WO2014042558A1

WO2014042558A1 - Method for identifying the cable via which a device is transmitting a signal

Info

Publication number: WO2014042558A1
Application number: PCT/RU2013/000774
Authority: WO
Inventors: Борис Алексеевич ХОЗЯИНОВ
Original assignee: Khozyainov Boris Alekseevich
Priority date: 2012-09-13
Filing date: 2013-09-05
Publication date: 2014-03-20
Also published as: RU2518439C2; RU2012139167A

Abstract

The invention relates primarily to communication engineering. It can be used to identify the cable via which a network device is transmitting a signal. For this purpose, a point is determined, on the outer sheath of a cable, at which the level of stray electromagnetic radiation arising from a signal is sufficient to be picked up by an appropriate sensor. Thereafter, the cable is identified by correlating the time at which a signal is altered and the time at which the sensor is activated.

Description

METHOD FOR CABLE IDENTIFICATION BY WHICH THE DEVICE SIGNS

The technical field to which the invention relates. The present invention relates to communication technology and can be used to identify the cable through which the network device is connected.

BACKGROUND OF THE INVENTION The closest analogue of this invention is the method described in patent RU2310210. In this patent, the ports of the patch panel are equipped with sensors that sense electromagnetic interference from signals transmitted through the cable path, and the patch panel port is identified based on the sensor signals.

The disadvantage of this method is that many patch panels have a design that does not allow the installation of sensors for spurious electromagnetic radiation. This disadvantage can be eliminated by placing sensors of spurious electromagnetic radiation directly on the cable where the signal is transmitted.

SUMMARY OF THE INVENTION

Thus, the present invention is the development of such means of cable identification, which would allow to identify the cable through which data is transmitted by the network device by installing sensors directly on the cable.

To achieve the specified technical result, a method for identifying a cable through which a network signal is transmitted the device, which consists in determining the place near the outer sheath of the cable, within which the spurious electromagnetic radiation sensor is able to perceive spurious electromagnetic radiation that occurs in the cable at the time of transmission of the signal from the network device through the cable; at the same time equip the cable with a sensor of spurious electromagnetic radiation, installing the sensor in the aforementioned place; using a network device change the signal transmitted by cable; comparing the time of the signal change and the time of the change in the state of the sensor, identify the cable through which the network device transmits the signal.

In one embodiment of the present invention, the cable may be an unshielded twisted pair cable.

At the place of installation of the sensor, one of the wires of one of the twisted pairs of the cable can be closer to the mentioned sensor than the second wire of the twisted pair, so that the reliability of the sensor is no less than the value specified by the user, installer, or manufacturer of the sensor.

The sensor senses the magnetic or electrical component of the electromagnetic field.

The location for installing the sensor can be determined during the manufacturing of the cable, either by determining the distance to one of the wires of the cable, or by transmitting a signal through the cable and moving the sensor along and / or around the cable at least until the first change in the state of the sensor.

The time of signal change can also be determined in different ways: using SNMP messages, by the time the changes appeared in the MAC address table, or by using a log file. Brief Description of the Drawings

In FIG. 1 shows an option for installing the sensor on a twisted pair cable.

DETAILED DESCRIPTION OF THE INVENTION The method of the present invention can be implemented in several ways, which, however, are carried out in a similar manner. Figure 1 shows a cable type unshielded twisted pair in section. The cable contains at least the outer sheath 1, inside of which there are twisted pairs, most often four. A differential signal is transmitted along the twisted pair, and currents flowing through the different wires of the pair in different directions almost completely destroy the electromagnetic radiation of the twisted pair. Indeed, if you install a sensor of spurious electromagnetic radiation on the surface of the shell 1 at point 2 of figure 1, it will be difficult to detect electromagnetic radiation from wire 3 for two reasons: wire 3 is far enough from the shell; at point 2, cable 4 creates an alternating electromagnetic field whose direction is opposite to the direction of the field from cable 3. In accordance with the principle of superposition, the incidental electromagnetic radiation at point 2 is practically zero, it is extremely difficult to detect.

