JP2004274445A - Antenna device and radio equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an antenna device complying with a plurality of communication systems and making the respective bands wide. <P>SOLUTION: The antenna device comprises: a first antenna element 1 resonating with a first frequency; a second antenna element 2 provided at the vicinity of the first antenna element 1, capacitively coupled to the first antenna element 1, and resonating with a second frequency different from the first frequency; phase converters 5, 6 connected to the feeding point of the first antenna element 1 and that of the second antenna element 2, respectively, and adjusting impedance; and band-pass filters 7, 8 connected to each of the phase converters 5, 6, respectively, and passing through a given frequency only. The impedance is adjusted, in feeding to one antenna element, by adjusting the phase converters 5, 6 connected to the other antenna element so that the other antennal element may operate as an parasitic element. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an antenna device and a wireless device, and more particularly to an antenna device and a wireless device suitable for use in a plurality of communication systems.
[0002]
[Prior art]
For example, an antenna mounted on a portable wireless device such as a mobile phone is required to be small and lightweight so as to be convenient to carry. However, if the antenna is simply physically reduced in size, the radiation resistance is reduced and the antenna efficiency is degraded. At the same time, the smaller the antenna, the higher the Q value, and the narrower the specific bandwidth of the antenna. If the antenna is simply physically reduced in size, desired antenna characteristics cannot be satisfied.
[0003]
In recent years, a plurality of communication systems have been required to be mounted on portable wireless devices, and some of them have actually been mounted. As an example of the plurality of communication systems, for example, a dual-band voice call function for making a voice call using two frequencies having different frequency bands, a GPS (Global Positioning System) function, a Bluetooth function (a short-range wireless communication function), and the like. Is mentioned.
[0004]
In this type of portable wireless device, an antenna corresponding to each frequency band is required to support a plurality of communication systems. As a method for satisfying this requirement, there are a method of devising a plurality of different frequencies and respective resonances in a single antenna, and a method of mounting a plurality of antennas resonating with the respective frequencies.
[0005]
However, in the former method, in addition to the complicated design of the antenna, a switch or a duplexer is required in a high-frequency circuit connected to the antenna. For this reason, in this method, an insertion loss of the switch or the duplexer occurs, and the radio characteristics deteriorate. On the other hand, in the latter method, deterioration of antenna characteristics due to interference between antennas, and when a plurality of communication systems operate simultaneously, a carrier transmission wave generated from one communication system and its spurious are mounted on the same portable wireless device. It can be considered that it becomes an interference wave of another communication system and causes a problem in wireless characteristics.
[0006]
Therefore, as a technique for widening the antenna bandwidth, an antenna element having an electrical length of about λ / 4 (λ represents a frequency used in a communication system) having one end connected to a ground conductor, or about λ having both ends open. There is known a method in which another antenna element is arranged near an antenna feeding an antenna element having an electric length of / 2, and the arranged antenna element is operated as a parasitic element. In this method, a double resonance is obtained by inducing a high-frequency current by capacitive coupling in an antenna element arranged close to a fed antenna element.
[0007]
Several antenna devices have been proposed as antennas using this technique (for example, see Patent Document 1, Patent Document 2, Patent Document 3, and Patent Document 4). The built-in antenna for a wireless communication terminal described in Patent Literature 1 employs a configuration in which a parasitic element formed in a rod shape is arranged to face an antenna element forming a dipole antenna. The multi-resonant antenna described in Patent Literature 2 is a chip-shaped ultra-small antenna, and has a structure in which a parasitic element is arranged close to a feed element.
[0008]
The array antenna described in Patent Document 3 arranges a feed element and a parasitic element having a different element length of the feed element at a predetermined interval to obtain a wide band characteristic and adjust the length of the parasitic element at the same time. In addition, the directivity of the antenna can be adjusted as a director or a reflector. The side-by-side coil-fed antenna for portable radio described in Patent Document 4 includes a plurality of helical coils arranged and coupled with a conductive straight portion of the antenna to provide a multi-band antenna structure. In order to sufficiently remove the coupling disturbance, the structure is arranged at a distance from each other.
