JP2011250156A - Reception system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce rush-in of electromagnetic noise to a feeding line for reception antenna of a first frequency band while a structure of an antenna portion is prevented from becoming redundant in a reception system receiving a first frequency band (AM radio broadcast band, for example) and a second frequency band (FM radio broadcast band, for example).SOLUTION: An FM antenna element 12 has a cylindrical shape where an inner side becomes hollow. The feeding line 13 for an AM antenna element 11 is wired through an inner cavity of the FM antenna element 12, and a part of a radial outside in a longitudinal direction of the AM antenna element 11 is covered with the FM antenna element 12. A feeding route between an FM radio tuner 152 in a receiver 15 and the FM antenna element 12 is connected to a ground portion 156 via an inductance element 154. The inductance element 154 has a frequency characteristic in which impedance becomes relatively high in the FM radio broadcast band compared to the AM radio broadcast band.

Description

  The present invention includes an antenna that receives radio waves in a first frequency band (for example, AM radio broadcast band) and an antenna that receives radio waves in a second frequency band (for example, FM radio broadcast band). The present invention relates to a receiving system capable of receiving both radio signals in the frequency band.

  A receiving system capable of receiving both radio waves in two different frequency bands, for example, an AM radio broadcast band (hereinafter, AM band) and an FM radio broadcast band (hereinafter, FM band) is known. A typical configuration of the receiving system is shown in FIG. The receiving system 5 illustrated in FIG. 5 includes an AM antenna element 51 that can receive an AM band radio wave and an FM antenna element 52 that can receive an FM band radio wave. Japanese AM radio broadcast radio waves are generated by amplitude-modulating (AM) a carrier wave in an MF (Medium Frequency) band (specifically, 531 to 1602 kHz). Further, Japanese FM radio broadcast radio waves are generated by frequency modulation (FM) of a carrier wave in a VHF (Very High Frequency) band (specifically, 76 to 90 MHz).

  A balanced antenna such as a loop antenna or a bar antenna is often used as the AM antenna element 51 that receives MF band radio waves. FIG. 5 shows a case where the AM antenna element 51 is a loop antenna. The loop antenna has a structure in which a conductive wire with an insulation coating is wound about a dozen times on a concave groove provided in a resin frame. The AM antenna element 51 is connected to the antenna terminal 56 of the receiving device 55 by a feed line 53. When the AM antenna element 51 is a balanced antenna such as a loop antenna or a bar antenna, a balanced line such as a twisted pair wire or a parallel two-wire feeder line is used as the feed line 53. The length of the feeder line 53 is typically about 1 to 1.5 m.

  As the FM antenna element 52 that receives radio waves in the VHF band, a monopole antenna (that is, an unbalanced antenna) is often used. For example, in an audio device for home use, as the FM antenna element 52 having a simple structure, a lead wire having a length of about 1/4 to 1/2 (about 0.8 to 2 m) of the wavelength of the FM band is used. As the unbalanced FM antenna element 52, a rod antenna or the like is also used. The FM antenna element 52 is connected to the antenna terminal 57 of the receiving device 55 by a feed line 54. When the FM antenna element 52 is an unbalanced antenna, an unbalanced line such as a coaxial cable is used as the feed line 54.

  The receiving device 55 receives signals received by the AM antenna element 51 and the FM antenna element 52 via the antenna terminals 56 and 57. The receiving device 55 has an AM radio tuner function and an FM radio tuner function, and performs demodulation processing in synchronization with a channel designated by a user operation or the like.

  Patent Document 1 discloses a receiving system in which a first antenna element that receives AM-band radio waves and a second antenna element that receives AM-band and FM-band radio waves are connected to a receiving device via a feeder line. Is disclosed. The second antenna element has a cylindrical shape with a hollow inside. One end of the feed line of the first antenna element is connected to the first antenna element through a hollow portion of the cylindrical second antenna element. A filter for extracting an AM band signal is connected to the other end of the feed line of the first antenna element. The reception signal by the first antenna element after passing through the filter and the reception signal by the second antenna element are combined and supplied to the reception apparatus. The reception system disclosed in Patent Document 1 improves the reception sensitivity of AM charged waves by synthesizing the reception signals of the first and second antenna elements.

