the first embodiment. Herein,  FIG. 11(   a ), ( b ), ( c ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in UMTS-Tx (center frequency of transmitting band in the UMTS band), respectively.  FIG. 11(   d ), ( e ), ( f ) show antenna gains and directivities at E2-plane, E1-plane, and H-plane in UMTS-Rx (center frequency of receiving band in the UMTS band), respectively. Besides, in the first embodiment, the center frequency of the transmitting band in the UMTS band is 1950 MHz while the center frequency of the receiving band in the UMTS band is 2140 MHz. 
     In the data on the H-plane shown in  FIG. 11(   c ), ( f ), the curve (Vertical) representing directivity of vertically polarized waves substantially becomes a circle. Further, a drop in gain in the illustrated X direction is a little. Namely, in the antenna device  100 , it is understood that necessary and sufficient directivity and gain for practical use can be obtained even in the transmitting and the receiving bands in the UMTS band. 
     With the constitution for mounting, it becomes possible to keep a distance between the base body  110  or the conductor antenna  120  and the ground of the main substrate  150 . Accordingly, it is possible to realize the antenna device  100  that can operate in wide bands and can achieve an excellent antenna gain by the base body  110  and the conductor antenna  120 . 
     Next, description is made about a second embodiment of the present invention with reference to  FIGS. 12 and 13 .  FIG. 12  is a diagram showing a basic configuration of an antenna device according to a second embodiment of the present invention.  FIG. 13  is a diagram illustrating assembly processes of the antenna device according to the second embodiment. Besides, the second embodiment of the present invention has some portions similar to those of the first embodiment. The similar portions are designated by like reference numerals and of which explanations are omitted. 
     An antenna device  200  comprises a base body  110 , a conductor antenna  220 , a conductor line  230 , and the like, which are mounted on a mounting area  240  provided in a main substrate  250 . The main substrate  250  is made of the same material as that of the main substrate  150  of the first embodiment. A power feeding port  251  and a conductor line  241  are provided in the main substrate  250 . Further, the power feeding port  251  is electrically connected to the conductor line  241  and an antenna-fixing electrode  112 . Power is fed to the conductor antenna  220  through these conducting members. 
     The conductor antenna  220  is formed to be approximately U-shaped by a metal (a phosphor bronze having a thickness of 0.3 mm) thin plate member. In addition, the conductor antenna  220  is folded at a folded-back portion  224  so that a flat plane of one end side conductor  221  illustrated in a lower side and a flat plane of the other end side conductor  222  illustrated in an upper side opposite to each other may become substantially perpendicular to each other. Subsequently, an end portion  221   a  of one end side conductor  221  becomes a power feeding side to be connected to the power feeding port  261 . On the other hand, an end portion  222   a  of the other end side conductor  222  becomes an open-end terminal side to be connected to a part of an electrode for fixing antenna  111  of a base body  220 . Further, the one end side conductor  221  is separated from the other end side conductor  222 . A belt-shaped space  223  is formed between the one end side conductor  221  and the other end side conductor  222 . Moreover, the conductor antenna  220  is formed so that the other end side conductor  222 , when the conductor antenna  220  is fixed, may be located in parallel to the mounting area  240  substantially at the same distance as that of the base body  110  from the view point of the mounting area  240 . 
     The folded-back portion  224  substantially comprises a first folded-back portion  224   a  and a second folded-back portion  224   b . The first folded-back portion  224   a  has the same flat surface as that of the one end side conductor  221  and is extending perpendicular toward the other end side conductor  222 . The second folded-back portion  224   b  has the same flat surface as that of the other end side conductor  222  and is extending perpendicular toward the one end side conductor  221 . Both the first and the second folded-back portions  224   a  and  224   b  are joined to each other to make a right angle at a position to which both are made extending respectively to meet with each other. By such a configuration of the folded-back portion  224 , in the second embodiment, the end portion  221   a  of the conductor antenna  220  can detour from the base body  110  and be joined to the electrode for fixing antenna  112  while the end portion  222   a  can be joined to the electrode for fixing antenna  111 . 
