JPS5846465A - Money transaction processing system - Google Patents

Abstract

PURPOSE:To display information on each terminal and status information on each subordinate machine at a master device, by providing a master-device centralized remote monitoring controller with a memory for storing status information on subordinate-device centralized remote monitoring controllers. CONSTITUTION:A centralized remote monitoring controller CRMC consists of a memory 12 stored with the execution program of a CPU11 for monitoring control over unattended equipment and various data, a channel device 13 for connecting the unattended equipment, a power source 14, a timepiece 15, and a communication device 16. Terminals A1-A8 of the channel device 13 are connected to the unattended equipment 4 respectively, and a terminal B is connected to a display device 3. This terminal B is unnecessary when the CRMC is a subordinate device of a master-subordinate system and has no display device. Data transfer between the CRMC and each unattended equipment 4 is performed efficiently by applying DMA transfer. The communication device 16 is used for communication with another CRMC of the master-subordinate system.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a financial transaction processing system using an automatic teller machine, an automatic teller machine, or the like as a terminal.

This type of financial transaction processing system includes automated teller machines (hereinafter referred to as CDs), automated teller machines (hereinafter referred to as ATMs), automatic teller machines (hereinafter referred to as ADs), and automated teller machines (hereinafter referred to as ADs) that process deposits and withdrawals for customers. Unmanned devices such as currency exchange machines are used as terminals, and these terminals are centrally monitored and controlled by a centralized remote monitoring and control device (hereinafter referred to as ORMO) connected through a transmission line.

FIG. 1 shows how the unmanned equipment group and ORMO are connected. Multiple A'I'M's and CDs (4) are CR
Connected to M O(1). As a transmission method between these, a four-wire start-stop synchronization method or a modem interface method is used. ORM O (1) is a display device (3)
It is equipped with The display device (3) includes a keyboard (hereinafter referred to as KB) which will be described later. In this example, the display device (3) displays various data on a cathode ray tube (hereinafter referred to as CRT). The system shown in Figure 1 is called a child system in comparison with the system shown in Figure 2.
(1) is a slave device.

FIG. 2 shows an example in which multiple CRMCs are used, and this is called a parent-child system. One of the multiple (:!RMOs) is the base unit (indicated by (2)), and this CRMC (2)
Multiple other C! Connect RMO(1). The connection between CRM C (1) and (2) may be by a modem interface method using a specific communication line or public communication line, a modem (5) and a modem branching device (6), or by a 4-wire start-stop method. A synchronous method may also be used. C! A large number of unmanned devices (4) are connected to the RM O (1), as in the case of the child system. C
! RM C! A plurality of unmanned devices (4) can also be connected to (2). In a parent-child system, the display device (
3) is the main unit CRM C! It may be provided in (2), and is not necessarily required in CRM O (1) of the slave device.

By the way, in the above parent-child system applied when the amount of financial information is relatively large, the target monitored by the display device (3) is the unmanned device (4) connected to the CRMC (1) of each child device. is common. In other words, even if the master unit can grasp the status of each unmanned device (4), the ORM C! It is not possible to grasp the state of (1).

Under normal conditions this is not a problem.

However, for example, if it takes time to load the program of the slave unit CRM O(1), if the master unit ORMO(2) cannot grasp the status of the slave unit, the slave unit C! RM C (1)
This means that it will not be possible to accurately determine when the program starts. Additionally, if the status of the unmanned device (4) cannot be determined due to some kind of failure, the failure may be caused by the base unit CRM C!
It is not possible to determine whether the line is between the handset CRM C (2) and the handset CRM C (1), or the line between the handset ORMO O (1) and the unmanned device (4).

In this way, in the conventional financial transaction processing system as a parent-child system, the parent machine CRMO is unable to take sufficient measures, especially when the program is loaded on the slave machine, or when there is a failure in the slave CRMC or the line. However, there was a drawback that the operability of the system was not improved.

The purpose of this invention is to eliminate the above-mentioned drawbacks and to
To provide a financial transaction processing system in which the status of a slave unit ORMO can be monitored at any time.

To summarize, this invention provides a memory for storing the status information of the slave units in the base unit, and allows the base unit to display not only the information of each terminal but also the status information of each slave unit as needed. It is characterized by the fact that it is made in a similar manner.

