CN113794958B - Intelligent networking control method based on multiple areas - Google Patents

Abstract

The invention relates to an intelligent networking control method based on multiple areas, belongs to the technical field of networking control, and solves the problem that the prior art lacks of the intelligent networking control method related to the multiple areas and the multiple devices. The method comprises the following steps: according to networking requirements, connecting one or more networking devices in a region to an optical fiber HUB in the region, and connecting the optical fiber HUBs in the same region or different regions to form an optical fiber network; the networking control module controls the state of each fiber HUB connected to the fiber network to finish intelligent networking of networking equipment; when the networking control module controls the appointed networking equipment to transmit data, an optical fiber interface module connected with the appointed networking equipment receives an optical fiber signal sent by the appointed networking equipment, converts the optical fiber signal into a serial electric signal and transmits the serial electric signal to a cross switch in the optical fiber interface module; the transmission path of the serial electric signal is determined according to the state of the next-stage crossbar of the crossbar.

Description

Intelligent networking control method based on multiple areas

Technical Field

The invention relates to the technical field of intelligent networking, in particular to an intelligent networking control method based on multiple areas.

Background

In the prior art, with the development of diversification of networking forms, the networking forms are not limited to a single area, but devices in a plurality of areas are required to cooperate together to realize networking, that is, a certain work involves a plurality of devices in a plurality of areas.

Therefore, the networking mode of networking devices in a single area cannot meet the networking requirements, and how to implement intelligent networking control involving multiple areas and multiple devices has become an urgent problem to be solved.

Disclosure of Invention

In view of the above analysis, the present invention aims to provide an intelligent networking control method based on multiple areas, so as to solve the problem that the intelligent networking control method involving multiple areas and multiple devices is lacking in the prior art.

The invention provides an intelligent networking control method based on multiple areas, which comprises the following steps:

according to networking requirements, connecting one or more networking devices in a region to an optical fiber HUB in the region, and connecting the optical fiber HUBs in the same region or different regions to form an optical fiber network;

the networking control module controls the state of each fiber HUB connected to the fiber network to finish intelligent networking of networking equipment;

when the networking control module controls the appointed networking equipment to transmit data, an optical fiber interface module connected with the appointed networking equipment receives an optical fiber signal sent by the appointed networking equipment, converts the optical fiber signal into a serial electric signal and transmits the serial electric signal to a cross switch in the optical fiber interface module; the transmission path of the serial electric signal is determined according to the state of the next-stage crossbar of the crossbar.

Based on the scheme, the invention also makes the following improvements:

further, the determining the transmission path of the serial electric signal according to the state of the next-stage crossbar of the crossbar includes:

if the next-stage cross switch is in a conducting state, converting the serial electric signal into an optical fiber signal, transmitting the optical fiber signal to optical fiber equipment connected with the next-stage optical fiber interface module, and sending the optical fiber signal again by the optical fiber equipment;

if the next-stage cross switch is in an off state, the serial electrical signal is directly transmitted to the next-stage cross switch, and a transmission path of the serial electrical signal is repeatedly determined according to the state of the next-stage cross switch.

Further, in the process that the networking control module controls the appointed networking equipment to transmit data, when the optical fiber interface module connected with the appointed networking equipment receives the optical fiber signal again, the continuous transmission of the optical fiber signal is stopped.

Further, the status of the fiber optic HUB includes the status of each crossbar and each fiber optic interface in the fiber optic HUB;

the state of the cross switch comprises an on state and an off state;

the states of the fiber interface include an enabled state, a disabled state, and a connected state.

Further, the fiber HUB includes N fiber interface modules; wherein,

each optical fiber interface module comprises an optical transceiver sub-module and a crossbar switch: wherein,

the optical transceiver sub-module is used for externally connecting optical fiber equipment; the optical fiber equipment is an optical transceiver sub-module of an optical fiber interface module in one networking equipment or another optical fiber HUB;

the crossbar switch comprises a serial input end, a serial output end, a cascade input end and a cascade output end; wherein,

the serial output end of the optical transceiver sub-module is connected with the serial input end of the cross switch, and the serial input end of the optical transceiver sub-module is connected with the serial output end of the cross switch; the cascade input end and the cascade output end are used for realizing cascade connection among a plurality of the cross switches in the fiber HUB.