       FIG. 13  is a diagram for explaining assembly processes of the antenna device  200  according to the second embodiment. When the antenna device  200  is assembled, at first, the base body  110  is directly fixed on the mounting area  240  and then the conductor antenna  220  is fixed thereon. Antenna-fixing holes  242   aa ,  242   ab ,  242   b  each constituted by a through hole for fixing the conductor antenna  220  are provided in the mounting area  240 . On the other hand, projecting portions  221   aa ,  221   ab  fitting into the antenna-fixing holes  242   aa ,  242   ab  are provided in a head portion of the end portion  221   a  of the conductor antenna  220 . Further, a projecting portion  224   aa  is provided in a portion of the conductor antenna  220  in which both the one end side conductor  221  and the first folded-back portion  224   a  are folded back toward an illustrated lower end. The projecting portion  224   aa  is fitted into the antenna-fixing hole  242   b.    
     Then, the conductor antenna  220  has been attached to the mounting area  240  by adjusting and inserting the projecting portions  221   aa ,  221   ab ,  224   aa  of the conductor antenna  220  into the antenna-fixing holes  242   aa ,  242   ab ,  242   b  from the illustrated upper side. Further, the projecting portions  221   aa ,  221   ab ,  224   aa  of the conductor antenna  220  are joined to the antenna-fixing holes  242   aa ,  242   ab ,  242   b , respectively, by soldering. Furthermore, the end portion  222   a  is joined by soldering to the electrode for fixing antenna  111  that has already fixed on the base body  110 . The conductor antenna  220  has thereby been fixed on the mounting area  240 . Besides, the projecting portion  221   aa  is in a manner that the projecting portion  221   aa  comes into contact with and is joined to the electrode for fixing antenna  112  of the base body  110  and the conductor line  241 , when the projecting portion  221   aa  has been joined to the antenna-fixing hole  242   aa.    
     Thus, in the antenna device  200  according to the second embodiment, not only one end side of the conductor antenna  220  is joined to the base body  110  but also the conductor antenna  220  is fixed on the mounting area  240  by four points of the projecting portions  221   aa ,  221   ab ,  224   aa , and the end portion  222   a . The conductor antenna  220  is therefore supported by the four points on the mounting area  240 . 
     Further, since the end portion  222   a  of the conductor antenna  220  is fixed on the base body  110  that has been directly fixed on the mounting area  240 , a load of the conductor antenna  220  is applied on the base body  110 . At this time, in the conductor antenna  220 , the projecting portion  224   aa  is fixed on and supported by the mounting area  240 , the conductor  222  is fixed so that the conductor  222  may become parallel to the mounting area  240  with being separated from the mounting area  240  by substantially the same distance as that from the mounting area  240  to the electrode for fixing antenna  111 . Consequently, it can be considered that the other end side conductor  222  is a both ends support beam supported by both the base body  110  and the projecting portion  224   aa . Therefore, the load applied onto the base body  110  from the other end side conductor  222 , that acts in a direction for tearing the base body  110  off, turns out to be distributed by the projecting portion  224   aa . As a result, the load applied onto the base body  110  is reduced to be approximately a half thereof. 
     In addition, in the antenna device  200  according to the second embodiment, a pattern for adjusting transmitting and receiving frequencies  243  (shown by a dotted line) is provided on a back surface of the mounting area  240 , that is reverse to the surface on which the base body  110 , and the like were mounted. The pattern for adjusting transmitting and receiving frequencies  243  is connected to the projecting portion  224   aa  through an antenna-fixing portion  242   b . Accordingly, the transmitting and receiving frequencies of the antenna device  200  especially in the DCS/PCS/UMTS bands can be adjusted only by chipping a part of the pattern for adjusting transmitting and receiving frequencies  243 . 
     Accordingly, with the constitution thus mentioned, the antenna device  200  according to the second embodiment can obtain advantageous effects similar to those of the antenna device  100  according to the first embodiment. 
     Next, description is made about a third embodiment of the present invention with reference to  FIGS. 14 and 15 .  FIG. 14  is a diagram showing a basic configuration of an antenna device according to a third embodiment of the present invention.  FIG. 15  is a diagram illustrating assembly processes of the antenna device according to the third embodiment. Besides, the third embodiment of the present invention has some portions similar to those of the first and the second embodiments. The similar portions are designated by like reference numerals and of which explanations are omitted. 