[0009]
[Patent Document 1]
JP-A-2002-9534 (pages 35 and 36, FIG. 66)
[Patent Document 2]
JP-A-2002-252514 (Pages 3 and 4; FIG. 1)
[Patent Document 3]
JP-A-9-55621 (Pages 3 and 4; FIG. 1)
[Patent Document 4]
JP-A-10-242741 (pages 3 to 5, FIG. 1)
[0010]
[Problems to be solved by the invention]
However, the techniques described in Patent Literature 1, Patent Literature 2, and Patent Literature 3 only take a wide band near the same frequency, and do not have a structure in which a band is taken at a plurality of different frequencies. It is difficult to support a plurality of communication systems. Further, the technology described in Patent Document 4 can support a plurality of communication systems, but it is difficult to increase the bandwidth of each antenna.
[0011]
Therefore, the present invention has been made in view of such a problem, and an object of the present invention is to provide an antenna device and a wireless device that correspond to a plurality of communication systems and have a wide band for each band.
[0012]
[Means for Solving the Problems]
An antenna device according to the present invention includes a first antenna element that resonates with a first frequency, a second antenna element that capacitively couples with the first antenna element and resonates with a second frequency, An impedance adjusting unit is connected to the feeding point of each of the second antenna elements and adjusts impedance. The frequency adjusting unit is connected to the impedance adjusting unit and passes only a predetermined frequency. In this antenna device, when power is supplied to one antenna element, the impedance adjusting means connected to the other antenna element is adjusted, and the impedance is adjusted so that the other antenna element operates as a parasitic element.
[0013]
According to the antenna device of the present invention, when power is supplied to one antenna element, the impedance adjusting means connected to the other antenna element capacitively coupled to this antenna element is adjusted, and the other antenna element operates as a parasitic element. When the impedance is adjusted so that each antenna operates, each antenna operates at its own frequency and has a wide band in each frequency band.
[0014]
A wireless device according to the present invention includes a first antenna element that resonates with a first frequency, a second antenna element that capacitively couples with the first antenna element and resonates with a second frequency, An impedance adjusting unit connected to a feeding point of each of the second antenna elements and adjusting impedance; a frequency passing unit connected to the impedance adjusting unit and passing only a predetermined frequency; and a radio circuit unit transmitting and receiving signals. Is provided. In this antenna device, when power is supplied to one antenna element, the impedance adjusting means connected to the other antenna element is adjusted to adjust the impedance such that the other antenna element operates as a parasitic element. It has a control unit.
[0015]
According to the wireless device of the present invention, when power is supplied to one antenna element, the control unit adjusts the impedance adjustment means connected to the other antenna element that is capacitively coupled to the other antenna element, and disables the other antenna element. Since the impedance is adjusted so as to operate as a feed element, each antenna operates at each frequency and has a wide band in each frequency band.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, specific embodiments of an antenna device and a wireless device to which the present invention is applied will be described in detail with reference to the drawings. In this embodiment, an antenna device and a wireless device according to the present invention are applied to a mobile phone.
[0017]
"First Embodiment"
As shown in FIG. 1, the wireless device is provided with a first antenna element 1 that resonates with a first frequency, and is provided near the first antenna element 1, and is capacitively coupled to the first antenna element 1. In addition, a second antenna element 2 that resonates with a second frequency different from the first frequency, and feed points 3 and 4 of the first antenna element 1 and the second antenna element 2 are connected to adjust the impedance. Phase shifters 5 and 6, which are impedance adjusting means, and band-pass filters 7, 8 which are frequency-passing means respectively connected to the phase shifters 5 and 6 and pass only a predetermined frequency, and wirelessly transmit and receive signals. And a circuit section 9.
[0018]
The antenna shown in FIG. 1 is a notch antenna formed by forming a slit having a predetermined electrical length from one end 10a to a rear end 10b of a ground plane (ground conductor) 10. Each of the first antenna element 1 and the second antenna element 2 is formed to have a crank-shaped planar shape, and resonates at different frequencies. For example, the first antenna element 1 resonates at a frequency of 2 GHz, and the second antenna element 2 resonates at a frequency of 2.5 GHz. The first antenna element 1 and the second antenna element 2 are arranged close to each other at a predetermined distance so as to be capacitively coupled to each other in order to widen the band in each frequency band.
