JP2940922B2 - Optical transmission equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial applications]

The present invention relates to an optical transmission device for performing data transmission between modules having a communication function such as a sequence controller and a personal computer.

[Prior art]

Conventionally, in data transmission between modules having a communication function such as a sequence controller and a personal computer, when a part of an optical transmission line which is a full-duplex type (hereinafter referred to as "full-duplex") double line is used and coupled, Other electrical transmission lines also had to be full duplex double tracks.

[Problems to be solved by the invention]

For the optical transmission line that is a full-duplex double-track, the wiring is simplified by changing the other electric transmission lines from a full-duplex double-track to a single-wire of a half-duplex type (hereinafter referred to as “half-duplex”). It is. SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to change an electric transmission line coupled to an optical transmission line, which is a full-duplex double-track, from a full-duplex double-track to a half-duplex. An object of the present invention is to reduce the complexity of the wiring of the transmission line and improve the reliability by using a double single line.

[Means for Solving the Problems]

The configuration of the invention for solving the above-mentioned problem is that an electric signal transmitted to a half-duplex transmission line that performs bidirectional communication on a shared transmission line passes through a receiver, and the bidirectional communication is individually transmitted. The optical signal is converted to an optical signal by a modulator comprising an optical modulation circuit and transmitted to a full-duplex transmission line performed on the line.
Alternatively, an optical transmission device in which an optical signal transmitted to a full-duplex transmission line is converted into an electric signal by a demodulator including an optical demodulation circuit, and transmitted to a half-duplex transmission line via a driver. And detecting a start bit in a data block of the electric signal passing through the receiver, and at least a time from when the start bit of the data block is transmitted to when a stop bit is transmitted, from a half-duplex transmission line. A first transmission direction maintaining signal output circuit for outputting a first maintenance signal for maintaining a transmission direction reaching a full-duplex transmission line via a receiver, and a data block of the electric signal converted by the demodulator. Detecting the start bit, and at least the time from when the start bit of the data block is transmitted to when the stop bit is transmitted,
A second transmission direction maintaining signal output circuit for outputting a second maintenance signal for maintaining a transmission direction from a full-duplex transmission line to a half-duplex transmission line via a driver, and a first transmission direction maintenance Receiving a first sustaining signal from a signal output circuit and a second sustaining signal from a second transmission direction maintaining signal output circuit;
If neither the first sustaining signal nor the second sustaining signal is input, the receiver is set to the signal passing state and the driver is turned off. If the first sustaining signal is input before the second sustaining signal, the receiver is turned off. Is set to a signal passing state, the driver is turned off, and when the second sustaining signal is input before the first sustaining signal, the receiver is turned off to put the driver in the signal passing state. A transmission direction switching signal output circuit is provided for outputting a switching signal to the driver and the receiver when the second maintenance signal is input simultaneously with the receiver and the driver in the signal passing state and the driver in the cutoff state. .

[Action]

An electric signal transmitted through a half-duplex transmission line passes through a receiver, is converted into an optical signal by a modulator, and is transmitted to a full-duplex transmission line. The optical signal transmitted through the full-duplex transmission line is converted into an electric signal by the demodulator and transmitted to the half-duplex transmission line via the driver. The first transmission direction maintaining signal output circuit or the second transmission direction maintaining signal output circuit constituting the optical transmission device detects a start bit in a data block of an output signal from a receiver or a demodulator, and at least detects the start bit in the data block. A first sustaining signal and a second sustaining signal for maintaining the transmission direction during a period from when the start bit is transmitted to when the stop bit is transmitted are output. That is, the first transmission direction maintenance signal output circuit outputs a first maintenance signal for maintaining the transmission direction from the half-duplex transmission line to the full-duplex transmission line via the receiver, and outputs the second transmission signal. The direction maintaining signal output circuit outputs a second maintaining signal for maintaining a transmission direction from a full-duplex transmission line to a half-duplex transmission line via a driver. Then, the transmission direction switching signal output circuit constituting the optical transmission device inputs the first sustaining signal and the second sustaining signal, and controls as follows. The first sustain signal and the second
If neither of the sustain signals is input, the receiver is set in a signal passing state and the driver is shut off. When the first sustaining signal is input before the second sustaining signal, the receiver is set to the signal passing state, and the driver is set to the cutoff state. Second
When the sustaining signal is input before the first sustaining signal, the receiver is turned off and the driver is turned on. When the first sustaining signal and the second sustaining signal are input at the same time, the receiver is set to the signal passing state, and the driver is set to the cutoff state. Thus, when received data is input first from the half-duplex transmission line, and when received data is input simultaneously from the half-duplex transmission line and the full-duplex transmission line, the full-duplex transmission line As a result, transmission of data to the half-duplex transmission line is prevented, so that data collision on the half-duplex transmission line is prevented.

