KR960004803B1 - Remote power control system and method - Google Patents

Abstract

No content.

Description

Remote power control system and method

1 is a block diagram of a remote power control system according to the present invention.

2 is a control flowchart of a remote power control system according to the present invention.

3 is a block diagram showing a modem connection between a remote site and a system in a remote power control system according to the present invention.

4 is a detailed view of a check unit of the remote power control system according to the present invention.

5 is a detailed view of each part of the remote power control system according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Upper control module 2: Interface

3: display unit 4: modem

5: signal conversion unit 6: check unit

7: Power Drive 8: Inhibit

9: power on / off control unit 10: remote terminal

11: remote modem 61: oscillator

62: delay unit 63: counter unit

64: check signal output unit

The present invention relates to a system control at a far distance, in particular, to enable the power control of the system at a distance to provide remote system management, such as failure diagnosis of an unmanned system or a remote system. The present invention relates to a long-distance power control system and method of TCOM system, which has improved reliability and confidentiality.

In a conventional principle controller, a power related to a modem can be monitored to turn on or off in order to provide a remote power on / off function.

That is, when the CD signal is recognized by the CD signal of the modem of the system when the remote modem and the modem of the system are interconnected by dialing the system side from the remote terminal through the modem, the system power is turned on. To perform the related work, and after the related work is finished, turn off the modem or negate the CD signal to provide a power off function.

However, in the related art, which detects the CD signal and controls the power on / off, the power secret is not secreted and power on / off is opened to anyone who can access the system. There is a problem. That is, if only the telephone number of the corresponding system is known, there is a problem that after the communication with the corresponding system through the modem, the power of the system can be turned on / off at any time.

In addition, as a problem of power reliability, an error may occur in power on / off operation of the system due to noise or glitches due to the characteristics of the modem and the line. As a problem that the various functions of the controller are insufficient in performing the power on / off in, there is a problem that cannot solve the problem of the remote diagnosis approach of the third party.

In view of the above problems, the present invention evaluates the reliability of the signals of the modem in hardware and allows the user to check the system's availability to control the power of the system, thereby unattended operation of the system and post-system remote operation. Invented a remote power control system of the TCOM system to comprehensively manage the management and system management, which will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a remote power control system of the Ticon system according to the present invention, and as shown therein, to control the power control module by SCM F / W through a central processing unit (hereinafter referred to as a CPU). The upper control module 1, an interface 2 for inputting the output of control data of the upper control module 1 and respective state signals to the upper control module 1, and a display unit for displaying the power control state ( 3) and a modem 4 which communicates with the telephone line while receiving a carrier detect (CD signal) on the telephone line, and input / output signals between the modem 4 and the system. A signal converter 5 for proper conversion, a checker 6 input from the modem 4 to check the reliability of each signal through the signal converter 5, and the interface 2 By the power control signal of the upper control module (1) through A power on / off control unit 9 which generates a power on / off control signal and outputs a display control signal to the display unit 3, and controls the upper control module 1 through the interface 2; On the basis of the wrong password being checked, the inhibit bit section 8 which inhibits power control and display control, the inhibit signal of the inhibit bit section 8, and the power on / off control section 8 Outputs a power drive signal (Power-request) for powering on / off based on the power control signal of the control unit and the control signal of the check unit 6 and to the upper control module 1 through the interface 2. And a power driver 7 for outputting a status signal.

As shown in FIG. 4, the check unit 6 includes an oscillator 61 generating a predetermined frequency and a DCD signal input from the signal converter 5 of the delay unit 62-1. The oscillator 61 through the delay unit 62 delaying the delay time by the flip-flop 62-2 and the counter 63-1 receiving the output signal of the delay unit 62 as a clear signal. And a counting unit 63 for counting the oscillation frequency to a predetermined value, and a check signal output unit 64 for outputting the DCD signal by the ripple carry signal of the counting unit 63.

