JPH01126052A - Power supply on/off detection system for terminal equipment - Google Patents

Abstract

PURPOSE:To discriminate power supply on/off of a terminal equipment and an open line by a master station by applying loop connection of two reception wires to two transmission wires when the power supply is turned off in a terminal equipment where it is connected in star with the master station by a 4-wire line. CONSTITUTION:An exchange 101 is used as the master station and plural terminal equipments 103-1-103-N are connected thereto in star by 4-wire lines 102-1-102-N. The two wires of the four wires are used for signal reception wires from the master station and the remaining two wires are used for signal transmission wires from a terminal equipment. When the power supply of the terminal equipment is turned off, the two wires for reception and the two wires for transmission are connected in a loop by the terminal equipment. A signal is sent to the reception line by the master station to detect the reception state of the transmission line. Thus, the power supply interruption of the terminal equipment and the communication line interruption are discriminated easily to improve the maintenance performance.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a method for detecting the power on/off (ONloFF) state of terminal devices, and in particular detects power-off and line disconnection of terminals connected in a star configuration. The present invention relates to a power supply 0N10FF state detection method of a terminal device suitable for identification.

[Conventional technology]

An example of a method for detecting power-on of a terminal device is disclosed in Japanese Patent Application Laid-open No. 52
-149042. This method is applied to a terminal control device and a terminal connected to it at multiple points, and communication is performed between the terminal device and the terminal control device using a polling selection method.

(1) When the terminal device is powered on, it sends a power-on signal from the terminal device to the communication control device.

(2) The terminal control device treats the signals from each terminal device as general information signals until there is no response to polling, and after that, treats the signals as power-on signals to turn on the power to the terminal device. To detect.

Further, in a local area network, for example, Ethernet, power-off of a terminal is detected by no response to a packet to that terminal.

Furthermore, since power is supplied to the general telephone terminal from the exchange side, there is no need for the exchange side to detect the power ON 10FF of the terminal.

[Problem that the invention seeks to solve]

The above-mentioned conventional technology is used to detect communication cable disconnection.
It was not updated and there were maintenance problems.

For example, in the case of JP-A-52-149042, even if a communication cable is broken, there is no response to polling, resulting in the same state as when the terminal power is cut off, so it is impossible to discover and repair a communication cable break at an early stage.

Furthermore, in the case of Ethernet, a similar problem occurs because it is not possible to distinguish between a communication cable disconnection and a terminal power disconnection.

An object of the present invention is to improve maintainability by making it possible to clearly distinguish between a communication cable disconnection and a terminal power disconnection on the switching device side, particularly in a system in which terminal devices are connected in a star shape.

[Means for solving problems]

The above purpose is to directly connect the receiving line and the transmitting line in the terminal device when the power is off, and to connect the receiving line and the transmitting line directly on the network (exchange) side.
This is achieved by checking the continuity between the receiving cables.

Furthermore, the transmission path is time-division multiplexed between terminal equipment networks, and synchronization patterns are used to synchronize frames from the network to the terminal.
Different patterns are used from the terminal to the network, and if the receiving line is out of frame synchronization on the network (exchange) side, the terminal outputs the frame synchronization pattern of the network to the transmitting line, or
Alternatively, by confirming synchronization from the network using the frame synchronization pattern for terminals on the receiving side, it is possible to distinguish between power failure and communication line disconnection and immediately detect them.

[Effect]

By directly connecting the transmission and reception lines on the terminal side only when the terminal equipment is powered off, the transmission and reception lines will be in a conductive state from the perspective of the f4 (exchange) side, so if there is no response from the terminal, the network By checking the continuity between the transmitting and receiving lines from the (exchange) side, it is possible to determine whether the terminal device is powered on or off.

Furthermore, if the transmission path is time-division multiplexed and a frame synchronization pattern is inserted periodically, the terminal power supply O
FF, disconnection of the communication line is caused by loss of frame synchronization (
It can be detected immediately on the switching equipment side. Here, by outputting the frame synchronization pattern on the transmitting side only when the terminal device has established frame synchronization on the receiving line, disconnection of the terminal line from the network will also cause frame synchronization on the network side. can be detected.