  Patent Document 2 discloses a technique in which one antenna element (for example, a helical antenna) is used for both reception of an AM charging wave and an FM charging wave. Specifically, the antenna device described in Patent Document 2 has a structure in which an FM band passing circuit and an AM band parallel resonance circuit are connected in parallel between an antenna element and a feeding coaxial cable. Here, the FM band passing circuit has a low impedance with respect to the FM band and a high impedance with respect to the AM band. The AM band parallel resonance circuit resonates the AM band signal in parallel with the antenna element capacitance and the coaxial cable capacitance. The FM bandpass circuit typically includes a capacitive element. The AM band parallel resonance circuit typically includes an inductor element that cuts off an FM band signal and a matching transformer circuit.

Japanese Patent Laid-Open No. 5-37224 JP 2001-36328 A

  In recent audio apparatuses (reception apparatus 55 in FIG. 5), an apparatus using a switching power supply in a power supply circuit part and an apparatus having a digital signal processor or a color liquid crystal display unit are increasing. In such a case, electromagnetic noise radiated from the audio apparatus to the outside jumps into the AM antenna element 51 or the AM antenna feed line 53, thereby deteriorating the reception performance of the AM charged wave. Also, in a home theater system that has recently become widespread, a television receiver and an audio device are arranged and used close to each other. Therefore, there is a problem that the electromagnetic noise radiated from the television receiver to the outside of the AM antenna element 51 and the feed line 53 deteriorates the reception performance of the AM charged wave.

  The inventors of the present application have studied the above-described solution to the deterioration of the AM charging wave reception performance. Among the above-described factors of deterioration in AM reception performance, electromagnetic noise jumping into the AM antenna element 51 increases the length of the feed line 53 and disposes the AM antenna element 51 away from the audio device and the television receiver. Can be reduced. However, simply moving the AM antenna element 51 away from the audio device and the television receiver does not reduce electromagnetic noise jumping into the feed line 53 that connects the AM antenna element 51 and the audio device (receiving device 55). In particular, jumping of electromagnetic noise into the portion near the antenna terminal 56 of the audio device (reception device 55) in the entire length of the feed line 53 becomes a problem.

  In order to reduce the jump of electromagnetic noise into the feed line 53, the feed line 53 may be shielded by a grounded conductor. However, if the shield of the feed line 53 is provided in addition to the AM antenna element 51 and the FM antenna element 52, there is a problem that the entire configuration of the reception system 5 (particularly, the configuration of the antenna portion) becomes redundant.

  Patent Documents 1 and 2 do not disclose any configuration for reducing the jumping of electromagnetic noise to the feeding line 53 for the AM antenna element 51 while suppressing the redundant configuration of the antenna portion.

  Further, the above-described problem is not limited to the case where the AM band and the FM band are received. That is, it is generally a problem in a reception system that receives both radio waves in the first frequency band and radio waves in the second frequency band having a higher frequency.

  The present invention has been made on the basis of the above-mentioned knowledge by the inventors of the present application, and in the receiving system that receives the first and second frequency bands, while suppressing the redundant configuration of the antenna portion, It is an object to reduce electromagnetic noise jumping into the power supply line for the receiving antenna in the first frequency band (the power supply line 53 for the AM antenna element 51 in FIG. 5).

