KR19980701595A - ANTENNA - Google Patents

Abstract

When the antenna element is extended, the helical element 4 becomes a non-powered element, and the helical element 4 is excited at high frequency by the high frequency current flowing through the element conductor 3. Become a parasitic element. In the case where the antenna element is stored, power is fed from the upper end of the upper conductor part 6 to the upper end of the helical element 4 so that the overlapping portion of the helical element 4 and the upper conductor part 6 is an L-C parallel resonant circuit. To form. This causes the antenna to perform two resonant operations.

Description

antenna

An outline of this type of conventional antenna is shown in Figs. 5A and 5B. An antenna of type A shown in Fig. 5A has an antenna element and a helical element having an insulating portion 109 formed on the element conductor 103, as described in JP-A-6-216630. 104). The antenna element can slide in the helical element 104 to be accommodated in the case body 100, and the accommodated antenna element can extend from the case body 100. The helical element 104 is fixedly installed in the upper protrusion of the case body 100.

A state in which the antenna element of such an antenna is slid and extended is shown in FIG. 5A. In this case, the signal from the signal source 102 in the case body 100 is supplied to the power supply unit 105 via the matching circuit (MC) 101. And the power supply part 105 is electrically connected to the lower end of the element conductor 103 and the lower end of the helical element 104, and the element conductor 103 and the helical element 104 become an operation state.

Moreover, the state which accommodated in the case body 100 by sliding an antenna element is shown to the same figure (b). In this case, the signal from the signal source 102 in the case body 100 is supplied to the feed section 105 through the matching circuit (MC) 101, which feeds the lower end of the helical element 104. Are electrically connected only to the helical element.

In this case, the insulating portion 106 formed on the antenna element is located in the helical element 104 so that the antenna element does not affect the helical element 104.

Moreover, the outline | summary of the conventional type B antenna which is different from the above-mentioned antenna is shown to FIG. 5 (B). As described in Japanese Patent Laid-Open No. 2-271701, the antenna is composed of an antenna element and a helical element 104 having insulation portions 106 formed on the upper and lower portions of the coil-shaped element conductor 103. The antenna element may slide in the helical element 104 and be accommodated in the case body 100, and the received antenna element may extend from the case body 100.

In addition, the helical element 104 is fixedly installed in the upper protrusion of the case body.

The state in which the antenna element of such an antenna is slid and extended is shown in (a) of FIG. In this case, the signal from the signal source 102 in the case body 100 is supplied to the power supply unit 105 via the matching circuit (MC) 101. And the power supply part 105 is electrically connected to the lower end of the helical element 104, and the helical element 104 is excited. Since the helical element 104 and the coil-like element conductor 103 are dielectrically coupled, the helical element 104 is excited to excite the dielectric conductor element 103.

Thus, the antenna element and helical element 104 are put into operation. At this time, the insulating portion 106 formed under the antenna element is located in the helical element 104.

Moreover, the state which accommodated in the case body 100 by sliding an antenna element is shown in FIG. In this case, the signal from the signal source 102 in the case body 100 is supplied to the power supply unit 105 via the matching circuit (MC) 101 and connected to the power supply unit 105. Becomes the operating state. At this time, the coil-shaped element conductor 103 is housed in the case body 100 to be in an inoperative state.

In this case, the insulating portion 106 formed on the antenna element is located in the helical element 104 so that the antenna element does not affect the helical element 104.

Next, the operation of the antenna will be described. In the conventional type A antenna described above, when the antenna element is extended, the element conductor 103 and the helical element 104 are connected in parallel. At this time, since the helical element 104 acts to increase the equivalent thickness of the element conductor 103, consequently, the frequency-to-impedance characteristic is wider than that of the element conductor 103 alone. (廣 帶 域) is displayed. The characteristic of the frequency-to-voltage standing wave ratio VSWR at this time is shown as type A in Fig. 3 (a), but since the resonance frequencies of the helical element 104 and the element conductor 103 are set equal to each other, I) become a characteristic.

When the antenna element is accommodated in the conventional type A antenna, only the helical element 104 is operated, resulting in an L-C series resonance antenna. Therefore, the frequency versus VSWR characteristic at this time becomes a single resonance characteristic as shown as types A and B in Fig. 3B.

