JP4979630B2 - Broadcast receiving apparatus and tuner module mounting method - Google Patents

Description

  The present invention relates to a broadcast receiving apparatus capable of receiving a plurality of broadcast systems, a tuner module mounted on the broadcast receiving apparatus, and a tuner module mounting method.

  As background art, for example, the following Patent Documents 1 to 3 are known.

  In Patent Document 1, in order to configure a broadcast receiving apparatus having an input circuit that supplies signals to a plurality of tuners without degrading the quality of a signal coming from an antenna, the first and second tuners, There is a technique of providing a balun built-in distributor that distributes antenna input to each high-frequency input terminal of the first tuner and the second tuner, and directly connecting the distributor to each high-frequency input terminal of the first tuner and the second tuner. It is disclosed.

  Further, in Patent Document 2, in order to provide a receiving apparatus that can accurately, simply and safely connect to an input terminal, a signal input from the input terminal is converted into a satellite broadcast band signal and a terrestrial broadcast band signal. A demultiplexer for demultiplexing, a main tuner and a sub tuner that can receive satellite broadcasting and terrestrial broadcasting, and a first terrestrial broadcasting band signal output side of the demultiplexer that is supplied to the main tuner. A switching unit that selectively switches connection between a setting and a second setting in which a signal is supplied from the second input terminal to the tuner unit, and terrestrial broadcasting in each of the first setting and the second setting A technique for detecting a signal and controlling the setting of the switching unit based on the detection result and the setting of the switching unit when detected is disclosed.

  Further, in Patent Document 3, a tuner unit capable of receiving terrestrial analog broadcasting, terrestrial digital broadcasting, and satellite digital broadcasting is mounted, and a main tuner and The sub-tuner was mounted on both sides of the board with the top and bottom faces in the same direction, and a distributor for distributing antenna input was installed across the board between the input terminals of these tuner units. A broadcast receiving apparatus and a distributor for the same are disclosed.

JP 2001-44870 A JP 2007-104314 A JP 2007-288548 A

  Terrestrial digital broadcasting in Japan started in December 2003 in the three major metropolitan areas, and started in December 2006 at all prefectural offices, increasing the household coverage ratio nationwide. On the other hand, terrestrial analog broadcasting is scheduled to end in July 2011, and the transition to terrestrial digital broadcasting is being promoted. Therefore, until July 2011, there will be an area where both terrestrial digital broadcasting and terrestrial analog broadcasting can be received.

  On the other hand, satellite digital broadcasting in Japan started BS digital broadcasting in December 2000, and 110-degree CS digital broadcasting started in July 2000. The BS digital broadcast and the 110-degree CS digital broadcast can be received by a common antenna and receiving unit because the satellites are located on the same longitude. Under such circumstances, the broadcast receiving apparatus receives three types of broadcast waves, terrestrial digital broadcast and terrestrial analog broadcast, and satellite digital broadcast represented by BS digital broadcast and 110-degree CS digital broadcast, respectively. (So-called three-wave broadcasting receiver).

  Further, in recent years, there has been a demand for further thinning of plasma televisions, liquid crystal televisions, so-called thin televisions, and there is a strong demand for miniaturization of the tuner built in the broadcast receiving apparatus.

  Recent broadcast receivers receive two broadcast waves of the same broadcast system and display them on the screen at the same time, while receiving one broadcast wave and displaying the video, Multi-functionalization such as a back program recording function for recording a physical channel program on a built-in large-capacity storage medium is being promoted. In order to realize this function, a digital terrestrial broadcast tuner, a terrestrial analog broadcast tuner, and a satellite digital broadcast tuner are integrated into one module, and two such tuner modules are mounted on the broadcast receiver. Things are happening.

  According to the above-described prior art, when a plurality of tuner units capable of receiving terrestrial analog broadcasting, terrestrial digital broadcasting, and satellite digital broadcasting are mounted, the distribution of distributing the input signal of the broadcast receiving device to each input terminal of the tuner module The receiver module is required, and there is a problem that the broadcast receiver cannot be reduced in size and cost. Also, when designing a three-wave broadcast receiver, the broadcast receiver can be used depending on the presence / absence of a distributor module for each model having a plurality of combinations of the number of digital terrestrial broadcast reception systems and the number of satellite digital broadcast reception systems. There is also a problem that the cost of the design cannot be reduced due to the common design.

  The present invention has been made in view of such circumstances, and an object of the present invention is to receive one or more systems of terrestrial digital broadcasting, terrestrial analog broadcasting, and satellite digital broadcasting, respectively. Another object of the present invention is to provide a three-wave broadcasting receiver.

  Another object is to provide a space-saving and inexpensive tuner module mounting method.

  The above object can be achieved, for example, by the invention described in the claims. The following is a brief description of an outline of typical inventions disclosed in the present application.

