JP2000040912A - Antenna which can freely be pulled out/stored and radio equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an extension/contraction antenna which can wait for/ receive the frequency band of a dual band and in which the length in a storage state can be shortened. SOLUTION: For a folded antenna element 10, where a linear or band-like conductor is installed in the direction of a tip side from a base end, the conductor is folded at least once on the tip sided and is installed in parallel to the direction is made into a cylindrical form. A bar-like antenna element 12 is installed in the axial direction so that it is freely movable. Capacity is connected with connection opacity C in a pull-out state and in a state, where the base end side of the bar-like antenna element 12 is inserted into the tip side of the folded antenna element 10. An effective length from the base end of the folded antenna element 10 to the tip is set to a 1/4 wavelength for a first frequency and set to a 3/4 wavelength for a second frequency f2. The effective length from the base end of the folded antenna element 10 to the tip of the bar-like antenna element 12 in the pull-out state is to be the 1/4 wavelength for the first frequency and to be the 3/4 wavelength for the second frequency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna which can stand by and receive in a dual band frequency band, and which can be pulled out and stored so that the size of the antenna in a stored state is reduced. Also, the present invention relates to a radio device suitable for a dual-band small mobile phone or the like using the antenna which can be pulled out and stored.

[0002]

2. Description of the Related Art The present inventors have disclosed in Japanese Patent Application No. 8-160016.
The first frequency f1 and 1800 in the 900 MHz band comprise a cylindrical folded antenna element and a rod-shaped antenna element movably disposed in the axial direction.
There has been proposed an antenna that can be pulled out and housed, which can be used in a dual band with a second frequency f2 in the MHz band. The shape of the folded antenna element is such that a linear or band-shaped conductor is disposed in the direction from the base end to the distal end side, and the conductor is turned at least once at the distal end side and disposed in a zigzag shape parallel to the direction. Things. Then, the folded antenna element made of the conductor having this shape is formed in a tubular shape. In this retractable antenna, the effective length from the base end to the front end of the folded antenna element is 1/4 wavelength with respect to the first frequency f1, and the second frequency is higher than the first frequency. It is set to be 3/4 wavelength for f2. Further, the effective length from the base end to the front end of the rod-shaped antenna element is set to be 波長 wavelength for the first frequency f1 and one wavelength for the second frequency f2.

In the antenna that can be pulled out and stored proposed in the above-mentioned Japanese Patent Application No. Hei 8-160016, the effective length of the folded antenna element can be set to a desired wavelength of the first frequency f1 and the second frequency f2. difficult. Therefore,
The present inventors have proposed an improved drawer-storable antenna technology in Japanese Patent Application No. 10-136000. The folded antenna element that constitutes the antenna that can be freely pulled out and stored is proposed in Japanese Patent Application No. Hei 8-1.
It differs from the structure proposed in US Pat. No. 60016 in part. In other words, the structure of the folded antenna element proposed in Japanese Patent Application No. 10-136000 is such that a linear or band-shaped conductor is disposed in a direction from the base end to the tip side, and the conductor is turned at least once at the tip side. The first element is formed by being arranged in a zigzag shape in parallel with the direction, and the conductor is branched at least halfway from the base end to the first turning point on the distal side in the middle or at the first turning point. The second element is formed in a zigzag arrangement parallel to the direction. Further, the folded antenna element made of a conductor having such a shape is formed in a tubular shape. Then, the folded antenna element is moved from the base end to the first
The effective length from the base end to the tip of the second element is 1/4 wavelength with respect to the second frequency f2 while the effective length from the base end to the tip of the second element is 1/4 wavelength with respect to the first frequency f1. Is set to Thus, the first frequency f1
Since the effective length can be set independently for the first element and the second element for the second frequency f2 and the second frequency f2, the adjustment is easy. The rod-shaped antenna element has the same structure as that proposed in Japanese Patent Application No. 8-160016, and its effective length is 1 with respect to the first frequency f1.
/ 2 wavelengths and one wavelength for the second frequency f2.

