JPH02111196A - Time-sharing remote control system - Google Patents

Abstract

PURPOSE: To connect a central unit to all function units by a simple method by sending a command signal on a two-wire line only for a previously determined 1st period and penerating a response signal on the two-wire line in the previously determined period. CONSTITUTION: The central unit 1 is connected to plural function units 3 by a two-wire lines 2 such as a telephone line. A program preparator 9 allocates code numbers corresponding to counters of a frequency dividing circuit 8 one by one to respective function units 3 in comparators 10, 11. At the moment of '0', the line 2 is conducted and a zero reset device 5 starts an oscillator 6 after the elapse of 10ms. The unit 1 switches a bidirectional relay 13 in accordance with previously determined order. Immediately after the end of a 1st stage, a monostable circuit 20 adjusted to 640ms opens a gate 19. A series of frequency generated from oscillators 18 in different function units 3 applears on the line 2.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a time-division remote control/remote monitoring system.

[Conventional system]

At present, a control and processing central unit is provided in one or more states, each of which has, on the one hand, an activation mechanism which can be controlled by signals coming from the central unit and, on the other hand, whose output signals can be sent to the central unit for processing purposes. No such system is known that is connected in a simple manner to the entire functional unit with sensors.

It is an object of the present invention to provide such a system.

To this end, the invention comprises a two-wire line, such as a telephone line, a central unit 7) connected to the ends of such a line, and a plurality of functional units connected in parallel on such a line. , the central unit is arranged to emit and receive signals on a two-wire line, and each functional unit has coding means for assigning it a code number, a first oscillator, such a counter arranged to count the impulses from the first oscillator, a zero-resetting device for such counter, starting means, a predetermined number of pulses counting from the moment when the content of the counter reaches the value of the code number; means for sending a command signal on a two-wire line to said activation means for a period of time of 1; means for sensing a state of said functional unit; generating a response signal that is a function of said state; and means for transmitting the response signal on the two-wire line during a predetermined second period starting from a predetermined time after the moment when the content of the counter reaches the value of the code number. The object of the present invention is to provide a time-division remote control/monitoring system characterized in that the system includes means for emitting a signal.

In a preferred embodiment of the invention, each functional unit includes means for de-energizing the two-wire line, the zero-resetting device of the counter being specifically activated by energizing this line.

It can be seen that under these conditions the system according to the invention functions in two successive stages.

Upon energization of the line, the zero reset device starts the oscillator/counter of each functional unit. In each unit, the activation means are made to wait until the content of the counter reaches the value of the sequence number of this particular unit. At this moment a "window" opens, so that if the control signal coming from the central unit is on the two-wire line, this signal will activate the activation means. If there is no such signal within the "window", the activation means remain in the state they were in before.

Since each functional unit has a different code number,
Each window will shift over time. It is therefore sufficient to cause the central unit to emit its control signal on the two-wire line in the window corresponding to the functional unit whose activation means are desired to be activated.

The second stage begins after the predetermined time mentioned above has elapsed. This time can of course only be less than the cumulative time of the windows of all functional units.

During this second phase, the different functional units sequentially emit their response signals on the two-wire line in the same order as those of the first phase.

This response signal may translate only the state of the activation means of the functional unit under consideration or may be generated from a local sensor of some physical size. especially,
Using the system according to the invention it is also possible to equip each functional unit with multiple sensors.

In this case, the sensors that have to transmit their information during the second stage are selected by control signals issued by the central unit during the first stage.

The second phase may be interrupted as soon as the entire functional unit issues its response signal, or it may be continued periodically with a period equal to said predetermined time.

In this case, the various functional units continue to emit response signals periodically until a new zero reset intervenes, for example triggered by an interruption of the power supply on the 2yA line.

Preferably, the activation means include bistable relays, in which the functional units are disconnected until the first phase of a new cycle is initiated by reactivation of the line and a control signal is applied to these units during this first phase. It is desirable to have a starting means that maintains the same state during the process.