  The broadcast receiving apparatus according to the present invention includes first and second tuner modules that receive a plurality of broadcast signals. For example, the first tuner module includes an RF signal input terminal to which a broadcast signal is input, and the RF signal. One of a wideband amplifier that amplifies the RF signal input to the input terminal, a distributor that distributes the RF signal amplified by the broadband amplifier in two, and an RF distribution signal that is distributed by the distributor The RF distribution signal output terminal for outputting the RF distribution signal of the first distribution unit, the first receiving unit for converting the frequency from the other RF distribution signal among the RF distribution signals distributed by the distributor, and the distributor A second receiving unit that converts the other RF distribution signal into an image signal and an audio signal among the RF distribution signals. The second tuner module is input to an RF distribution signal input terminal to which an RF distribution signal output from an RF distribution signal output terminal provided in the first tuner module is input, and to the RF distribution signal input terminal. A third receiver for converting the frequency of the RF distribution signal; an RF signal input terminal for receiving a broadcast signal; a broadband amplifier for amplifying an RF signal input from the RF signal input terminal; and the broadband amplifier A distributor that distributes the RF signal amplified by 2 into two, and a fourth receiver and a fifth receiver that select a desired physical channel from the RF distributed signal distributed by the distributor and perform frequency conversion And comprising. The first tuner module and the second tuner module are mounted on the same substrate, and the RF distribution signal output terminal and the RF distribution input terminal are connected by the substrate wiring of the substrate.

  According to the present invention, it is possible to provide a three-wave broadcast receiving apparatus capable of receiving one or more systems of terrestrial digital broadcasting, terrestrial analog broadcasting, and satellite digital broadcasting. In addition, it is possible to provide a space-saving and inexpensive tuner module mounting method without using a distribution module.

  As an example of the terrestrial digital broadcasting system according to the present invention, an ISDB-T system that is a terrestrial digital broadcasting system in Japan and an ISDB-S system that is a satellite digital broadcasting system will be described as examples.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same reference numerals indicate the same or corresponding parts. Further, the present invention is not limited to the illustrated example.

  FIG. 1 is a block diagram showing an outline of a first tuner module according to an embodiment of the present invention. In FIG. 1, a first tuner module 100 includes a first terrestrial digital broadcast receiver 101, a terrestrial analog broadcast receiver 102, a terrestrial broadcast input terminal 104, a broadband amplifier 105, a distributor 106, An RF distribution signal output terminal 114, a channel selection control signal input terminal 115a, an IF signal output terminal 116a, an AGC control signal input terminal 117a, a video signal output terminal 118, and an audio signal output terminal 119 are provided. The first digital terrestrial broadcast receiving unit 101 includes a channel selection unit 107a, a path switching unit 108, a digital terrestrial broadcast band limiting unit 109a, and a variable amplification unit 110a. On the other hand, the terrestrial analog broadcast receiving unit 102 shares the channel selection unit 107a and the path switching unit 108 with the first terrestrial digital broadcast receiving unit 101, the terrestrial analog broadcast band limiting unit 111, the terrestrial analog demodulation unit 112, An audio demultiplexing unit 113.

  FIG. 2 is a block diagram showing an outline of the second tuner module according to the embodiment of the present invention. In FIG. 2, the second tuner module 200 includes a second terrestrial digital broadcast receiver 103, a first satellite digital broadcast receiver 201, a second satellite digital broadcast receiver 202, and a satellite broadcast input terminal 203. Broadband amplifier 204, distributor 205, AGC control signal input terminals 209a and 209b, IQ signal output terminals 210a and 210b, channel selection control signal input terminals 211a and 211b, and channel selection control signal input terminal 115b. An IF signal output terminal 116b, an AGC control signal input terminal 117b, and an RF distribution signal input terminal 120. Here, the first satellite digital broadcast receiving unit 201 includes a variable attenuating unit 206a, a broadband amplifying unit 207a, and a channel selecting unit 208a, and the second satellite digital broadcast receiving unit 202 includes a variable attenuating unit 206b. A broadband amplifying unit 207b and a channel selecting unit 208b. On the other hand, the second terrestrial digital broadcast receiving unit includes a channel selection unit 107b, a terrestrial digital broadcast band limiting unit 109b, and a variable amplification unit 110b.

  Further, in the configuration of the first tuner module 100 and the second tuner module 200 in FIG. 1 and FIG. 2, subscripts “a” and “b” are attached to a plurality of blocks to distinguish them for convenience of explanation. However, blocks with the same number are assumed to perform the same operation.

