JPH0750885B2 - Communication method and communication system - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a method and system for communicating between terminal stations using a frequency division multiplexing transmission line.

[Prior art]

Conventionally, in the case of performing data communication between computers of arbitrary two terminal stations separated from each other, a telephone line and a modulation / demodulation device are usually used, and the terminal station of the communication partner is selected by dialing. Using this telephone line has the advantage that communication is possible regardless of short distance or long distance,
There is the inconvenience of having to dial each one at the time of communication.

[Problems to be Solved by the Invention]

Therefore, a method such as LAN for constructing a communication system between terminal stations by using a dedicated transmission line has been considered. One of the possible methods is to use a coaxial cable such as CATV as a transmission line, multiplex the channels by frequency division multiplexing, and have each end station communicate arbitrarily. There is no known method of automatically establishing a communication channel between them. Therefore, the present invention connects a terminal station to a frequency-division-multiplexed transmission path and arbitrarily establishes a channel between the terminal stations,
A method and a communication system that enable full-duplex communication.

[Means for solving problems]

A configuration of a first invention for solving the above-mentioned problems is a communication system including a transmission line for transmitting a signal subjected to frequency division multiplexing, and a modulation / demodulation device constituting a terminal station connected to the transmission line, A unique receiving channel is assigned to each terminal in advance, and the calling station detects the presence or absence of the carrier of the receiving channel unique to the called station of the communication partner. If the carrier is not detected, the receiving station unique reception is performed. The transmission channel of the calling station is set according to the channel, the identification signal that identifies the calling station is sent to the transmission channel of the calling station, and the called station identifies the calling station sent from the calling station. It is characterized in that a full-duplex communication channel is formed between the calling station and the called station by setting the transmission channel of the called station according to the signal. The second invention is a communication system comprising a transmission line for transmitting a signal subjected to frequency division multiplexing, and a modulation / demodulation device constituting a terminal station connected to the transmission line, wherein an incoming call of a communication partner at a calling station is received. Carrier detection means for detecting the presence / absence of a carrier of the peculiar reception channel assigned to the station, and when the carrier is not detected, the transmission channel of the calling station is set according to the peculiar reception channel of the called station. Calling station transmission channel setting means, calling means for sending an identification signal for identifying the calling station to the transmission channel of the calling station, and receiving the identification signal sent from the calling station for the identification signal And a called station transmission channel setting means for setting a transmission channel accordingly.

[Action]

A unique reception channel is assigned in advance to each terminal station. When a communication channel is established from the calling station to the called station of the communication partner, it is performed as follows. The calling station detects the presence / absence of a carrier of a unique reception channel assigned to the called station. If the carrier is detected, it means that the called station is communicating with another terminal station, and in this case, the communication channel is not established. On the other hand, when the carrier of the receiving channel of the called station is not detected, it means that the called station is not in communication, so that the channel can be established with the called station. Therefore, the calling station sets the transmission channel according to the reception channel unique to the called station. That is, the transmission channel of the calling station and the transmission channel of the called station establish a communication channel from the calling station to the called station. Then, the communication channel from the called station to the calling station is established as follows. Using the communication channel from the calling station to the called station established as described above, the identification signal for identifying the calling station is transmitted from the calling station to the called station. Since the identification signal identifies the calling station, the receiving channel unique to the calling station assigned to the calling station can be known. Therefore, the called station can set the transmission channel corresponding to the receiving channel unique to the calling station by the identification signal. In this way, the communication channel from the called station to the calling station is established by the transmission channel of the called station and the reception channel of the calling station, and communication from the called station to the calling station becomes possible.
As a result, a full duplex communication channel is formed between the calling station and the called station.