     An antenna device  300  comprises a base body  110 , a conductor antenna  320 , a conductor line  341 , and the like, which are mounted on a mounting area  340  provided in a main substrate  350 . The main substrate  350  is made of the same material as that of the main substrate  150  of the first embodiment. A power feeding port  351  and the conductor line  341  are provided in the main substrate  350 . Power is fed to the conductor antenna  320  from the power feeding port  351  through the conductor line  341 . 
       FIG. 15  is a diagram for explaining the assembly processes of the antenna device  300  according to the third embodiment. In the antenna device  300 , notch portions  342   aa ,  342   ab ,  342   b  each for fixing the conductor antenna  320  are provided in the mounting area  340 . On the other hand, projecting portions  321   aa ,  321   ab  fitting into the notch portions  342   aa ,  342   ab  are provided in a head portion of the end portion  321   a  of the conductor antenna  320 . Further, a projecting portion  324   aa  is provided in a portion of the conductor antenna  320  in which both the one end side conductor  321  and the first folded-back portion  324   a  are folded back toward an illustrated lower end. 
     In the conductor antenna  320  of the antenna device  300 , the notch portions  342   aa ,  342   ab ,  342   b  are formed by notches, so that the conductor antenna  320  can be attached to the mounting area  340  only by fitting the projecting portions  321   aa ,  321   ab ,  324   aa  of the conductor antenna  320  into the notches. Therefore, the conductor antenna  320  can be attached to the mounting area  340  by inserting the projecting portions  321   aa ,  321   ab ,  324   aa  into the notches from the illustrated front side or the illustrated upper side. Accordingly, in the antenna device  300 , it is possible to select a direction from which the conductor antenna  320  is attached to the mounting area  340 . Namely, the conductor antenna  320  can be attached from the direction that is easier for attaching. The conductor antenna  320  is then attached to the mounting area  340  in the same manner as that of the second embodiment. 
     In addition, in the antenna device  300  according to the third embodiment, a pattern for adjusting transmitting and receiving frequencies  343  is provided on a back surface of the mounting area  340 , that is reverse to the surface on which the base body  110 , and the like were mounted. The pattern for adjusting transmitting and receiving frequencies  343  is connected to the projecting portions  321   aa ,  321   ab  through the notch portions  342   aa ,  342   ab . Accordingly, the transmitting and receiving frequencies of the antenna device  300  especially in the GSM band can be adjusted only by chipping a part of the pattern for adjusting transmitting and receiving frequencies  343 . 
     Accordingly, with the constitution thus mentioned, the antenna device  300  according to the third embodiment can obtain advantageous effects similar to those of the antenna device  100  according to the first embodiment. 
     Next, description is made about a fourth embodiment of the present invention with reference to  FIGS. 16 and 17 .  FIG. 16  is a diagram showing a basic configuration of an antenna device according to a fourth embodiment of the present invention.  FIG. 17  is a diagram illustrating assembly processes of the antenna device according to the fourth embodiment. Besides, the fourth embodiment of the present invention has some portions similar to those of the above-described embodiments. The similar portions are designated by like reference numerals and of which explanations are omitted. 
     An antenna device  400  comprises a base body  110 , a conductor antenna  420 , a conductor pattern  443 , and the like, which are mounted on a sub-substrate  440 . Herein, the same one as the sub-substrate  140  of the first embodiment can be used as the sub-substrate  440 . However, the conductor line, the cable connector, and the attaching portions in the both end portions are omitted in the sub-substrate  440 . Further, a material and a constitution similar to those of the main substrate of the embodiment mentioned above can be used for the main substrate of the fourth embodiment. Then, from the power feeding port at the main substrate side is electrically connected up to the conductor line at the sub-substrate side. Power is fed to the conductor antenna  420  through these conductive members. 
