JP2010034980A - Integral receiving system, antenna device, and demodulation apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an integral receiving system reducing an increase in wire harnesses with extension of antenna devices. <P>SOLUTION: The integral receiving system includes: a plurality of antenna devices 20 disposed in the vicinity of an antenna 50 and each including a plurality of received signal processing sections 21 converting a high frequency signal received by the antenna 50 into a digital signal, a first digital modulation processing section 23 for modulating the high frequency signal on the basis of the converted digital signal, and a first communication processing section 24 for outputting the modulated high frequency signal to a transmission line 40; a demodulation apparatus 30 including a second digital demodulation processing section 31 for demodulating the high frequency signal transmitted from each of the antenna devices 20; and the common transmission line 40 connecting the antenna devices 20 and the demodulation apparatus 30. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an antenna device that receives a broadcast wave with an antenna, a demodulation device that demodulates a broadcast wave input from the antenna device, and an integrated reception system including the antenna device and the demodulation device.

  Signals received by multiple media such as AM, FM, and digital TV are digitized and multiplexed by an integrated antenna device as an antenna device provided immediately below the antenna, and then transmitted to an integrated demodulation device as a demodulator. For example, Patent Document 1 discloses a receiving device that uses a serial data transmission cable as an integrated receiving system that demodulates with an integrated demodulating device. Although not described in the receiving device of Patent Document 1, an actual integrated receiving system requires a power supply line for supplying power from the integrated demodulating device to the integrated antenna device.

  FIG. 1 shows a configuration example of an integrated reception system when a plurality of antennas are provided close to each other.

  As shown in FIG. 1, the integrated reception system is configured by connecting an integrated antenna device 200 and an integrated demodulation device 300 via two serial lines and a power line.

  That is, the integrated antenna device 200 is disposed in the vicinity of a plurality of antennas 100 having different signal systems, and receives a plurality of reception signal processing units 211 to 21n that convert a high-frequency signal received by each antenna 100 into a digital signal. A multiplexing processing unit 220 that multiplexes the digital signals output from the signal processing units 211 to 21n, and the digital multiplexed signal multiplexed by the multiplexing processing unit 220 to the integrated demodulation device 300 via the first serial line 410. The control signal is received from the serial data transmission unit 230 to be transmitted and the integrated demodulator 300 via the second serial line 420, and the control signal is separated for each signal system and based on the separated control signal of each signal system. And a control data receiving unit 240 for controlling the received signal processing units 211 to 21n and the like.

The integrated demodulator 300 also receives a serial data receiver 310 that receives a digital multiplex signal transmitted from the integrated antenna device 200 via the first serial line 410, and receives the received digital multiplex signal as a received digital signal for each signal system. A separation processing unit 320 that separates the received digital signals into signals, a demodulation unit 330 that demodulates each received digital signal separated by the separation processing unit 320 and outputs the demodulated signal to a DSP (Digital Signal Processor), etc., and an integrated antenna via the second serial line 420 Supplied from a control data sending unit 340 that outputs a control signal to the apparatus 200, a control unit 350 that receives and outputs a control signal composed of a reception frequency designation signal and the like from an operation unit that designates a reception frequency, and the like The received power is stepped up or down to a predetermined voltage and output to the integrated antenna device 200 through the power line 430. And it includes a source unit 360.
WO2007 / 058341

  In the configuration example of FIG. 1, there is one integrated antenna device. However, when signals are received by a diversity method or the like, it is necessary to provide antennas at a plurality of locations that are not close to each other. In that case, the integrated reception system needs to include a plurality of integrated antenna devices to be arranged in the vicinity of the antenna.

  Then, as shown in FIG. 2, for each of the integrated antenna devices 2001 to 200 m and the integrated demodulator 300, serial lines 4101 to 410 m from the integrated antenna devices 2001 to 200 n to the integrated demodulator 300, the integrated demodulator A serial line 4201 to 420m from 300 to each integrated antenna device and a power line 430 from the integrated demodulator 300 to the integrated antenna device are required. That is, as the number of integrated antenna devices 200 increases, the number of wire harnesses increases.

  Therefore, in the integrated reception system, it is difficult to add an integrated antenna device, and there is a possibility that a flexible system configuration cannot be performed. Further, when the integrated reception system is mounted on a vehicle or the like having a limited mounting space, the mounting is difficult.

  In view of the above-described conventional problems, an object of the present invention is to reduce the increase in wire harnesses accompanying the increase in the number of antenna devices, and to improve the flexibility of the system configuration and the mountability in a limited space. The object is to provide a reception system, an antenna device, and a demodulation device.

  In order to achieve the above-described object, the characteristic configuration of the integrated reception system according to the present invention includes a reception signal processing unit that is disposed in the vicinity of an antenna and converts a high-frequency signal received by the antenna into a digital signal, and the reception signal processing A first digital modulation processing unit that modulates a high-frequency signal based on a digital signal output from the unit, and a first communication processing unit that outputs the high-frequency signal modulated by the first digital modulation processing unit to a transmission line A plurality of antenna devices, a demodulator including a second digital demodulation processing unit that demodulates a high-frequency signal transmitted from each antenna device via the transmission line, and a common connection between each antenna device and the demodulator Transmission line.

  According to the above-described configuration, the first communication processing unit transmits / receives the high-frequency signal modulated by the first digital modulation processing unit, the high-frequency signal transmitted from another antenna device, and the high-frequency signal transmitted from the demodulation device. By controlling the timing and the like, it is possible to transmit a high-frequency signal through a common transmission line.

  And by transmitting a high frequency signal with a common transmission line, it is not necessary to increase the number of wire harnesses even if the number of antenna devices is increased.

  As described above, according to the present invention, there is provided an integrated reception system capable of reducing the increase in wire harness accompanying the increase in the number of antenna devices and improving the flexibility of the system configuration and the mountability in a limited space. I was able to do that.

  Hereinafter, an embodiment in which an integrated reception system, an integrated antenna device as an antenna device, and an integrated demodulation device as a demodulation device according to the present invention are applied to a vehicle will be described.

  As shown in FIG. 3, the integrated reception system 1 includes a plurality of integrated antenna devices 20 (201 to 20 n), an integrated demodulator 30, and a common transmission line 40 to which each integrated antenna device 20 and the integrated demodulator 30 are connected. And.

