JP2005079959A - Antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an antenna that realizes widening of a transmission and reception band while maintaining the antenna small. <P>SOLUTION: This antenna has a plurality of antennas having different resonance frequencies and a power supplying part for supplying power to the feeding terminals of the plurality of antennas in common. The open terminals of the plurality of antennas are independent of each other, and at least one of the plurality of antennas is constituted of a helical antenna having a trimmed helical conductor part to thereby realize the widening of the transmission and reception band. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an antenna device that is suitably used for electronic devices that perform wireless communication such as mobile communication and personal computers.

  In recent years, data communication is increasing in mobile terminals such as mobile phones and notebook personal computers. The amount of data required for data communication, that is, the transmission rate is steadily increasing, and in order to cope with the increase in transmission rate, the transmission / reception band required for wireless communication tends to increase.

  On the other hand, when the transmission / reception band is expanded, an antenna capable of transmission / reception in this band is required.

  In order to meet such demands, in order to broaden the transmission / reception band of the antenna, a peak crown conductor or the like is attached to the tip of the antenna, and the peak of the resonance frequency is made gentle by using the top crown conductor as a load capacity. Has been performed (see, for example, Patent Document 1). Alternatively, a signal received by each of a plurality of narrowband antennas having a fixed band is demodulated, and as a result, all of the data spread over a wide band is received (see, for example, Patent Document 2).

FIG. 14 is a configuration diagram of a communication device including an antenna device according to a conventional technique. 100 is a communication device, 101, 102, 103, and 104 are narrowband antennas, 105, 106, 107, and 108 are transmission paths, and 109 is a transmission / reception unit. The narrowband antennas 101 to 104 are antennas having a certain band, and the respective resonance frequencies are slightly different. For example, the resonance frequency of the narrowband antenna 101 is 500 MHz, the resonance frequency of the narrowband antenna 102 is 510 MHz, the resonance frequency of the narrowband antenna 103 is 520 MHz, and the resonance frequency of the narrowband antenna 104 is 530 MHz. Assume that the bandwidth is 10 MHz. Next, signals received by the narrowband antennas 101 to 104 are transmitted to the transmission / reception unit 109 through the transmission paths 105 to 108. The transmitted signal is individually detected and demodulated by the transmission / reception unit 109, and finally demodulated data is combined to be used for reproduction. As a result of this processing, it is possible to receive and demodulate broadband data that has been modulated in the band from 500 MHz to 530 MHz. The same applies to transmission.
JP 2000-124812 A JP 2003-101342 A

  However, in the conventional antenna device using the top crown conductor, there is a limit in expanding the bandwidth, and there is a problem of increasing the size of the antenna device. In addition, there are many restrictions on the shape and size of the crown conductor due to the mounting area, etc., and there are problems such as unnecessary expansion of the mounting area and changes in the housing shape to achieve sufficient bandwidth. there were.

Alternatively, in an antenna apparatus that uses a plurality of narrowband antennas as shown in FIG. 14 and combines data after individually receiving and demodulating, it is necessary to provide as many circuits as transmission lines, detection, demodulation, etc. as the number of antennas. There is a problem in that the size of the device, the size of the communication device, and the cost are increased. In addition, in the method of widening the band by combining the data received and demodulated by a plurality of narrowband antennas, data order matching processing is required when combining the data,
There was also a problem that it was necessary to perform processing that matched data combination in advance on the transmission side. In such a system, there is a problem that it is not possible to cope with only an antenna for wideband reception, and it is necessary to cope with both the reception apparatus and the transmission apparatus.

  An object of the present invention is to provide an antenna device that can transmit and receive in a wide band while realizing miniaturization.

  The present invention has a configuration in which a plurality of antennas having different resonance frequencies and a power feeding unit that feeds power to power feeding terminals of the plurality of antennas in common are provided, and the open terminals of the plurality of antennas are independent from each other.

  In the present invention, by connecting a plurality of antennas having adjacent resonance frequencies to a common feeder line, the bands of the respective antennas can be overlapped to realize a wider band. This enables communication at a high transmission rate that requires a wide band.

  In addition, by using at least one of the plurality of antennas as a helical antenna, the antenna itself can be downsized, and downsizing of the antenna device can be realized.

  Furthermore, by using at least one of the antennas as a substrate pattern antenna, the antenna itself is similarly miniaturized, and wideband transmission / reception can be realized while miniaturizing the antenna device.

  The invention according to claim 1 of the present invention includes a plurality of antennas having different resonance frequencies and a power feeding unit that feeds power to the power feeding terminals of the plurality of antennas in common, and the open terminals of the plurality of antennas are each independently provided. The antenna device is characterized in that the transmission / reception band is widened.

  The invention according to claim 2 of the present invention is the antenna device according to claim 1, wherein different frequencies are adjacent frequencies, and the transmission / reception band is reduced while minimizing gain reduction. Has the effect of broadening the bandwidth.

