JP5380685B2 - Multi-frequency receiving system - Google Patents

Description

  The present invention relates to a multi-frequency receiving system that receives signals of a plurality of frequencies, and more particularly to a portable communication device that receives a plurality of communication waves and broadcast waves.

  Currently, mobile phones are wireless transceivers that use signals in the communication band, as well as one-seg digital broadcast receivers, GPS receivers that receive radio waves from GPS satellites, and Bluetooth transceivers that communicate with other devices. And a plurality of wireless devices (receivers). For this reason, many antennas such as built-in antennas for mobile phones, that is, built-in antennas for mobile phones, whip antennas for one-segment broadcasting, built-in antennas for GPS reception, built-in antennas for Bluetooth, etc. are already mounted on cellular phones.

  Currently, a mobile multimedia broadcasting service for mobiles using the VHF band frequency (207.5 to 222 MHz) is scheduled to start. However, since a plurality of antennas are already mounted on the mobile phone, there is no room for mounting an antenna for receiving mobile multimedia broadcasts. For this reason, in order to mount a reception antenna for mobile multimedia broadcasting, it is necessary to enlarge the mobile phone or delete other functions.

  In addition, when a plurality of antennas are arranged close to each other, interference occurs between the antennas, and the characteristics of the antenna may be deteriorated.

  An object of the present invention is to provide a mobile communication device having a function of newly receiving a mobile multimedia broadcast without changing the size of the mobile phone and without deleting various functions.

The first invention corrects the electrical length of a rod-shaped antenna having a length of 150 mm or less and a diameter of 10 mm or less, a low-pass filter that passes a VHF band signal, a high-pass filter that passes a UHF band signal, and the rod-shaped antenna. An electrical length correction circuit; a first matching circuit for matching impedance between the rod-shaped antenna and the VHF receiving circuit; and a second matching circuit for matching impedance between the rod-shaped antenna and the UHF receiving circuit. The low-pass filter and the high-pass filter are connected in parallel to the feed point of the rod-shaped antenna, the electrical length correction circuit is connected to the rear stage of the low-pass filter, and the first stage is connected to the rear stage of the electrical length correction circuit. A matching circuit is connected, and the second matching circuit is connected after the high-pass filter.

A second invention includes a rod-shaped antenna having a length of 150 mm or less and a diameter of 10 mm or less, a matching circuit that matches impedances of the rod-shaped antenna and a receiver in a plurality of frequency bands, and a low-pass filter that passes a VHF band signal. , A high-pass filter that allows UHF band signals to pass through, and an electrical length correction circuit that corrects the electrical length of the rod-shaped antenna. The matching circuit is connected to a feeding point of the rod-shaped antenna, and a subsequent stage of the matching circuit Further, the electrical length correction circuit is connected, the low-pass filter is connected to the subsequent stage of the electrical length correction circuit, and the high-pass filter is connected to the subsequent stage of the matching circuit.

According to a third aspect of the present invention, a rod-shaped antenna having a coil that acts as a choke coil in the UHF band in the middle of a rod-shaped conductor having a length of 150 mm or less and a diameter of 10 mm or less, a low-pass filter that passes a VHF band signal, A high-pass filter that allows a signal to pass through, an electrical length correction circuit that corrects the electrical length of the rod-shaped antenna, a first matching circuit that matches impedance between the rod-shaped antenna and the VHF reception circuit, and the rod-shaped antenna and UHF reception A second matching circuit that matches impedance with the circuit, and the low-pass filter and the high-pass filter are connected in parallel to a feeding point of the rod-shaped antenna, and the electrical length correction is performed after the low-pass filter. connect the circuit, downstream of the electrical length compensation circuit, connected to the first matching circuit, said highpass The subsequent data, is characterized in that connected to the second matching circuit.