  First, in the first tuner module 100, for example, an RF signal such as a terrestrial digital broadcast signal (ISDB-T signal) or an analog terrestrial broadcast signal (NTSC signal) received by the receiving antenna is input to the terrestrial broadcast input terminal 104. The

  The RF signal input to the terrestrial broadcast input terminal 104 is supplied to the wideband amplifier 105. The broadband amplifying unit 105 amplifies the RF signal supplied from the terrestrial broadcast input terminal 104 and supplies the amplified RF signal to the distributor 106. The distributor 106 distributes the RF signal supplied from the wideband amplifier 105 to two paths. One of the RF signals distributed by the distributor 106 is output from the distribution output terminal 114 as the RF distribution signal 121 of the first tuner module 100. The other distributed RF signal is supplied to the tuning unit 107a. In addition, a first bypass circuit 130 is provided between the wideband amplification unit 105 and the channel selection unit 107a, and the RF signal amplified by the wideband amplification unit 105 is directly transmitted to the channel selection unit 107a without using the distributor 106. It is possible to supply. In the bypass circuit 130, for example, a signal path can be selected by changing mounting components such as a resistor and a capacitor.

The channel selection unit 107 a selects a desired physical channel from the RF signal supplied from the distributor 106, converts the frequency into an IF signal, and supplies the IF signal to the path switching unit 108. The physical channel to be selected by the channel selection unit 107a is controlled by a channel selection control signal 122a input from the channel selection control signal input terminal 115a, for example, serial control using the I ² C protocol.

  The path switching unit 108 switches the signal path depending on whether a terrestrial digital broadcast signal or a terrestrial analog broadcast signal is selected. Although the control of the path switching unit 108 is not shown in FIG. 1, for example, a channel selection control signal 122a input from a channel selection control signal input terminal 115a is used to select a channel for terrestrial digital broadcasting and channel selection for terrestrial analog broadcasting. There is a method in which information indicating which channel to select is included, a general-purpose port output in accordance with this information is provided in the channel selection unit 107a, and control is performed by this general-purpose port. However, the tuner module according to the present invention is not limited to this.

  Here, when it is controlled to select a terrestrial digital broadcast signal by the channel selection control signal 122a, the path switching unit 108 supplies the IF signal supplied from the channel selection unit 107a to the terrestrial digital broadcast band limiting unit 109a. To do. On the other hand, when the channel selection control signal 122a is controlled to select the terrestrial analog broadcast signal, the path switching unit 108 supplies the IF signal supplied from the channel selection unit 107a to the terrestrial analog broadcast band limiting unit 111. .

  The terrestrial digital broadcast band limiting unit 109a limits the IF signal supplied from the path switching unit 108 with a bandwidth of about 6 MHz in the case of, for example, the ISDB-T system, and supplies the limited signal to the variable amplification unit 110a. The variable amplifier 110a variably amplifies the IF signal supplied from the digital terrestrial broadcasting band limiting unit 109a and outputs the IF signal 125a from the IF signal output terminal 116a. The amplification factor of the variable amplification unit 110a is controlled by the AGC control signal 126a input from the AGC control signal input terminal 117a.

  The terrestrial analog broadcast band limiting unit 111 limits the IF signal supplied from the path switching unit 108 with a bandwidth of about 6 MHz in the case of the Japanese NTSC system, for example, and supplies the terrestrial analog demodulation unit 112 with the band limit. The terrestrial analog demodulation unit 112 analog-demodulates the IF signal supplied from the terrestrial analog broadcast band limiting unit 112 to generate a video signal 123 and an audio IF signal. The video signal 123 demodulated by the terrestrial analog demodulation unit 112 is output from the video signal output terminal 118, and the audio IF signal is supplied to the audio demultiplexing unit 113. The audio demultiplexing unit 113 demultiplexes the audio IF signal supplied from the terrestrial analog demodulation unit 112 and outputs the audio signal 124 from the audio output terminal 119.

  Next, in the second tuner module 200, for example, an RF signal of a satellite digital broadcast signal transmitted from a broadcast station via a broadcast satellite is received by a reception antenna, and a BS-IF signal frequency-converted by a converter is received. Input to the satellite broadcast input terminal 203.

  The BS-IF signal input to the satellite broadcast input terminal 203 is supplied to the wideband amplifier 204. The broadband amplification unit 204 amplifies the BS-IF signal supplied from the satellite broadcast input terminal 203 and supplies the amplified BS-IF signal to the distributor 205. The distributor 205 distributes the BS-IF signal supplied from the wideband amplifier 204 to two paths. One of the RF signals distributed by the distributor 205 is supplied to the variable attenuating unit 206a in the first satellite digital broadcast receiving unit 201, and the other distributed RF signal is supplied to the second satellite digital broadcast receiving unit. 202 is supplied to the variable attenuator 206b. Further, a second bypass circuit 220 is provided between the broadband amplifying unit 204 and the variable attenuating unit 206a in the first satellite digital broadcast receiving unit 201, and the BS-IF signal amplified by the wideband amplifying unit 204 is supplied. It is possible to supply directly to the variable attenuating unit 206a in the first satellite digital broadcast receiving unit 201 without using the distributor 205. In the bypass circuit 220, for example, a path can be selected by changing mounting components such as a resistor and a capacitor.

