JP2010130609A - Communication device and electronics employing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize a communication device excellent in manufacturing efficiency by reducing the number of signal lines electrically connecting a first unit and a second unit. <P>SOLUTION: The communication device shares the ground of a first circuit 8 and a second circuit 9 and transmits an IF signal and a control signal through multiplexing, so that the number of signal lines for electrically connecting a first unit 2 and a second unit 3 is reduced to realize the communication device high in manufacturing efficiency, and the device is used suitably for wireless signal communication device for vehicles. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a communication apparatus that has two units and needs to arrange a large number of signal lines between the two units, and an electronic apparatus using the communication apparatus.

  For example, a conventional electronic device used when receiving ISDB-T digital television broadcasting by car will be described with reference to FIG.

  In FIG. 6, an electronic device 100 includes a first unit 101, a second unit 102, and a transmission line group 103 that electrically connects them. The first unit 101 is connected to a first antenna 104, a second antenna 105, and a first antenna 104 that receive digital television broadcasts, and converts an input signal to a desired frequency (hereinafter, the signal after frequency conversion is converted). A first tuner 106 (referred to as an IF signal) and a second tuner 107 connected to the second antenna 105 and converting an input signal to a desired frequency are included. The second unit 102 is connected to the demodulation circuit 108 that demodulates the input television signal, the video processing unit 109 that is connected to the output side of the demodulation circuit 108 and decodes the demodulated television signal, and the output side of the video processing unit 109 And a display unit 110 for displaying a television signal.

  As an example, the first unit 101 is disposed on the outer edge of the windshield of the car, and the second unit 102 is disposed in the car navigation unit. The first unit 101 and the second unit 102 are electrically connected with a transmission line group 103 of about 5 m, and input / output signals of the first tuner 106 and the second tuner 107 are transmitted to the transmission line group 103. It is connected to the demodulation circuit 108 via The transmission line group 103 includes an IF signal, a ground, a power supply, an AGC signal (a signal for controlling the gain of the variable gain amplifier constituting the first tuner 106 and the second tuner 107), channel data (the first tuner 106). , A signal for controlling the channel of the second tuner 107), and two sets of six signal lines used for transmission of channel clock data (signal for synchronizing channel data).

As prior art document information related to the invention of this application, for example, Patent Document 1 is known.
JP 2001-169196 A

  The conventional electronic device 100 that receives the ISDB-T digital television broadcast shown in FIG. 6 has as many as 12 signal lines of about 5 m in order to electrically connect the first unit 101 and the second unit 102. There is a problem that it is necessary to use, and manufacturing efficiency is very poor.

  Therefore, an object of the present invention is to realize a communication device that can reduce the number of signal lines that electrically connect the first unit and the second unit, and has excellent manufacturing efficiency.

  In order to achieve this object, the communication apparatus of the present invention includes a first unit, a first line, a second line, a third line, one of which is electrically connected to the first unit, and the first line, And a second unit in which the other of the second line and the third line is electrically connected. The first unit includes a first circuit, a second circuit, a ninth filter that electrically connects the first circuit and one of the first lines, and a second circuit and one of the third lines. And an eleventh filter to be electrically connected.

  The second unit includes a third circuit, a tenth filter that electrically connects the other of the first line and the third circuit, and a second circuit that electrically connects the other of the third line and the third circuit. 12 filters. The ground of the first unit is electrically connected to the ground of the second unit via the second line.

  The first control signal that operates at a frequency different from the output signal of the first circuit is supplied to the first line via the third filter of the first unit, or is output from the first line, and the second unit It supplies to a 1st track | line via the 4th filter which has, or is output from a 1st track | line.

  The second control signal that operates at a frequency different from the output signal of the second circuit is supplied to the third line via the fifth filter of the first unit, or is output from the third line, The signal is supplied to the third line via the sixth filter of the unit or output from the third line.

  As described above, the communication device of the present invention can share the ground of the first circuit and the second circuit and multiplex and transmit the IF signal and the control signal. The number of signal lines to be electrically connected can be reduced, and a remarkable effect can be obtained that a communication device with high manufacturing efficiency can be realized.