  In order to achieve the above object, a receiving system (1) according to a first invention includes a first tuner unit (151) for selecting a receiving frequency in a first frequency band, and the first frequency band. A receiving device (15) including a second tuner unit (152) for selecting a receiving frequency in a high second frequency band, and a first antenna element (11) for receiving radio waves in the first frequency band And a second antenna element (12) for receiving a radio wave in the second frequency band, and having a cylindrical shape with an inside hollow, and passing through the cavity of the second antenna element (12) The first antenna element (11) and the receiver (15) are connected to each other, and at least a part of the outer side in the longitudinal direction is covered with the second antenna element (12). Track (13) and said first Between the second antenna element (12) and the second tuner section (152), the second feed line (14) connecting the antenna element (12) and the receiver (15). Connected between a power supply path including the second power supply line (14) and a ground part (156) having a ground potential, and relatively in the second frequency band as compared to the first frequency band. And an inductance element (154) having a high impedance.

  The receiving system (1) according to the second invention is the first invention described above, wherein the inductance element (154) causes the signal in the first frequency band to flow to the grounding part (156). The second frequency band signal has an impedance characteristic determined so as to be supplied to the receiving device (15) without substantially flowing to the ground unit (156).

  The receiving system (1) according to the third invention is the first or second invention described above, wherein the first feeding line (13) is an axis of the second antenna element (12). It is longer than the length of the direction.

  Moreover, the receiving system (1) according to the fourth invention is the above-mentioned third invention, wherein the second antenna element (12) is arranged in the longitudinal direction of the first feeding line (13). It is arrange | positioned so that the side close | similar to the said receiver (15) may be covered partially.

  A receiving system (1) according to a fifth aspect of the present invention is any one of the first to fourth aspects described above, wherein the second antenna element (12) is in the second frequency band. It has a length of 1 / integer of the wavelength of the representative frequency included.

  A receiving system (1) according to a sixth invention is any one of the first to fifth inventions described above, wherein the first antenna element (1) of the first feeder line (13) is provided. 11) N pole (N is connected to the end of the second feeder line (14) not connected to the second antenna element (12)) Two or more phone plugs (200), the receiver (15) further includes an N-pole phone jack (16), and the inductance element (154) is disposed in the receiver (15). When the phone plug (200) is inserted into the phone jack (16), the first and second antenna elements (11 and 12), the receiver (15), and the inductance element (154) are connected. Between Those that are configured to be gas-connected.

  A receiving system (1) according to a seventh invention is the invention according to any one of the first to sixth inventions, wherein the inductance element (154) has an impedance in the first radio frequency band. It is adjusted to be smaller than the first reference value.

  The receiving system (1) according to an eighth aspect of the present invention is any one of the first to seventh aspects described above, wherein the first frequency band is an AM radio broadcast frequency band, and the second The frequency band is the FM radio broadcast frequency band.

  According to the first to eighth inventions described above, the power supply line for the receiving antenna in the first frequency band (in FIG. 5, the power supply for the AM antenna element 51 is suppressed while suppressing the redundant configuration of the antenna portion. The electromagnetic noise can be reduced from entering the line 53).

It is a schematic diagram which shows the example of whole structure of the receiving system which concerns on Embodiment 1 of this invention. It is a figure which shows the structural example of the antenna part 10 shown in FIG. It is a figure which shows the structural example of the receiver 15 shown in FIG. It is a figure which shows the other structural example of the antenna part 10 shown in FIG. It is a schematic diagram which shows the example of whole structure of the receiving system which concerns on background art.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. In the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted as necessary for the sake of clarity.

<Embodiment 1 of the Invention>
A configuration example of the receiving system 1 according to the present embodiment is shown in FIG. In FIG. 1, an antenna unit 10 includes an AM antenna element 11 that receives an AM charging wave and an FM antenna element 12 that receives an FM charging wave. The AM antenna element 11 is not particularly limited, and may be a known balanced antenna or unbalanced antenna capable of receiving an AM charged wave. In the example of FIG. 1, the case where the AM antenna element 11 is a balanced loop antenna as in the case of the AM antenna element 51 shown in FIG. The AM antenna element 11 is connected to an antenna terminal 16 provided in the receiving device 15 by a feed line 13.

