Source: https://patents.google.com/patent/JP5516681B2/en
Timestamp: 2020-01-20 15:08:45
Document Index: 86361033

Matched Legal Cases: ['art 31', 'art 33', 'art 33', 'art 32', 'art 31', 'art 32', 'art 33', 'art 41', 'art, 142']

JP5516681B2 - Multi-mode antenna, manufacturing method thereof, and portable radio terminal using the antenna - Google Patents
Multi-mode antenna, manufacturing method thereof, and portable radio terminal using the antenna Download PDF
JP5516681B2
JP5516681B2 JP2012212012A JP2012212012A JP5516681B2 JP 5516681 B2 JP5516681 B2 JP 5516681B2 JP 2012212012 A JP2012212012 A JP 2012212012A JP 2012212012 A JP2012212012 A JP 2012212012A JP 5516681 B2 JP5516681 B2 JP 5516681B2
JP2012212012A
JP2013021716A (en
智之 小川
守彦 池ヶ谷
圭介 福地
2003-11-13 Priority to JP2003383647 priority Critical
2003-11-13 Priority to JP2003383647 priority
2012-09-26 Application filed by 日立金属株式会社 filed Critical 日立金属株式会社
2012-09-26 Priority to JP2012212012A priority patent/JP5516681B2/en
2013-01-31 Publication of JP2013021716A publication Critical patent/JP2013021716A/en
2014-06-11 Publication of JP5516681B2 publication Critical patent/JP5516681B2/en
The present invention relates to an antenna of a wireless terminal that provides a multimedia service to a user. In particular, the present invention is suitable for a multimedia wireless terminal that is suitably applied to a multimedia wireless terminal that performs a plurality of services by information transmission using electromagnetic waves of different frequencies. The present invention relates to an antenna and a manufacturing method thereof, and relates to a portable wireless terminal using the antenna.
In recent years, multimedia services that provide various information transmission and information provision services using wireless communication are becoming popular, and many wireless terminals have been developed and put into practical use.
These services have been diversified year by year such as telephone, television, LAN (Local Area Network), etc., and in order for the user to enjoy all the services, they have a wireless terminal corresponding to each service.
In order to improve the convenience of users who enjoy such services, there has been a movement to provide multimedia services to users without being aware of the existence of media anytime, anywhere. So-called multi-mode terminals that realize a plurality of information transmission services are partially realized.
Since a normal wireless ubiquitous information transmission service uses electromagnetic waves as a medium, a plurality of services are provided to the user by using one frequency for one type of service in the same service area. Therefore, the multimedia terminal has a function of transmitting and receiving electromagnetic waves having a plurality of frequencies.
In a conventional multimedia terminal, for example, a method of preparing a plurality of single mode antennas corresponding to one frequency and mounting them on one wireless terminal is adopted. In this method, in order to operate each single mode antenna independently, it is necessary to install them at a distance of about a wavelength, and the frequency of electromagnetic waves used for services related to ordinary ubiquitous information transmission is free space propagation characteristics. Therefore, the distance between the antennas is several tens of centimeters to several meters, so that the terminal size is increased and the convenience for carrying the user is not satisfied. In addition, since antennas having sensitivity to different frequencies are arranged at a distance, it is necessary to separate and install a high-frequency circuit coupled to the antenna for each frequency.
For this reason, it is difficult to apply semiconductor integrated circuit technology, and there is a problem that not only the terminal size increases but also the cost of the high-frequency circuit increases. Even if the integrated circuit technology is applied and the entire circuit is integrated, it is necessary to connect the high-frequency circuit to the antenna separated from each other by a high-frequency cable. By the way, the shaft diameter of the high-frequency cable that can be applied to a terminal having a size portable by the user has a diameter of 1 mm inside or outside. Therefore, at present, the transmission loss of the high-frequency cable reaches several dB / m. The use of such a high-frequency cable increases the power consumed by the high-frequency circuit, causing a significant decrease in the usage time of the terminal providing the ubiquitous information service or a significant increase in the weight of the terminal due to an increase in the battery volume. There is a problem that the convenience of the user who does this is significantly impaired.
One of the important elements for solving the various problems of the multimode wireless terminal that provides a plurality of information services to the user is a multimode antenna having sensitivity to electromagnetic waves of a plurality of frequencies. The antenna structure has a single feeding point corresponding to a plurality of frequencies, and is electrically coupled to the high-frequency circuit unit of the multi-mode terminal to transmit and receive communication signals between the free space and the high-frequency circuit unit. Several multimode antennas that enable this have already been proposed.
As a conventional multimode antenna, for example, there is a two-mode antenna disclosed in Patent Document 1. This antenna has a structure in which a U-shaped slit is formed by removing a part of a conductive flat plate, and an L-shaped conductor is added in the U-shaped slit. The U-shaped slit operates at the first frequency, and the L-shaped conductor mainly operates at the second frequency. The radiation mechanism of electromagnetic waves in each frequency region is based on radiation elements including structures that are orthogonal to each other.