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

The financial transaction processing system which is an embodiment of this invention has a second
The system configuration is the same as that shown in the figure.

FIG. 3 shows the internal configuration of ORM OQ) or (2). CRMC is a central processing unit (hereinafter referred to as CPU) θη,C that monitors and controls unmanned equipment, which will be described in detail later.
Memory α for storing the PUQυ execution program and various data Channel device 0 for connecting unmanned equipment (4)
It consists of a wharf, a power source 0→, a clock 00, and a communication device 0. Terminals (A1) to (A1) of channel device 03
A8) (In this example, there are 8 pieces) for each unmanned device (4)
The terminal Q3) is connected to the display device (3). If the ORMC is a slave device in a parent-child system and does not have a display device, this terminal CB) is unnecessary. It is efficient to perform data transmission between the CRMO and each unmanned device (4) by DMA transfer. Communication device 0. is used for communication with other CRMOs in the parent-child system.

FIG. 4 shows the internal configuration of an unmanned device using A'll'M as an example. ATM (4) is 0PUGI, which processes withdrawal transactions and controls data transmission with ORMO.
I), 0PtJQ]) memory for storing programs and necessary data (6), transmission control circuit (goods) (c),
Distribution device (b), power supply θQ1 Passbook device that reads passbook stripes and prints transaction data on the passbook ←υ,
The customer service panel 6 is composed of a slip device (goods) including a card reader and a slip printing device, a bill dispenser (goods), and a deposit machine including a pill checker.

Each input/output device 6η to 6 has a slave 0 that controls them.
i) Each U (SOPU) is provided, and the CPU
With 0°C as the master CPU (MOPU), the mask
Configuring a slave system. Transmission control circuit 03
and a distribution device (b) performs transmission control of this mask-slave system. The transmission control circuit (c) is an OR
Controls data transmission with M O (1) or (2).

FIG. 5 shows the internal configuration of the display device (3).

The display device (3) is composed of a CPU 01), a memory 0, a CR medium 03° KB, and a transmission control circuit (c), and is equipped with a printer (g) if necessary. The transmission control circuit (c) controls data transmission with ORM C (2) or (1).

FIG. 6 shows the KB (goods) of the display device (3). K
B (b) has function keys for inputting commands to each unmanned device (4), numeric keys, display command key for OR'l'f3, power key/switch (b), and ORM C
! REMO only for display device (3) connected to (1)
A TE/L00AL key (c) is provided. The numeric keys also serve as part of the function keys. When the key switch (c) is turned on, it is only a monitor; if you want to give some commands manually, turn on the key switch (b).
is set to CNTL (console).

T (EMOTE/T, 0OAL key (T) selects the ORM O(1) to which the display device is connected to the ORM O(2)
LOCA to be placed in REMOTE state or operated independently
This is a switch that determines whether to place it in the L state.

FIG. 7 shows the contents of the memory α4 of Cj RM O(1) or (2). This memory 02 includes an address storage area (MA), a command data storage area (Ml), and an operational data storage area (M2).

Elijah (Ml) (M2) is that ORMC! is provided for each unmanned device (4) connected to. Elijah (Ml
) displays the status and model information of the corresponding unmanned device (4), as well as the KB (ro) of the display device (3).
The command data input by is stored. Elijah (
M2) is always transmitted from the corresponding unmanned device (4), and the operation mode (A'l'M, CD or A
Periodic transmission items (MP2) up to D) and other items including transaction data are stored. Elijah (MA) is
That C! The addresses of the command data storage area (Ml) and the operational data storage area (M2) are stored for each unmanned device (4) (channel) connected to the RMO. Therefore, each area (Ml) (M2) of the corresponding unmanned device (4) can be searched by referring to this address. Areas (MA) and (Ml) are non-volatile memories.

Handset C! Since the RM C (1) monitors and controls only the unmanned devices (4) connected to it, it is sufficient to store the data of each unmanned device (4) as shown in FIG. Base unit C
RM C! In addition to the unmanned device (4) directly connected to it, (2) includes the slave CRM C (
1) Self and slave ORM C! The unmanned device (4) to be monitored and controlled in (1) is also monitored and controlled. So, the main unit C! R
In addition to the data shown in FIG. 7, MO(2) stores the data shown in FIG. 8 in its memory 0. In FIG. 8, the address storage area (ma) is located in the memory θ
and storage area (ml) for status information etc. and slave unit ORM C! There is an area (m2) that stores the status information of (1).

