JP3367218B2 - Antenna device for portable radio - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna device used in a portable radio such as a cordless telephone or a personal handyphone system.

[0002]

2. Description of the Related Art Handy type wireless telephones, which are applicable to wireless telephone systems that are expected to make rapid progress among portable wireless devices, require smaller and lighter devices than ever before. There is also a demand for improved performance, ease of handling and convenience. In addition, when using a wireless telephone, it is always required to ensure a certain level of performance or more. Especially, since the wireless telephone system is a bidirectional communication means, it is necessary to always be able to receive a calling signal from the other party. From
As a handy type wireless telephone antenna device,
An ungrounded antenna or an antenna close to it is required to keep the reception sensitivity above a certain level regardless of whether it is used or not.

For this reason, as an early handheld type antenna device for wireless telephones, in order to always secure a receiving sensitivity above a certain level, an antenna element is always projected and fixed outside the main body of the wireless telephone. Had been used. However, in such a configuration, the antenna element projects from the main body even when the wireless telephone is not used, which is an obstacle when carrying the wireless telephone. Therefore, considering the convenience of handling, it is preferable that the antenna element can be housed in the wireless telephone body when not in use.

However, if the antenna element is simply housed in the main body of the radio telephone, all of the three major elements of the antenna, that is, the gain, the directivity, and the impedance are significantly reduced, so that the calling signal from the other party is transmitted. There is a risk that you will not be able to receive it. In order to solve such a problem, as shown in FIG. 14, an antenna element is a main external antenna that can be pulled out and stored in the main body of the wireless telephone, and the antenna is stored in the main body of the wireless telephone in advance, and the external antenna is stored in the main body of the wireless telephone. There has been proposed an antenna device configured with an internal antenna so that a receiving sensitivity higher than a certain level can be obtained even in such a state.

FIG. 14 is a block diagram showing an antenna device in a conventional handy type wireless telephone having a movable external antenna and a fixed built-in antenna. In the figure, reference numeral 100 denotes a portable radio telephone main body, 101 denotes a linear antenna, and the radio telephone main body 100 can be pulled out and stored. Reference numeral 102 denotes a built-in antenna built in the wireless telephone main body 100.
It is arranged perpendicular to 1. 103 is a power supply line 104
Power from the linear antenna 101 or the built-in antenna 10
It is a minute changeover switch for switching to any of the two.

Next, the operation of the antenna device configured as described above will be described. Since the linear antenna 101 is configured to obtain a desired gain, directivity and impedance when the telephone is used, that is, when the linear antenna 101 is extended, in this case, the minute changeover switch 10 is used.
3 is closed on the side of the linear antenna 101 to supply power. Further, when the telephone is not used, that is, when the linear antenna 101 is housed, the gain, directivity and impedance of the linear antenna 101 are lowered, and desired performance cannot be obtained. Therefore, the minute changeover switch 103 is closed to the built-in antenna 102 side. As a result, it is possible to always secure a receiving sensitivity above a certain level.

With the above-mentioned structure, even in a two-way communication system such as a wireless telephone, when the telephone is not in use, the external antenna can be housed so that it can be carried in a compact state and the calling signal from the other party can be transmitted. Can always be received. FIG. 15 shows another conventional technique and is a configuration diagram showing a diversity antenna device such as a mobile phone. In the figure, 201 is a linear antenna that can be pulled out and stored in the telephone body, and 20
2 is an inverted F antenna built in the main body of the wireless telephone, 203
Is the substrate. Reference numeral 204 is a coaxial cable, 205 is a high frequency circuit, 206 is a coaxial connector, and 207 is a linear antenna holder.

Next, the operation will be described. The linear antenna 201 mainly has vertical polarization (Z-axis direction), and the inverted F antenna 202 mainly has horizontal polarization (Y-axis direction). Generally, in mobile communication, the base station transmits vertically polarized waves, but in urban areas and indoors, the plane of polarization changes variously due to multiple reflections from walls, roads, trees, etc. of buildings. In addition, the mobile station side may also tilt and use the moving body itself during a call, so that the receiving antenna also has an angle. Therefore, the received polarized waves on the mobile station side are also received at various angles. As a result, there are both possibilities of strong vertical polarization and strong horizontal polarization of the received wave depending on the propagation path.

Utilizing this property, by arranging an antenna sensitive to vertical polarization and an antenna sensitive to horizontal polarization on the mobile station side as described above, the effect of polarization diversity can be obtained. it can. Linear antenna 201
Requires the linear antenna holder 207 so that the antenna is electrically connected to the power supply line when the antenna is extended and stored and the linear antenna 201 is fixed. The power supply between the linear antenna holder 207 and the substrate 203 is
It is performed by the coaxial cable 204 and the coaxial connector 206. Similarly, the power feeding between the inverted F antenna 202 and the substrate 203 is also performed by the coaxial cable 204 and the coaxial connector 206.