According to a fourth aspect of the present invention, there is provided a rod-shaped antenna including a coil that acts as a choke coil in the UHF band in the middle of a rod-shaped conductor having a length of 150 mm or less and a diameter of 10 mm or less; A matching circuit, a low-pass filter that passes a signal in the VHF band, a high-pass filter that passes a signal in the UHF band, and an electrical length correction circuit that corrects the electrical length of the rod-shaped antenna. The matching circuit is connected to the feeding point, the electrical length correction circuit is connected to the subsequent stage of the matching circuit, the low pass filter is connected to the subsequent stage of the electrical length correction circuit, and The high-pass filter is connected to the subsequent stage.

According to a fifth aspect of the present invention, there is provided a helical antenna having a conductor spirally formed with a length of 150 mm or less and a diameter of 20 mm or less, a low-pass filter that passes a VHF band signal, and a high-pass filter that passes a UHF band signal. An electrical length correction circuit for correcting the electrical length of the helical antenna, a first matching circuit for matching impedance between the helical antenna and the VHF receiving circuit, and an impedance between the helical antenna and the UHF receiving circuit. A second matching circuit for matching, the low-pass filter and the high-pass filter are connected in parallel to a feeding point of the helical antenna, and the electrical length correction circuit is connected to the subsequent stage of the low-pass filter, downstream of the long correction circuit, connected to the first matching circuit, downstream of the high-pass filter, before Characterized in that connecting the second matching circuit.

A sixth invention includes a helical antenna in which a conductor is spirally formed with a length of 150 mm or less and a diameter of 20 mm or less, a matching circuit that matches impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands, A low-pass filter that passes a signal in the VHF band, a high-pass filter that passes a signal in the UHF band, and an electrical length correction circuit that corrects the electrical length of the helical antenna, and the matching point at the feeding point of the helical antenna A circuit is connected, the electrical length correction circuit is connected downstream of the matching circuit, the low pass filter is connected downstream of the electrical length correction circuit, and the electrical length correction circuit and The low-pass filter is connected in series in order, and the high-pass filter is connected downstream of the matching circuit.

According to a seventh aspect of the present invention, there is provided a balanced antenna formed of a conductor incorporated in a housing, a low-pass filter that passes a VHF band signal, a high-pass filter that passes a UHF band signal, and the balanced antenna. An electrical length correction circuit for correcting electrical length; a first matching circuit for matching impedance between the balanced antenna and the VHF receiving circuit; and a first matching circuit for matching impedance between the balanced antenna and the UHF receiving circuit. Two matching circuits, wherein the low-pass filter and the high-pass filter are connected in parallel to the feeding point of the balanced antenna, and the electrical length correction circuit is connected to the subsequent stage of the low-pass filter, and the electrical length correction the subsequent circuit, connects the first matching circuit, downstream of the high-pass filter, to characterized in that connected to the second matching circuit .

According to an eighth aspect of the present invention, there is provided a balanced antenna formed of a conductor incorporated in a housing, a matching circuit for matching impedances of the rod antenna and the receiver in a plurality of frequency bands, and a signal in the VHF band. And a high-pass filter that allows UHF band signals to pass through, and an electrical length correction circuit that corrects the electrical length of the balanced antenna. The matching circuit is connected to a feeding point of the balanced antenna. The electrical length correction circuit is connected to the subsequent stage of the matching circuit, the low-pass filter is connected to the subsequent stage of the electrical length correction circuit, and the high-pass filter is connected to the subsequent stage of the matching circuit. Features.

A ninth invention corrects the electrical length of a built-in antenna having a pattern formed on a dielectric substrate, a low-pass filter that passes a VHF band signal, a high-pass filter that passes a UHF band signal, and the built-in antenna. An electrical length correction circuit, a first matching circuit for matching impedance between the built-in antenna and the VHF receiving circuit, and a second matching circuit for matching impedance between the built-in antenna and the UHF receiving circuit. The low-pass filter and the high-pass filter are connected in parallel to the feeding point of the built-in antenna, the electrical length correction circuit is connected to the rear stage of the low-pass filter, and the second stage is connected to the second stage of the electrical length correction circuit. connect the first matching circuit, downstream of the low-pass filter, in turn connected in series with the electrical length compensation circuit and the first matching circuit Downstream of the high-pass filter, characterized in that connected to the second matching circuit.

