RU2618190C1 - System of cable connections monitoring with usage of reflectometer - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: monitoring system is equipped with a cord panel with a switch, which changes the results of using the reflectometer in the cable path. Comparing the moment of using the switch and the changes in the results of reflectometer usage, the port of cord panel is determined, into which the port of network device is connected.

EFFECT: ability to monitor cable connections without establishing a network connection by using the built-in network device reflectometer.

17 cl, 4 dwg

Description

FIELD OF THE INVENTION

The present invention relates primarily to communication technology and can be used to monitor the connection of patch panels.

State of the art

In the world there are various means of monitoring cable connections, the main task of which is to understand how the devices are connected using a cable.

For example, in US 2006/0164998, a Time Domain Reflectometry is used to analyze newly appeared connections in a cable line.

Also known is the method and system described in patent RU 2313800, having connection sensors on the patch panel. Sensors are triggered when a connection between devices is established, and the identification of the panel port where the network device is connected occurs by comparing the sensor triggering events and changing the status of the network device port.

Also known is the method and system described in patent RU2490807, which describes a patch panel with sensors that sense OTDR signals. The disadvantage of this solution is the design complexity of the OTDR sensor, since the OTDR signals are not standardized.

SUMMARY OF THE INVENTION

Thus, the present invention is the development of such a means of monitoring cable connections using a reflectometer, which will allow you to identify the port of the patch panel where the port of the network device is connected, using a simpler design of system elements than described in patent RU 2490807.

To achieve the indicated technical result, a cable connection monitoring system using an OTDR is proposed, comprising a network device containing ports for network connections, in which at least several ports are connected to the OTDR for cable lines to measure the parameters of the cable path connected to the port; patch panel with ports for connecting cables; characterized in that it contains at least one section of the cable path, which is part of the patch panel and includes one of the ports of the panel containing a device that changes the electrical parameters of the cable path, including the said section of the cable path; contains a hardware-software complex capable of changing the result of using an OTDR on a cable path containing said section, acting on a device that changes the electrical parameters of the cable path; and the hardware-software complex identifies the port of the patch panel where the port of the network device is connected, comparing the result (s) of the OTDR measurements and the cable path in which the electrical parameters are changed.

In one embodiment of the present invention, the patch panel may include at least one data sensor that changes the output signal when data is transmitted between the network devices through the panel port corresponding to the sensor. The data transfer sensor can pick up spurious electromagnetic radiation from data transmission signals transmitted through a conductor connected to the 3 or 6 pin of the IEC 60603-7 standard connector on the network device port. Or the data transfer sensor may have an electrical connection to the 3 and 6 pins of the IEC 60603-7 standard connector of the corresponding port of the above-mentioned patch panel.

At the same time, the hardware-software complex can identify the port of the patch panel where the port of the network device is connected by comparing the time of the change in the data transfer signal between the network devices and the time of the change in the signal of the data transfer sensor.

In addition, the hardware-software complex can change the electrical parameters of the cable path when, using the data transmission sensor, it determines the absence of some data transmission signals in the cable path.

In yet another embodiment of the present invention, a device that changes the electrical parameters of the cable path can be connected to the tracks of the printed circuit board or the wires of the cable path. In this case, a device that changes the electrical parameters of the cable path can increase the resistance in one of the conductors of the cable path or reduce the resistance between the two conductors of one pair of cable path, which is connected to the 3 and 6 or 1 and 2 pins of the connector of the IEC 60603-7 standard of the network device port .

A device that changes the electrical parameters of the cable path may contain a reed switch or an analog key.

In another embodiment, the patch panel may include infrared sensors that detect the presence of a patch cord connector in the panel port, as well as indicator lights for their ports.

A data transmission sensor and / or a device that changes the electrical parameters of the cable path can be connected to the cable path using a connector. In another case, the data transfer sensor can sense spurious electromagnetic radiation using an inductor that is connected to the signal amplifier through a connector.

To reduce noise immunity, the data transfer sensor may contain two inductors; one of them receives radiation from data transmission signals transmitted through a conductor connected to the 3-pin connector of the IEC 60603-7 standard port of a network device; the other mentioned coil receives radiation from data transmission signals transmitted through a conductor connected to the 6th pin of the IEC 60603-7 standard network device port connector; and said coils are arranged and interconnected so that the phases of the emf of the coils differ by no more than 45 degrees. Additionally, one contact terminal of each of these inductors can be connected via a connector to a signal amplifier, and with the help of another contact terminal, the coils are connected to each other.

Brief Description of the Drawings

In FIG. 1 shows a general diagram of a cable connection monitoring system.

In FIG. 2 shows a diagram of a device that changes the electrical parameters of the cable path, increasing the resistance in the cable path.

In FIG. 3 shows a diagram of a device that changes the electrical parameters of the cable path, reducing the resistance between the conductors of one pair of cable path.

In FIG. Figure 4 shows a typical port of a network device in accordance with IEC 60603-7.