[0004] In any of the drawer-retractable antennas proposed in Japanese Patent Application Nos. 8-160016 and 10-136000, a rod-shaped antenna element is disposed from the tip side of a folded antenna element in an antenna extended state. Even when the base end side is pulled out or inserted, the overlapping dimension is small, and the capacitance value of the coupling capacitance between them is set relatively small. Therefore, the folded antenna element and the rod-shaped antenna element are capacitively coupled with a relatively small capacitance value.

[0005]

In any of the above-mentioned proposed retractable antennas, the effective length of the rod-shaped antenna element is set to a half wavelength of the first frequency f1. The overall dimensions of the antenna that can be pulled out and stored in the antenna stored state are regulated by the physical length of the rod-shaped antenna element. Here, if the rod-shaped antenna element is formed of a single whip antenna element, the first frequency f1 is 900
At MHz, its length can be as much as about 17 cm. Therefore, in order to further shorten the physical length, a whip antenna element and a helical antenna element provided on the tip side thereof are used as rod-shaped antenna elements.

[0006] By the way, in a portable telephone or the like, miniaturization and weight reduction are achieved to make it more portable. Therefore, it is desired that the entire length of the retractable antenna in the retracted state is shorter.

[0007] The present invention has been made to further improve the above-mentioned proposed technique, and has as its object to provide a drawer-storable antenna capable of shortening the total length in a stowed state. Another object of the present invention is to provide a wireless device that can be easily miniaturized by using such an antenna that can be freely stored in a drawer.

[0008]

In order to achieve this object, a drawer-retractable antenna according to the present invention comprises a linear or band-shaped conductor arranged in a direction from a base end to a distal end side, and the distal end side is provided at the distal end side. A folded antenna element formed by arranging the conductor at least once and in parallel with the direction,
The effective length from the base end to the tip is 1 for the first frequency.
波長 wavelength and ３ wavelength with respect to the second frequency. The folded antenna element is formed in a cylindrical shape, and the rod-shaped antenna element is movably disposed in the axial direction. The base end of the rod-shaped antenna element is capacitively coupled to the cylindrical tip of the folded antenna element in the pulled-out state in the inserted state, and the effective length from the base end of the folded antenna element to the tip of the rod-shaped antenna element is
It is configured to be １ ／ wavelength for the first frequency and ／ wavelength for the second frequency.

Further, a linear or band-shaped conductor is disposed in a direction from the base end to the distal end side, and the conductor is disposed at least one turn at the distal end side to be disposed in parallel with the direction to form a first element. And at the same time from the base end to the first turning point on the tip side or at the first turning point, the conductor is branched and turned at least one time to be arranged in parallel with the direction to form a second element. The effective length from the base end of the folded antenna element to the front end of the first element is 1/4 of the first frequency.
Wavelength, the effective length from the base end to the tip of the second element is set to 1/4 wavelength with respect to the second frequency, and the folded antenna element is cylindrical and the rod-shaped antenna element is movably arranged in the axial direction. When the rod-shaped antenna element is pulled out, the base end of the rod-shaped antenna element is capacitively coupled to the cylindrical distal end side of the folded antenna element in an inserted state, and the rod-shaped antenna element is inserted from the base end of the folded antenna element. The effective length up to the tip of the first frequency is 1 to the first frequency.
波長 wavelength, and may be configured to be ／ wavelength with respect to the second frequency.

[0010] The rod-shaped antenna element may be constituted by a whip antenna element and a helical antenna element disposed on the tip side thereof.

Further, the rod-shaped antenna element may be constituted by a whip antenna element and a tubular antenna element which is movably covered in the axial direction on the tip side thereof.

The rod-shaped antenna element is configured such that the tip end side of the rod-shaped antenna element is not electrically coupled to the folded antenna element when the rod-shaped antenna element is stored.