In addition, the check signal output unit 64 receives the DCD signal DCD1 as a data input and receives a ripple carry signal of the counter unit 63 as a clock signal and outputs the DCD signal DCD1. A flop 64-1, a delay unit 64-2 for delaying the DCD signal DCD1, an output signal of the flip flop 64-1, an output signal of the delay unit 64-2, The flip-flop 64 by NAND combining an oragate OR1 outputting the DCD signal DCD2 and an output signal of the oragate OR1 and an output signal of the delay unit 64-2. And a NAND gate NAND1 for feeding back a preset signal of -1).

5 is a detailed configuration diagram of each part of the remote power controller device of the TCOM system according to the present invention. As shown in FIG. 5, the power on / off control unit 9 receives a power on / off signal as a data input. The control signal CSR-WR through the interface 2 of FIG. 1 is applied as a clock signal to output a non-inverted output signal to the power driver 7 as a power control signal, and to output the inverted output signal to the display unit 3. NAND gate for outputting a flip-flop F1 output as a system down display signal and a signal obtained by NAND combining the inverted output signal of the flip-flop F1 and the DCE signal DCD2 as a control signal to the power driver 7. ND1).

In addition, the inhibit unit 8 receives the password PASSWD-WRONG signal of the check unit 6 as a data input and receives the control signal CSR-WR through the interface 2 as a clock signal. A flip-flop F2 for outputting a non-inverted output signal to the power driver 7 as an inhibit bit signal, and outputting an inverted output signal to the display part 3 as an inhibit bit signal; And a NAND gate ND2 for combining the DCD signal DCD2 through the power supply voltage Vcc as a clear signal of the flip-flop F2.

The power driver 7 receives a system power control signal of the power on / off controller 9 as a data input, a flip-flop F2 that receives a remote power control signal as a clear signal, and the inhibit bit. The three-state gate T-1 for controlling the output signal of the flip-flop F2 and the output signal of the three-state gate T-1 by the output signal of the section 8 are displayed as the power drive signal and the display. A photocoupler P.C1 to be transmitted as a signal, a relay RY1 for outputting a power drive signal POWER-REQUEST based on the output signal of the photocoupler P.C1, and the DCD signal DCD2. The inverter gate I1 outputs a CD signal latch control signal to the interface 2 by inverting.

In addition, the display section 3 is based on the light emitting diode (LED1) for remote power control display by the DCD signal of the check section 6 and the system down based on the output signal of the power on-off control section (9). The light emitting diode LED2 for displaying, the light emitting diode LED3 for displaying the remote power request inhibit based on the output signal of the inhibit bit 8, and the power driving signal of the power driver 7; It consists of a light emitting diode (LED4) for remote power drive display.

Referring to the operation and effect of the remote power control system of the T-com system according to the present invention configured as described above are as follows.

FIG. 2 is a flow chart of a remote power control system of the T-com system according to the present invention. If there is a remote power on signal as shown in FIG. 2, the upper control module 1 uses the control flow as shown in the flowchart of FIG. You have control.

When the CD signal is input through the telephone line, the CD signal is transmitted to the check unit 6 through the modem 4 and the signal converting unit 5, and the check unit 6 recognizes the normal CD signal as noise or glitch. The recognition is judged and transmitted to the power driver 7 in the case of a genuine CD signal.

Accordingly, the power driving unit 7 turns on the power of the system.

In addition, it checks whether the password is correct or not and applies a signal to the inhibit bit 8 when the password is long.

First, a CD signal detecting step (STEP1) for determining whether a CD signal is detected is performed to discriminate whether it is a power on control at a remote location or a power on control at a system side.

If the CD signal is detected, it is a power-on control at a remote location, and thus latches that the CD signal has been detected in the register at the interface 2. When latched in this way, the power control signal of the power driver 7 is safely driven. Then, a password check step (STEP2) is performed while performing a power on boot (BOOT) operation from a remote location.

In the password check step (STEP2), it is determined whether to continue the operation by asking for a password so as to know whether the user who has made a call is a suitable user and checks whether the system is used.

