WO2007129931A1

WO2007129931A1 - Method, system and a connecting sensor for for identifying the port of a plug board

Info

Publication number: WO2007129931A1
Application number: PCT/RU2007/000181
Authority: WO
Inventors: Boris Alekseevich Khozyainov; Mikhail Valeryevich KOZELEV
Original assignee: Khozyainov Boris; Kozelev Mikhail
Priority date: 2006-05-03
Filing date: 2007-04-13
Publication date: 2007-11-15
Also published as: RU2310210C1; RU2310210C9

Abstract

The invention relates to communication engineering. The use of the invention for identifying a plug board port, through which a network device is connectable, makes it possible to identify the port or a cable which is connected thereto and used for transmitting data by said network device without the replacement or transformation of the entire plug board. For obtaining the claimed technical result, the inventive method consists in embodying each of the connecting sensors, with which the plug board ports are provided, in such a way that they make it possible to detect leakage electromagnetic radiation signals where a discontinuity in a cable path occurs, in placing each connecting sensor near the respective port of the plug board remotely from the other ports and in identifying the concrete port of the plug board by means of a data processing unit, when a leakage electromagnetic radiation is detected by said connecting sensor.

Description

METHOD, SYSTEM AND CONNECTION SENSOR FOR IDENTIFICATION OF THE PANEL PANEL PORT

FIELD OF THE INVENTION

The present invention relates to communication technology and can be used to identify the patch panel port through which the network device is connected.

State of the art

Currently, various means are known for determining the specific port of the patch panel through which the connection and transmission of signals from a network device is carried out.

For example, US Pat. No. 6,684,179 (01/27/2004) and US Pat. No. 6,725,177 (04/20/2004) describe systems and related methods for monitoring a combination of cable port connections. In these systems, each port is equipped with input and output modules, which are opened by an appropriate command from the microprocessor, when data must be transmitted or received through this port. These systems determine which port of a given patch panel connects to which port of another patch panel. However, system data does not determine which port is currently transmitting data.

WO Ns 2004/044599 (May 27, 2004) discloses a system for monitoring ports of a patch panel into which cables are inserted. For this, each port of the patch panel is equipped with a scanned contact, in the case of connecting to it a response contact on the cable connector during electrical scanning of the ports, a response signal is generated. Such a system makes it possible to determine in which port of the patch panel the cable connector is inserted, but cannot identify the cable connected to this panel through which data is transmitted.

Similar systems and methods are described in US Pat. Nos. 6,285,293 (09/04/2001) and JYO 6222975 (04/24/2001) for electrical and optical cables, respectively. Each port of patch panels in systems according to these patents contains a corresponding mechanical sensor that works when a cable end is inserted into this port. However, as in the previous case, in these systems it is impossible to identify the cable connected to this panel through which data is transmitted by the network device.

SUMMARY OF THE INVENTION

Thus, it is an object of the present invention to provide means for identifying a port of a patch panel that would allow identification of a port or cable connected to it through which data is transmitted by a network device without replacing or altering the entire patch panel.

To achieve the indicated technical result, a method for identifying a patch panel port is proposed, each port of which is intended for cable connection of a network device, which consists in equipping each of at least some ports of the patch panel with an appropriate connection sensor and connecting all connection sensors to the processing unit data, moreover, in this method, according to the first object of the present invention, each of the connection sensors is perceptible signals of spurious electromagnetic radiation at the site of heterogeneity in the cable path; place each of the connection sensors near the corresponding port of the patch panel at a distance sufficient for the reception of signals of secondary electrical magnetic radiation arising at the site of inhomogeneity in the cable path near this port when connected by a cable, during transmission of the corresponding signals through this cable, and at a distance from any of the other ports of the patch panel, eliminating false alarms of this connection sensor from signals of secondary electromagnetic radiation from the cable path to any of these other ports; the data processing unit identifies the specific port of the patch panel by a signal from at least the connection sensor corresponding to this port when sensing spurious electromagnetic radiation by this connection sensor.

Data packets can be transmitted along the cable path, then spurious electromagnetic radiation from the transmitted data packets, for example, spurious electromagnetic radiation from the identifiers of the sender and (or) recipient, which identifiers the transmitted data packets are equipped with, is sensed using the connection sensor, including when the sensors perceive these identifiers connectivity.