  The FM antenna element 12 is constituted by a conductor having a cylindrical shape with a hollow inside. The FM antenna element 12 is connected to the antenna terminal 16 by a feed line 14. Note that the above-described feed line 13 for the AM antenna element 11 is connected between the antenna terminal 16 and the AM antenna element 11 through a cavity inside the FM antenna element 12. As a result, at least a part of the outside in the radial direction of the entire feed line 13 in the longitudinal direction is covered with the FM antenna element 12. Although details will be described later, since the FM antenna element 12 functions as an electromagnetic shield in the AM band, the feed line 13 covered by the FM antenna element 12 is shielded against electromagnetic noise from the outside.

  The feed line 13 and the FM antenna element 12 only need to be electrically insulated. For this reason, the feed line 13 may be separated from the inner wall of the cavity portion of the FM antenna element 12, or is in contact with the inner wall of the cavity portion of the FM antenna element 12 via an insulator (for example, an insulation coating of a twisted pair wire). May be. Further, the FM antenna element 12 does not have to be cylindrical. The FM antenna element 12 may be a cylindrical shape having an arbitrary cross-sectional shape, and may be, for example, a shield portion of a coaxial shield wire that covers the feed line 13.

  The receiving device 15 includes an AM radio tuner unit 151 and an FM radio tuner unit 152, which will be described later, and performs demodulation processing in synchronization with a channel designated by a user operation or the like. The receiving device 15 has an antenna terminal 16 to which the feed lines 12 and 13 can be connected.

  Next, the detailed configuration of the antenna unit 10 will be described. FIG. 2 is a diagram illustrating a configuration example of the antenna unit 10. In the example of FIG. 2, the feed line 13 is a twisted pair line. However, the twisted pair wire is merely an example of a balanced line, and another balanced line such as a parallel two-wire feeder line may be used as the feed line 13. When the AM antenna element 11 is an unbalanced antenna, any unbalanced line may be used as the feed line 13. As described above, the feed line 13 is connected to the AM antenna element 11 through the internal cavity of the FM antenna element 12. An arbitrary cable may be used for the feed line 14.

  In the example of FIG. 2, a three-terminal phone plug 20 is connected to the end of the feeder lines 13 and 14 on the receiving device 15 side. In this case, the antenna terminal 16 provided in the receiving device 15 may be a phone jack. When the phone plug 20 is inserted into the phone jack (antenna terminal 16), the antenna elements 11 and 12 and the AM and FM radio tuner units 151 and 152 in the receiving device 15 are electrically connected. The tip portion 201, the ring portion 202, and the sleeve portion 203 of the phone plug 20 are insulated by insulating rings 204 and 205. In the example of FIG. 2, one of the twisted pair lines (feed line 13) is connected to the chip part 201, and the other of the twisted pair lines (feed line 13) is connected to the ring part 202. In addition, the feed line 14 is connected to the sleeve portion 203 of the phone plug 20.

  According to the example of FIG. 2, the antenna elements 11 and 12 and the receiving device 15 can be connected by a pair of phone jacks and phone plugs. For this reason, connection and removal of the antenna unit 10 and the receiving device 15 can be easily performed. In addition, since the antenna terminal 16 provided in the receiving device 15 needs only one phone jack, the area required for arranging the antenna terminals can be reduced, which contributes to downsizing of the receiving device. Needless to say, the connections between the tip portion 201, the ring portion 202, and the sleeve portion 203 and the feed lines 13 and 14 are not limited to the combinations shown in FIG. Further, the number of terminals of the phone plug 20 may be determined according to the number of lines of the feed lines 13 and 14, and may be two terminals or four terminals or more. Furthermore, when the FM antenna element 12 is a shield part of a coaxial shield line formed with the feed line 13, the FM antenna element 12 is directly connected to the sleeve part 203 without providing a separate feed line 14 for the FM antenna element 12. You may connect.