When the antenna element is extended in the conventional type B antenna described above, the helical element 104 is connected to the feed section. At this time, the helical element 104 is dielectrically coupled to the element conductor 103, which is a non-powered element, to impart an excitation to the element conductor 103 at high frequency. At this time, the characteristics of the frequency-to-voltage standing wave ratio VSWR are shown as type B in Fig. 3 (a). However, since the resonance frequencies of the helical element 104 and the element conductor 103 are set to be the same, the single resonance characteristic do.

In the case where the antenna element is accommodated in the conventional type B antenna, only the helical antenna 104 is operated, so that it becomes an L-C series resonance antenna. Therefore, the frequency versus VSWR characteristic at this time becomes a single resonance characteristic as shown by types (A, B) in Fig. 3B.

By the way, in the portable telephone, as shown by the frequency axis shown in FIG. Therefore, it is necessary for the antenna of the cellular phone to characterize the transmitter and receiver.

However, as shown in Fig. 3, the conventional type A and type B antennas exhibit short resonance characteristics both at the time of extension and at the time of storage, so that appropriate characteristics covering the transmission and reception stages cannot be obtained. There was this.

Therefore, an object of the present invention is to provide an antenna capable of covering a transmission band and a reception band allocated to different frequencies at the time of expansion and storage.

Disclosure of the Invention

In order to achieve the above object, the antenna of the present invention is an antenna having an antenna element and a helical element having an upper conductor portion through an insulating portion on the element conductor, the antenna element is freely stretched by sliding in the helical antenna And a lower end of the antenna element becomes a feeder in the state where the antenna element is extended, and an upper end of the helical element and an upper end of the upper conductor part are connected while the lower end of the upper conductor part is connected. It is intended to be a feed section.

In the above antenna, the antenna element is free to slide in a holder conductor connected to a circuit in a case body, and a lower end of the antenna element and the holder conductor are connected while the antenna element is extended, and the antenna element Is connected to the lower portion of the upper conductor portion and the holder conductor,

In addition, when the antenna element is extended and stored, the antenna element and the helical element are operated as two resonant antennas.

According to the antenna of the present invention, since the antenna consisting of the antenna element and the helical element is subjected to two resonance operations, the characteristics of the antenna capable of covering the transmission band and the reception band allocated to different frequencies at the time of extension and storage are obtained. It becomes possible.

The present invention relates to an antenna in which sliding is freely installed in a case body, and particularly, when applied to a portable radiotelephone.

FIG. 1 (a) is a diagram showing an outline of the configuration at the time of extension of the embodiment of the antenna of the present invention, and FIG. 1 (b) is a diagram showing the outline of the configuration at the time of storing the embodiment of the antenna of the present invention.

Fig. 2 (a) is a diagram showing a detailed configuration example at the time of extension of the embodiment of the antenna of the present invention, and Fig. 2 (b) is a diagram showing a detailed configuration example at the time of storing the embodiment of the antenna of the invention.

Fig. 3 (a) is a diagram showing the characteristics of the frequency band VSWR when the antenna of the present invention and the conventional antenna are stretched, and Fig. 3 (b) is a diagram showing the characteristics of the frequency vs VSWR when the antenna of the present invention and the conventional antenna are stored. to be.

4 is a diagram showing another detailed configuration example of the embodiment of the antenna of the present invention.

Fig. 5A is a diagram showing the configuration of a conventional type A antenna, and Fig. 5B is a diagram showing the construction of a conventional type B antenna.

In order to describe the present invention in more detail, it will be described according to the accompanying drawings.

Fig. 1 (a) and (b) show a schematic configuration of an embodiment of the antenna of the present invention, and in Fig. 1 (a) and (b), the antenna is formed through the insulating portion 8 on the element conductor 3. It consists of an antenna element with an upper conductor part 6 and a helical element 4.

In this antenna, the antenna element slides inside the helical element 4 so that the antenna element is freed from the inside of the case body 10, and the state in which the antenna element is accommodated in the case body 10 is shown in Fig. 1B. 1A shows a state where the antenna element is extended from the case body 10. In addition, the helical element 4 is fixedly installed in the upper protrusion of the case body 10.