(Embodiment 1)
FIG. 1 is a block diagram of communication apparatus 1 according to Embodiment 1 of the present invention. In FIG. 1, the communication device 1 includes a first unit 2, a first line 4, a second line 5, a third line 6, a fourth line 7, one of which is electrically connected to the first unit 2, The second unit 3 includes the first line 4, the second line 5, the third line 6, and the fourth line 7 that are electrically connected to the other.

  The first unit 2 includes a first circuit 8 to which an output signal of the first antenna 10 is input, a second circuit 9 to which an output signal of the second antenna 11 is input, a first circuit 8 and a first line. 4, a first balanced filter 12 that electrically connects one of the second lines 5 and a third circuit 9 that electrically connects the second circuit 9 and one of the third line 6 and the fourth line 7, respectively. And a balanced filter 13.

  The second unit 3 includes a second balanced filter 14 in which one of the first line 4 and the second line 5 is electrically connected to the other, and the other one of the third line 6 and the fourth line 7 is connected to the other. It has the 4th balance type filter 15 electrically connected, and the 3rd circuit 16 to which the other of the 2nd balance type filter 14 and the 4th balance filter 15 is electrically connected.

  The ground of the first unit 2 is electrically connected between the first balanced filter 12 and the first line 4 via the first filter 17, and the ground of the second unit 3 is connected to the second filter 18. Is electrically connected in the vicinity of the connection point between the second balanced filter 14 and the first line 4. Thereby, the ground of the 1st unit 2 and the 2nd unit 3 will be electrically connected.

  Next, the first control signal is input or output from between the first balanced filter 12 and the second line 5 through the third filter 19, and the second balanced filter through the fourth filter 20. 14 and the second line 5 are input or output.

  The second control signal is input or output from between the third balanced filter 13 and the third line 6 via the fifth filter 21, and the fourth balanced filter 15 via the sixth filter 22. And the third line 6 are input or output.

  Further, the third control signal is input or output from between the third balanced filter 13 and the fourth line 7 through the seventh filter 23, and the fourth balanced filter 15 through the eighth filter 24. And the fourth line 7 are input or output.

  Hereinafter, in order to facilitate understanding of the communication device of the present invention described in the first embodiment, a case where the communication device of the present invention described in the first embodiment is used for an in-vehicle digital television receiver will be described as an example. To do. In this case, the first circuit 8 in FIG. 1 corresponds to the first tuner 8, the second circuit 9 corresponds to the second tuner 9, and the third circuit 16 corresponds to the demodulation circuit 16.

  And the 1st unit 2, the 1st antenna 10, and the 2nd antenna 11 are arrange | positioned at the windshield outer edge of a vehicle, and a 2nd unit is installed in a car navigation. The first unit 2 and the second unit 3 are electrically connected by four signal lines of about 5 m.

  A digital television signal received by the first antenna 10 is input to the first tuner 8, frequency-converted to a desired frequency band (IF band), and then differentially transmitted to the first balanced filter 12. The digital television signal received by the second antenna 11 is input to the second tuner 9, frequency-converted to a desired frequency band (IF band), and then differentially transmitted to the third balanced filter 13. By differentially transmitting the television signals output from the first tuner 8 and the second tuner 9, it is possible to prevent the quality of the television signal from being deteriorated due to external noise.

  The IF signals output to the first balanced filter 12 and the third balanced filter 13 generally use the same frequency band, so that the IF signal from the first tuner 8 is the first line 4, The two IF signals are transmitted to the second unit 3 via the two lines 5, and the IF signal from the second tuner 9 is transmitted to the second unit 3 via the third line 6 and the fourth line 7. Is preventing interference.

  Here, for the IF band, a frequency band different from the AGC signal, channel data, and channel clock data, which are control signals, is selected. This is to prevent interference when the IF signal and the control signal are multiplexed on one signal line.

  The first balanced filter 12 and the third balanced filter 13 remove noise, control signals, and DC signals other than the frequency band in which the television signal (IF signal) exists. Further, in order to differentially transmit the IF signal, the filter configuration is a balanced configuration.