【Example】

Hereinafter, the present invention will be described based on specific examples. First, description will be made with reference to FIG. 3 as an overall connection diagram. The communication module 20 and the optical transmission device 10 are RS422
(Balanced operation transmission circuit) Half-duplex connected by standard RS422 electric transmission line (hereinafter referred to as “RS422 line”), and optical transmission device 10 and optical transmission device 10 ′ are connected by optical transmission line. Combined full duplex. Then, data is exchanged between the communication modules via the RS422 line →→ optical transmission line →→ RS422 line transmission path. FIG. 1 is a block diagram showing an electrical configuration of the present apparatus. The half-duplex RS422 line transmits and receives on one transmission path, and the full-duplex optical transmission line transmits and receives on two transmission paths dedicated to transmission and reception.
Path A on the 422 line, path B _S on the transmission side of the optical transmission line,
When the receiving side of the optical transmission line and path B _R, the transmission direction of the transmission signal, A → B _S, a two-way B _R → A. An optical transmission device 10 includes a receiver 11 as an RS422 communication circuit coupled to an RS422 line, and a modulator including an optical modulation circuit.
12, demodulator 13 composed of an optical demodulation circuit, driver 14 as a communication circuit for RS422 coupled to RS422 line, receiver 1
A first transmission direction maintaining signal output circuit 15 for detecting a start bit in the data block of the output signal from 1 and outputting a signal for maintaining the transmission direction of the receiver 11 for at least a predetermined time during which the data block can be transmitted; A second transmission direction maintaining signal output circuit 16 for detecting a start bit in the data block of the output signal from the device 13 and outputting a signal for maintaining the transmission direction of the driver 14 for at least a predetermined time during which the data block can be transmitted; First transmission direction maintaining signal output circuit 15 and second transmission direction maintaining signal output circuit 16
The switching signal of the transmission direction according to the output signal from the receiver
Transmission direction switching signal output circuit to output to 11 and driver 14
17, and an inversion signal output circuit 18 for inverting the output signal of the transmission direction switching signal output circuit 17. Here, the electric signal is a serial digital signal (baseband) as shown in FIG. 2, and the data block starts with a start bit and ends with a stop bit. The time t from the start bit to the stop bit is the transmission time of the data block of the electric signal,
The time length of the output signals from the first transmission direction maintaining signal output circuit 15 and the second transmission direction maintaining signal output circuit 16 is time t.
Set as a longer timer. Next, the operation will be described. First, when the communication module device is turned to the power ON state, the optical transmission device 10 is path A side, stands by in a state where data can be transmitted from either side of the path B _R side. In other words, the output signal of the transmission direction switching signal output circuit 17 in the standby state is always at the L level and the driver 14 is inactivated, and the output signal of the inverted signal output circuit 18 is at the H level and the receiver 11
Is activated. Therefore, it becomes possible to monitor the presence or absence of an electrical signal path A-side first transmission direction sustain signal output circuit 15, the presence or absence of the optical signal path B _R side in the second transmission direction sustain signal output circuit 16. Next, when an electric signal is input to the path A, the receiver 11 is in an operating state, and therefore, the first transmission direction maintaining signal output circuit 15 normally outputs an L level signal and outputs the L signal. H level which is the start bit of the data block →
A point at which the signal has changed to the L level is detected, and an H level signal is output for at least a predetermined time during which the data block of the electric signal can be transmitted. At this time, if the optical signal to the path B _R side is not inputted, the second transmission direction sustain signal output circuit 16,
It outputs an L-level signal. Then, as in the standby state, the transmission direction switching signal output circuit 17 keeps outputting the L level signal, and maintains the operating state of the receiver 11 and the inactive state of the driver 14. Here, an optical signal is input from the path _BR side during the setting timer of the first transmission direction maintaining signal output circuit 15 for the data block of the electric signal input to the path A side, and the second transmission direction maintaining signal output Even if the output signal of the circuit 16 changes from the L level to the H level, the output signal of the transmission direction switching signal output circuit 17 remains at the L level, and the change of the operation state of the receiver 11 and the non-operation state of the driver 14 Absent. By controlling in this way, reception is prioritized over transmission, and collision of electric signals on the half-duplex path A side is prevented. Then, not be input electrical signal path A side, when the optical signal is input to the path B _R side, a first transmission direction sustain signal output circuit 15 has output an L level signal The second transmission direction maintaining signal output circuit 16 normally outputs an L-level signal, and the optical signal is a start bit of a data block of an electric signal converted by the demodulator 13 and is H-level → L-level. Is detected, and an H level signal is output for at least a predetermined time during which the data block of the electric signal can be transmitted. Then, the output signal of the transmission direction switching signal output circuit 17 changes from L level to H level in synchronization with the signal. Therefore, the driver 14 is switched to the operating state, and at the same time, the output signal of the inverted signal output circuit 18 becomes L level, so that the receiver 11 becomes inactive, and the electric signal obtained by converting the optical signal by the demodulator 13 into the path B. Route A from _R side
Transmitted to the side. When the optical signal is input to the path B _R side set timer time of the second transmission direction sustain signal output circuit 16 is completed for the data block of the electrical signal converted by the demodulator 13 whose output signal is H level → Since the signal changes to the L level, the output signal of the transmission direction switching signal output circuit 17 changes from the L level to the H level in synchronization with the signal, the driver 14 becomes inactive again, and at the same time, the output signal of the inversion signal output circuit 18 Since the output signal becomes H level, the receiver 11 returns to the operating state. Here, when the data simultaneously to the path A-side and the path B _R side (start bit) is input, it operates to prioritize path A side. In the optical transmission device having such a configuration, the route A
Since the RS422 line is half-duplex and can be transmitted and received through one transmission path, the transmission line is simplified and the reliability of the transmission line is improved. In addition, the circuit configuration of such an optical transmission device can be realized by using ICs such as a gate circuit, a flip-flop circuit, and a timer circuit, and each circuit element can be efficiently mounted on a printed circuit board. Since the apparatus can be provided at a small size and at a low price, it is possible to reduce the cost required for laying the entire transmission line including the optical transmission apparatus.