When the antenna element of such an antenna is extended, the signal from the signal source 2 in the case body 10 is supplied to the power supply part 5 via the matching circuit MC 1. And the power supply part 5 is electrically connected to the lower end of the element conductor 3, and the element conductor 3 will be in an operation state. At this time, the helical element 4 becomes a non-powered element which is not connected anywhere, but the helical element 4 is excited at high frequency by the high frequency current flowing through the element conductor 3.

Moreover, as shown in the same figure (b), in the state accommodated in the case body 10, the signal from the signal source 2 in the case body 10 receives the matching circuit MC (1). The feeder 5 is supplied through the feeder 5, which is electrically connected to the lower end of the upper conductor part 6 above the antenna element. The upper end of the helical element 4 is also electrically connected at the connection point 7 to the upper end of the upper conductor part 6. Thus, the helical element 4 is driven through the upper conductor portion 6.

In this case, the element conductor 3 is insulated from the upper conductor portion 6 by the insulating portion 8 to be in an inoperative state.

Next, the operation of the antenna of the present invention will be described. When the antenna element is extended, the element conductor 3 is connected to the feed section 5 so that the element conductor 3 is excited. At this time, the helical element 4 acts as a parasitic element excited by a high frequency current flowing through the element conductor 3, for example, the resonance frequency of the helical element 4 is set to the center frequency of the mobile station receiver. Since the resonant frequency of the element conductor 3 is set to the center frequency of the mobile station transmission table, two resonance characteristics can be obtained in the frequency vs. impedance characteristic.

In other words, the characteristics of the frequency-to-voltage standing wave ratio VSWR of the antenna at the time of extension become two resonance characteristics covering the assigned mobile station transmission zone and the mobile station reception zone as shown in FIG. 3 (a) as the present invention.

In the antenna of the present invention, when the antenna element is accommodated, the upper conductor portion 6 is connected to the feed section 5, and the upper end of the upper conductor portion 6 is connected to the helical element 4, so that Distribution capacity occurs at the overlapping portion of the conductor portion 6 and the helical element 4. Therefore, since the L-C parallel resonant circuit is configured, a resonant frequency different from the natural resonant frequency of the upper conductor part 6 can be obtained. As a result, two resonance characteristics can be obtained.

That is, the characteristics of the frequency band VSWR of the antenna at the time of storing are two resonance characteristics covering the assigned mobile station transmission zone and the mobile station reception zone as shown in FIG. 3 (b) as the present invention.

As described above, the antenna of the present invention makes the resonant frequencies of the element conductor 3 and the helical element 4 different so as to perform a two-resonance operation covering the mobile station transmitter and the mobile station receiver in stretching and storing. As an example, an example of the detailed structure is shown to FIG. 2 (a) (b).

FIG. 2A is a diagram illustrating a state in which the antenna element is extended from the case body 10, and FIG. 2B is a diagram illustrating a state in which the antenna element is accommodated in the case body 10.

In the antenna element shown to Fig.2 (a), (b), the insulated antenna saw 13 is formed in the front-end | tip, and the upper conductor is located in the lower outer periphery of the extending | stretching part extended downward from this antenna upper part 13. Part 6 is fitted. The lower end of the extending part of the antenna upper part 13 protrudes from the lower end of this upper conductor part 6, and this protruding extending part and the upper end of the element conductor 3 are integrated by shaping | molding.

An insulating tube 9 is fitted into the outer circumference of the element conductor 3, and a stopper conductor 11 is inserted into the lower end of the element conductor 3 from above the insulating tube 9 so that the element conductor 3 can be inserted. And the stopper conductor 11 are electrically connected.

The antenna element slides freely into the holder conductor 12 fixed to the case body 10 by inserting into the helical element 4 accommodated in the outer protrusion of the case body 10. The holder conductor 12 is electrically connected to the matching circuit 1, and the matching circuit 1 is connected to the signal source 2.

When the antenna transmits, the signal source 2 corresponds to the signal source 2 at the last end of the transmission unit provided in the case body 10. When the antenna receives the signal source 2, the signal source 2 is a case body ( Corresponds to the reception signal supplied to the reception section provided within the circuit 10).