Further, the crossbar switch is in an off state by default, at this time, a serial input end of the crossbar switch is connected with a serial output end, and a cascade input end is connected with a cascade output end;

when the cross switch is in a conducting state, the serial input end of the cross switch is connected with the cascade output end, and the cascade input end is connected with the serial output end.

Further, the cascade output end of the ith cross switch is connected with the cascade input end of the (i+1) th cross switch, i=1, … and N-1;

the cascade output end of the N-th cross switch is connected with the cascade input end of the 1-th cross switch.

Further, the optical transceiver submodule includes:

the optical fiber interface is used for externally connecting optical fiber equipment and receiving optical fiber signals from the optical fiber equipment or sending the optical fiber signals to the optical fiber equipment;

the optical fiber transceiver is connected with the optical fiber interface and is used for realizing the mutual conversion between an optical fiber signal and a serial electric signal; and taking a port of the optical fiber transceiver for sending the serial electric signal as a serial output end of the optical transceiver sub-module, and taking a port of the optical fiber transceiver for receiving the serial electric signal as a serial input end of the optical transceiver sub-module.

Further, the networking control module completes intelligent networking of the networking device by performing the following operations:

the networking control module receives the status of the optical fiber HUB and gathers the interface IDs of the optical fiber interfaces in the connected status;

when the networking control module controls the appointed networking equipment to transmit data, determining the optical fiber equipment for receiving the transmission data based on the interface ID of the optical fiber interface in the connected state;

controlling a cross switch in an optical fiber interface module corresponding to the optical fiber equipment for receiving the transmission data to be switched to a conducting state;

and then, starting the designated networking equipment to transmit data.

Further, the fiber HUB further comprises a control assembly;

the optical fiber interface is in an enabled state by default; when the optical fiber interface in the starting state is externally connected with optical fiber equipment, the control assembly controls the optical fiber interface to be switched to the connected state;

the control component is also used for detecting faults of the optical fiber interface, and when the faults of the optical fiber interface are detected, the optical fiber interface is controlled to be switched to a forbidden state;

the control component is also used for receiving an optical fiber interface forbidden control signal sent by the networking control module and controlling the optical fiber interface to be switched to a forbidden state based on the received optical fiber interface forbidden control signal.

Compared with the prior art, the invention has at least one of the following beneficial effects:

the intelligent networking control method based on multiple areas can effectively improve the flexibility of networking and wiring processes, effectively improve networking capacity, and well solve the problem that the prior art lacks of intelligent networking control methods involving multiple areas and multiple devices; when the networking task changes, the user only needs to replace optical fiber equipment to access the optical fiber HUB again, and the work of rewiring is not needed, so that the operation of the user is facilitated. In addition, through the interconnection of a plurality of optical fiber HUBs, the expansion of networking equipment accessed in the intelligent networking process is realized.

Meanwhile, the method also describes a networking control process, and the process can realize the transmission of data in the networking.

In the invention, the technical schemes can be mutually combined to realize more preferable combination schemes. Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

The drawings are only for purposes of illustrating particular embodiments and are not to be construed as limiting the invention, like reference numerals being used to refer to like parts throughout the several views.

Fig. 1 is a flowchart of an intelligent networking control method based on multiple areas in an embodiment of the present invention;

FIG. 2 is a schematic diagram of a cascaded relationship of a crossbar in an optical fiber HUB according to an embodiment of the present invention; wherein,

the crossbars of fig. 2 (a) are all in the off state;

the first and fourth crossbars of fig. 2 (b) are in the on state;

fig. 3 is a schematic structural diagram of an optical fiber HUB according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of an intelligent networking system based on multiple areas in an embodiment of the present invention.

Detailed Description

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings, which form a part hereof, and together with the description serve to explain the principles of the invention, and are not intended to limit the scope of the invention.

