RU83679U1 - MULTIPLEXOR DISPLAY CONNECTIONS MONITORING SYSTEM - Google Patents

Abstract

A monitoring system for detachable connections with a multiplexer, comprising: patch panels, each of at least some of the ports of which is equipped with a connector sensor that changes state when a patch cable connector is connected to said ports of the patch panel; radio frequency reader; antennas located on said patch panels; connecting cables, at least one connector of which is equipped with a connector sensor with a near-field RFID tag, which is readable by said RFID reader, if the distance between said RFID tag of the connector sensor and any of the mentioned ports is less than the distance specified by the manufacturer, system supplier or user; a controller that processes the signals of said connector presence sensors, and which is capable of identifying said connector and / or connecting cable and said patch panel port to which said connector is connected based on a signal of said connector presence sensor and information about a change in a response signal from an RF tag of said sensor a connector transmitted by said radio frequency reader to said controller after connecting a connector of a connecting cable equipped with omyanutym sensor connector, in a patch panel port, equipped with said sensor availability connector; characterized in that it comprises a multiplexer which supplies a signal of said radio frequency reader to one of said antennas, selected by said controller on the basis of and

Description

The technical field to which the utility model relates.

This utility model relates to communications technology and can be used to monitor patch panel connections.

State of the art

In the world there are various means of monitoring cable systems. The main purpose of such systems is to determine which ports of the patch panel the connecting cable is connected to, that is, monitoring the connections of the variable part of the cable path (channel in terms of ISO / IEC 11801: 2002).

For example, a similar system based on a wireless solution is described in US Pat. No. 6,784,802. Radio frequency tags are installed on the connectors of the connecting cables. Tag identifiers are read using RF reader antennas installed in each port on the patch panel. The disadvantage of this system is that the reader antenna must be installed in each port of the panel.

The closest analogue is the system described in the patent for utility model of the Russian Federation No. 79738. The patch panel ports are equipped with a connector sensor. Radio frequency tags are installed on the connectors of the connecting cables, which change the response signal when the connector is close to the port of the patch panel. Tag IDs are read using RF reader antennas. The connection is identified by comparing the closest sensors for the presence of the connector and

changing the response from the RF tag of the connector. The disadvantage of this system is that due to the limited processing speed of tags, a large number of patch panels need to install many RF readers.

Utility Model Essence

Thus, the objective of this utility model is to develop detachable connection monitoring tools that will identify the patch cable and patch panel port to which the patch cable connector is connected, while a single RF reader can serve a large number of panels.

To achieve the indicated technical result, a monitoring system for detachable connections with a multiplexer is proposed, comprising patch panels, each of at least some of the ports of which is equipped with a connector sensor that changes state when a patch cable connector is connected to the patch panel ports; radio frequency reader; antennas located on patch panels; connecting cables, at least one connector of which is equipped with a connector sensor with a near-field RF tag, which is readable by a radio frequency reader, if the distance between the RF tag of the connector sensor and any of the mentioned ports is less than the distance specified by the manufacturer, supplier or system user; a controller that processes the signals of the presence sensors of the connector, and which is able to identify the connector and / or connecting cable and port of the patch panel to which the connector is connected based on the signal of the presence sensor of the connector and

information on the change in the response signal from the radio frequency tag of the connector sensor transmitted by the radio frequency reader to the controller after connecting the connector of the connecting cable equipped with the connector sensor to the port of the patch panel equipped with the presence sensor of the connector; characterized in that it comprises a multiplexer that supplies a signal from an RF reader to one of the antennas, selected by the controller based on a change in the signal of one of the sensors of the presence of the connector and / or direct indication of the user.

To increase the functionality of the system, the panel ports can be equipped with modulators that change the response of the RF tags of the connector sensors perceived by the reader under the influence of a control signal from the controller.

In addition, the panel ports can have at least one indicator light controlled by the controller, as well as a switch activated by the human hand, the state of which is perceived by the controller.

Brief Description of the Drawings

Figure 1 shows a General block diagram of a monitoring system detachable connections with a multiplexer.

Figure 2 shows a possible embodiment of a modulator with a PIN diode.