As another example of a conventional two-mode antenna, Patent Document 2 describes an antenna in which two opposing linear conductors are formed inside a conductor having a slit. The linear conductor also operates as a feed line for the slit, and electromagnetic waves having different frequencies are transmitted and received between the slit and the feed line. The operation principle is the same as that of Patent Document 1.
JP 2003-101326 A JP 2003-152430 A
In the above-described conventional multimode antenna, in order to efficiently radiate electromagnetic waves in free space at different frequencies, a plurality of radiation conductors that operate almost independently with little interference are arranged orthogonally. Then, it is necessary to adopt an antenna structure in which the slit and the linear conductor are made different structures and operate independently at different frequencies. Therefore, as the frequency of the electromagnetic wave to be radiated increases, the number of independent structures increases, and it becomes extremely difficult to keep the size or volume of the multimode antenna small as a whole. Actually, the above Patent Documents 1 and 2 do not show a multimode antenna having three or more modes.
An object of the present invention is to provide a small multimode antenna for realizing an inexpensive and small multimedia wireless terminal, in particular, an antenna that operates not only in two modes but also in three or more modes, and a method for manufacturing the same. The object is to provide a portable wireless terminal equipped with the antenna.
In order to achieve the above object, an antenna according to the present invention includes a ground conductor having a ground potential, a single feed point having a part of the ground conductor as one end, and a plurality of high frequency powers supplied to the feed point. A plurality of transmission lines that radiate electromagnetic waves of a certain frequency to space, and the plurality of transmission lines include a transmission line that radiates electromagnetic waves of a plurality of frequencies to the space in common, with respect to the plurality of frequencies at the feeding point. Thus, impedance matching is performed.
The antenna of the present invention for achieving the above object also includes a ground conductor having a ground potential, a single feeding point having one end of the grounding conductor as one end, and high-frequency power supplied to the feeding point. A plurality of transmission lines that input and radiate electromagnetic waves of a plurality of frequencies into the space, and the plurality of transmission lines include a transmission line that radiates electromagnetic waves of the plurality of frequencies to the space in common, and the plurality of frequencies is 2 In the case of frequency, the plurality of transmission lines include a transmission line having one end connected to a feeding point and the other end connected to a branch point, and a transmission line connected to the branch point. In the above case, the plurality of transmission lines have one end connected to the feeding point and the other end connected to the branch point, the transmission line connected between the branch points, and the transmission connected to the branch point. For multiple frequencies at the feed point Wherein the length of each of said plurality of transmission lines are set such impedance matching is performed.
The antenna of the present invention having a plurality of transmission lines as constituent elements includes a transmission line that radiates electromagnetic waves in a free space in common in a plurality of frequency bands. For a point, a distributed constant matching circuit that realizes impedance matching at each operating frequency of the multimode is formed.
By considering the electromagnetic wave energy radiated from the transmission line to free space as the energy lost by the distributed constant circuit consisting of the transmission line, and by considering this as the loss, the normal distributed constant circuit theory is expanded, Impedance matching conditions for a single feed point at the operating frequency can be designed. The antenna of the present invention does not embed a plurality of antenna structures that operate at different frequencies in a small volume like a conventional antenna, but from the entire structure composed of a plurality of transmission lines in each frequency band to be operated. Radiates electromagnetic energy non-locally. Then, impedance matching between the free space and the high-frequency circuit unit coupled to the antenna feeding unit is performed with the reactance component of the transmission line.
In a conventional configuration in which a plurality of antenna structures operating at different frequencies are integrated in a small volume, the main part that radiates electromagnetic waves is localized for each frequency, and thus multiple radiations that radiate multiple electromagnetic waves. It is necessary to arrange the conductors in a small volume with little interference. For this reason, an increase in volume of the entire antenna cannot be avoided.
On the other hand, the basic operation principle of the antenna of the present invention is to radiate electromagnetic waves from the antenna to free space non-locally in each frequency band to be operated. It is not necessary to consider the arrangement so as not to interfere with each other. The transmission line, which is an element of the antenna according to the present invention, is constituted by a linear conductor or a narrow strip conductor, and these are simply arranged in a small volume or a small size. It becomes possible to arrange in.
In the multimode antenna according to the present invention, electromagnetic wave energy is radiated without being localized from a plurality of transmission lines at each frequency, and therefore, different modes (for example, dipole mode and loop) as in the above-mentioned Patent Document 2. Compared with an antenna having a structure that resonates in (mode), there is a feature that there are few portions of the antenna structure that hardly contribute to radiation when electromagnetic waves are radiated.
The impedance matching band, which is one of the important characteristics of the antenna, becomes wider as the total length or size of the current path of the conductor portion contributing to the radiation of the multimode antenna due to the long wavelength effect is shorter. The impedance matching of the antenna can be expressed by a transmission line. The electrical characteristics of the transmission line can be described by the function shown in Expression (1) using the speed of light c, frequency f, line length L, and propagation constant β.