Example 1

The invention discloses an intelligent networking control method based on multiple areas, wherein a flow chart is shown in fig. 1, and the method comprises the following steps:

step S1: according to networking requirements, connecting one or more networking devices in a region to an optical fiber HUB in the region, and connecting the optical fiber HUBs in the same region or different regions to form an optical fiber network;

step S2: the networking control module controls the state of each fiber HUB connected to the fiber network to finish intelligent networking of networking equipment;

step S3: when the networking control module controls the appointed networking equipment to transmit data, an optical fiber interface module connected with the appointed networking equipment receives an optical fiber signal sent by the appointed networking equipment, converts the optical fiber signal into a serial electric signal and transmits the serial electric signal to a cross switch in the optical fiber interface module; the transmission path of the serial electric signal is determined according to the state of the next-stage crossbar of the crossbar.

In step S3, the determining a transmission path of the serial electrical signal according to the state of the next-stage crossbar of the crossbar includes:

step S31: if the next-stage cross switch is in a conducting state, converting the serial electric signal into an optical fiber signal, transmitting the optical fiber signal to optical fiber equipment connected with the next-stage optical fiber interface module, and sending the optical fiber signal again by the optical fiber equipment;

it should be noted that, if the optical fiber device is an optical transceiver sub-module of one optical fiber interface module in another optical fiber HUB, the optical fiber signal is sent out through the optical transceiver sub-module of the corresponding optical fiber interface module in the current optical fiber HUB, and if the crossbar switch in the corresponding optical fiber interface module in the other optical fiber HUB is in a conducting state, the optical fiber signal is also sent out through the optical transceiver sub-module of the corresponding optical fiber interface module in the other optical fiber HUB.

Step S32: if the next-stage cross switch is in an off state, the serial electrical signal is directly transmitted to the next-stage cross switch, and a transmission path of the serial electrical signal is repeatedly determined according to the state of the next-stage cross switch.

Preferably, in the process that the networking control module controls the designated networking device to transmit data, when the optical fiber interface module connected with the designated networking device receives the optical fiber signal again, the continuous transmission of the optical fiber signal is stopped.

The status of the fiber HUB referred to in step S2 includes the status of each crossbar and each fiber interface in the fiber HUB;

the state of the cross switch comprises an on state and an off state;

the states of the fiber interface include an enabled state, a disabled state, and a connected state.

Preferably, the optical fiber HUB in this embodiment includes N optical fiber interface modules; wherein,

each optical fiber interface module comprises an optical transceiver sub-module and a crossbar switch: wherein,

the optical transceiver sub-module is used for externally connecting optical fiber equipment; the optical fiber equipment is an optical transceiver sub-module of an optical fiber interface module in one networking equipment or another optical fiber HUB;

the crossbar switch comprises a serial input end, a serial output end, a cascade input end and a cascade output end; wherein,

the serial output end of the optical transceiver sub-module is connected with the serial input end of the cross switch, and the serial input end of the optical transceiver sub-module is connected with the serial output end of the cross switch; the cascade input end and the cascade output end are used for realizing cascade connection among a plurality of the cross switches in the fiber HUB.

The cross switch is in an off state by default, at the moment, the serial input end of the cross switch is connected with the serial output end, and the cascade input end is connected with the cascade output end;

when the cross switch is in a conducting state, the serial input end of the cross switch is connected with the cascade output end, and the cascade input end is connected with the serial output end.

The cascade output end of the ith cross switch is connected with the cascade input end of the (i+1) th cross switch, i=1, … and N-1;

the cascade output end of the N-th cross switch is connected with the cascade input end of the 1-th cross switch.

The schematic structure of the cross switch is shown in fig. 2; wherein each of the crossbars of FIG. 2 (a) is in an off state; the first and fourth crossbars of fig. 2 (b) are both in the on state. Wherein, in the first crossbar, the serial input is denoted as A _in1 The serial output is denoted as A _out1 The cascade input is denoted B _in1 The cascade output is denoted B _out1 。

Preferably, the optical transceiver submodule includes:

the optical fiber interface is used for externally connecting optical fiber equipment and receiving optical fiber signals from the optical fiber equipment or sending the optical fiber signals to the optical fiber equipment;

the optical fiber transceiver is connected with the optical fiber interface and is used for realizing the mutual conversion between an optical fiber signal and a serial electric signal; and taking a port of the optical fiber transceiver for sending the serial electric signal as a serial output end of the optical transceiver sub-module, and taking a port of the optical fiber transceiver for receiving the serial electric signal as a serial input end of the optical transceiver sub-module.

