JPH0628063A - Computer system - Google Patents

Abstract

(57) [Summary] [Purpose] With regard to a computer system, the purpose is to ensure that the power is turned on normally when the power control of peripheral devices is switched from local to remote. [Configuration] A computer system that connects a higher-level device 1 and a lower-level device 2 with a single interface cable 5 and transfers a plurality of information in a time-sharing manner. Remote control by the instruction of device 1,
Alternatively, a switching unit 3 for switching to local control performed by the lower-level device 2 and a flag 4 indicating whether the power is on or off are provided, and the lower-level device 2 switches the switching unit 3 to local control to turn on the power. After the disconnection, while the switching unit 3 is switched to the remote control and the flag 4 indicates the power-on state, the host device 1 issues the power-on instruction and the flag 4 indicates the power-off state. Is configured so that the higher-level device 1 does not issue the power-on instruction even when the switching unit 3 is switched to the remote control.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a computer system in which peripheral devices are powered on and off by the control of a central processing unit, and more particularly, a plurality of computer systems are provided via one interface cable connecting the central processing unit and the peripheral devices. When the information of (1) is transferred in a time-division manner, the present invention relates to a computer system in which power is normally turned on when the power control of peripheral devices is switched from local to remote.

In recent years, computer systems have become larger in scale, and along with that, the number of interface cables between the central processing unit and peripheral devices has also increased, but this increase in interface cables reduces the installation efficiency of the devices. I am letting you.

For this reason, the number of interface cables has been reduced by changing the parallel interface from a parallel interface to a serial interface, and the installation efficiency of the apparatus has been improved.

Generally, in the case of a parallel signal interface, since it is possible to control by a logic level signal by giving a meaning to each signal line, it becomes easy to control peripheral devices. .

However, in the case of a serial signal interface, the data in the interface section changes in synchronism with the serial-parallel conversion clock, which makes control difficult.

Therefore, when the central processing unit controls the power supply of the peripheral device using the serial interface, the peripheral device independently turns on or off the power supply by the remote / local changeover switch provided in the peripheral device. After that, it is necessary that no inconvenience occurs when returning to the control of the central processing unit again.

[0007]

2. Description of the Related Art FIG. 3 is a block diagram illustrating an example of a conventional technique. FIG. 3 (A) shows a case of a parallel interface, and the central processing unit 6 and the peripheral device 7 are connected by a plurality of interface cables 10. From the central processing unit 6, one of the interface cables 10 is connected. A power-on or power-off signal is sent to the peripheral device 7 via the cable 11.

That is, the central processing unit 6 is turned on by itself or in response to an instruction from the operator.
As a power-on signal, for example, send out a logic "1",
The power of the central processing unit 6 itself is cut off, or a logic "0" is transmitted as a power supply cutoff signal in response to an instruction from the operator.

Generally, the peripheral device 7 is provided with a switch 8 for remote or local switching so that the peripheral device 7 itself can be turned on or off in preparation for maintenance of the computer system. There is.

When the switch 8 is switched to the remote side, the power supply control from the central processing unit 6 becomes effective, and the logic "1" or "0" sent from the central processing unit 6 via the switch 8 is activated. Is supplied to the power supply device 9, the power supply device 9 is automatically turned on or off.

When the switch 8 is switched to the local side, the power switch provided in the power supply device 9 becomes effective, and the peripheral device 7 itself can control the power supply. That is, the power can be turned on or off by the operator turning the power switch on or off in the peripheral device 7.

When the operator switches the switch 8 to the remote side again, the logic "1" or "0" sent by the central processing unit 6 is sent to the power supply unit 9, so that the peripheral device 7 is again turned on. The power supply of the central processing unit 6 can be controlled.

Therefore, for maintenance of the peripheral device 7, the operator switches the switch 8 to the local side, turns off the power of the peripheral device 7 to perform maintenance, and then turns on the power of the peripheral device 7 to complete the self-diagnosis. After that, even if the switch 8 is switched to the remote side, if the logic "1" is still sent from the central processing unit 6 to the cable 11, the power-on state can be maintained.