Detailed description of utility model

The system according to the present utility model can be implemented in several versions, which, nevertheless, are implemented in a similar manner, as shown in figure 1. The system contains patch panels 1, the ports of which are equipped with sensors for the presence of a connector

connecting cable in the port of the panel 2. Their design can be different, a mechanical switch or a pair of LED-photodiode (US patent No. 6424710). The connectors of the connecting cable 3 are equipped with sensors of the connector in the form of a radio frequency tag (RFID tag) of the near field 4 of a suitable size, for example, Impinj Button2. In this case, an unambiguous correspondence of the labels 4 with the connecting cords 3 and the sensors 2 with the ports of the patch panels 1. In another case, the pair of label identifiers 4 of one connecting cable contains the same unique code for this cable, and one of the identifier bits determines the connector number of this cord. A database (not shown) is connected to controller 5 via Ethernet (in this case, the controller is identical to the software and hardware complex of RF patent No. 79738). The controller 5 can be made on the basis of a conventional personal computer connected to the reader module 6 (for example, MTI RU-859) via USB. The antennas 7 of the radio frequency reader 6 are a current loop, which covers the ports 8 of the patch panel, or microstrip lines on the printed circuit board. The radio frequency reader 6 can be connected to several antennas 7 through a coaxial cable 8 through controlled RF switches 9.

The RF switch 9 may contain a T-shaped connector and a switching relay (for example, Tohtsu CX-230 or solid-state on a printed circuit board) that connects to a coaxial cable 8 or antenna 7, or a load impedance matched to the wave impedance. In another case, the switching relay either connects the antenna 7, or another segment of the coaxial cable 8, located farther from the reader (RF cross over relay).

Thus, the RF switches 9 play the role of a distributed multiplexer. But the signals to antenna 7 can also be supplied by a conventional RF multiplexer.

The controller 5 receives information about the state of the sensors 2 via the data bus 10. The bus 10 can be of type I2C Fm +, while the state of the sensors can be obtained using the I2C PCA9698 expander. Or it is possible to organize a synchronous bus from a flat cable, through which a panel is selected with one serial clock from the controller 5, and a panel sensor is selected with other serial clocks, from which the state of the corresponding sensor 2 is received on the controller 5, i.e. on a printed circuit board with antenna 7 of the patch panel 1 installed at least a pair of logical counters-decoders. On the same bus 10, complex 5 controls the RF switches 9.

Several panels 1 with the equipment described above are similarly connected to coaxial cable 8 and bus 10. Each of them has its own unique address for this controller 5, either based on the PCA9698, or DIP switches with logical circuits “AND”. Typically, the number of panels 1 is limited by the size of the 19 "telecommunications cabinet, which is served by one controller 5.

In the standby state, the controller 5 polls the sensors 2 of all the panels serviced 1. In this case, the RF reader does not transmit a signal to the coaxial cable 8. As soon as the connecting cable 3 is connected to one of the ports of one of the panels 1, the state of the corresponding sensor 2 will change and will be sensed by the controller 5. The controller 5, via bus 10, uses the RF switch (s) 9 to connect the corresponding antenna 7 through the coaxial cable 8 to Reader 6. Reader 6 reads all available RFID tags 4 and

transfers identifiers from controller 5. Controller 5 selects among these marks a new one that was absent at the previous start of reader 6 on this panel. Knowing the number of the panel 1, the number of the sensor 2 that worked on this panel and the identifier of the label 4 of the connector, controller 5 correlates this connector with the mentioned port and transfers the information to the database.

A second variant of connecting antenna 7 to the reader is possible. Usually connecting cables 3 are connected in panel 1 according to a strictly defined task (a list of future connections). If the user gives a direct indication to controller 5, then he can pre-connect the antenna to the reader 6, the panel of which appears in the next step of the task. In this case, it is also possible to interrogate the sensors 2 of all panels in order to avoid erroneous or unauthorized connection, in which case the first option for connecting antennas can be used.

When disconnecting the cable 3 from the panel 1, the corresponding sensor 2 also changes its state, about which the controller 5 notifies the database. At the same time, you can not use the reader 6, since the identifier of the label of the disconnected connector is already determined at connection.