[0019]
It is known that the notch antenna basically resonates when the length of the slit is an electrical length of about λ / 4 of the frequency. In an antenna used in a mobile phone, the impedance between the RF circuit and the antenna is generally of a 50Ω system, and in order to achieve impedance matching with the 50Ω system, the slit short-circuit portions 1a and 2a to the slit open end 1b. , 2b side at a position having a length of about 5 to 15% (this is referred to as offset power supply).
[0020]
Also, in this antenna, when the first antenna element 1 resonates at the first frequency, the second antenna element 2 is operated as a parasitic element (parasitic element) by capacitive coupling, and the second antenna element 2 is operated at the second frequency. When the antenna element 2 is resonated, the first antenna element 1 is operated as a parasitic element by capacitive coupling. For this reason, in this antenna, the electrical length of one antenna element that operates as a parasitic element is determined by changing the electrical length of the antenna element on the power feeding side so that a wide band can be obtained in each frequency band (2 GHz band and 2.5 GHz band). Make it shorter than the electrical length.
[0021]
For example, assuming that power is supplied to the first antenna element 1, the electric length of the second antenna element 2 is shortened by about 10% to 20% of the electric length of the first antenna element 1. This allows the antenna to obtain the widest band characteristics. In the antenna shown in FIG. 1, the electrical length of the second antenna element 2 is shorter than the electrical length of the first antenna element 1.
[0022]
To the feeding points 3 and 4 of the first antenna element 1 and the second antenna element 2, phase shifters 5 and 6 and bandpass filters 7 and 8 are connected in this order. The band-pass filters 7 and 8 are configured to pass only specific frequencies and not to pass frequencies other than the specific frequencies. For example, the band-pass filter 7 connected to the first antenna element 1 passes a high-frequency signal of 2 GHz, but does not pass a high-frequency signal of 2.5 GHz, which is another frequency band. Similarly, the band-pass filter 8 connected to the second antenna element 2 passes a high-frequency signal of 2.5 GHz, but does not pass a high-frequency signal of 2 GHz, which is another frequency band.
[0023]
Note that these band-pass filters 7 and 8 constitute, for example, a part of the RF circuit 11. Although not shown, switches, duplexers, amplifiers, and the like are connected to the band-pass filters 7 and 8.
[0024]
Each of the phase shifters 5 and 6 includes, for example, a capacitor 12 and a coil 13 connected to both ends of the capacitor 12 and having one end grounded, as shown in FIG. The phase shifters 5 and 6 perform impedance adjustment for rotating the phase of a frequency other than the specific frequency passing through the band-pass filters 7 and 8. The phase shifters 5 and 6 and the band-pass filters 7 and 8 will be described later in detail.
[0025]
The wireless circuit section 9 includes an RF circuit 11, a baseband signal circuit 14, and a CODEC (codec) 15. The CODEC 15 encodes an audio signal input from the microphone and sends it to the baseband signal circuit 14, and supplies an audio signal obtained by decoding the signal received from the baseband signal circuit 14 to a speaker. The baseband signal circuit 14 adjusts the signal received from the CODEC 15 to a baseband signal for transmission, sends the signal to the RF circuit 11, and extracts a signal that can be processed by the CODEC 15 from the baseband signal demodulated by the RF circuit 11. The RF circuit 11 supplies an RF signal modulated according to the baseband signal transmitted from the baseband signal circuit 14 to the antenna, and demodulates the baseband signal from the RF signal received via the antenna. The signal is sent to the band signal circuit 14. The CPU, which is a control unit (not shown), controls the operation of the wireless circuit unit 9 based on a predetermined program.
[0026]
Here, in the wireless device having the above-described configuration, the high-frequency current in the 2 GHz band is supplied to the first antenna element 1 while the high-frequency current in the 2 GHz band is supplied to the feeding point 4 of the second antenna element 2. Is performed, the first antenna element 1 is resonated at a first frequency (for example, 2 GHz).