  The output signal (IF signal) of the first balanced filter 12 is input to the second balanced filter 14 via, for example, the first line 4 and the second line 5 configured by feeder lines. Similarly, the output signal (IF signal) of the third balanced filter 13 is input to the fourth balanced filter 15 via the third line 6 and the fourth line 7.

  Similarly to the first balanced filter 12 and the third balanced filter 13, the second balanced filter 14 and the fourth balanced filter 15 also have noise and control signals other than the frequency band in which the television signal (IF signal) exists. The DC signal is removed.

  Output signals (IF signals) from the second balanced filter 14 and the fourth balanced filter 15 are input to the demodulating circuit 16, and the demodulating circuit 16 demodulates and synthesizes the modulated television signal.

  The first tuner 8 includes a first variable gain amplifier 28, and the gain of the first variable gain amplifier 28 is adjusted according to the signal quality and power value of the television signal input from the first antenna 10. . Here, since the signal quality and power value of the television signal input from the first antenna 10 are generally detected by the demodulation circuit 16, the demodulation circuit 16 uses the first variable gain amplifier based on the detection result. The optimal gain of 28 is determined. The first gain control circuit 29 included in the demodulation circuit 16 outputs an AGC signal for changing the gain of the first variable gain amplifier 28 to the optimum gain to the fourth filter 20.

  Similarly, the second tuner 9 has a second variable gain amplifier 30, and the gain of the second variable gain amplifier 30 is adjusted according to the signal quality and power value of the television signal input from the second antenna 11. Is done. The signal quality and power value of the television signal output from the second tuner 9 are detected by the demodulation circuit 16, and the demodulation circuit 16 determines the optimum gain of the second variable gain amplifier 30 based on the detection result. Then, the second gain control circuit 31 included in the demodulation circuit 16 outputs an AGC signal for changing the gain of the second variable gain amplifier 30 to the optimum gain to the eighth filter 24.

  The fourth filter 20 and the eighth filter 24 are filters having a characteristic of allowing only the AGC signal to pass and blocking the IF signal, the channel data, and the channel clock data. There is almost no flow into the first gain control circuit 29 and the second gain control circuit 31. For this reason, the AGC signal, channel data, and channel clock data are set so that the occupied frequency bands are different. Further, since the AGC signal for controlling the first variable gain amplifier 28 and the AGC signal for controlling the second variable gain amplifier 30 can be signals occupying the same frequency band, the second unit 3 can be connected via different signal lines. It is transmitted to the first unit 2. Thereby, it can prevent that two AGC signals interfere.

  Also, the two AGC signals transmitted via the second line 5 and the fourth line 7 are both based on the ground potential superimposed on the first line 4 and conventionally required for the ground. Two signal lines can be reduced to one.

  The power necessary for the first unit 2 is supplied from the power circuit 32 included in the demodulation circuit 16 to the third line 6 via the thirteenth filter 33, and the first unit 2 is connected via the fourteenth filter 34. To the active circuit it has. As a result, it is possible to reduce the number of power supply signal lines, which conventionally required two, to one.

  The thirteenth filter 33 and the fourteenth filter 34 have a characteristic of passing a DC signal such as a power supply, but blocking the IF signal and the control signal, so that the IF signal and the control signal flow into the power supply circuit 32. Is preventing.

  The first tuner 8 has a first synthesizer 35 that generates a local frequency signal used during frequency conversion. Similarly, the second tuner 9 has a second synthesizer 36 that generates a local frequency signal used during frequency conversion.

The oscillation frequencies of the first synthesizer 35 and the second synthesizer 36 are controlled by a channel selection signal output from a channel control circuit 37 included in the demodulation circuit 16. The channel selection signal is composed of channel data and channel clock data. As an example, there are cases where an SDA signal (Serial Data) of an I ² C signal and an SCL (Serial Clock) are used.

