JPS62271596A - Automatic setting system for terminal equipment number - Google Patents

Abstract

PURPOSE:To automatically set the number of a terminal equipment by continuously connecting plural terminal equipment through a highway and a numbering signal line and incrementing the number of each terminal equipment with '1' and transmitting the incremented number to the numbering signal line. CONSTITUTION:The terminal equipments 1-1-1-n are provided with a circuit 3 incrementing with '1', and continuously connected by the numbering signal line 4 through the circuit 3. The number that the circuit 3 increments with '1' is set as the number of the terminal equipment. Since the number that the circuit 3 increments with '1' is transferred to the next terminal equipment according to the order of connecting the equipments 1-1-1-n, the numbers of the next and subsequent terminal equipments are automatically set after the number of the 1st terminal equipment is decided. Consequently, only by cascade connecting the terminal equipment, numbers their numbers are automatically set.

Description

[Detailed Description of the Invention] 3. Detailed Description of the Invention [Summary] A plurality of terminal devices are cascaded by a highway and a number setting signal line, and each terminal device increments the number by 1 and connects the number setting signal line to the number setting signal line. By sending the information, the terminal device number which is sequentially incremented by 1 is automatically set.

[Industrial application field]

The present invention provides a system in which a plurality of terminal devices are cascaded to a switching network via a highway and multiplexed data on the highway is distributed according to terminal device numbers.
This invention relates to an automatic terminal device number setting method that automatically sets terminal device numbers by cascading terminal device numbers.

A configuration is known that simplifies the connection configuration between a switching network and a plurality of terminal devices by cascade-connecting a plurality of terminal devices via a highway and distributing multiplexed data to each terminal device according to the terminal device number. ing. In such a configuration, it is desired to be able to easily and error-freely set the terminal device number during system construction or maintenance.

[Conventional technology]

A conventional system in which a plurality of terminal devices are connected in cascade to a switching network has, for example, the configuration shown in FIG.
is a switching network, 331 is an optical highway, 33 is a highway, 34 is a photoelectric conversion unit, 35.38 is a selector,
36 and 39 are setting units, 37 is a demultiplexing unit, and each of the terminal devices 31-1 to 31-4 has the same configuration.

The selector 35 selects an input terminal according to the setting contents of the setting section 36, and the selector 38 selects the data separated by the demultiplexing section 37 according to the setting contents of the setting section 39. In this case, the terminal devices 31-1 to
Since a terminal device number is set in each of the setting sections 39 corresponding to 3I-4, different separated data are selected by the selector 38. Further, the first terminal device ff311 with respect to the switching network 32 is connected to the switching network 32 via an optical highway 33', and the terminal devices 31-1 to 31-3 are connected to each other via a highway for transmitting data using electrical signals. 33.

For example, if the optical highway 33' transmits an 8 Mb/S optical signal obtained by multiplexing four 2 Mb/s highways into one, the first terminal device 31-1
It is converted into an electric signal by the photoelectric conversion section 34 of the setting section 3.
Since the selector 35 controlled by 6 selects the photoelectric conversion section 34 side as shown by the dotted line, the 8 Mb/S multiplexed data converted into an electrical signal is transmitted to the next terminal device 31-
2 via the highway 33, and is separated into four highways of 2 Mb/s in the demultiplexer 37 and added to the selector 38. This selector 38 selects and outputs the first of the four highways separated by the demultiplexer 37 as shown by the dotted line according to the number of the terminal device 31-1 set in the setting part 39.

Also, 8 Mb/5 multiplexed data is added from the selector 35 to the selector 35 of the next terminal device 31-2 via the highway 33, and at this time, as shown by the dotted line, according to the settings of the setting section 36, Selector 35 is highway 3
Select the terminal side of 3. Then, the four 2 Mb/s highways separated by the demultiplexing unit 37 select and output number 2, as shown by the dotted line, according to the number of the terminal device 31-2 set in the setting unit 39.

Also, the multiplexed data is transferred from the selector 35 to the next terminal device 31-3 via the highway 33, and this terminal device 3
1-3, demultiplexed 2 Mb/s
The third of the four highways is selected, and the multiplexed data is further transferred to the next terminal device 31-4 via the highway 33, and in this terminal device 31-4, the demultiplexed 2 Mb /S highway number 4 is selected.

FIG. 4 is an explanatory diagram of distribution in the terminal device described above,
The multiplexed data of 8 Mb/s is transmitted to each terminal device 31.
-1 to 31-4 are separated into four 2 Mb/s highways #0 to #3, and the first terminal device 31-
1 selects highway #0, and the second terminal device 31-2 selects highway #1,
The third terminal device 31-3 selects highway #2, and the fourth terminal device 31-4 selects highway #3.