Further, when the rod-shaped antenna element is stored, the distal end side of the rod-shaped antenna element is capacitively or inductively coupled to the folded antenna element, but from the base end of the folded antenna element to the base end of the rod-shaped antenna element. The effective length up to may be such that frequencies within the frequency band of the first frequency and the second frequency do not resonate.

According to a second aspect of the present invention, there is provided a wireless device using the retractable antenna according to the first or second aspect, wherein the folded antenna element is protruded outward and electrically connected to the base end side of the folded antenna element. The power supply fitting provided in this way is disposed so as to penetrate the side wall of the wireless device housing, and a wireless circuit housed in the wireless device housing is electrically connected to the power supply fitting.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the drawer-storable antenna according to the present invention will be described below with reference to FIGS. FIGS. 1A and 1B are diagrams showing a first embodiment of an antenna which can be pulled out and stored according to the present invention, wherein FIG. 1A shows an antenna pulled out state, FIG.
(C) is an equivalent circuit diagram in the state where the antenna is pulled out. FIG. 2 is an external perspective view of an example of a cylindrical folded antenna element.

As shown in FIG. 2, the folded antenna element 10 has a cylindrical shape. A rod-shaped antenna element 12 is provided coaxially with the cylindrical folded antenna element 10 so as to be movable in the axial direction. This first
In the folded antenna element 10 of the embodiment, a linear or band-shaped conductor is disposed in a direction from the base end to the distal end side, and the conductor is turned at least once at the distal end side and disposed in a zigzag shape in parallel with the direction. It becomes. In addition, the rod-shaped antenna element 12 is, of course, configured so that its movement is appropriately regulated so as not to fall out in either the pull-out direction or the storage direction. Moreover, in the drawer-storable antenna of the present invention, in the pulled-out state, the movement in the pull-out direction is made such that the base end side of the rod-shaped antenna element 12 overlaps with the distal end side of the folded antenna element 10 to be inserted. Be regulated.

The folded antenna element 10
Is set so that the effective length from the base end to the front end is 波長 wavelength for the first frequency f1 (wavelength λ1) and ３ wavelength for the second frequency f2 (wavelength λ2). Is done. The dimension from the base end of the folded antenna element 10 to the first folded point is about 25 m as an example.
m. Further, the dimension of the rod-shaped antenna element 12 is, for example, 110 mm, and is set to overlap the distal end of the folded antenna element 10 by about 10 mm in the pulled-out state. Dimensions up to about 125 mm. Here, as an example, the first frequency f1 is 900 MHz, and the second frequency f2 is 1800 MHz.

In this configuration, in the housed state shown in FIG. 1B, the first frequency f1 and the second frequency f2 are resonated by the folded antenna element 10 alone, and standby reception is possible. The folded antenna element 10 has an effective length of １ ／ of the first frequency f1.
Since this is a wavelength, which is ／ wavelength with respect to the second frequency f2, the input and output impedances are both about 50 ohms. In the retracted state, the distal end of the rod-shaped antenna element 12 is sufficiently separated from the folded antenna element 10 and is not electrically coupled at all, and the rod-shaped antenna element 12 does not act as an antenna. Do not give. Further, even if the distal end of the rod-shaped antenna element 12 is close to the folded antenna element 10 and is capacitively coupled or inductively coupled, the effective distance from the base end of the folded antenna element 10 to the base end of the rod-shaped antenna element 12 is reduced. The length may be configured so that frequencies within the frequency band of the first frequency f1 and the second frequency f2 do not resonate.