     In this embodiment, the conductor antenna  420  comprises one end side conductor  421  formed by a metal (a phosphor bronze having a thickness of 0.3 mm) thin plate member, and the other end side conductor  422  constituted by a conductor pattern  443  (shown by alternate long and short dash line) made of a metal foil (copper) and formed on a back surface of the sub-substrate by printing, and the like. A folded-back portion  424  of the one end side conductor  421  and the conductor pattern  443  are connected to each other to produce an approximately U-shaped conductor antenna  420 . Then, a flat plane of the one end side conductor  421  and a flat plane of the other end side conductor  422  become substantially perpendicular to each other. Subsequently, the end portion  421   a  of the one end side conductor  421  becomes a power feeding side to be connected to a power feeding port (not shown). On the other hand, the end portion  422   a  of the other end side conductor pattern  443  becomes an open-end terminal side. Further, the one end side conductor  421  is separated from the other end side conductor  422  by way of the sub-substrate. A belt-shaped space  423  is formed between the one end side conductor  421  and the other end side conductor  422 . Besides, an alternative embodiment, and the like can be employed. In the alternative embodiment, the belt-shaped space  423  is enlarged, and then a folded-back portion is formed in a head projecting portion  421   aa  of the one end side conductor  421 , an another conductor extending within the enlarged belt-shaped space  423  is further constituted. 
     When the antenna device  400  is assembled, at first, the base body  110  is directly fixed on a predetermined position of the sub-substrate  440  by soldering, and the like. An antenna-fixing hole  442   b  constituted by a through hole is provided in an end portion of the longitudinal direction of the sub-substrate  440 . On a back surface following to the through hole fixing hole  442   b , a conductor pattern  443  made of a copper foil, and the like is formed by printing, or the like. On the other hand, a projecting portions  421   aa  is provided in a head portion of the end portion  421   a  of the conductor antenna  420 . Further, a projecting portion  424   aa  is formed in an end portion  424   a  of a folded-back portion of the other end side. Accordingly, the projecting portion  424   aa  of one end side conductor  421  is adjusted and inserted into the antenna-fixing hole  442   b . The projecting portion  424   aa  is then connected to the conductor pattern  443  and thereafter joined to the conductor pattern  443  by soldering. At that time or after that time, another projecting portion  421   aa  and a part of the end portion  421   a  are connected to the antenna-fixing electrodes  112 ,  113  and then joined to the antenna-fixing electrodes  112 ,  113  by soldering. The conductor antenna  420  comprises one end side conductor  421  and the other end side conductor  422  to be approximately U-shaped. Thereby, the conductor antenna  420  is attached and joined to both the base body  110  and the sub-substrate  440 . Besides, a fixing hole into which the projecting portion  421   aa  of the one end side conductor  421  is inserted may be provided in the sub-substrate, so that the one end side conductor  421  may also be fitted into and fixed to the sub-substrate. 
     With the constitution thus mentioned, the antenna device  400  according to the fourth embodiment can obtain advantageous effects similar to those of the antenna device  100  according to the first embodiment. 
     Next, description is made about a fifth embodiment of the present invention with reference to  FIGS. 18 and 19 .  FIG. 18  is a diagram showing a basic configuration of an antenna device according to a fifth embodiment of the present invention.  FIG. 19  is a diagram illustrating assembly processes of the antenna device according to the fifth embodiment. Besides, the fifth embodiment of the present invention has some portions similar to those of the above-described embodiments. The similar portions are designated by like reference numerals and of which explanations are omitted. 
     An antenna device  500  comprises a base body  110 , a conductor antenna  520 , a conductor line  530 , and the like, which are mounted on a sub-substrate  540 . The sub-substrate  540  is provided at a position separated from a main substrate (not shown), similarly to that of the first embodiment. In this sub-substrate  540 , attaching portions  140   a ,  140   b  are provided on both ends of longitudinal direction of the sub-substrate  540 . A cable connector  531  is mounted on the side of the attaching portion  140   a  in the sub-substrate  540 . The cable connector  531  of the sub-substrate  540  is connected to the separated main substrate by the coaxial cable  141 . 