DETAILED DESCRIPTION OF THE INVENTION

The system of the present invention can be implemented in several versions, which, however, are implemented in a similar manner, as shown in figure 1. The design of the patch panel 1 may be different. The IEC 60603-7 (RJ45) standard connector on the panel 1 port can be connected behind the front of panel 1 to the IDC connectors (to which the cable from the workstation is connected) using conductors on the printed circuit board. In another embodiment, the port on the front of panel 1 may be a KeyStone type connector, which, using a twisted pair behind the panel, connects to the same KeyStone connector, which, in turn, connects to the cable from the workstation terminated by an RJ45 plug (IEC 60603-7 ) In both versions, a device that changes the electrical parameters of the cable path and a sensor for data transmission signals can be installed on the portion of the cable path between the front connector and the rear connector (KeyStone or IDC).

A sensor for data transmission signals is described, for example, in patent RU 74536 or RU 2490807 and is used to determine the presence of spurious electromagnetic radiation (PEMI) near the port of a patch panel caused by data transmission signals between network device 2, in this case, a 100Base-T switch, and another network device, such as a personal computer, connected via cable to the panel 1 port on the back. Alternatively, the connection sensor may be electrically connected directly to the cable path. If such a sensor has a high input resistance, then its effect on the useful signal will be negligible.

As described in patent RU 2313800 at the time of establishing an electrical connection between the personal computer and the switch (including via connecting cable 3), data immediately begins to be transmitted, since even in the absence of user data, the signal is transmitted “Idle” on the cable. At the same time, information on changes in the port state is transmitted to the firmware on a hardware-software complex via a network (standard way using SNMP traps, a log file or reading the current status of the MAC address table). The hardware-software complex, which in the general case is a network computer with the corresponding software, compares the connection setup time and the sensor response time, determines which port of panel 1 connects the cable 3 connector that connects the panel 1 port to switch port 2.

But such a system is inoperative if the said personal computer is not connected to the network. The invention RU2490807 is intended to solve this problem. Many modern network switches (for example, the Cisco 2960 series) have a Time Domain Reflectometry, which allows you to determine the total length of the cable path connected to the switch port. The start of the OTDR signals through the port of the switching panel 1 and the detection of the OTDR signals with the help of the sensor make it possible to determine which port of the panel 1 is connected to the port of the switch 2, without establishing a network connection. Such an OTDR signal sensor is difficult to manufacture and produce, it must accept non-standardized pulses of a nanosecond duration. Therefore, the present invention proposes to replace the OTDR signal sensor with a device that changes the electrical parameters of the cable path and has a very simple design.

In one of the options it can be a reed switch, for example Meder MK22, in another an analog key, for example MAX4706. In both cases, this is a switch controlled by the hardware-software complex, which in the closed state has a resistance close to zero and in the open state at least several hundred ohms (taking into account the fact that both the key and the reed switch represent the capacitance for the RF signal). In FIG. 2 and 3, the switch 4 is connected to a portion of the cable path 5. In FIG. 2, switch 4 is normally closed. OTDR signals pass through it without interference, but due to the effect of the software and hardware complex (applying a logic level to the analog switch, applying voltage to the electromagnet coil near the reed switch), the switch opens, and as a result of the OTDR operation, a cable break can be detected. You can, of course, remember the “normal” OTDR test results for scanned ports for comparison, but there is an easier way. The switch must be connected to a conductor electrically connected to 3 or 6 pins of the panel port connector (or network switch, since the panel and switch ports are connected by cable 3 of Fig. 1 one to one). In any case, the switch tests at least two pairs of cable. The lengths of these pairs are almost equal. This means that if, as a result of testing with an OTDR, a sharp difference in lengths is detected in the cable, the desired section of the cable path is determined, so the cable path itself and the port of the patch panel, which is an integral part of the cable path, are identified. Knowing on which port of the network device the “defective” test was run, one can compare the measurement result (s) of the mentioned OTDR and the cable path in which the electrical parameters have changed and identify the port of the patch panel where the port of the mentioned network device is connected.

If you use the circuit in FIG. 3, then, at the command of the hardware-software complex, a normally open switch “shorts” the conductors of the pair of contacts 3 and 6. Thus, the OTDR test detects the “closure” of the pair at a small distance from the network switch. In this case, the pair length at pins 1 and 2 remains normal.

It is understood that the use of the switch in cable paths where data is transmitted can lead to a malfunction. For this, data transmission sensors should be used. First you need to check if there is data in the cable path, and then "short-circuit" or break the conductors. Please note that not all data impedes the use of the switch. For example, 100Base-T auto-negotiation signals also carry 16 bit information, but the use of a device that changes the electrical parameters of the cable path in the path with such signals will not lead to failure.