  Each integrated antenna device 20 is arranged in the vicinity of a plurality of antennas 50 having different signal systems, and a plurality of reception signal processing units 21 that convert high-frequency signals received by the respective antennas 50 into digital signals, and each reception signal processing unit. A multiplexing processing unit 22 that multiplexes digital signals output from the first digital modulation processing unit 22; a first digital modulation processing unit 23 that modulates a high-frequency signal based on the digital signals multiplexed by the multiplexing processing unit 22; And a first communication processing unit 24 that outputs the high-frequency signal modulated by the modulation processing unit 23 to the transmission line. The first communication processing unit 24 will be described later.

  As shown in FIG. 4, the reception signal processing unit 21 includes a high frequency amplification unit 211 that amplifies the high frequency signal received by each antenna 50, a frequency conversion unit 212 that converts the amplified high frequency signal into an intermediate frequency signal, an intermediate frequency A band-pass filter 213 that passes a signal of a desired frequency component of the signal, an A / D converter 214 that converts an output signal of the band-pass filter 213 into a digital signal, an orthogonal transform unit 215 that will be described below, and an orthogonal transform Downsampling units DS (I) and DS (Q) for downsampling the I and Q components of the digital signal output from the unit 215 are provided. For a signal with a narrow band such as AM broadcasting, the dynamic range can be increased by sampling at a high speed and then down-sampling rather than sampling at a low speed.

  As shown in FIG. 5, the orthogonal transform unit 215 includes an oscillator 215A that generates a signal having the same frequency as the input digital signal, a phase shifter 215B that shifts the output signal of the oscillator 215A by 90 degrees, and the digital A product of the signal and the output signal of the oscillator 215A to output the I component of the quadrature signal, and the digital signal and the output signal of the phase shifter 215B to multiply the Q component of the quadrature signal. The mixer 215D for output and the low-pass filter 216 provided in each of the output stages of the mixers 215C and 215D are configured, and the I component of the orthogonal component of the digital signal output from the mixers 215C and 215D And the Q component are input to the down-sampling units DS (I) and DS (Q) through low-pass filters 215C and 215D, respectively.

  The multiplexing processing unit 22 assigns the I component and Q component of a plurality of digital signals input via the reception signal processing unit 21 corresponding to each antenna 50 to a transfer block set in a predetermined format. In the predetermined format, for example, a header is allocated to an area corresponding to the first predetermined bit of the transfer block, and the data of the digital TV broadcast channel 1 (first signal system) and the digital TV broadcast channel 2 (first) are sequentially described below. Second signal system) data, FM broadcast channel 1 (third signal system) data, FM broadcast channel 2 (fourth signal system) data, and AM broadcast (fifth signal system) data Is a format in which high-frequency signals equivalent to the above are assigned to areas corresponding to predetermined bits set for each signal system.

  Up to this point, the case where there are a plurality of antennas 50 and reception signal processing units 21 has been described. However, in the present invention, as shown in FIG. The antenna device 20 without the part 22 may be used.

  That is, the antenna device 20 is disposed in the vicinity of the antenna 50, based on the reception signal processing unit 21 that converts a high-frequency signal received by the antenna 50 into a digital signal, and the digital signal output from the reception signal processing unit 21. A first digital modulation processing unit 23 that modulates a high-frequency signal and a first communication processing unit 24 that outputs the high-frequency signal modulated by the first digital modulation processing unit 23 to a transmission line are provided.

  In this case, since the antenna device 20 does not include the multiplexing processing unit 22, the first digital modulation processing unit 23 is a high-frequency signal based on the digital signal output from the reception signal processing unit 21 instead of the multiplexing processing unit 22. Modulate. In the following description, as described above, when there are a plurality of antennas 50 and reception signal processing units 21, that is, the first digital modulation processing unit 23 is a high-frequency signal based on the digital signal multiplexed by the multiplexing processing unit 22. A case where the signal is modulated will be described.

  As shown in FIG. 6A, the first digital modulation processing unit 23 divides transmission data from the multiplexed transmission unit 22 every predetermined number of bits, and the predetermined number of bits of transmission data are set in advance. A mapping unit 231 that divides and outputs the signal level of the I component and the Q component based on the signal level, and an orthogonal modulation unit 232 that converts the signal level of the I component and the Q component output from the mapping unit 231 into a high frequency. Yes.

  The first digital modulation processing unit 23 performs modulation by, for example, 16-value quadrature amplitude modulation (QAM (Quadrature Amplitude Modulation)). In this case, the data map of the mapping unit 231 is configured by an IQ constellation in which the signal levels of the I component and the Q component are (+3, +1, -1, -3) as shown in FIG. The mapping unit 231 uses the I-Q constellation with the first 2 bits of the data obtained by dividing the transmission data from the multiplexed transmission unit 22 every 4 bits as a predetermined number of bits as the I component and the second 2 bits as the Q component. To calculate the signal level of each component.

  Each signal level is a relative value, and may be (+1, +1/3, -1/3, -1), for example. Further, the modulation by the first digital modulation processing unit 23 is not limited to 16-value QAM, and may be 64-value QAM, 256-value QAM, or the like.

  The quadrature modulation unit 232 outputs an oscillator 236 that generates a signal of a predetermined frequency, a phase shifter 233 that shifts the output signal of the oscillator 236 by 90 degrees, and a mapping unit 231 in order to convert each input component into a high frequency. A mixer 234 that multiplies and outputs the Q component and the output signal of the oscillator 236, and a mixer 235 that multiplies and outputs the I component output from the mapping unit 231 and the output signal of the phase shifter 233. And an adder 236 for adding the outputs of the mixers 234 and 235.

  The high frequency signal modulated by the first digital modulation processing unit 23 is input to the first communication processing unit 24 via the high frequency transmission unit 26. Here, the high-frequency transmission unit 26 includes an amplifier that amplifies the high-frequency signal modulated by the first digital modulation processing unit 23 to a predetermined level. The predetermined level is a level at which a signal within a predetermined range can be output from the transmission line 40 when the high-frequency signal is output from the transmission line 40 through processing (described later) in the first communication processing unit 24. It is.

  Each integrated antenna device 20 includes a first digital demodulation processing unit 25 that demodulates a high-frequency signal input via the transmission line 40 and generates a control signal for each reception signal processing unit 21.

  The first digital demodulation processing unit 25 is received from the integrated demodulation device 30 via the transmission line 40 and input via the first communication processing unit 24 and the high frequency receiving unit 27 as shown in FIG. A quadrature demodulator 251 that separates a high frequency signal into an I component and a Q component, and a predetermined number of bits of received data based on a preset data map of the I component and Q component high frequency signals output from the quadrature demodulator 251 And a demapping unit 252 for generating and outputting.