According to a tenth aspect of the present invention, there is provided a built-in antenna having a pattern formed on a dielectric substrate, a matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands, and a low-pass filter for passing a VHF band signal. A high-pass filter that allows UHF band signals to pass through, and an electrical length correction circuit that corrects the electrical length of the built-in antenna, and the matching circuit is connected to a feeding point of the built-in antenna, The electrical length correction circuit is connected to the subsequent stage, the low pass filter is connected to the subsequent stage of the electrical length correction circuit, and the high pass filter is connected to the subsequent stage of the matching circuit.

  According to the present invention, by providing a matching circuit and an electrical length correction circuit in the antenna, it is possible to perform one-seg digital broadcasting and mobile multimedia broadcasting using an antenna (for example, one-seg antenna) already installed in a portable radio device. A portable communication device capable of receiving can be provided.

It is an external view which shows an example of the antenna for portable communication apparatuses of embodiment of this invention. It is an external view which shows an example of the antenna for portable communication apparatuses of embodiment of this invention. It is an external view which shows an example of the antenna for portable communication apparatuses of embodiment of this invention. It is an external view which shows an example of the antenna for portable communication apparatuses of embodiment of this invention. It is an external view which shows an example of the antenna for portable communication apparatuses of embodiment of this invention. It is a block diagram which shows the structure of the front end part of the high frequency circuit of the portable communication apparatus of embodiment of this invention. It is a block diagram which shows the structure of another front end part of the high frequency circuit of the portable communication apparatus of embodiment of this invention. It is a circuit diagram which shows the specific structure of another front end part of the high frequency circuit of the portable communication apparatus of embodiment of this invention. It is a figure which shows the characteristic of the front end part shown in FIG. It is a block diagram which shows the structure of another front end part of the high frequency circuit of the portable communication apparatus of embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 to 5 are external views showing an example of an antenna for a portable communication device according to an embodiment of the present invention.

  As shown in FIG. 1, a bar-shaped antenna 21 having a frequency band used for communication is provided on the upper part of the main body of the portable communication device 1. The rod-shaped antenna 21 is designed to resonate at one frequency by itself.

  Moreover, as shown in FIG. 2, the antenna 22 provided in the upper part of the main body of the portable communication device 1 may be provided with a coil in the middle of the element. This coil functions as a choke coil, and by raising the impedance at a specific frequency, the elements below the choke coil function at the specific frequency (for example, UHF band), and other frequencies than the specific frequency ( For example, the choke coil and the upper and lower elements function in the VHF band. For this reason, the antenna 22 itself is designed to resonate at a plurality of frequencies.

  Moreover, as shown in FIG. 3, the antenna 23 provided in the upper part of the main body of the portable communication device 1 may be a helical antenna whose entire length is constituted by a coil. The helical antenna 23 is designed to resonate at one frequency by changing the winding method (pitch, diameter) of the coil on the way.

  Moreover, as shown in FIG. 4, the antenna 24 provided in the main body of the portable communication device 1 may be a built-in antenna mounted inside the housing. The built-in antenna 24 is an antenna having a conductor pattern formed on a dielectric substrate (or an inner layer sandwiched between dielectric substrates), and can be designed to resonate at a plurality of frequencies. .

  As shown in FIG. 5, when the portable communication device 1 is a portable communication device (for example, a foldable mobile phone) in which two housings are coupled by a hinge, a conductor (conductor) incorporated in the upper housing. It may be a balanced antenna formed by an antenna 25A made up of an antenna 25A made up of a pattern, a metal plate or the like) and an antenna 25B made up of a conductor (conductor pattern, metal plate made up of the lower casing). Such a balanced antenna can be designed to resonate at a plurality of frequencies by changing the combination of a plurality of elements.