An area (ml) is provided for each slave unit ORM O(1) connected to the parent unit ORM O(2), and each area (ml) includes information for each slave unit Cj RM C(1) connected to the parent unit ORM O(2). The status and model information of all unmanned devices (4) are stored. Elijah (m2) is also a main phone CRM
Handset C connected to C(2)! RM c (1), and each area (m2) has a slave unit OR
Status information of M O(1) is stored. Elijah (m
In a), for each slave unit ORMO (1), addresses of the area (ml) and area (m2) for the slave unit are stored.

FIG. 9 shows the contents of the memory (6) of the unmanned device (4). Memory θ2 +r + imaginary, status, model,
and operation of the same contents as the memory 0 pier area (M2),
Transaction data is stored.

FIG. 10 shows the format of the message exchanged between the CRMC and the unmanned device. This telegram is standardized and includes a start flag, address (address of the unmanned device)
, a control field, information, a check field and a termination flag. The messages sent from the unmanned device (4) include a get message (hereinafter referred to as a G sentence) and a put sentence (hereinafter referred to as a P sentence).

The G sentence makes an inquiry, and includes a code (gr) representing the G sentence as information. As a response to this G statement, ORM O(1) or (2) uses the data of (MGI) in the area (Ml) and if necessary (M
G2) control information is sent. The P sentence sends status information or operational data of the unmanned device (4), and includes as information a code (ar) indicating that it is a P sentence and the content of the information. There are 11 sentences in the P sentence, as described below.
There are 22 and 23 sentences.

Data transmission between ORM O(1) and ORM O(2) and CRM C! A similar message format is used in data transmission between (1) or (2) and the display device (3), and G sentences and P sentences are also used.

First, in the parent-child system shown in Figure 2, ORM a
The procedure for data transmission between devices when (1) is set to the LOCAL state will be described. These processes are performed by each CPU 01)I:31)(4υ).

FIG. 11 shows the processing procedure of the unmanned device (4).

First, it is checked whether there has been a change in the status by inquiring each input/output device G1) to GZeng (step (101)). The status items include power off, operational but inactive, operation stopped, operational and handling, expiration of banknotes and slips, call for staff, waiting for staff, passbook update, expiration forecast, and collected invalid cards. There are overflows, etc., and these are all important items. If there is a change in the status, corresponding processing, such as memory storage or down setting, is performed (step (102)). For example, if you run out of banknotes, the status of memory θ
Elijah is flagged as out of banknotes and is no longer available. Then, edit the P sentence that includes this status information and create C!
Transmit to RM O(1) (step (4oa))
. Let this P sentence be 11 sentences.

If NO in step (Lot) and step (10
After the process of 8), the G sentence is edited and transmitted to ORMO(1) (step (104)). The G sentence transmission may be performed at regular intervals using a method such as a timer interrupt. As a response to this G statement, CRMC(1
), the command is received (step (105)), and it is checked whether there is any change in the contents of the command (step (106)). The command sent from ORM O(1) for the G statement is stored in memory 0.
This is the content of (MGI) in area (Ml) of No. 2, and this is the operation mode input by KB (b) of display device (3). Elijah (Ml)'s (MG2) date, etc.
If there is a change in the contents, this is also sent as a command to the unmanned device (4). Since the previously transmitted command is stored in the memory θ of the unmanned device (4),
By comparing this stored content with the transmitted command, it can be determined whether the command content has changed. If there is a change, the changed content is stored in memory 0 and updated (step (107)).

For example, when the unmanned device (4) is a deposit dispensing machine that also operates as a deposit machine or a payment machine, when the operation mode is changed from the deposit dispensing machine (ATM) mode to the dispensing machine (CD) mode, A'['The CD mode is stored in place of the M mode, and the CPU operates in this CD mode from now on.

If there is no change in the command in step (106) and after the process in step (107), edit the operation mode contents (MP 2 ) stored in the memory (c) and perform (3RM O(1) (Step (108)
) ). This is 22 sentences. Then, it is checked whether there was a transaction request, that is, whether there was a key input or card insertion specifying the transaction type (step (1)
09) ). If there is no transaction request, step (1o
Return to step 1) and repeat the above process. Step (101)
~(109) is a standby state process.