Different synchronization patterns are used from the network to the terminal and from the terminal to the network. Therefore, if synchronization occurs on the network (switch) side, either the frame synchronization pattern from the network to the terminal is changed to the synchronization pattern for the terminal to the network, or the frame synchronization pattern on the receiving line on the network (switch) side is changed. By checking the synchronization from the network using the frame synchronization pattern for the terminal,
It is possible to distinguish between a terminal power outage and a communication line break. That is, when the terminal is powered off, the transmission and reception lines are directly connected in the terminal device, so the signal transmitted from the network (exchange) side returns to the receiving side as is. Therefore, frame synchronization on the receiving side can be established by changing the frame synchronization pattern on the transmitting or receiving side. In addition, if the communication line is disconnected, the network (exchange)
Frame synchronization cannot be established because no frame synchronization pattern appears on the receiving side. Therefore, power failure of the terminal device and disconnection of the communication line can be easily identified.

〔Example〕

An embodiment of the present invention will be described below with reference to FIGS. 1 to 4.

FIG. 1 shows a typical system to which the present invention is applied. A plurality of terminal devices 103-1 to 103-N are connected to the exchange 101 in a star shape via four-wire lines 102-1 to 102-N. One pair of the four-wire lines 102-1 to 102-N is connected from the exchange 101 to the terminal devices 103-1 to 103-10.
3-N, and the other pair is used for signal transmission in the opposite direction.

Signals between the exchange 101 and the terminal devices 103-1 to 103-N) are time-division multiplexed and transmitted. FIG. 2 shows the frame structure. The transmission speed is 2.048 Mbps, the frame period is 125 μs, and one frame consists of 256 bits. Two B channels (mainly for audio,
64kbps), P channel for high-speed packet transmission (
1,536 Mbps), D channel for signaling (
16kbps) and frame synchronization pattern (SYN
C), terminal control information (CNT2), information for controlling the flow between the P channel terminal device and the exchange (CNTI
), parity pits (S) are multiplexed. More P.

The D channel is a channel for packet transmission, and a V pit (indication of data transmission in progress) is added to every 1 byte to indicate the start and end of a packet.

The frame synchronization pattern is "'11010" from the exchange 101 to the terminal devices 103-1 to 103-N, and '01 from the terminal devices 103-1 to 103-N to the exchange.
011'' is used. The transmitting and receiving circuits in the terminal devices 103-1 to 103-N operate using the clock extracted from the received signal.

FIG. 3 shows communication line interfaces of the terminal devices 103-1 to 103-N. Receiving side line 301
And the transmission side line 302 is connected to a relay 319. Relay 319 has contacts 303 to 306 and control electromagnet 3
It consists of 07. The operation of relay 319 is controlled by power switch 308 of terminal devices 103-1 to 103-H. That is, the terminal devices 103-1 to 103-N
When the power is cut off, the contacts 303 to 306 are tilted in the direction shown in FIG. 3, and the receiving line and the transmitting line are directly connected. In addition, terminal devices 103-7 to 103
- When the power switch 308 of H is turned on, the control electromagnet 3
07, the relay contacts 303 to 306 operate, and the transmission/reception lines 301 and 302 are connected to the balanced/unbalanced conversion transformers 309 and 310. The received signal is corrected for distortion on the transmission path by an equalizer 311, and converted from a transmission path code (for example, a differential Manchester code) to an NRZ signal (313). Meanwhile, a clock is extracted from the equalizer 311 output signal (314) and supplied to the transmitting/receiving circuit. A frame synchronization circuit 314 extracts a frame signal from the received signal converted to an NRZ signal, and uses this to separate each channel (315). Conversely, each channel signal generated by the terminal device is multiplexed. (318), converted into a transmission line code (317), and outputted to the transmission line by the driver 316. Frame synchronization circuit output 32
If the channel multiplexer 318 is controlled with 0, a frame synchronization pattern (SYNC) can be output to the transmitting side only when frame synchronization on the receiving side is established.

FIG. 4 shows the configuration of the frame synchronization circuit on the exchange 101 side. Similarly to the terminal devices 103-1 to 103-N, the received signal 401 converted into an NRZ signal is delayed by the number of bits specified by the counter 403 in the variable delay shift register 402. 5-bit shift register 4
The signal 410 parallelized by 04 is compared with the frame synchronization pattern by a coincidence detection circuit 405. The frame synchronization pattern is "0101" from the terminal device to the exchange.
1" and "11010" for the terminal device from the exchange can be selected and used with the selector 407.

In a synchronized state, the synchronization pattern is output from the 5-bit shift register 404 at the rising edge of the frame signal 408, so the output of the coincidence detection circuit 405 is uHn (high), and the output of the AND gate 406 is 1L' (low). ), and the counter 403 is not counted up.