  FIG. 6 is a block diagram showing the configuration of the front end portion of the high-frequency circuit of the portable communication device according to the embodiment of the present invention.

  The antenna 2 connected to the front end portion shown in FIGS. 6 to 10 includes a rod-shaped antenna 21 shown in FIG. 1, an antenna 22 with a choke coil shown in FIG. 2, a helical antenna 23 shown in FIG. Either the built-in antenna 24 or the storage balanced antennas 25A and 25B shown in FIG. 5 may be used.

  In FIG. 6, the high frequency signal output from the antenna 2 is input to the low pass filter 5 and the high pass filter 6. Instead of the low-pass filter 5 and the high-pass filter 6, a band-pass filter that passes a signal in a desired frequency band may be used. Further, the high-frequency signal output from the antenna 2 may be branched into the low-pass filter 5 and the high-pass filter 6 by a distributor.

  As for the signal input to the low-pass filter 5, a signal (UHF band broadcast wave) that becomes an interference wave when receiving a VHF band broadcast is suppressed and input to the electrical length correction circuit 4. The electrical length correction circuit 4 is a circuit for increasing the electrical length of the antenna as viewed from the VHF receiver side, and is, for example, an inductor (or a lumped constant circuit composed of an inductor and a capacitor). The signal output from the electrical length correction circuit 4 is input to the matching circuit 3A. The matching circuit 3A matches the impedance in the VHF band of the front end portion with the impedance on the VHF receiver side, and may be provided as necessary. Thereafter, the output of the matching circuit 3A is input to a mobile multimedia broadcast (VHF band) receiver.

  On the other hand, the signal input to the high-pass filter 6 is suppressed from a signal (VHF band broadcast wave) that becomes an interference wave when receiving a UHF band broadcast, and is input to the matching circuit 3B. The matching circuit 3B matches the impedance in the UHF band of the front end portion with the impedance on the UHF receiver side, and may be provided as necessary. Thereafter, the output of the matching circuit 3B is input to a one-segment digital broadcast (UHF band) receiver.

  Since all of the low-pass filter 5, the high-pass filter 6, the electrical length correction circuit 4, and the matching circuits 3A and 3B are LC circuits, they may be configured by one LC circuit obtained by synthesizing two or three circuits. By integrating a plurality of circuits, the number of parts can be reduced and circuit loss can be reduced.

  Since the front end portion of the high-frequency circuit shown in FIG. 6 is provided with filters 5 and 6 for separating a VHF band signal (mobile multimedia broadcast wave) and a UHF band signal (one-segment digital broadcast wave), the interference wave Thus, the S / N ratio in each frequency band can be improved. In addition, since the matching circuits 3A and 3B are provided for each frequency band, the receiver and the antenna can be matched under conditions suitable for each frequency band. Furthermore, since the electrical length correction circuit 4 for the VHF band is provided, the electrical length can be compensated even if the physical length of the antenna is short with respect to the wavelength of the reception frequency. In other words, since the antenna resonates in the UHF band and the VHF band antenna is not provided, the VHF band signal is received by the UHF band antenna, or the VHF band antenna length is set to the wavelength of the reception frequency. On the other hand, even if it is short, the antenna can be matched to the VHF band frequency.

  FIG. 7 is a block diagram showing a configuration of another front end unit of the high-frequency circuit of the portable communication device according to the embodiment of the present invention.

  The high frequency signal output from the antenna 2 is input to the dual frequency matching circuit 7. The two-frequency matching circuit 7 includes a VHF output terminal and a UHF output terminal, and matches the impedance in the VHF band of the front end portion with the impedance on the VHF receiver side. Further, the impedance in the UHF band of the front end portion , The impedance on the UHF receiver side is matched.