On the switching network 32 side, terminal devices 31-1 to 31-
Optical Highway 33 is multiplexed according to the connection order of 4.
', each terminal device 31-1 to 31-4 separates, for example, 8 Mb/s multiplexed data according to the terminal device number set in the setting section 39, and
You will have to choose from four highways: b/s.

[Problem that the invention seeks to solve]

Setting section 36.3 in each terminal device 3I-1 to 31-4
9 is generally configured to be set using a construction terminal. Therefore, when maintenance work such as package replacement is performed, the settings must be reset based on materials such as annotations. In that case, there is a possibility that the settings are incorrect, and selector 35.3
There was a drawback that setting of the setting sections 36 and 39 for controlling the 8 was not easy.

An object of the present invention is to automatically set a terminal device number simply by cascading terminal devices.

[Means for solving problems]

The automatic terminal device number setting method of the present invention is to sequentially and automatically set terminal device numbers by cascading connections using number setting signal lines, and will be explained with reference to FIG. By setting terminal numbers to a plurality of terminal devices 1-1 to 1-n cascade-connected by Highway 2,
In a system in which the multiplexed data transmitted to the
Terminal device 1-1 via number setting signal line 4 via circuit 3
.about.l-n are connected in cascade, and the number incremented by +1 by this +1 circuit 3 is set as the terminal device number.

[Effect]

Terminal devices 1-1 to cascade-connected via highway 2
According to the connection order of 1-n, the number incremented by +1 by the +1 circuit 3 is transferred to the next terminal device, so when the number of the first terminal device is determined, the numbers of the subsequent terminal devices are automatically set. will be determined. Therefore, it is possible to automatically set the terminal device numbers simply by cascading the terminal device numbers.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 2 is a block diagram of an embodiment of the present invention, showing two terminal devices among a plurality of terminal devices.

In the figure, 11-1 and 11-2 are terminal devices, 12 is a highway, 12' is an optical highway connected to a switching network (not shown), 13 is a number setting signal line, 14 is a photoelectric conversion unit, 15 is a selector, 16 is a demultiplexer, 17
is a selector for selecting demultiplexed data, 18-2
1 is a light emitting diode and a phototransistor that constitute a photocoupler, 22.23 is an inverter, 24.25 is an OR circuit, 26 to 28 are NAND circuits, T1 to T7 are connection terminals, and the TI eye is connected to the optical highway 12'. It is a connection terminal.

The OR circuit 25 and the NAND circuits 26 to 28 constitute a +1 circuit in FIG. 1, which adds +1 to the terminal device number of the 2-via configuration. Also, hotokabura and inverter 2
2.23 and the OR circuit 24 constitute a setting section for setting a terminal device number, and the selector 17 constitutes the distribution section 5 in FIG.

As in the case shown in FIG. 3, the first terminal + UA device 11-1 is connected to a switching network (not shown) via an optical highway 121, and this optical highway 12' It is connected to terminal T1. Also, terminal device 1
1-1.11-2, the terminal T5 of the terminal device 11-1 and the terminal T2 of the terminal device 11-2 are connected by the highway 12, and the terminal T6. T7 and terminal T3 of the terminal device 11-2. T4 is number setting signal line 1
Connected by 3.

In the first terminal device flll, the optical highway 12
The optical signal transmitted through the optical signal is converted into an electrical signal by the photoelectric converter 14 and applied to the selector 15. At this time, this terminal device 11-1 has terminal T3. Since nothing is connected to T4, the light emitting diodes 18 and 19 do not emit light, and the phototransistors 20 and 21 are turned off. Therefore, the output signals of the inverters 22 and 23 become "0", and the terminal device number becomes "00"=0. Then, since the output signal of the OR circuit 24 becomes "0", the selector 15 selects the photoelectric conversion unit 1 as shown by the dotted line.
You will have to choose between 4 sides.

The output signals of the inverters 22 and 23 are also applied to the selector 17, and the selector 17 selects the first of the four demultiplexed highways, as shown by the dotted line.