  Here, the high frequency receiving unit 27 is configured by an amplifier that amplifies the high frequency signal output from the first communication processing unit 24 to a predetermined level. Here, the predetermined level is a level at which the first digital demodulation processing unit 25 can appropriately demodulate the control signal as the baseband signal from the high-frequency signal.

  The quadrature demodulator 251 separates the input high-frequency signal into an I component and a Q component, and an oscillator 252 that generates a signal having a predetermined frequency, a phase shifter 253 that shifts the output signal of the oscillator 252 by 90 degrees, and an input A mixer 254 that multiplies the high-frequency signal and the output signal of the oscillator 252 and outputs it as a Q component of the high-frequency signal, and multiplies the input high-frequency signal and the output signal of the phase shifter 253 to multiply the high-frequency signal I And a mixer 255 for outputting as a component.

  Similar to the first digital modulation processing unit 23, the first digital demodulation processing unit 25 performs demodulation using, for example, a 16-value QAM system. In this case, the data map of the demapping unit 252 is composed of an IQ constellation shown in FIG. The demapping unit 252 divides the signal level of the high frequency signal output from the quadrature demodulation unit 251 into one of four levels (+3, +1, −1, −3), respectively. Above, when the level of the I component is the I axis of the IQ constellation and the level of the Q component is the Q axis of the IQ constellation, control the 4-bit data corresponding to the coordinates A signal is generated and output to the control data analysis unit 28. The control data analysis unit 28 will be described later.

  As with the mapping unit 231, each signal level is a relative value, and may be (+1, +1/3, -1/3, -1), for example. Further, the demodulation by the first digital demodulation processing unit 25 is not limited to 16-value QAM, and may be 64-value QAM, 256-value QAM, or the like.

  According to the above-described configuration, the integrated antenna device 20 includes the first digital modulation processing unit 23 that modulates the high-frequency signal based on the reception signal (baseband signal) from the antenna 50, thereby converting the baseband signal into the high-frequency signal. The first digital demodulation processing unit 25 that demodulates the baseband signal from the high-frequency signal input from the integrated demodulator 30 via the transmission line 40 as well as being output to the transmission line 40 by being superimposed on the A baseband signal superimposed on the signal can be input from the transmission line 40.

  The integrated demodulator 30 demodulates the high frequency signal transmitted from each integrated antenna device 20 via the transmission line 40, and the digital signal demodulated by the second digital demodulator 31 And a separation processing unit 32 that separates the digital signals for each system.

  The second digital demodulation processing unit 31 has the same configuration as the first digital demodulation processing unit 25 shown in FIG. However, the second digital demodulation processing unit 31 receives a high-frequency signal from the high-frequency receiving unit 37 provided in the integrated demodulation device 30, and the second digital demodulation processing unit 31 receives a predetermined signal generated by the demapping unit. Several bits of received data are output to the separation processing unit 32.

  Here, the high frequency receiving unit 37 has the same configuration as the high frequency receiving unit 27 provided in each integrated antenna device 20. However, the predetermined level amplified by the high frequency receiving unit 37 is multiplexed as a baseband signal from the high frequency signal transmitted from each integrated antenna device 20 via the transmission line 40 in the second digital demodulation processing unit 31. The level is such that the digital signal can be demodulated properly.

  The separation processing unit 32 includes a first separation processing unit that separates the digital signal demodulated by the second digital demodulation processing unit 31 into a digital signal corresponding to each of the plurality of integrated antenna devices 20, and a multiplexing processing unit 22. The digital signal data that has been multiplexed is subjected to processing opposite to that performed by the multiplexing processing unit 22, so that the integrated antenna device 20 separates the data for each signal system of the same type as when received from each antenna 50. And a separation processing unit. Each digital signal separated by the separation processing unit 32 is output to a demodulation processing unit 38 corresponding to each signal system.

  As shown in FIG. 17, when each antenna device 20 does not include the multiplexing processing unit 22, the separation processing unit 32 does not include the second separation processing unit.

  Each demodulation processing unit 38 demodulates each digital signal separated for each signal system by the separation processing unit 32 and outputs the demodulated signal to a DSP or the like connected to the subsequent stage side of the integrated demodulation device 30.

  So far, the description has been given of the case where the demodulating device 30 transmits and receives to / from the antenna device 20 connected to the multiple systems of antennas 50. However, in the present invention, as shown in FIG. The configuration may be such that the antenna device 20 connected to the antenna 50 is transmitted and received. In this case, the demodulation processing unit 38 is one system. In addition, the following description demonstrates the case where the demodulation apparatus 30 transmits / receives with the antenna apparatus 20 connected with the antenna 50 of multiple systems like said d.

  The integrated demodulation device 30 includes a control unit 33 that generates a control signal for each integrated antenna device 20, a second digital modulation processing unit 34 that modulates a high-frequency signal based on the control signal generated by the control unit 33, and a second A second communication processing unit 35 that outputs the high-frequency signal modulated by the digital modulation processing unit 34 to the transmission line 40 is provided. The second communication processing unit 35 will be described later.

  The control unit 33 converts various data such as reception frequency, reception bandwidth, down-sampling parameters, orthogonal transform frequency, and transmission format into a control signal that is collected, and outputs the control signal to the second digital modulation processing unit 34. To do.

  Here, various data are set by a user operating an operation unit or the like of a navigation device mounted on the vehicle, and input to the control unit 33 from the navigation device or the like.

  The reception frequency is used for channel selection by the frequency conversion unit 212 of each integrated antenna device 20.

  The reception bandwidth is used by the bandpass filter 213 of each integrated antenna device 20 to set the bandwidth.

  The downsampling parameter is, for example, a value indicating the decimation ratio and the number of stages of the low-pass filter, a coefficient value indicating the characteristic, and the like, and is used in the downsampling units DS (I) and DS (Q) of each integrated antenna device 20.

  The orthogonal transform frequency is used by the orthogonal transform unit 215 of each integrated antenna device 20 in order to set an oscillation frequency for orthogonal transform.

  The transmission format indicates the number of bits of one sample of the received signal, the data transmission order, the number of dummy data, and the like, and is used by the multiplexing processing unit 22 of each integrated antenna device 20.

  These various data are transmitted from the integrated demodulation device 30 to each integrated antenna device 20. The high frequency signal transmitted to each integrated antenna device 20 is input to the first digital demodulation processing unit 25 via the first communication processing unit 24 and the high frequency reception unit 27, and demodulated into a control signal by the first digital demodulation processing unit 25. And input to the control data analysis unit 28.

