FR2474790A1 - Transmission system connecting processor to peripherals - has dual conductor transmission lines which become unidirectional when accessed, for duration of communication plus processing - Google Patents

Abstract

The system used for series information transfer has the messages fed through at least one amplifier. When no message is present the two-wire communications line is accessible in both directions. Reception of a message at one end of the line locks the transmission direction in the required propagation sense and blocks transmission in the opposite sense, for a duration equal to that of the message plus the time required for it to be fed through the interface and amplification circuit. Pref. an optoelectronic coupling is used between each interface and the line, to provide galvanic separation between them. The system is designed to prevent the transmitted messages being subject to interference.

Description

METHOD AND DEVICE FOR BIDIRECTIONAL TRANSMISSION
LOGICAL INFORMATION WITH HIGH IMMUNITY TO PARASITES
The present invention relates to a method and a device for serial transmission, bidirectional, fast, on two-wire shielded lines ("twinax" type) of logical information exchanged between several equipment connected on the same line, having a high immunity to parasites.

It applies, in particular, to the exchange of logical information in the form of messages, between the central unit of a computer and a plurality of peripherals, such as: display screen, printers. In what follows, we will agree to call "message" the logical information exchanged between the various equipment.

The use of transmission lianas presents serious difficulties as soon as they reach hectometres or kilometric lengths, especially in industrial environments where the conmutations of high power electliclues cause significant parasites. In addition, the disparity of earthquakes used over such distances often generates traffic currents which are also a source of parasites. It is difficult and very expensive to build truly equipotential ground connections.

The use of "modems" could be a solution, but the transmission speed is then much too low, and unsuited to the processing capacity of the central unit.

The object of the invention is a method of serial transmission, bidirectional, fast, on two-wire shielded lines, messages constituted by logical information exchanged between several stations connected on the same line by interface means, such as a central unit and a plurality of peripherals, for rendering the transmission insensitive to the parasites and in which the messages pass through at least one amplification means, a method according to which, in the absence of a message, the line is accessible in both meaning, and the first message that occurs at one end of the line locks the transmission in the sense that the message is propagated, and blocks any transmission in the opposite direction, for a duration equal to that of the message increased time of propagation of the information in the interface and amplification means.

In addition, each station can also be galvanically isolated from the transmission line, and the various stations together, in particular by opto-electronic couplers.

In the case where the transmission line is relatively long, the logic signals are amplified before their introduction on the line.

Each direction of transmission has separate but interlocking amplification means.

Another object of the invention is a device for implementing the two-way serial transmission method, on two-wire shielded lines, as defined above, made between cracks and the transmission line, a means of bidirectional lockable interface, a path for the forward direction and a path for the return direction, each path having at least one amplifier element which can be blocked by applying a signal produced by the passage of a message on the other path.

The blockable amplifier element may be a differential amplifier provided with a "validation" input (strobe) which makes it possible to inhibit its operation or to authorize it according to the level (0 or 1) of the signal present on said input. This lockable element can also be an optoelectronic coupler provided with a "validation" input.

The blocking signal of the amplifier of one channel is taken at the output of the amplifier of the other channel, through a cell with a time constant, the time constant being at least equal to the propagation time. the message in the amplifier and at most equal to the interval between a message and a return message.

FIG. 1 represents a transmission device according to the invention.

FIG. 2 schematically illustrates an information processing assembly comprising a central unit and peripherals connected to the transmission lines.

Figure 3 shows the flow diagram of messages on the transmission line.

The central unit (1) of a computer is connected via the device according to the invention (2) to a transmission line (3), called a "long-distance line" connected, also by the intermediate devices according to the invention, to a number of devices (4a) (4b) (4c) (4d) (Figure 2).

In FIG. 1, the element (5) that will be called "station" in the following, which may be the central unit or a peripheral, is connected by a shielded two-wire line element (6). twinax) (matched impedance) to an input of the lockable bidirectional interface (7) which is delimited by the dashed line frame and which is preferably arranged in a metal cabinet provided with connectors at the input and output lines ( 8) and (9).

Each conductor (10) and (11) of the two-wire line is connected to the positive and negative inputs of the differential amplifier A1 and, respectively, to the negative and positive inputs of the differential amplifier A2, so as to switch automatically the positive signals. and negative. In addition, two resistors R1 and R2 of 56 olms provide impedance matching between the line and the inputs of A1 and A2. Although A1 and A2 may be of any type, it is particularly advantageous to use an integrated model having a sensitivity adjustment possibility, which is performed here by injecting a current on the control terminal, starting from Potentiometric dividers P1 - R15 / P2
R16 (decoupled by a capacity of 10 nF), with a series resistance R13 / R14.

The DS 8820 AN model of "National Semi-conductors" is particularly suitable for this function.

The signals from the stations are of the positive "three-state logic" type, for the logic level 1, negative for the logic level 0, and "free line" in the absence of bit.

Al and A2 are fed conventionally from a stabilized DC voltage source which is here 5 volts.