  The invention according to claim 3 of the present invention is the antenna device according to claim 2, wherein the adjacent frequency is 10 MHz or more and 200 MHz or less, and transmission and reception are performed while minimizing gain reduction. Has the effect of widening the band.

  According to a fourth aspect of the present invention, at least one of the antennas has a base, a helical part provided on the base, and a pair of terminal parts provided on the base, and the helical part and the terminal part are electrically connected. 4. The antenna device according to claim 1, wherein the antenna device is a helical antenna that is connected to each other and one of the terminal portions is a feeding terminal and the other is an open terminal. And having a function of realizing a small antenna device.

  The antenna device according to claim 5 of the present invention is characterized in that the helical antenna is formed by trimming a base body provided with a conductive film to provide a spiral groove. And it has the effect | action which forms a highly accurate helical antenna.

The invention according to claim 6 of the present invention is the antenna device according to claim 4, wherein the helical antenna is formed by applying a conductive winding to a base. It has the effect | action which comprises.

  The invention according to claim 7 of the present invention is the antenna device according to any one of claims 1 to 6, characterized in that at least one of the antennas is formed by a substrate pattern, particularly for high frequency. It has the effect of realizing a small antenna.

  The invention according to claim 8 of the present invention is the antenna device according to any one of claims 1 to 7, characterized in that a top crown conductor is provided at an open terminal of the antenna, further increasing the bandwidth. Has the effect of promoting.

  The invention according to claim 9 of the present invention forms an arbitrary transmission / reception band, an antenna group including a plurality of antennas having different resonance frequencies, forms a transmission / reception band different from the arbitrary transmission / reception band, and has different resonance frequencies. An antenna group including a plurality of antennas and a power feeding unit that feeds power to the power feeding terminals of the plurality of antennas included in the antenna group, and the open terminals of the plurality of antennas included in the antenna group are independent from each other. The dual-mode or triple-mode antenna device has the function of widening the transmission / reception band.

  According to the tenth aspect of the present invention, in an antenna group forming an arbitrary transmission / reception band, an antenna included in an antenna group having a high frequency in the transmission / reception band is supplied in common to an antenna included in an antenna group having a low frequency. The antenna device according to claim 9, wherein the antenna device is connected close to an electric wire, and has an effect of securing a sufficient gain.

  The invention according to claim 11 of the present invention is discriminated by the antenna device according to any one of claims 1 to 10, a frequency discriminator that is connected to the antenna device and discriminates a frequency of a received signal, and a frequency discriminator. And a data demodulator that demodulates data contained in the signal detected by the detector, and performs wideband reception corresponding to a high transmission rate, etc. In addition, it has the function of demodulating.

  The invention according to claim 12 of the present invention is characterized in that a down-conversion unit for reducing the frequency of a signal received by the antenna device exists between the frequency discriminator and the antenna device. Even if it is a case where it receives a high frequency band, it has the effect | action which reduces a demodulation processing burden.

  According to a thirteenth aspect of the present invention, an error detection unit that performs error detection on the data demodulated in the data demodulation unit is present in the subsequent stage of the data demodulation unit. The receiving apparatus according to claim 1 has an effect of further improving reception accuracy.

  The invention according to claim 14 of the present invention is characterized in that an error correction unit for correcting an error in the data demodulated in the data demodulation unit is present in the subsequent stage of the data demodulation unit. The receiving apparatus according to 1, wherein the receiving apparatus has an effect of further improving reception accuracy.

  Hereinafter, it demonstrates using drawing.

(Embodiment 1)
1 and 2 are perspective views of a helical antenna according to Embodiment 1 of the present invention. FIG. 3 is an equivalent circuit diagram of the helical antenna according to the first embodiment of the present invention. FIG. 4 is a manufacturing process diagram of the helical antenna according to the first embodiment of the present invention.

1 is a helical antenna, 2 is a helical part, 3 is a terminal part, 4 is a spiral groove, 6 is a substrate, and 7 is a protective film. One of the terminal portions 3 and 4 is connected to the power feeding portion, and the other is connected to the open portion.

  The configuration of the helical antenna will be described with reference to FIG.

  The substrate 6 is formed by subjecting an insulator or dielectric such as alumina or a ceramic material mainly containing alumina to a pressing process, an extrusion method, or the like. As the constituent material of the substrate 6, ceramic materials such as forsterite, magnesium titanate, calcium titanate, zirconia / tin / titanium, barium titanate, lead / calcium / titanium may be used. Alternatively, a resin material such as an epoxy resin may be used. In the first embodiment, alumina or a ceramic material mainly composed of alumina is used from the viewpoints of strength, insulation, and ease of processing. Further, a single layer or a plurality of conductive films made of a conductive material such as copper, silver, gold, or nickel are laminated on the base 6 as a whole to form a conductive surface. For the conductive film, plating, vapor deposition, sputtering, paste, or the like is used.