A signal of a predetermined type can be transmitted along the cable path, then, by means of a connection sensor, spurious electromagnetic radiation that occurs only when this signal is transmitted in a predetermined form is sensed. In this case, a signal of a predetermined type can be transmitted from the data processing unit through the patch panel to the corresponding network device and the corresponding port of the patch panel is identified by identifying the connection sensor of this port that is triggered during this transmission. Or it is possible to pass a signal of a predetermined form from the network device through the patch panel to the data processing unit, then the corresponding port of the patch panel is identified by identifying the connection sensor of this port, which is triggered in this case. In all these cases, a signal of a predetermined form can be formed using IP request, for example, using an echo request using the Internet Protocol Messenger Protocol (ICMP) protocol. A signal of a predetermined form may contain repeatedly repeated sendings for more reliable operation of the corresponding connection sensor. It is possible to identify a specific port of the patch panel by the data processing unit by the moment the signal from the corresponding connection sensor appears, the closest in time to the moment of the event, as a result of which the characteristics of the side electromagnetic radiation change, which leads to the appearance of the signal from the corresponding connection sensor. Moreover, the moment of occurrence of such an event corresponds to the moment of receipt of the notification of the occurrence of this event on the data processing unit. Information about the moment of occurrence of the event may be contained in the notification of the occurrence of the event received on the data processing unit. This event is the setting of either a break in the signal connection via the cable path or a call of the telephone subscriber via the cable path. In order to eliminate false port identification in the event of the simultaneous occurrence of more than one of these events, the final port identification can be carried out after a statistical analysis of the connection sensors operation facts stored in the data processing unit together with information received from the corresponding notifications.

To achieve the same technical result, it is also proposed a system for identifying a patch panel port, comprising a patch panel, each port of which is intended for cable connection of a network device; group of connection sensors; and a data processing unit to which all group connection sensors are connected, and in this system, according to the second object of the present invention, each group connection sensor is configured to receive signals of secondary electromagnetic radiation at the site of the appearance of heterogeneity in the cable path near this port and placed near the corresponding port of the patch panel at a distance sufficient to receive signals of spurious electromagnetic radiation that occurs at the site of the appearance of heterogeneity in the cable path between this port and the cable connected to it, during transmission on this cable the corresponding signals, and at a distance from any of the other ports of the patch panel, eliminating false alarms of this connection sensor from the signal Cable spurious emission to any of these other ports.

The cable in this system can be electric or optical. In the proposed system, the connection sensor can be configured to receive spurious electromagnetic radiation from data packets transmitted through the cable path, including spurious electromagnetic radiation from the identifiers of the sender and (or) receiver, which identifiers are provided with the transmitted data packets; or the connection sensor is configured to sense spurious electromagnetic radiation that occurs when only a predetermined signal is transmitted through the cable path. In the proposed system, the data processing unit can be configured to identify the sender and (or) the recipient of the transmitted data packets by identifiers received by the connection sensor. Otherwise, the data processing unit is capable of transmitting a signal of a predetermined form through a switching panel to the corresponding network device and identifying the corresponding port of the switching panel by identifying a connection sensor of this port that is triggered during this transmission. Or the data processing unit is capable of identifying a signal of a predetermined form that has passed from a network device through a switch- W

the control panel, and identifying the corresponding port of the patch panel by identifying the connection sensor of this port, which is triggered in this case. A signal of a predetermined form can be generated using an IP request, for example, using an echo request using the Internet Control Message Protocol (ICMP); A signal of a predetermined form may contain repeatedly repeated sendings for more reliable operation of the corresponding connection sensor. Finally, the data processing unit can be configured to identify a specific port of the patch panel at the time of the appearance of the signal from the corresponding connection sensor, the closest in time to the moment of the event, as a result of which the characteristics of the side electromagnetic radiation change, which leads to the mentioned appearance of the signal from the corresponding sensor connectivity. In this case, the moment of occurrence of the event may correspond to the time of receipt of the notification of the occurrence of this event at the data processing unit; or information about the moment of occurrence of the event is contained in the notification of the occurrence of this event received on the data processing unit; this event may consist in the installation or disconnection of the signal connection via the cable path or be a call to the telephone subscriber via the cable path. To eliminate false port identification in the event of the simultaneous occurrence of more than one of these events, the data processing unit can be configured to perform final port identification after a statistical analysis of the connection sensors operation facts stored in the data processing unit along with information received from the corresponding notifications.