And the frequency differentiation of the electrical characteristic of the transmission line which shows the frequency dependence is represented like Formula (2).
As shown in Expression (2), the frequency differentiation of the electrical characteristics of the transmission line is proportional to the line length L.
For this reason, as the line length L increases, the change of the impedance in the frequency band where the antenna resonates with respect to the frequency becomes steeper, and as a result, the impedance matching band in the same frequency band becomes narrower. That is, the matching band is narrowed by the long wavelength effect.
In the present invention, electromagnetic waves are delocalized at each frequency and radiated from the transmission line constituting the antenna. Therefore, unlike the multimode antenna of the prior art, a specific transmission line is commonly used for a plurality of frequencies. This contributes to the radiation, and the presence of this common portion contributes to the reduction in the overall length or size of the current path of the conductor portion contributing to the radiation of the multimode antenna. Therefore, since the total length or size of the current path is shorter than that of the conventional multimode antenna, the antenna of the present invention can be widened.
The operation principle of the multimode antenna of the present invention will be described as follows with reference to FIG. The number of modes of the multimode antenna is n, and the wavelength of the electromagnetic wave to be used is defined as shown in Equation (3).
The antenna matching condition can be realized by canceling the susceptance component at the feeding point. In order to perform a design in which the susceptance at the feeding point is zero at a plurality of wavelengths in the equation (3), Si (i = 1, 2,..., N−1) in FIG. Put.
In this way, when designing impedance matching of the feeding point at the wavelength of λi, the potential at the intersection of Li and Si can be made zero, so that transmission of Li + 1 to Ln and Si + 1 to Sn−1 is possible. There is no need to consider the track.
In order to make the susceptance of the feeding point zero at λ1, L1 = S1 may be set. L2 for making the susceptance of the feeding point zero at λ2 is obtained by Expression (5). However, βi = 2π / λi.
From the expression (4) and the condition of L1 = S1, the right side of the expression (5) is positive, and as a result, the expression (6) is obtained.
L3 for making the susceptance of the feeding point zero at λ3 is obtained by Expression (7).
Since the derivative with respect to the propagation constant of the first term on the right side of Equation (7) is Equation (8), it is always positive.
Equation (8) is zero when β3 = 0.
Therefore, since the first term of Expression (7) is positive and the second term is also positive, Expression (9) is obtained.
Here, the recurrence formula of the following formula (10) with the first term on the right side of formula (7) as the first term is introduced.
The differentiation of the recurrence formula of Expression (10) is Expression (11).
Considering the first term of equation (10), it can be seen that equation (11) is always positive.
By using the recurrence formula of Formula (10), Formula (12) for determining Li is obtained.
The right side of equation (12) is always positive.
Therefore, equation (13) holds, and the total length T of the multimode antenna of the present invention shown in FIG. 16 can be expressed by equation (14).
As can be seen from Equation (13), in the multimode antenna of the present invention, the maximum wavelength is given by the quarter wavelength structure of the longest wavelength of the electromagnetic wave having the multimode frequency and the half wavelength structure of the other wavelengths.
In the conventional multimode antenna, when different structures exhibiting a resonance length at each frequency are realized in the antenna structure, the different structures need to be separated by a necessary distance so as not to be electromagnetically coupled. Then, there is no such need, and continuous arrangement is possible. For this reason, the antenna of the present invention is smaller in size than the conventional antenna, and therefore, the effect of expanding the frequency band of impedance matching occurs. Equation (13) is an inequality, and in many cases, the antenna of the present invention can realize a multi-mode antenna with a small size according to the above-described maximum size condition, and the effects of size reduction and matching band expansion are further increased.
The above description is based on the topology (network structure) of FIG. Here, when the two structures of FIG. 17A and FIG. 17B are taken up, the succession Yi can be expressed by Expression (15) and Expression (16), respectively.
From this, the conditions for making the sustainance zero are the same in the two structures of FIGS. 17A and 17B.
Therefore, the present invention is obviously applicable not only to the structure of FIG. 16 but also to a topology in which a plurality of open-ended transmission lines are coupled to a portion corresponding to Si, for example.
The topology shown in FIG. 18 is an example of a three-mode antenna configured according to the operation principle explanatory diagram of FIG. Further, the topology shown in FIG. 19 is an example of a four-mode antenna in which the principle structure of FIG. 16 is modified using the principle shown in FIGS. 17A and 17B.
Special requirements regarding the real part of the input impedance of the antenna from the high-frequency circuit side to which the antenna is coupled (for example, when the characteristic impedance of the front-end semiconductor device mounted on the high-frequency substrate is particularly high or low, When there is a request to match the real part of the input impedance of the antenna to the impedance), like the topology shown in FIG. 20, the feed point of each multimode frequency for the three-mode topology shown in FIG. It is effective to add a transmission line that finely adjusts the real part.