[0010]

Since the conventional antenna device for a portable wireless device is configured as described above, the first prior art is concerned with the minute changeover switch 103 for switching between the external antenna and the built-in antenna, and Since a mechanism for switching the minute changeover switch 103 is required, there is a problem that the entire radio becomes large and complicated. In addition, if the mechanical minute changeover switch 103 is interposed in the ultra-high frequency transmission line, even if the switch is opened, the loss during that period only increases and the current may continue to flow, making it difficult to obtain a sufficient performance guarantee. It has an essential defect.

For this reason, it is difficult to make a complete switch, and since it is a mechanical switch, the guaranteed number of uses of the switch is only about 5,000 times at the most, and there is a problem that it is not reliable in long-term use. A high-frequency switch may be used instead of such a mechanical switch, but in such a case, there is a problem that the configuration becomes complicated as compared with the mechanical switch. Further, there is a problem that efficiency is poor because only one of the external antenna and the built-in antenna is used when the external antenna is pulled out and stored.

Further, since the antenna element as a whole has a structure which operates only when the external antenna is completely pulled out or completely housed, the use of the radio even in a place where the radio wave condition is good or the eyes are distracting. Sometimes there was a problem that the external antenna had to be pulled out completely. In addition, the second conventional technique has a problem in that a feeding line is required for each antenna, and it takes time to process and attach the antenna. Further, since the structure is complicated, the mutual coupling between the two antennas and the influence of the radiation pattern have to rely on the confirmation after mounting, and it is difficult to predict and calculate at the design stage. That is, the conventional antenna device for a portable wireless device has problems that the utilization efficiency of the linear antenna and the fixed antenna is poor, and that the structure for supplying power to the linear antenna and the fixed antenna is complicated and the cost is large.

The present invention has been made in order to solve the above problems, and does not require a mechanical switch for switching the power feeding to the antenna, and can expect highly reliable operation for a long period of time. Moreover, it is an object of the present invention to obtain an antenna device for a portable wireless device, which is small in size and has wide-band antenna characteristics with a simple structure. Another object of the present invention is to obtain a polarization diversity antenna which has a small mutual coupling between two antennas, has a simple structure, is easy to design, and can be constructed at low cost.

[0014]

[0015]

A device according to the invention of claim 1
The antenna device for the band wireless device should be fixed to the power supply unit.
State notch antenna and capacitive coupling with this notch antenna
However, the position of this electrostatic coupling changes according to its own movement.
A that linear antenna, the wire antenna includes a portion having an electrical length of less than lambda / 2 starting from the electrostatic coupling portion at a predetermined position of the movable range, the electrical length of the electrically lambda / 4 It is configured so as to become a part having. Invention of Claim 2
An antenna device for a portable wireless device according to claim 1,
A mobile phone antenna device, in which the notch antenna is arranged perpendicular to the linear antenna. An antenna device for a portable wireless device according to the invention of claim 3
Is an antenna device for a portable wireless device according to claim 1.
Te, in which the notch antenna and arranged in parallel with the said linear antenna.

[0016] In the invention according to mobile phone antenna device according to claim 4, the first notch antenna and the second Notchiante na fixed state each connected to a power source, before
Either the first notch antenna or the second notch antenna
It electrostatically couples with one of them, and the position of this electrostatic coupling is its own.
And a linear antenna that varies according to the movement, the linear A
Is obtained by horizontally arranged either the vertically other before Symbol first notch antenna and the second notch antenna to antenna. An antenna device for a portable wireless device according to a fifth aspect of the present invention is the antenna device for a portable wireless device according to the fourth aspect, wherein the short-circuited portion of the first notch antenna and the open portion of the second notch antenna are close to each other. It is arranged.

Further, an antenna device for a portable radio device according to a sixth aspect of the present invention is the antenna device for a portable radio device according to the fifth aspect, wherein the linear antenna is the first notch.
Arranged perpendicular to the antenna, it is obtained by coupling the open portion and the electrostatic of the first notch antenna. An antenna device for a portable wireless device according to the invention of claim 7 is the antenna device for a portable wireless device according to claim 5, wherein the linear antenna
, The second and arranged in parallel with the notch antenna, combines electrostatic arranged near the said second notch antenna.