【Example】

Hereinafter, the present invention will be described based on specific examples. Example 1 This example is an example in which a frequency converter is not used in the head end. In FIG. 1, D is a transmission line made up of a coaxial cable, K1.
~ K3 is a bidirectional coupler, M1 to M3 are modems, C1 to C3 are computers.
T1 to T3 are configured. Each of the modulation / demodulation devices M1 to M3 is configured such that its reception channel and transmission channel can be individually set based on the control data instructed by each computer C1 to C3. As shown in FIG. 2, there are three channels, ch1 to ch3, and the carrier frequency of each channel is f1 to f3. Then, the reception channels of the terminal stations T1 to T3 are respectively assigned to the channel ch1 to ch3 specific to the terminal station in advance. Next, a procedure for establishing a communication channel will be described based on a flowchart showing a processing procedure of a computer. A communication channel is established from the terminal station T1 to the terminal station T2, the terminal station T1 is called a calling station T1, and the terminal station T2 is called a called station T2. When power is supplied to the devices at each terminal T1 to T3, each terminal T1 to T3
The computers C1 to C3 of T3 output control data for setting the frequencies f1 to f3 of the carriers of the receiving channels ch1 to ch3 specific to each terminal T1 to T3 to the respective modulation / demodulation devices M1 to M3.
The receiving channel of each modulator / demodulator M1 to M3 is channel ch1.
~ Initially set to ch3. Next, when a communication request is issued to the terminal station T2 at the terminal station T1, the computer C1 executes the program shown in FIG. In step 100, the parameters L and M are initialized.
The parameter L stores the number of times that the calling operation to the called station T2 is repeatedly executed when the called station T2 is already communicating with another terminal station, and the parameter M stores the calling operation. When there is no response from the called station later, the number of times of executing the operation of detecting the response is repeatedly stored. Next, the process proceeds to step 102, the control data for setting the receiving channel of the calling station T1 to the receiving channel ch2 unique to the called station T2 is output to the modulation / demodulation device M1, and the modulation / demodulation device M1.
Changes the receiving channel to channel ch2. Then, the signal of the channel ch2 from the transmission line D is transmitted to the modulator / demodulator M1.
When the carrier is detected, the carrier detection signal CD is output from the modulation / demodulation device M1 to the computer C1. After changing the reception channel, the computer C1 waits for a certain period of time, then determines whether or not the carrier detection signal CD is turned on in step 104.If the carrier detection signal CD is not turned on, the process proceeds to step 106, The control data for setting the transmission channel of the calling station T1 to the reception channel ch2 unique to the called station T2 is output to the modulation / demodulation device M1. Then,
The modulator / demodulator M1 changes the transmission channel to the channel ch2. Next, in step 108, the identification data identifying the calling station T1 is output to the modulation / demodulation device M1, modulated by the modulation / demodulation device M1 with the carrier of frequency f2, and transmitted to the channel ch2. Then, the process proceeds to step 110, the control data for setting the receiving channel of the calling station T1 to the receiving channel ch1 unique to the calling station T1 is output to the modulation / demodulation device M1, and the modulation / demodulation device M1 uses the reception channel as a channel. Change to ch1. Then, in step 112, when the transmission channel of the called station T2 is set to the unique reception channel ch1 of the calling station T1, the ACK signal is output from the called station T2 to the channel ch1. It is determined whether a signal has been received. A
When the CK signal is received, the calling procedure from the calling station T1 to the called station T2 is completed. If the carrier detection signal CD is turned on in step 104, it means that the receiving channel ch2 unique to the called station T2 has already been used. Wait for a set amount of time, then proceed
At 116, the parameter L is updated by 1. Then, in step 118, it is determined whether or not the parameter L is equal to or greater than the predetermined value n, and if the determination result is NO, the process returns to step 104 and the above-described calling operation for the terminal station T2 is re-executed. On the other hand, if the decision result in the step 118 is YES, it is determined that the occupied time of the channel ch2 is long and the process shifts to the step 120 to abandon the calling operation to the terminal station T2 and display that effect. If the ACK signal, which is the response from the called station T2, is not received in step 112, steps 122 to 128 are executed,
Similar to steps 114 to 120, a process of waiting for an irregular time and then determining whether or not an ACK signal is received is executed n times. And, during the n times of repeated execution, ACK
If no signal is received, the calling procedure is abandoned.
In this case, it means that the terminal station T2 is not powered. On the other hand, when the computer of the terminal station that does not perform the call operation is turned on, after the initial setting such as setting the receiving channel to the receiving channel peculiar to the terminal station is executed, the computer enters the waiting state or the terminal station. Just running your own program. Then, in order to detect whether or not its own terminal has been called, the program of FIG. 4 is executed at fixed time intervals by an interval timer interrupt. Explaining the computer C2 of the called station T2, when the modem M2 detects the carrier of the reception channel ch2,