  The channel data output from the channel control circuit 37 is supplied to the third line 6 via the sixth filter 22 and input to the desired channel derivation circuit 38 of the first unit 2 via the fifth filter 21. Is done. The channel clock data output from the channel control circuit 37 is supplied to the second line 5 via the fifteenth filter 39 and input to the desired channel derivation circuit 38 via the sixteenth filter 40. Both the channel data and the channel clock data are transmitted via the second line 5 and the third line 6 with reference to the ground potential superimposed on the first line 4.

  The desired channel deriving circuit 38 derives a desired channel based on the input channel data and channel clock data, and changes the oscillation frequency of the first synthesizer 35 and the second synthesizer 36 so that the desired channel can be received. Are output to the first tuner 8 and the second tuner 9. Note that channel data and channel clock data are overlapped on different signal lines because the occupied frequency bands may overlap.

  With the configuration as described above, it is possible to reduce the number of signal lines between the first unit 2 and the second unit 3 that were conventionally required to 12 to 4 and remarkably increase the manufacturing efficiency of the communication device. Can be improved. Moreover, compared with the conventional communication apparatus, the installation volume required at the time of attachment to a vehicle is small, and the effect that handling is easy is also acquired.

  Also, by adopting different transmission methods for IF signals that want to reduce signal quality degradation during transmission and control signals that have a large noise degradation tolerance during transmission, the signal can be maintained while maintaining good reception performance. A communication device with a small number of lines can be realized.

  In the above description, the present invention has been described by taking a reception-only communication device as an example. However, the present invention is not limited to this, and the present invention can also be applied to a communication device that performs transmission. Obtainable. In the above description, the case where the control signal (AGC signal, channel data, channel clock data) is transmitted from the second unit 3 to the first unit 2 is not limited to this. The present invention can also be applied to an application in which a control signal is transmitted from 2 to the second unit 3.

  In the above description, the case where the digital television signal received by the first unit 2 is diversity-combined by the second unit 3 has been described. However, the present invention is not limited to this. The present invention can also be applied to an application in which the circuit 9 receives and transmits channels having different frequencies.

In addition, a ground is superimposed on the first line 4, a power source is superimposed on the second line 5, and an AGC signal and channel clock data for controlling the first variable gain amplifier 28 are superimposed on the third line 6. In addition, an AGC signal for controlling the second variable gain amplifier 30 and channel data may be superimposed on the fourth line 7. As a result, a DC signal is superimposed on both the first line 4 and the second line 5, and the quality of the output signal of the first tuner 8 can be maintained high. In addition, since the control signal (AGC signal, I ² C signal) that is paired with each other is superimposed on the third line 6 and the fourth line 7, each control signal is separated by the first unit 2 and the second unit 3. The filters are also composed of filters that are paired with each other (approximately the same time constant). Thereby, the phase difference and the amplitude difference between the channel data and the channel clock data, which are a pair of control signals, can be suppressed to be small, so that the problem of erroneous recognition of the control signals can be suppressed. If the communication device having such a configuration is applied to, for example, a system in which the first antenna 10 has better antenna characteristics than the second antenna 11, the quality of the output signal of the first tuner 8 is extremely high. Therefore, the signal quality after diversity combining in the demodulation circuit 16 can be improved. In the above description, the AGC signal for controlling the first variable gain amplifier 28 and the channel clock data are superimposed on the third line 6, and the AGC for controlling the second variable gain amplifier 30 is superimposed on the fourth line 7. The example in which the signal and the channel data are superimposed has been described. However, the present invention is not limited to this, and the two AGC signals are not superimposed on the same signal line. There is no problem even if the control signals are superposed in any combination as long as they are not superposed.

  In the above description, the example in which the power supply to the first unit 2 is performed from the demodulation circuit 16 of the second unit 3 has been described. However, the present invention is not limited to this, and the power supply to the first unit 2 is performed. The power may be supplied from another power source (not shown) in the car navigation system, and further supplied from the fourteenth filter 34 to the first tuner 8 and the second tuner 9 of the first unit 2 via a regulator (not shown). You may do it. In this case, the power necessary for the first unit 2 is supplied from the other power source (not shown) in the car navigation system to the third line 6 via the thirteenth filter 33, and only the power source is separated by the fourteenth filter 34. After that, it is supplied to the first tuner 8 and the second tuner 9 via a regulator (not shown). As a result, it is possible to stably supply the necessary power supply voltage and current consumption to the first unit 2, and to realize a stable operation and good reception performance of the communication device.