[0018]

An antenna device for a portable wireless device according to the invention of claim 1
In the arrangement , the capacitance in the electrostatic coupling portion between the linear antenna and the notch antenna and the inductance component of the linear antenna form a constant K-type band filter for the frequency used, thereby widening the frequency band used. To realize. Then, by setting the linear antenna at a predetermined position, the capacitance component and the inductance component of the notch antenna are in a parallel resonance state with respect to the used frequency.

[0019]

Further, the resonance frequency due to the portion having the electrical length of λ / 4 of the linear antenna and the resonance frequency due to the notch antenna become two resonances, and a wide band can be achieved with respect to the used frequency. When the linear antenna moves from the predetermined position,
Since the reactance component of the entire linear antenna changes,
The resonance frequency fluctuates in a portion of the linear antenna having an electric length of λ / 4. Therefore, the parallel resonance of the notch antenna is mainly effective in the used frequency band, and the linear
Even if the receiving sensitivity of Tena is lowered, any antenna length
The notch antenna to maintain reception sensitivity than a constant level in the.

In the portable radio device antenna device according to the second aspect of the present invention, the notch antenna is electrostatically coupled in a short section of the linear antenna and has a strong vertical polarization component in the horizontal plane direction.
In the portable wireless device antenna device according to the invention of claim 3, the notch antenna is electrostatically coupled in a long section of the linear antenna,
It has a horizontal polarization component in a predetermined direction in the horizontal plane. Further, the antenna device for a portable wireless device according to the invention of claim 4 is a linear device.
At the capacitive coupling between the antenna and the notch antenna
The capacitance and the inductance component of the linear antenna are used.
A constant K type band filter is formed for the frequency
A wide wave number band is realized. And the linear antenna
Set the notch antenna to
The quantity component and the inductance component are parallel to the used frequency.
The column resonance occurs. Further, the two notch antennas each have a vertical polarization component and a horizontal polarization component, so that the two notch antennas function as a polarization diversity antenna.

Ante for portable radio equipment according to the invention of claim 5
Na apparatus, the Rukoto is arranged close shorted portion of the first notch antenna and the open portion of the second notch antenna, current of the first notch antenna, toward the open portion of the high-impedance second notch antenna To prevent inflow and reduce mutual coupling between the two. Also,
Configure the 1-notch antenna perpendicular to the horizontal plane of the portable radio.
If the two notch antennas are fed by the second notch antenna,
It becomes possible to arrange them on the antenna side.

Further, for a portable radio device according to the invention of claim 6.
Antenna device, an open portion and a linear antenna of the first notch antenna is electrostatically coupled, mobile according to the invention of claim 7
Radio antenna device, by binding electrostatically arranged linear antenna in the vicinity of the second notch antenna, the radiation position of the radio wave been around condensed in feed coupling portion side of the linear antenna, the influence of the obstacle The structure makes it difficult to receive.

[0024]

【Example】

Example 1. Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a partial cross-sectional view showing an antenna device of a portable radio device according to the present embodiment. In the figure, 7 is a radio telephone body, 1 is a linear antenna which is a movable antenna that can be pulled out and stored in the radio telephone body 7. In the linear antenna, the inductive antenna element has an electrical length of less than λ / 2, where λ is the wavelength of the radio wave in the used frequency band. 2 is a notch antenna built in the main body of the wireless telephone, and a linear antenna 1
In order to be electrostatically coupled to the linear antenna 1, the linear antenna 1 is arranged in the direction close to the linear antenna 1 in the vicinity of the entrance of the portion accommodated in the wireless telephone body 7 and in the direction orthogonal to the axis of the linear antenna 1. ing.

Also, the notch antenna 2 does not require a dedicated substrate for ground because of its structural characteristics, unlike an inverted F antenna, and can be manufactured by pattern printing on a single substrate, and the structure can be further simplified. Therefore, the notch antenna according to the present embodiment is constructed in such a manner that it is inexpensive and can be downsized. The notch antenna 2 is set so as to be matched with the frequency band used in the state where the linear antenna 1 is pulled out from the wireless telephone body 7.

The capacitance in the electrostatic coupling portion between the linear antenna 1 and the notch antenna 2 and the inductance component of the linear antenna 1 are configured so as to form a constant K band filter with respect to the frequency used. . 3 is a microstrip line feed line connected to the notch antenna 2, 4
Is a high frequency circuit, 5 is a notch antenna 2 and a high frequency circuit 4.
, A linear antenna 1
Is a rubber ring which serves as an electrostatic coupling, which is an antenna holding means for holding the wireless telephone main body 1 at an arbitrary position when the wireless telephone main body 1 is stopped at that position, and 8 is mainly the linear antenna 1. The notch antenna 2 is an electrostatic coupling portion that is electrostatically coupled.