If there is a transaction request (YES in step (109)), the transaction processing according to the request is executed (step (110)
) ). Transaction data generated in this transaction processing, such as processing progress step (C!TR value), transaction type, card input data, passbook input data (including account number),
ORM C! maintenance code (MTC), serial number, deposit, withdrawal, remaining amount, etc. in 23 sentences.
(1) (step (nl)). When the transaction processing is completed, the process returns to step (101) to perform standby processing.

FIG. 12 shows the processing procedure of ORMO(1). First, Kado Womiru receives the message from the unmanned device (4) (step (121)). cRMc (1) controls to receive messages equally from each unmanned device (4). Furthermore, since the 11th sentence contains the most important data card, the 11th sentence is received with priority. In any case,
When a message from unmanned device (4) is received, the received message is P.
Judging whether it is a sentence or a G sentence (step (122)), P sentences (PI sentences to P3 sentences, steps (108) (108) (1
11)), compare the content with the content stored in areas (Ml) (M2) of the corresponding unmanned device (4) in memory 02, and change the content stored in memory a. Check whether it is necessary (step (1)
28) ). If you need to change the memory contents, please contact Elijah (
The data to be changed in Ml) or (M2) is updated according to the contents of the P sentence (step (124)), and it is then checked whether the contents of the received P sentence need to be transmitted to the display device (3) ( step (125)). When it is necessary to change the display content on the CRT screen of the display device (3), for example when an error occurs in the unmanned device (4), a new P sentence is generated from the contents of the received P sentence. Edit and transmit to display device (3) (step (126)
) ).

In case of G sentence in step (122) (step (104)
), read the data (MGI) (if necessary (MG2)) from the area (Ml) of memory 02, edit it, and send it as a command to the corresponding unmanned device (4) (
Step (127) ) (corresponds to step (105))
.

NO in step (121) or step (126)
Or after processing (127), K of display device (3)
To enter the data entered by B (b),
Transmit the G sentence to the display device (3) (step (128)
'). When the response to the G sentence sent from the display device (3) is received, the area (Ml) of the memory 02 is
If it is necessary to change the contents of (M2), update the stored contents with the received data (step (129)),
If it is necessary to change the display content on the CRT (c) (step Qao), the P sentence is edited and sent to the display device (3) (step (181)).

This is C! This is because RMO(1) controls the display content on the CRT(g). After this, step (121)
Go back and repeat the above process.

FIG. 13 shows the processing procedure of the display device (3).

First, check whether there is key human power by KB((l) (step (141)), and if there is key human power data, store that data in memory 02 (step (141)).
42) ). Next C! It is checked whether a message from RMC (1) has been received (step (148)), and if so, it is checked whether the message is a G sentence or a P sentence (step (144)). If it is a G sentence (step (128
), in response to ORM key human data
O(1) (step (145)) (corresponding to step (129)).

If the received message is a P sentence (step (126) (1
81)), store this message in memory in ) and (
Step (146)) and display on the CRT (c) (Step (14?)). Thereafter, the process returns to step (141) and the above-described process is repeated.

FIG. 14 shows a display example of CR'I' (c).

This is defined by KB (b) as 0.0. The key to display and complete is what is displayed when there is human power, and ORMO (
Status information of all unmanned devices (4) connected to 1) is displayed. The numbers 11 to 82 in the left column represent the identification number (address) of the unmanned device (4). Further, 12:34 at the bottom right of the screen indicates the time, and the characters LOCAL indicate that the slave unit is not monitored and controlled by the parent unit. In addition, if the characters RBMO'l'E are displayed, this slave unit CRMC! And the terminal connected to the slave CRMO is the master ORMC! Indicates that it is monitored and controlled by Therefore, in this case, the terminal control commands (power on/off, reset, etc.) issued from the KB (b) of the slave CRM O(1) are invalid. In the case of such a display, the display content is updated when there is a change in the status of each unmanned device (4).

More detailed status, operation mode, transaction data, etc. for each unmanned device (4) are also displayed, and this detailed display will be described later.

