JPH02244855A - Self-diagnostic device for communication function - Google Patents

Abstract

PURPOSE:To easily switch a mode from a communication mode to a self- diagnostic mode at need by performing the control of a changeover switch provided between a connector for external connection and the input/output terminal of an interface by a program. CONSTITUTION:Self-diagnosis is performed by directly receiving the transmission data of a serial communication interface 11. And the change-over switches 21a-21d are provided between the transmission and reception terminals of the serial communication interface 11 and terminals 12a-12d for external connection, and the transmission data can be directly received by controlling the change-over switches by the program. Thereby, the mode can be easily switched from the communication mode to the self-diagnostic mode.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a communication function self-diagnosis device suitable for serial data communication.

[Summary of the invention]

The present invention provides a communication function self-diagnosis device for a serial communication interface that can switch from a communication mode to a self-diagnosis mode at any time by program-controlling a changeover switch provided between an external connection connector and an input/output terminal of the interface. This allows for easy switching.

[Conventional technology]

Conventionally, in order to check the communication function of a serial communication interface, the transmitting terminal and receiving terminal of this interface are directly connected and the self-diagnosis mode is set.
A so-called loopback test is performed in which a device directly receives its own transmitted data and detects a failure between the received data and the transmitted data.

It is also known that when the interface has a double buffering structure, multiple pieces of transmission data are sent consecutively to prevent automatic insertion of synchronization characters (Japanese Patent Laid-Open No. 62
(Refer to Publication No.-269528).

[Problem to be solved by the invention]

By the way, when performing a loopback test, conventionally,
It was necessary to remove the communication cable from the connector of the target interface and attach a jumper connector prepared specifically for testing.

For example, in the R5-232C standard interface using an unbalanced communication line, as shown in Figure 3, a serial communication circuit (interface) that exchanges data with a computer's central processing unit (CPU) (10) is used. (
11) are the four bins (12) of the external connection connector (12).
12a), (12b), (12c) and (12
d) and four leads (13a), (13b),
Connected by (13e) and (13d).

On the other hand, the jumper connector (2) is the pin (2a).

(2b), (2c) and (2a) are connected by jumpers (3ab) and <3cd), respectively.

When this jumper connector (2) is attached to the connector (12), the transmit data signal TxD from the interface (11) passes through the jumper (3ab) and is returned to the interface (11)'C as a receive data signal RXD. At the same time, the receivable state control signal DTP sent from the interface (11) passes through the jumper (3cd) and is sent to the interface (11) as the transmittable state control signal DSR.
11).

Note that, for the sake of simplicity, illustrations of things related to the grounding level are omitted in FIG.

In addition, in the R3-422A standard interface using a balanced communication line, as shown in Figure 4, the R3-232C interface exchanges data with the computer's central processing unit (CPU) (10). (11)
A balanced/unbalanced conversion circuit (1) is connected between the
5) is inserted. A complementary driver (or receiver) (15a) for this conversion circuit (15).

(15b), (15c) and (15d) are connected to the interface (11) by leads (13a) to (13d).
) and a connector (14) for external connection.
4 pairs of bottles (14aL (14b), (14c) and (14d) and 4 twisted pair leads (16a)
, (16b), (16c) and (16d).

On the other hand, jumper connectors (4) are connected to each pair of bins (4a
), (4b) and (4c), (4d) are connected by pair jumpers (5ab) and (5cd), respectively.

When this jumper connector (4) is attached to the connector (14), the transmission data signal TxD from the interface (11) is transmitted to the complementary driver (15a).
.

jumper (5ab) and complementary receiver (
15b) and is returned to the interface (11) as a received data signal RxD.
11) The receivable state control signal DTR sent from
Complementary driver (15c), jumper (
5cd) and a complementary receiver (15d), and is returned to the interface (11) as a transmit enable state control signal DSR.

The jumper connector mentioned above is used during the loopback test.
This involved the troublesome task of attaching and detaching each interface to be tested.

In view of the above, an object of the present invention is to provide a communication function self-diagnosis device that can easily perform a loopback test at any time by eliminating the troublesomeness of conventional self-diagnosis using jumper connectors. be.

[Means to solve the problem]

The present invention provides a communication function self-diagnosis device that performs self-diagnosis by directly receiving transmission data from a serial communication interface (11).
d), selector switches (21a) to (21d
), and these changeover switches are controlled by a program to directly receive transmitted data.

(Function) According to this configuration, it is possible to easily switch from the communication mode to the self-diagnosis mode at any time.

〔Example〕

Hereinafter, an embodiment of the communication function self-diagnosis device according to the present invention will be described with reference to FIG.

FIG. 1 shows the configuration of an embodiment of the present invention. In FIG. 1, parts corresponding to those in FIG. 3 are given the same reference numerals.

In FIG. 1, (21) is a selector, which has four changeover switches (21a), (21b), (21
c) and (21d), for example, CPU (
The connection state is switched in conjunction with the control signal from 10).