[0027]
In this wireless device, as described above, since the slit length of the second antenna element 2 is shorter than the slit length of the first antenna element 1, high-frequency current is applied to the second antenna element 2 by capacitive coupling. Is induced, and the second antenna element 2 resonates at a higher frequency than the first antenna element 1. For this reason, the second antenna element 2 operates in two roles, that is, a wider band of the notch antenna composed of the first antenna element 1 and a notch antenna that operates at a higher frequency than the first antenna element 1. Become.
[0028]
However, there is a concern that antenna characteristics may be affected depending on the impedance on the circuit side as viewed from the feeding points 3 and 4 of the antenna. That is, a high-frequency signal (high-frequency current) of 2 GHz to be fed to the first antenna element 1 passes through the feeding point 4 depending on the magnitude of the impedance on the circuit side viewed from the feeding point 4 of the second antenna element 2. There is a case where the signal enters the wireless circuit unit 9. In such a case, it is difficult to widen the band of the first antenna element 1 by the second antenna element 2 provided close to the first antenna element 1 to operate as a parasitic element.
[0029]
However, in this wireless device, since the phase shifters 5 and 6 and the band-pass filters 7 and 8 are connected to the feeding points 3 and 4, the phase connected to the non-feeding second antenna element 2 is set. By adjusting the impedance of the antenna 6 so that the second antenna element 2 operates as a parasitic element, the 2 GHz band that resonates with the first antenna element 1 can be broadened. This principle will be described below.
[0030]
The band-pass filters 7 and 8 are designed so that a desired frequency band has an impedance close to the characteristic impedance and a band that does not pass the band has a characteristic of reflection with respect to the characteristic impedance in order to pass a desired band. I have. If this is shown by the Smith chart of FIG. 3 showing the characteristics of an arbitrary band-pass filter, the desired frequency band (for example, 50Ω system) is near the center, and the band not to be passed is traced in a region farther than near the center. Draw. Utilizing this characteristic, a phase shifter 6 is added to the feeding point 4 of the second antenna element 2, and the impedance other than the pass band is adjusted by the phase shifter 6.
[0031]
The phase shifters 5 and 6 are designed with the characteristic impedance of the antenna, and have a role of rotating the locus of the impedance on the Smith chart. That is, the phase shifter 6 connected to the feed point 4 of the second antenna element 2 can adjust the impedance in the frequency band outside the pass band without changing the impedance near the pass band. For example, in this embodiment, the impedance of the second antenna element 2 is set to open (that is, the impedance is infinite), which is the right end on the Smith chart. In FIG. 3, the range in which the impedance is almost open is represented by a dotted line. With this adjustment, the impedance seen from the circuit side from the feed point 4 of the second antenna element 2 looks open, so that the frequency band of the antenna by the first antenna element 1 can be widened.
[0032]
Explaining with a specific example, when the first antenna element 1 is operated as a 2 GHz antenna, the high frequency current of 2 GHz is not supplied to the feeding point 4 of one of the second antenna elements 2, Power is supplied only to the feeding point 3 of the antenna element 1. Then, the non-fed second antenna element 2 is capacitively coupled by the fed first antenna element 1, and a high-frequency current is excited in the second antenna element 2. At this time, since the impedance of the second antenna element 2 is open or short depending on the phase, it cannot be determined whether the impedance is open or short in this state.
[0033]
Therefore, in the phase shifter 6 connected to the feeding point 4 of the second antenna element 2, the 50 Ω system is used so that the second antenna element 2 operates as a 2.5 GHz band antenna in the 2.5 GHz band so that no problem occurs. Is maintained (meaning that the center position is not moved), and the impedance is opened by rotating the phase so that the high frequency signal of the 2 GHz band does not enter the circuit of the 2.5 GHz band. Then, the impedance on the circuit side of the second antenna element 2 as viewed from the feeding point 4 becomes infinite, and the high-frequency signal in the 2 GHz band does not enter the circuit side connected to the second antenna element 2.
[0034]
As a result, the first antenna element 1 operates as a so-called antenna with a parasitic element using the second antenna element 2 as a parasitic element, so that the 2 GHz band is widened in this wireless device. FIG. 4A is a Smith chart showing that the band is widened in the 2 GHz band. As can be seen from the Smith chart, it can be seen that the α-type trajectory that has a broadband characteristic is clearly shown in this chart.