But the wires in a twisted-pair cable continuously twist one relative to the other. At some point in space along the cable sheath 1, one of the twisted pair wires 5 turns out to be in close proximity to the cable sheath, as at point 6, and much closer than wire 7. If a sensor 8 is installed in close proximity to point 6, it receives an incidental electromagnetic radiation, it is possible to obtain information at least about the presence in the conductor 5 of data transmission signals. The sensor options and identification method are largely based on patents RU74536 and RU2310210. In one embodiment, an EC24 type inductor of 1 mH can be used as a sensor. When signals (including the Idle signal) of the Ethernet standard are transmitted in the cable, for example, lOOBase-T, the current flowing in the wire 5, or rather its inherent alternating magnetic field, creates an EMF in the coil turns (sensor 8). This EMF can be amplified and detected by standard circuitry (JFET field effect transistor, operational amplifiers and comparators including those with input field effect transistors). Obviously, the magnitude of the magnetic field inverse from the cable 7 will be less than the field from the cable 5 due to the greater distance to the sensor 8. In this case, the cable can be identified as follows. Modern network switches, for example, Cisco 2960, record (through SNMP, MAC address table, log files) the moment of connection establishment and disconnection in the switch port. And the moment of installation and breaking of the connection coincides with the moment of appearance of a certain type of spurious electromagnetic radiation in the cable. Comparing the moment the connection is established or disconnected by the port and the moment the sensor status changes, you can determine through which cable one or another switch port transmits signals. Moreover, in the present patent, a network device is understood to mean a device having a MAC address or other unique network identifier. It should be noted that, unlike patent RU2310210, the patch panel may be absent and present in the cable path at the request of the user.

If a field-effect JFET transistor is used as sensor 8, the method of the present invention can be used to detect a ringing signal of telephony, which creates an electric field at point 6. Again, comparing the response time of the sensor and the start time of the subscriber’s call, you can determine which port of the telephone exchange the cable is connected to. For the correct functioning of the method of the present invention, it is important to correctly determine the location of the sensor 8 on the cable sheath 1. There are several ways to do this.

At the time of manufacture of the cable at the factory, mark in the right place on the outer sheath of the cable.

"See" the place where the wire 5 is closest to the outer shell 1, using an X-ray or terahertz apparatus.

The optimal location for the sensor is the point on the sheath, where the conductor comes closest to the outer sheath of the cable. This place can be determined using a metal detector with an inductive sensor, based on a change in the oscillation amplitude of the generator when a metal object is introduced into the active zone of the sensor. The disadvantage of this method is that it is difficult to determine the number of twisted pair, the conductor of which was in the sensor coverage area. Therefore, for the 100Base-T protocol, which uses pairs 2 and 3, this method is not suitable, but for other protocols that use all pairs, for example, 1000Base-T, it is applicable.

Another way to determine the location of the sensor is as follows. You can connect two devices with a cable and transmit signals through it. For example, connect two network devices using a cable using the 100Base-T protocol. In this case, at least an Idle signal will always be present in the cable. Then move the temporary or permanent spurious transducer along and around the cable sheath. The point at which the level of spurious electromagnetic radiation is sufficient can be noted to place a permanent sensor or immediately attach the sensor to the cable in this place.

Claims

Claim

1. A method for identifying a cable through which a network device transmits a signal, the method comprising:

- determine the place near the outer sheath of the cable, within 5 of which the sensor of spurious electromagnetic radiation is able to perceive spurious electromagnetic radiation that occurs in said cable at the time of transmission of the signal from the network device via said cable;

- equip said cable with a sensor of secondary electromagnetic radiation, installing said sensor in said place;

- using said network device change said signal transmitted over said cable;

- comparing the time of change of the said signal and the time 15 of the change of state of the said sensor, identify the cable through which the signal transmits the said network device.

2. The method according to p. 1, characterized in that said cable is a cable of unshielded twisted pair type.

3. The method according to p. 1, characterized in that in said place one of the 20 wires of one of the twisted pairs of said cable is closer to said sensor than the second wire of said twisted pair, so that the reliability of operation of said sensor has a value no lower than specified by the user, installer, or manufacturer of said sensor.

25 4. The method according to p. 1, characterized in that the said sensor senses the magnetic component of the electromagnetic field.

5. The method according to p. 1, characterized in that the said sensor senses the electrical component of the electromagnetic field.

6. The method according to p. 1, characterized in that said place is determined in the manufacturing process of said cable.

7. The method according to p. 1, characterized in that the said place is determined by determining the distance to the wire mentioned

5 cables.

8. The method according to p. 1, characterized in that said place is determined by transmitting a signal through said cable and moving a sensor receiving electromagnetic spurious radiation along and / or around said cable at least until the first change in the state of the sensor.

9. The method according to p. 1, characterized in that the said signal change time is determined using SNMP messages.

10. The method according to p. 1, characterized in that the said time of change of the signal is determined by the time the change in the table

15 MAC addresses.

11. The method according to p. 1, characterized in that the said signal change time is determined using a log file.