The system described above has the following disadvantage. When the system power is turned off, the commutation that has occurred will not be recorded. And it will be difficult to restore them. To do this, it is proposed to equip each port of panel 1 with a modulator that will change the response signal of label 4 received by the reader 6 when the corresponding connector is connected to the panel port, according to the control action of the controller 5.

The modulator may have a different design, but in any case, it is controlled via the same bus 10 by the controller 5. This can be

electromagnet. In such an embodiment, tag 4 may include a reed switch in series in the antenna, so that tag 4 is read without the modulator’s magnetic field. After a power failure, the controller 5 can sequentially scan all the tags 4 connected in the connector panel. Obviously, you need to scan only those ports of the panels where the connector of the connecting cable 3 is connected. In this case, the antenna 7 of the scanned panel is connected to the reader 6. Before scanning, the controller 5 receives a list of all the labels available on the panel 4. Then it supplies power to the electromagnet of the first port (if there there is a connector), and the reader reads all available tags. The label that has disappeared from the list of available ones (due to the opening of the reed switch) uniquely identifies the corresponding connector. The same operation is performed with other ports and other panels.

The modulator may have a different design, which allows you to modulate conventional RF tags without switches. This design is shown in FIG. 2, and is a fragment 11 of a microstrip antenna 7 in the form of a printed conductor on a printed circuit board with a PIN diode 12. The lower part of the fragment 11 is located near the RF tag of the connector when the connector is connected to the panel. If a bias current is not applied to diode 12, then its dynamic resistance is very high, and the RF current of the reader antenna flows along the lower part of fragment 11. As soon as a constant bias voltage is applied to diode 11 with a controller 5, its resistance becomes very small, and part of the RF signal will go through diode 12 bypassing the lower part of the fragment. In this case, the alternating magnetic field coming from the lower fragment 11 to the label 4 will decrease. In this case, the RFID tag 4 may stop reading at all. In any case, its response signal level (RSSI) will greatly decrease. And on the basis of this, just as in the construction with

electromagnets, you can conclude which particular label was modulated.

In addition, each port of the system can be equipped with one or more light indicators (LEDs or bulbs), also controlled via the bus 10 by the controller 5, for visual indication of the port in several versions. As well as a trace switch (in the form of a button or a pair of a photodiode LED for reflection), when activated by the operator, the LEDs highlight the corresponding port and the port with which the first port is connected.

In this way, the patch cable and patch panel port to which the patch cable connector is connected can be identified, while a single RF reader can serve a large number of panels.

Claims (4)

A monitoring system for detachable connections with a multiplexer, comprising: patch panels, each of at least some of the ports of which is equipped with a connector sensor that changes state when a patch cable connector is connected to said ports of the patch panel; radio frequency reader; antennas located on said patch panels; connecting cables, at least one connector of which is equipped with a connector sensor with a near-field RFID tag, which is readable by said RFID reader, if the distance between said RFID tag of the connector sensor and any of the mentioned ports is less than the distance specified by the manufacturer, system supplier or user; a controller that processes the signals of said connector presence sensors, and which is capable of identifying said connector and / or connecting cable and said patch panel port to which said connector is connected based on a signal of said connector presence sensor and information about a change in a response signal from an RF tag of said sensor a connector transmitted by said radio frequency reader to said controller after connecting a connector of a connecting cable equipped with omyanutym sensor connector, in a patch panel port, equipped with said sensor availability connector; characterized in that it comprises a multiplexer which supplies a signal of said radio frequency reader to one of said antennas, selected by said controller based on a change in signal of one of said sensors of connector presence and / or direct indication of a user. 2. The system according to claim 1, characterized in that said panel ports have a modulator that changes the response signal of said radio frequency tags of the connector sensors perceived by said reader under the influence of a control signal from said controller. 3. The system according to claim 1, characterized in that said panel ports have at least one indicator light controlled by said controller. 4. The system according to claim 1, characterized in that said panel ports have a switch activated by the human hand, the state of which is perceived by said controller.