     In this embodiment, an antenna electrode (a second conductor pattern)  511  is formed from an upper surface of the base body  110  to one side surface of the base body  110 . A power feeding side electrode (a third conductor pattern)  512  is also formed in the one side surface of the base body  110 . Further, the antenna electrode (a second conductor pattern)  511  is joined to an open-end terminal  522   a  of an end of the other end side conductor  522  of a conductor antenna  520 , as will later be described, through a joining line (a first conductor pattern)  533 . The power feeding side electrode (a third conductor pattern)  512  is joined to a power feeding portion  521   a  of an end of one end side conductor  521  of the conductor antenna  520  through a power feeding line (a fourth conductor pattern)  532 . With these constitutions, the base body  110  is adjusted to be existing between the antenna electrode (a second conductor pattern)  511  and the power feeding side electrode (a third conductor pattern)  512 , where the antenna electrode (a second conductor pattern)  511  is connected to the open-end terminal  522   a  through the joining line (a first conductor pattern)  533  and where the power feeding side electrode (a third conductor pattern)  512  is connected to the power feeding portion  521   a  through the power feeding line (a fourth conductor pattern)  532 . Consequently, the end portion of the one end side conductor  521  is capacitively coupled to the end portion of the other end side conductor  522  through the base body  110 . 
     The conductor antenna  520  is folded at a folded-back portion  524  so that a flat plane of one end side conductor  521  and a flat plane of the other end side conductor  522  may become substantially perpendicular to each other. The conductor antenna  520  is thereby formed to be approximately U-shaped, similarly to that of the first embodiment. Subsequently, an end portion  521   a  of one end side conductor  521  becomes a power feeding side to be connected to the power feeding port by way of the power feeding line (a fourth conductor pattern)  532 , the power feeding side electrode (a third conductor pattern)  512 , the conductor line  530 , and the cable connector  531 . On the other hand, an end portion  522   a  of the other end side conductor  522  becomes an open-end terminal side to be connected to the antenna electrode (a second conductor pattern)  511  on the base body  110  by way of the joining line (a first conductor pattern)  533 . 
     When the antenna device  500  is assembled, at first, the base body  110  is directly fixed on a predetermined position of the sub-substrate  540  by soldering, and the like. Further, the conductor antenna  520  is fixed on the sub-substrate  540  by soldering in a manner that the conductor antenna  520  is not in contact with the base body  110 . In the sub-substrate  540 , notch portions  542   a ,  542   b  and a fixing hole  543  each of which is for use in fixing the conductor antenna  520 . The end portion  521   a  of the one end side conductor  521  is formed as a projecting portion  521   aa  fitting into the notch portion  542   a . A hook portion  624   aa  positioned in a lower end side of the first folded-back portion  524   a  is adjusted to come into contact with the notch portion  542   b . Further, the end portion  522   a  of the other end side conductor  522  is adjusted to be inserted into the fixing hole  543 . 
     With the constitution mentioned above, the projecting portion  521   aa , the hook portion  524   aa  are positioned to be corresponding with the notch portions  542   a ,  542   b  and then inserted into the notch portions  542   a ,  542   b , respectively. In addition, the end portion  522   a  is fitted into the fixing hole  543 . The conductor antenna  520  is thereby attached on the sub-substrate  540 . At that time or after that time, the projecting portion  521   aa , the hook portion  524   aa  of the conductor antenna  520  are joined to the notch portions  542   a ,  542   b  by soldering, respectively. In addition, the end portion  522   a  is joined to the fixing hole  543  by soldering. The conductor antenna  520  is thereby fixed on the sub-substrate  540 . Besides, the projecting portion  521   aa  is in a manner that the projecting portion  521   aa  comes into contact with the power feeding line  532 , when the projecting portion  521   aa  has been joined to the notch portion  542   a . Similarly, the end portion  522   a  of the other end side conductor  522  is in a manner that the end portion  522   a  comes into contact with the joining line  533 , when the end portion  522   a  is joined to the fixing hole  543 . 
     The antenna device  500  according to the fifth embodiment can obtain advantageous effects similar to those of the antenna device  100  according to the first embodiment. Further, since the base body  110  and the conductor antenna  520  are fixed on the sub-substrate  540  independently from each other, the base body  110  and the conductor antenna  520  are in a manner that the base body  110  and the conductor antenna  520  are not dynamically influenced from each other. With the manner, an external force applied on the base body  110  is not transferred to the conductor antenna  520  while, on the contrary, an external force applied on the conductor antenna  520  is not transferred to the base body  110 . Further, the base body  110  is directly fixed on the sub-substrate  540 . In addition, the conductor antenna  520  is fixed on the sub-substrate  540  by the projecting portion  521   aa , the hook portion  524   aa , and the end portion  522   a . The conductor antenna  520  is therefore supported by three points on the sub-substrate  540 . Furthermore, in the antenna device  500 , since the base body  110  and the conductor antenna  520  are mounted on the sub-substrate  540  independently from each other. It is therefore possible to freely alternate the order of the base body  110  and the conductor antenna  520  in mounting on the sub-substrate  540  in order to facilitate the mounting thereof. Consequently, assembly of the antenna device becomes easy. Thereby, it becomes possible to improve production efficiency of the antenna device. 