  In a system that does not need to transmit / receive signals when switching channels, the IF signal, the AGC signal, and the channel selection signal are not transmitted at the same time. Therefore, the fifth filter 21 and the sixth filter in FIG. Even if at least one of the filter 22, the fifteenth filter 39, and the sixteenth filter 40 is eliminated, the advantageous effects of the communication device of the present invention can be maintained. Thereby, the circuit scale of the communication device can be reduced, and the communication device can be downsized.

  Further, since the IF signal is differentially transmitted, the characteristics of each filter are designed so that the symmetry of the transmission line through which the IF signal is transmitted is maintained.

  The electronic device 27 is connected to the communication device 1 and the output side of the communication device 1, and the video processing unit 25 to which the demodulated television signal from the communication device 1 is input and the video processing unit 25 decodes the electronic device 27. And a display unit 26 to which a TV signal is input.

(Embodiment 2)
FIG. 2 is a block diagram of communication device 1 according to Embodiment 2 of the present invention. In addition, the same code | symbol is attached | subjected about the same site | part as FIG.

  The difference between the communication apparatus according to the second embodiment shown in FIG. 2 and the communication apparatus according to the first embodiment is that IF signals that are output signals of the first tuner 8 and the second tuner 9 are differentially transmitted. And the number of signal lines that electrically connect the first unit 2 and the third unit 3 is three.

  In the communication device 1 of FIG. 2, the output signal (IF signal) of the first tuner 8 is transmitted to the second unit 3 via only one first line 4 based on the ground potential of the second line 5. Is done. Further, the output signal (IF signal) of the second tuner 9 is transmitted to the second unit 3 through only one third line 6 with reference to the ground potential of the second line 5.

  In the communication apparatus 1 according to the second embodiment, since the IF signal is not differentially transmitted, the first balanced filter 12, the second balanced filter 14, the third balanced filter 13, and the fourth balanced filter in FIG. 2 are replaced with the ninth filter 41, the tenth filter 42, the eleventh filter 43, and the twelfth filter 44, which are not balanced, in FIG.

  A power voltage, an AGC signal for controlling the gain of the first variable gain amplifier 28, and channel clock data are superimposed on the first line 4, and a second variable gain amplifier is superimposed on the third line 6. An AGC signal for controlling the gain of 30 and channel data are superimposed.

  The second line 5 electrically connects the grounds of the first unit 2 and the second unit 3 together. Since the IF signal and the control signal are not superimposed on the signal line to which the ground is assigned as compared with the communication device 1 in FIG. 1, the first filter 17 required in the communication device 1 in FIG. The second filter 18 can be eliminated. Thereby, since the circuit scale can be reduced, the size of the communication device can be reduced.

  With the configuration shown in FIG. 2, it is possible to reduce the number of signal lines between the first unit 2 and the second unit 3 which conventionally required twelve to three, thereby improving the manufacturing efficiency of the communication device. It can be significantly improved. Moreover, compared with the conventional communication apparatus, the installation volume required at the time of attachment to a vehicle is small, and the effect that handling is easy is also acquired.

  In a system that does not need to transmit / receive signals when switching channels, the IF signal, the AGC signal, and the channel selection signal are not transmitted at the same time. Even if at least one of the filter 22, the fifteenth filter 39, and the sixteenth filter 40 is eliminated, the advantageous effects of the communication device of the present invention can be maintained. Thereby, the circuit scale of the communication device can be reduced, and the communication device can be downsized.

  In FIG. 2, the power supply voltage is superimposed on the first line 4. For example, a fourth line electrically connected between the first unit 2 and the second unit 3 is newly provided, It is good also as a structure which transmits a power supply voltage via a 4th track | line. As a result, noise caused by the control signal can be avoided from entering the power supply, and a power supply voltage with less noise can be supplied to, for example, the first tuner 8 and the second tuner 9. Can be improved.

