JPH023334B2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field] The present invention provides a coaxial cable branching and distribution system that includes:
This invention relates to a two-way communication method for a two-way multiplex communication system in which a frequency conversion converter is installed at the head end of a coaxial cable.

[Background technology]

FIG. 1 shows an example of a two-way multiplex communication system in which a converter is provided at the end (head end) of a coaxial cable. In the figure, 1 is a converter having a frequency conversion function, 2 is a coaxial cable, and a plurality of branchers 3 are inserted and connected at appropriate locations along the coaxial cable 2. 4A, 4B...
is a terminal connected to one end of each branch 3.
The converter 1 is provided at the end of the coaxial cable 2. In this system, bidirectional multiplex communication is performed between the terminal 4A and another terminal 4B. Communication in this case refers to data transmission, audio, and video transmission. Here, the frequency from terminal 4A
Sends a signal _A. Further, a signal having a signal frequency _B different from the signal frequency _A is transmitted from the other terminal 4B. Signal frequency _A is converted to frequency F _A by converter 1, and signal frequency _B is converted to frequency F _B
is converted to An example of frequency allocation is shown in FIG. In this way, by changing the frequency bands of the upstream signals with signal frequencies _A and _B and the frequency bands of the converted downstream signals with frequencies A and _B , it is possible to easily separate _the received signal and the transmitted signal. Furthermore, if the transmission signal is sent out from the head end as it is, there will be adverse effects such as ghosting of the video signal due to synthesis due to signal time differences. Therefore, in the branch distribution system, a bidirectional communication system using the converter 1 is used. However, this method has a serious drawback in that the transmission frequency cannot be used as the local oscillation frequency of the received signal. In other words, this system has a problem in that simultaneous bidirectional communication cannot be performed unless a local oscillation circuit for receiving the reception signal is provided in addition to the oscillation circuit for the transmission signal.

[Purpose of the invention]

The present invention has been provided in view of the above-mentioned points, and provides a two-way communication system for the purpose of simplifying the circuit for communication between terminals in a branch distribution two-way communication system having a converter at the head end. It is something.

[Disclosure of the invention]

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Note that the basic method and configuration are the same as the conventional one.
FIG. 3 shows a block diagram of the converter 1, where 5 is a branching mixer and 8 is a frequency F ₀ inside the converter 1.
7 is a frequency conversion circuit that oscillates a local oscillation circuit, 7 is a frequency conversion circuit, and transmits signal frequencies _A and _B from the splitter mixer 5.
and the local oscillation frequency F ₀ from the local oscillation circuit 8 are mixed and frequency-converted into frequencies F _A and F _B . Here, the relationships are F _A = F _O + _A and F _B = F _O + _B. 6 is a mixer, which mixes the converted frequencies F _A and F _B from the frequency conversion circuit 7 and the local oscillation frequency F _O from the local oscillation circuit 8 to produce frequencies F _A , F _B , and F _O , respectively. Output. 9 is an external connection terminal. Here, when the outgoing signal frequencies _A and _B are received from the terminal 4A or 4B through the external connection terminal 9, the outgoing signal frequencies _A and _B are input to the frequency conversion circuit 7 via the branch mixer 5, and are input to the local oscillation circuit. The local oscillation frequency F _O from 8 is converted into the frequency F _A =F _O + _A (F _B =F _O + _B ) in the frequency conversion circuit 7 . Furthermore, in the mixer 6, the frequencies F _A ,
F _O (F _B , F _O ) is output, and frequencies F _A and F _O (F _B , F _O ) are sent out from the branching mixer 5 and external connection terminal 9 . The signal is then transmitted to the terminal 4B or 4A via the coaxial cable 2 and the branch 3. In this way, the converter 1 receives the signals sent from the terminals 4A and 4B, converts the frequency and retransmits the signals, and also sends out the local oscillation frequency F _O used when converting the frequency.

FIG. 4 is a block diagram of a terminal 4A that transmits a signal of signal frequency _A and receives a signal of signal frequency _B. 10 is an external connection terminal, 11 is a modulation signal output terminal, and 12 is a demodulation signal output terminal. 13 is a branching mixer, and 14 is an oscillation circuit that oscillates and outputs frequency _A. 15 is a modulation circuit, 16 is a down converter circuit, 17 is a mixing circuit, and 18 is a demodulation circuit. Thus, the oscillation circuit 14 oscillates a frequency _A and sends it to the mixing circuit 17 and modulation circuit 15. In the modulation circuit 15, the frequency _A is modulated (AM, FM, etc.) by the modulation signal input from the modulation signal input terminal 11, and is sent to the demultiplexing mixer 13 as the signal frequency _A. The signal frequency _A received by the demultiplexing mixer 13 is sent out as the sending signal frequency _A to the branch distribution system via the external connection terminal 10. Furthermore, the frequencies F _A , F _B , and F _O received as signals from the converter 1 at the external line connection terminal 10 are transmitted to the down converter circuit 16 via the branch mixer 13 . The down converter circuit 16 converts the frequencies F _A and F _B into signal frequencies _A (= F _A − F _O ) and _B (= F _B − F _O ) using F _O as the local oscillation frequency. Then, the signal frequencies _A and _B are transmitted to the mixing circuit 17. The mixing circuit 17 uses the oscillation frequency _A of the oscillation circuit 14 as the local oscillation frequency to set signal frequencies _A and _B.
Convert the frequency and extract the intermediate frequency | _A − _B |. The signal | _A − _B | is demodulated by the demodulation circuit 18,
The demodulated signal is output from the demodulated signal output terminal 12 as a demodulated output. In other words, the functions of terminal 4A are _A
In order to transmit the signal frequency modulated at the frequency of , and demodulate the signal of frequency F _B from the converter 1, the local oscillation frequency in the converter 1 transmitted from the head end is set as the local oscillation frequency of the terminal 4A. Convert the frequency F _B to the signal frequency _B sent from the terminal 4B, and further,
The signal frequency _B is frequency-converted to an intermediate frequency using the transmission frequency _A of the terminal 4A as a local oscillation frequency, and demodulated.