  The high frequency signal output from the VHF output terminal of the dual frequency matching circuit 7 is input to the electrical length correction circuit 4. The electrical length correction circuit 4 is a circuit for increasing the electrical length of the antenna as viewed from the VHF receiver side, and is, for example, an inductor (or a lumped constant circuit composed of an inductor and a capacitor). The signal output from the electrical length correction circuit 4 is input to the low-pass filter 5 to suppress a signal (UHF band broadcast wave) that becomes an interference wave when receiving a VHF band broadcast. Thereafter, the output of the low-pass filter 5 is input to a mobile multimedia broadcast (VHF band) receiver.

  On the other hand, the high-frequency signal output from the UHF output terminal of the two-frequency matching circuit 7 is input to the high-pass filter 6 and a signal (VHF band broadcast wave) that becomes an interference wave when receiving UHF band broadcast is suppressed. The Thereafter, the output of the high-pass filter 6 is input to a one-segment digital broadcast (UHF band) receiver.

  Instead of the low-pass filter 5 and the high-pass filter 6, a band-pass filter that passes a signal in a desired frequency band may be used.

  Since all of the low-pass filter 5, the high-pass filter 6, the electrical length correction circuit 4, and the matching circuits 3A and 3B are LC circuits, they may be configured by one LC circuit obtained by synthesizing two or three circuits. By integrating a plurality of circuits, the number of parts can be reduced and circuit loss can be reduced.

  Since the matching circuit 7 for matching the VHF band (mobile multimedia broadcasting frequency band) and the UHF band (one-segment digital broadcasting frequency band) is provided in the front end portion of the high frequency circuit shown in FIG. 7, it is suitable for each frequency band. The receiver and the antenna can be matched under certain conditions. In addition, since the filters 5 and 6 for suppressing unnecessary waves by the VHF band signal and the UHF band signal are provided, the S / N ratio in each frequency band can be improved while reducing the influence of the interference wave. . Furthermore, since the electrical length correction circuit 4 for the VHF band is provided, the electrical length can be compensated even if the physical length of the antenna is short with respect to the wavelength of the reception frequency. In other words, since the antenna resonates in the UHF band and the VHF band antenna is not provided, the VHF band signal is received by the UHF band antenna, or the VHF band antenna length is set to the wavelength of the reception frequency. On the other hand, even if it is short, the antenna can be matched to the VHF band frequency.

  FIG. 8 is a circuit diagram showing a specific configuration of another front end portion of the high-frequency circuit of the portable communication device according to the embodiment of the present invention.

  The high frequency signal output from the antenna 2 is input to the matching circuit 8. The matching circuit 8 is an LC circuit, and matches the impedance of the front end unit with the impedance of the receiver side.

  The high-frequency signal output from the matching circuit 8 is input to the low-pass filter 5, and a signal (UHF band broadcast wave) that becomes an interference wave when receiving a VHF band broadcast is suppressed. The low-pass filter 5 is configured by an LC circuit (lumped constant circuit). Thereafter, the output of the low-pass filter 5 is input to a mobile multimedia broadcast (VHF) receiver.

  The front end portion shown in FIG. 8 is not provided with an independent electrical length correction circuit, unlike the front end portion shown in FIG. However, in the front end portion shown in FIG. 8, the first-stage inductor (42 nH) of the matching circuit functions to extend the electrical length of the antenna 2.

  On the other hand, the high-frequency signal output from the matching circuit 8 is input to the high-pass filter 6, and a signal (VHF band broadcast wave) that becomes an interference wave when receiving a UHF band broadcast is suppressed. The high pass filter 6 is configured by an LC circuit (lumped constant circuit). Thereafter, the output of the high-pass filter 6 is input to a one-segment digital broadcast (UHF) receiver.

  FIG. 9 shows a simulation result of the characteristics of the front end portion (FIG. 8) according to the embodiment of the present invention. The antenna 2 was calculated as a 150 mm rod antenna. As can be seen from FIG. 9, a good return loss can be obtained in the mobile multimedia broadcast band (207.5 to 222 MHz) of the VHF band, and a good return loss can also be obtained in the one-segment digital broadcast band (470 to 770 MHz). Thus, according to the embodiment of the present invention, it is possible to resonate in a plurality of frequency bands and obtain good antenna characteristics without increasing the number of antennas.

