JP2006128891A - Wireless broadcast receiving system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide "a wireless broadcast receiving system" by which the wiring length of the antenna element of a glass antenna can be reduced. <P>SOLUTION: The first end of a first antenna element 1 is connected to an antenna booster amplifier 4. The output of the antenna booster amplifier 4 is input to an FM receiver 5. The second end of the first antenna element 1 and the first end of a second antenna element 2 are connected to a switch 3. The antenna having a first directional pattern can be achieved by the connection of the first antenna element 1 with the second antenna element by turning on the switch 3. The antenna having a second directional pattern can be achieved by the separation of the second antenna element 2 from the first antenna element 1 by turning off the switch 3. An antenna system control unit 37 inverts a state of the switch 3 when the occurrence of the multipath is notified from the FM receiver 5. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technology for effectively utilizing an antenna element provided on a window glass of an automobile in a radio broadcast receiving apparatus mounted on the automobile.

  There are various types of radio broadcast receivers mounted on automobiles, such as FM broadcast receivers, AM broadcast receivers, television broadcast receivers, and VICS broadcast receivers. Conventionally, a dedicated antenna is generally prepared for each of these wireless communication devices having different frequency bands. On the other hand, in order to suppress communication failures such as multipath, diversity using a plurality of antennas in one wireless communication device is also widely used (for example, Patent Document 1).

  Also, in automobiles, for reasons of securing the antenna length and for decorative reasons, a glass antenna or antenna in which antenna wiring that functions as an antenna is wired in or on the window glass (front window, rear window, etc.) of the automobile In many cases, a film-type glass antenna for attaching a wiring for use on a window glass is used (for example, Patent Document 2).

On the other hand, as a technique for changing the characteristics of an antenna, a plurality of antenna elements are sequentially connected with a switch interposed therebetween, and the effective length of the antenna is changed by turning on / off the switch, so that the same antenna element is changed to a different frequency band. A technique shared for the communication of the network is known (for example, Patent Document 3).
Japanese Unexamined Patent Publication No. 07-283767 JP 2004-253986 JP JP 2001-14809

As described above, there are various types of wireless broadcast receivers installed in automobiles. In addition, with the progress of computerization in the future, the number of wireless communication devices mounted on automobiles is expected to increase further.
On the other hand, since the area of the window glass of an automobile is limited and it is not possible to place the antenna wiring on the window glass without limitation, it is important to use the antenna wiring on the window glass as effectively as possible. Become.
Accordingly, an object of the present invention is to realize a plurality of antennas necessary for diversity and communication in different frequency bands with fewer antenna wirings.

  In order to achieve the above object, the present invention provides a radio broadcast receiving system that is mounted on an automobile and receives diversity of radio broadcasts, and includes a plurality of antenna elements wired on a window glass of the automobile, and the plurality of antenna elements. An antenna system configured with one or a plurality of interposed switches, and forming an antenna configured by different combinations of the plurality of antenna elements according to an on / off state of each switch; and a radio using the antenna A radio broadcast receiver that receives broadcasts, a multipath detection unit that detects occurrence of a multipath failure based on a reception signal of the radio broadcast receiver, and a response to the detection of the occurrence of a multipath failure by the multipath detection unit Antenna control means for switching the on / off state of each switch. It is intended.

  More specifically, such a radio broadcast receiving system includes, for example, the antenna system, one switch, a first end connected to a feeding point for the radio broadcast receiver, and a second end. A first antenna element connected to the switch and a second antenna element having a first end connected to the switch, and a first antenna element only by the first antenna element when the switch is off. An antenna having directivity is formed, and an antenna having a second directivity different from the first directivity is formed by combining the first antenna element and the second antenna element when the switch is on. According to the detection of the occurrence of a multipath failure in the multipath detection means in the antenna control means And to switch the ON / OFF state of the switch.

  According to the configuration of these radio broadcast receiving systems, the same antenna element can be shared in order to form a plurality of antennas having different characteristics required for diversity reception. Therefore, the antenna element can be used effectively, and the wiring length on the glass antenna can be shortened as compared with the case where a plurality of antennas are provided without sharing the antenna element.