The fiber HUB further comprises a control assembly;

the optical fiber interface is in an enabled state by default; when the optical fiber interface in the starting state is externally connected with optical fiber equipment, the control assembly controls the optical fiber interface to be switched to the connected state;

the control component is also used for detecting faults of the optical fiber interface, and when the faults of the optical fiber interface are detected, the optical fiber interface is controlled to be switched to a forbidden state;

the control component is also used for receiving an optical fiber interface forbidden control signal sent by the networking control module and controlling the optical fiber interface to be switched to a forbidden state based on the received optical fiber interface forbidden control signal.

Preferably, the control component is further configured to send the updated status of the fiber HUB to the networking control module when the status of the fiber HUB is updated;

in step S3, the networking control module completes intelligent networking of the networking device by performing the following operations:

the networking control module receives the status of the optical fiber HUB and gathers the interface IDs of the optical fiber interfaces in the connected status; it should be noted that, the optical fiber interface of each optical fiber HUB accessing the optical fiber network has a unique interface ID.

When the networking control module controls the appointed networking equipment to transmit data, determining the optical fiber equipment for receiving the transmission data based on the interface ID of the optical fiber interface in the connected state;

the control component is used for controlling a cross switch in an optical fiber interface module corresponding to the optical fiber equipment for receiving the transmission data to be switched to a conducting state;

and then, starting the designated networking equipment to transmit data.

In order to better understand the data transmission process in this embodiment, the data transmission process in the intelligent networking control method based on multiple areas is described as follows based on the state of the crossbar in fig. 2 (b):

assuming that the designated networking device is connected to the optical fiber interface module 1, at this time, the crossbar 1 in the optical fiber interface module 1 is in a conductive state, and the serial input terminal a _in1 And cascade output terminal B _out1 Connected with serial output end A _out1 And cascade input terminal B _in1 Are connected;

at this time, the optical fiber interface module 1 receives an optical fiber signal sent by the specified networking equipment, converts the optical fiber signal into a serial electrical signal, and transmits the serial electrical signal to the crossbar 1 in the optical fiber interface module;

as can be seen from fig. 2 (B), the next-stage crossbar (i.e., crossbar 2) of crossbar 1 is in an off state, and the serial electrical signal is output from cascade output terminal B _out1 After output, the output is transmitted to the next-stage cross switch 2, and the output is sequentially transmitted to the next-stage cross switch via B _in2 、B _out2 Outputting the mixture after the reaction;

at this time, the next-stage crossbar of crossbar 2 (i.e., crossbar 3) is also turned offStatus, therefore, serial electrical signal is output from cascade output terminal B _out1 After output, the output is transmitted to the next-stage cross switch 2, and the output is sequentially transmitted to the next-stage cross switch via B _in3 、B _out3 Outputting the mixture after the reaction;

then, the next-stage crossbar of crossbar 3 (i.e., crossbar 4) is in an on state, and thus, the serial electrical signal is transmitted from B _out3 After output via B _in4 、A _out4 And the optical fiber sub-module 4 converts the processed signal into an optical fiber signal, and transmits the optical fiber signal to optical fiber equipment connected with the optical fiber sub-module 4, and the optical fiber equipment re-transmits the optical fiber signal, converts the optical fiber signal into a serial electrical signal and transmits the serial electrical signal to A in the cross switch 4 _in4 B (B) _out4 ；

Then, the transmission paths of the serial electric signals are repeatedly determined according to the states of the cross switch 5 and the cross switch 6.

Serial electric signal is formed by B _out6 After output, the serial signal is input to the crossbar switch 1 again, and at this time, the serial signal passes through B _out 、A _in1 The optical fiber sub-module 1 is processed and then converted into an optical fiber signal, and the optical fiber signal is transmitted to optical fiber equipment connected with the optical fiber sub-module 1; at this time, the liquid crystal display device,

and after the optical fiber interface module 1 connected with the designated networking equipment receives the optical fiber signal again, the designated networking equipment recovers the sent optical fiber signal and stops the continuous transmission of the optical fiber signal.