To increase the sensitivity and noise immunity, the data transmission sensor may contain two inductors, one of which receives spurious electromagnetic radiation from one conductor, and the other perceives spurious electromagnetic radiation from another conductor of the same pair, to which the first conductor is arranged, so that the phases EMF of these two coils differ by no more than 45 degrees. That is, the EMF from the common-mode interference simultaneously traveling along two conductors of the same pair will be subtracted, and it will be added up from the data transmission signals.

As a device that changes the electrical parameters of the cable path, the data transfer sensor can be soldered to the wires or mounted on a printed circuit board. In the latter case, it is convenient to connect the switch and the sensor using the connectors. The sensor amplifier, for example, the BFT46 JFET transistor and the reed switch, should be placed on a separate printed circuit board, and the inductance (s) should be soldered directly above the circuit board track. From the terminals of the inductance and from the tracks of the printed circuit board, make branches (using matching elements) to the pin connectors, for example, PBS-5 sockets. A separate printed circuit board with a transistor and a reed switch can be connected to the printed circuit board of the patch panel using a similar PLS-4 pin plug. If two coils are used for the data transmission sensor, then the coils are connected in series, and the remaining free leads are connected to the connector.

In addition, it is useful to equip the patch panel with IR sensors that trigger the connection of the connector to the panel port, and LED indicators above the panel ports.

Although the present invention has been described with reference to specific embodiments, it will be apparent to those skilled in the art that these illustrative examples in which various modifications can be made do not limit the scope of the invention defined only by the appended claims.

Claims (23)

1. A monitoring system for cable connections using an OTDR, comprising: - a network device containing ports for network connections, in which at least several of these ports are connected to an OTDR for cable lines to measure the parameters of the cable path connected to the port; - patch panel with ports for connecting cables, characterized in that - contains at least one portion of the cable path, which is part of the patch panel and includes one of the ports of the panel containing a device that changes the electrical parameters of the cable path, including the said portion of the cable path; - contains a hardware-software complex capable of changing the result of using the said reflectometer on the cable path containing the said section, acting on the said device, which changes the electrical parameters of the cable path; - said hardware-software complex identifies the port of said patch panel where the port of said network device is connected, comparing the result (s) of measurements of the mentioned OTDR and the cable path in which the electrical parameters are changed. 2. The system according to claim 1, characterized in that said panel comprises at least one data transmission sensor that changes the output signal when data is transmitted between network devices through a panel port corresponding to said sensor. 3. The system according to claim 2, characterized in that said data transmission sensor picks up side electromagnetic radiation from data transmission signals transmitted through a conductor connected to 3 or 6 pin of the IEC 60603-7 standard port connector of said network device. 4. The system according to claim 2, characterized in that said data transmission sensor has an electrical connection to 3 and 6 pins of an IEC 60603-7 standard connector of the corresponding port of said patch panel. 5. The system according to claim 2, characterized in that said software and hardware complex identifies a port of said patch panel where a port of said network device is connected, comparing the time of change of the data signal between network devices and the time of change of the signal of said data transfer sensor. 6. The system according to claim 2, characterized in that said software and hardware complex changes the electrical parameters of the cable path when, using the said data transmission sensor, it determines the absence of some data transmission signals in the cable path. 7. The system according to claim 1, characterized in that the said device, which changes the electrical parameters of the cable path, is connected to the tracks of the printed circuit board or the wires of the cable path. 8. The system according to p. 1, characterized in that the said device, which changes the electrical parameters of the cable path, is able to increase the resistance in one of the conductors of the cable path. 9. The system according to claim 1, characterized in that the said device, which changes the electrical parameters of the cable path, is able to reduce the resistance between the two conductors of one pair of cable path, which is connected to the 3 and 6 or 1 and 2 pins of the connector of the IEC 60603-7 standard port said network device. 10. The system according to p. 1, characterized in that the said device, which changes the electrical parameters of the cable path, contains a reed switch or an analog key. 11. The system according to claim 1, characterized in that said patch panel contains infrared sensors that detect the presence of a patch cord connector in the panel port. 12. The system according to claim 1, characterized in that the patch panel contains light indicators for its ports. 13. The system according to p. 4, characterized in that said data transmission sensor is connected to said path using a connector. 14. The system according to p. 1, characterized in that the said device, which changes the electrical parameters of the cable path, is connected to the cable path using a connector. 15. The system according to p. 3, characterized in that the said data transmission sensor receives spurious electromagnetic radiation using an inductor that is connected to the signal amplifier through a connector. 16. The system according to p. 3, characterized in that said data transmission sensor comprises two inductors; one of them receives radiation from data transmission signals transmitted through a conductor connected to the 3-pin connector of the IEC 60603-7 standard port of the mentioned network device; the other mentioned coil receives radiation from data signals transmitted over a conductor connected to the 6th pin of said port of the IEC 60603-7 standard port of a network device; said coils are arranged and interconnected in such a way that the EMF phases of said coils differ by no more than 45 degrees. 17. The system according to p. 16, characterized in that one contact terminal of each of said inductors is connected through a connector to a signal amplifier, and using another contact terminal, said coils are connected to each other.

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