  Below, the length L1 of the feed line 13 in the longitudinal direction, the length L2 of the FM antenna element 12 in the longitudinal direction, and the arrangement of the FM antenna elements 12 will be described. In order to reduce the jump of electromagnetic noise from a noise source such as the receiving device 15 (audio device) to the AM antenna element 11, the length of the feed line 13 so that the AM antenna element 11 can be arranged away from the receiving device 15. L1 should be lengthened. For example, the length may be longer than 1 to 1.5 m, which is a typical length of a feed line for an AM antenna, or 2 to 3 m or more. The electric field strength of electromagnetic noise radiated from noise sources such as the receiving device 15 (audio device) and the television receiver is inversely proportional to the distance. For this reason, if the length L1 of the feed line 13 is increased, for example, if L1 is set to 2 to 3 m, electromagnetic noise jumping into the AM antenna element 11 can be sufficiently reduced.

  On the other hand, in order to increase the reception sensitivity of the FM band radio wave, the length L2 of the FM antenna element 12 in the longitudinal direction (axial direction) is preferably between 1/4 and 1/2 of the FM band wavelength. Since the FM radio broadcast frequency band (FM band) in Japan is 76 to 90 MHz, the length of 1/4 to 1/2 of the wavelength of the FM band is about 0.8 to 2 m. The length L2 in the longitudinal direction of the FM antenna element 12 is specifically set to 83 MHz, which is a center frequency of 76 to 90 MHz, as a representative frequency, and is 0.9 m when the frequency is 1/4 of the wavelength of the representative frequency. When it is / 2, it is 1.8 m.

  When the lengths L1 and L2 are determined as described above, the entire length of the feed line 13 cannot be covered by the FM antenna element 12. In this case, as shown in FIG. 2, the FM antenna element 12 may be disposed so as to cover the receiving device 15 side of the AM band feed line 13, that is, the phone plug 20 side. More specifically, the FM antenna element 12 may be disposed so as to cover a portion from the end end on the phone plug 20 side to the length L2 in the entire longitudinal direction of the feed line 13. The electric field intensity of electromagnetic noise is larger as it is closer to a noise source (such as a receiver 15 (audio device) and a television receiver). For this reason, the FM antenna element 12 preferentially shields the side close to the receiving device 15 out of the entire feed line 13, thereby effectively suppressing a decrease in the reception quality of the AM charged wave due to electromagnetic noise. In this way, the length L1 is made longer than the length L2, and the FM antenna element 12 is arranged on the side closer to the receiving device 15 to obtain the electromagnetic shielding effect by the FM antenna element 12, and the receiver 15 is arranged. It is easy to keep the AM antenna element 11 away from a noise source such as an audio device or a television receiver.

  Next, the detailed configuration of the receiving device 15 will be described below. FIG. 3 is a diagram illustrating a configuration example of the receiving device 15. In the example of FIG. 3, the case where the antenna terminal 16 is a phone jack is shown in accordance with the phone plug 20 shown in FIG. The contact fitting 161 is in physical and electrical contact with the tip portion 201 of the phone plug 20. Similarly, the contact fitting 162 contacts the ring portion 202 of the phone plug 20. Further, the sleeve-shaped contact metal fitting 163 contacts the sleeve portion 203 of the phone plug 20.

  The AM radio tuner 151 receives a signal received by the AM antenna element 11 and performs demodulation processing in synchronization with a channel designated by a user operation or the like. The FM radio tuner 152 receives a reception signal from the FM antenna element 12 and performs demodulation processing in synchronization with a channel designated by a user operation or the like. The matching transformer 153 performs balanced-unbalanced conversion and impedance matching between the feeding line 13 on the AM antenna element 11 side and the line of the AM radio tuner 151.

  The inductance element 154 is connected between a line 155 connecting the contact fitting 163 and the FM radio tuner 152 and a grounding part 156 having a ground potential (ground). The grounding unit 156 is connected to, for example, an earth terminal provided on the housing of the receiving device 15 or an earth terminal provided on a power outlet (outlet). Moreover, the grounding part 156 may be connected to a grounding rod or the like embedded in the ground.