Next, the operation will be described. Transmission power is supplied to the notch antenna 2 from the high frequency circuit 4 including the transmission / reception circuit through the microstrip line power supply line 3.
FIG. 2 is an equivalent circuit diagram of FIG. The electrical length of the linear antenna 1 is set within the range of λ / 4 to λ / 2. When the linear antenna 1 is pulled out from the wireless telephone body 7 and extended, the linear antenna 1 can skip radio waves without creating a so-called dead zone in the shadow of the head of the user. In this state, the capacitance component C2 and the inductance component L2 of the notch antenna 2 are set to resonate in parallel with the used frequency.

On the other hand, the linear antenna 1 and the notch antenna 2
And an electrostatic capacitance C1 in an electrostatic coupling portion composed of the end of
The inductance component La of the linear antenna 1 is configured so as to form a constant K-type bandpass filter for the frequency band used. As a result, a wider band can be achieved. In this way, unlike the case of the conventional switching circuit, by capacitive coupling, both the linear antenna and the notch antenna can be operated without waste, and the performance can be improved.

When the linear antenna 1 is housed in the radio telephone main body 7, the inductance component L of the linear antenna 1
Since a varies, the linear antenna 1 and the notch antenna 2
The resonance frequency due to the capacitance C1 in the electrostatic coupling portion 8 and the inductance component La of the linear antenna 1 fluctuates. As a result, the parallel resonance of the notch antenna 2 is mainly effective in the used frequency band, and the notch antenna 2 mainly contributes to the radiation and reception of radio waves. Since the performance of the notch antenna 2 guarantees the receiving sensitivity and the like of the antenna at a certain level or higher, the antenna performance is always kept at a certain level or higher by adopting such a configuration.

The linear antenna 1 is constructed so that it can be stopped and held at an arbitrary position where it is expanded and contracted by a rubber ring 6. In this embodiment, since the linear antenna is a linear antenna, the antenna holding structure can be easily realized with such a ring-shaped rubber. With such a configuration, the antenna length to be pulled out from the wireless telephone body 1 can be flexibly set within the entire length of the linear antenna 1.
Also in this case, since the parallel resonance of the notch antenna 2 is effective in the used frequency band, some VSWR is required.
Although the (voltage standing wave ratio) is deteriorated, the antenna performances sufficient for practical use can be obtained by the functions of both antennas.

Conventionally, the switch is switched to feed power to one antenna only when the linear antenna is pulled out and completely extended, or when it is completely housed in the main body of the wireless telephone. However, in the present embodiment, the wire is fed. The linear antenna 1 can be used by pulling it out to an arbitrary position, and the performance is exhibited by both antennas. Therefore, when there is a good radio wave condition or there is a circumstance where the linear antenna cannot be fully pulled out, The antenna can be used by pulling it out halfway. Further, since the linear antenna of linear antennas, experiments capacitive coupling with the notch antenna, designed easily performed because of the high simulation accuracy, easy to make something of this structure.

As described above, according to the above construction, the main linear antenna that can be expanded and contracted and the built-in notch antenna are automatically and contactlessly shifted as the linear antenna expands and contracts to expand and contract. Optimum and wide-band antenna characteristics are exhibited according to the state of storage and the state of storage, and no mechanical changeover switch for supplying power to the linear antenna is required at all, and highly reliable operation can be expected over a long period of time. In addition, the ring allows the linear antenna to be pulled out to an arbitrary position for use.

Further, by using the notch antenna, the high frequency circuit and the notch antenna are formed on one board,
By using a linear antenna, you can hold it in any position with a rubber ring, so there are few components, cost can be reduced, loss of the power feeding part is reduced as much as possible, and the length of the antenna can be adjusted freely before use can do. The antenna holding means may be a suitable one depending on the type of the movable antenna.

Example 2. FIG. 3 is a partial cross-sectional view showing an antenna device of a portable radio device according to another embodiment. In the drawing, 1 to 8 show the same or corresponding portions as those of the first embodiment, and the same reference numerals are given. The description is omitted. In the present embodiment, the antenna length of the linear antenna 1 that is pulled out from the wireless telephone body 7 (exposed portion) is λ / 2 to the boundary of the capacitive coupling portion 8 with the notch antenna 2 when the linear antenna 1 is fully pulled out. λ / 4 is set so that the antenna length of the portion (inner portion) that is still contained in the main body is electrically λ / 4.