  When the IF signals from the first tuner 8 and the second tuner 9 shown in FIG. 2 are output by differential transmission, an operational amplifier circuit 45 as shown in FIG. Transmission can be converted to single transmission.

  If the IF signals from the first tuner 8 and the second tuner 9 are used as differential transmission outputs, the signal amplitude values handled by the first tuner 8 and the second tuner 9 can be reduced. In manufacturing the tuner 9, it is possible to employ a fine process having a relatively low withstand voltage. This makes it possible to reduce the size of the communication device.

  In FIG. 2, when the electrical lengths of the first line 4 and the third line 6 are significantly different, a phase difference may be generated between the channel data and the channel clock data in the desired channel derivation circuit 38. . In this case, the desired channel deriving circuit 38 is expected to have a problem that a desired channel cannot be derived. This state will be described in detail with reference to FIGS. 4 (a) and 4 (b).

  The graph of FIG. 4A shows the waveforms of channel data and channel clock data with time on the horizontal axis. When the electrical lengths of the first line 4 and the third line 6 are significantly different from each other. This is a waveform at the time of input to the desired channel deriving circuit 38.

  At the time of output from the channel control circuit 37, there is no phase shift in the timing of the waveform of the channel data and the waveform of the channel clock data, but the electrical lengths of the first line 4 and the third line 6 are significantly different. As shown in FIG. 4A, a phase shift of the time interval D occurs in each waveform. For this reason, when synchronization is taken at the rising timing of the channel clock data and the channel data is sampled and read, a data read error may occur.

  In order to prevent this, the method used by the communication apparatus of the present invention will be described below.

  With respect to the channel clock data in FIG. 4A, the time when the channel clock data waveform first falls from the arbitrary time t0 is t1, and the time when the waveform clock data falls for the second time is t2. Similarly, for channel data, the time when the channel data waveform falls from time t0 is t3.

  The desired channel deriving circuit 38 derives a time interval T indicating the difference between the time t1 and the time t2 and indicating the cycle of the channel clock data waveform, and similarly, the difference between the time t1 and the time t3 and the channel clock data The time interval P indicating the phase delay amount of the channel data with respect to is derived, and the time interval D derived in (Equation 1) using these two time intervals is used as a correction value to avoid the above data reading error.

  Specifically, the desired channel deriving circuit 38 samples and reads the channel data at a timing shifted by the time interval D from the falling timing of the channel clock data waveform. As a result, the waveform timings of the channel data and the channel clock data can be aligned, so that data reading errors can be eliminated.

Here, in the embodiment of the present invention, an I ² C signal is used as an example of the control signal. In the above description, the phase of each of the channel data and the channel clock data is the communication protocol of the I ² C signal. An example of the operation corrected to comply is shown. Although details are omitted, as a generally known I ² C signal communication protocol, a bus start condition (indicating a state in which communication of the I ² C signal is started, with the clock kept at “H”, only data “L” The signal timing is determined such as “falling down to” and normal data transfer (data can be changed only when the clock is set to “L”).

  FIG. 4B shows the waveform of the channel clock data and the channel data after correcting the read timing of the channel data using the time interval D.

As apparent from FIG. 4B, the waveforms of the channel data and the channel clock data are corrected to the timing conforming to the communication protocol of the I ² C signal, and the channel data is changed from the first rising timing of the channel clock data. Sampled and correct data reading is possible.

In the above description, the phase difference of the control signal is corrected using the I ² C signal as an example. However, the present invention is not limited to this, and a correction method based on the actually used communication protocol is used instead. Thus, the same effect can be obtained.

  FIG. 5 is a diagram showing a state in which the communication device 1 of the present invention is arranged in a car. A film antenna 46 in which the first antenna 10 and the second antenna 11 shown in FIGS. 1 and 2 are formed by a method such as printing is attached to the upper region of the windshield. And the 1st unit 2 is arrange | positioned in the windshield upper area | region by the structure electrically supplied to the 1st antenna 10 and the 2nd antenna 11 which were formed in the film antenna 46. FIG. Specifically, the first unit 2 is covered with a resin case or the like, and is electrically connected to the first antenna 10 and the second antenna 11 via a power supply terminal exposed from the cover. The first unit 2 and the film antenna 46 are fixed by, for example, an adhesive.