The variable attenuating unit 206a in the first satellite digital broadcast receiving unit 201 variably attenuates the BS-IF signal supplied from the distributor 205 or the BS-IF signal supplied via the bypass circuit 220, and wideband amplification is performed. Supplied to the unit 207. The attenuation factor of the variable attenuation unit 206a is controlled by the AGC control signal 212a input from the AGC control signal input terminal 209a. The broadband amplification unit 207a amplifies the BS-IF signal supplied from the variable attenuation unit 206a and supplies the amplified BS-IF signal to the channel selection unit 208a. The channel selection unit 208a selects a desired physical channel from the BS-IF signal supplied from the broadband amplification unit 207a, converts the frequency into an IQ signal 213a, and outputs the IQ signal 213a from the IQ signal output terminal 210a. The physical channel to be selected by the channel selection unit 208a is controlled by a channel selection control signal 214a input from the channel selection control signal input terminal 211a, for example, serial control using the I ² C protocol.

  The operation in the second satellite digital broadcast receiving unit 202 is the same as the operation in the first satellite digital broadcast receiving unit 201 and will not be described.

  Further, in the second tuner module 200, the RF distribution signal 121 distributed by the distributor 106 in the first tuner module 100 can be input from the RF distribution signal input terminal 120. The signal 121 is supplied to the channel selection unit 107b.

The channel selection unit 107b selects a desired physical channel from the RF signal supplied from the RF distribution signal input terminal 120, converts the frequency into an IF signal, and supplies the IF signal to the band limiting unit 109b for digital terrestrial broadcasting. The physical channel to be selected by the channel selection unit 107b is controlled by a channel selection control signal 122b input from the channel selection control signal input terminal 115b, for example, serial control using the I ² C protocol. The digital terrestrial broadcast band limiting unit 109b limits the band of the IF signal supplied from the channel selection unit 107b with a bandwidth of about 6 MHz in the case of, for example, the ISDB-T system and supplies the IF signal to the variable amplification unit 110b. The variable amplifying unit 110b variably amplifies the IF signal supplied from the terrestrial digital broadcast band limiting unit 109b and outputs the IF signal 125b from the IF signal output terminal 116b. The amplification factor of the variable amplification unit 110b is controlled by the AGC control signal 126b input from the AGC control signal input terminal 117b.

  Three-wave shared broadcasting capable of receiving terrestrial digital broadcasting, terrestrial analog broadcasting, and satellite digital broadcasting using the first tuner module and the second tuner module configured as described above. The configuration of the receiving device will be described.

  FIG. 3 shows a first embodiment to which the present invention is applied, and can receive two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and two systems of satellite digital broadcasting. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in the possible broadcast receiving apparatus of 3 wave sharing.

  On the mounting substrate 300, the first tuner module 100, the second tuner module 200, the terrestrial digital demodulation units 140a and 140b, the satellite digital demodulation units 230a and 230b, and the substrate wiring 301 are mounted.

  First, the operation when the first terrestrial digital broadcast receiving unit 101 receives a terrestrial digital broadcast will be described. First, the terrestrial digital demodulation unit 140a generates a channel selection control signal 122a including a physical channel to be selected by the channel selection unit 107a and terrestrial digital broadcast channel selection instruction information for switching the path switching unit 108. This is supplied to the first digital terrestrial broadcast receiving unit 101 via the channel selection control signal input terminal 115a. Then, the first terrestrial digital broadcast receiving unit 101 selects a physical channel instructed by the terrestrial digital demodulation unit 140a, and converts the frequency into an IF signal 125a. The IF signal 125a frequency-converted by the first terrestrial digital broadcast receiving unit 101 is supplied to the terrestrial digital demodulation unit 140a via the IF signal output terminal 116a. The terrestrial digital demodulator 140a digitally demodulates the supplied IF signal 125a to generate a TS (Transport Stream) signal. Also, the AGC control signal 126a is generated so that the signal level of the IF signal 125a supplied from the first terrestrial digital broadcast receiving unit 101 becomes a desired level, and the first terrestrial digital signal is received via the AGC control signal input terminal 117a. This is supplied to the digital broadcast receiving unit 101.

  Next, an operation when the terrestrial analog broadcast receiving unit 102 receives terrestrial digital broadcast will be described. First, the terrestrial digital demodulation unit 140a generates a channel selection control signal 122a including a physical channel to be selected by the channel selection unit 107a and terrestrial analog broadcast channel selection instruction information for switching the path switching unit 108. This is supplied to the first digital terrestrial broadcast receiving unit 101 via the channel selection control signal input terminal 115a. Then, the terrestrial analog broadcast receiving unit 102 selects a physical channel instructed by the terrestrial digital demodulation unit 140a, and generates a video signal 123 and an audio signal 124.