Through the data transmission process, the transmission of the optical fiber signals sent by the designated networking equipment in the optical fiber HUB is realized, the optical fiber signals sent by the designated networking equipment are sent to the optical fiber equipment connected with the optical fiber interface assembly 4, and meanwhile, when the data sent by the designated networking equipment are received again, the transmission of the data is stopped.

Preferably, the fiber HUB may further comprise a control interface; the control interface is used for connecting the networking control module; preferably, the control interface may be a USB interface or CPCI interface. The schematic structure of the fiber HUB is shown in fig. 3.

In this embodiment, the optical transceiver sub-module is externally connected to the optical fiber device through an optical fiber line; when the optical fiber line is a multimode optical fiber line, the optical transceiver sub-module is a multimode optical transceiver sub-module; when the optical fiber line is a single-mode optical fiber line, the optical transceiver sub-module is a single-mode optical transceiver sub-module.

Considering that the interconnected optical fibers HUB may be located in the same area or different areas, the transmission distances thereof are not the same; when the transmission distance between the two optical fibers HUB is not more than a short transmission distance threshold, the optical fiber line is selected from the multimode optical fiber line or the single-mode optical fiber line; when the transmission distance between the two optical fibers HUB is between the short transmission distance threshold value and the long transmission distance threshold value, the optical fiber line is selected as the single-mode optical fiber line. Illustratively, the short transmission distance threshold is 300m and the long transmission distance threshold is 5000m. In order to improve convenience, the optical transceiver sub-modules may be hot plug devices, and at this time, only a single-mode optical transceiver sub-module or a multi-mode optical transceiver sub-module is inserted into the same optical fiber HUB, or the single-mode optical transceiver sub-module and the multi-mode optical transceiver sub-module are simultaneously inserted into the same optical fiber HUB.

Preferably, in order to facilitate centralized storage of the optical fiber HUB, at least one HUB chassis is arranged in each area, and the optical fiber HUB in each area is uniformly distributed in the HUB chassis in the area.

The embodiment also shows a schematic structural diagram of an intelligent networking system based on multiple areas, as shown in fig. 4, including:

the optical fiber HUB is at least arranged in each area, and the optical fiber HUB is used for connecting one or more networking devices in the area; the optical fiber is also used for forming an optical fiber network after being connected with the optical fiber HUB in the same area or different areas; the connection relationship between a typical fiber HUB and networking equipment is shown in fig. 1, and in the actual networking process, one fiber HUB may be connected to multiple fiber HUBs at the same time, but it is required to ensure that at least one networking equipment is connected to each fiber HUB.

And the networking control module (not shown in fig. 4) is used for controlling the state of each fiber HUB accessed to the fiber optic network to complete intelligent networking of networking equipment.

Those skilled in the art will appreciate that all or part of the flow of the methods of the embodiments described above may be accomplished by way of a computer program to instruct associated hardware, where the program may be stored on a computer readable storage medium. Wherein the computer readable storage medium is a magnetic disk, an optical disk, a read-only memory or a random access memory, etc.

The present invention is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the technical scope of the present invention are intended to be included in the scope of the present invention.

Claims (3)

1. The intelligent networking control method based on the multiple areas is characterized by comprising the following steps of:

according to networking requirements, connecting one or more networking devices in a region to an optical fiber HUB in the region, and connecting the optical fiber HUBs in the same region or different regions to form an optical fiber network;

the networking control module controls the state of each fiber HUB connected to the fiber network to finish intelligent networking of networking equipment;

the optical fiber HUB comprises N optical fiber interface modules; wherein,

each optical fiber interface module comprises an optical transceiver sub-module and a crossbar switch: wherein,

the optical transceiver sub-module is used for externally connecting optical fiber equipment; the optical fiber equipment is an optical transceiver sub-module of an optical fiber interface module in one networking equipment or another optical fiber HUB;