FIG. 3B shows the case of a serial interface, in which the central processing unit 6 and the peripheral device 13 are connected by a single interface cable 5, and a plurality of information are time-divisionally transmitted via this interface cable 5. Transferred.

That is, together with information such as the command sent by the central processing unit 6 and the status sent by the peripheral device 13, the signal sent by the central processing unit 6 for instructing power-on or power-off is synchronized with the serial-parallel conversion clock. Are sent to the peripheral device 13.

Therefore, the signal sent by the central processing unit 6 to instruct the power-on is sent to the interface cable 5 when the power is turned on to the central processing unit 6 or when the operator gives an instruction, and serial-parallel conversion is performed. After the power-on instruction signal is transferred at a certain timing in synchronization with the clock, other information is sent to the interface cable 5 in response to the next change in the serial-parallel conversion clock. The peripheral device 13 stores this power-on instruction signal in, for example, the register 12 and holds it until the power-off instruction signal is received.

The signal for instructing power off is sent to the interface cable 5 when the power of the central processing unit 6 is turned off, or when instructed by the operator, and in the same manner as above, this power off signal is also registered. 12 and is held until the power-on instruction signal is received.

[0018]

As described above, in the computer system using the conventional serial interface,
The peripheral device 13 stores and holds the control signal sent from the central processing unit 6 for instructing power-on or power-off.
When the switch 8 is switched to the local side, the power-on instruction signal held in the register 12 is reset.

However, the central processing unit 6 does not send the power-on instruction signal again unless the operator gives an instruction. Therefore, when the central processing unit 6 does not send the power-on instruction signal again when the switch 8 is switched from the local to the remote in the peripheral device 13, the remote power-on instruction signal is stored in the register 12 of the peripheral device 13. Since it is not held, when the power switch provided in the power supply device 9 of the peripheral device 13 is turned on and then the switch 8 is switched to the remote state, the power-on instruction signal is not sent from the register 12 to the power supply device 9. Therefore, even if the power switch is on, the power is cut off by the remote control.

In recent years, when the serial interface is used, the central processing unit 6 and the peripheral device 13 are often installed at different locations, and the operator of the central processing unit 6 is informed each time the power-on instruction signal is sent. However, there is a problem that maintenance efficiency is low.

In view of the above problems, the present invention sets the flag when the power switch is turned on in the peripheral device 13 so that the central processing unit 6 is turned on again when the switch 8 is switched to the remote side. The purpose is to automatically send an instruction signal.

[0022]

FIG. 1 is a block diagram for explaining the principle of the present invention. The computer system comprises a lower-level device 2 and a higher-level device 1 that controls the lower-level device 2. The upper-level device 1 and the lower-level device 2 are connected by a single interface cable 5, and the interface cable 5 A plurality of information is time-divisionally transferred via.

In the lower device 2, switching means 3 for switching the power-on control to remote control which is instructed by the upper device 1 or local control which is performed on the lower device 2 side.
And a flag 4 indicating whether the power is on or off.

After the lower device 2 switches the switching means 3 to the local control and turns off the power, the switching means 3
Is switched to remote control, and when the flag 4 indicates a power-on state, the switching device 3 is remote while the host device 1 issues a power-on instruction and the flag 4 indicates a power-off state. Even if the control is switched to the control, the host device 1 does not issue the power-on instruction.

[0025]

With the above configuration, when the lower unit 2 is powered on and the switching means 3 is switched to the remote side, the upper unit 1 can be automatically sent a power-on instruction signal again.

Therefore, it is possible to maintain the power-on state of the lower device 2 without requesting the upper device 1 to send out a power-on instruction signal at the end of the maintenance work.
It is possible to prevent deterioration of maintenance efficiency.