  Next, the operation when the second terrestrial digital broadcast receiving unit 103 receives terrestrial digital broadcast will be described. The RF distribution signal output terminal 114 of the first tuner module 100 and the RF distribution signal input terminal 120 of the second tuner module 200 are connected by a substrate wiring 301 wired on the substrate. Therefore, the RF distribution signal 121 distributed by the distributor 106 is always supplied to the second terrestrial digital broadcast receiving unit 103 via the RF distribution signal input terminal 120. The first bypass circuit 130 is not used.

  First, the terrestrial digital demodulation unit 140b generates a channel selection control signal 122b including a physical channel to be selected by the channel selection unit 107b and terrestrial digital broadcast channel selection instruction information for switching the path switching unit 108. This is supplied to the second digital terrestrial broadcast receiving unit 103 via the channel selection control signal input terminal 115b. Then, the second terrestrial digital broadcast receiving unit 103 selects the physical channel instructed by the terrestrial digital demodulation unit 140b, and converts the frequency into an IF signal 125b. The IF signal 125b frequency-converted by the second terrestrial digital broadcast receiving unit 103 is supplied to the terrestrial digital demodulation unit 140b via the IF signal output terminal 116b. The terrestrial digital demodulator 140b digitally demodulates the supplied IF signal 125b to generate a TS signal. Also, the AGC control signal 126b is generated so that the signal level of the IF signal 125b supplied from the second terrestrial digital broadcast receiving unit 103 becomes a desired level, and the second terrestrial digital signal is input via the AGC control signal input terminal 117b. The digital broadcast receiving unit 103 is supplied.

  Here, by arranging the board wiring 301 in the intermediate layer of the multilayer board, it is possible to reduce the influence of noise from the outside and prevent the reception performance from being deteriorated. Also, it is desirable to wire as short as possible.

  Next, the operation when the first satellite digital broadcast receiving unit 201 receives satellite digital broadcast will be described. First, the satellite digital demodulator 230a generates a channel selection control signal 214a including a physical channel to be selected by the channel selection unit 208a, and sends it to the first satellite digital broadcast reception unit 201 via the channel selection control signal input terminal 211a. Supply. Then, the first satellite digital broadcast receiving unit 201 selects a physical channel instructed by the satellite digital demodulation unit 230a, and converts the frequency into an IQ signal 213a. The IQ signal 213a frequency-converted by the first satellite digital broadcast receiver 201 is supplied to the satellite digital demodulator 230a via the IQ signal output terminal 210a. The satellite digital demodulator 230a digitally demodulates the supplied IQ signal 213a to generate a TS signal. Further, the AGC control signal 212a is generated so that the signal level of the IQ signal 213a supplied from the first satellite digital broadcast receiving unit 201 becomes a desired level, and the first satellite is transmitted via the AGC control signal input terminal 212a. This is supplied to the digital broadcast receiving unit 201.

  Next, the operation when the second satellite digital broadcast receiving unit 202 receives the satellite digital broadcast will be described. First, the satellite digital demodulator 230b generates a channel selection control signal 214b including a physical channel to be selected by the channel selection unit 208b, and sends it to the second satellite digital broadcast reception unit 202 via the channel selection control signal input terminal 211b. Supply. Then, the second satellite digital broadcast receiving unit 202 selects a physical channel instructed by the satellite digital demodulation unit 230b, and converts the frequency into an IQ signal 213b. The IQ signal 213b frequency-converted by the second satellite digital broadcast receiver 202 is supplied to the satellite digital demodulator 230b via the IQ signal output terminal 210b. The satellite digital demodulator 230b digitally demodulates the supplied IQ signal 213b to generate a TS signal. Further, the AGC control signal 212b is generated so that the signal level of the IQ signal 213b supplied from the second satellite digital broadcast receiving unit 202 becomes a desired level, and the second satellite is connected via the AGC control signal input terminal 212b. The digital broadcast receiving unit 202 is supplied. Note that the second bypass circuit 220 is not used.

  As described above, in the embodiment of the present invention, three-wave common broadcasting capable of receiving two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and two systems of satellite digital broadcasting. In addition to realizing the receiving device, a space-saving and inexpensive tuner module configuration can be realized without using a distribution module. Further, by inputting the RF distribution signal of the terrestrial broadcasting in the first tuner module to the second tuner module via the wiring in the intermediate layer of the board, it is possible to reduce the influence of disturbance from the outside. .

  FIG. 4 shows a second embodiment to which the present invention is applied. Two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and one system of satellite digital broadcasting can be received. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in the possible broadcast receiving apparatus of 3 wave sharing.