Here, the antenna length of the internal portion is ideally λ / 4, but if a dielectric material is interposed between the internal portion and the substrate 5, for example, a wavelength short circuit may occur, or Is not necessarily λ / 4 if there is a portion where the substrate 5 and the linear antenna 1 are not parallel to each other because there is a screw hole or the like in the substrate 5. /
The antenna length may be set so as to be 4. Generally, the length is designed to have an electrical length of about 0,2λ to 0,3λ. Other configurations are the same as those in the first embodiment.

Next, the operation will be described. The basic operation and the operation of the components similar to those of the first embodiment are the same as those of the first embodiment. FIG. 4 is an equivalent circuit of FIG. Linear antenna 1
In the state in which the linear antenna 1 is pulled out and extended, the internal portion of the linear antenna 1 has an electrical length of λ / 4 electrically, and is matched with the notch antenna 2 by the resonance frequency of the inductance component L3 and the capacitance component C3 of this portion. As a result, two resonances are obtained, and a wider band can be achieved with respect to the used frequency band.

In the state where the linear antenna 1 is housed in the radio telephone main body 7, the reactance component of the entire linear antenna 1 changes, so that the resonance frequency of the internal portion also changes.
Therefore, the parallel resonance of the notch antenna 2 is mainly effective in the used frequency band, and the notch antenna 2 contributes to radiation and reception of radio waves. As described above, according to the above configuration, in addition to the effect obtained in the first embodiment, a wider band antenna characteristic can be obtained.

The same applies to the case of the first embodiment, but if the notch antenna is arranged perpendicularly to the linear antenna, that is, the slot of the notch antenna is perpendicular to the linear antenna, a short section of the linear antenna is obtained. Can be electrostatically coupled with. Further, when mounted on a wireless telephone or the like, the performance deteriorates when the substrate or the like is placed so as to overlap the notch antenna, so this structure is effective when the wireless telephone itself has a margin in the height direction. The wireless telephone has a limit in downsizing in the height direction due to the positional relationship between the user's ear and mouth, and in that sense, the vertical arrangement is advantageous. Also, since the notch antenna alone has a strong vertical polarization component in the horizontal plane, it is effective when such a radiation pattern is required.

Example 3. FIG. 5 is a partial cross-sectional view showing an antenna device of a portable wireless device in another embodiment. In the drawing, 1 to 8 show the same or corresponding portions as those in the first embodiment, and the same reference numerals are given. The description is omitted. In the present embodiment, as in the case of the second embodiment, the linear antenna 1
However, the antenna length of the portion (exposed portion) pulled out from the wireless telephone main body 7 is λ / 2 to λ / 4 and is housed in the main body with the electrostatic coupling portion 8 with the notch antenna 2 as a boundary at the maximum pulling out. The antenna length of the as-built portion (inner portion) is electrically set to λ / 4.

Further, the notch antenna 2 is the linear antenna 1
And the slot of the notch antenna 2 is arranged parallel to the linear antenna 1 (perpendicular to the ground surface). The high frequency circuit 4 is arranged on the same substrate as the notch antenna 2 on the opposite side of the linear antenna 1 with the slot of the notch antenna 2 interposed therebetween. Next, the operation will be described. The basic operation of the antenna is similar to that of the second embodiment, and the description thereof is omitted.

FIG. 6 shows experimental data of (a) impedance characteristics and (b) VSWR characteristics when the linear antenna 1 of the antenna device constructed as in this embodiment is pulled out from the wireless telephone body 7 and extended. FIG. As can be seen from this VSWR characteristic, it shows a wide band characteristic. FIG. 7 is a diagram showing experimental data of (a) impedance characteristics and (b) VSWR characteristics when the linear antenna 1 of the same device is housed in the wireless telephone body 7.
Good broadband characteristics are shown even when stored.

Further, FIG. 8 is a state diagram showing the wireless telephone when the linear antenna 1 is extended, and FIG. 9 is a state diagram showing the wireless telephone when the linear antenna is housed. X and Y are in the horizontal plane Z
Indicates the vertical (height) direction. In this way, when the notch antenna is arranged parallel to the linear antenna, that is, the slot of the notch antenna is parallel to the linear antenna, capacitive coupling occurs in a long section of the linear antenna. With such a structure, it is easy to induce a current between the linear antenna 1 and the notch antenna 2 especially at high frequencies.

However, when it is mounted on a wireless telephone or the like, the performance is deteriorated when the substrate or the like is placed so as to overlap the notch antenna. Therefore, this structure is effective when the wireless telephone itself has a margin in the horizontal direction. Also, since the notch antenna alone has horizontal polarization components in both directions of the X axis in the horizontal plane (XY plane), it is effective when such a radiation pattern is required during storage.