  The terminal portions 3 and 4 are formed at both ends of the base 6 and are used by at least one of a thin film such as a conductive plating film, a vapor deposition film, and a sputtered film, a silver paste applied, and the like. It is done.

  The base body 6 may have a cross section having the same size as the terminal portions 3 and 4, but may be stepped down, and the cross-sectional area of the base body 6 is smaller than the cross-sectional area of the end portions 3 and 4. May be. Since the outer periphery of the base body 6 is stepped down, the base body 6 can have a distance from the surface of the antenna mounting board during mounting, and deterioration of characteristics can be prevented. At this time, the stepping may be performed only on a part of the surface of the substrate 6 or may be performed over the entire surface. When the step is dropped over the entire surface, it is not necessary to pay attention to the selection of the surface in contact with the electronic substrate at the time of mounting, and the cost at the time of mounting can be reduced.

  Further, each corner of the base 6 may be chamfered. By providing this chamfer, chipping of the base 6 is prevented, the conductive film is prevented from being thinned, or damage to the helical portion 2 is prevented.

  Here, the base body 6 and the terminal portions 3 and 4 may be formed separately and then integrated by pasting together, or may be formed integrally in advance. Further, the substrate 6 may not be a square shape, but may be a triangular or pentagonal polygon shape, or a cylindrical shape. In the case of a columnar shape, there is an advantage that the corner portion is not present, so that the impact resistance is improved and the spiral groove 5 can be easily formed.

  The helical portion 2 is formed by spirally excavating the surface of the base 6 having conductivity with the base 6 using trimming with a laser or the like to form a spiral groove 5 and has an inductor component. One end portion of the helical portion 2 is connected to the terminal portion 3, and the other end portion of the helical portion 2 is connected to the terminal portion 4, and has a capacitance component between the respective connections. That is, the inductor component and the capacitance component are connected by a series connection structure. The helical antenna 1 may be a λ / 4 type antenna or a λ / 2 type antenna. However, in order to further promote downsizing, the λ / 4 type antenna is often used. In some cases, a transmission / reception gain is ensured by using an image current generated on the ground plane in the vicinity of the helical antenna 1.

  Further, although not shown in FIG. 1, one of the terminal portions 3 and 4 is connected to the power feeding portion, and the other is connected to the open portion. The power supply portion is formed of a solder land or the like, and similarly, the open portion is formed of a solder land or the like. At this time, lead-free solder is used as the solder land, so that it is possible to provide an electronic device with little influence on the environment.

  Next, the helical antenna 1 shown in FIG. 2 has a protective film 7 on the surface. By providing the protective film, it is possible to prevent damage to the conductive film of the substrate 6 and damage to the spiral groove 5 and the like. In particular, it is possible to protect against impact and heat during transportation and mounting. As the protective film 7, a tube-shaped protective film or a paste-shaped protective film is used.

  The paste-like protective film is realized by applying a resin material such as an epoxy resin. When the protective film 7 is formed by coating or the like, the protective film 7 enters the spiral groove 5, and if the protective film 7 is a high dielectric constant material, the resonance frequency of the antenna may be changed. For this reason, the material used for the protective film 7 preferably has a low dielectric constant. However, antenna characteristics such as a desired frequency can be obtained by designing the shape and size of the helical portion after taking into account the dielectric constant of the protective film 7 to some extent. Preferably, the protective film 7 is formed so as to be accommodated in the stepped portion of the base 6 so that the height of the side surfaces of the terminal portions 3 and 4 is equal to the height of the side surface of the protective film 7. It is preferable to be configured as follows. This is because the ease of work at the time of mounting on the antenna mounting board is ensured.

  The tube-shaped protective film is realized by attaching a tube-shaped protective film around the base 6 and applying heat to press-bond. Since the tubular protective film is formed so as to cover the helical portion 2, the protective film does not flow into the spiral groove 5. For this reason, the antenna characteristic does not vary due to the provision of the tube-shaped protective film. Preferably, the tubular protective film is made of resin and has heat shrinkability. This is because the tube 6 is covered with a tube-shaped protective film and heat-treated to shrink the tube, and the tube-shaped protective film can be reliably formed on the substrate 6.

  The protective film 7 is preferably formed on the surface of the base 6 so as to cover at least the helical portion 2. Although the terminal portions 3 and 4 may be covered with the protective film 7, the adverse effect during mounting can be avoided by forming the protective film 7 excluding the terminal portions 3 and 4. Moreover, there is an advantage that the terminal portions 3 and 4 can be easily distinguished from the helical antenna 1 in the image recognition at the time of automatic mounting by making the colors of the protective film 7 and the terminal portions 3 and 4 different. In this case, there is an advantage that the terminals other than the terminal portions 3 and 4 are not connected to the solder land or the like at the time of mounting.