[0027]

FIG. 2 is a block diagram of a circuit showing an embodiment of the present invention. The same reference numerals as those in FIG. 3 denote the same functions.
The central processing unit 6 sends an instruction to the data transfer control circuit 16 of the peripheral device 14 via the interface cable 5 and receives the execution result of this instruction in response from the data transfer control circuit 16 of the peripheral device 14. , Attention to polling is received and the state change of the peripheral device 14 is reported.

As described with reference to FIG. 3, the peripheral device 14 stores the power-on instruction signal received via the interface cable 5 and the data transfer control circuit 16 in the register 12, and if the switch 8 is on the remote side, 12
Sends this power-on instruction signal to the power supply device 9 via the switch 8. Therefore, the peripheral device 14 is operated by being supplied with power from the power supply device 9.

When the operator switches the switch 8 to the local side for maintenance or the like, the power-on instruction signal stored in the register 12 is reset, but the power switch 15 of the power supply device 9 is effective, so that the operator turns on the power. Peripheral device 14 continues to operate until switch 15 is disconnected.

When the operator's maintenance work is completed and the power switch 15 which has been cut off is turned on, the flag 4 is set. The setting of the flag 4 is reported by the data transfer control circuit 16 by the attention to the polling of the central processing unit 6, and the central processing unit 6 recognizes the setting of the flag 4.

Then, the switch 8 is switched to the remote side, and when this state is reported by the attention of the data transfer control circuit 16 to the polling of the central processing unit 6, the central processing unit 6 has set the flag 4. When the switch 8 is switched to the remote side, the power-on instruction signal is sent to the data transfer control circuit 16 of the peripheral device 14 via the interface cable 5.

Therefore, since the power-on instruction signal is stored again in the register 12 via the data transfer control circuit 16 and sent to the power supply device 9 via the switch 8, the power supply device 9
Holds the power-on state and supplies power to the peripheral device 14.

When the operator's maintenance work is completed and the switch 8 is switched to the remote side, the central processing unit 6 is notified by the attention to the polling in the same manner as described above. While it is not set, the power-on instruction signal is not transmitted, and the operator turns on the power switch 15 of the power supply device 9,
When the flag 4 is set, a power-on instruction signal is sent out.

[0034]

As described above, according to the present invention, when the peripheral device is in the local state and the power switch is turned on, the peripheral device is not turned off by being in the remote state. Is maintained and the operation of the computer system can be started promptly without the need for human intervention.

Further, since the power of the peripheral device is not turned on when the power switch of the peripheral device is turned off, or when the switch for remote or local switching is switched to the remote, safety of maintenance work is improved. Is not damaged.

[Brief description of drawings]

FIG. 1 is a block diagram illustrating the principle of the present invention.

FIG. 2 is a block diagram of a circuit showing an embodiment of the present invention.

FIG. 3 is a block diagram illustrating an example of a conventional technique.

[Explanation of symbols]

 1 Upper device 2 Lower device 3 Switching means 4 Flags 5, 10 Interface cable 6 Central processing unit 7, 13, 14 Peripheral device 8 Switch 9 Power supply device 11 Cable 12 Register 15 Power switch 16 Data transfer control circuit

Claims (1)

[Claims] 1. A lower device (2) and an upper device (1) for controlling the lower device (2). A single device is provided between the upper device (1) and the lower device (2). Interface cable (5)
A computer system for connecting a plurality of pieces of information via the interface cable (5) in a time-divisional manner, and performing power-on control for the lower-level device (2) according to an instruction from the higher-level device (1). A switching means (3) for switching between remote control or local control performed by the lower device (2) and a flag (4) indicating whether the power is on or off are provided. ) After switching the switching means (3) to local control and turning off the power, when the switching means (3) is switched to remote control and the flag (4) indicates a power-on state, While the host device (1) issues a power-on instruction and the flag (4) indicates a power-off state,
A computer system characterized in that the host device (1) does not issue a power-on instruction even when the switching means (3) is switched to remote control.