1A, the leading end of the folded antenna element 10 and the base end of the rod-shaped antenna element 12 are capacitively coupled by a relatively large coupling capacitance C. Therefore, as shown in FIG. 1C, the equivalent circuit forms a series resonance circuit of the inductance L1, the coupling capacitance C, and the inductance L2.
Here, the folded-back antenna element 1 is pulled out.
The physical length from the base end of 0 to the front end of the rod-shaped antenna element 12 is １ ／ wavelength (83.3) of the first frequency f1.
mm), but the effective length becomes shorter than this due to the capacitive coupling C interposed therebetween, and operates as a quarter wavelength of the first frequency f1. Further, the capacitive coupling C interposed therebetween acts so as to similarly shorten the effective length with respect to the high frequency second frequency f2, and operates as a ３ wavelength of the second frequency f2. Therefore, even in the state where the antenna is pulled out, the first frequency f1 and the second frequency f2 resonate and transmission and reception are possible. In addition, the effective length is 1/4 wavelength and 3/4 wavelength with respect to the first frequency f1 and the second frequency f2, and their input and output impedances are both about 50 ohms, which is almost the same as the stored state. Therefore, by connecting a coaxial cable and a radio circuit having an input / output impedance of 50 ohms to the retractable antenna of the present invention having an input / output impedance of about 50 ohms, a signal can be efficiently transmitted without the need for a matching circuit. It is possible to transmit.

Further, the total length of the retractable antenna which can be pulled out and stored in the retracted state by the physical length of the rod-shaped antenna element 12 is shorter than that of the proposed antenna, which is suitable as an antenna for a cellular phone or the like which is downsized. is there.

Incidentally, the first frequency f1 and the second frequency f
The setting of the effective length of the folded antenna element 10 and the rod-shaped antenna element 12 with respect to 2 is performed by the following procedure as an example. First, the developed physical length from the base end to the front end of the folded antenna element 10 is set to be substantially a quarter wavelength of the first frequency f1, and this is made into a zigzag shape. The zigzag folded antenna element 10 generates a stray capacitance between the conductors, but does not greatly affect the first frequency f1 having a low frequency, and the first frequency f1 can resonate. However, the stray capacitance between the conductors greatly affects the second frequency f2, so that the effective length from the base end to the front end is greatly reduced. Therefore, the stray capacitance between the conductors is adjusted by adjusting the zigzag interval and the parallel length to obtain the second structure.
The effective length can be set to 3/4 wavelength with respect to the frequency f2.

Next, in the first state in the state where the antenna is pulled out,
The setting of the effective length for the frequency f1 and the second frequency f2 will be described. In the state in which the antenna is pulled out, the resonance frequency increases when the overlap between the folded antenna element 10 and the rod-shaped antenna element 12 is increased to increase the capacitance value of the coupling capacitance C, and the overlap is reduced to reduce the coupling capacitance C.
, The resonance frequency decreases. Thus, in the pulled-out state, the physical length from the base end of the folded antenna element 10 to the tip of the rod-shaped antenna element 12 is first set to be longer than の wavelength of the first frequency f1, and the folded antenna element 10 and the rod-shaped antenna element are set. By adjusting the capacitance value of the coupling capacitance C by adjusting the overlap between the twelve, the effective length is set to a quarter wavelength of the first frequency f1. In this state, the effective length is 3
If the frequency that resonates as the 波長 wavelength is higher than the second frequency f2, the capacitance value is reduced by slightly reducing the overlap between the folded antenna element 10 and the rod-shaped antenna element 12 to reduce the resonance frequency at the ／ wavelength. Is lowered to match the second frequency f2. With such adjustment,
The resonance frequency at the quarter wavelength is lower and lower than the first frequency f1, but its effect is less than for the second frequency f2. Further, the rod-shaped antenna element 12
Is slightly shortened to increase the resonance frequency at the 1/4 wavelength to match the first frequency f1. Then, with this adjustment,
The resonance frequency at the ／ wavelength is higher, but its effect is less than for the first frequency f1. In this way,
By repeating the adjustment of the coupling capacitance C between the folded antenna element 10 and the rod-shaped antenna element 12 and the adjustment of the length of the rod-shaped antenna element 12, the effective length from the base end of the folded antenna element 10 to the tip of the rod-shaped antenna element 12 is obtained. With respect to the first frequency f1
At / 4 wavelength, it can be set to ／ wavelength with respect to the second frequency f2. Further, in the pulled-out state, the rod-shaped antenna element 1
The effective length up to the tip of 2 is 1/4 wavelength of the first frequency f1. In this state, if the effective length is 3/4 wavelength and the resonating frequency is lower than the second frequency f2, the folded antenna element 10 and the rod-shaped The overlapping of the antenna elements 12 is increased and the rod-shaped antenna elements 12
The length can be adjusted in the same manner by increasing the length.
Based on the dimensional values obtained by experiments in this way,
Mass production design is performed.