As described above, according to the present invention, an antenna that operates in multiple modes of three or more modes can be realized. That is, it is possible to design a multimode antenna having three or more modes by using a distributed constant circuit theory using a narrow band conductor, a linear conductor, or a narrow strip conductor that can be handled as a transmission line. In addition, there is no problem of reducing the interference of radiation conductors as seen in the conventional integration of multiple antenna structures, so the multimode antenna can be made smaller and the frequency band is one of the important characteristics of the antenna. A great effect can be obtained.
1 is a structural diagram for explaining a first embodiment of an antenna according to the present invention. FIG. 6 is a structural diagram for explaining a second embodiment of the present invention. FIG. 6 is a structural diagram for explaining a third embodiment of the present invention. FIG. 6 is a structural diagram for explaining a fourth embodiment of the present invention. FIG. 10 is a structural diagram for explaining a fifth embodiment of the present invention. It is a perspective view for demonstrating the 5th Embodiment of this invention. It is a structural diagram for demonstrating the 6th Embodiment of this invention. It is a perspective view for demonstrating the 6th Embodiment of this invention. FIG. 10 is a structural diagram for explaining a seventh embodiment of the present invention. It is a perspective view for demonstrating the 7th Embodiment of this invention. It is a structure figure for demonstrating the 8th Embodiment of this invention. It is a structural diagram for explaining a ninth embodiment of the present invention. It is a structure figure for demonstrating the 10th Embodiment of this invention. It is a structure figure for demonstrating the 11th Embodiment of this invention. It is a structure figure for demonstrating the 12th Embodiment of this invention. It is a structure figure for demonstrating the product structure of 12th Embodiment. It is a front view for demonstrating the 13th Embodiment of this invention. It is an assembly drawing for demonstrating the 13th Embodiment of this invention. It is a structure figure for demonstrating the 1st manufacturing process of the 14th Embodiment of this invention. It is a structure figure for demonstrating the 2nd manufacturing process of 14th Embodiment of this invention. It is a structure figure for demonstrating the 3rd manufacturing process of 14th Embodiment of this invention. It is a block diagram for demonstrating the principle of the antenna of this invention. It is a block diagram for demonstrating the part of the antenna of this invention. It is a block diagram for demonstrating another part of the antenna of this invention. It is a block diagram for demonstrating the topology (network structure) of the antenna of this invention. It is a block diagram for demonstrating another topology (network structure) of the antenna of this invention. It is a block diagram for demonstrating another topology (network structure) of the antenna of this invention.
Hereinafter, an antenna according to the present invention, a manufacturing method thereof, and a portable wireless terminal using the antenna will be described in more detail with reference to some embodiments shown in the drawings.
FIG. 1 shows a first embodiment of the present invention. This embodiment forms a three-mode antenna. The antenna 1 has a structure in which a ground conductor (ground portion) 2, branch portions 31 and 32, and transmission lines 41, 42, 51, 61, and 62 are integrated. A feeding point 7 for supplying power is formed between one end of the transmission line 41 and a part of the ground conductor 2. Moreover, the antenna 1 of this embodiment is comprised with an integral metal plate.
A bifurcated first branch portion 31 is connected to a first transmission line 41 extending in a direction perpendicular to the ground conductor 2 from the feed point 7, and a first tip open transmission is connected to one end of the first branch portion 31. The line 61 is connected to another end of the second transmission line 42 in parallel with the ground conductor 2. Further, a second branch portion 32 that is a bifurcated portion is connected to the tip of the second transmission line 42 extending from the first branch portion 31, and between the one end of the second branch portion 32 and the ground conductor 2. The short-circuit transmission line 51 is connected to the other end, and a second open-end transmission line 62 arranged in parallel with the ground conductor 2 is connected to the other end.
The transmission lines 41 and 42, the tip short-circuit transmission line 51, and the tip open transmission lines 61 and 62 constituting the antenna 1 of the present invention are distributed constant circuit elements. Therefore, the antenna 1 of the present invention is a distributed constant circuit network composed of distributed constant circuits.
The antenna 1 of the present invention determines the dimensions of the transmission lines 41, 42, the short-circuited transmission line 51, and the open-circuit transmission lines 61, 62 so as to resonate in three different frequency bands in this distributed constant network. Thus, three-mode operation is realized.
In this embodiment, as an example of three frequencies, the minimum wavelength λ1 = 129.9 mm, the intermediate wavelength λ2 = 178.0 mm, and the longest wavelength λ3 = 451.1 mm are selected, the transmission line 41 = 20 mm, and the transmission line 42 = 40 mm. The transmission line 51 is set to 40 mm, the transmission line 61 is set to 80 mm, and the transmission line 62 is set to 80 mm. The total length of the transmission line is 260 mm, which is smaller than λ1 / 2 + λ2 / 2 + λ3 / 4 = 266.8 mm, and the expression (14) is satisfied.
As shown in FIG. 1, the above transmission line is composed of a narrow strip-shaped conductor. In addition, these transmission lines can be composed of linear conductors or narrow strip lines.