In a particular embodiment of the invention, said means for emitting a response signal on a two-wire line is controlled by said first oscillator, and a second oscillator is provided for managing the response signal. Good too. Note that the frequency of this second oscillator is adjusted according to the above-mentioned conditions.

EXAMPLES Certain embodiments of the invention will now be described by way of non-limiting example with reference to the accompanying drawings, in which: FIG.

As shown in FIG. 1, the central unit (1) is
A two-wire line (2), such as a telephone line, connects the functional units (3).

Each functional unit is powered by a voltage regulator (4) connected to the line (2).

The zero reset circuit (5) is connected to the output end of the regulator (4), and the output end of the circuit (5) is connected to an oscillator/counter (oscillator integrated wattmeter (6)) induced by the crystal (7). It is arranged so that it can be pulled out.

A frequency divider circuit (8) divides the frequency generated by the oscillator (6).

Each functional unit (3) is programmed by the program creator (9).
), the frequency divider circuit (8
) can be assigned one code number to be compared. If the two inputs of the comparator (10, 11) are equal, they are optionally present on the line (2) via a capacitor (14) and a gate (15) whose control is detailed below. Validate the gate (12) to send a signal to the bistable relay (13).

The bistable relay (13) has on the one hand a working contact (16) capable of activating any desired device.
) and on the other hand via the line (2) the central unit (1
) measurement contact (1) that can send measurement signals to
7) is attached.

A circuit of contacts (17) is connected to this oscillator (18) to vary the frequency of the oscillator depending on whether this contact is open or closed.

The output of the oscillator H (18) is connected to a gate (19) which is controlled by a monostable circuit (2o) which is itself activated by a zero reset signal.

The output terminal of the gamer) (19) has an output terminal connected to the line (2) via the amplifier (22), and the output terminal of the comparator (10, 11).
) is controlled by a signal from another gate (
21).

Furthermore, the output terminal of the monostable circuit (20) is also
-(15) is also controlled.

Figure 2 shows the signals on the line (2) and as an example 1
．． Functional units (3) with code numbers 2 and 3
It shows the function of

In this figure, after the division in the circuit (8), the oscillator (
The signal output from 6) has a period of 10 m5 and is 1, and the signal from VA path (
2) Above, it is assumed that 640 functions and Uniso 1-(3) are connected in parallel.

Since this line is energized at the moment of zero, the zero reset device (5) starts the oscillator (6) after a time of 10m5.9 From this moment on, its code programmed on the programno, creator (9) Units with number equal to 1 (3
) are equal, so the two inputs of the comparator (10, 11) are equal, so
A gate pulse (30) that opens the gate I~(12) appears at the output ◇:also1 of this comparator. Since no frequency is present on the line (2) during this gate opening time, the bistable relay (13) remains at the same value (31).

Next, during the period <IC1m5, the comparator (10, 1
The two outputs of 1) are equal because of the functional unit (3) whose code number programmed on the programmer (9) has the value 2, and thus the output of this programmer has the value 2. Ge~Tbalus (32)
appears, and as a result, game 1 (2) is opened. However, in this case, there is 1
Since there are two frequencies (33), bistable relay a(1
, 1) is activated and its state (34) changes at the moment of occurrence of this frequency.

Similarly, for the function unit 7-Soto having the code number A of C and i, a gate pulse (35) appears at the output of the comparator (10, 11) after 101m5. Since the frequency (36) exists in this instantaneous line (2), the state of the bistable relay (13) of this functional unit of rank l is (
37) is changed every time the point of origin of this frequency changes.

This first stage of functioning of the system according to the invention therefore lasts 650 m5. In other words, 10m5 for zero reset
and 640 m5 for the central unit (1) to review the entire unit (3) with or without switching its bistable relays according to a predetermined sequence.

Since the monostable circuit (20) tripped by the zero reset device (5) has a length of 640 m5, during this first stage it means that any number 13 from the oscillator (18) will not be on the line (2). Block the gate (19) so that it cannot be transmitted.

On the other hand, once this first stage is completed, the monostable circuit (
20) blocks the gate (15) so that no signal can be sent to the bistable relay (13) during the second functional phase.