  Next, the operation of the helical antenna will be described with reference to FIG. FIG. 3 shows an equivalent circuit of the helical antenna. The helical portion 2 provided with the spiral groove 5 has an inductor component L, and the portion other than the helical portion 2 has a capacitance component C. The inductor component L and the capacitance component C are connected in series. As is apparent from this equivalent circuit, the resonance frequency ω is expressed by the following (Equation 1):

As apparent from (Equation 1), the resonance frequency is determined by the inductor component L and the capacitance component C, and as a result, the transmission / reception frequency of the helical antenna 1 is determined by the inductor component L and the capacitance component C. Accordingly, the helical antenna 1 operates at a transmission / reception frequency determined by (Equation 1) to transmit and receive radio waves.

The inductor component is determined in proportion to the number of turns of the spiral groove 5, and the resonance frequency is inversely proportional to the square root value of the inductor component. For this reason, it is possible to realize a higher resonance frequency by reducing the number of turns of the spiral groove 5 that realizes the inductor component on the power feeding unit side.

  Next, the construction method of the helical antenna 1 will be described with reference to FIG.

  10 is a rotation support base, 11 is a motor, 12 is a laser irradiator, 13 is a substrate with a conductive film, and 14 is a spiral groove. As described in Embodiment 1, the conductive film-attached substrate 13 is formed by subjecting an insulator or dielectric material such as alumina or a ceramic material mainly composed of alumina to a pressing process, an extrusion method, or the like. Furthermore, the conductive film of the base body 13 with a conductive film is formed by laminating a single layer or a plurality of conductive films made of a conductive material such as copper, silver, gold, or nickel.

  As shown in FIG. 4, a substrate 13 with a conductive film is installed on the rotation support base 10 and rotated by a motor 11, and a laser beam is irradiated from the laser irradiator 12 to the substrate 13 with a conductive film. A helical spiral groove 14 is formed by moving at least one of the rotation support bases 10. At this time, the spiral groove 14 is reliably excavated beyond the conductive film, and the helical conductive film remains, whereby the helical portion 2 having the helical conductive film is formed. Note that a cutting process such as a grindstone may be used instead of laser irradiation.

  In the case of the above-described forming method, since the conductive film is provided on the entire substrate 13 with conductive film, the conductive film is naturally provided also on the surfaces of the terminal portions 3 and 4. Therefore, the conductive film provided on the terminal portions 3 and 4 may be used as a connection surface during mounting. Further, a corrosion-resistant film (or solder erosion preventing film) such as nickel or lead-free solder obtained by adding other metal (except lead) to Sn or Sn on the conductive films on the surfaces of the terminal portions 3 and 4 At least one of the bonding films made of may be provided. In addition, the conductive film is provided only on the surface of the substrate other than the end, and a conductive paste material such as silver paste is applied to the surfaces of the terminal portions 3 and 4 and baked, and the baked conductor and the conductive film are electrically connected to each other. The parts 3 and 4 may be formed. Further, at least one of a corrosion-resistant film or a bonding film may be provided on the baked conductor. As described above, the helical antenna 1 can be manufactured.

  In addition, you may form the helical part 2 by winding linear bodies, such as conducting wire. In this case, what is necessary is just to fix a linear body on the base | substrate 6 using members, such as an adhesive agent and a resin mold. It should be noted that the thickness, length, etc. of the helical portion 2 can be obtained by an appropriate experiment according to the characteristics of the electronic device used.

  Next, a description will be given of performing a broadband antenna.

  5 and 6 are configuration diagrams of the antenna device according to Embodiment 1 of the present invention.

Reference numeral 15 denotes an antenna device, 16 denotes a first antenna, 17 denotes a second antenna, 18 and 19 denote matching elements, 20 denotes an open portion, 21 denotes an antenna substrate, and 22 denotes a feeder line. The first antenna 16 may be a helical antenna as shown in FIG. 5, a pattern antenna on a substrate, or another antenna. Similarly, the second antenna 17 may be a helical antenna, a pattern antenna on a substrate, or another antenna. In FIG. 5, a helical antenna is represented as the first antenna 16, and a pattern antenna is represented as the second antenna 17. It is appropriate to select whether to use a helical antenna or a pattern antenna by optimizing manufacturing and cost. Note that the resonance frequencies of the first antenna 16 and the second antenna 17 are not the same, but are adjacent frequencies.

  The matching elements 18 and 19 are elements such as inductors and capacitors, and are provided for impedance matching between the first antenna 16 and the second antenna 17 and the feeder line 22. Further, the feed line 22 may be a feed pattern formed on the antenna substrate 21 as shown in FIG. 5, or may be a conductive line such as a coaxial cable or a copper wire.