FIG. 2 shows a second embodiment of the present invention. The antenna 11 in FIG. 2 is a three-mode antenna having a structure in which the tip open transmission line 62 in the antenna 1 in FIG. This structure has an effect of increasing the mechanical strength of the structure as compared with the first embodiment.
In the present embodiment, as an example of three frequencies, the minimum wavelength λ1 = 85.2 mm, the intermediate wavelength λ2 = 13.4 mm, and the longest wavelength λ3 = 235.3 mm are selected, the transmission line 41 = 10 mm, and the transmission line 42 = 20 mm. The transmission line 51 is set to 20 mm, the transmission line 61 is set to 50 mm, and the transmission line 62 is set to 50 mm. The total length of the transmission line is 150 mm, which is smaller than λ1 / 2 + λ2 / 2 + λ3 / 4 = 168.8 mm, and Expression (14) is satisfied.
FIG. 3 shows a third embodiment of the present invention. The antenna 12 of FIG. 3 replaces the first branch part 31 that is two branches in the antenna 1 of FIG. 1 with a branch part 33 that is three branches, and a new open-ended transmission line 63 is connected to the branch part 33. This is a three-mode antenna having a structure in which the number of elements constituting the antenna is increased.
With this structure of increasing the number of elements, it is possible to increase the parameters of the distributed constant network, thereby enabling fine adjustment of the real part of the antenna input impedance at the feeding point in addition to the effect of the antenna 1 of FIG. Become.
In the present embodiment, as an example of three frequencies, the minimum wavelength λ1 = 104.7 mm, the intermediate wavelength λ2 = 219.8 mm, and the longest wavelength λ3 = 322.6 mm are selected, the transmission line 41 = 10 mm, and the transmission line 42 = 20 mm. Transmission line 51 = 20 mm, transmission line 61 = 40 mm, transmission line 62 = 40 mm, and transmission line 63 = 70 mm. The total length of the transmission line is 200 mm, which is smaller than λ1 / 2 + λ2 / 2 + λ3 / 4 = 243 mm, and the expression (14) is satisfied.
FIG. 4 shows a fourth embodiment of the present invention. The antenna 13 shown in FIG. 4 is a three-mode antenna having a structure in which a groove 8 is formed in a part of the ground conductor 2 and an open-ended transmission line 63 is accommodated in the groove 8.
In FIG. 4, a first branch portion 31 that is bifurcated is connected to a first transmission line 41 that extends in a direction perpendicular to the ground conductor 2 from the feeding point 7, and one end of the first branch portion 31 is grounded. A short-circuited short transmission line 52 is formed between the conductor 2 and a second transmission line 42 is connected to the other end in parallel with the ground conductor 2. Further, a second branch part 32 that is a two-branch is connected to the tip of the second transmission line 42 extending from the first branch part 31, and one end of the second branch part is parallel to the ground conductor 2. A second open-ended transmission line 62 is connected to the first open-ended transmission line 62 that extends perpendicularly to the ground conductor at the other end and is longer than the first open-ended transmission line 62 accommodated in the groove 8 of the ground conductor 2. The open-ended transmission line 63 is connected.
In the present embodiment, as an example of three frequencies, a minimum wavelength λ1 = 80.4 mm, an intermediate wavelength λ2 = 103.8 mm, and a longest wavelength λ3 = 397.4 mm are selected, a transmission line 41 = 10 mm, and a transmission line 42 = 20 mm. The transmission line 52 is set to 30 mm, the transmission line 62 is set to 40 mm, and the transmission line 63 is set to 60 mm. The total length of the transmission line is 160 mm, which is smaller than λ1 / 2 + λ2 / 2 + λ3 / 4 = 191.5 mm, and the expression (14) is satisfied.
With this structure, when the size of the open-ended transmission line 63 is long, there is an effect of increasing the mechanical strength of the antenna itself rather than arranging the open-ended transmission line 63 so as to surround the entire antenna.
In the case where the same thing occurs in the short-circuited short-circuit transmission line, the short-circuited short-circuit transmission line may be connected to be accommodated in the groove of the ground conductor in the same manner as the open-ended transmission line 63 of the antenna 13 of the present invention. Similar effects can be obtained.
5A and 5B show a fifth embodiment of the present invention. 5A and 5B is a three-mode antenna having a structure in which an antenna structure of an integral metal plate is supported by a dielectric layer and a strip conductor pattern is formed on the back surface of the same metal plate. In order to replace the first open-ended transmission line 61 connected to one end of the first branch portion 31 that is bifurcated in the antenna 1 of FIG. 1 with the open-ended transmission line 64 having a longer dimension than the open-ended transmission line 61. In this structure, the through-hole 100 provided in the dielectric layer 9 is used, and the open-ended transmission line 64 is formed on one surface of the dielectric layer 9 and another surface.
This structure has the effect of reducing the antenna size due to the wavelength shortening effect of the dielectric constant of the dielectric layer.