Next, a second embodiment of the drawer-storable antenna of the present invention will be described with reference to FIG. 3A and 3B are diagrams showing a second embodiment of the drawer-storable antenna according to the present invention, wherein FIG.
(B) shows the antenna storage state.

In FIG. 3, a rod-shaped antenna element 22 is disposed coaxially with a cylindrical folded antenna element 20 so as to be movable in the axial direction. In the folded antenna element 20 of the second embodiment, a linear or band-shaped conductor is disposed in the direction from the base end to the tip side, and the conductor is turned at least once at the tip side to form a zigzag shape parallel to the direction. And the first element 24 is formed.
The second element 26 is formed by branching the conductor at the first turning point on the distal side from the base end and arranging it at least once, and arranging the conductor in a zigzag shape parallel to the above direction. The second
The element 26 may be formed by branching halfway from the base end to the first turning point on the front end side. The rod-shaped antenna element 22 is formed by a whip antenna element 28 on the base end side and a helical antenna element 30 provided on the tip end side. The rod-shaped antenna element 22 is, of course, configured so that its movement is appropriately restricted and does not fall off in either the pulling-out direction or the storing direction. In addition, the movement of the folded antenna element 20 in the pull-out direction is regulated so that the base end side of the rod-shaped antenna element 22 overlaps with the distal end side of the folded antenna element 20 in the pulled-out state so as to be in the inserted state.

Then, the folded antenna element 20
Is the first element 2 from the base end for the first frequency f1.
4 is set so that the effective length up to the distal end becomes 1/4 wavelength, and the second element 2 from the proximal end to the second frequency f2.
The effective length up to the tip of No. 6 is set to be 1/4 wavelength. The dimension from the base end of the folded antenna element 20 to the first folded point is about 25 mm as an example.
It is said. The dimension of the rod-shaped antenna element 22 is the first dimension corresponding to the provision of the helical antenna element 30.
It is set shorter than in the embodiment. Also, the base end of the whip antenna element 28 on the base end of the rod-shaped antenna element 22 is overlapped by about 10 mm on the distal end side of the folded antenna element 20 in the pulled-out state. The physical dimensions up to the tip of the element 22 are:
It is set shorter than in the first embodiment.

Even in the second embodiment having such a configuration, in the antenna stowed state, the first frequency f1 and the second frequency f2 are resonated by the first element 24 and the second element 26 of the folded antenna element 20, respectively. Standby reception is possible. In addition, even when the antenna is pulled out, the effective length from the base end of the folded antenna element 20 to the tip of the rod-shaped antenna element 22 acts as a quarter wavelength with respect to the first frequency f1 and 3 with respect to the second frequency f2. Acts as a quarter wavelength. In addition, since the folded antenna element 20 has the first element 24 and the second element 26, the effective length of each of the first element 24 and the second element 26 is set with respect to the first frequency f1 and the second frequency f2. The adjustment can be made independently for each quarter wavelength, and the adjustment is easy. Further, the physical length of the rod-shaped antenna element 22 can be further reduced by providing the helical antenna element 30 at the tip, and the total length of the drawer-storable antenna in the antenna-storing state is smaller than that of the first embodiment. It can be even shorter.

A third embodiment of the drawer-storable antenna according to the present invention will be described with reference to FIG. FIG.
It is a figure which shows the 3rd Example of the antenna which can be freely pulled out and stored of this invention, (a) shows an antenna pulled out state,
(B) shows the antenna storage state.