To achieve the same technical result, a connection sensor is also proposed to identify the port of the patch panel, each port of which is designed for cable connection of the network devices, moreover, according to a third aspect of the present invention, the connection sensor is configured to receive signals of spurious electromagnetic radiation at the site of heterogeneity in the cable path near the port, located close to the corresponding port of the patch panel at a distance sufficient to receive signals of spurious electromagnetic radiation, occurring at the site of heterogeneity in the cable path between this port and the cable connected to it, during transmission through the cable of the corresponding signals, and at a distance from any of the other ports of the patch panel, eliminating false alarms of the connection sensor from signals of spurious electromagnetic radiation from the cable path to any of these other ports, and is connected to a data processing unit configured to identify a specific port of the patch panel based on at least the signals of the connection sensor.

The connection sensor can be equipped with a photosensitive electronic component mounted at the bend of the exposed core of the fiber optic male, connected to the corresponding port of the patch panel. Either this connection sensor can be equipped with an antenna mounted near the electrical connector of the corresponding port of the patch panel or near the end of the electric cable connected to the corresponding port of the patch panel. The connection sensor can also be equipped with a light indication element for highlighting the triggered connection sensor by the corresponding signal from the data processing unit.

Brief Description of the Drawings

In all the drawings, the same reference numerals refer to the same or similar elements. In FIG. 1 depicts a general block diagram of a system for identifying a patch panel port according to the present invention.

In FIG. Figure 2 shows an example of placement of connection sensors in a patch panel according to one embodiment of the present invention when optical cables are used.

DETAILED DESCRIPTION OF THE INVENTION

The method of the present invention can be implemented in several similar ways, which, however, are implemented in the same system. A block diagram of this system is shown in FIG. 1 and contains a patch panel 1 having several (at least two) ports 2, each intended for cable connection of a device. Next to each port 2 is a connection sensor 3. Details of its placement are given below. A network device 5 is connected to each port 2 using an appropriate cable connection (cable) 4. In FIG. 1 personal computers are shown as network devices, however this is just an illustration, as network devices can be, for example, printers, information boards and other network devices, the specific form of which does not matter for the implementation of the present invention.

The patch panel 1 is connected to the network hub 6 using the appropriate cables 7. In addition, the system has a data processing unit 8 connected by a connection 9 to the network hub and a connection 10 to all sensors 3 of the patch panel 1. FIG. Figure 1 shows the case when the number of ports 2 of the patch panel 1 is less than the number of ports on the network hub 6, but this is just an illustration. In the general case, the number of ports on the hub and the panels that are produced by different companies are not connected in any way. The cable path 4 can be either electric or optical. This particular embodiment of cable 4 determines what type of connection sensor 3 will be used. However, regardless of the design of cable 4, each connection sensor 3 has a special arrangement in the patch panel 1.

In FIG. 2 shows the case where the cables 4 are optical. In this case, each connection sensor 3 is located next to the place where the core of the optical cable is bent to connect to its port 2 (connector). In this place, incidental optical radiation arises due to the inhomogeneity (bending) of the optical cable 4. A connection sensor 3 is intended for recording this incidental radiation. However, each of the connection sensors 3 is located at a sufficient distance from any of the other ports 2, so that this connection sensor 3 does not have false positives from the spurious emission of cables 4 to neighboring ports 2. In the optical cable variant 4, sensors 3 can be surrounded by an individual opaque screen, covering the nearest length of the core of the optical cable. The sensors 3 in the case of optical cables 4 can be made, for example, in the form of phototransistors or photodiodes sensitive to radiation with the wavelength used in these optical cable paths 4.

If electric cables 4 having a shielding braid are used, then the sensors 3 are located in close proximity to the place where the electric core of cable 4 leaves this braid for connection with its port 2, i.e. in the place of heterogeneity in the cable path 4, and at a sufficient distance from any of the other ports 2, so as not to perceive the spurious (spurious) radiation of these neighboring ports 2. In this case, the connection sensors 3 can be made in the form of a simple current loop, which plays a role antennas and laid around the unshielded section of the cable path 4 core or near the port 2 itself.

In FIG. 1, connections 7 between the patch panel 1 and the network hub 6 are shown arbitrary (one of the cables 7 is shown removed from its sockets). The connection 9 according to the protocol is similar to the connections of network devices 5 with a network hub 6. The connection 10 from the data processing unit 8 is generally bus.

The data processing unit 8 is any computing tool programmed to perform the actions described below. It can be a separate computer, but it can also be a microcontroller or a processor with memory integrated directly into the patch panel 1 or into a network hub 6.