Figure 15 shows the processing procedure of slave unit ORM O (1) when each slave unit ORM C (1) is set to the REMOTE state, and Figure 16 shows the processing procedure of master unit CRM O (2). has been done. Unmanned equipment (4) and display device (3)
The processing procedures are the same as those shown in FIG. 11 and FIG. 13, respectively. In FIG. 15, step (15
1) to (154) and (1 to 7) are slave machine CRM (3
Processing for the unmanned device (4) connected to (1), which includes steps (121) to (124) and (1) described above.
27) This is the same process as in (Fig. 12). Step (
161) to (166) are processes for the parent machine CRM O(2). When the processing for the unmanned device (4) is completed, it is checked whether a message from the base CRM O (2) has been received (step (161)). The parent unit (2) is also P
Sends the sentence and G sentence. There are two types of G statements: G1, which requests status information and REMOTE/LOCAL information.
There are 02 sentences that request detailed information. Parent unit (2
), it is checked whether it is a P sentence or a G sentence (step (162)), and if it is a P sentence, the commands included in this message are stored in area (Ml) of memory 02 and the stored contents are Update (data (MGI) (MG2)
) (step (168)). If it is a G sentence, check whether it is a G1 sentence or a 02 sentence (step (164)). In the case of a G1 statement, the status information stored in memory α and ]'tEMOTE/LOCAL information are sent to the base unit (2).
If the message is 02, detailed information such as the operation mode and transaction data is sent (step (166)).

When the process for the parent device (2) is completed, step (151)
) and repeat the above process. In addition, step (1
In step 65), when the handset ORM OQ) responds for the first time after turning on the power, it also sends store number data in addition to the above information.

In FIG. 16, steps (171) to (176) are the unmanned device (4) directly connected to the parent unit ORM O (2).
The processing for the above-mentioned steps (121) to (
127) This is the same process as in (Fig. 12). Steps (178) to (187) are processes for the data entered manually by KB■ of the display device (3). Send the G sentence to the display device (3) (step (178))
, when there is a response, the response is a display request (
If the request is a simple information display request of the base unit connected terminal or a detailed information display request of the base unit connected terminal), a simple information display request of the slave unit connected terminal, or a request to display the slave unit information, the area of memory Q ( Edit the data from Ml) (M2), Elijah (ml), or Elijah (m2) and send the P sentence to the display device (3) (steps (180), (181)). On the other hand, if the response content is a request to display detailed information of the slave connected terminal, the detailed information is obtained from the slave ORM O (1) using the 02 sentence and the P sentence is sent to the display device (3) (step (1B2). )～(
185) ).

Also, if the above response is a command to the unmanned device (4), when the unmanned device is the master device connection terminal, the data in the area (Ml) (M2) should be updated and this data will be updated in step (17?). When the unmanned device is a slave unit connection terminal, it transmits a P sentence to the slave unit CRM C(1) (step (187)).

After completing the above processing, the next step is to use slave unit C! RMO(1)
Step (188)) to send the 01 sentence to the slave unit OR
Status information and REMOTE/LOC from MO (1)
When there is a response by message containing AL information (step (1)
89) ) (corresponding to step (165)), first, R
Check whether there is a change in the EMO'I'E/LOCAL information (step (190)), and if there is a change, update the REMOTE/LOCAL information of the area (m2) (
step (191)). Then, if the display screen of the display device (3) is the handset information screen, a P sentence is sent to the display device (3) to change the display (step (198)).
). Furthermore, if the response from the slave unit ORM O (1) is the first response, the store number data is included in the response information (see step (165)). Set the installation store number. Furthermore, if there is a change in the status, update the status (
Steps (196), (197)). Socite new E
When VENT (receiver unit identification) display becomes necessary,
If you need to erase the ENT display, use the display device (3
) (step (199)). After this, the process returns to step (171) and the above-described process is repeated.

The parent unit ORM O (2) has multiple slave units ORM O (1
) are connected, so the above processing for the slave units is controlled equally for all slave units.

FIG. 17 shows a display example of status information among the display contents on the CRT of the display device (3) connected to the main unit CRM O (2). EVENT03 on the upper left represents the identification number of the slave device. The status of the unmanned device connected to slave device #8 is displayed.

FIG. 18 shows an example of displaying detailed information.

As mentioned above, detailed information is transmitted from the slave unit ORM O(1) to the base unit (ERM C!(2)) (step (
166) (184)) and is further transmitted to the display device (3) (step (185)), making it possible to display such detailed information.