In FIG. 4, a rod-shaped antenna element 42 is arranged coaxially with a cylindrical folded antenna element 40 so as to be movable in the axial direction. The folded antenna element 40 of the third embodiment is the same as the folded antenna element 10 of the first embodiment, except that the portion from the base end to the first folded point is formed in a zigzag shape. The rod-shaped antenna element 42 is provided with a whip antenna element 44 on the base end side, and the cylindrical antenna element 46 is covered from the tip side of the whip antenna element 44 so as to be relatively movable in the axial direction like a telescope. A spring 48 made of a conductive material provided at the tip of the whip antenna element 44 resiliently contacts the inner peripheral wall of the tubular antenna element 46 to make electrical connection. Then, in a state where the rod-shaped antenna element 42 is extended in the antenna pulled-out state, the effective length from the base end of the folded antenna element 40 to the tip of the rod-shaped antenna element 62 is １ ／ wavelength with respect to the first frequency f1 and The wavelength is set to be 3/4 wavelength with respect to the second frequency f2. This adjustment can be performed similarly to the first embodiment.

In the third embodiment having such a configuration, the first frequency f1 and the second frequency f2 resonate and transmit and receive in both the antenna retracted state and the antenna retracted state. In the antenna housing state, the length of the rod-shaped antenna element 42 is shorter than that of the whip antenna element 44 because most of the whip antenna element 44 is housed in the tubular antenna element 46.

Referring to FIG. 5, a description will be given of a structure of a wireless device using an antenna which can be pulled out and stored as described above. FIG.
FIG. 2 is a longitudinal sectional view of a main part of an antenna pulled out state in which the drawer-storable antenna of the present invention is arranged in a wireless device.

In FIG. 5, a cylindrical core member 8 made of an insulating material is provided on the distal end side of a power supply fitting 80 made of a substantially cylindrical conductive material.
2 is arranged and fixed. As an example, the cylindrical folded antenna element 10 of the first embodiment is disposed on the outer peripheral surface of the core member 82, and its base end is appropriately electrically connected to the power supply fitting 80 by soldering or the like. A C-shaped resin spring 84 is disposed at the tip of the core member 82, and covers the outer periphery of the folded antenna element 10 and is made of an insulating material so as to restrict the axial movement of the C-shaped resin spring 84. 86 is covered and its base end is screwed and fixed to the power supply fitting 80. Note that a step portion 82a having a smaller diameter on the distal end side is provided on the inner periphery of the core member 82.

As an example, the rod-like antenna element 1 of the first embodiment, which is made of a flexible and conductive linear body,
2 is covered with an insulating tube 88, and a stopper 90 made of an insulating material is provided at a base end thereof. An insulating member 92 having the same diameter as the stopper 90 is provided on the distal end side of the rod-shaped antenna element 12, and a top member 94 is disposed and fixed at the distal end. Then, the assembled body such as the rod-shaped antenna element 12 is incorporated and arranged in the assembled body such as the folded antenna element 10 so as to be movable in the axial direction. Moreover, the step 90 of the inner peripheral wall of the core member 82 is
2a prevents the pull-out in the pull-out direction, and the C-shaped resin spring 84 elastically engages with a groove formed around the axis on the outer peripheral surface of the stopper 90, whereby the axial movement is elastically restricted. The withdrawn state is maintained. In addition, the top member 94 prevents movement in the housing direction, and the C-shaped resin spring 84 elastically engages a groove formed around the axis on the outer peripheral surface of the insulating member 92 so that the axial movement is elastic. And the stored state is maintained.