The method of the present invention is implemented in the described system as follows. In a system whose patch panel 1 is equipped with the indicated connection sensors 3 located in the manner described above near the corresponding ports 2 of the patch panel 1 and connected to the data processing unit 8, several operating modes can be performed. In the process of any of these modes, the processing unit 8 identifies a specific port 2 of the patch panel 1 by a signal from a connection sensor 3 located next to this port and, possibly, another signal. The connection sensor 3 responds to spurious electromagnetic radiation that occurs at a place of heterogeneity in the cable path near its corresponding port 2 and generates a signal to the data processing unit 8.

In one of the possible operating modes, the connection sensor 3 senses spurious electromagnetic radiation from data packets transmitted via a cable path 4 connected to that port 2 near which this connection sensor 3 is located. In this case, block 8 processing data registers simply the fact of the transmission of packet data on the corresponding cable path 4.

In a more complex version, each data packet transmitted along the cable path 4 or some of these data packets are provided with identifiers of the sender and (or) receiver. Such identifiers can be MAC addresses or IP addresses of the sender and (or) receiver. In this case, the connection sensor 3 can be configured to perceive precisely these identifiers - for example, by appropriately manufacturing the connection sensor 3, in which each connection sensor 3 will have a specialized chip that extracts the identifiers from the standard Ethernet protocol packets. In this case, the data processing unit 8 will identify the port 2 through which the transfer is carried out by these identifiers of the data packets. The data processing unit 8 can itself extract these identifiers from the signals coming from the connection sensor 3, and it is not necessary to complicate the design of the connection sensor 3 in any way.

In yet another mode of operation, the cable path 4 from the data processing unit 8 through connection 9 and through a network hub 6 transmit a signal of a predetermined form to the network device 5. This may be, for example, a unique sequence of pulses. This option can also be implemented in the “reverse” direction, i.e. a signal of a given type can also be transmitted from a network device 5. In this case, the connection sensor 3 may contain a matched filter configured for this signal of a given type. When receiving spurious radiation during the passage of such a signal through port 2, the sensor 3 will give a signal to the data processing unit 8, which identifies the port 2 through which this signal is transmitted. As in the case with packet identifiers, the connection sensor 3 can only be a device, any spurious radiation from its port 2, and the recognition of a predetermined signal will be carried out in the data processing unit 8.

It can be noted here that a signal of a predetermined form can be generated using an IP request, i.e. request in accordance with the Internet protocol. For example, such a signal can be generated with the help of the so-called echo request using the IPTop Copper Messaging Protocol (ICMP) protocol (see, for example, the website http://book.itep.ru/4/44/icmp_444.htm). You can, for example, send a pip request to the appropriate network address, containing a code in your body that causes the formation of radiation of a predetermined form. A signal of a predetermined form may contain repeatedly repeating transmissions, for example, transmissions of the unique pulse sequence mentioned above, for more reliable operation of the corresponding connection sensor 3.

In another mode of operation, the identification of port 2 through which transmission is carried out is as follows. Through a network hub 6, a signal of a given type is sent to the corresponding network device 5, however, in this case, the type of this signal does not matter for identifying port 2. Network hub 6 transmits to the data processing unit 8 via connection 9 a notification of the type “the specified signal was transmitted to such that moment in time)). The data processing unit 8, having received this notification, compares it with which of the connection sensors 3 received the change in the spurious electromagnetic radiation at the moment closest to the moment indicated in the message. Instead of a notification from the network hub 6, a simple pulse signal can be received about the fact of the transmission of a given signal, then the data processing unit 8 will register that connection sensor 3, which will work immediately after receiving this pulse signal.

The signal of a given type can not be transmitted, but instead, the data processing unit 8 will register some event that changes spurious electromagnetic radiation, which is perceived by the corresponding connection sensor 3. Such an event may be the installation of a signal connection via the corresponding cable path 4 or, conversely, a break in such a connection. It is clear that in order to eliminate the false identification of port 2 in the case when several (more than one) of the above events occur simultaneously, in the data processing unit 8, it is possible to carry out a statistical analysis of the stored data on the facts of the operation of the connection sensors 3 together with the information obtained from the above - broadcasts.

Each of the connection sensors 3, regardless of whether the cable path 4 is optical or electric, can be equipped with a light indication element (not shown), so that it is easier to identify the triggered connection sensor 3 when a signal of a given kind of.