  In order to achieve the above object, the present invention provides a radio broadcast receiving system that is mounted on an automobile and receives radio broadcasts, including three or more antenna elements wired on a window glass of the automobile, and the plurality of antenna elements. An antenna system configured with a plurality of switches interposed therebetween, and forming an antenna configured by different combinations of the plurality of antenna elements according to a combination of on / off states of the switches, and using the antenna A first radio broadcast receiver for receiving a radio broadcast in the first frequency band, a second radio broadcast receiver for receiving a radio broadcast in the second frequency band using the antenna, and the first radio broadcast reception A radio broadcast receiver selecting means for selecting one of the radio broadcast receiver and the second radio broadcast receiver as the active radio broadcast receiver; A multipath detecting means for detecting the occurrence of a multipath failure based on a received signal of one radio broadcast receiver; and the radio broadcast receiver selecting means is connected between the first radio broadcast receiver and the second radio broadcast receiver. Which one of them is selected as a working wireless broadcast receiver, and when the wireless broadcast receiver selecting means selects the first wireless broadcast receiver as a working wireless broadcast receiver, Antenna control means for switching the combination of the on / off states of the switches in response to detection of the occurrence of a multipath failure by the path detection means.

  According to the configuration of these radio broadcast receiving systems, the same antenna element is shared in order to form an antenna for receiving radio broadcasts in different frequency bands and a plurality of antennas having different characteristics necessary for diversity reception. Will be able to. Therefore, the antenna element can be used effectively, and an independent antenna is provided for each frequency band without sharing the antenna element, and a glass antenna is provided as compared with a case where a plurality of antennas are provided for diversity reception of one frequency band. The upper wiring length can be shortened.

  As described above, according to the present invention, diversity and a plurality of antennas necessary for communication in different frequency bands can be realized with fewer antenna wires.

Hereinafter, embodiments of the present invention will be described.
First, the first embodiment will be described.
FIG. 1a shows the configuration of the wireless broadcast receiving system according to the first embodiment.
As shown in the figure, the wireless broadcast receiving system includes a first antenna element 1, a second antenna element 2, a switch 3, an antenna booster amplifier 4, an FM receiver 5, and an antenna control unit 6.
Here, the 1st antenna element 1 and the 2nd antenna element 2 are wired on the rear glass of a motor vehicle, as shown in FIG. 1b.
The first end of the first antenna element 1 is connected to the antenna booster amplifier 4, and the output of the antenna booster amplifier 4 is input to the FM receiver 5. The second end of the first antenna element 1 and the first end of the second antenna element 2 are connected to the switch 3, and the first antenna element 1 and the second element are connected by turning on the switch 3. Then, the second antenna element 2 is separated from the first antenna element 1 by turning off the switch 3.

  Here, the directivity characteristics of the antenna as viewed at the feeding point 7 on the input side of the antenna booster amplifier 4 are the state in which the switch 3 is turned off and the second antenna element 2 is separated from the first antenna element 1, and the switch 3 is turned on. The two antenna elements 2 are set to have different directivity characteristics in a state where they are connected to the first antenna element 1. For example, in a state where the switch 3 is turned off and the second antenna element 2 is separated from the first antenna element 1, the directivity characteristics shown in FIG. 1c are obtained, and the switch 3 is turned on and the second antenna element 2 is connected to the first antenna element 1. In the state, it is set so as to have the directivity shown in FIG.