[0035]
On the other hand, when the second antenna element 2 is operated as a 2.5 GHz antenna, the high frequency current of 2.5 GHz is not supplied to the feeding point 3 of the first antenna element 1 and the second antenna element 2 Power is supplied only to the power supply point 4 of No. 2. Then, the first antenna element 1 to which the 2.5 GHz high-frequency signal (high-frequency current) is not fed is capacitively coupled by the fed second antenna element 2, and the first antenna element 1 has a high-frequency current. Is excited. At this time, it is impossible to determine whether the impedance of the first antenna element 1 is open or short based on the phase in this state, as in the previous example.
[0036]
Therefore, in the phase shifter 5 connected to the feed point 3 of the first antenna element 1, the 50Ω system is maintained while maintaining the 50Ω system so that no problem occurs in the 2GHz band in which the first antenna element 1 operates as a 2GHz band antenna. The impedance is adjusted by rotating the phase so that the high frequency signal of the 2.5 GHz band does not enter the circuit of the 2 GHz band. At this time, if the impedance is opened as described above, the first antenna element 1 operates as a parasitic element having an electrical length longer than that of the second antenna element 2, so that the 2.5 GHz band is broadened. It becomes difficult to do.
[0037]
Therefore, in the phase shifter 5 connected to the feeding point 3 of the first antenna element 1, the impedance on the circuit side as viewed from the feeding point 3 of the first antenna element 1 becomes short-circuit (impedance 0Ω) at the left end of the Smith chart. adjust. By this adjustment, in the frequency band in which the second antenna element 2 resonates, the first antenna element 1 is equivalently short-circuited at the feeding point 3 of the first antenna element 1 as shown in FIG. The first antenna element 1 operates as a parasitic element shorter than the second antenna element 2 because the first antenna element 1 appears as a notch antenna.
[0038]
As a result, the second antenna element 2 operates as a so-called antenna with a parasitic element using the first antenna element 1 as a parasitic element, so that the band of the 2.5 GHz band is widened in this wireless device. FIG. 4B is a Smith chart showing that the band has been widened in the 2.5 GHz band. In this Smith chart, it can be seen that an α-type locus is shown in the chart as in the case of 2 GHz.
[0039]
Therefore, in this wireless device, two notch antennas can be operated at different frequencies, and broadband matching can be achieved by using the other notch antenna as a parasitic element in each frequency band. . As a result, the wireless device can realize a wide band in each band while supporting antennas in different frequency bands, and can perform a plurality of communication such as voice communication, GPS, or short-range wireless communication. Compatible with wireless devices equipped with a system.
[0040]
In the above example, when the first antenna element 1 is operated as a 2 GHz antenna, the second antenna element 2 is not operated as a 2.5 GHz antenna, and the second antenna element 2 is operated at 2.5 GHz. Although the present embodiment has been described in the case where the first antenna element 1 is not operated as a 2 GHz antenna when the antennas are operated as the above antennas, the same operation and effect can be obtained by operating these antennas having different frequencies simultaneously. Needless to say. That is, when the first antenna element 1 is operated as a 2 GHz antenna and the second antenna element 2 is operated as a 2.5 GHz antenna at the same time, the same operation and effect as in the above-described example can be obtained.
[0041]
"Second embodiment"
As shown in FIG. 6, the wireless device according to the second embodiment is an example in which the first antenna element 1 and the second antenna element 2 are notch antennas having a substantially straight planar shape. Here, the electrical length of the second antenna element 2 is set to be longer than the electrical length of the first antenna element 1. However, as in the wireless device of the first embodiment, the first antenna element 2 The electrical length of the first antenna element 2 may be longer than the electrical length of the second antenna element 2. Other configurations are the same as those of the wireless device according to the first embodiment.
[0042]
When the electric length of the second antenna element 2 is longer than the electric length of the first antenna element 1 as in this wireless device, the case where the phase is operated in the first embodiment is Need to do the opposite. That is, when operating the first antenna element 1 as a 2 GHz band antenna, in the first embodiment, the phase shifter 6 connected to the second antenna element 2 is shifted in phase so that the impedance is open. However, here, the phase is shifted so that the impedance is short-circuited.