The modulation / demodulation device M2 turns on the carrier detection signal CD to be output to the computer C2, but in step 200 it is determined whether the carrier detection signal CD is on, and if the carrier detection signal CD is not on, the program Execution is terminated. When it is determined that the carrier detection signal CD is ON, the process proceeds to step 202, and the identification data transmitted from the calling station T1 to the receiving channel ch2 is received in step 108 of FIG. Data is entered. Next, the process proceeds to step 204, the receiving channel ch1 unique to the calling station T1 is specified from the identification data, and step 2
At 04, control data for setting the transmission channel of the called station T2 to the reception channel ch1 unique to the calling station T1 is output to the modulation / demodulation device M2. Then, the modulator / demodulator M2 sets the transmission channel to the channel ch1. Next, in step 206, the ACK signal is sent to channel ch1.
The interval timer interrupt for activating this program in the next step 208 is prohibited and the communication channel is established. In this way, the transmission from the calling station T1 to the called station T2 is
The reception channel ch2 peculiar to T2 is performed, and the transmission from the called station T2 to the calling station T1 is performed on the reception channel ch1 peculiar to the calling station T1, and full duplex communication is performed between the channel ch1 and the channel ch2. Done. After the communication channel is established as described above, it can also be used for data transmission between computers and transmission of analog signals such as voice and video between terminal stations. Although the number of terminal stations is three in the above description, the number of terminal stations can be increased up to the maximum number of channels that can be used in the transmission path. The communication channel establishing procedure realized by a computer may be executed by the modulation / demodulation device by making the modulation / demodulation device intelligent. The carrier detecting means, the calling station originating channel setting means, the calling means, and the called station originating channel setting means in the claims are composed of a modulator / demodulator and a computer as hardware. Then, in the correspondence relationship with the computer procedure, the carrier detection means is
104, the calling station originating channel setting means corresponds to step 106, the calling means corresponds to step 108, and the called station originating channel setting means corresponds to steps 200 to 204. Further, the transmission channel or the reception channel of the modulator / demodulator can be variably set by generating a carrier having a set frequency by using a PLL oscillation circuit or the like. Second Embodiment The second embodiment relates to a communication system using a frequency conversion device. The overall system configuration is configured as shown in FIG. The difference from FIG. 1 showing the configuration of the first embodiment is that directional couplers H1 to H3 are used for connecting the terminal station and the transmission line D, and the frequency at the head end of the transmission line D. Converter
FT is connected and bidirectional relay amplifier A1 ~
That is, A4 is inserted. In this embodiment, the channels are arranged as shown in FIG. 6, and upstream channels chS1 to chS3 are used for communication from the terminal station to the headend side, and communication from the headend to the terminal station side is performed. For this purpose, downlink channels chR1 to chR3 are used. Up channels chS1 to chS3 are transmission channels of the terminal station and exist in the low group band. Downstream channels chR1 to chR3 are reception channels of the terminal station and exist in the high group band. Then, the frequency conversion device FT provided at the head end converts the input signal in the low group band to the offset frequency Δ
The signal is shifted by f to obtain an output signal in the high group band, and the signals transmitted to the head end by the transmission channels chS1 to chS3 are transmitted to the terminal station side by the reception channels chR1 to chR3. Therefore, the transmission channel chS1 and the reception channel chR1 are always used as one set. The same applies to other channels. In this embodiment, each terminal station T1 to T3 has a unique reception channel chR1.
~ ChR3 is assigned in advance. The calling procedure is similar to that of FIG. 3 showing the calling procedure of the first embodiment, except for the following points. That is, in step 102, the receiving channel of the calling station T1 is changed to the unique receiving channel chR2 of the called station T2 of the calling partner station. Then, in step 106, the transmission channel of the calling station T1 is changed to the transmission channel chS2 corresponding to the unique reception channel chR2 of the called station T2. In step 110, the receiving channel of the calling station T1 is restored to the unique receiving channel chR1 of the calling station T1. On the other hand, the incoming call procedure is the same as that of FIG. 4 showing the incoming call procedure of the first embodiment, but in step 204 the outgoing channel of the called station T2 is unique to the calling station T1 specified by the identification data. The difference is that the transmission channel chS1 corresponding to the reception channel chR1 is set. When a communication channel is established by such a procedure,
The signal output from the calling station T1 to the upstream transmission channel chS2 is converted to the downstream reception channel chR2 by the head-end frequency conversion device FT and output to the transmission path D. Then, the signal is received by the called station T2 that can receive the signal of the reception channel chR2. In addition, the signal output from the called station T2 to the upstream transmission channel chS1 is sent to the downstream reception channel ch by the frequency converter FT at the headend.
It is converted to R1 and output to the transmission path D. Then, the calling station T1 capable of receiving the signal of the reception channel chR1 receives the signal. Therefore, the transmission channel chS2 and the reception channel chR2 perform communication from the calling station T1 to the called station T2, and the transmission channel chS1 and the reception channel chR1 perform communication from the called station T2 to the calling station T1. Be seen.