  The control data analysis unit 28 converts the input control signal into various types of data (reception frequency, reception bandwidth, downsampling parameters, orthogonal transform frequency, transmission format, etc.) for each signal system, and handles various types of data. Output to signal system and corresponding functional block. For example, the reception frequency is the frequency conversion unit 212, the reception bandwidth is the band pass filter 213, the downsampling parameters are the downsampling units DS (I) and DS (Q), the orthogonal transformation frequency is the orthogonal transformation unit 215, and the transmission format is multiplexed. The data is output to the processing unit 22.

  Each data is not limited to the above. For example, the control unit 33 inputs the gain control data of each signal system from each demodulation processing unit 38 and transmits the gain control data to the control data analysis unit 28, and the control data analysis unit 28 transmits the gain control data to each received signal processing unit 21. Gain control can also be performed by outputting to the high-frequency amplifier 211.

  The second digital modulation processing unit 34 has the same configuration as the first digital modulation processing unit 23 shown in FIG. However, the control signal from the control unit 33 is input to the second digital modulation processing unit 34, and the high frequency signal generated by the quadrature modulation unit is output from the second digital modulation processing unit 34 to the high frequency transmission unit 39. The

  The high frequency transmission unit 39 has the same configuration as the high frequency transmission unit 26 of each integrated antenna device 20. However, the predetermined level amplified by the high-frequency transmission unit 39 is a signal within a predetermined range when the high-frequency signal is output from the transmission line 40 through processing (described later) in the second communication processing unit 35. Can be output from the transmission line 40.

  According to the above-described configuration, the integrated demodulator 30 includes the second digital demodulation processing unit 31 that demodulates the baseband signal from the high-frequency signal input from each integrated antenna device 20 via the transmission line 40, thereby A baseband signal superimposed on the signal can be input from the transmission line 40, and a second digital modulation processing unit 34 that modulates a high-frequency signal based on various data (control signals) from a navigation device or the like is provided. Thus, the baseband signal can be superimposed on the high frequency signal and output to the transmission line 40.

  The integrated demodulator 30 also includes a power feeding unit 36 that superimposes a DC voltage to be fed to each integrated antenna device 20 on a high-frequency signal transmitted to each integrated antenna device 20 via the transmission line 40.

  The power feeding unit 36 includes a constant voltage power source that outputs a predetermined constant voltage (for example, 12 V) by stepping down or boosting a voltage input from a vehicle battery or the like. The constant voltage output from the power feeding unit 36 Is superimposed on the high-frequency signal output from the integrated demodulator 30 to the transmission line 40 via the low-pass filter 361.

  According to the above-described configuration, the voltage output from the power feeding unit 36 is superimposed on the high frequency signal and transmitted via the transmission line 40. Therefore, it is necessary to separately provide a power line for feeding power to each integrated antenna device 20. Absent.

  The transmission line 40 is composed of a plurality of coaxial cables 401 to 40m provided with connectors 41 at both ends, and the integrated demodulation device 30 and each integrated antenna device 20 are connected in cascade with each coaxial cable 401 to 40m. A coaxial cable 40 m connected to the stage integrated antenna device 20 n is connected to the terminator 60.

  In FIG. 3, each integrated antenna device 20 is provided with two connector insertion ports 42, and one of the integrated demodulation device 30 and the other integrated antenna device 20 is connected to one insertion port and the other insertion port. Is done.

  In addition, each coaxial cable 40 is configured such that each coaxial cable 40 can be extended without connecting the integrated antenna device 20 or the integrated demodulator 30 by connecting the connectors 41 of the coaxial cables 40 to each other.

  The terminator 60 is constituted by a termination resistor having a predetermined resistance value (for example, 50Ω or 75Ω), for example.

  In FIG. 3, the integrated demodulator 30 is connected to a terminal that is not connected to the terminator 60 and has only one insertion port. You may connect to a position that is not.

  Each transmission line 40, that is, a plurality of coaxial cables 401 to 40m, is mounted on the back side of each interior of the vehicle and on the back side of the interior decorative panel. The connector 41 is mounted in the vicinity of the installation location.

  For example, as shown in FIGS. 8A and 8B, each coaxial cable 40 is connected to the back side of the decorative panel, the lower part of the front window, the pillar, from the integrated demodulator 30 provided near the decorative panel of the vehicle. (The front pillar and the rear pillar in FIG. 8), the front window, the roof side, and the rear window are wired to a terminator 60 provided near the rear window of the vehicle along the rear side of the interior.

  The black circles in FIG. 8 indicate the connection of the connectors 41 of the two different coaxial cables 40. Of the wiring of the coaxial cables 40, only the portion of the connector 41 is arranged at a position where it is easy to work in the vehicle interior machine. Then, as shown in FIG. 8B, each integrated antenna device 20 is connected to a connector 41 arranged at a position where it is easy to work, and at least one antenna 50 is connected to each integrated antenna device 20. In FIG. 8B, the black circle to which the integrated antenna device 20 is not connected indicates the connection between the future antenna 50 and the connector 41 provided for expansion of the integrated antenna device 20.

  As the antenna 50 and the integrated antenna device 20 mounted on the vehicle, there are digital TV (DTV), FM, AM, and FM and AM sharing, but digital audio broadcasting, GPS reception, The satellite broadcasting antenna 50 and the integrated antenna device 20 may be mounted. Further, the integrated antenna device 20 (and the antenna 50 connected to the integrated antenna device 20) is connected to a connector 41 provided for expansion of the future antenna 50 and the integrated antenna device 20 even if it is not currently mounted on the vehicle. It can also be connected.

  Further, the antenna 50 and the integrated antenna device 20 for communication such as road-to-vehicle communication and vehicle-to-vehicle communication may be mounted on the vehicle. That is, the integrated reception system, integrated antenna device 20 and integrated demodulation device 30 according to the present invention can be used not only for reception from the antenna 50 but also for transmission.

  According to the above-described configuration, an integrated reception system including the common transmission line 40 to which each integrated antenna device 20 and the integrated demodulation device 30 are connected can be specifically realized using the coaxial cable 40.

  In addition, by providing the connectors 41 at both ends of each coaxial cable 40, when the integrated antenna device 20 is not connected, the connectors 41 are connected to each other and the coaxial cables 40 are connected as described above. When the connector 41 is connected, it is possible to remove the connected connector 41 and connect each removed connector 41 to each insertion port 42 of the integrated antenna device 20. That is, it is possible to realize an integrated reception system having a high system configuration in which the integrated antenna device 20 can be easily added or removed.