Example 4. FIG. 10 is a partial cross-sectional view showing the configuration of an antenna device of a portable wireless device according to another embodiment. In the drawing, 4 is a high frequency circuit, 5 is a single substrate,
On this substrate 5, a notch antenna parallel to and perpendicular to the linear antenna (hence vertical and horizontal to the ground plane) and the high frequency circuit 4 are formed. 20 is a notch antenna that is parallel to the linear antenna 1 (and thus is vertical to the ground surface), 21 is a vertical (same horizontal) notch antenna, 30 is a feed line for the parallel notch antenna 20, and 31 is a vertical line. The power supply lines of the notch antenna 21 are connected to the same high frequency circuit 4.

The two notch antennas are in a relationship orthogonal to each other, and the short-circuited portion of the vertical notch antenna 21 is
The structure is close to the high impedance part in the open part of the parallel notch antenna 20. Next, the operation will be described. Since the parallel notch antenna 20 and the vertical notch antenna 21 are orthogonal to each other, they function as polarization diversity.

Since the short circuit part of the vertical notch antenna 21 is arranged close to the high impedance part in the open part of the parallel notch antenna 20, the current of the vertical notch antenna 21 is transferred to the parallel notch antenna 20. Inflow is prevented and mutual coupling of the two antennas is reduced. Further, according to the above configuration, the two notch antennas 20 and 21 can be configured only by the pattern on the substrate 5, and the high frequency circuit can also be configured on the same substrate, so that the accuracy is high and the cost is low. Further, by configuring on the same substrate in this way, it becomes possible to easily predict and calculate the influence of mutual coupling and radiation patterns at the time of designing before mounting.

Example 5. FIG. 11 is a partial cross-sectional view showing the configuration of an antenna device for a portable wireless device according to another embodiment. In the drawing, the same or corresponding parts as those of the fourth embodiment are designated by the same reference numerals and their description is omitted. To do. In the present embodiment, the parallel notch antenna 20 has its open portion facing downward,
The structure is such that the open part of the vertical notch antenna 21 is brought close to the short-circuit part of the parallel notch antenna 20. Other configurations are similar to those of the fourth embodiment, and the description thereof is omitted.

The operation in the case of the above configuration is similar to that in the case of the fourth embodiment. However, with such a configuration, the feed portion 30 of the parallel notch antenna 20 and the feed portion 31 of the vertical notch antenna 21 are connected. However, both of them are close to the height direction, and it is easy to design so that the power feeding parts of both sides are not affected by obstacles. Moreover, since they are concentrated at a high position of the antenna device, they are mounted on a mobile phone or the like. In this case, it is easy to design so as not to be hidden behind the hand holding the telephone. Therefore, when the telephone is held by hand, the decrease in antenna gain can be reduced as compared with the configuration of the fourth embodiment.

Example 6. FIG. 12 is a partial cross-sectional view showing an antenna device of a portable radio device according to another embodiment. In the drawing, the same or corresponding parts as those of the first and fourth embodiments are designated by the same reference numerals and their description will be given. Is omitted. In the present embodiment, the arrangement configuration of the notch antenna is the same as that of the fourth embodiment, and the linear antenna 1 as an external antenna is electrostatically arranged on the open side of the vertical notch antenna 21 so as to be orthogonal to the vertical notch antenna 21. It is arranged by combining. Although the other arrangements are omitted in the drawing, they are the same as those in the first embodiment except the structure of the substrate 5.

Next, the operation will be described. The parallel notch antenna 20 is sensitive to the electric field, and the vertical notch antenna 2
1 is sensitive to magnetic fields. Further, the linear antenna 1 is contactlessly capacitively coupled to the vertical notch antenna 21. Although the parallel notch antenna 20 is affected by the main body of the wireless telephone, it is sensitive to vertical polarization as a monopole, and the vertical notch antenna 21 is sensitive to a notch.

The vertical notch antenna 21 and the linear antenna 1 are mutually coupled to assist radiation and prevent the radiation pattern from dropping. According to the above configuration, the same effect as that of the first embodiment can be expected, the height of the radiated radio wave can be increased, and when applied to a mobile phone or the like, a decrease in gain due to the influence of the human head can be suppressed. You can

Example 7. FIG. 13 is a block diagram showing an antenna device of a portable wireless device in another embodiment. In the drawing, the same or corresponding parts as those in the first and fourth embodiments are designated by the same reference numerals and their description is omitted. Omit it. In this embodiment, the arrangement configuration of the notch antenna is the same as that of the fourth embodiment, and the linear antenna 1 which is an external antenna is arranged on the parallel notch antenna 20 side in parallel with the parallel notch antenna 20. It is electrostatically coupled. Although the other arrangements are omitted in the drawing, they are the same as those in the first embodiment except the structure of the substrate 5.