【The invention's effect】

According to the present invention, a transmission direction switching signal output circuit receives a first sustaining signal and a second sustaining signal, and sets a receiver to a signal passing state when neither the first sustaining signal nor the second sustaining signal is input. Is shut off, and the first maintenance signal is
When the signal is input before the sustain signal, the receiver is in a signal passing state and the driver is in a cutoff state. When the second sustain signal is input before the first sustain signal, the receiver is shut off. State, and the driver passes the signal.
When the sustaining signal and the second sustaining signal are input at the same time, the receiver is set to the signal passing state, and the driver is set to the cutoff state. As a result, transmission from the half-duplex transmission line to the full-duplex transmission line is prioritized, and at the connection point of the half-duplex transmission line with the full-duplex transmission line, collision between transmission data and reception data is prevented, The two systems can be connected to different transmission lines. This configuration also simplifies the transmission line and improves reliability.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an optical transmission device according to a specific embodiment of the present invention. FIG. 2 is an explanatory diagram showing electric signals according to the embodiment. FIG. 3 is an explanatory diagram showing the entire transmission path including the optical transmission device according to the embodiment. 10 optical transmission device, 12 modulator, 13 demodulator, 20
… Communication module

Continuing on the front page (72) Inventor Goro Kobayashi 1 Toyota Town, Toyota City, Aichi Prefecture Toyota Motor Corporation (72) Inventor Naonori Nakamura 1 Toyota Town, Toyota City, Aichi Prefecture Toyota Motor Corporation (72) Invention Person Yoichi Shibata 1 Toyota Town, Toyota City, Aichi Prefecture Inside Toyota Motor Corporation (72) Inventor Toshihiro Mori 2-1-1-12 Sonezaki, Kita-ku, Osaka City, Osaka Prefecture Inside Hokuyo Electric Co., Ltd. (56) References JP 56-138350 (JP, A) JP-A-63-18839 (JP, A) JP-A-62-107550 (JP, A) JP-A-60-4344 (JP, A) JP-B-63-28376 (JP, A) B2) (58) Field surveyed (Int.Cl. ⁶ , DB name) H04L 5/14-5/18 H04B 10/00-10/28 H04J 14/00-14/08

Claims (1)

(57) [Claims] An electric signal transmitted to a half-duplex transmission line for performing bidirectional communication on a shared transmission line passes through a receiver, and a full-duplex system for performing bidirectional communication on an individual transmission line. The optical signal is converted to an optical signal by a modulator comprising an optical modulation circuit and transmitted to the transmission line of the optical signal, or the optical signal transmitted to the full-duplex transmission line is converted into an electric signal by a demodulator comprising an optical demodulation circuit. An optical transmission device which is converted into a signal and transmitted to the half-duplex transmission line via a driver, wherein a start bit in a data block of the electric signal passing through the receiver is detected, and at least a start bit of the data block is detected. A first maintenance method for maintaining a transmission direction from the half-duplex transmission line to the full-duplex transmission line via the receiver during a period from the transmission of the start bit to the transmission of the stop bit. A first transmission direction maintaining signal output circuit for outputting a carrier signal, and detecting a start bit in a data block of the electric signal converted by the demodulator, and detecting a stop bit at least after the start bit of the data block is transmitted. A second transmission direction maintaining signal for outputting a second maintenance signal for maintaining a transmission direction from the full-duplex transmission line via the driver to the half-duplex transmission line until transmission. An output circuit, receiving the first sustain signal from the first transmission direction sustain signal output circuit, and receiving the second sustain signal from the second transmission direction sustain signal output circuit, When neither the second sustaining signal is input, the receiver is set to the signal passing state, and the driver is turned off, and the first sustaining signal is output earlier than the second sustaining signal. When the power is input, the receiver is set to a signal passing state to turn off the driver, and when the second sustaining signal is input before the first sustaining signal, the receiver is turned off. When the first sustaining signal and the second sustaining signal are input simultaneously, the switching signal for setting the receiver to the signal passing state and setting the driver to the shutoff state is transmitted to the driver and the driver. An optical transmission device, comprising: a transmission direction switching signal output circuit that outputs the signal to the receiver.