Detailed information display is performed when a command to that effect and an identification number of the unmanned device (4) to be displayed are inputted by key input by KB (b). EVEN'l'0821 at the upper left of the screen of OR'I' (c) indicates the unmanned device (4) of EVEN 21 connected to the child device of #3. In addition to the status of unmanned equipment (OR'l'), operation mode,
Information stored in the area (M2) of the memory α, such as transaction data and specific details of the failure, is displayed.

When this kind of display is displayed, other handset c
In communication with RM O (1), base unit C! RM C(
When information that requires a change in the display of another handset is transmitted to 2), this information is also transmitted to display device (3) (steps (196) to (199)). When the display device (3) receives such information, the display device (3) displays the 18th
As shown in (G) in the figure, a display such as EVENT04 is performed. EVEN'l'04 is #4's slave CRMC (
Display change for 1) indicates that the necessary information has been transmitted. As a result, the staff member knew that an abnormality had occurred in the #4 handset, and by performing a keystroke to specify the #4 handset, he first identified all the connections connected to the #4 handset. It is possible to switch to the display of the status of the unmanned devices (corresponding to FIG. 17), and if necessary, the details of a specific unmanned device (corresponding to FIG. 18) can be displayed.

FIG. 19 shows the above operations in a unified manner. #
An example is shown in which the unmanned device (4) of No. 21 connected to the slave device ORM O (1) of No. 3 runs out of 1,000 yen bills. The processing steps in FIGS. 11, 13, 15, and 16 are numbered corresponding to each step in FIG. 19 (the same applies to FIG. 20, which will be described later).

When the unmanned device (4) detects that 1,000 yen has run out (step (2)
01) ), set 1,000 yen out and down in its memory (6) (steps (202) (208)),
The operation is stopped (step (204)). And 2
Edit one sentence and send the status information to the slave device ORM O (1)
to be transmitted. When the slave unit ORM O (1) receives this 21 sentence, it updates the status of the area (Ml) in the memory (2) (step (206) ) and the area (M2).
Step (207)) to set the 1,000 yen limit
When the 01 sentence is received from RM O (2), status information is sent to the base unit ORM O (2) (step (2)
0B) ). The parent device ORM O (2) receives the response message from the child device (1) to the 01 statement, and if there is a change in the status (step (209)), it stores the memory 0 area (
ml) (step (210))
.

Then, if it is necessary to change the display (step (211)
), EVEN'I'08 is displayed on the CRT (to) (step (212)). When the staff member sees this display,
When the display command for 3 is input by KB (b) (step (218)), status information as shown in FIG. 17 is displayed (step (214)). Furthermore, when a key is input to display the unmanned device in black 21 of handset #8 (step (215)), detailed display as shown in FIG. 18 is performed (step (216)).
. After this, the staff instructs the maintenance staff to replenish the 1,000 yen bills (step (21?)). Then, when you press the completion key (step (218)), EV is displayed on the cR'rH screen.
Other information is erased, leaving the characters EN'l''08 (step (219)).

FIG. 20 shows a unified processing procedure for canceling the 1,000 yen cutoff. When the maintenance personnel replenishes the corresponding unmanned device with 1,000 yen bills (step (221)), the unmanned device returns and performs the necessary recovery processing (step (222)).
). In other words, when the replenishment of 1,000 yen bills is detected (step (
Steps (224) (225)) - 1P1 statement sends new status information to the slave unit ORM
(step (226)). Child unit ORM C
! When (1) receives the 21st sentence, it updates its memory Q (steps (227) (228)), and
Status information is transmitted in response to the 01 sentence from RMO(2) (step (229)). Base unit CRM C
! (2) receives this status information, and if there is a change in the status (step (210)), the memory (
Update the memory contents of 12 areas (ml) (step (
281) ), erase the characters (7) EVENTO3 on cR'rH (steps (282) (288)).

Figure 21 shows the main unit C! A display example of slave unit CRMO information connected to RM O (2) is shown. This screen is displayed when you key in ``Display'' and ``Complete'' on KB (B) of the display device (3). EVENT03 on the upper left is
Indicates the identification number of the handset (1), and the display content is the handset (1).
status information, that is, the contents of area (m2). The information on each handset indicates, from the left, station number, shop number, power status, power on/off command, REMOTE/LOCAL, and line status. The display screen represents the following status.