At this time, if the caller is not a system administrator or a reserved user, the previous power-on sequence is activated. That is, if the password checked in the password check step STEP2 is not correct, if the remote power-on control is inhibited, the inhibit bit step STEP3 is performed. Here, the lower bit causes the inhibit bit 8 to inhibit the remote power on sequence of the power driver 7 and the display unit 3 under the control of the upper control module 1. In step 3), the drive ready state of the input / output device is checked and if the drive is ready, the device is prepared for power-off, the device is deselected, and the remote power-on control is inhibited.

When the password is passed, the system performs a boot operation so that the system can be used normally, and performs a remote control step (STEP4) for operating as a console of the terminal on the remote side.

On the other hand, if the CD signal is not detected in the CD signal detection step (STEP1), the system side power-on control, and thus the system control step (STEP5) for normal power-on booting and performing the operation under the control of the system side. ).

After performing the remote control step STEP4 and the cyste control step STEP5 in this manner, as a power-down operation, it is checked whether or not the CD signal is latched. As a result of the check, if the CD signal is latched, it is checked whether the request of the CD signal continues, and if there is a request of the CD signal, the process returns to the CD signal checking process, and if the CD signal is not latched or there is no request of the CD signal. Then, a power off step (STEP6) is performed to turn off the power and terminate the control routine.

In the power-off step (STEP6), the upper control module 1 sets the power-off to the interface 2. Accordingly, the power on / off control unit 9 is set to power off at the interface 2, and the CD signal is checked. In this operation, the power driver 7 outputs the CD signal passing the password to the interface 2 by the check unit 6, so that when the remote user turns off the modem, the CD signal is lost and the power driver The power on signal of (7) is canceled and a power off operation takes place.

Alternatively, the remote user may drive the inhibit section 8 to cancel the output of the power driver 7.

FIG. 3 is a block diagram showing a modem connection between a remote site and a system in a remote power control system of a TCOM system according to the present invention. As shown in FIG. 3, the remote terminal 10 transmits a remote modem through an RS232C serial communication cable. (11), the remote modem is connected to the telephone cable, connected to the telephone cable of the system modem (4), and connected to the signal conversion unit (5) through the RS232C serial communication cable to the system modem (4) It is.

Accordingly, the DCD signal (CD signal) generated from the remote terminal 10 is transmitted to the telephone line via the remote modem 11, and received by the system modem 4 of the system in communication with the remote modem 11. It is input to the signal conversion part 5. Therefore, the signal converter 5 converts the signal into a signal that can be recognized in the system and transmits the signal to the checker 6.

On the other hand, in the check unit 6, the DCD signal is applied to the data input terminal of the flip-flop 62-2 by the delay unit 62, and the DCD signal delayed by the predetermined time through the delay unit 62-1 is stored. Since it is applied to the clock terminal of the flip-flop 62-2 through the inverter gate I1, the inverted signal corresponding to the DCD signal is output after being delayed for the delay time (about 150 nsec) of the delay 62-2.

The inverted output signal of the flip-flop 62-2 of the delay unit 62 is applied as a clear signal by the counter 63-1 of the counter 63 and counts up to a predetermined value. In the delay unit 62, if the DCD signal DCD1 changes within a predetermined time (about 150 nsec), the output signal of the flip-flop 62-2 does not change. Accordingly, in the initial state, the counter 63-1 is cleared and the counting operation is not performed.

On the other hand, when the DCD signal DCD1 does not change for more than a predetermined time (about 150 nsec) in the delay unit 62, the output signal of the flip-flop 62-2 changes according to the DCD signal, and the counter 63-1 ) Is cleared and counting starts.

When the ripple carry signal is generated at the counter 63-1, the ripple carry signal is fed back to the preset signal of the delay unit 62 through the inverter gate I2. Since the clock signal of the flip-flop 62-2 is applied only when the DCD signal is output to the counter 63-1 and the DCD signal input to the delay unit 62 is changed and maintained for a predetermined time or more, the changed DCD signal is applied to the changed DCD signal. The output state changes accordingly to release the clear state of the counter 63-1. That is, the delay unit 62 recognizes only the signal that lasts longer than the delay time of the delay unit 62-1 as a normal signal, Clear release control of (63) is performed.