  FIG. 10 is a block diagram showing a configuration of another front end unit of the high-frequency circuit of the portable communication device according to the embodiment of the present invention.

  The high frequency signal output from the antenna 2 is input to the VHF circuit 9 and the UHF circuit 10.

  The VHF circuit 9 is a circuit having the functions of a low-pass filter, an electrical length correction circuit, and a matching circuit. In the VHF circuit 9, the low-pass filter, the electrical length correction circuit, and the matching circuit are arranged in the order of the low-pass filter, the electrical length correction circuit, and the matching circuit as shown in FIG. Even in the order of the matching circuit, the electrical length correction circuit, and the low-pass filter, the order of the electrical length correction circuit, the matching circuit, and the low-pass filter may be as shown in FIG.

  Further, the UHF circuit 10 is a circuit having both functions of a high-pass filter and a matching circuit. The arrangement order of the high-pass filter and the matching circuit in the UHF circuit 10 may be the order of the low-pass filter and the matching circuit as shown in FIG. 6, or the order of the matching circuit and the low-pass filter as shown in FIG.

  The front end portion of the high-frequency circuit shown in FIG. 10 has a low-pass filter, an electrical length correction circuit, and a matching circuit (or low-pass filter and matching circuit) in addition to the effects of the front-end portion described above with reference to FIGS. Since the circuit unit is configured, the configuration of the portable communication device can be simplified by reducing the number of parts. In addition, circuit loss can be reduced.

  As described above, the antenna of the portable communication device typified by the cellular phone has been described. However, the portable receiver having no communication function (for example, a television receiver capable of receiving one-segment digital TV broadcasting and mobile multimedia broadcasting). Can also be applied.

DESCRIPTION OF SYMBOLS 1 Mobile communication device 2 Antenna 21 Rod-shaped antenna 22 Antenna 23 Helical antenna 24 Built-in antenna 3A, 3B Matching circuit 4 Electrical length correction circuit 5 Low-pass filter 6 High-pass filter 7 Two-frequency matching circuit 8 Matching circuit 9 VHF circuit 10 UHF circuit

Claims (10)