6A and 6B show a sixth embodiment of the present invention. The antenna 15 shown in FIGS. 6A and 6B is a three-mode antenna, and the antenna 13 of the present invention shown in FIG. 4 is supported by the dielectric layer 9 and further penetrates the dielectric layer 9 from the end of the ground conductor 2 of the antenna 13. The second ground conductor 21 formed on the other surface of the dielectric layer 9 is connected to the ground conductor 2 of the antenna 13 using a plurality of through holes 100 reaching the back surface of the antenna 13.
With this structure, there is an effect that the antenna size is reduced due to the wavelength shortening effect of the dielectric constant of the dielectric material constituting the circuit board, the ground conductor area is increased, and the operation of the antenna is stabilized.
7A and 7B show a seventh embodiment of the present invention. The antenna 16 shown in FIGS. 7A and 7B is connected to the ground conductor 2 of the antenna 13 shown in FIG. 4 configured on one surface of the dielectric layer 9 and the ground conductor 21 configured on the other surface of the dielectric layer 9. This is a three-mode antenna having a structure using a plating layer 72 formed on the side surface of the antenna.
With this structure, it is possible to save the trouble of producing the through hole employed in the sixth embodiment, and to obtain the same effect as that of the sixth embodiment with less manufacturing cost.
FIG. 8 shows an eighth embodiment of the present invention. In this embodiment, the entire structure of the antenna 1 of FIG. 1 is bent so as to be rounded. The structure of this embodiment can be manufactured at low cost by first punching the antenna structure of FIG. 1 with an integral metal plate and then bending press processing.
In the antenna structure of the present embodiment, when the internal shape of the casing of the wireless terminal on which the antenna is mounted is a curved surface, the volume in the casing that can be substantially occupied by the antenna can be increased. As a result, the design man-hour can be shortened.
FIG. 9 shows a ninth embodiment of the present invention. In this embodiment, FIG. 9 shows a three-mode antenna in which the transmission line 41 having the antenna structure of FIG. In order to ensure the length of the transmission line 41, the transmission line is formed along the periphery of the ground conductor 2. Furthermore, open-ended transmission lines 61 and 62 are provided in meander-shaped grooves 81 and 82 formed in the ground conductor.
With the configuration of the present embodiment, when the total length of the transmission line that is a component of the antenna is long, it is possible to realize these transmission lines within a small size. The application of this technique is naturally possible even in the case of a short-circuited short-circuit transmission line.
FIG. 10 shows a tenth embodiment of the present invention. The difference from the embodiment of FIG. 9 is that the shape of the grooves 83 and 84 for realizing the open-ended transmission line in the ground conductor is a square spiral shape. By adopting a spiral shape, the inductance component increases, and the physical length of the open-ended transmission line can be reduced equivalently. This increases the area of the ground conductor and improves the stability of the antenna operation.
FIG. 11 shows an eleventh embodiment of the present invention. The difference from the embodiment of FIG. 10 is that the shape of the grooves 85 and 86 for realizing the open-ended transmission line in the ground conductor is a circular spiral shape. Since the circular spiral shape has less structural discontinuity than the square spiral shape, the change in electrical characteristics with respect to the dimensional accuracy of the spiral shape can be reduced. For this reason, the manufacturing yield can be improved, and as a result, the manufacturing cost of the antenna product can be reduced.
FIG. 12 shows a twelfth embodiment of the present invention. In this embodiment, a coaxial cable is used for power feeding. As shown in FIG. 12, a coaxial cable 71 is connected to the feeding point 7 of the antenna 1 of FIG. 1, and power is supplied via the coaxial cable 71.
Since the coaxial cable has a characteristic of low transmission loss in the high frequency band, it has an effect of efficiently supplying power to the antenna. Furthermore, the use of a coaxial cable enables connection to a communication module or the like located away from the antenna, and has the effect of increasing the degree of freedom of the antenna installation position.
An example of the product structure of the antenna according to FIG. 12 in which the coaxial feeder 71 is provided in the antenna 1 of FIG. 1 is shown in FIG. The antenna of FIG. 13 includes the coaxial feed line shown in FIG. 12 as a constituent element, and the entire antenna is laminated by a thin dielectric sheet 72 except for a coupling portion between the coaxial feed line and the antenna feed part. As the dielectric sheet, for example, a polyimide material can be used. The joint between the coaxial feeder and the antenna feeder is such that the outer conductor of the coaxial line, the ground conductor of the antenna, and the transmission line including the conductor of the coaxial line and the antenna feed point are electrically soldered in a later process. As long as joining is possible, it is desirable to expose the conductor constituting the antenna and cover the other conductor portion of the antenna with a dielectric sheet as much as possible in order to prevent deterioration due to external factors.
In the present embodiment, the product structure shown in FIG. 13 prevents the antenna from coming into contact with other electronic / electrical components in the wireless terminal housing, and corrosion due to external factors of the integrated metal plate constituting the antenna. This has the effect of preventing deterioration and improving the temporal stability (aging) of the antenna characteristics.