Accordingly, in the counter 63, after the clear release signal is input from the delay unit 62, the counter unit 63 counts up to a predetermined count value and outputs a new ripple carry signal.

Subsequently, the check signal output unit 64 receives the output signal of the count unit 63 as a clock signal of the flip-flop 64-1, and outputs the DCD signal in synchronization with the clock signal. The clock signal is applied only when the set count value of the counter 63-1 is maintained, thereby outputting the DCD signal DCD1 from the flip-flop 64-1. That is, in the case of noise or glitch, the delay time of the delay unit 62 and the count time of the counter 63-1 are blocked.

In this way, the DCD signal from the modem 4 is passed through the signal converter 5, and then the checker 6 checks whether it is noise or glitch. If the DCD signal is an actual DCD signal, the power driver 7, Supply to the inhibit section 8 and the power on / off control section 9.

In this case, the power driver 7 generates a power drive signal (power-request) to inform the interface 2 that the CD signal has been detected.

Accordingly, the upper control module 1 reads the latch bit of the CD signal and performs a corresponding control operation while the power is turned on.

On the other hand, when the first light emitting diode LED1 of the display unit 3 is turned on, it is turned on in the sense that the remote user requests the system, and the reliability check unit 6 checks it and then turns on the power. Then, when the second light emitting diode LED2 is turned on, it becomes large when the user uses the system and requests power off. Even if the light emitting diode LED2 is turned on, if the DCD signal through the modem is true, the power is not actually turned off, and the power is turned off only when the modem is turned on. In addition, when the third light emitting diode LED3 is turned on, it indicates that the remote user is not an authorized user so that the remote user cannot be used by the system by the form Ware, and the power is turned off. . In addition, when the fourth light emitting diode LED4 becomes large, since the remote user has requested a system use right and is an authorized user, the power of the system is turned on to indicate that the system is currently in use.

As described above, the present invention, in the aspect of system management, when the failure diagnosis can perform its function at a remote location, and since the system administrator can access the system of real users, it can be useful also in the post-management of the system. It can be effective.

In addition, the system can be operated unattended, so that the operation of the system can be performed in an area that is inaccessible to humans.

In addition, since the remote control is possible in the post-management of the system, the cost can be reduced, and the utility (UTILITY) can be provided to the user of the system.

Claims (10)