Next, the operation will be described. FIG. 13 shows a state where the linear antenna 1 is extended. Even when the linear antenna 1 is extended, the parallel open portion of the notch antenna 20 and the internal portion of the linear antenna 1 are parallel to each other. Has been done. Even with such a configuration, the same effect as that of the sixth embodiment can be obtained.

[0054]

As it is evident from the foregoing description, according to the invention described in claim 1, and a notch antenna fixed state of being connected to a power source, the notch antenna and the electrostatically bonded, this electrostatic coupling located and a linear antenna that fluctuates in accordance with the movement of itself, the linear antenna is static at a predetermined position of the movable range
A portion having an electric length of less than λ / 2 from the electric coupling portion as a starting point,
It is configured so that it is a portion having an electrical length of λ / 4 electrically.
Since it was, and non-contact shifted between the linear antenna and a notch antenna, also operates both without waste of the linear antenna and a notch antenna, depending on the storage state and the linear antenna extended state In addition to exhibiting the optimum and wide-band antenna characteristics, there is no need for a mechanical changeover switch for feeding the linear antenna, so that highly reliable operation can be expected over a long period of time.

[0055] Further, since the linear antenna of linear antennas, experiments capacitive coupling with the notch antenna, designed easily performed, after a high simulation accuracy, one fixed antenna by using a notch antenna Since it can be configured by a substrate, and the high frequency circuit can be configured by a notch antenna and a single substrate, it is possible to reduce the number of components, and it is possible to achieve an effect that the device can be downsized and the cost can be reduced.

[0056] Also, it is combined with 2 resonance notch antenna the resonance frequency due an inductance component and a capacitance component portion having an electrical length of lambda / 4, the effect of attained further broaden to the use frequency band obtained To be

Further , according to the second aspect of the invention, since the notch antenna is arranged perpendicularly to the linear antenna, the linear antenna has a structure in which there is no thickness in the movable direction, and the size in the height direction is reduced. for there is a limit cellular obina line machine,
It is possible to easily realize a configuration in which the notch antenna and the other substrate or the like are not arranged so as to overlap each other in the horizontal direction, and it is possible to maintain the performance of the notch antenna without increasing the size of the entire device.

Further, according to the invention of claim 3, since the notch antenna is arranged in parallel with the linear antenna, the linear antenna is electrostatically coupled in a long section, and particularly in the case of high frequency, the linear antenna is linear. It is possible to obtain the effect of facilitating the induction of current between the antenna and the notch antenna. Further, according to the invention of claim 4, the first notch antenna and the second notch antenna in a fixed state, each of which is connected to the power feeding portion, and the first notch antenna or the second notch antenna.
Electrostatically coupled to one of the tenas,
And a linear antenna that changes according to its own movement, and one of the first notch antenna and the second notch antenna is perpendicular to the linear antenna and the other is perpendicular to the linear antenna.
Since it is placed horizontally , the linear antenna and the notch antenna
Between the linear antenna and the knock
Both the antenna and the
Optimal and wide band depending on the exposed state and the stored state
In addition to exhibiting antenna characteristics, it also feeds a linear antenna.
No mechanical changeover switch required
The result is that reliable operation can be expected.
It Also, since the linear antenna is a linear antenna,
It is easy to experiment and design the capacitive coupling with the switch antenna.
High accuracy of simulation and use of notch antenna
By doing so, the fixed antenna can be configured with one board,
In addition, the high-frequency circuit consists of a notch antenna and a single substrate.
Since it is also possible to reduce the number of components,
The effects of downsizing and cost reduction can be obtained.
In addition, the notch antenna functions as a polarization diversity, the antenna performance is improved, and the two notch antennas can be configured only by the pattern on the board, and the high frequency circuit can be configured on the same board. Is high and cheap. Further, by configuring them on the same substrate, it is possible to easily predict and calculate the influence of mutual coupling and radiation patterns at the time of designing before mounting.

[0059]

According to the invention described in claim 5,
Since were located close shorted portion of the one notch antenna and the open portion of the second notch antenna, short portion of the first notch antenna, high put <br/> Ru impedance at the open portion of the second notch antenna since will be placed close to the part, the current of the first notch antenna prevents flow into the second notch antenna, the effect is obtained that the mutual coupling of the two antennas is reduced. Also, the first knock
If the antenna is configured perpendicularly to the horizontal plane of the portable radio,
The first notch antenna feed section and the second notch antenna
The power supply part of the
The power source of the other side is not affected by the other components of the portable wireless device.
It is easy to design the portable wireless device,
Moreover, the power supply is concentrated at the high position of the portable wireless device.
So that the power supply is not hidden behind the hand holding the portable wireless device.
The effect is that it can be easily measured.