A rod-shaped antenna having a length of 150 mm or less and a diameter of 10 mm or less;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the rod-shaped antenna;
A first matching circuit for matching impedance between the rod-shaped antenna and the VHF receiving circuit;
A second matching circuit for matching impedance between the rod-shaped antenna and the UHF receiving circuit,
Connect the low-pass filter and the high-pass filter in parallel to the feed point of the rod-shaped antenna,
The electrical length correction circuit is connected to the subsequent stage of the low-pass filter ,
The first matching circuit is connected to the subsequent stage of the electrical length correction circuit ,
The multi-frequency receiving system, wherein the second matching circuit is connected after the high-pass filter. A rod-shaped antenna having a length of 150 mm or less and a diameter of 10 mm or less;
A matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the rod-shaped antenna,
The matching circuit is connected to the feeding point of the rod antenna,
The electrical length correction circuit is connected to the subsequent stage of the matching circuit ,
The low pass filter is connected to the subsequent stage of the electrical length correction circuit ,
Furthermore, the high frequency filter is connected to the subsequent stage of the matching circuit. A rod-shaped antenna provided with a coil acting as a choke coil in the UHF band in the middle of a rod-shaped conductor having a length of 150 mm or less and a diameter of 10 mm or less;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the rod-shaped antenna;
A first matching circuit for matching impedance between the rod-shaped antenna and the VHF receiving circuit;
A second matching circuit for matching impedance between the rod-shaped antenna and the UHF receiving circuit,
Connect the low-pass filter and the high-pass filter in parallel to the feed point of the rod-shaped antenna,
The electrical length correction circuit is connected to the subsequent stage of the low-pass filter ,
The first matching circuit is connected to the subsequent stage of the electrical length correction circuit ,
The multi-frequency receiving system, wherein the second matching circuit is connected after the high-pass filter. A rod-shaped antenna provided with a coil acting as a choke coil in the UHF band in the middle of a rod-shaped conductor having a length of 150 mm or less and a diameter of 10 mm or less;
A matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the rod-shaped antenna,
The matching circuit is connected to the feeding point of the rod antenna,
The electrical length correction circuit is connected to the subsequent stage of the matching circuit ,
The low pass filter is connected to the subsequent stage of the electrical length correction circuit ,
Furthermore, the high frequency filter is connected to the subsequent stage of the matching circuit. A helical antenna in which a conductor is formed in a spiral shape with a length of 150 mm or less and a diameter of 20 mm or less;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the helical antenna;
A first matching circuit for matching impedance between the helical antenna and the VHF receiving circuit;
A second matching circuit for matching impedance between the helical antenna and the UHF receiving circuit,
The feed point of the helical antenna is connected in parallel with the low pass filter and the high pass filter,
The electrical length correction circuit is connected to the subsequent stage of the low-pass filter ,
The first matching circuit is connected to the subsequent stage of the electrical length correction circuit ,
The multi-frequency receiving system, wherein the second matching circuit is connected after the high-pass filter. A helical antenna in which a conductor is formed in a spiral shape with a length of 150 mm or less and a diameter of 20 mm or less;
A matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the helical antenna,
The matching circuit is connected to the feeding point of the helical antenna,
The electrical length correction circuit is connected to the subsequent stage of the matching circuit ,
The low pass filter is connected to the subsequent stage of the electrical length correction circuit ,
Furthermore, the high frequency filter is connected to the subsequent stage of the matching circuit. A balanced antenna formed by a conductor incorporated in the housing;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the balanced antenna;
A first matching circuit for matching impedance between the balanced antenna and the VHF receiving circuit;
A second matching circuit for matching impedance between the balanced antenna and the UHF receiving circuit,
The low-pass filter and the high-pass filter are connected in parallel to the feeding point of the balanced antenna,
The electrical length correction circuit is connected to the subsequent stage of the low-pass filter ,
The first matching circuit is connected to the subsequent stage of the electrical length correction circuit ,
The multi-frequency receiving system, wherein the second matching circuit is connected after the high-pass filter. A balanced antenna formed by a conductor incorporated in the housing;
A matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the balanced antenna,
Connecting the matching circuit to a feeding point of the balanced antenna;
The electrical length correction circuit is connected to the subsequent stage of the matching circuit ,
The low pass filter is connected to the subsequent stage of the electrical length correction circuit ,
Furthermore, the high frequency filter is connected to the subsequent stage of the matching circuit. A built-in antenna having a pattern formed on a dielectric substrate;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the built-in antenna;
A first matching circuit for matching impedance between the built-in antenna and the VHF receiving circuit;
A second matching circuit for matching impedance between the built-in antenna and the UHF receiving circuit,
The low-pass filter and the high-pass filter are connected in parallel to the feeding point of the built-in antenna,
The electrical length correction circuit is connected to the subsequent stage of the low-pass filter ,
The first matching circuit is connected to the subsequent stage of the electrical length correction circuit ,
The multi-frequency receiving system, wherein the second matching circuit is connected after the high-pass filter. A built-in antenna having a pattern formed on a dielectric substrate;
A matching circuit for matching impedances of the rod-shaped antenna and the receiver in a plurality of frequency bands;
A low-pass filter that passes a signal in the VHF band;
A high-pass filter that passes UHF band signals;
An electrical length correction circuit for correcting the electrical length of the built-in antenna,
Connect the matching circuit to the feeding point of the built-in antenna,
The electrical length correction circuit is connected to the subsequent stage of the matching circuit ,
The low pass filter is connected to the subsequent stage of the electrical length correction circuit ,
Furthermore, the high frequency filter is connected to the subsequent stage of the matching circuit.

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