  On the mounting substrate 300, the first tuner module 100, the second tuner module 200, the terrestrial digital demodulation units 140a and 140b, the satellite digital demodulation unit 230a, and the substrate wiring 301 are mounted.

  The difference from the block diagram showing the first embodiment shown in FIG. 3 is that, in the second tuner module, the BS-IF signal amplified by the wideband amplification unit 204 does not go through the distributor 205 but the second tuner module. 2 is directly supplied to the variable attenuating unit 206a via the bypass circuit 220. Further, the distributor 205, the second satellite digital broadcast receiving unit 202, and the satellite digital demodulating unit 230b shown by broken lines are not mounted. The other blocks are assumed to perform the same operation as the block diagram showing the first embodiment shown in FIG.

  As described above, in the embodiment of the present invention, three-wave broadcasting capable of receiving two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and one system of satellite digital broadcasting. In addition to realizing the receiving device, a space-saving and inexpensive tuner module configuration can be realized without using a distribution module. Further, by inputting the RF distribution signal of the terrestrial broadcasting in the first tuner module to the second tuner module via the wiring in the intermediate layer of the board, it is possible to reduce the influence of disturbance from the outside. .

  FIG. 5 shows a third embodiment to which the present invention is applied. One system of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and two systems of satellite digital broadcasting can be received. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in the possible broadcast receiving apparatus of 3 wave sharing.

  On the mounting substrate 300, the first tuner module 100, the second tuner module 200, the terrestrial digital demodulation unit 140a, the satellite digital demodulation units 230a and 230b, and the substrate wiring 301 are mounted.

  The difference from the block diagram showing the first embodiment shown in FIG. 3 is that, in the first tuner module, the RF signal amplified by the wideband amplification unit 105 does not go through the distributor 106 but the first The point is that the signal is directly supplied to the channel selection unit 107 a via the bypass circuit 130. Further, the distributor 106, the second terrestrial digital broadcast receiving unit 103, and the terrestrial digital demodulating unit 140b shown by broken lines are not mounted. The other blocks are assumed to perform the same operation as the block diagram showing the first embodiment shown in FIG.

  As described above, in the embodiment of the present invention, a three-wave shared broadcast capable of receiving one terrestrial digital broadcast, one terrestrial analog broadcast, and two satellite digital broadcasts. In addition to realizing the receiving device, a space-saving and inexpensive tuner module configuration can be realized without using a distribution module.

  FIG. 6 shows a fourth embodiment to which the present invention is applied. One system of terrestrial digital broadcast, one system of terrestrial analog broadcast, and one system of satellite digital broadcast can be received. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in the possible broadcast receiving apparatus of 3 wave sharing.

  On the mounting substrate 300, the first tuner module 100, the second tuner module 200, the terrestrial digital demodulation unit 140a, and the satellite digital demodulation unit 230a are mounted.

  The difference from the block diagram showing the second embodiment shown in FIG. 4 is that, in the first tuner module, the RF signal amplified by the wideband amplifier 105 does not pass through the distributor 106, The point is that the signal is directly supplied to the channel selection unit 107 a via the bypass circuit 130. Further, the distributor 106, the second terrestrial digital broadcast receiving unit 103, and the terrestrial digital demodulating unit 140b shown by broken lines are not mounted.

  As described above, in the embodiment of the present invention, a three-wave shared broadcast that can receive one terrestrial digital broadcast, one terrestrial analog broadcast, and one satellite digital broadcast. A receiving device can be realized.

  In addition, as shown in the first to fourth embodiments, a multi-model three-wave shared broadcast receiving apparatus having a plurality of combinations of the number of terrestrial digital broadcast reception systems and the number of satellite digital broadcast reception systems is designed and developed. In some cases, it is possible to cope with minor changes by not performing unnecessary component mounting, and it is possible to provide an inexpensive three-wave broadcast receiving apparatus by sharing the design.

  As described above, according to the present invention, there is provided a three-wave broadcast receiver capable of receiving one or more systems of terrestrial digital broadcast, terrestrial analog broadcast, and satellite digital broadcast. In addition, it is possible to realize a space-saving and inexpensive tuner module configuration without using a distribution module.

  Further, by inputting the RF distribution signal of the terrestrial broadcasting in the first tuner module to the second tuner module via the wiring in the intermediate layer of the board, it is possible to reduce the influence of disturbance from the outside. .

  In addition, in the design and development of multiple types of three-wave shared broadcast receivers that have multiple combinations of the number of terrestrial digital broadcast reception systems and the number of satellite digital broadcast reception systems, minor changes by not mounting unnecessary parts By sharing the tuner module and its mounting method, an inexpensive three-wave shared broadcast receiving apparatus can be provided.