14A and 14B show a thirteenth embodiment of the present invention. 14A and 14B, reference numeral 130 denotes a mobile phone (portable wireless terminal) incorporating the multimode antenna 1 of the present invention shown in FIG. 1, and reference numeral 142 denotes a speaker of the mobile phone 130.
In FIG. 14B, a circuit board 140 disposed between the front cover 131 and the rear cover 132 of the mobile phone 130 is disposed. The multi-mode antenna 1 of the present invention is installed between the circuit board 140 and the back cover 132 behind the speaker 142 of the main body, that is, at a position above the main body. A power supply unit 141 of a high frequency circuit is installed on the circuit board 140, and the power supply unit 141 is connected to the power supply unit 7 of the multimode antenna 1 of the present invention.
When a mobile phone is used, the user's hand hardly reaches the back side of the main body on the upper side of the mobile phone. Therefore, by setting the position where the antenna is built on the back side of the main body on the upper side of the main body of the mobile phone, there is an effect of reducing deterioration of the transmission / reception sensitivity of the antenna by the user's hand.
Currently, image services are becoming an important application in multimedia wireless terminals. With the progress of image services, displays such as liquid crystal used for wireless terminals tend to become larger. In particular, the tendency is remarkable in the portable mobile radio telephone in which the volume of the terminal itself is small. In order to realize a large video screen with a small volume, the adoption of a foldable casing is progressing in multimedia terminals. In the folded shape, the thickness direction of the space in which the antenna is mounted is substantially limited, so that the compatibility of the multimode antenna of the present invention having a thin plate shape is extremely high. By adopting the multi-mode antenna of the present invention, it is possible to mount the antenna on the back surface of the large display unit in the folding housing of the multimedia terminal provided with the large display unit.
In addition, although the multimode antenna 1 of 1st Embodiment of FIG. 1 was mounted in the mobile phone of this embodiment, not only this but any antenna of 2nd-12th Embodiment can be mounted. Is possible.
15A to 15C show a fourteenth embodiment of the present invention. In the figure, an embodiment of a method for manufacturing a multimode antenna of the present invention is shown. In the present embodiment, a manufacturing method in the case where the transmission line that is a component of the antenna does not include the tip short-circuited transmission line or the case where the physical strength of the junction between the tip short-circuited transmission line and the ground conductor cannot be obtained is taken up.
First, as shown in FIG. 15A, the entire antenna structure is formed by a metal press punching process integrally with a support conductor portion 73 for ensuring physical strength of a joint between a series of integrated transmission line portions and a ground conductor.
Next, as shown in FIG. 15B, the thin dielectric sheet 72 is used to cover the entire antenna except for the feeding portion of the antenna and the supporting conductor portion.
Subsequently, as shown in FIG. 15C, the supporting conductor portion essentially unnecessary for the antenna operation is cut off again by the metal press punching process. Finally, the coaxial cable is assembled by a soldering process to complete the manufacture of the antenna as a product.
By applying the technique of the present embodiment, it is possible to manufacture the relative positional relationship between the ground conductor and the transmission line with high accuracy, and as a result, the effect of improving the product yield is produced.
As described above, according to the present invention, at a plurality of frequencies, a single power feeding unit enables good impedance matching between the high-frequency circuit unit and free space using a transmission line, and an antenna that operates in multiple modes of three or more modes. Can be realized. In addition, since a structure in which a transmission line is shared by a plurality of frequencies can be realized, a great effect can be obtained in reducing the size of the multimode antenna and expanding the matching band of the multimode antenna.
The antenna according to the present invention is suitable for use in a portable radio communication apparatus, and particularly suitable for use in a multimedia radio terminal of a system that provides a multimedia service using a plurality of frequencies.
DESCRIPTION OF SYMBOLS 1 ... Antenna, 11 ... Antenna, 12 ... Antenna, 13 ... Antenna, 14 ... Antenna, 15 ... Antenna, 16 ... Antenna, 2 ... Ground conductor (ground part), 21 ... Second ground conductor, 31 ... First Branch part 32 ... Second branch part 33 ... Branch part 41 ... First transmission line 42 ... Second transmission line 51 ... Tip short circuit transmission line 52 ... Tip short circuit transmission line 61 ... Tip open Transmission line, 62 ... Open-ended transmission line, 63 ... Open-ended transmission line, 64 ... Open-ended transmission line, 7 ... Feeding point, 71 ... Coaxial cable, 72 ... Plating layer, 8 ... Groove, 81 ... Meander-shaped groove, DESCRIPTION OF SYMBOLS 82 ... Meander-shaped groove | channel, 9 ... Dielectric layer, 100 ... Through hole, 130 ... Mobile phone, 131 ... Front cover, 132 ... Back cover, 140 ... Circuit board, 141 ... Power supply part, 142 ... Speaker.