The logic signals amplified by A1 and A2 control, by means of transistors T1 and T2 mounted, in the usual manner, as a common emitter amplifier, the LEDs LED-1 and LED-2 of the two optoelectronic couplers Ci-I and Ci-2, high bandwidth, and high rate of rise (at least 1 tEz with Tp {45 nS) and isolation at least equal to 1000 volts, for example HCPL 2602 Hewlett-Packard type.

The output of each photocoupler A1 and A2 controls a transistor current generator (T3 - T5 - T7 and T4 - T6 - T8).

The photocouplers Ci-1 and Ci-2 are supplied with a steady and stabilized voltage of 5 volts. The current generators are preferably supplied with a higher voltage (also continuous and stabilized), which can reach, for example, 18 to 20 volts), which makes it possible to send on the "long distance line" (9 ) signals of up to 15 volts, at an ampere-peak, at logic level 1, which is used to supply a line of not less than 2 meters in order to obtain, at the end of the line, a level sufficient to maintain the immunity to parasites.

In the direction "signal return" of the line (9) to the station, there is, below the line AB of Figure 2, the same type of circuit as in the forward direction, that is to say say: two differential amplifiers
A3 and A4 with adjustable sensitivity, from potentiometric dividers
P3-R17 and P4-R13, decoupled by 10 nF, two transistors amplifiers T11 and T12 as a common emitter supplying the LED-3 and LED-4 diodes of the optoelectronic couplers Ci-3 and Ci-4. On the other hand, the output splitter, which only supplies a short link line with the station (5), is reduced to the two transistors T9 and T10, conventionally mounted as a common emitter.

In the embodiment of FIG. 1, it can be seen that there is a galvanic isolation between the substation and the long-distance line which is therefore mounted "floating". It can therefore have, therefore, a galvanic isolation of all connected equipment, with the grounding of each of them individually, at the place where it is, without any risk to convey on the line of the currents of parasitic traffic due to non - equipotential lands and, in addition, rejection of other types of noise due to the Al - A2 - A3 - A4 differential amplifiers which have a very high common mode rejection rate.

Strictly speaking, this galvanic isolation is only necessary if all the substations are on a site that is largely developed in the horizontal plane, such as chemical plants, refineries, aluminum electrolysis plants, warehouses, where the distances reach and exceed the kilometer. When the stations are grouped in a vertical building, even of great height, this problem is less critical, because it is easier to have a single ground.

The function of the device, object of the invention, can be described as follows
The organization of message exchanges between a central unit and the various peripherals or peripherals - the most commonly under farm of "words" of 8 or 16 bits - is done with a certain time interval between the messages "iler" and the "back" messages. This interval is defined by the amximal length of the "long distance line" and the message transmission speed, as well as by the response time of the controlled systems, so as to avoid the overlapping of messages coming from a peripheral close to the This time interval is used to interverroll the transmitters and receivers in the system in order to avoid the cumulative effect of the transmitters on the receivers connected to the same line.

In the idle state, the line is free and the system is ready to receive or transmit messages on either side of the optoelectronic barrier. The voltage across each two-wire line is zero.

The first message on one side of the device locks (by a mechanism to be specified below) in the direction of arrival of the message. This locking is maintained by a circuit with a time constant which is prolonged for a time a little longer than the response time of the system and a little shorter than the time intervals existing between a forward message and a return message. During this time, the line is accessible only to the first message that came up. After passing this message, and after this delay, the device is again ready to receive - and amplify - the first message that will be presented in one direction or the other.

The locking mechanism is as follows: the outputs of the amplifiers A1 and A2, at the moment of arrival of a signal, discharge, by the diodes D1 and D2, the capacitors C1 and C2, connected to the inputs "validation" (strobe ) photocouplers Ci-3 and Ci-4 which are thus inhibited, this locking being maintained after passage of the signal, by the time constant of the cells R3-C1 and R4-C2.

In addition, from the outputs of the photocouplers Ci-i and Ci-2, the same locking of the amplifiers A3 and A4 is carried out thanks to the diodes
D3 and D4 connected, respectively, to the inputs "validation" (strobe) of A3 and A4, with also a time constant determined by the cells RiC5 and R6-C6 and this, in order to prolong the lock at the end of signal of a time substantially equal to the propagation time of the photocouplers.

So, during the passage of a message going from the post to the line by
A1-A2, the amplifiers A3-A4 and the photocouplers Ci-3 and Ci-4 are inhibited. The line will be released after the delay caused by the R3-C1, R4-C2, R5-C5 and R6-C6 time constant cells.

In the opposite direction, the locking mechanism is identical, the locking being ensured by the diodes D5, D6, D7, D8 and the delays by the cells R7-C7, R8-C8, R9-C11 and R10-C10.

FIG. 3 schematically shows the flow of signals in the "out" and "back" directions.

Diagram 3a shows an example of the width of each message and the interval between "go" messages and "return" messages, and the state of the line (free or busy).