Handset #1 is operating normally in the REMO'I'B state.

Regarding slave unit #2, the power is off, but the base unit (2)
) is issuing a command to turn on the power.

As for slave unit #3, the power did not turn on for some reason, even though the power supply person's command was issued from the master unit (2).

Handset #4 is currently operating in the LOCAL state, but the line condition is poor and a line error has occurred.

Next, the procedure for setting and updating the area (m2) will be explained (see FIG. 8).

As mentioned above, the slave unit ORM O (1) is the master unit C! R.M.
C! When responding to the 01 sentence in (2) for the first time, store number data is added (steps (165), (189)
) ), in that case, the relevant store number data is set in the handset installation store number area of area (m2) (step (194)
, (195)).

In the power status area, the handset (1) is displayed in step (189).
It is set ON when there is a response from , and OFF when there is no response. The power on/off command area has a display device (3
)'s K141 issues a power on/off command to the handset (1), the ONN register 0FF signal is set, and the power does not turn on or turn off after a certain period of time. , ON size 10FF size is set. REMOTE/LOCAL area is step (
191).

In addition, the line status area is set at steps (188) and (18).
9) is set when communication with the handset (1) does not go well.

As explained in detail above, according to the present invention, the master unit ORMC! On the display device of each slave unit C! R.M.
Since the status information of O can be displayed, each slave CRMC can be constantly monitored, and the financial transaction processing system can therefore respond relatively quickly even in the event of a line failure.

[Brief explanation of the drawing]

Figure 1 is a block diagram showing the outline of the child system, Figure 2 is a block diagram showing the outline of the parent-child system, and Figure 3 is the ORM.
Figure 4 is a block diagram showing the contents of C, Figure 4 is a block diagram showing the contents of the unmanned device, Figure 5 is a block diagram showing the contents of the display device, Figure 6 is a diagram showing KB, Figure 7 is the memory of CRMO. FIG. 8 is a diagram showing the additional contents of the memory of the parent unit ORMO in the parent-child system.
The figure shows the contents of the memory of the unmanned device, Figure 10 shows the format of the message, and Figures 11 to 14 show the CR.
This shows the operation contents when MO(1) is placed in the LOCAL state, and FIG. 11 is a flow chart showing the processing procedure of the unmanned device, and FIG. 12 is a flow chart showing the processing procedure of CRMO.・Charts; FIG. 13 is a flow chart showing the processing procedure of the display device; FIG. 14 is a diagram showing an example of a CRT display; FIGS. 15 to 20 are C! R.M.
15 shows the operation details of the parent and child system when O(1) is placed in the REMOTE state.
FIG. 16 is a flow chart showing the processing procedure of the MC; FIG. 17 is a flow chart showing the processing procedure of the parent machine CRMC;
Figures 1 and 18 are diagrams showing display examples of OR'I'.
9 and 20 are flow charts showing the overall operation in a unified manner, and FIG. 21 is a diagram showing a display example of handset information. (1)(2)...ORMC (centralized remote monitoring and control device)
, (3)...display device, (4)...unmanned equipment, (to)...CRT, (b)...KB0 or more Patent applicant: Tateishi Electric Co., Ltd. Representative Patent Attorney Hisao Komori No. 3 Figure 4 Figure 10 (Bi1.Bi1.'F'j) Death Figure 11 (7%, human/machine/equipment) 01 ``4- Yes, bag processing G sentence construction P1 sentence sending [)3 Command “Uke” Meishi 4-Yes Y
1o7 mode゛ Updated 92 sentences Sender Wataru Bow 14J 翿ゝ一

Claims (1)

[Claims] (1) It has a plurality of terminals such as automatic teller machines, a first memory that divides these terminals into a plurality of groups, stores operational data and command data for the plurality of terminals in each group, and a transmission line. a plurality of handsets that control the terminals via a second memory that stores operational data and command data of the plurality of handsets, and a third memory that stores status information of the plurality of handsets. , and a base unit that is equipped with a display device and controls the plurality of slave units via a transmission line, and the base unit displays status information of each slave unit as needed along with information on each terminal. A financial transaction processing system designed to