  As is clear from FIG. 5, the two antennas, the first antenna 16 and the second antenna 17, are fed through a common feeding line 22. Accordingly, a common signal current is supplied to the first antenna 16 and the second antenna 17, and signals received by the first antenna 16 and the second antenna 17 are transmitted through the feeder lines 22, respectively. Although not shown in FIG. 5, the first antenna 16 and the second antenna 17 are mounted on a power feeding unit such as a solder land, and the matching elements 18 and 19 and the power feeding line 22 are opened through the power feeding unit. Connected. The other is connected to the open portion 20, and the open portion 20 is similarly formed of a solder land or the like. It is also appropriate to increase the bandwidth of each of the first antenna 16 and the second antenna 17 by providing a top crown conductor portion in the open portion 20 and increasing the load capacity. At this time, the top crown conductor is formed of a solder land or a substrate pattern. By connecting to the open part, radiation and reception of radio waves as an antenna are realized.

  The antenna device 15 shown in FIG. 5 is an antenna device having two different resonance frequencies which are close to each other and which the first antenna 16 and the second antenna 17 have.

  In FIG. 6, an antenna device 15 including three antennas that are close and have different resonance frequencies is shown. Reference numeral 23 denotes a third antenna, which may be a pattern antenna on the substrate, a helical antenna, or another antenna. The first antenna 16 and the second antenna 17 are different from each other but have close resonance frequencies. The third antenna 23 is also connected to the matching element and the power supply line 22 through the power supply unit, and is connected to the open part 20 by a solder land or the like. The third antenna 23 is connected to the same feeder line 22 as the first antenna 16 and the second antenna 17, is supplied with a common signal current, and transmits a received signal in common. According to the antenna device shown in FIG. 6, an antenna device having three adjacent resonant frequencies is configured.

  Next, a description will be given of the enhancement of the bandwidth.

  7 and 8 are frequency characteristic diagrams of the antenna device according to Embodiment 1 of the present invention. FIG. 9 is a special frequency diagram for a single antenna. The horizontal axis represents frequency and the vertical axis represents gain. FIG. 7 shows the frequency characteristics when the first antenna 16 and the second antenna 17 shown in FIG. 5 exist, and FIG. 8 shows the case where the third antenna 23 shown in FIG. 6 exists. It is the frequency characteristic.

f1 is the resonance frequency of the first antenna 16, f2 is the resonance frequency of the second antenna 17, and f3 is the resonance frequency of the third antenna 23. fΔ is a frequency band for transmission and reception, and a frequency band in which a necessary gain can be secured is shown. That is, it is a state in which signals included in the band fΔ can be transmitted and received. On the other hand, FIG. 9 shows frequency characteristics when a single antenna is used. As is apparent from fΔ in FIG. 9, a single antenna has a narrow band, which is insufficient when a wide band is required, such as communication at a high transmission rate. On the other hand, in the frequency characteristics of the antenna device according to the first embodiment of the present invention shown in FIGS. 7 and 8, it can be seen that fΔ is sufficiently wide and wide. By smoothly connecting two or more different resonance frequencies which are close to each other, the band fΔ is expanded. Further, as apparent from FIGS. 7 and 8, since the band fΔ is expanded by connecting different resonance frequencies close to each other, if the respective resonance frequencies f1, f2, and f3 are too far apart, Each of the peak intervals of f1, f2, and f3 becomes too large, and a region having a very low gain occurs between the peaks. In this case, since transmission / reception is not sufficient, the band fΔ is not expanded. On the other hand, if f1, f2, and f3 are too close to each other, even if these resonance frequencies are connected, the band fΔ is still narrow, and the intended broadening of the band cannot be realized. For this reason, it is necessary to optimally determine the resonance frequency of each antenna from the relationship between the target band and the gain. In addition, when a very wide band is required, it can be realized by connecting not only the third antenna but also a plurality of antennas.

  Since all the signals included in the expanded band fΔ are transmitted through the same feeder line 22, it is possible to receive and demodulate all the data included in the wideband region. Thereby, transmission / reception in a very wide band required for data communication such as a high transmission rate is realized.

  Each of the first antenna 16, the second antenna 17, and the third antenna 23 may be a helical antenna, a pattern antenna, or another antenna. From the standpoint of making it easier, it is preferable that the main first antenna is a helical antenna and the other antennas are pattern antennas. In particular, high frequencies such as 800 MHz, 900 MHz, and 1.8 GHz in a cellular phone are particularly suitable because miniaturization of the antenna device is promoted by a helical antenna or a pattern antenna. At this time, wide-band transmission / reception can be realized while maintaining the downsizing of the electronic apparatus incorporating the antenna device.

  In addition, when reception is required in a dual band of 900 MHz and 1.8 GHz, such as GSM of a mobile phone, for example, it is possible to realize an antenna device having a wide band by using two antennas. it can.