  When the first antennas 10 and 11 are not balanced antennas but are unbalanced antennas such as monopole antennas, a ground element is required. For this reason, the communication device 1 normally has a ground member (not shown for convenience) that electrically connects the ground portion of the first unit 2 and the chassis (metal frame) of the car.

  In FIG. 5, the first unit 2 and the second unit 3 (not shown) built in the car navigation etc. are electrically connected by a signal line group 47. Further, the signal line group 47 is pushed into the space between the interior cushion and the chassis in the vehicle interior so as not to be seen by the passengers of the vehicle.

  As can be seen from FIG. 5, since the first unit 2 and the second unit 3 (not shown) are electrically connected by a signal line group 47 of about 5 m, the signal line group 47 is a conventional communication device. If the signal line group 47 is constituted by a large number of signal lines as described above, the space required to accommodate the signal line group 47 becomes large. In addition, the weight of the signal line group 47 is increased, and the fuel efficiency of the vehicle is deteriorated.

  On the other hand, the communication device 1 of the present invention can reduce the number of signal lines constituting the signal line group 47, so that it is easy to arrange the communication device in the vehicle and reduce the weight. It is possible to suppress the deterioration of the fuel consumption performance of the vehicle.

  The communication device of the present invention can reduce the number of signal lines that electrically connect the first unit and the second unit, can realize a communication device with high manufacturing efficiency, and can be used for an in-vehicle wireless signal communication device. Suitable for Further, in recent years, in the in-vehicle digital broadcast receiver, the number of tuners constituting the first unit has increased to four, and as many as 24 signal lines are used for the signal line group between the first unit and the second unit. The necessity has arisen, and the difficulty of attachment to a vehicle can be reduced by applying the communication apparatus of this invention to such a communication apparatus.

Block diagram of communication apparatus of the present invention Block diagram of communication apparatus of the present invention Circuit block diagram constituting the first unit of the present invention (A) Time chart before correction of channel data and channel clock data, (b) Time chart after correction of channel data and channel clock data The perspective view when the communication apparatus of this invention is attached to the car Block diagram of a conventional communication device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Communication apparatus 2 1st unit 3 2nd unit 4 1st track 5 2nd track 6 3rd track 7 4th track 8 1st circuit, 1st tuner 9 2nd circuit, 2nd tuner 10 1st antenna 11 2nd Antenna 12 First balanced filter 13 Third balanced filter 14 Second balanced filter 15 Fourth balanced filter 16 Third circuit, demodulating circuit 17 First filter 18 Second filter 19 Third filter 20 Fourth filter 21 First 5 filter 22 6th filter 23 7th filter 24 8th filter 25 Video processing unit 26 Display unit 27 Electronic equipment

Claims (9)