FIG. 5 is a block diagram showing how the respective transmission frequencies are received and converted to intermediate frequencies in the relationship between the terminals 4A and 4B and the converter 1. Frequency _A generated by the oscillation circuit 14A of the terminal 4A is modulated by the modulation circuit 15A and transmitted to the converter 1. Converter 1 converts _A into F _A using the local oscillation frequency F _O and sends it out. Converter 1 also sends out a local oscillation frequency F _O.
In the terminal device 4B, the down converter circuit 16 converts the frequency F _A into a signal frequency using the local oscillation frequency F _O.
A , and the signal frequency _A is converted by the mixing circuit 17 into an intermediate frequency _IF =| _A − _B | using the frequency _B oscillated by the oscillation circuit 14B of the terminal 4B.

〔Effect of the invention〕

As described above, in the two-way communication system, the present invention is provided with an oscillation circuit that oscillates a different frequency in each terminal, a converter that includes a local oscillation circuit that oscillates a predetermined frequency, and a local oscillation circuit that oscillates a predetermined frequency. The converter includes a frequency conversion circuit that mixes the signal frequency from the terminal and converts it into a predetermined signal frequency, and the converter converts the signal frequency transmitted and received from the terminal to the oscillation frequency from the local oscillation circuit and the frequency conversion circuit. The converted signal frequency and the local oscillation frequency of the local oscillation circuit are sent from the converter to the terminal device via the coaxial cable and the branch. The local oscillation frequency of the own station is used as the local oscillation frequency of the own station, and the signal frequency from the converted converter is differentially mixed with the signal frequency from the converter to reconvert to the transmission signal frequency of the other party, and this reconverted transmission signal frequency of the other party and The oscillation frequency from the oscillation circuit, which is the sending signal frequency of the own station, is differentially mixed and converted into an intermediate frequency, and the intermediate frequency is demodulated, so the local oscillation frequency of the converter is transmitted to the terminal side. On the terminal side, the receiving frequency is reconverted to the sending signal frequency of the other party's terminal using the local oscillation frequency of the converter, and the sending signal frequency of the own terminal is converted to an intermediate frequency as the local oscillating frequency. As a result, the oscillation circuit of the terminal needs only the frequency of the sending signal, and there is no need to provide a separate local oscillation circuit as in the conventional case, which has the effect of simplifying the circuit and reducing costs. Also, if a PLL circuit is used for multi-station,
The PLL circuit can be used both as a local oscillation circuit and for generating a transmission frequency.

[Brief explanation of drawings]

Fig. 1 is a block diagram of a two-way multiplex communication system, Fig. 2 is a frequency allocation diagram of the same as above, Fig. 3 is a block diagram of a converter according to an embodiment of the present invention, Fig. 4 is a block diagram of a terminal of the same as above, FIG. 5 is a block diagram showing the frequency conversion path of the same as above. 1 is a converter, 2 is a coaxial cable, 3 is a branch, 4 is a terminal, 7 is a frequency conversion circuit, 8 is a local oscillation circuit, 14 is an oscillation circuit, _A and _B are sending signal frequencies, F _O is a local oscillation frequency , F _A , F _B indicate the converted frequencies.

Claims (1)

[Claims] 1. Each terminal is connected to a plurality of branching switches installed in the middle of a coaxial cable, and a converter is installed at the end of the coaxial cable to convert different signal frequencies transmitted from each terminal via the coaxial cable. A two-way communication method in which the frequency is converted by a converter, the frequency-converted signal frequency is reconverted by each terminal via a coaxial cable and a branch, and two-way communication is performed between each terminal via the converter. , each terminal is equipped with an oscillation circuit that oscillates at a different frequency, and the converter includes a local oscillation circuit that oscillates a predetermined frequency, and a converter that mixes the local oscillation frequency from this local oscillation circuit with the signal frequency from the terminal. The converter mixes the signal frequency transmitted and received from the terminal with the oscillation frequency from the local oscillation circuit in the frequency conversion circuit and converts it into a sum frequency. This converted signal frequency and the local oscillation frequency of the local oscillation circuit are sent from the converter to the terminal device via the coaxial cable and branch,
The terminal device uses the local oscillation frequency of the received converter as the local oscillation frequency of its own station, mixes the difference with the signal frequency from the converted converter, and reconverts it to the transmission signal frequency of the other party. A two-way communication system characterized by differentially mixing the transmission signal frequency of the other party and the oscillation frequency from the oscillation circuit, which is the transmission signal frequency of the local station, converting the frequency to an intermediate frequency, and demodulating the intermediate frequency.