Further, a power supply fitting 98 made of a conductive material is provided through the side wall of the wireless device housing 96. A circuit board 100 on which a radio circuit 50 (not shown in FIG. 5) is mounted is appropriately provided in the radio housing 96, and a power supply leaf spring 102 provided on the circuit board 100 is wirelessly mounted. It is elastically connected to a power supply fitting 98 projecting into the machine housing 96. Of course, the power supply leaf spring 102 is appropriately electrically connected to the wireless circuit 50. Then, by screwing and fixing the power supply fitting 80 to the power supply receiving piece 98, the base end of the folded antenna element 10 is mounted on the circuit board 100 via the power supply fitting 80, the power supply receiving piece 98, and the power supply leaf spring 102. Electrically connected to the circuit 50,
A wireless device is configured.

The structure of the folded antenna element is not limited to the above embodiment, and the effective length of the folded antenna element is 1/4 wavelength or 3/4 for the first frequency f1 and the second frequency f2.
Any wavelength can be used as long as it can resonate. Further, the structure of the rod-shaped antenna element is not limited to the above embodiment,
It is only necessary that the appearance be rod-shaped. Further, the tubular antenna element 46 is not limited to one-stage as in the third embodiment, but may be provided in a plurality of stages. Further, in the wireless device shown in FIG. 5, if the power supply fitting 80, the power supply receiving tool 98, and the power supply leaf spring 102 perform an antenna function, the base end of the folded antenna element as an antenna is the base end of itself. Not the circuit board 10 of the power supply leaf spring 102
It will be easily understood that this is a connection point to zero.

[0035]

As described above, since the drawer-storable antenna and the radio of the present invention are constituted, the following special effects can be obtained.

In any of the retractable antennas according to the first and second aspects, the effective length of the rod-shaped antenna element can be shorter than that of the proposed proposed retractable antenna. The total length of the drawer-storable antenna is shorter.

According to the third aspect of the present invention, the physical length of the rod-shaped antenna element can be shortened by providing the helical antenna element in a part thereof, and the total length of the antenna in the retracted state can be reduced accordingly. Can be shortened.

Further, in the antenna capable of being retracted and retracted according to the fourth aspect, the length of the rod-shaped antenna element in the retracted state can be substantially increased by forming the telescopic shape using the cylindrical antenna element. The length can be reduced to half or less, and the total length in the stored state can be shortened accordingly.

In the retractable antenna according to the fifth aspect, since the rod-shaped antenna element is not electrically coupled to the folded antenna element in the housed state, only the folded antenna element acts as an antenna in the housed state, The antenna characteristics are not affected by the rod-shaped antenna element.

Further, in the antenna capable of being retracted and retracted according to the sixth aspect, even if the tip of the rod-shaped antenna element is capacitively coupled or inductively coupled to the folded antenna element in the retracted state, the antenna can be moved from the base end of the folded antenna element. Since the effective length up to the base end of the rod-shaped antenna element is set so that frequencies within the frequency band of the first frequency and the second frequency do not resonate, the antenna characteristics are not particularly affected.

In the wireless device according to the seventh aspect,
The use of a drawer-storable antenna having a short overall length in a storage mode allows easy downsizing.

[Brief description of the drawings]

FIGS. 1A and 1B are diagrams showing a first embodiment of an antenna which can be pulled out and stored according to the present invention, wherein FIG. 1A shows an antenna pulled out state, FIG. 1B shows an antenna stored state, and FIG. FIG.

FIG. 2 is an external perspective view of an example of a cylindrical folded antenna element.

FIGS. 3A and 3B are diagrams showing a second embodiment of the antenna which can be pulled out and stored according to the present invention, wherein FIG. 3A shows the antenna pulled out state, and FIG. 3B shows the antenna stored state.

4A and 4B are diagrams showing a third embodiment of the antenna which can be pulled out and stored according to the present invention, wherein FIG. 4A shows the antenna pulled out state, and FIG. 4B shows the antenna stored state.

FIG. 5 is a longitudinal sectional view of a main part of an antenna pulled out state in which the drawer-storable antenna of the present invention is arranged in a wireless device.