The state in which synchronization is established persists. On the other hand, in a state where synchronization is lost, the output of the coincidence detection circuit 405 becomes l L +, so the counter 403 counts up at the rising edge of the frame signal, the delay amount of the variable delay shift register 402 changes, and finally can achieve frame synchronization. The frame synchronization circuit requires forward and backward protection circuits, but these are omitted because they are not related to the present invention.

Based on the above explanation, a method for detecting a terminal device's power supply 0N10FF will be explained.

In the frame synchronization circuit on the exchange 101 side, selector 407
”01011 as the frame synchronization pattern.
” is used. When the terminal devices 103-1 to 103-H are powered on, the relay 319 uses g3oi for one communication.

Since 302 is connected to the transformers 309 and 310, the frame synchronization pattern from the terminal side is "01011".
", and frame synchronization can be achieved on the exchange 101 side. In this state, the terminal devices 103-1 to 103-N
When the power to the communication line 3 is cut off, the relay 307
01 and 302 are connected. As a result, the frame synchronization pattern ``11010'' sent from the exchange 101 is looped back and returned to the exchange 101, resulting in a loss of frame synchronization.Here, when the selector 407 is controlled to change the frame synchronization pattern to ``11010'', the frame Synchronization can be achieved and it can be determined that the terminal is powered off.From the exchange 101 to the terminal devices 103-1 to 103-1
If the communication line going to 03-N is disconnected, terminal device 1
03-1 to 103-N are out of synchronization, transmission to the frame synchronization pattern exchange 101 side is stopped, and if the communication line from the terminal devices 103-1 to 103-N to the exchange 101 is disconnected, Since no signal is input, frame synchronization is lost on the exchange 101 side in any case, and synchronization is not recovered even if the frame synchronization pattern is changed, so it is possible to distinguish and identify the terminal devices 103-1 to 103-N. .

Furthermore, it is obvious that a power outage of a terminal can be distinguished from a disconnection of a communication line by checking the continuity between the transmitting and receiving lines from the converter side.

〔Effect of the invention〕

According to the present invention, power disconnection of a terminal and disconnection of a communication line can be easily distinguished and identified, which is effective in improving maintainability.

[Brief explanation of the drawing]

Fig. 1 is a conceptual diagram of a communication system implementing the present invention, Fig. 2 is a frame configuration diagram on a communication line, Fig. 3 is a block diagram of a communication line interface of a terminal device, and Fig. 4 is a frame on the exchange side. FIG. 2 is a block diagram of a synchronous circuit. 101... Exchange, 102-1 to 102-N... Communication line, 103-1 to 103-N... Terminal device, 30
1゜302...Communication line, 303-306...Relay contact, 307...Relay control electromagnet, 308...
Terminal device power switch, 309, 310...Transformer, 311...Equalizer, 312...Clock extraction circuit, 313°317...Code converter, 314...Frame synchronization circuit, 315...・Channel separation circuit, 316
...Driver, 318...Channel multiplex circuit, 31
9... Relay, 320... Frame synchronization status display line, 401... Frame synchronization circuit input, 402... Variable delay shift register, 403... Counter, 404
...Shift register, 405...Coincidence detection circuit, 4
06...AND gate, 407...Selector, 40
8... Frame signal, 409... Frame synchronization circuit output, 410... Shift $11\l] Figure 2 12345 and 739

Claims (1)

[Claims] In a system in which terminals are connected in a star configuration using 1- and 4-wire lines, when the power to the terminals is turned off, the terminals transmit signals received through the receiving line to the transmitting line. 1. A power on/off detection method for a terminal device, comprising means for transmitting data to a network side through a line. 2. In the system described in item 1, the power on/off detection method for a terminal device is characterized by having means for directly connecting a receiving line to a transmitting line when the terminal device is powered off. . 3. In the system described in item 1, synchronization between the network and the terminal and between the terminal and the network is achieved by periodically inserting different frame synchronization patterns from the network to the terminal and from the terminal to the network,
On the network side, if the receiving line is out of frame synchronization, either change the frame synchronization pattern inserted into the transmitting line from the terminal to the network frame synchronization pattern, or use the frame synchronization pattern from the network to the terminal. A power on/off detection method for terminal equipment that determines whether the terminal is powered on or off by checking the frame synchronization status of the receiving line. 4. In the system described in item 2, a power on/off detection method for a terminal device that determines whether the terminal is powered on or off by measuring the continuity state of the transmitting side line and the receiving side line on the network side. 5. In the system described in item 3, the terminal device power on/off detection method is characterized in that the terminal device outputs a frame synchronization pattern to the transmission line only when synchronization of the reception line is established.