  As mentioned above, although embodiment of the broadcast receiver according to this invention was described, this invention is not limited to the said embodiment, A various improvement and deformation | transformation can be performed in the range which does not deviate from the summary of this invention.

It is a block diagram which shows the outline of the 1st tuner module which concerns on embodiment of this invention. It is a block diagram which shows the outline of the 2nd tuner module which concerns on embodiment of this invention. 1 shows a first embodiment to which the present invention is applied, and is capable of receiving two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and two systems of satellite digital broadcasting. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in a common broadcast receiver. 3 shows a second embodiment to which the present invention is applied, and is capable of receiving two systems of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and one system of satellite digital broadcasting. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in a common broadcast receiver. 3 shows a third embodiment to which the present invention is applied, and is capable of receiving one system of terrestrial digital broadcasting, one system of terrestrial analog broadcasting, and two systems of satellite digital broadcasting. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in a common broadcast receiver. 4 shows a fourth embodiment to which the present invention is applied, and is capable of receiving a single terrestrial digital broadcast, a single terrestrial analog broadcast, and a single satellite digital broadcast. It is a block diagram for demonstrating the connection method of the 1st tuner module and the 2nd tuner module, and the mounting method to a board | substrate in a common broadcast receiver.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... 1st tuner module 101 ... 1st terrestrial digital broadcast receiver 102 ... Terrestrial analog broadcast receiver 103 ... 2nd terrestrial digital broadcast receiver 104 ... Terrestrial broadcast input terminal 105 ... Broadband amplifier 106 ... Divider 107a, 107b ... Channel selection unit 108 ... Route switching unit 109a, 109b ... Terrestrial digital broadcast band limiting unit 110a, 110b ... Variable amplification unit 111 ... Terrestrial analog broadcast band limiting unit 112 ... Terrestrial analog demodulation unit 113 ... Audio demultiplexing unit 114 ... RF distribution signal output terminals 115a and 115b ... Tuning control signal input terminals 116a and 116b ... IF signal output terminals 117a and 117b ... AGC control signal input terminal 118 ... Video signal output terminal 119 ... Audio signal output terminal 120 ... RF distribution Signal input terminal 121 RF distribution signal 122 Channel selection control signal 123 Video signal No. 124 ... Audio signal 125a, 125b ... IF signal 126a, 126b ... AGC control signal 130 ... First bypass circuit 140a, 140b ... Terrestrial digital demodulator 200 ... Second tuner module 201 ... First satellite digital broadcast receiver 202 ... Second satellite digital broadcast receiver 203 ... Satellite broadcast input terminal 204 ... Broadband amplifier 205 ... Dividers 206a, 206b ... Variable attenuators 207a, 207b ... Broadband amplifiers 208a, 208b ... Channel selectors 209a, 209b ... AGC Control signal input terminals 210a, 210b ... IQ signal output terminals 211a, 211b ... Channel selection control signal input terminals 212a, 212b ... AGC control signals 213a, 213b ... IQ signals 214a, 214b ... Channel selection control signal 220 ... Second bypass circuit 230a, 230b ... Satellite digital recovery Unit 300 ... mounting substrate 301 ... substrate wiring 400 ... terrestrial broadcast wave distribution module 410 ... satellite broadcast wave distribution module 401, 411 ... input terminals 402, 412 ... wideband amplifiers 403, 413 ... distributors 404, 405, 414, 415 ... output terminals 420, 430 ... terrestrial broadcast / satellite broadcast shared tuner modules 421, 422, 431, 432 ... input terminals 423, 433 ... terrestrial channel selection units 424, 434 ... satellite selection units 425, 435 ... analog demodulation units 426, 436 ... Audio demultiplexing units 440a, 440b ... Terrestrial digital demodulation units 450a, 450b ... Satellite digital demodulation units

Claims (11)