Thus, in the implementation of the present invention, it is possible to identify the port 2 of the patch panel 1 or the cable path 4 connected to this cable 2 through which data is transmitted. In this case, it is not necessary to replace or remake the entire patch panel 1, it is enough to install the connection sensors 3 according to the present invention on it.

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

Claim

1. A method for identifying a patch panel port, each port of which is intended for cable connection of a network device, which consists in the following:

- equip each of at least some ports of said patch panel with a corresponding connection sensor;

- connect all the connection sensors to the data processing unit; characterized in that:

- perform each of the mentioned connection sensors with the possibility of receiving signals of secondary electromagnetic radiation at the place of occurrence of heterogeneity in the cable path;

- place each of the said connection sensors near the corresponding port of the said patch panel at a distance sufficient to perceive the above-mentioned signals of spurious electromagnetic radiation arising at the site of inhomogeneity in the cable path near this port when connected by cable, when the corresponding signals are transmitted through this cable, and at a distance from any of the other ports of the aforementioned patch panel, eliminating false alarms of said connection sensor from signals of spurious electromagnetic radiation from the cable path to any of these other ports;

- identify by the data processing unit the specific port of the patch panel by a signal from at least the connection sensor corresponding to this port when sensing the said spurious electromagnetic radiation by this connection sensor.

2. The method according to claim 1, characterized in that the data packets are transmitted along the cable path and the secondary electromagnetic radiation from the transmitted data packets is sensed by the connection sensor. 2

3. The method according to p. 2, characterized in that they are used to sense spurious electromagnetic radiation from the identifiers of the sender and (or) the receiver, with which identifiers the transmitted data packets are equipped with, using the connection sensor.

4. The method according to claim 3, characterized in that the sender and / or the receiver of the transmitted data packets are identified by the data processing unit by the identifiers received by the connection sensor.

5. The method according to claim 1, characterized in that a signal of a predetermined type is transmitted through said cable path and, with the aid of a connection sensor, spurious electromagnetic radiation that occurs only when this signal is transmitted in a predetermined form is sensed.

6. The method according to claim 5, characterized in that said signal of a predetermined form is transmitted from said data processing unit via said patch panel to a corresponding network device and the corresponding port of said patch panel is identified by identifying a connection sensor of this port that is triggered by this transmission.

7. The method according to p. 5, characterized in that the said signal of a predetermined form, transmitted from the network device through the said patch panel, is fed to the data processing unit and the corresponding port of the said patch panel is identified by identifying the connection sensor of this port, which .

8. The method according to p. 5, characterized in that said signal of a predetermined form is formed using an IP request.

9. The method according to claim 8, characterized in that said signal of a predetermined form is formed using an echo request using the Internet Control Message Protocol (ICMP). 3

10. The method according to p. 5 or 9, characterized in that the said signal of a predetermined form contains repeatedly repeated premises for more reliable operation of the corresponding connection sensor.

11. The method according to p. 1, characterized in that the data processing unit identifies the specific port of the patch panel at the time the signal from the corresponding connection sensor appears, the closest in time to the time the event occurs, as a result of which the characteristics of the side electromagnetic radiation change, which leads to mentioned occurrence of a signal from a corresponding connection sensor.

12. The method according to p. 11, characterized in that the moment of occurrence of said event corresponds to the moment of receipt of a notification of the occurrence of said event at said data processing unit.

13. The method according to p. 11, characterized in that information about the moment of occurrence of the mentioned events is contained in the notification of the occurrence of the mentioned events received on the data processing unit.

14. The method according to p. 11, characterized in that said event is the installation of a signal connection along said cable path.

15. The method according to claim 11, characterized in that said event is a break in the signal connection in said cable path.

16. The method according to p. 11, characterized in that said event is a call to a telephone subscriber on said cable path.

17. The method according to p. 12 or 13, characterized in that in order to eliminate the false identification of the port in the event of the simultaneous occurrence of more than one of the mentioned events, the final identification of the port is carried out after a statistical analysis of the memorized 4 of the data processing unit of the facts of the operation of the said connection sensors together with the information obtained from the corresponding notices.

18. A system for identifying a patch panel port, comprising: a patch panel, each port of which is for cable connection of a network device; group of connection sensors; and a data processing unit to which all the connection sensors of the said group are connected, characterized in that each connection sensor of the said group is configured to receive signals of spurious electromagnetic radiation at the site of the heterogeneity in the cable path near the port and is located near the corresponding port of the said patch panel on a distance sufficient to perceive the above-mentioned signals of secondary electromagnetic radiation arising at the site of the appearance of inhomogeneity in Yelnia path between the data port and attached to it a cable, transmission by the cable respective signals, and at a distance from any of the other ports of said patch panel, eliminates false triggering of said sensor is connected by signal side cable channel radiation to either of the other ports.