A first unit;
A first line, one line electrically connected to the first unit, and a second line;
A second unit electrically connected to the other of the first line and the second line,
The first unit includes a first circuit;
A first balanced filter that electrically connects the first circuit and each of the first line and the second line;
The second unit is
A second balanced filter in which the other one of the first line and the second line is electrically connected;
A third circuit to which the other of the second balanced filters is electrically connected,
The ground of the first unit is electrically connected between the first balanced filter and the first line via a first filter, and
The ground of the second unit is electrically connected to the vicinity of a connection point between the second balanced filter and the first line via a second filter,
The first control signal is input or output from between the first balanced filter and the second line via a third filter,
A communication device that inputs or outputs from between the second balanced filter and the second line via a fourth filter. The communication device according to claim 1,
The communication device further includes a third line, a fourth line, one of which is electrically connected to the first unit,
A second unit electrically connected to the other of the third line and the fourth line, and
The first unit further includes a second circuit;
A third balanced filter that electrically connects the second circuit, the third line, and the fourth line;
The second unit further includes:
The other of the third line and the fourth line is electrically connected to the other, and the other has a fourth balanced filter electrically connected to the third circuit,
The second control signal is input or output from between the third balanced filter and the third line via a fifth filter,
Input or output from between the fourth balanced filter and the third line through the sixth filter,
The third control signal is input or output from between the third balanced filter and the fourth line via a seventh filter,
A communication device that inputs or outputs from between the fourth balanced filter and the fourth line via an eighth filter. A first unit;
A first line, a second line, a third line, one of which is electrically connected to the first unit;
A second unit in which the other of each of the first line, the second line, and the third line is electrically connected;
The first unit includes a first circuit, a second circuit,
A ninth filter that electrically connects the first circuit and one of the first lines;
An eleventh filter electrically connecting the second circuit and one of the third lines;
The second unit is
A third circuit;
A tenth filter for electrically connecting the other of the first lines and the third circuit;
A twelfth filter electrically connecting the other of the third lines and the third circuit;
The ground of the first unit is electrically connected to the ground of the second unit via the second line,
The first control signal that operates at a frequency different from the output signal of the first circuit is supplied to the first line via the third filter of the first unit, or is output from the first line, Supplied to the first line through the fourth filter of the second unit, or output from the first line,
The second control signal that operates at a frequency different from the output signal of the second circuit is supplied to the third line via the fifth filter of the first unit, or is output from the third line, The communication apparatus which supplies to the said 3rd track | line via the 6th filter which the said 2nd unit has, or is output from the said 3rd track | line. The diversity communication apparatus according to claim 2, wherein the first circuit includes a first tuner, the second circuit includes a second tuner, and the third circuit includes a demodulation circuit. The diversity communication apparatus according to claim 3, wherein the first circuit includes a first tuner, the second circuit includes a second tuner, and the third circuit includes a demodulation circuit. The first tuner includes a first variable gain amplifier;
The second tuner includes a second variable gain amplifier;
One of the first control signal and the second control signal is a first gain control signal for controlling the gain of the first variable gain amplifier, and the other control signal is the second control signal. A second gain control signal for controlling the gain of the variable gain amplifier;
The second unit includes a channel control circuit that generates a channel selection signal for selecting a frequency channel to be received.
The channel selection signal is composed of channel data and channel clock data,
The channel data is input to one of the first line and the third line in the second unit, and is output to a desired channel derivation circuit included in the first unit in the first unit. ,
The channel clock data is input in the second unit to the one of the first line and the third line to which the channel data is not input, and the desired channel of the first unit in the first unit. Output to the derivation circuit,
The desired channel deriving circuit derives a desired channel based on the input channel data and the channel clock data, and outputs a control signal to the first tuner and the second tuner so that the desired channel can be received. The communication device according to claim 5. The first tuner includes a first variable gain amplifier;
The second tuner includes a second variable gain amplifier;
One of the first control signal, the second control signal, and the third control signal is a first gain control signal for controlling the gain of the first variable gain amplifier, One of the control signals is a second gain control signal for controlling the gain of the second variable gain amplifier,
The second unit includes a channel control circuit that generates a channel selection signal for selecting a frequency channel to be received.
The channel selection signal is composed of channel data and channel clock data,
The channel data is input to any one of the second line, the third line, and the fourth line in the second unit, and the desired channel of the first unit in the first unit. Output to the derivation circuit,
The channel clock data is input to any one of the second line, the third line, and the fourth line to which the channel data is not input in the second unit, In one unit, it is output to a desired channel deriving circuit included in the first unit,
The desired channel deriving circuit derives a desired channel based on the input channel data and the channel clock data, and outputs a control signal to the first tuner and the second tuner so that the desired channel can be received. The communication apparatus according to claim 4. Deriving a time difference between an arbitrary rising portion or an arbitrary falling portion in the signal waveform of the channel data and an arbitrary rising portion or an arbitrary falling portion in the signal waveform of the channel clock data;
8. The communication device according to claim 6, wherein when performing data sampling of the channel data based on the channel clock data, the data sampling is performed by shifting the time difference. 9. The communication device according to any one of claims 1 and 3,
A video processing unit connected to the output side of the communication device;
An electronic apparatus comprising: a display unit connected to an output side of the video processing unit.

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