  Hereinafter, the first communication processing unit 24 and the second communication processing unit 35 will be described in detail.

  The high frequency signal output from the second communication processing unit 35 is transmitted to the first communication processing unit 24 of each integrated antenna device 20 via the transmission line 40.

  The first communication processing unit 24 includes a high-frequency coupling unit 241 that attenuates a high-frequency signal transmitted from the transmission line 40 by a predetermined attenuation amount.

  For example, as shown in FIGS. 9A and 9B, the high-frequency coupling unit 241 has one end connected to the transmission line 40 and the other end connected to a transmission / reception control unit 242 described later, and the other end to the transmission line 40. And a resistor R2 that is grounded at the other end. In FIG. 9, a capacitor for removing the DC component is inserted.

  With this configuration, when a high frequency signal is input from the integrated demodulation device 30 to the integrated antenna device 20 via the transmission line 40, the high frequency signal input to the high frequency coupling unit 241 is illustrated in FIG. Instead of being attenuated by a predetermined amount on the path A and outputting to the transmission / reception control unit 242, the path B shown in FIG. 9 (a) has an attenuation much smaller than the attenuation, that is, connected in cascade without substantial attenuation. Can be output to the integrated antenna device 20. As a result, it is possible to reduce the adverse effect of transmission signal attenuation caused by cascading a large number of integrated antenna devices.

  Further, when a high frequency signal is output from the integrated antenna device 20 to the integrated demodulation device 30 via the transmission line 40, the route C shown in FIG. 9B can be output with substantially the same amount of attenuation as the route A.

  This will be described in detail below. For example, a case where the characteristic impedance Zo of the coaxial cable is 50 (Ω), the resistance R1 is 450 (Ω), and the resistance R2 is 50 (Ω) will be described.

  First, a case where a high frequency signal of −20 (dBm) is input from the integrated demodulation device 30 to the integrated antenna device 20 will be described with reference to FIG.

In FIG. 9A, the voltage at the position P1, which is the output side of the high frequency signal, is 1/10 of the voltage at the position P2, which is the input side, from the following formula 1. Therefore, the attenuation amount in the path A is −20 (dB) from the following formula 2.

  Accordingly, the input high frequency signal of −20 (dBm) is output to the transmission / reception control unit 242 as a high frequency signal of −40 (dBm) attenuated by −20 (dB).

Further, since the attenuation amount in the path A is −20 (dB), the ratio of the power Po output to the transmission / reception control unit 242 to the power Pi input from the insertion port 42A via the transmission line 40 (Po / Pi) is 0.01 from the following equation (3).

Therefore, the power output from the other insertion port 42B to the other integrated antenna device 20 via the transmission line 40 is the power obtained by removing the output power Po from the input power Pi. That is, it is attenuated by −0.04 (dB) from the following formula 4 to −20.04 (dBm).

  From the above description, the attenuation amount is -20 (dB), and the attenuation amount significantly smaller than the attenuation amount is -0.04 (dB).

  Next, a case where a high frequency signal of −17 (dBm) is output from the integrated antenna device 20 to the integrated demodulation device 30 will be described with reference to FIG.

In FIG. 9B, the voltage at the position P4 on the output side of the high-frequency signal is 1/10 from the following formula 5 with respect to the voltage at the position P3 on the input side. Therefore, the attenuation amount in the path C is −20 (dB) from the following formula 6.

  Accordingly, the input high frequency signal of −17 (dBm) is output to the transmission line 40 as a high frequency signal of −37 (dBm) attenuated by −20 (dB). Here, since there are two high-frequency signal output paths, the path through the insertion port 42A and the path through the insertion port 42B, the power output to each path is halved. That is, the power output to each path is −3 (dB) to −40 (dBm).

  The above description is an example. That is, the input high frequency signal is not limited to −20 (dBm) or −17 (dBm), and the predetermined attenuation is not limited to −20 (dBm). Then, the value of each element (for example, the resistance value of the resistor) used in the high-frequency coupling unit is appropriately determined according to the power and attenuation amount of a desired input / output high-frequency signal.

  Further, as shown in FIGS. 9A and 9B, the high-frequency signal input to the high-frequency coupling unit 241 is input to the high-frequency coupling unit 241 by superimposing only the DC component, that is, the high-frequency signal, in the low-pass filter 29. Only the DC voltage obtained is taken out, and the DC voltage is used for feeding power to each part of the integrated antenna device 20.

  The first communication processing unit 24 and the second communication processing unit 35 include transmission / reception control units 242 and 351 that transmit and receive each high-frequency signal in a time division duplex (TDD) system.

  As shown in FIG. 10A, the transmission / reception control unit 242 and the transmission / reception control unit 351 are configured by switches composed of FETs or the like. FIG. 10A shows the transmission / reception control unit 242. In the case of the TDD scheme configuration, the control signal transmitted from the integrated demodulator 30 to each integrated antenna device 20 includes a switch control signal for switching the switch. As indicated by a one-dot chain line in FIG. 3, the control unit 33 controls the transmission / reception control unit 351, and the control data analysis unit 28 controls the transmission / reception control unit 242 based on the switch control signal. The switch control signal is transmitted / received so that the transmission / reception controller 242 receives when the transmission / reception controller 351 transmits, and the transmission / reception controller 242 transmits when the transmission / reception controller 351 receives. A signal for controlling the control unit 242.

  The switch as the transmission / reception control unit 242 is based on the switch control signal transmitted from the control data analysis unit 28, and is a path through which a high frequency signal is transmitted from the high frequency transmission unit 26 to the high frequency coupling unit 241 (ie, integrated from the integrated antenna device 20). (Transmission to the demodulator 30) and a path through which a high-frequency signal is transmitted from the high-frequency coupling unit 241 to the high-frequency receiver 27 (that is, reception from the integrated demodulator 30 to the integrated antenna device 20) can be switched at high speed. Realize apparent simultaneous transmission and reception.

  The switch as the transmission / reception control unit 351 is configured to transmit a high-frequency signal from the connector 42 to the high-frequency receiving unit 37 based on control by the control unit 33 (that is, reception from each integrated antenna device 20 to the integrated demodulation device 30). The apparent simultaneous transmission / reception is realized by switching at high speed the path through which the high-frequency signal is transmitted from the high-frequency transmission unit 39 to the connector 42 (that is, transmission from the integrated demodulation device 30 to each integrated antenna device 20).