[0043]
"Third embodiment"
As shown in FIG. 7, the wireless device according to the third embodiment is an example in which the first antenna element 1 and the second antenna element 2 are antenna elements forming a monopole antenna. Even in a wireless device using an antenna element as a monopole antenna, the two monopole antennas can operate at different frequencies, as in the wireless device of the first embodiment, and the other in each frequency band. Broadband matching can be achieved by using a monopole antenna as a parasitic element.
[0044]
Although FIG. 7 shows a monopole antenna, the first antenna element 1 and the second antenna element 2 are helical antenna, loop antenna, meander antenna, meander line antenna, zigzag antenna (comb-shaped antenna). And so on.
[0045]
"Fourth embodiment"
As shown in FIG. 8, the wireless device according to the fourth embodiment differs from the wireless device according to the third embodiment in that the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6 are different from each other. This is an example in which matching circuits 16 and 17 are provided between them. In this wireless device, since the matching circuits 16 and 17 are provided, adjustment of impedance characteristics can be more easily performed.
[0046]
Although the matching circuits 16 and 17 are provided between the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6 in FIG. 5 and 6 and the band-pass filters 7 and 8 may be provided.
[0047]
"Fifth embodiment"
As shown in FIG. 9, the wireless device according to the fifth embodiment differs from the wireless device according to the third embodiment in that the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6 are different from each other. This is an example in which connectors 18 and 19 as connection means for connecting an external antenna are provided between them. That is, the connectors 18 and 19 are provided between the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6 via the switch circuits 20 and 21.
[0048]
The connectors 18 and 19 are connected to connectors provided on an in-vehicle antenna mounted on, for example, an automobile. Note that the connectors 18 and 19 can also be used as connectors for measuring the RF output from the RF circuit 11.
[0049]
In FIG. 9, the connectors 18 and 19 are provided between the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6. 6 and the band-pass filters 7 and 8 may be provided.
[0050]
"Sixth embodiment"
As shown in FIG. 10, the radio apparatus according to the sixth embodiment can operate each monopole antenna at three different frequencies, and use the other monopole antenna in each frequency band. Broadband matching can be achieved by using it as a feed element.
[0051]
In FIG. 10, in addition to the first antenna element 1 and the second antenna element 2 constituting the monopole antenna, a third antenna element 22 and a phase shifter connected to a feed point 23 of the third antenna element 22 This is an example in which 24 and a band-pass filter 25 are provided. In the wireless device of this embodiment, each bandwidth can be widened in three different frequency bands, and the wireless device can be used in three communication systems.
[0052]
Although FIG. 10 shows an example in which three different frequencies are used, the wireless device according to the present embodiment can be used in a communication system that uses three or more different frequency bands. In that case, an antenna element, a phase shifter, and a band-pass filter corresponding to the number of frequencies are used.
[0053]
"Seventh embodiment"
As shown in FIG. 11, the wireless device according to the seventh embodiment is configured such that the first antenna element 1 and the second antenna element 2 are inverted F antennas. Other configurations are the same as those of the wireless device of the first embodiment.
[0054]
When the first antenna element 1 and the second antenna element 2 are inverted F antennas, the two inverted F antennas can be operated at different frequencies, similarly to the wireless device of the first embodiment. In each frequency band, wideband matching can be achieved by using the other inverted F antenna as a parasitic element.
[0055]
As described above, the specific embodiments to which the present invention is applied have been described, but the present invention is not limited to the above-described embodiments, and various changes can be made.
[0056]
For example, in the wireless devices of the first to seventh embodiments described above, a circuit for changing the characteristic impedance is provided between the first antenna element 1 and the second antenna element 2 and the phase shifters 5 and 6. It may be provided. For example, in the above-described embodiment, the characteristic impedance is set to 50Ω, but this characteristic impedance may be changed to 30Ω. If the circuit is provided, the wireless device according to the seventh embodiment is suitable for changing the frequency ratio at which wideband characteristics can be obtained and adjusting the isolation between antennas.
[0057]
Further, in the above-described embodiment, the description has been given by taking the mobile phone as an example. However, the present invention is not limited to the mobile phone. Even when the present invention is applied to a portable communication terminal device, the same operation and effect can be obtained.