  FIG. 10 is a configuration diagram of the dual-band antenna device according to Embodiment 1 of the present invention. For example, this is a case where two antenna systems that perform transmission and reception in the 900 MHz band and antenna system that perform transmission and reception in the 1.8 GHz band are mounted as dual bands.

  Reference numeral 25 denotes an antenna device, 26 denotes a first helical antenna, 28 denotes a first pattern antenna, 27 denotes a second helical antenna, 29 denotes a second pattern antenna, and 30 denotes a feeder line. All antennas are connected to a common feeder line 30 through matching elements and the like. The other terminal portion is connected to an independent open portion. The first helical antenna 26 and the first pattern antenna 28 form an arbitrary frequency band (for example, 900 MHz band), and the second helical antenna 27 and the second pattern antenna 29 form another frequency band (for example, 1.. 8 GHz band). Further, the resonance frequencies of the first helical antenna 26 and the first pattern antenna 28 are close to each other and are different from each other, and each resonance frequency is smoothly connected, so that the broadband fΔ as described in FIG. It is formed. On the other hand, the resonance frequencies of the second helical antenna 27 and the second pattern antenna 29 are also close to each other and differ from each other, and each resonance frequency is smoothly connected to form a wide band fΔ. At this time, since the transmission / reception frequency generated by the first helical antenna 26 and the first pattern antenna 28 and the transmission / reception frequency generated by the second helical antenna 27 and the second pattern antenna 29 are different bands, for example, 900 MHz. Dual band communication such as 1.8 GHz will be realized. Further, since each frequency band is widened as described with reference to FIG. 8 and the like, wideband communication necessary for a high transmission rate is realized.

In FIG. 10, in order to realize a wide band, a wide band was realized by combining one helical antenna and one pattern antenna for communication in an arbitrary frequency band. It is also possible to increase the bandwidth by combining three or more antennas.

  In the case of a triple band or the like, it can be realized by adding a combination of a plurality of antennas having a resonance frequency necessary for the triple band and a resonance frequency close thereto.

  Next, experimental results for these antenna devices will be described.

  FIG. 11 shows experimental results of comparison of frequency characteristics between the conventional antenna device and the antenna device of the present invention. 11A is a schematic diagram of a conventional antenna device, FIG. 11B is a schematic diagram of the antenna device of the present invention, and FIG. 11C is a frequency characteristic diagram.

  As shown in FIG. 11A, the conventional antenna device is composed of a single helical antenna (or a pattern antenna or another antenna) and has a single resonance frequency. On the other hand, in the antenna device of the present invention shown in FIG. 11B, a pattern antenna is connected to a common feeding line in addition to the helical antenna. Further, although the helical antenna and the pattern antenna are close to each other, their resonance frequencies are different. As is apparent from FIG. 11C, which shows the experimental results in terms of frequency characteristics, it can be seen that the bandwidth of the antenna device of the present invention is greatly expanded compared to the bandwidth of the conventional antenna device. According to the experimental results, the bandwidth is expanded to about 1.8 to 2 times. As described above, the transmission / reception bandwidth can be effectively expanded by connecting a plurality of antennas having different resonance frequencies close to each other to a common feeder line as in the present invention. In the experiment, the case where two antennas are used has been described. However, when three or more antennas are used, the band is further expanded and the gain can be secured more easily. Further, by using a helical antenna or a pattern antenna as an antenna, it can be configured while maintaining a sufficiently small size as compared with a conventional antenna device.

  FIG. 12 shows the contents of an experiment using two antennas in each of the GSM band (900 MHz) and the DCS band (1.8 GHz). 12A is a schematic diagram of a GSM band antenna device, FIG. 12B is a schematic diagram of a DCS band antenna device, FIG. 12C is a frequency characteristic diagram of an experimental result of the GSM band, and FIG. ) Is a frequency characteristic diagram of an experimental result of the DCS band, and FIG. 12E is a diagram showing a gain result. As shown in each of FIGS. 12A and 12B, the helical antenna and the pattern antenna are connected to a common feeder line, and the resonance frequencies of the helical antenna and the pattern antenna are close to each other, It is different. As shown in the frequency characteristic diagrams of FIGS. 12C and 12D, the resonances of the helical antenna and the pattern antenna occur close to each other, which are smoothly connected, resulting in the transmission / reception band. Is expanding. f1 is the difference between the resonance frequencies of the helical antenna and the pattern antenna in the GSM band, and f2 is the difference between the resonance frequencies of the pattern antenna and the helical antenna in the DCS band. Since the differences f1 and f2 are related to the transmission / reception frequency band, the frequency band is expanded by increasing f1 and f2. However, the greater the difference between the resonance frequencies, the greater the portion of the gain that is sandwiched between the peaks of each resonance frequency, which results in lowering the overall gain. It is necessary to adjust from the balance. It is necessary to determine the resonance frequency of the antenna constituting the antenna device so that the balance between the gain and the bandwidth is optimal.