【The invention's effect】

A unique receiving channel is assigned to each terminal in advance, and the calling station detects whether there is a carrier of the unique receiving channel assigned to the called station of the communication partner to determine whether the called station is in the non-communication state. Is detected. Further, since the transmission channel corresponding to the reception channel peculiar to the called station is set in the calling station, it is possible to make a call from the calling station to the called station and to perform subsequent communication. Further, since the called station is assigned a unique receiving channel, if a carrier is detected in the receiving channel, it can be recognized that its own terminal station has called. Then, it becomes possible to identify the calling station by the identification signal received by the receiving channel, and by setting the transmitting channel of the called station to the channel corresponding to the receiving channel unique to the calling station, It becomes possible to transmit the signal from the calling station to the calling station. Therefore, by using the transmission line frequency division multiplexed by the communication method and the communication system of the present invention to select two channels in a predetermined procedure between arbitrary terminal stations, simultaneous two-way communication between terminal stations is possible. That is, full duplex communication can be executed.

[Brief description of drawings]

FIG. 1 is a block diagram showing a communication system according to a specific embodiment of the present invention. FIG. 2 is an explanatory diagram showing the channel arrangement. FIG. 3 is a flowchart showing a calling procedure. FIG. 4 is a flowchart showing an incoming call procedure. FIG. 5 is a block diagram showing a communication system according to another embodiment. FIG. 6 is an explanatory view showing the channel arrangement. T1 to T3: Terminal station, M1 to M3: Modulator / demodulator C1 to C3: Computer, D: Transmission line, FT: Frequency converter

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tatsu Ogasawara, 4-15-23, Sakae, Naka-ku, Nagoya-shi, Aichi Stock company cast (72) Inventor Shinzo Mizuno 2 Mei-Minami, Nakamura-ku, Nagoya, Aichi No. 14-19 Hibiya General Equipment Co., Ltd. Nagoya Branch (56) References JP-A-51-55612 (JP, A) JP-A-57-211850 (JP, A) JP-A-59-178842 (JP, A) ) JP-A-59-97250 (JP, A) JP-A-60-198934 (JP, A)

Claims (5)

[Claims] 1. In a communication system comprising a transmission line for transmitting a signal subjected to frequency division multiplexing and a modulation / demodulation device constituting a terminal station connected to the transmission line, a reception channel unique to each terminal station is provided in advance. Allocation, the calling station detects the presence or absence of the carrier of the receiving channel peculiar to the called party of the communication partner, and if the carrier is not detected, the transmitting channel of the calling station is decided according to the receiving channel peculiar to the called station. Is set, the identification signal that identifies the calling station is sent to the sending channel of the calling station, and at the called station, the sending channel of the called station is sent according to the identification signal of the calling station sent from the calling station. Is set to form a full-duplex communication channel between the calling station and the called station. 2. A frequency converter for converting a low group frequency band or a high group frequency band into a high group frequency band or a low group frequency band is connected to the transmission line, and the high group frequency band and the low group frequency band are connected. By forming an upstream channel for transmitting a signal in one direction and a downstream channel for transmitting a signal in the opposite direction to the one direction, wherein the transmission channel is an upstream channel and the reception channel is a downstream channel. The communication method according to claim 1. 3. The communication method according to claim 1, wherein the communication after the calling station and the called station are channel-connected is data, voice or video communication. 4. A communication system comprising a transmission line for transmitting a signal subjected to frequency division multiplexing and a modulation / demodulation device constituting a terminal station connected to the transmission line, wherein a called station of a communication partner at a calling station Carrier detection means for detecting the presence / absence of a carrier of the peculiar receiving channel assigned to the calling station, and if the carrier is not detected, the transmitting channel of the calling station is set according to the receiving channel peculiar to the called station. Calling station transmission channel setting means, calling means for transmitting an identification signal identifying the calling station to the transmission channel of the calling station, and receiving the identification signal sent from the calling station and responding to the identification signal And a called station transmission channel setting means for setting a transmission channel by means of a communication system. 5. A frequency converter for converting the low group frequency band or the high group frequency band into the high group frequency band or the low group frequency band is connected to the transmission line, and the high group frequency band and the low group frequency band are connected. By forming an upstream channel for transmitting a signal in one direction and a downstream channel for transmitting a signal in the opposite direction to the one direction, wherein the transmission channel is an upstream channel and the reception channel is a downstream channel. The communication system according to claim 4.