Display of the upper control module 1, which controls the power control module, the output of control data of the upper control module 1, and an interface 2 for inputting each status signal to the upper control module 1, and a power control state. A display unit 3, a modem 4 for receiving a carrier direct (CD) signal on a telephone line and communicating via a telephone line, and converting input / output signals between the modem 4 and the system. A note converter 5, a check unit 6 inputted from the modem 4, and a check unit 6 for checking the reliability of each signal through the signal converter 5, and the higher level control through the interface 2 A power on / off control unit 9 for generating a power on / off control signal based on the power control signal of the module 1 and outputting a display control signal to the display unit 3, and the interface 2 Pass under the control of the upper control module (1) through If the error is checked, the inhibit bit 8 for inhibiting the power control and the display control, the inhibit signal of the inhibit bit 8, the power control signal of the power on / off control unit 9 and the check And a power driver (7) for outputting a power drive signal (power-request) under the control of the unit (6) and outputting a status signal to the interface (2). 2. The check unit (6) according to claim 1, wherein the check unit (6) transmits the DCD signal input from the oscillator (61) and the signal converter (5) which generate a predetermined oscillation frequency by the delay time of the delay unit 62-1. Oscillation of the oscillator 61 through a delay unit 62 delaying the output through the flip-flop 62-2 and a counter 63-1 receiving the output signal of the delay unit 62 as a clear signal. And a counting unit (63) for counting frequencies up to a predetermined value, and a check signal output unit (64) for outputting the DCD signal by the ripple carry signal of the counting unit (63). The DCD signal DCD1 of claim 2, wherein the check signal output unit 64 receives the DCD signal DCD1 as a data input and receives the ripple carry signal of the counter unit 63 as a clock signal. ), A flip-flop 64-1 for outputting?), A delayer 64-2 for delaying the DCD signal DCD1, an output signal of the flip-flop 64-1, and the delayer 64-2. By NAND combining the output signal of the oragate OR1 and the output signal of the delayer 64-2 with an oragate OR1 outputting a DCD signal DCD2. A remote power control system comprising a NAND gate (NAND1) for padding back to a preset signal of a flip-flop (64-2). 2. The non-inverting device of claim 1, wherein the power on / off control unit 9 receives a power on / off signal as a data input and receives a control signal CSR-WR through the interface 2 as a clock signal. A flip-flop F1 for outputting an output signal to the power driver 7 as a power control signal and outputting an inverted output signal to the display unit 3 as a system down display signal; and an inverted output signal of the flip-flop F1; A remote power control system comprising a NAND gate (ND1) for outputting a NAND combination of a DCD signal (DCD2) to the power driver (7) as a control signal. The control unit (CSR-WR) of claim 1, wherein the inhibit unit (8) is supplied with a password PASSWD-WRONG signal of the check unit (6) as a data input. Is supplied as a clock signal and a non-inverted output signal is output to the power driver 7 as an Inhibit control signal, and a flip-flop F2 for outputting an inverted output signal to the display unit 3 as an Inhibit display signal; And a NAND gate (ND2) for applying the DCD signal (DCD2) through the check unit (6) as a clear signal of the flip-flop (F2) in combination with a power supply voltage (Vcc). The flip-flop (F2) according to claim 1, wherein the power driver (7) receives a system power control signal of the power on-off control unit (9) as a data input and receives a remote power control signal as a clear signal. And a power drive signal and a deep three-state gate TI for controlling passage of the output signal of the flip-flop F2 by the output signal of the inactivated unit 8, and an output signal of the three-state gate TI. A photo coupler P. C1 transmitted as a display signal, a relay RY1 for outputting a power drive signal POWER-REQUEST signal based on the output signal of the photo coupler P. C1, and the DCD signal ( And an inverter gate (I1) which inverts DCD2) and outputs the CD signal latch control signal to the interface (2). 2. The display unit (3) according to claim 1, wherein the display unit (3) is provided with a light emitting diode (LED1) for remote power control display by the DCD signal of the check unit (6) and an output signal of the power on-off control unit (9). On the basis of the light emitting diode LED2 for system down display, the light emitting diode LED3 for remote power request inhibit display based on the output signal of the inhibit unit 8, and the power of the power driver 7. Long range power control system, characterized in that consisting of a light emitting diode (LED4) to display a remote power drive display by a drive signal. After the remote power on signal is recognized, the CD signal detecting step (STEP1) for discriminating whether the CD signal is detected, and when the CD signal is detected, latches the CD signal in the register at the interface 2, and remote power on boot. A password checking step (STEP2) for performing a (BOOT) operation and checking a password, and an inhibit bit step (STEP3) for enabling a remote power-on control if the password checked in the password checking step (STEP2) does not match. When the password is passed, the remote control step (STEP4) performs a system boot operation so that the system can be used normally, and operates as a console of the terminal on the remote side, and the CD signal in the CD signal detection step (STEP1). If is not detected, the system control step (STEP5), the remote control step (STEP4), and the system perform a normal power-on boot and perform the corresponding operation by the control on the system side. After performing the control step (STEP5), the remote power control method to perform a power off step (STEP6) to turn off the power by the power off signal and end the control routine. The method according to claim 8, wherein the inhibit step (STEP3) checks the drive ready state of the input / output device and if the drive ready state is set, prepares the power-off of the input / output device, and then cancels the selection of each device. And enabling the remote power-on control to be inhibited. 9. The method of claim 8, wherein the power-off step (STEP6) checks whether the CD signal is latched after inputting the power off signal, and if the CD signal is latched, checks whether the request of the CD signal continues. If a CD signal is requested, returning to the CD signal checking process, and if the CD signal is not latched or if there is no request of the CD signal, turning off the power and terminating the control routine. Long range power control.