Further, the output signals of the inverters 22 and 23 are applied to the light emitting diode 19 of the next terminal device 11-2 via the OR circuit 25 and the NAND circuit 26, and in this case, a signal of "1" (high level) is applied. Since the light emitting diode 19 is added to the light emitting diode 19, the light emitting diode 19 does not emit light, and therefore the phototransistor 21 is in an off state. Further, the output signal of the inverter 22 is applied to the light emitting diode 18 via the NAND circuits 27 and 28, and in this case, a "0" (low level) signal is applied to the light emitting diode 18. emits light, and the phototransistor 20 is turned on.

Since the phototransistor 20 is on and the phototransistor 21 is off, the output signals of the inverters 22 and 23 become "1" and O. By setting “01” to the lower bit, this terminal device number becomes “01”.
The terminal device Ii number causes the selector 17 to select number 2 of the four demultiplexed highways as shown by the dotted line. Also, each time the output signal of the OR circuit 24 becomes "L", the selector 15
The terminal T2 side is selected as shown by the dotted line. That is, when the 2-bit terminal device number includes a bit that is "1", the selector 15 selects the terminal T2 side.

Then, since the output signal of the OR circuit 25 of the terminal device 11-2 becomes "1", the output signal of the NAND circuit 26 becomes "0".
Therefore, the output signal of the NAND circuit 28 becomes "1". That is, the number setting signal line 1 is connected to the next terminal bag W (not shown).
3, the terminal device number “01” of the terminal device 11-2=
The terminal device number of 10″-2 is transferred by +1 to 1. Furthermore, +1 is added to the next terminal device (not shown).
+1 was added to the terminal device number “10”-2 by the circuit.
The terminal device number 11"-3 will be transferred. Therefore, the terminal device number of the terminal device 11-1 will be set to 0, and the terminal device numbers I and 2.3 will be sequentially set.

As mentioned above, by simply cascade-connecting terminal devices in sequence using the number setting signal line 13, each terminal device will be set with a terminal device number according to the connection order, and even if packages are exchanged, etc. However, if the terminal device numbers are connected in cascade through the number setting signal line 13, the terminal device numbers are automatically set, and no setting errors occur.

Furthermore, although the case where the connection with the switching network is shown by an optical highway is shown, it is of course possible to connect by a highway that transmits multiplexed data using electrical signals. In this case, the photoelectric conversion unit 14. The selector 15 and the OR circuit 24 can be omitted. Also, an OR circuit 25 constituting a +1 circuit. NAND circuits 26-28 can also be implemented with other gate circuit configurations.

〔Effect of the invention〕

As explained above, the present invention provides a plurality of terminal devices 1-1
~]-n is provided with +1 circuit 3, terminal devices 1-1 to 1-n are connected in cascade via highway 2, and +1 circuit 3 is provided in +1 circuit 3.
are connected in cascade by number setting signal line 4 through
The number incremented by 1 by the circuit 3 is set as the terminal device number, and compared to the conventional example in which the terminal device number is set according to the order information, the terminal device can be connected simply by cascading via the number setting signal line 4. Since the number can be set, errors in setting the terminal device number will not occur. In addition, when replacing the package, simply by connecting the number setting signal line 4, the terminal device number will be automatically reset.
This has the advantage that the terminal device number can be set easily and without error.

[Brief explanation of drawings]

Fig. 1 is a block diagram of the principle of the present invention, Fig. 2 is a block diagram of an embodiment of the invention, Fig. 3 is a block diagram of a conventional example, and Fig. 4 is a block diagram of the principle of the present invention.
The figure is an explanatory diagram of distribution in a terminal device. 1-1 to l-n are terminal devices, 2 is highway, 3 is +1
circuit, 4 is number setting signal line, 5 is distribution section, 11-1.1
1-2 is a terminal device, 121 is an optical highway, 12 is a highway, 13 is a number setting signal line, 14 is a photoelectric conversion unit, 1
5.17 is a selector, 16 is a demultiplexer, 18.19 is a light emitting diode, 20.21 is a phototransistor, 22
．． 23 is an inverter, 24.25 is an OR circuit, T1 to T
7 is a connection terminal.

Claims (1)

[Claims] Terminal device numbers are set for a plurality of terminal devices (1-1) to (1-n) cascade-connected by the highway (2), and multiplexed data is transmitted by the highway (2). According to the terminal device number set, the terminal device (1-
1) In a system for distributing to each of (1-n), a +1 circuit (3) is provided for each of the terminal devices (1-1) to (1-n), and the terminal devices (1-1) to (1-n) are each provided with a +1 circuit (3). (1-n) are sequentially connected in cascade through the +1 circuit (3) by the number setting signal line (4), and the number incremented by 1 by the +1 circuit (3) is set as the terminal device number. Automatic terminal device number setting method.