[0058]
【The invention's effect】
According to the antenna device of the present invention, a plurality of antennas are operated at different frequencies in order to adjust the impedance adjusting means connected to the antenna element and adjust the impedance so that the antenna element operates as a parasitic element. And broadband matching can be achieved in each frequency band.
[0059]
According to the wireless device of the present invention, the control unit adjusts the impedance so as to operate the antenna element as a parasitic element by adjusting the impedance adjustment unit connected to the antenna element. It can be operated at different frequencies, can achieve wideband matching in each frequency band, and can correspond to a plurality of communication systems.
[Brief description of the drawings]
FIG. 1 is a functional block diagram illustrating a wireless device according to a first embodiment.
FIG. 2 is an enlarged functional block diagram illustrating a main part of the wireless device according to the first embodiment;
FIG. 3 is a Smith chart showing characteristics of an arbitrary band-pass filter.
FIGS. 4A and 4B are Smith charts showing simulation results for band matching in the wireless device of the first embodiment, in which FIG. 4A is a Smith chart in a 2 GHz band, and FIG. 4B is a Smith chart in a 2.5 GHz band. is there.
FIG. 5 is a diagram equivalently showing the antenna when the impedance on the circuit side as viewed from the feed point of the first antenna element is adjusted to be short-circuited in the wireless device of the first embodiment.
FIG. 6 is a functional block diagram illustrating a wireless device according to a second embodiment;
FIG. 7 is a functional block diagram illustrating a wireless device according to a third embodiment.
FIG. 8 is a functional block diagram illustrating a wireless device according to a fourth embodiment.
FIG. 9 is a functional block diagram illustrating a wireless device according to a fifth embodiment.
FIG. 10 is a functional block diagram illustrating a wireless device according to a sixth embodiment.
FIG. 11 is a functional block diagram illustrating a wireless device according to a seventh embodiment.
[Explanation of symbols]
1. First antenna element
2. Second antenna element
3, 4, 23 ... feeding point
5, 6, 24 ... phase shifter
7, 8, 25 ... band pass filter
9 Radio circuit
10: Ground plate
11 ... RF circuit
14. Baseband signal circuit
15: CODEC (codec)
16, 17… Matching circuit
18, 19… Connector
22... Third antenna element

Claims (7)

A first antenna element that resonates with a first frequency;
A second antenna element provided near the first antenna element, capacitively coupled to the first antenna element, and resonating with a second frequency different from the first frequency;
Impedance adjustment means connected to feed points of the first antenna element and the second antenna element, respectively, for adjusting impedance;
A frequency passing unit connected to each of the impedance adjusting units and passing only a predetermined frequency,
An antenna device, comprising: adjusting the impedance adjusting means connected to the other antenna element when feeding one antenna element to adjust the impedance such that the other antenna element operates as a parasitic element. . The antenna device according to claim 1,
At least two or more antenna components including antenna elements having different resonance frequencies, impedance adjusting means connected to a feeding point of the antenna element, and frequency passing means connected to the impedance adjusting means. Characteristic antenna device. The antenna device according to claim 1,
An antenna device, wherein a matching circuit is provided between the antenna element and the impedance adjusting unit. The antenna device according to claim 1,
An antenna device, wherein a matching circuit is provided between the impedance adjusting unit and the frequency passing unit. The antenna device according to claim 1,
An antenna device, wherein a connection means for connecting an external antenna is provided between the antenna element and the impedance adjustment means. The antenna device according to claim 1,
An antenna device, wherein a connection means for connecting an external antenna is provided between the impedance adjustment means and the frequency passing means. A first antenna element that resonates with a first frequency;
A second antenna element provided near the first antenna element, capacitively coupled to the first antenna element, and resonating with a second frequency;
Impedance adjustment means connected to feed points of the first antenna element and the second antenna element, respectively, for adjusting impedance;
Frequency passing means connected to each of the impedance adjusting means and passing only a predetermined frequency,
A radio circuit unit for transmitting and receiving signals,
A control unit that adjusts the impedance so as to adjust the impedance adjustment unit connected to the other antenna element when the power is supplied to one of the antenna elements, so that the other antenna element operates as a parasitic element. A wireless device characterized by the above-mentioned.

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