  The inductance element 154 has a relatively high impedance in the FM band, which is about two orders of magnitude higher than the AM band. Specifically, the impedance frequency characteristic of the inductance element 154 is such that an AM band signal or a signal having a frequency lower than that of the AM band and the AM band flows to the ground side, and the FM band signal does not substantially flow to the ground side. It may be determined to be supplied to the radio tuner 152 side. More specifically, the inductance element 154 may have a sufficiently low impedance in the AM band, and the impedance frequency characteristic of the inductance element 154 may be determined so that the impedance in the AM band is about 1Ω. Thereby, in the AM band, it can be considered substantially equivalent to the FM antenna element 12 being directly grounded, and the FM antenna element 12 can be used as an electromagnetic shield in the AM band. The inductance element 154 is formed with a general choke coil, for example, a winding coil, a laminated coil in which a winding pattern is formed by screen printing, or a winding pattern using a semiconductor manufacturing technique (sputtering, vapor deposition, etc.). A thin film coil or a lead inductor may be used.

  According to the present embodiment, the FM antenna element 12 can also be used as an electromagnetic shield in the AM band. For this reason, it is possible to reduce the jumping of electromagnetic noise from the noise source such as an audio device or a television receiver in which the receiving device 15 is arranged into the power supply line 13 while suppressing the redundant configuration of the antenna unit 10. Can do.

<Embodiment 2 of the Invention>
In the present embodiment, a modified example of the antenna unit 10 will be described. The overall configuration of the receiving system according to the present embodiment may be the same as the configuration of receiving system 1 shown in FIG. Further, the configuration of receiving apparatus 15 included in the receiving system according to the present embodiment may be the same as the configuration shown in FIG.

  FIG. 4 shows a configuration example of the antenna unit 10 included in the reception system according to the present embodiment. In the example of FIG. 4, the side close to the AM antenna element 11 of the feed line 13 is a twisted pair wire, and the side close to the receiving device 15 (that is, the phone plug 20) is a pair of parallel conductors. Of these, the pair of parallel conductors are covered with FM antenna elements 12A and 12B that function as an AM band electromagnetic shield. Each of the FM antenna elements 12A and 12B has a cylindrical shape with a hollow inside.

  The FM antenna elements 12A and 12B are electrically connected by a feed line 14. The feed line 14 is connected to the sleeve portion 203 of the phone plug 20 as in the configuration shown in FIG. Also with the configuration shown in FIG. 4, the jumping in of electromagnetic noise to the feed line 13 can be reduced by the shielding effect of the FM antenna elements 12A and 12B. In addition, the side near the receiving device 15 (that is, the phone plug 20) of the entire feed line 13 is shielded preferentially by the FM antenna elements 12A and 12B, so that the receiving device 15 (audio device), the television receiver, and the like. It is possible to effectively suppress the deterioration of the reception quality of the AM charged wave due to the electromagnetic noise radiated by.

<Other embodiments>
2 and 4 show an example in which the phone plug 20 is used as a connection portion with the antenna terminal 16. Thereby, attachment and removal of the antenna part 10 are easy, and the installation area of the antenna terminal 16 can be reduced. However, the connection part with the antenna terminal 16 provided in the feed lines 13 and 14 may not be a phone plug. For example, another electrical connector may be used as a connection portion with the antenna terminal 16. Further, for example, a conductive wire portion exposed by removing the insulation coating of the feed lines 13 and 14 may be used as a connection portion with the antenna terminal 16.

  In the first and second embodiments of the present invention, the reception system for receiving the radio waves in the AM band and the FM band has been described. However, the configuration of the receiving system described in Embodiments 1 and 2 is not limited to the combination of the AM band and the FM band, and can be applied to a receiving system that receives radio waves in two different radio frequency bands.