FIG. 12E shows gain measurement results at two frequency points when f1 and f2 are changed. As is apparent from the table, when f1 and f2 change to this extent, it can be seen that the gain is substantially maintained. Furthermore, in the GSM band, the necessary gain is -2.0 dBi, so it can be seen that this necessary gain is almost achieved. Furthermore, it can be seen that the frequency band is expanded and a sufficient balance between gain and band is secured. Thus, it can be seen that wideband transmission for requiring a high transmission rate in the GSM band is achieved.

  Similarly, even in the DCS band, a result in which a balance between the frequency band and the gain is ensured is obtained, and it can be seen that the antenna apparatus can realize wideband transmission using the DCS band.

  Although the above experimental results have been described using the GSM band and the DCS band as an example, the same applies to other bands, and it is said that communication related to this frequency band is not limited to GSM and DCS. Not too long.

  Further, the antenna device has been described as being realized by a combination of a helical antenna and a pattern antenna, but other antennas may be used, and the antenna device is configured using three or more antennas. It may be. In addition, by connecting both the antenna group that constitutes the GSM band and the antenna group that constitutes the DCS band to the same feeder line, broadband transmission is realized in each frequency band while supporting dual bands. It is also suitable. In the case of such a dual band, it is desirable to connect from an antenna group having a high frequency band with reference to the feeder line. Although it is not shown in the figure, it is confirmed from the experimental results that the gain is improved by doing so.

  In addition, since the helical antenna secures the current density by utilizing the image current generated on the ground surface, it is desirable to secure the ground surface.

  It is also preferable to increase the load capacity and further promote the broadband by connecting the top crown conductor to the open terminal of the helical antenna.

  With the antenna device as described above, wide-band transmission / reception required for high-transmission-rate wireless communication and the like is realized. Further, it is possible to maintain a small size by using a helical antenna for part or all of the antenna of the antenna device.

(Embodiment 2)
FIG. 13 is a block diagram of a receiving apparatus according to Embodiment 2 of the present invention. 40 is a receiving device, 41 is an antenna device, 42 is a frequency discriminator, 43 is a detector, 44 is a data demodulator, and 45 is an error detector. The error detection unit 45 may be replaced with an error correction unit that performs error correction.

  First, the operation of the receiving device 40 will be described.

  The antenna device 41 receives a radio signal, and the received signal is transmitted to the frequency discriminator 42. At this time, since the antenna device 41 realizes wideband reception as described in the first embodiment, it is appropriate when data communication is performed over a very wide band such as a high transmission rate. With such an antenna device capable of wideband reception, all necessary bands can be received, and the received signals can be detected and demodulated at once, eliminating the need for an extra circuit configuration and demodulating data. There is a merit that the processing procedure such as reconstruction is unnecessary.

In the frequency discriminator 42, a signal having a frequency desired to be received is extracted. A signal from the frequency discriminator 42 is transmitted to the detection unit 43. The detection unit 43 extracts a necessary signal waveform from the carrier wave by synchronous detection or delay detection. The signal extracted by the detector 43 is a data demodulator 44.
The data that has been transmitted and modulated is demodulated. For example, phase-modulated digital data is demodulated into original digital data by demapping in an orthogonal plane. Alternatively, the frequency-modulated digital data is demodulated as “1” and “0” which are binary signals due to the difference in modulation frequency. The data demodulated by the data demodulator 44 is subjected to error detection by the error detector 45 as necessary. For example, error detection is performed by a cyclic code check (hereinafter referred to as “CRC”), a parity code, or the like. Specifically, a match between the parity code attached on the transmission side and the even parity or odd parity of the actually demodulated data is detected. Alternatively, it is detected by dividing the demodulated data by the generator polynomial and confirming the remainder. When an error is detected, processing such as requesting retransmission of data is performed.

  Alternatively, error correction may be performed by Viterbi decoding or Reed-Solomon decoding. In this case, since the detected error can be corrected, a data retransmission request or the like becomes unnecessary, resulting in an increase in reception performance.

  It is also preferable to mount a low-noise amplifier or a down-conversion unit after the antenna device as necessary. In the case of very high frequency wireless communications, it may be difficult to detect and demodulate data at high frequencies, so it may be appropriate to reduce the frequency to an intermediate frequency by down-conversion. is there.

  With the receiving apparatus 40 as described above, it is possible to realize reception with high transmission rate data communication requiring a wide band with a small circuit configuration.

  Realization of wide bandwidth by having two antennas with different resonant frequencies in close proximity and a feeding part that feeds power to the feeding terminals of the two antennas in common, and the open terminals of the two antennas being independent from each other Therefore, the present invention can be applied to applications that need to realize communication at a high transmission rate that requires a wide band.