Diagram 3b shows an example of expanded "go" and "return" messages so as to make the sequence of bits O and 1 visible.

At time to, the line is free. The amp "go" (A1-A2) and "return" (A3-A4) are unlocked (passersby).

At time t1, a message 1-A is in the "out" direction at the input of A1. It has been symbolically represented at a high level, because it will be amplified before committing to the "distance" line. Al-A2 therefore remain passersby and A3-A4 are locked (as well as Ci-3 and Ci-3). 4).

At time t2: end of the message sent. But, in practice, the message will occupy the line until t because of the propagation delay of the amplifier (t3) and the photocoupler (t4); thanks to the constants C3-C1-R4-C2 and R5-C5-R6-C6, the unlocking takes place only at t4. The line is free again. Occurs, then, at time t5, a "return" message (1-R), figured with a lower level, due to its attenuation in the line. (It is, moreover, deformed in particular by the capacities of the distance line.The shape represented is also schematic and simplified).

The transmitted message theoretically stops at t6 but, for the reasons explained above, the opening time of the line up to t7 is extended to take account of the transmission delay in A3-A4 and up to t8 for take into account the transmission delay in the photocouplers Ci-3
Ci-4. At t8, the line is released; a new message go 2-A appears at t9 and the process starts again as at tl.

EXENIPLE OF APPLICATION
The invention has been applied to an information processing system of the IBPI-34 type, installed in an aluminum production plant by electrolysis of alumina dissolved in molten cryolite, comprising several hundred tanks fed under 110,000. amps. The entire plant extends over an area of 1/2 kilometer-square with distances between end stations reaching 1400 m.

A transmission test on a single two-wire shielded line (twinax) between the central unit and the peripherals has totally failed due to the level of all types of pests (circulation currents between non-equipotential lands, very high power consumption).

The implementation of the method and of the device according to the invention, in accordance with the diagram of FIG. 1, has ensured perfectly secure transmissions of messages, without parasites, with a speed of 1 Mbits / second, which makes it possible to use as much as possible the processing capacity of the CPU.

The same link, made by Modem, would lead to a speed about 100 times lower. In addition, the high-rental price of the modem would further increase the unfavorable balance of this solution.

NOMENCLATURE OF THE ELEMENTS OF FIGURE 1

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Claims (10)

1 / - Serial transmission method, bidirectional, fast, on two-wire shielded lines of messages consisting of logical information exchanged between several stations connected on the same line by interface means, such as the central unit of a computer and a plurality of peripherals, for rendering the transmission insensitive to the parasites and in which the messages pass through at least one amplification means, characterized in that, in the absence of a message, the line is accessible in both directions, and in that the first message which occurs at one end of the line locks said transmission in the sense that the message propagates and blocks any transmission in the opposite direction, for a duration equal to that of the increased message of the delay of the transmission. information in the interface and amplification means. 20 / - Transmission process according to claim 1 characterized n that is isolated galvanically each station of the transmission line. 30 / - Transmission method according to claim 2, characterized in that the isolation is achieved by the use, as interface means between the stations and the line, optoelectronic couplers.  4 / - Transmission method according to any one of claims 1 to 3, characterized in that all the stations are electrically isolated from each other. 50 / - A transmission method according to any one of claims 1 to 4, characterized in that the logic signals are amplified before their introduction on the transmission line. 60 / - A transmission method according to any one of claims 1 to 5, characterized in that each station is connected to the line by separate amplifiers, but interlockable for each direction of transmission. 70 / - A transmission method according to any one of claims 1 to 6, characterized in that amplifies the signal-emitted by the station to the line up to a level sufficient to compensate for the weakening in the line of transmission. 80 / - Device for implementing the transmission method according to any one of claims 1 to 7, characterized in that it comprises between each station and the transmission line, a bidirectional locking interface means, comprising a path for the forward direction and a path for the return direction, each path having at least one lockable amplifier element by applying a signal produced by the passage of a message on the other path. 90 / - Device according to claim 8, characterized in that the blockable amplifier element is a differential amplifier provided with a "validation" input. 100 / - Device according to claim 8, characterized in that the blockable amplifier element is an optoelectronic coupler provided with a "validation" input. 110 / - Device according to any one of claims 8 to 10, ca characterized in that the input of the blocking signal of an amplifier of a channel is connected to the output of an amplifier of the other channel.  12 / - Device according to any one of claims 8 to 11, characterized in that the connection between the amplifier of a channel and the sampling input of the amplifier of the other channel comprises a constant cell of predetermined time. 130 / - Device for implementing the method according to claim 12, characterized in that the time constant of the cell is at least equal to the propagation time of the message in the amplifier. 140 / - Device for implementing the method according to claim 12, characterized in that the time constant of the cell is at most equal to the interval between a forward message and a return message.  15 / - Application of the method and the device according to any one of the preceding claims to the rapid bidirectional transmission of logic information in a highly parasitic environment.