  Next, the FM receiver 5 includes a front-end unit 51 that performs amplification of the signal supplied from the antenna booster amplifier 4 and conversion to an intermediate frequency signal, an IF amplifier 52 that performs amplification of the intermediate frequency signal, and an intermediate frequency signal. FM detector 53 for performing FM detection from, FM demodulator 54 for demodulating and outputting stereo sound from the FM detected signal, S meter 55 for detecting the electric field strength of the intermediate frequency signal and outputting electric field strength signal SM, And a multipath detection unit 56 that detects the occurrence of multipath based on the fluctuation of the electric field strength SM and outputs a multipath detection signal MP. In such a configuration, the IF amplifier 52 performs a process of narrowing the band of the intermediate frequency to be output at the time of multipath detection based on the multipath detection signal MP. Further, the FM demodulator 54 changes a stereo separation characteristic, a high cut characteristic, and the like based on the multipath detection signal MP. More specifically, the FM demodulator 54 increases the attenuation amount of the high frequency component of the audio and reduces the degree of separation between the L channel audio and the R channel audio, for example, at the time of multipath detection.

The electric field strength signal SM and the multipath detection signal MP generated by the FM receiver 5 are also output to the antenna control unit 6.
The antenna control unit 6 performs antenna characteristic switching processing shown in FIG. 2 using these input signals.
As shown in the figure, in this antenna characteristic switching process, it is checked whether or not the electric field strength signal SM is larger than a predetermined threshold Th (step 202). If the electric field strength signal SM is not larger than the threshold Th, the electric field strength signal is shown. Wait for SM to become greater than threshold Th. If the electric field strength signal SM is larger than the threshold Th, it is further checked whether multipath has occurred from the multipath detection signal MP (step 204). If multipath has occurred, the switch 3 is turned on. Invert the OFF state (step 206). That is, at that time, if the switch 3 is on, the switch 3 is turned off, and if the switch 3 is off, the switch 3 is turned on. If no multipath has occurred, the process returns to step 202.

  By the above processing, when multipath occurs when the electric field strength signal SM is larger than the threshold value Th, the connection state between the first antenna element 1 and the second antenna element 2 is reversed, and the antenna directivity characteristics Will be switched. Therefore, diversity equivalent to the case where two antennas having different directivity characteristics are used is realized while sharing the first antenna element 1 for realizing antennas having different directivity characteristics.

Note that when the electric field strength signal SM is not larger than the threshold value Th, the state of the switch 3 is not reversed because the switching noise that occurs remarkably when the antenna directivity is switched when the electric field strength is weak. It is for preventing.
The first embodiment of the present invention has been described above.
In the above description, the application to the FM receiver 5 that performs diversity has been described as an example. However, the first embodiment can be similarly applied to receivers that perform other diversity. In the above description, the case where two antenna elements connected by a switch are used as diversity antennas having two different characteristics by controlling on / off of the switch 3 has been described. Three or more antenna elements that are sequentially connected may be provided, and these antenna elements may be used as diversity antennas having three or more different characteristics by controlling on / off of each switch.

Hereinafter, a second embodiment of the present invention will be described.
FIG. 3a shows the configuration of the wireless broadcast receiving system according to the first embodiment.
As shown in the figure, the radio broadcast receiving system includes a first antenna element 1, a second antenna element 2, a third antenna element 31, a first switch 32, a second switch 33, an FM band antenna booster amplifier 34, and an AM band antenna. A booster amplifier 35, FM receiver 5, AM receiver 36, antenna system control unit 37, and control unit 38 are included.

Here, the 1st antenna element 1, the 2nd antenna element 2, and the 3rd antenna element 31 are wired on the rear glass of a motor vehicle, as shown in Drawing 3b.
The first end of the first antenna element 1 is connected to both the FM band antenna booster amplifier 34 and the AM band antenna booster amplifier 35, and the output of the FM band antenna booster amplifier 34 is the FM receiver 5. In addition, the output of the AM band antenna booster amplifier 35 is input to the AM receiver 36. Note that the output of the FM band antenna booster amplifier 34 and the AM band antenna booster amplifier 35 can be disabled by the control from the antenna system control unit 37 to obtain a high impedance output. Also, the frequency characteristics of the FM band antenna booster amplifier 34 and the AM band antenna booster amplifier 35 are different. The FM band antenna booster amplifier 34 has a frequency characteristic suitable for the FM band. It has frequency characteristics suitable for AM band.