The perspective view of the helical antenna in Embodiment 1 of this invention The perspective view of the helical antenna in Embodiment 1 of this invention FIG. 3 is an equivalent circuit diagram of the helical antenna according to the first embodiment of the present invention. Manufacturing process diagram of helical antenna in Embodiment 1 of the present invention Configuration diagram of antenna apparatus according to Embodiment 1 of the present invention Configuration diagram of antenna apparatus according to Embodiment 1 of the present invention Frequency characteristic diagram of antenna apparatus according to Embodiment 1 of the present invention Frequency characteristic diagram of antenna apparatus according to Embodiment 1 of the present invention Frequency characteristics for a single antenna Configuration diagram of dual-band antenna device according to Embodiment 1 of the present invention (A) Schematic diagram of conventional antenna device (b) Schematic diagram of antenna device of the present invention (c) Frequency characteristic diagram (A) Schematic diagram of antenna device in GSM band (b) Schematic diagram of antenna device in DCS band (c) Frequency characteristic diagram of experimental result in GSM band (d) Frequency characteristic diagram of experimental result in DCS band (e) Gain Figure showing the results The block diagram of the receiver in Embodiment 2 of this invention Configuration diagram of a communication device including an antenna device in the prior art

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Helical antenna 2 Helical part 3, 4 Terminal part 5 Spiral groove 6 Base | substrate 7 Protective film 10 Rotation support stand 11 Motor 12 Laser irradiator 13 Base | substrate with a conductive film 14 Spiral groove 15 Antenna apparatus 16 1st antenna 17 2nd antenna DESCRIPTION OF SYMBOLS 18, 19 Matching element 20 Opening part 21 Board | substrate 22 Feed line 23 3rd antenna 25 Antenna apparatus 26 1st helical antenna 27 2nd helical antenna 28 1st pattern antenna 29 2nd pattern antenna 30 Feed line 40 Reception Device 41 Antenna device 42 Frequency discriminator 43 Detection unit 44 Data demodulation unit 45 Error detection unit 100 Communication device 101, 102, 103, 104 Narrow band antenna 105, 106, 107, 108 Transmission path 109 Transmission / reception unit

Claims (14)

A plurality of antennas having different resonance frequencies;
A power supply unit that supplies power to the power supply terminals of the plurality of antennas in common;
An antenna device, wherein open terminals of the plurality of antennas are independent of each other. The antenna apparatus according to claim 1, wherein the different frequencies are adjacent frequencies. The antenna device according to claim 2, wherein the adjacent frequency is 10 MHz to 200 MHz. At least one of the antennas has a base, a helical part provided on the base, and a pair of terminal parts provided on the base, and the helical part and the terminal part are electrically connected, and The antenna device according to any one of claims 1 to 3, wherein the antenna device is a helical antenna in which one of the terminal portions is a feeding terminal and the other is an open terminal. The antenna device according to claim 4, wherein the helical antenna is formed by trimming a base body provided with a conductive film to provide a spiral groove. 5. The antenna device according to claim 4, wherein the helical antenna is formed by applying conductive windings to the base. The antenna device according to claim 1, wherein at least one of the antennas is formed by a substrate pattern. The antenna device according to claim 1, wherein a top crown conductor is provided at an open terminal of the antenna. An antenna group including a plurality of antennas forming an arbitrary transmission / reception band and having different resonance frequencies;
An antenna group consisting of a plurality of antennas forming a transmission / reception band different from the arbitrary transmission / reception band and having different resonance frequencies;
A power feeding unit that feeds power to power feeding terminals of a plurality of antennas included in the antenna group;
An antenna device, wherein open terminals of a plurality of antennas included in the antenna group are independent of each other. In the antenna group forming the arbitrary transmission / reception band, the antenna included in the antenna group having a high frequency in the transmission / reception band is connected closer to the common feeder than the antenna included in the antenna group having a low frequency. The antenna device according to claim 9. The antenna device according to any one of claims 1 to 10,
A frequency discriminator for discriminating the frequency of the received signal connected to the antenna device;
A detector for detecting the signal discriminated by the frequency discriminator;
A receiving apparatus comprising: a data demodulating unit that demodulates data contained in the signal detected by the detecting unit. The receiving apparatus according to claim 11, wherein a down-conversion unit that reduces a frequency of a signal received by the antenna apparatus exists between the frequency discriminator and the antenna apparatus. The receiving apparatus according to claim 11, wherein an error detection unit that performs error detection on data demodulated in the data demodulation unit is present at a subsequent stage of the data demodulation unit. The receiving apparatus according to claim 10, wherein an error correcting unit that corrects an error in data demodulated in the data demodulating unit is present at a subsequent stage of the data demodulating unit.

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