  Further, the control signal transmitted from the integrated demodulator 30 to each integrated antenna device 20 includes a signal for identifying which integrated antenna device 20 is the signal, and transmits the signals in time order. Thereby, transmission from the integrated demodulation device 30 to each integrated antenna device 20 realizes TDM (Time Division Multiplex).

  Signals transmitted from each integrated antenna device 20 to the integrated demodulation device 30 are integrated and demodulated from each integrated antenna device 201 to 20n in a time period controlled so that the transmission / reception control unit 351 receives and the transmission / reception control unit 242 transmits. A predetermined amount of high-frequency signal is transmitted to the device 30 in a time-sharing manner. Thereby, the transmission from each integrated antenna device 20 to the integrated demodulation device 30 realizes TDMA (Time Division Multiple Access).

  For example, FIG. 11A is a diagram of signal paths and power distribution on the time axis to which TDD and TDM / TDMA are applied. The integrated demodulator (referred to as H / U: Head Unit in FIG. 11) and each integrated antenna device (referred to as ACU: Antenna Control Unit in FIG. 11) are divided in order of the target ACUs on the time axis during transmission / reception. The one cycle is set, for example, from several tens (μs) to several (ms) depending on the antenna 50 and the necessary data amount.

  According to the above-described configuration, it is not necessary to individually connect the integrated demodulator 30 to each of the plurality of integrated antenna devices 20, and thus it is possible to prevent an increase in wire harness due to the addition of the integrated antenna device 20. .

  Hereinafter, another embodiment will be described. In the above-described embodiment, the case where the high-frequency coupling unit 26 is configured with a resistor as illustrated in FIG. 9 has been described, but the high-frequency coupling unit 26 may be configured with a resistor other than the resistor.

  For example, as shown in FIG. 12A, capacitors C1 and C2 are used instead of the resistors R1 and R2, and coils L1 and L2 are used instead of the resistors R1 and R2 as shown in FIG. As shown in FIG. 13A, the high-frequency coupling unit 26 may be a high-pass filter composed of a capacitor and a coil. In these cases as well, when the resistors R1 and R2 are used, the capacitance of the capacitor and the inductance of the coil are appropriately determined according to the power and attenuation of the desired input / output high-frequency signal.

  Moreover, the high frequency coupling unit 241 may be configured with a directional coupler. As the directional coupler, a distributed coupled directional coupler, a lumped constant directional coupler, or the like is used.

  For example, as shown in FIG. 13B, two microstrip lines 243 having a length that is a quarter of the waveform of the high-frequency signal transmitted and received by the integrated antenna device 20 provided with the directional coupler are parallel to each other. By arranging, the amount of attenuation between the insertion ports a and b can be reduced, and the amount of attenuation between the insertion ports a and b and the transmission / reception control unit 242 can be increased. That is, the high-frequency coupling unit 241 configured with a directional coupler has the same effects as those in FIGS. 9, 12, and 13 (a). Note that the interval between the microstrip lines, the characteristic impedance, and the like are appropriately determined according to the power and attenuation of the desired input / output high-frequency signal.

  In the above-described embodiment, the first communication processing unit 24 and the second communication processing unit 35 have been described with respect to the case of multiplexing by TDD / TDM / TDMA. The unit 35 may perform multiplexing using a duplex scheme based on FDD (Frequency Division Duplex) or FDM (Frequency Division Multiplex) / FDMA (Frequency Division Multiple Access).

  For example, the frequency transmitted from each integrated antenna device 20 to the integrated demodulator 30 is set higher than the frequency transmitted from the integrated demodulator 30 to each integrated antenna device 20.

  In this case, for example, as shown in FIG. 10B, the transmission / reception control unit 242 passes a transmission high-frequency signal between the high-frequency transmission unit 26 and the high-frequency coupling unit 241 (in FIG. 10B, a high-pass filter: 2421 and a filter (referred to as a low-pass filter: LPF in FIG. 10B) 2422 that passes the received high-frequency signal between the high-frequency receiving unit 27 and the high-frequency coupling unit 241.

  On the other hand, for example, as shown in FIG. 10C, the transmission / reception control unit 351 is a filter that allows the transmission high-frequency signal to pass between the high-frequency receiving unit 37 and the connector 42 (in FIG. 10C, a high-pass filter: HPF). 3511, and a filter (indicated as a low-pass filter: LPF in FIG. 10B) 3512 that passes the received high-frequency signal between the high-frequency transmitter 39 and the connector 42.

  Thereby, a high frequency band is used for the frequency of the signal transmitted from each integrated antenna device 20 to the integrated demodulation device 30, and a low frequency band is used for the frequency of the signal transmitted from the integrated demodulation device 30 to each integrated antenna device 20. Thus, FDD can be realized.

  Further, regarding the transmission signal from the integrated demodulator 30 to each integrated antenna device 20, a plurality of high-frequency transmitters 39 have different frequencies depending on the ACU to be transmitted, and the high-frequency receiver 27 of each integrated antenna device 20 By changing the frequency to be received, transmission from the integrated demodulator 30 to each integrated antenna device 20 realizes FDM.

  Furthermore, with respect to the transmission signal from each integrated antenna device 20 to the integrated demodulation device 30, the frequency of the high-frequency transmission unit 26 is changed for each integrated antenna device 20, and the high-frequency receiving unit 37 of the integrated demodulation device 30 changes the reception frequency. By recognizing the target integrated antenna device 20 among the integrated antenna devices 20, transmission from each integrated antenna device 20 to the integrated demodulator 30 realizes FDMA.

  For example, FIG. 11B is a diagram of a signal path and power distribution on the frequency axis to which FDD and FDM / FDMA are applied. The integrated demodulator (referred to as H / U: Head Unit in FIG. 11) and each integrated antenna device (referred to as ACU: Antenna Control Unit in FIG. 11) transmit and receive, and the target ACU is delimited by the frequency axis, and necessary data. Depending on the amount, for example, a number (MHz) to a number (GHz) is set.

  The duplex method of transmission and reception may transmit and receive each high-frequency signal by a CDD (Code Division Duplex) method that shares transmission and reception by changing the sequence of spreading codes using spread spectrum. OFDMA, which is a modification of the CDMA (Code Division Multiple Access) method or FDMA method, which uses spread spectrum as a multiplexing method for distinguishing the integrated antenna device 20 that accesses the network, and multiplexes transmission and reception by changing the spreading code sequence Each high-frequency signal may be transmitted and received by the (Orthogonal Frequency Division Multiple Access) method.