     Next, description is made about a sixth embodiment of the present invention with reference to  FIG. 20 .  FIG. 20  is a diagram showing a base body that is a characterized portion of an antenna device according to a sixth embodiment of the present invention. Besides, the sixth embodiment of the present invention has constitutions substantially similar to those of the first through the fifth embodiments except that the base body is different from those of the first through the fifth embodiments. Accordingly, the similar portions are designated by like reference numerals and of which explanations are omitted. 
     In the antenna device  600  according to the sixth embodiment, a pattern for adjusting transmitting and receiving frequencies  643  is provided on the base body  610 . Herein, in  FIG. 20(   a ), the pattern for adjusting transmitting and receiving frequencies  643  is provided from an upper surface of the base body  610  to one side surface of the base body  610 . The pattern for adjusting transmitting and receiving frequencies  643  is extending on the upper surface of the base body  610  from one side thereof at which the other end portion  122   a  of the conductor antenna is joined to the another side thereof. The pattern for adjusting transmitting and receiving frequencies  643  is then folded-back at the another side toward the one side surface of the base body  610 . The pattern for adjusting transmitting and receiving frequencies  643  is thereafter extending toward an end portion of the one side surface of the base body  610 . Thus, the pattern for adjusting transmitting and receiving frequencies  643  is extended as long as possible on the base body  610 . 
     In  FIG. 20(   b ), illustrated is an another example of the base body. Herein, the pattern for adjusting transmitting and receiving frequencies  643 ′ is provided from an upper surface of the base body  610 ′ to one side surface of the base body  610 ′. The pattern for adjusting transmitting and receiving frequencies  643 ′ is folded at a central portion of the upper surface of the base body  610 ′ toward the one side surface of the base body  610 ′. Thereafter, the pattern for adjusting transmitting and receiving frequencies  643 ′ is extending toward the other end side of the one side surface of the base body  610 ′. Consequently, in the base body  610 ′, the pattern for adjusting transmitting and receiving frequencies  643 ′ is extended on two surfaces of the base body  610 ′ in the same direction as each other of the two surfaces. Furthermore, the transmitting and receiving frequencies of the antenna device  600  especially in the GSM band can be adjusted by chipping a part of these patterns for adjusting transmitting and receiving frequencies  643  and  643 ′. 
     As explained above, according to the antenna devices of the above embodiments of the present invention, it is made possible to realize an embedded antenna device which can operate in a wide band (quad-band) including GSM band, DCS/PCS bands, and UMTS band, and obtain excellent antenna gain in every band and maintain non-directivity of vertically polarized waves in a space-saving manner. Further, as structural features, the antenna device can be made small in size as a whole, and have a higher degree of freedom of design by adding an insulating base body of a ceramic dielectric body, a ceramic magnetic body, or the like for enabling miniaturization of the antenna device to an approximately U-shaped conductor antenna consisting, for example, of a metal plate having a high degree of freedom of configuration. Further, the antenna device can operate in a plurality of bands by adding one ceramic dielectric body or one ceramic magnetic body to the conductor antenna consisting of one metal plate. It therefore becomes unnecessary that antennas are provided for the bands different from each other per each band. Thereby, saving space can be achieved. 