[Explanation of symbols]

 10, 20, 40 Folded antenna element 12, 22, 42 Rod antenna element 24 First element 26 Second element 28, 44 Whip antenna element 30 Helical antenna element 46 Cylindrical antenna element 48 Spring 50 Radio circuit 70 Cylindrical antenna element 80 Power supply fittings 96 Radio housing 98 Power supply fittings 100 Circuit board 102 Power supply leaf spring f1 First frequency f2 Second frequency

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Hirotoshi Mizuno 1112 Shinnohara, Tomioka-shi, Gunma F-term in the Yokoo Tomioka Plant (reference) 5J046 AA07 AB06 EA06 JA02 5J047 AA07 AB06 BG04 FA02 FD02

Claims (7)

[Claims] 1. A linear or band-shaped conductor is disposed in a direction from a base end to a distal end, and at least one conductor is disposed on the distal end.
The folded antenna element which is folded back and disposed in parallel with the above direction has an effective length from the base end to the front end of which is 1/4 wavelength with respect to the first frequency and 3/3 with respect to the second frequency. The wavelength is set to 4 wavelengths, and the folded antenna element is formed in a cylindrical shape, and the rod-shaped antenna element is movably disposed in the axial direction. The base end of the rod-shaped antenna element is capacitively coupled in the inserted state, and the effective length from the base end of the folded antenna element to the tip of the rod-shaped antenna element is １ ／ wavelength with respect to the first frequency, An antenna which can be pulled out and housed, wherein the antenna is configured to have a wavelength of 3/4 with respect to the second frequency. 2. A linear or band-shaped conductor is disposed in a direction from a base end to a distal end, and at least one conductor is disposed at the distal end.
The conductor is folded back and disposed in parallel with the direction to form a first element, and the conductor is branched at least in the middle from the base end to the first turning point on the distal end side or at the first turning point. A folded antenna element, which is folded back and disposed in parallel with the above-mentioned direction to form a second element, has an effective length from the base end to the front end of the first element which is 1/4 wavelength with respect to the first frequency. The effective length from the base end to the distal end of the second element is set to 1/4 wavelength with respect to the second frequency, and the folded antenna element is formed in a cylindrical shape and the rod-shaped antenna element is movably disposed in the axial direction. Then, with the rod-shaped antenna element pulled out, the base end side of the rod-shaped antenna element is inserted into the cylindrical distal end side of the folded antenna element. In capacitively coupled, the effective length to the tip of the rod-shaped antenna element from the base end of the folded antenna element, 1/4 with respect to the first frequency
A drawer-and-storable antenna, wherein the antenna is configured to have a wavelength of 3/4 wavelength with respect to the second frequency. 3. The drawer-storable antenna according to claim 1, wherein the rod-shaped antenna element is constituted by a whip antenna element and a helical antenna element disposed at a tip side thereof. Antenna. 4. The antenna according to claim 1, wherein the rod-shaped antenna element is constituted by a whip antenna element and a tubular antenna element which is axially movably covered on a tip side thereof. A drawer that can be stored freely. 5. The retractable antenna according to claim 1, wherein a distal end of the rod-shaped antenna element is not electrically coupled to the folded antenna element when the rod-shaped antenna element is stored. Features a drawer-storable antenna. 6. The retractable and retractable antenna according to claim 1, wherein a tip end of the rod-shaped antenna element is capacitively or inductively coupled to the folded antenna element when the rod-shaped antenna element is stored. A drawer-retractable antenna, wherein an effective length from a base end of the antenna element to a base end of the rod-shaped antenna element is configured such that frequencies within the frequency bands of the first frequency and the second frequency do not resonate. . 7. A power supply fitting provided by using the retractable antenna according to claim 1 or 2 and projecting the folded antenna element outward and electrically connected to a base end side of the folded antenna element. A wireless device, wherein the wireless device is provided by penetrating a side wall of a wireless device housing, and a wireless circuit accommodated in the wireless device housing is electrically connected to the power supply fitting.