  In addition, you may use combining each system demonstrated above. For example, the TDD scheme may be used as the transmission / reception duplex scheme and the FDM / FDMA scheme may be used as the multiplexing scheme.

  According to the above-described configuration, it is not necessary to individually connect the integrated demodulator 30 to each of the plurality of integrated antenna devices 20, and thus it is possible to prevent an increase in wire harness due to the addition of the integrated antenna device 20. .

  In the above-described embodiment, the transmission line 40 is configured by a plurality of coaxial cables 401 to 40m provided with connectors 41 at both ends, and the integrated demodulator 30 and the integrated antenna devices 20 are cascaded by the coaxial cables 401 to 40m. The case where the coaxial cable 40m connected to the final stage integrated antenna device 20n is connected to the terminator 60 has been described.

  However, as shown in FIG. 14, the transmission line 40 is composed of a plurality of coaxial cables 401 to 40 m provided with connectors 41 at both ends, and the integrated demodulator 30 and the integrated antenna devices 20 are connected to the coaxial cables 401 to 40 m. The coaxial cable 40m connected to the integrated antenna device 20 at the final stage may be connected to the integrated demodulator 30 while being cascade-connected at 40m.

  In this case, the integrated demodulation device 30 is not provided with the second communication processing unit 35, and transmission and reception of the high-frequency signal are individually controlled. That is, a high frequency signal from each integrated antenna device 20 to the integrated demodulator 30 is input to the high frequency receiver 37 of the integrated demodulator 30, and a high frequency signal from the integrated demodulator 30 to each integrated antenna device 20 is a high frequency transmitter. 39.

  In the case of FIG. 14, the first communication processing unit 24 can be configured with a directional coupler as shown in FIG.

  The directional coupler serves as a high frequency coupler as described in the above embodiment. In the configuration of FIG. 14, the transmission path from each integrated antenna device 20 to the integrated demodulation device 30 and the transmission path from the integrated demodulation device 30 to each integrated antenna device 20 are fixed in one direction. As shown in FIG. 15, the directional coupler in which only one of transmission from the insertion port a to the high frequency receiving unit 27 and transmission from the high frequency transmission unit 26 to the insertion port b is performed serves as a transmission / reception control unit. You can also

  That is, in the case of FIG. 14, the high-frequency coupling unit 241 and the transmission / reception control unit 242 can be used together, and the reduction in circuit scale and cost reduction can be realized.

  In the above-described embodiment, the case where the integrated reception system 1 includes the common transmission line 40 to which each integrated antenna device 20 and the integrated demodulation device 30 are connected has been described. However, each integrated antenna device 20 and the integrated demodulation device are described. As long as 30 is a configuration capable of transmitting and receiving signals through a common transmission path, the configuration is not limited to that in the above-described embodiment.

  For example, a configuration as shown in FIG. 16 may be used. In FIG. 16, each integrated antenna device 200 includes blocks 211 to 21n shown in FIG. 2 (in FIG. 16, a plurality of reception signal processing units are collectively referred to as reception signal processing unit 210), 220, 230, and 240. In addition, the digital signal from the serial data transmission unit 230 of the other integrated antenna device 20 is received between the multiplexing processing unit and the serial data transmission unit 230, and the serial data transmission unit 230 of the own integrated antenna device 20 is provided. Serial data receiving unit 250 for transmitting the digital signal via the control data receiving unit 240, the received signal processing unit 210 and the multiplexing processing unit 220 from the integrated demodulator 300 or another integrated antenna device 200. The control signal is received by the self-integrated antenna device 200 via the control data receiving unit 240, and the control signal And a control data transmission section 260 to be transmitted to another integrated antenna device 200.

  The serial data receiving unit 250 outputs the digital signal from the multiplexing processing unit 220 and the digital signal from the serial data sending unit 230 of the other integrated antenna device 200 to the serial data sending unit 230 of its own device in time series or the like. To do.

  The control data transmission unit 260 analyzes the received control signal and determines whether or not the control signal is transmitted to the self-integrated antenna device 200. And when the said control signal is a control signal sent to the self-integrated antenna apparatus 200, the received signal processing part 210 etc. are controlled and the said control signal is not a control signal sent to the self-integrated antenna apparatus 200 In this case, the control signal is transmitted to another integrated antenna device 200.

  According to the above-described configuration, the number of wire harnesses can be reduced as compared with the configuration illustrated in FIG.

  In the above-described embodiment, the embodiment in which the integrated reception system, the integrated antenna device, and the integrated demodulation device according to the present invention are applied to a vehicle has been described, but the present invention is not limited to the vehicle. For example, the integrated reception system, integrated antenna device, and integrated demodulation device according to the present invention may be applied to ships, aircraft, houses, and the like.

  Note that the above-described embodiment is merely an example of the present invention, and it is needless to say that the specific configuration of each block can be changed and designed as appropriate within the scope of the effects of the present invention.

Functional block configuration diagram of the integrated reception system when a plurality of antennas are provided close to each other Functional block configuration diagram of the integrated reception system when a plurality of antennas are not provided close to each other Functional block configuration diagram of the integrated reception system of the present invention Functional block diagram of the received signal processor Functional block diagram of orthogonal transform unit (A) is a functional block configuration diagram of the first digital modulation processing unit, (b) is a functional block configuration diagram of the first digital demodulation processing unit Explanatory diagram of IQ constellation (A) is a perspective view of an in-vehicle mounting example of the integrated receiving system, (b) is a top view of the in-vehicle mounting example of the integrated receiving system. (A) is explanatory drawing of the high frequency signal transmission from an integrated demodulation apparatus to an integrated antenna apparatus when a high frequency coupling part is comprised by resistance, (b) is an integrated demodulation from an integrated antenna apparatus when a high frequency coupling part is comprised by resistance. Illustration of high-frequency signal transmission to equipment (A) is a functional block configuration diagram when the transmission / reception control unit is configured with a switch, (b) is a functional block configuration diagram when the transmission / reception control unit is configured with a filter, and (c) is configured with a transmission / reception control unit with a filter. Functional block configuration diagram (A) is an explanatory diagram when transmission / reception between the integrated demodulation device and each integrated antenna device is performed in a time division manner, and (b) is an explanatory diagram when transmission / reception between the integrated demodulation device and each integrated antenna device is performed at different frequencies. (A) is a circuit diagram in the case where the high-frequency coupling portion is configured by a capacitor, and (b) is a circuit diagram in the case where the high-frequency coupling portion is configured by a coil. (A) is a circuit diagram in the case where the high-frequency coupling unit is configured by a high-pass filter, and (b) is a circuit diagram in the case where the high-frequency coupling unit is configured by a directional coupler. Functional block diagram of another embodiment of the integrated reception system of the present invention Circuit diagram when the first communication processing unit is configured with a directional coupler Functional block diagram of another embodiment of the integrated reception system of the present invention Functional block configuration diagram of the integrated reception system of the present invention