In this example, this second stage starts from the beginning of the first stage.
50 m5 later, each functional uni-node is therefore offset by 640 m5 in relation to its reception time.
It has a transmission time of m5.

For this purpose, as soon as the first stage is completed, 640 m
The monostable circuit (20) adjusted to 5 is connected to the gate (19)
open. Furthermore, the output (end) of the comparator (10, 11) is
Open gate (21) in the same way as you opened game 1-(12) during the first stage.

Therefore, at the input end of the gate (21), from the output end of the comparator, there is a gate pulse (38) of 10m5 for the rank 1 unit (3), and then a gate pulse (38) for the rank 2 unit (3). A pulse (39) appears, and generally a gate pulse (40) for the rank 1 unit (3).

During the duration of this gate pulse, gates 1- (1, 9 and 21) are open, thus causing the oscillator (18) to emit 1! '' will be sent to the line (2) via the amplifier (22).

Therefore, on the line (2) there appears a series of frequencies emitted by the oscillators (18) of different functional units.

In the example in which the contacts (17) of the relays (13) only indicate whether these relays are open or closed, the central unit () (], ) first connects the rank 1 functional unit (3) from the line (2). a first frequency (41) indicating that the relay (13) of the rank 2 functional unit (3) is open, then a modified frequency (42) indicating that the relay (13) of the functional unit (3) of rank 2 is closed. and generally receives a modified frequency (43) indicating that the relay of the rank 10 functional unit (3) is closed.

In this embodiment, the frequency of the oscillator (18) is modified in an all-or-nothing manner according to the open or closed state of the relay (13), but this frequency is of course within the circuit of the contacts (17). may be modulated according to the state of a sensor located at.

As long as the line (2) remains energized, the second stage continues periodically every 640 m5. As soon as line (2) is de-energized, the cycle is interrupted and the bistable relay (
13) maintains the same position.

It will be appreciated that various changes and modifications may be made to the above description without departing from the spirit and scope of the invention.

[Brief explanation of drawings]

FIG. 1 is a schematic diagram of a system according to the invention. FIG. 2 is a time diagram showing the functioning of this system. Main component numbers 1... Central unit, 2... 2-wire line, 3... Machine TM unit, 6... Oscillator, 9. ... Coding means, 5.12 ... Zero reset device, 13 ...
・・Bistable m electric appliance, 1G・・・・Work contact 1-117・・・・
・Measurement contact, 18...Oscillator, 19.21...Gate. Procedural amendment (method)? Name of the invention Time-division remote control system 3, relationship with the person making the amendment case

Claims (7)

[Claims] (1) a two-wire line (2), a central unit (1) connected to the ends of such line and a plurality of functional units (3) connected in parallel to such line; are arranged to emit and receive signals on a two-wire line, and each functional unit is provided with a coding means (9) for assigning it a code number, a first oscillator (6); ), a counter (6) arranged to calculate the impulses from such a first oscillator, a zero-resetting device for such a counter (
12), activating means (13, 16), which activates the aforementioned activating means on the two-wire line only for a predetermined first period starting from the moment when the content of the counter reaches the value of the code number; means for sending a command signal (12), means for detecting the state of said functional unit (17), means for generating a response signal that is a function of this state (18) and the contents of the counter are means (19, 21, 22). 2. System according to claim 1, characterized in that each functional unit includes means (4) for its power supply from the two-wire line. (3) The system according to claim 2, wherein the counter zero reset device is activated by energizing a two-wire line. (4) The means for managing response signals includes:
4. A system according to any of claims 1 to 3, characterized in that it includes a second oscillator whose frequency is modulated depending on the state. (5) The means for emitting a response signal on the two-wire line is arranged to be controlled by the first oscillator. system described in. (6) The system according to any one of claims 1 to 5, characterized in that the activation means includes a bistable relay (13). (7) The means for emitting the response signal on the two-wire line is arranged to emit the signal at time intervals equal to the predetermined time. , a system according to any one of claims 1 to 5.