JPH02241154A - Communication system - Google Patents

Abstract

PURPOSE:To use a slave station optionally switchingly depending on the presence of application of power by providing a bypass communication line bypassing each slave station and a switch normally closed to be opened when power to a relevant slave station is applied. CONSTITUTION:Plural slave stations (10-1)-(10-n) are connected to a master station 10-0 sequentially through cables (12-1)-(12-n) to form a communication line 12 reaching sequentially from the master station 10-0 to the slave stations (10-1)-(10-n). Moreover, a bypass communication line 14-i is provided, which is branched from the communication line 12 to bypass each slave stations 10-i. When any one of the slave stations 10-i receives a power, the normally closed switch 16-i for the relevant bypass communication line 14-i is opened and the slave station 10-i is inserted to the communication line 12-i. Thus, an optical slave terminal equipment 10-i is selected depending on the presence of power application and inserted to the system.

Description

[Detailed Description of the Invention] [Summary] A communication system in which a plurality of slave stations are sequentially connected to a master station via cables, and a communication path from the master station to each slave station is formed by each cable and slave station. The purpose of this system is to provide a communication system in which slave stations can be selected and used at will, depending on whether the power is turned on or not. In a communication system in which a communication path leading sequentially to a slave station is formed by each cable and slave station, there is a bypass communication path that branches from the communication path and bypasses each slave station, and a bypass communication path that is inserted into each bypass communication path and goes to the corresponding slave station. A normally closed switch that is driven open when the power is turned on is provided.

[Industrial Field of Application] The present invention relates to a communication system in which a plurality of slave stations are sequentially connected to a master station via cables, and a communication path from the master station to each slave station is formed by each cable and slave station. system.

According to this type of system, slave stations can be added one after another, making it possible to expand the system scale as necessary.

[Prior Art] Fig. 4 shows an example of a POS system, in which a master terminal (master station) 1 (master station) serving as a controller is connected to
0 to multiple slave terminals (slave stations) 10j, 102
...φ10-n, 10n+1 is cable 12 1.12
2...12-n and 12-n+1 are connected in sequence.

As a result, terminal 1 (jO, 131, 132...10
Cable 121 connecting between n, 10 and n+1, respectively
, 132φ...12n, 12-n+1 and each terminal 10-1
．． 102...10n+10n+1 internal transfer paths from the master terminal 100 to each slave terminal 10j.

10 2 = 10 n, a communication path 12 sequentially reaching 10-n+1 is formed.

All terminals of this POS system 100.101.132・
...When the power is turned on to 10-n and 10-n+1, the product information etc. sent from the master terminal 100 is transferred to the communication channel 1.
2, each slave terminal 10-1.132
...10 n, 10-n+11'f! 5 are sequentially transferred to each slave terminal 10j, 132...10-n,
10 n+1 becomes in a state where sales data can be input by being given this information.

In addition, each slave terminal 10-1.102...10-n
, 10-n+1, the human-powered sales data is transferred between them in the opposite direction to the master terminal 10-n+1.
Processing related to sales management and inventory management is performed at the master terminal 100 using this collected data.

Here, each terminal 1 (31, 102...1) is connected to the communication path 12.
Since the internal transfer path 0-n is included, when the power is turned off at any slave terminal 131, 102... or 10-n, that slave terminal 101, 102...
Alternatively, the communication path 12 is cut off at 10-n.

As a result, slave terminals 102 .

Therefore, power down the slave terminal 101.10
The order in which 2φ numbers 10n and 10-n+1 are disconnected from the system is based on the slave terminals 13 on the communication path 12.
1.102...10-n, 10-n+1, and the order in which they are added to the system is also constrained.

Therefore, when reducing the number of slave terminals used in the system, slave terminals 1310102...1
The power supplies 0-n and 10n+1 are sequentially turned off from the terminal side of the communication path 12.

Furthermore, when increasing the number of slave terminals used in the system, the slave terminals 101, 102, .

[Problems to be Solved by the Invention] As described above, conventionally, slave terminals 10-1.
Since the order in which 102...10-n and 10n+1 are separated or added is restricted by their arrangement on the communication path 12, each checkout can be done according to the flow of customers to each cashier and the convenience of each cashier. Slave terminals 10j, 132...10
n, 10-n+1 cannot be freely selected and used, which makes it difficult to use the system flexibly.

The present invention has been made in view of the above-mentioned conventional problems,
The purpose is to provide a communication system that allows slave stations to be arbitrarily selected and used depending on whether or not the power is turned on.

[Means for Solving the Problems] In order to achieve the above object, a communication system according to the present invention is configured as shown in FIG.

In the same figure (A), a plurality of slave stations 101,132...10n are connected to a master station 100 by cables 121
．． 15J2...12-n, and from the master station 100 to each slave station 10j, 13
2...10n, the communication path 12 sequentially leads to each cable 121.12-2...12-n and the slave station 10.
1.132...10-n.