Each one of switches (21a) to (21d) (cm side)
The fixed contacts and each movable contact are connected to leads (13a) to (L3
d) is inserted between each. Switch (21a) and (
21c), the fixed contact on the other Bb side) has "Hl" in common.
A fixed level voltage is supplied, and the other fixed contacts of the switches (21b) and (21d) are connected to jumpers (
switch (21a) by (22ab) and (22cd)
) and (21c), respectively.

In the communication mode, each switch (21a) to (21d) is in the connected state shown in the figure, and the interface (11) and connector (12) are Once connected, serial communication with the other party (not shown) is carried out without any problems.

In the self-diagnosis mode, each switch (21a) to (21d) is switched to a connection state opposite to that shown in the drawing, for example, by a "Lo" level switching control signal. As a result, the transmission data signal TxD from the interface (11) becomes
Interface (11) as received data signal RxD through jumper (22ab) and switch (21b)
The receivable state control signal DTR sent from the interface (11) is returned to the jumper (22c).
d) and the switch (21d) and is returned to the interface (11) as a send enable state control signal DSR.

A diagnostic unit (not shown) compares the transmitted data and directly received data to diagnose whether the communication function of the interface is normal.

In this case, a fixed voltage at the level "rHi" is sent to the other party (not shown) through the switches (21a) and (21c), thereby informing the other party that the other party is unable to receive the signal.

According to the embodiment shown in FIG. 1, when an error occurs during communication, the control signal can immediately switch the selector to loopback mode and perform self-diagnosis.

Further, by appropriately setting the generation of the control signal in the program, self-diagnosis can be easily performed at any time, for example, every time the power is turned on.

Next, another embodiment of the communication function self-diagnosis device according to the present invention will be described with reference to FIG.

The structure of another embodiment of the invention is shown in FIG.

In FIG. 2, parts corresponding to those in FIG. 1 and FIG. 4 are given the same reference numerals.

In FIG. 2, (31) is a selector, which has four pairs of changeover switches (31a), (31b), (31
c) and (31d), for example, CPU (
The connection state is switched in conjunction with the control signal from 10).

Each one (cu+) of switch pairs (31a) to (31d)
The fixed contact on the side) and each movable contact are connected with twisted pair leads (
It is inserted between each of 16a) to (16d). A fixed voltage of rHi'' level is commonly supplied to the fixed contacts of the other Bb side of the switch pairs (31a) and (31c), and the fixed contacts of the other switch pairs (31b) and (31d) are connected to the jumper. (32ab) and (32cd) are connected to the other fixed contact of the switch pair (31a) and (31c).

In the communication mode, for example, each switch pair (31a) to (31d) is in the connection state shown in the figure by the rHi J level switching control signal, and the interface (11) and connector (14) are connected via the selector (31). is connected,
Serial communication with the other party (not shown) is carried out without any problems.

In the case of self-diagnosis mode, each switch pair (31a) to (31d) is
is switched to the opposite connection state from that shown.

As a result, the transmission data signal TxD from the interface (11) is transmitted to the complementary driver (15a).
, through the jumper (32ab), the switch pair (31b) and the complementary receiver (1,5b), and is returned to the interface (11) as a received data signal RxD, as well as sent out from the interface (11). Complementary stop signal
It passes through the driver (15e), the Johnny/Bar (32cd), the switch pair (31, d), and the complimentary receiver (15d), and is returned to the interface (11) as the transmittable state control signal DSR. .7 In the diagnostic section, the transmitted data and directly received data are compared and 1. It is diagnosed whether the communication function of the interface is normal or not.

In addition, in this case [the fixed voltage of the old Lebel is connected to the switch pair (
31,a) and (31e) to the other party (not shown), and is informed that the other party is in a state in which reception is not possible.

In the embodiment shown in FIG. 2, as in the embodiment shown in FIG. 1, self-diagnosis can be easily performed at any time.

(Effects of the Invention) As detailed above, according to the present invention, the changeover switch provided between the external connection connector and the input/output terminal of the serial communication interface is program-controlled.
Therefore, it is possible to obtain a communication function self-diagnosis device that can easily switch from communication mode to self-diagnosis mode at any time.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the configuration of one embodiment of the communication function self-diagnosis device according to the present invention, FIG. 2 is a block diagram showing the configuration of another embodiment of the invention, and FIGS. 3 and 4 are respectively 1 is a block diagram showing a configuration example of a conventional communication function self-diagnosis device. (10) is the central processing unit (CPU), (11) is the serial communication circuit, (12) and (14) are the connectors, (
21), (31) are selectors, (22), (32
) is a jumper.

Claims (1)

[Scope of Claims] A communication function self-diagnosis device that performs self-diagnosis by directly receiving transmission data of a serial communication interface, wherein a changeover switch is provided between the transmission terminal and reception terminal of the serial communication interface and the external connection terminal, respectively. A communication function self-diagnosis device characterized in that the changeover switches are program-controlled to directly receive the transmitted data.