As shown in Fig. 2 (a), when the antenna element is extended, the stopper conductor 11 inserted into the lower end of the element conductor 3 is fitted into the holder conductor 12 and electrically connected to each other. The signal source 2 connected via 1) is connected to the element conductor 3 via the holder conductor 12 and the stopper conductor 11. At this time, by the high frequency current flowing through the element conductor 3, the helical element 4 made of a non-powered element which is not connected anywhere is coupled with the element conductor 3 at high frequency so that the helical element 4 is a parasitic element. Acts as.

In addition, the upper conductor part 6 does not function as an antenna by the action of the insulating part 8.

When the antenna element is accommodated in the case body 10 as shown in the same figure (b), the antenna upper part 13 abuts on the outer protrusion part of the case body 10, and the upper conductor part 6 makes the helical element 4 It is inserted in the inside thereof, and its lower part is fitted into the holder conductor 12 so as to be electrically connected. Thus, the signal source 2 connected via the matching circuit 1 is connected to the lower portion of the upper conductor portion 6 via the holder conductor 12. At this time, the upper end of the upper conductor part 6 is connected to the upper end of the helical element 4 so that a high frequency current flows through the upper conductor part 6 and the helical element 4.

In addition, the element conductor 3 is brought into an inoperative state by the action of the insulating portion 8. The overlapping portion of the upper conductor portion 6 and the helical element 4 constitutes an L-C parallel resonant circuit.

Next, another example of the detailed structure of the antenna of this invention is shown in FIG. The antenna shown in this figure is different from the structure of the antenna shown in FIG.2 (a) (b) in that it is not integrated with the case body 10, and is comprised independently. The operation of the antenna is the same as that of the antenna shown in FIG.

4 shows an extended state of the antenna element, and a stopper 11 electrically connected to the lower end of the element conductor 3 inserted into the insulation tube 9 is fitted to the lower end of the holder conductor 12. . At this time, the holder conductor 12 and the element conductor 3 are connected, and the element conductor 3 is connected to the matching circuit 1 and the like built in the case body 10.

Therefore, the helical element 4 made of a non-powered element coupled to the element conductor 3 at high frequency by the high frequency current flowing through the element conductor 3 is disposed in the helical element cover 14 formed of resin or the like. This helical element cover 14 is fixed to the upper part of the holder conductor 12.

When attaching the antenna thus constructed to the case body 10, the antenna 10 may be attached to the case body 10 using the attachment screw portion 12-1 formed on the lower portion of the holder conductor 12.

In addition, in the antenna of the present invention described above, since the element conductor 3 is formed of an elastic material, the element conductor 3 coated with the insulation tube 9 has flexibility and is extended. Even if the antenna element collides with an obstacle or the like, breakage of the antenna element can be prevented.

In the stretching and storing, the operation mode of the antenna can be any length from about 1/4 wavelength to about 1/2 wavelength. In this case, the matching circuit 1 can be omitted under conditions close to 1/4 wavelength.

Since the resonant frequency of the element conductor and the resonant frequency of the helical element are different from each other as described above, the antenna of the present invention acts as a parasitic element when the helical element is a non-powered element, thereby performing two resonant operations, In this case, the overlapping portion of the upper conductor portion and the helical element forms an L-C parallel resonance circuit, thereby performing two resonance operations.

Therefore, the antenna of the present invention can be used as a two-resonant antenna that can cover the mobile station transmitter and the mobile station receiver in the case of extension and storage. Therefore, the antenna of the present invention is suitable when applied to a portable device, especially a portable radiotelephone.

Claims (3)

An antenna having an upper conductor portion and an helical element having an upper conductor portion through an insulation portion over an element conductor, The antenna element is freely stretched by sliding in the helical antenna, and the lower end of the antenna element is a feeding part in the state where the antenna element is extended, and the top and the top of the helical element in the state where the antenna element is accommodated. And an upper end of the upper conductor part is connected and a lower end of the upper conductor part is a feeder. The antenna element according to claim 1, wherein the antenna element is free to slide in a holder conductor connected to a circuit in a case body, and a lower end of the antenna element and the holder conductor are connected while the antenna element is extended, and the antenna element And the holder conductor is connected to a lower portion of the upper conductor portion in a state in which the upper conductor portion is accommodated. The antenna according to claim 1 or 2, wherein, when the antenna element is extended and stored, the antenna element and the helical element operate as two resonant antennas.