  The second end of the first antenna element 1 and the first end of the second antenna element 2 are connected to the first switch 32, and the first antenna element 1 and the second end are turned on when the first switch 32 is turned on. The second antenna element 2 is separated from the first antenna element 1 by connecting the two elements and turning off the first switch 32. The second end of the second antenna element 2 and the first end of the third element are connected to the second switch 33, and the second antenna element 2 and the third element are connected when the second switch 33 is turned on. Then, the third antenna element 31 is separated from the second antenna element 2 by turning off the second switch 33.

  Here, as in the first embodiment, the directivity characteristics of the antenna viewed at the feeding point 38 on the input side of the FM band antenna booster amplifier 34 and the AM band antenna booster amplifier 35 are the same as those in the first embodiment. The second antenna element 2 is separated from the first antenna element 1, the first switch 32 is turned on, the second switch 33 is turned off, the second antenna element 2 is connected to the first antenna element 1, and the third antenna element 31 is connected. Different directivity characteristics are set when separated from the second antenna element 2. Further, the frequency characteristics of the antenna are set so as to conform to the FM band both when the first switch 32 is turned off and when the first switch 32 is turned on and the second switch 33 is turned off.

  On the other hand, when both the first switch 32 and the second switch 33 are turned on and the first antenna element 1, the second antenna element 2, and the third antenna element 31 are sequentially connected, the frequency of the antenna as viewed at the feeding point 38. The characteristics are set to match the AM band. That is, when the eleventh antenna element 1, the second antenna element 2, and the third antenna element 31 are connected, the length of the third antenna element 31 is set so that the effective antenna length matches the AM band. .

  Next, the FM receiver 5 is the same as that described in the first embodiment, and demodulates and outputs stereo sound from the signal supplied from the FM band antenna booster amplifier 34. In addition, the electric field strength signal SM and the multipath detection signal MP are output to the antenna system control unit 37. On the other hand, the AM receiver 36 demodulates and outputs monaural sound from the signal supplied from the AM band antenna booster amplifier 35.

  The control unit 38 controls the operation of the FM receiver 5 and the AM receiver 36, and the operation of an audio selector and an audio amplifier (not shown). Of the FM receiver 5 and the AM receiver 36, One is the active receiver, and the audio selector outputs the audio output from the active receiver to the speaker or the like as audio output from the audio amplifier or the like. Further, the control unit 38 notifies the antenna system control unit 37 which of the FM receiver 5 and the AM receiver 36 is selected as the active receiver.

And the antenna system | strain control part 37 performs the antenna characteristic switching process shown in FIG.
As shown in the figure, in this process, based on the notification from the control unit 38, it is checked which of the FM receiver 5 and the AM receiver 36 is currently selected as the active receiver (steps 402 and 408). . If the AM receiver 36 is selected (step 402), the FM band antenna booster amplifier 34 is disabled to enter a high impedance output state, and the AM band antenna booster amplifier 35 is set to enable (step 402). Step 404). Then, the second switch 33 and the second switch 33 are set to an on state (step 406). As a result, an antenna in which the first antenna element 1, the second antenna element 2, and the third element are sequentially connected is formed, and after the received signal from the antenna is amplified by the AM band antenna booster amplifier 35, the AM receiver The monaural sound is demodulated and output from the received signal by the AM receiver 36.

  On the other hand, when the FM receiver 5 is selected as the active receiver (step 408), the AM band antenna booster amplifier 35 is disabled and the high impedance output state is set, and the FM band antenna booster amplifier 34 is set to Enable is set (step 410). Further, the first switch 32 is turned on and the second switch 33 is turned off (step 412).

  Then, the following processing is performed until the FM receiver 5 is not selected as a working receiver (step 420). That is, it is checked whether or not the electric field strength signal SM is larger than a predetermined threshold Th (step 414). If the electric field strength signal SM is not larger than the threshold Th, the electric field strength signal SM becomes larger than the threshold Th. Wait for. If the electric field strength signal SM is larger than the threshold value Th, it is further checked whether or not multipath has occurred from the multipath detection signal MP (step 416). If multipath has occurred, the first switch 32 is checked. The on / off state of is reversed (step 418). If no multipath has occurred, the processing returns to step 414.