     Further, since the base body of a ceramic dielectric body or a ceramic magnetic body is not added between a radiation electrode and a ground conductor but added at a position of the conductor antenna of the metal plate having the folded-back portion (between a head of the metal plate and a near portion of the power feeding portion) where electric field strength between electrodes becomes larger, the antenna device can operate in plenty of frequencies and in a wide band. Further, the metal plate conductor antenna has a constitution that the metal plate conductor antenna is perpendicular to the ground conductor or has many portions perpendicular to the ground conductor. As a result, electrostatic capacity between the metal plate conductor antenna and the ground conductor is reduced. Thereby, the antenna device of the embodiments of the present invention can have an improved radiation efficiency and operate in a wider band. Further, as a functional feature, the antenna device of the embodiments of the present invention can have a band width twice as large as that of an antenna consisting only of a dielectric body. Therefore, antenna gain can be further improved. Furthermore, an advantageous effect of abbreviating wave length can be obtained by adding the base body of a ceramic dielectric body or a ceramic magnetic body. Especially, a dielectric constant can be large by the use of the ceramic dielectric body. Thereby, influence from the other bands can be reduced, so that confusion of directivity or deterioration of VSWR can be prevented from being caused to occur. 
     Further, since the antenna device of the embodiments of the present invention can have a dielectric constant larger than those of a generally used metal plate antenna and an antenna of such a type that a conductor foil is adhered on a resin, the ceramic dielectric body of the antenna device of the embodiments of the present invention can be small in size. Thereby, effective electrostatic capacity between the metal plate conductor antenna and the ground conductor is reduced. Thereby, the antenna device of the embodiments of the present invention can have an improved radiation efficiency and operate in a wider band. Further, since an effective distance between the metal plate conductor antenna and noise sources can also be reduced, a signal to noise ratio (S/N) is improved. Furthermore, since the metal plate conductor antenna having a certain thickness and a certain width is provided, radiation efficiency of electric waves can be improved. Moreover, a plurality of resonant frequencies can be controlled by adjusting a length of the folded-back conductor antenna and by selecting the dielectric constant of the ceramic dielectric body or a position that the ceramic dielectric body is located. Of course, similar advantageous effects can be obtained in the approximately U-shaped antenna of the present invention, even if the approximately U-shaped antenna is not made of a metal plate. However, when the approximately U-shaped antenna is made of a metal plate, the antenna device can have a comparatively higher degree of freedom of configuration. Accordingly, since the antenna device can be constituted at a low cost, it is favorable that the approximately U-shaped antenna is made of a metal plate. 
     Further, in the antenna device according to the above embodiments, the base body is directly fixed on a substrate, and then a conductor antenna joined to the base body is also fixed on the substrate. Consequently, the conductor antenna is supported by a plurality of points on the substrate. A load of the conductor antenna acting on the base body can be distributed. Furthermore, when constituted so, such a load as pushing the base body itself onto the substrate can be acted on the base body from the conductor antenna. Consequently, since the conductor antenna is supported by a plurality of points on the substrate, the conductor antenna can be fixed on the substrate with maintaining its stability. It therefore becomes possible to use a conductor antenna having a larger length. On the other hand, the base body directly fixed on the substrate can be released from a stress that is acted by the joined conductor antenna and acting on the base body in the direction of detaching the base body from the substrate. The base body can thereby be fixed on the substrate with maintaining its stability. Accordingly, the antenna device can be prevented from being damaged due to detachment of the base body, and the like. It becomes possible to maintain mechanical reliability of the antenna device. 
     In the antenna device according to the above embodiments, the conductor antenna is directly supplied with power from the conductor line. However, embodiments of the present invention are not limited to such a manner. For example, let a conductor pattern be provided on the base body, and then the conductor pattern be connected to the conductor line. Thus, power may be fed to the end portion of the conductor antenna through the conductor pattern on the base body. Further, a sub-substrate is fixed in a housing in the first embodiment of the present invention. A sub-substrate may be fixed in a main substrate in the present invention. 
     POSSIBILITY OF INDUSTRIAL USE 
     The present invention can be widely applied, as an antenna, not only to a mobile phone but also various wireless communication apparatuses including a GPS (Global Positioning System), wireless LAN, or the like. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     [ FIG. 1 ] is a diagram showing a basic configuration of an antenna device according to a first embodiment of the present invention. 
     [ FIG. 2 ] is a diagram illustrating an equivalent circuit of the antenna device shown in  FIG. 1 . 
     [ FIG. 3 ] is a diagram illustrating a detail of the antenna device shown in  FIG. 1 . 
     [ FIG. 4 ] is a diagram illustrating assembly processes of the antenna device shown in  FIG. 1 . 