In this system, as shown in FIG.
Branching from each slave station 10-i (i=1 to n)
Bypass communication path 14i (i=1 to n) that bypasses
will be provided.

And normally closed switch 1 is connected to these bypass communication paths 14-1.
6-i (i=1 to n) are respectively inserted, and the normally closed switch 16-■ is driven open when the corresponding slave station 10-i is powered on.

[Operation] In the present invention, when power is turned on to any slave station 10-1, the normally closed switch 16-1 of the corresponding bypass communication path 14-1 is opened, so that the communication path 12 is connected to the normally closed switch 16-1. Slave station 101 is inserted.

Also, when the power of this slave station 10i is turned off, the switch 1 of the corresponding bypass route 14-1 is turned off.
6-1 is closed, the slave station 1 is connected from the communication path 12.
0-1 are separated.

[Embodiments] Hereinafter, preferred embodiments of the system according to the present invention will be described based on the drawings.

Figure 2 shows the configuration of the POS system.
A plurality of slave stations 101, 10, -2...10 to a master terminal 100 serving as a controller of the S system
n, 10 n+1 is cable 131.12-2...
12-n + 12-n +1, respectively.

As a result, from terminal 100 to each slave terminal 101.10
A round trip communication path 12 is formed that sequentially reaches numbers 2 and 10n and 10n+1.

In the slave terminals 10-1, 132, .
A pair of bypass communication paths 14-1014-2...14-n are provided to bypass 1,232...2On.

Furthermore, each slave terminal 10 1. IC12...-10-
n both bypass communication paths 14-1, 142...14-n
is a normally closed switch (can be configured with a relay) 1B-1,1
6-2 .
-n are each driven open.

This embodiment has the above configuration, and its operation will be explained below.

Any one of slave terminals 10j, 132...10n
If power is not applied to 0-1, its main body 20-
1, the corresponding normally closed switches 16-1 are not driven open, and the bypass communication paths 14-1 into which they are inserted are both closed, as shown in FIG. 3(A).

Therefore, the communication path 12 bypasses the slave terminal 10 i, and the slave terminal 10-1 is separated from the communication path 12, and the slave terminals 1O-i-1 and 10-i+1 on both sides of the slave terminal 10i are unable to communicate. It is directly connected by Route 12.

Also, when the slave terminal 10-1ζ is powered on,
Since both normally closed switches 161 are driven open in the main body 20i, the bypass communication path 14 into which these are inserted
-1 is opened as shown in FIG. 3(B).

−10= Therefore, the communication path 12 does not bypass the slave terminal 10,
Therefore, slave terminal 10-i is slave terminal 10-i.
It is inserted between i-1 and 10-i+1.

As shown above, the slave terminal 10 is not powered on.
-i (i=1 to n) is bypassed, so slave terminals 101, 102...10-n, 1 excluding this
A round trip communication path 12 is formed sequentially from the master terminal 100 to 0-n+1.

Therefore, even if the power of the slave terminal 10-1 is turned off, the slave terminal 1, which is the terminal side of the communication path 12,
0- i+1-...10-n+1 and master terminal 10
Communication with 0 can be continued as is.

Furthermore, even if the power of the slave terminals 10-1, . It can be inserted into 12.

As described above, according to this embodiment, it is possible to select any slave terminal 10-1 and disconnect it from the system or insert it into the system, depending on whether the power is turned on or not, so that the slave terminal 101. 102...10-n, 1
0-n+1 can be used freely.

Therefore, slave terminals 10-1, 1 (32...1
It becomes possible to construct a highly flexible system that can efficiently use 0 n and 10 n+1.

[Effects of the Invention] As explained above, according to the present invention, any slave station can be freely disconnected from the system or easily added to the system as needed, so the flexibility of the system configuration is increased and each slave station can be used efficiently.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of the configuration of the invention, FIG. 2 is an explanatory diagram of the configuration of the embodiment, FIG. 3 is an explanatory diagram of the operation of the embodiment, and FIG. 4 is an explanatory diagram of the configuration of the conventional example. 0...Master PO8 terminal, 1.102...10-n, 10 n+1 block number slave PO8 terminal, 12...Communication path, 1.12-2...12-n, 12 n+1. ... Cable, 1, 14-2.14-n ... Bypass passage, 1.18-2 ... 16-n ... Normally closed switch, 1.20-2 ... 20-n φ・Main body of slave PO8 terminal. Action explanatory diagram of the embodiment

Claims (1)

[Claims] A master station (10_0) has a plurality of slave stations (10
___1, 10___2...10___n) is the cable (1
2__1, 12__2...12__n), and the communication path (12) from the master station (10__0) to each slave station (10__1, 10__2...10__n) is connected to each cable (12__1, 12__n).
___2...12___n) and slave station (10___1
, 10__2...10__n), each slave station (10_i
, i=1 to n).
___i, i=1~n), and a normally closed switch (16___i, i=1~n) inserted into each bypass communication path (14___i) and driven open when the corresponding slave station (10___i) is powered on. A communication system characterized by: n).