the crossbar switch comprises a serial input end, a serial output end, a cascade input end and a cascade output end; wherein,

the serial output end of the optical transceiver sub-module is connected with the serial input end of the cross switch, and the serial input end of the optical transceiver sub-module is connected with the serial output end of the cross switch; the cascade input end and the cascade output end are used for realizing cascade connection among a plurality of the cross switches in the fiber HUB;

the state of the fiber HUB comprises the state of each crossbar switch and each fiber interface in the fiber HUB;

the state of the cross switch comprises an on state and an off state;

the states of the optical fiber interface comprise an enabling state, a disabling state and a connected state;

the cross switch is in an off state by default, at the moment, the serial input end of the cross switch is connected with the serial output end, and the cascade input end is connected with the cascade output end;

when the cross switch is in a conducting state, the serial input end of the cross switch is connected with the cascade output end, and the cascade input end is connected with the serial output end;

the cascade output end of the ith cross switch is connected with the cascade input end of the (i+1) th cross switch, i=1, … and N-1;

the cascade output end of the N-th cross switch is connected with the cascade input end of the 1-th cross switch;

when the networking control module controls the appointed networking equipment to transmit data, an optical fiber interface module connected with the appointed networking equipment receives an optical fiber signal sent by the appointed networking equipment, converts the optical fiber signal into a serial electric signal and transmits the serial electric signal to a cross switch in the optical fiber interface module; determining a transmission path of a serial electric signal according to the state of a next-stage cross switch of the cross switch;

the networking control module completes intelligent networking of the networking equipment by executing the following operations:

the networking control module receives the status of the optical fiber HUB and gathers the interface IDs of the optical fiber interfaces in the connected status;

when the networking control module controls the appointed networking equipment to transmit data, determining the optical fiber equipment for receiving the transmission data based on the interface ID of the optical fiber interface in the connected state;

controlling a cross switch in an optical fiber interface module corresponding to the optical fiber equipment for receiving the transmission data to be switched to a conducting state;

then, starting the appointed networking equipment to transmit data;

the determining the transmission path of the serial electric signal according to the state of the next-stage cross switch of the cross switch comprises the following steps:

if the next-stage cross switch is in a conducting state, converting the serial electric signal into an optical fiber signal, transmitting the optical fiber signal to optical fiber equipment connected with the next-stage optical fiber interface module, and sending the optical fiber signal again by the optical fiber equipment;

if the next-stage cross switch is in an off state, the serial electric signal is directly transmitted to the next-stage cross switch, and a transmission path of the serial electric signal is repeatedly determined according to the state of the next-stage cross switch;

and stopping continuous transmission of the optical fiber signal after the optical fiber interface module connected with the appointed networking equipment receives the optical fiber signal again in the process that the networking control module controls the appointed networking equipment to transmit data.

2. The intelligent networking control method based on multiple areas according to claim 1, wherein the optical transceiver submodule comprises:

the optical fiber interface is used for externally connecting optical fiber equipment and receiving optical fiber signals from the optical fiber equipment or sending the optical fiber signals to the optical fiber equipment;

the optical fiber transceiver is connected with the optical fiber interface and is used for realizing the mutual conversion between an optical fiber signal and a serial electric signal; and taking a port of the optical fiber transceiver for sending the serial electric signal as a serial output end of the optical transceiver sub-module, and taking a port of the optical fiber transceiver for receiving the serial electric signal as a serial input end of the optical transceiver sub-module.

3. The multi-zone based intelligent networking control method of claim 2, wherein the fiber HUB further comprises a control component;

the optical fiber interface is in an enabled state by default; when the optical fiber interface in the starting state is externally connected with optical fiber equipment, the control assembly controls the optical fiber interface to be switched to the connected state;

the control component is also used for detecting faults of the optical fiber interface, and when the faults of the optical fiber interface are detected, the optical fiber interface is controlled to be switched to a forbidden state;

the control component is also used for receiving an optical fiber interface forbidden control signal sent by the networking control module and controlling the optical fiber interface to be switched to a forbidden state based on the received optical fiber interface forbidden control signal.