19. The system according to p. 18, characterized in that the said cable is made electric.

20. The system according to p. 18, characterized in that said cable is made optical.

21. The system according to claim 18, characterized in that the said connection sensor is configured to receive spurious electromagnetic radiation from data packets transmitted through the cable path. 5

22. The system according to p. 21, characterized in that the said connection sensor is configured to receive spurious electromagnetic radiation from the identifiers of the sender and (or) receiver, which identifiers are provided with the transmitted data packets.

23. The system of claim 22, wherein said data processing unit is configured to identify a sender and / or recipient of transmitted data packets by identifiers received by said connection sensor.

24. The system according to p. 18, characterized in that said connection sensor is configured to sense spurious electromagnetic radiation arising from the transmission of only a predetermined signal through said cable path.

25. The system of claim 24, wherein said data processing unit is configured to transmit said signal of a predetermined form through said switching panel to a corresponding network device and identifying the corresponding port of said switching panel by identifying a connection sensor of this port that is triggered by this transmission.

26. The system according to p. 24, characterized in that said data processing unit is configured to identify said signal of a predetermined form, passed from a network device through said patch panel, and to identify the corresponding port of said patch panel by identifying a connection sensor of this port that is triggered wherein.

27. The system according to p. 24, characterized in that said signal of a predetermined form is formed using an IP request.

28. The system according to p. 27, characterized in that said signal of a predetermined form is formed using an echo request using the Internet Control Message Protocol (ICMP). b

29. The system according to p. 24 or 28, characterized in that the said signal of a predetermined form contains repeatedly repeated sendings for more reliable operation of the corresponding connection sensor.

30. The system of claim 18, wherein said data processing unit is configured to identify a specific port of a patch panel at the time of the appearance of a signal from a corresponding connection sensor, closest in time to the occurrence of an event, as a result of which the characteristics of the side electromagnetic radiation change, which leads to the mentioned occurrence of a signal from a corresponding connection sensor.

31. The system according to p. 30, characterized in that the moment of occurrence of said event corresponds to the moment of receipt of a notification of the occurrence of said event at said data processing unit.

32. The system of claim 30, wherein the information about the moment of occurrence of the mentioned event is contained in the notification of the occurrence of the said event received on the data processing unit.

33. The system of claim 30, wherein said event is the installation of a signal connection over said cable path.

34. The system of claim 30, wherein said event is a break in a signal connection in said cable path.

35. The system according to p. 30, characterized in that said event is a call to a telephone subscriber on said cable path.

36. The system according to p. 31 or 32, characterized in that to eliminate the false identification of the port in case of simultaneous occurrence of more 7 of one of the mentioned events, said data processing unit is configured to perform final port identification after statistical analysis of the facts of activation of said connection sensors stored in said data processing unit together with information received from said corresponding notifications.

37. The connection sensor for identifying the port of the patch panel, each port of which is designed for cable connection of a network device, characterized in that said connection sensor is configured to receive signals of spurious electromagnetic radiation at the site of heterogeneity in the cable path near this port, located near the corresponding port said patch panel at a distance sufficient for the reception of said signals of spurious electromagnetic radiation, in when the corresponding signal is transmitted through this cable and away from any of the other ports of the aforementioned patch panel, eliminating false alarms of the aforementioned connection sensor from signals of secondary electromagnetic radiation from the cable path to any of these other ports, and is connected to a data processing unit configured to identify a specific port of the aforementioned switching port oh panel based on at least the signals of said sensor connection.

38. The connection sensor according to claim 37, characterized in that said connection sensor is equipped with a photosensitive electronic component mounted at the bend of the exposed core of the fiber optic male connected to the corresponding port of said patch panel. 8

39. The connection sensor according to claim 37, characterized in that said connection sensor is provided with an antenna mounted near the electrical connector of the corresponding port of said patch panel.

40. The connection sensor according to claim 37, wherein said connection sensor is provided with an antenna mounted near the termination point of the electric cable connected to the corresponding port of said patch panel.

41. The connection sensor according to any one of paragraphs. 37-40, characterized in that the said connection sensor is equipped with a light indication element for isolating a triggered connection sensor by a corresponding signal from said data processing unit.