  In the example of FIG. 3, an example in which the inductance element 154 is arranged in the receiving device 15 is shown. However, the inductance element 154 may be attached to any place on the line between the FM antenna element 12 and the FM radio tuner 152. Therefore, the inductance element 154 may be disposed outside the receiving device 15, may be attached to the feed line 14, or may be attached to the FM antenna element 12.

  2 and 4, the configuration in which the side close to the AM antenna element 11 in the entire longitudinal direction of the feed line 13 is not shielded by the FM antenna element 12 is shown. However, the conductor close to the AM antenna element 11 of the feed line 13 may be further shielded by a cylindrical conductor insulated from the FM antenna element 12. Furthermore, the conductor that shields the side near the AM antenna element 11 of the feed line 13 is connected to the FM radio tuner 152 and grounded via the inductance element 154, so that the FM antenna described in the first and second embodiments. You may make it operate | move similarly to the element 12, 12A, 12B. A conductor having a cylindrical shape in which the side close to the AM antenna element 11 is shielded by the FM antenna element 12 and the side close to the receiving device 15 is insulated from the FM antenna element 12 in the entire longitudinal direction of the feed line 13. You may shield by. Further, the whole of the feed line 13 in the longitudinal direction may be covered with the FM antenna element 12.

  Furthermore, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention described above.

DESCRIPTION OF SYMBOLS 1 Reception system 10 Antenna part 11 AM antenna element (1st antenna element)
12, 12A, 12B FM antenna element (second antenna element)
13 Feed line (first feed line)
14 Feed line (second feed line)
15 Receiver 16 Antenna Terminal 20 Phone Plug 151 AM Radio Tuner (First Tuner)
152 FM radio tuner (second tuner section)
153 Matching transformer 154 Inductance element 155 Line 156 Grounding part 161-163 Contact metal fitting 201 Tip part 202 Ring part 203 Sleeve part 204, 205 Insulation ring

Claims (8)

A receiving device including: a first tuner unit that selects a reception frequency in a first frequency band; and a second tuner unit that selects a reception frequency in a second frequency band higher than the first frequency band; ,
A first antenna element for receiving radio waves in the first frequency band;
A second antenna element having a cylindrical shape with a hollow inside and receiving radio waves in the second frequency band;
The first antenna element and the receiving device are connected through the cavity of the second antenna element, and at least a part of the longitudinal outer side in the longitudinal direction is covered with the second antenna element. 1 feed line,
A second feed line connecting the second antenna element and the receiving device;
Compared to the first frequency band, connected between a feeding path including the second feeding line between the second antenna element and the second tuner section and a ground section having a ground potential. An inductance element having a relatively high impedance in the second frequency band;
A receiving system.   The inductance element is defined such that a signal in the first frequency band flows to the grounding unit, and a signal in the second frequency band is supplied to the receiving device without substantially flowing to the grounding unit. The receiving system according to claim 1, wherein the receiving system has an impedance characteristic.   The receiving system according to claim 1, wherein the first feed line is longer than an axial length of the second antenna element.   The receiving system according to claim 3, wherein the second antenna element is disposed so as to partially cover a side close to the receiving device in a longitudinal direction of the first feeding line.   5. The reception system according to claim 1, wherein the second antenna element has a length that is 1 / integer of a wavelength of a representative frequency included in the second frequency band. Connected to the end of the first feed line not connected to the first antenna element and the end of the second feed line not connected to the second antenna element It further includes a phone plug with N poles (N is 2 or more),
The receiver further includes an N pole phone jack,
The inductance element is disposed in the receiver;
The phone plug is inserted into the phone jack so that the first and second antenna elements are electrically connected to the receiving device and the inductance element.
The receiving system according to any one of claims 1 to 5.   The receiving system according to claim 1, wherein the inductance element is adjusted so that an impedance in the first radio frequency band is smaller than a first reference value. The first frequency band is an AM radio broadcast frequency band;
The second frequency band is an FM radio broadcast frequency band;
The receiving system according to any one of claims 1 to 7.

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