According to the invention described in claim 6, the open part of the first notch antenna and the linear antenna are electrostatically coupled to the linear antenna, or the invention is described in claim 7.
According to the invention, since the linear antenna is arranged near the second notch antenna and electrostatically coupled to the linear antenna,
It is possible to increase the height of the radio wave radiated, when applied to a mobile obina line machine, the effect is obtained that the gain due to the generation of the shadow of the human head can be prevented from being lowered.

[Brief description of drawings]

FIG. 1 is a partial cross-sectional view showing a wireless telephone antenna device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing an equivalent circuit of FIG.

FIG. 3 is a partial sectional view showing an antenna device for a wireless telephone according to a second embodiment of the present invention.

FIG. 4 is a diagram showing an equivalent circuit of FIG.

FIG. 5 is a partial cross-sectional view showing a wireless telephone antenna device according to a third embodiment of the present invention.

FIG. 6 is a diagram showing experimental data of VSWR characteristics and impedance characteristics when an antenna of the wireless telephone antenna device according to the third embodiment of the present invention is extended.

FIG. 7 is a diagram showing experimental data of VSWR characteristics and impedance characteristics of the wireless telephone antenna device according to the third embodiment of the present invention when the antenna is housed.

FIG. 8 is a configuration diagram of a test antenna when the antenna device for a wireless telephone according to a third embodiment of the present invention is extended.

FIG. 9 is a configuration diagram of a test antenna when the antenna device for a wireless telephone according to the third embodiment of the present invention is housed.

FIG. 10 is a configuration diagram showing a notch antenna portion of a wireless telephone antenna device according to a fourth embodiment of the present invention.

FIG. 11 is a configuration diagram showing a notch antenna portion of a wireless telephone antenna device according to a fifth embodiment of the present invention.

FIG. 12 is a configuration diagram showing an antenna device for a wireless telephone according to a sixth embodiment of the present invention.

FIG. 13 is a configuration diagram showing an antenna device for a wireless telephone according to a seventh embodiment of the present invention.

FIG. 14 is a configuration diagram showing a conventional antenna device for a wireless telephone.

FIG. 15 is a configuration diagram showing a conventional antenna device for a wireless telephone.

[Explanation of symbols]

1 linear antenna, 2 notch antenna, 3 feeding line,
4 high frequency circuit, 5 substrate, 6 ring, 8 electrostatic coupling part, 20 parallel notch antenna, 21 vertical notch antenna

─────────────────────────────────────────────────── --- Continuation of the front page (56) References JP-A-4-58603 (JP, A) JP-A-1-272303 (JP, A) JP-A-6-140820 (JP, A) JP-A-6- 252619 (JP, A) (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04B 1/38-1/58 H04B ⁷ /02-7/12 H04L 1/02-1/06 H01Q 1/24

Claims (7)

(57) [Claims] 1. A notch antenna in a fixed state, which is connected to a power feeding section, and a linear antenna, which is electrostatically coupled to the notch antenna and whose electrostatic coupling position varies according to the movement of the notch antenna. The linear antenna is configured to have a portion having an electric length of less than λ / 2 and a portion having an electric length of λ / 4 electrically from the electrostatic coupling portion at a predetermined position in the movable range. An antenna device for a portable wireless device, which is characterized in that 2. The antenna device for a portable wireless device according to claim 1, wherein the notch antenna is arranged vertically to the linear antenna. 3. The antenna device for a portable wireless device according to claim 1, wherein the notch antenna is arranged parallel to the linear antenna. 4. A first notch antenna and the second Notchiante na fixed state each connected to a power source, the
Either the first notch antenna or the second notch antenna
One of them is electrostatically coupled to one of them, and the position of this electrostatic coupling is one's own
And a linear antenna that varies according to the movement, the linear Ann
Tena mobile phone antenna device being characterized in that arranged horizontally either the vertically other before Symbol first notch antenna and the second notch antenna to. 5. The antenna device for a portable wireless device according to claim 4, wherein the short-circuited portion of the first notch antenna and the open portion of the second notch antenna are arranged close to each other. 6. The linear antenna comprises the first notch antenna.
Arranged perpendicularly to the container, mobile phone antenna device according to claim 5, wherein the bound open portion and the electrostatic of the first notch antenna. 7. The linear antenna comprises the second notch antenna.
Parallel to and positioned relative antennas, mobile phone antenna device according to claim 5, wherein the bound electrostatically arranged near the said second notch antenna.