A ground conductor having a ground potential;
A feeding point having one end of the ground conductor as one end;
A plurality of transmission lines that input high-frequency power supplied to the feeding point and radiate electromagnetic waves of n types (n is a natural number of 3 or more ) in different frequency bands to space;
The plurality of transmission lines include a first transmission line, a second transmission line, and a third transmission line, and are integrated with (n−1) or more branch points starting from the feeding point. It has a topological structure,
The first transmission line extends along the edge of the ground conductor, and at least one end is open,
The second transmission line extends from between both ends of the first transmission line in the direction of the ground conductor, and electrically connects the first transmission line and the ground conductor.
In the third transmission line, a common transmission line is formed in a plurality of frequency bands between a coupling point between the first transmission line and the second transmission line and an open end of the first transmission line. As described above, the first transmission line is connected to the feeding point,
And the ground conductor, and the plurality of transmission lines are formed away from each other across the feeding point,
The multimode antenna, wherein the ground conductor, the feeding point, and the plurality of transmission lines are formed of an integral metal plate.
The multimode antenna according to claim 1, wherein the other end of the first transmission line is short-circuited .
The plurality of transmission lines include a first transmission line, a third transmission line, and a fourth transmission line, and are integrated with (n−1) or more branch points starting from the feeding point. It has a topological structure,
The first transmission line extends along the edge of the ground conductor, one end is open, and the other end is short-circuited to the ground conductor.
The fourth transmission line extends from between both ends of the first transmission line toward the ground conductor, and one end is open.
The third transmission line is common to a plurality of frequency bands between a connection point between the first transmission line and the fourth transmission line and the shorted one end of the first transmission line. A transmission line is formed, and the first transmission line is connected to the feeding point,
Multi-mode antenna, characterized in that the grounding conductor, the feeding point and said plurality of transmission lines is formed by integrally metal plate.
The total length of the plurality of transmission lines is a quarter wavelength of the electromagnetic wave in the first frequency band among the n frequency bands, and the third, second, fourth,... Higher than the first frequency band. The multimode antenna according to claim 1 , wherein the multimode antenna is shorter than a sum of each half wavelength of electromagnetic waves in the nth frequency band .
Multi-mode antenna according to claim 1, wherein the fifth transmission line for impedance adjustment in at least one of the feeding point or the first transmission line or said second transmission line is further connected .
The multimode antenna according to claim 1, wherein the plurality of transmission lines are located on the same plane as the ground conductor.
A method of manufacturing a multimode antenna according to claim 1,
A method of manufacturing a multimode antenna, comprising a step of forming the plurality of transmission lines and the ground conductor by metal plate pressing.
2. A portable wireless terminal comprising the multimode antenna according to claim 1 mounted therein, wherein the ground conductor, the feeding point, and the plurality of transmission lines are formed by an integral metal plate.
Including a step of forming the plurality of transmission lines and the ground conductor by metal plate pressing.
A method for manufacturing a multi-mode antenna.
A portable wireless terminal comprising the multimode antenna according to claim 1 mounted therein.
JP2012212012A 2003-11-13 2012-09-26 Multi-mode antenna, manufacturing method thereof, and portable radio terminal using the antenna Expired - Fee Related JP5516681B2 (en)
JP2003383647 2003-11-13
JP2012212012A JP5516681B2 (en) 2003-11-13 2012-09-26 Multi-mode antenna, manufacturing method thereof, and portable radio terminal using the antenna
JP2005515395 Division 2004-07-29
JP2013021716A JP2013021716A (en) 2013-01-31
JP5516681B2 true JP5516681B2 (en) 2014-06-11
ID=34587300
JP2005515395A Pending JPWO2005048404A1 (en) 2003-11-13 2004-07-29 Antenna, manufacturing method thereof, and portable radio terminal using the antenna
JP2012212012A Expired - Fee Related JP5516681B2 (en) 2003-11-13 2012-09-26 Multi-mode antenna, manufacturing method thereof, and portable radio terminal using the antenna
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2004-07-29 CN CN201410076412.3A patent/CN103887596A/en not_active Application Discontinuation
2004-07-29 WO PCT/JP2004/011193 patent/WO2005048404A1/en active Application Filing
2004-07-29 US US10/578,769 patent/US7755545B2/en active Active
2004-07-29 JP JP2005515395A patent/JPWO2005048404A1/en active Pending
2004-07-29 KR KR1020067009086A patent/KR20060086414A/en not_active Application Discontinuation
2012-09-26 JP JP2012212012A patent/JP5516681B2/en not_active Expired - Fee Related
CN1879256A (en) 2006-12-13
US20070139270A1 (en) 2007-06-21
CN103887596A (en) 2014-06-25
JP2013021716A (en) 2013-01-31
CN1879256B (en) 2014-11-05
US7755545B2 (en) 2010-07-13
WO2005048404A1 (en) 2005-05-26
JPWO2005048404A1 (en) 2007-05-31
TW200516804A (en) 2005-05-16
KR20060086414A (en) 2006-07-31
TWI237419B (en) 2005-08-01
US6847329B2 (en) 2005-01-25 Plate-like multiple antenna and electrical equipment provided therewith
2013-09-25 A711 Notification of change in applicant
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