A broadcast receiving apparatus in which first and second tuner modules for receiving a plurality of broadcast signals are mounted,
The first tuner module includes:
An RF signal input terminal for receiving a broadcast signal;
A wideband amplifier for amplifying an RF signal input to the RF signal input terminal;
A distributor for distributing the RF signal amplified by the wideband amplification unit into two;
Among the RF distribution signals distributed by the distributor, an RF distribution signal output terminal that outputs one RF distribution signal;
A first receiving unit that converts a frequency from the other RF distribution signal among the RF distribution signals distributed by the distributor;
A second receiving unit that converts the other RF distribution signal into an image signal and an audio signal among the RF distribution signals distributed by the distributor;
The second tuner module is:
An RF distribution signal input terminal to which an RF distribution signal output from an RF distribution signal output terminal provided in the first tuner module is input;
A third receiver for converting the frequency of the RF distribution signal input to the RF distribution signal input terminal;
An RF signal input terminal for receiving a broadcast signal;
A wideband amplifier for amplifying an RF signal input from the RF signal input terminal;
A distributor for distributing the RF signal amplified by the wideband amplification unit into two;
A fourth receiving unit and a fifth receiving unit that select a desired physical channel from the RF distribution signal distributed by the distributor and perform frequency conversion; and the first tuner module and the second tuner. The module is mounted on the same board,
The RF distribution signal output terminal and the RF distribution input terminal are connected by substrate wiring of the substrate,
A broadcast signal input to the RF signal input terminal provided in the first tuner module;
A broadcast signal transmitted via a transmission medium different from the broadcast signal input to the RF signal input terminal provided in the second tuner module;
A broadcast receiving apparatus characterized by the above. The broadcast receiving device according to claim 1,
The broadcast signal input to the RF signal input terminal provided in the first tuner module is
A broadcast receiving apparatus characterized by being one or both of a terrestrial analog broadcast signal and a terrestrial digital broadcast signal. The broadcast receiving device according to claim 1,
A broadcast receiving apparatus, wherein a broadcast signal input to the RF signal input terminal provided in the second tuner module is a satellite digital broadcast signal. The broadcast receiving device according to claim 2,
In the first receiver provided in the first tuner module,
Frequency conversion of digital terrestrial broadcast signal to IF signal,
In the second receiver provided in the first tuner module,
Convert terrestrial analog broadcast signals into video and audio signals,
In the third receiver provided in the second tuner module,
A broadcast receiver characterized by frequency-converting a terrestrial digital broadcast signal into an IF signal. The broadcast receiving apparatus according to claim 3,
The broadcast receiver according to claim 4, wherein the fourth receiver and the fifth receiver provided in the second tuner module frequency-convert satellite digital broadcast signals into baseband signals. The broadcast receiving device according to claim 4,
The first receiving unit provided in the first tuner module includes:
A channel selection unit that selects a desired physical channel from the RF distribution signal distributed by the distributor provided in the first tuner module, and converts it into an IF signal;
A first band limiting unit that limits a frequency band of the IF signal frequency-converted by the channel selection unit;
A variable amplifying unit for adjusting a signal level of the IF signal whose frequency band is limited by the first band limiting unit,
The second receiving unit provided in the first tuner module includes:
A channel selection unit that selects a desired physical channel from the RF distribution signal distributed by the distributor provided in the first tuner module, and converts it into an IF signal;
A second band limiting unit that limits a frequency band of the IF signal frequency-converted by the channel selection unit;
An analog demodulation unit that analog-demodulates the IF signal whose frequency band is limited by the second band-limiting unit and outputs a video signal and an audio signal;
A broadcast receiver characterized by comprising: The broadcast receiving device according to claim 4,
The third receiving unit provided in the second tuner module includes:
A channel selection unit that selects a desired physical channel from the RF distribution signal input to the RF distribution signal input terminal provided in the second tuner module, and converts the channel into an IF signal;
A band limiting unit that limits the frequency band of the IF signal frequency-converted by the channel selection unit;
A variable amplifying unit for adjusting a signal level of the IF signal whose frequency band is limited by the band limiting unit;
A broadcast receiving apparatus comprising: The broadcast receiving device according to claim 5,
The fourth receiving unit provided in the second tuner module includes:
A first variable attenuator for adjusting a signal level of the RF signal distributed by the distributor provided in the second tuner module;
A first wideband amplifier for amplifying the RF signal level-adjusted by the first variable attenuator;
A first channel selection unit that frequency-converts the RF signal amplified by the first wideband amplification unit into a baseband signal,
The fifth receiving unit provided in the second tuner module includes:
A second variable attenuation unit for adjusting a signal level of the RF signal distributed by the distributor provided in the second tuner module;
A second wideband amplifier for amplifying the RF signal level-adjusted by the second variable attenuator;
And a second channel selection unit that frequency-converts the RF signal amplified by the second broadband amplification unit into a baseband signal. A method for mounting a tuner module mounted on a broadcast receiving apparatus capable of receiving a plurality of broadcast systems according to any one of claims 1 to 8,
The substrate wiring between the RF distribution signal output terminal and the RF distribution input terminal is
A tuner module mounting method, wherein the tuner module is disposed in an intermediate layer of the substrate. The broadcast receiving device according to claim 1,
The RF signal amplified by the wideband amplifier provided in the first tuner module is provided in the first tuner module without passing through the distributor provided in the first tuner module. A bypass circuit for supplying to the first receiving unit;
With
A broadcast receiving apparatus, wherein the distributor provided in the first tuner module is not mounted as a component. The broadcast receiving device according to claim 1,
The RF signal amplified by the wideband amplifier provided in the second tuner module is provided in the second tuner module without passing through the distributor provided in the second tuner module. A bypass circuit for supplying to the fourth receiving unit,
The broadcast receiving apparatus, wherein the distributor provided in the second tuner module is not mounted as a component.

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