  As described above, according to the second embodiment, in addition to the effects of the first embodiment, the first antenna element 1 and the second antenna element 2 used for the diversity of the FM receiver 5 are connected to the AM receiver 36. By sharing the antenna, there is an effect that the total length of the antenna wiring can be shortened as compared with the case where the antenna for the AM receiver 36 is provided exclusively.

  In the above description, the application to the combination of the FM receiver 5 that performs diversity and the AM receiver 36 has been described as an example. However, the second embodiment can be similarly applied to combinations of other receivers. .

1 is a diagram illustrating a configuration of a wireless broadcast receiving system according to a first embodiment of the present invention. It is a flowchart which shows the antenna characteristic switching process which concerns on 1st Embodiment of this invention. It is a figure which shows the structure of the radio broadcast receiving system which concerns on 2nd Embodiment of this invention. It is a flowchart which shows the antenna characteristic switching process which concerns on 2nd Embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... 1st antenna element, 2 ... 2nd antenna element, 3 ... Switch, 4 ... Antenna booster amplifier, 5 ... FM receiver, 6 ... Antenna control part, 31 ... 3rd antenna element, 32 ... 1st switch, 33 2nd switch, 34 ... FM band antenna booster amplifier, 35 ... AM band antenna booster amplifier, 36 ... AM receiver, 37 ... antenna system control unit, 38 ... control unit, 51 ... front end unit, 52 ... IF Amplifier 53... FM detector 54. FM demodulator 55 55 S meter 56 Multipath detector

Claims (3)

A radio broadcast receiving system mounted on an automobile and receiving diversity of radio broadcasts,
A plurality of antenna elements wired on a window glass of an automobile, and one or a plurality of switches interposed between the plurality of antenna elements, and the plurality of antennas according to an on / off state of each switch An antenna system forming an antenna constituted by different combinations of elements;
A radio broadcast receiver for receiving radio broadcast using the antenna;
Multipath detection means for detecting the occurrence of a multipath failure based on a received signal of the wireless broadcast receiver;
A radio broadcast receiving system, comprising: antenna control means for switching on / off states of the switches in response to detection of occurrence of a multipath failure by the multipath detection means. The wireless broadcast receiving system according to claim 1,
The antenna system includes one switch, a first antenna element having a first end connected to a feeding point for the radio broadcast receiver and a second end connected to the switch, and a first end connected to the switch. The first antenna element is formed only by the first antenna element when the switch is in an off state, and the first antenna is formed when the switch is in an on state. Forming an antenna having a second directivity different from the first directivity by combining an element and a second antenna element;
The radio broadcast receiving system according to claim 1, wherein the antenna control unit alternately switches on / off states of the switch in response to detection of occurrence of a multipath failure by the multipath detection unit. A radio broadcast receiving system that is mounted on a car and receives radio broadcasts,
Three or more antenna elements wired on the window glass of the automobile, and a plurality of switches interposed between the plurality of antenna elements, the plurality of the plurality of antenna elements according to the combination of the on / off state of each switch An antenna system forming an antenna constituted by different combinations of antenna elements;
A first radio broadcast receiver for receiving a radio broadcast of a first frequency band using the antenna;
A second radio broadcast receiver for receiving a radio broadcast of a second frequency band using the antenna;
A radio broadcast receiver selecting means for selecting one of the first radio broadcast receiver and the second radio broadcast receiver as the active radio broadcast receiver;
Multipath detecting means for detecting occurrence of a multipath failure based on a received signal of the first wireless broadcast receiver;
Which of the first radio broadcast receiver and the second radio broadcast receiver is selected as the active radio broadcast receiver by the radio broadcast receiver selection means, and the radio broadcast receiver selection means A combination of the on / off states of the switches in response to the detection of the occurrence of a multipath failure in the multipath detection means when the first radio broadcast receiver is selected as the active radio broadcast receiver. And an antenna control means for switching between.