Explanation of symbols

20: Antenna device (integrated antenna device)
21: Received signal processing unit 22: Multiplexing processing unit 23: First digital modulation processing unit 24: First communication processing unit 241: High frequency coupling unit 242: Transmission / reception control unit 25: First digital demodulation processing unit 30: Demodulator ( Integrated demodulator)
31: second digital demodulation processing unit 32: separation processing unit 33: control unit 34: second digital modulation processing unit 35: second communication processing unit 351: transmission / reception control unit 36: power feeding unit 40: transmission line 50: antenna

Claims (20)

A reception signal processing unit that is disposed in the vicinity of the antenna and converts a high-frequency signal received by the antenna into a digital signal, and a first digital modulation that modulates the high-frequency signal based on the digital signal output from the reception signal processing unit A plurality of antenna devices comprising: a processing unit; and a first communication processing unit that outputs a high-frequency signal modulated by the first digital modulation processing unit to a transmission line;
A demodulator including a second digital demodulation processing unit that demodulates a high-frequency signal transmitted from each antenna device via the transmission line;
An integrated reception system comprising: each antenna device and a common transmission line to which the demodulation device is connected. At least one of the plurality of antenna devices is disposed in the vicinity of a plurality of antennas having different signal systems, and a plurality of reception signal processing units that convert high-frequency signals received by the respective antennas into digital signals, and each reception signal processing unit An antenna apparatus including a multiplexing processing unit that multiplexes an output digital signal, wherein the first digital modulation processing unit modulates a high-frequency signal based on the digital signal multiplexed by the multiplexing processing unit An antenna device,
2. The integrated reception system according to claim 1, wherein the demodulator includes a separation processing unit that separates the digital signal demodulated by the second digital demodulation processing unit into a digital signal for each signal system.   The demodulator includes a control unit that generates a control signal for each antenna device, a second digital modulation processing unit that modulates a high-frequency signal based on the control signal generated by the control unit, and the second digital modulation processing unit 3. The integrated reception system according to claim 1, further comprising a second communication processing unit that outputs the high-frequency signal modulated in step 1 to the transmission line. 4.   4. The integrated reception system according to claim 3, wherein the first communication processing unit includes a high frequency coupling unit that attenuates a high frequency signal transmitted from the transmission line by a predetermined attenuation amount.   The integrated reception system according to claim 4, wherein the high-frequency coupling unit includes a directional coupler.   5. The integrated reception system according to claim 3, wherein the first communication processing unit and the second communication processing unit include a transmission / reception control unit that transmits and receives each high-frequency signal in a time-division duplex method.   5. The integrated reception system according to claim 3, wherein each of the first communication processing unit and the second communication processing unit includes a transmission / reception control unit that transmits and receives each high-frequency signal using a frequency division duplex method.   8. A power feeding unit that superimposes a DC voltage to be fed to each antenna device on a high frequency signal transmitted from the demodulating device to each antenna device via the transmission line is provided. The integrated reception system according to any one of the above.   The transmission line is composed of a plurality of coaxial cables provided with connectors at both ends, and the demodulating device and each antenna device are connected in cascade with each coaxial cable, and the coaxial cable is connected to the final stage antenna device. The integrated receiving system according to claim 1, wherein the terminal is connected to a terminator.   The transmission line is composed of a plurality of coaxial cables provided with connectors at both ends, and the demodulating device and each antenna device are connected in cascade with each coaxial cable, and the coaxial cable is connected to the final stage antenna device. The integrated receiving system according to claim 1, wherein the integrated receiving system is connected to the demodulator.   The transmission line is composed of a plurality of coaxial cables provided with connectors at both ends, and the demodulating device and each antenna device are connected in cascade with each coaxial cable, and the coaxial cable is connected to the final stage antenna device. 4. The integrated reception system according to claim 1, wherein the first communication processing unit includes a directional coupler.   12. The integrated reception system according to claim 1, wherein each transmission line is mounted on the back side of each interior of the vehicle and mounted on the back side of the interior decorative panel. The integrated reception system is mounted so that the connector is positioned in the vicinity of the installation location of each antenna device.   A reception signal processing unit that is disposed in the vicinity of the antenna and converts a high-frequency signal received by the antenna into a digital signal, and a first digital modulation that modulates the high-frequency signal based on the digital signal output from the reception signal processing unit An antenna apparatus comprising: a processing unit; and a first communication processing unit that outputs a high-frequency signal modulated by the first digital modulation processing unit to a transmission line.   Multiple signal reception units that are arranged near multiple antennas with different signal systems and convert high-frequency signals received by each antenna into digital signals, and digital signals that are output from each reception signal processor are multiplexed. A multiplexing processing unit; a first digital modulation processing unit that modulates a high-frequency signal based on the digital signal multiplexed by the multiplexing processing unit; and a high-frequency signal modulated by the first digital modulation processing unit as a transmission line The first communication processing unit that outputs to the antenna device.   15. The antenna apparatus according to claim 13, further comprising a first digital demodulation processing unit that demodulates a high-frequency signal input through the transmission line and generates a control signal for each received signal processing unit. .   The antenna device according to any one of claims 13 to 15, wherein the first communication processing unit includes a high-frequency coupling unit that attenuates a high-frequency signal transmitted from the transmission line by a predetermined attenuation amount. .   17. The antenna device according to claim 16, wherein the high-frequency coupling unit is constituted by a directional coupler.   A second digital demodulation processing unit that generates a digital signal by demodulating a high-frequency signal input from the antenna device according to any one of claims 13 to 17 via a transmission line, and demodulated by the second digital demodulation processing unit And a separation processing unit that separates the digital signal into a digital signal for each signal system.   A control unit that generates a control signal for the antenna device, a second digital modulation processing unit that modulates a high-frequency signal based on the control signal generated by the control unit, and a high frequency that is modulated by the second digital modulation processing unit 19. The demodulator according to claim 18, further comprising a second communication processing unit that outputs a signal to the transmission line.   The demodulator according to claim 18 or 19, further comprising a power feeding unit that superimposes a DC voltage to be fed to the antenna device on a high-frequency signal output to the transmission line.