     [ FIG. 5 ] is a diagram for explaining a method of adjusting transmitting and receiving frequencies of the antenna device shown in  FIG. 1 . 
     [ FIG. 6 ] is a diagram illustrating an antenna characteristic of the antenna device shown in  FIG. 1  in a GSM band. 
     [ FIG. 7 ] is a diagram illustrating an antenna characteristic of the antenna device shown in  FIG. 1  in DCS-UMTS bands. 
     [ FIG. 8 ] is a diagram illustrating an antenna gain directivity characteristic of the antenna device shown in  FIG. 1  in a GSM band. 
     [ FIG. 9 ] is an another diagram illustrating an antenna gain directivity characteristic of the antenna device shown in  FIG. 1  in a DCS band. 
     [ FIG. 10 ] is a yet another diagram illustrating an antenna gain directivity characteristic of the antenna device shown in  FIG. 1  in a PCS band. 
     [ FIG. 11 ] is a still another diagram illustrating an antenna characteristic of the antenna device shown in  FIG. 1  in a UMTS band. 
     [ FIG. 12 ] is a diagram showing a basic configuration of an antenna device according to a second embodiment of the present invention. 
     [ FIG. 13 ] is a diagram illustrating assembly processes of the antenna device shown in  FIG. 12 . 
     [ FIG. 14 ] is a diagram showing a basic configuration of an antenna device according to a third embodiment of the present invention. 
     [ FIG. 15 ] is a diagram illustrating assembly processes of the antenna device shown in  FIG. 14 . 
     [ FIG. 16 ] is a diagram showing a basic configuration of an antenna device according to a fourth embodiment of the present invention. 
     [ FIG. 17 ] is a diagram illustrating assembly processes of the antenna device shown in  FIG. 16 . 
     [ FIG. 18 ] is a diagram showing a basic configuration of an antenna device according to a fifth embodiment of the present invention. 
     [ FIG. 19 ] is a diagram illustrating assembly processes of the antenna device shown in  FIG. 18 . 
     [ FIG. 20 ] is a diagram showing a sixth embodiment of the present invention. 
     DESCRIPTION OF THE REFERENCE NUMERALS 
       100 ,  200 ,  300 ,  400 ,  500 ,  600 : antenna device,  110 ,  410 ,  610 : base body,  111 ,  112 : electrode for fixing antenna,  120 ,  210 ,  320 ,  420 ,  520 : conductor antenna,  121 ,  221 ,  321 ,  421 ,  521 : conductor of one end side,  122 ,  222 ,  322 ,  422 ,  522 : conductor of the other end side,  121   a ,  122   a ,  221   a ,  222   a ,  321   a ,  322   a ,  421   a ,  422   a ,  521   a ,  522   a : end portion,  121   aa ,  221   aa ,  221   ab ,  224   aa ,  321   aa ,  321   ab ,  324   aa ,  424   aa ,  521   aa : projecting portion,  124   aa ,  324   aa ,  524   aa : hook portion,  123 ,  223 ,  323 ,  423 : space,  124 ,  224 ,  324 ,  524 : folded-back portion,  124   a ,  224   a ,  324   a ,  524   a : first folded-back portion,  124   b ,  224   b ,  324   b : second folded-back portion,  130 ,  241 ,  341 ,  530 : conductor line,  131 : cable connector,  140 ,  440 ,  540 : sub-substrate,  140   a ,  140   b : attaching portion,  141 : coaxial cable,  141   a ,  141   b : connecting portion,  142   a ,  142   b ,  242   aa ,  242   ab ,  242   b ,  342   aa ,  342   ab ,  342   b ,  542   a ,  542   b : notch portion,  150 ,  250 ,  350 : main substrate,  151 ,  251 ,  351 : electric power feeding port,  221   aa ,  221   ab ,  224   aa ,  321   aa ,  321   ab ,  324   aa : hook-projecting portion,  240 ,  340 : mounting area,  243 ,  343 ,  643 : pattern for adjusting transmitting and receiving frequencies,  443 : conductor pattern,  543 : fixing hole,  533 : line for joining first conductor pattern),  511 : antenna electrode (second conductor pattern),  512 : power feeding side electrode (third conductor pattern),  532 : line for power feeding (fourth conductor pattern)