CN113114592A - Method for indicating state of network board, pluggable network equipment and interface board - Google Patents

Abstract

The application provides a method for indicating the state of a network board, a pluggable network device and an interface board, wherein the method is applied to the pluggable network device, and the network device comprises a processor and at least one interface board; the interface board comprises a plurality of connectors for accessing the screen board, indicator lights in one-to-one correspondence with the connectors, and a logic device for controlling the indicator lights; the method comprises the following steps: the processor determines state information of the screen plate accessed to the interface board through each connector and generates a state signal corresponding to the state information; the logic device receives the state signal and converts the state signal into a control signal; and the logic device controls the indicator light to be switched to an output mode corresponding to the state of the screen plate based on the control signal. Through the technical scheme, the steps of acquiring the state information by the user are simplified, the learning cost is reduced, and the working efficiency is improved.

Description

Method for indicating state of network board, pluggable network equipment and interface board

Technical Field

The present application relates to the field of communications technologies, and in particular, to a method for indicating a status of a network board, a pluggable network device, and an interface board.

Background

Because the frame switch can insert a large number of boards to perform network data exchange, the frame switch can be preferentially used as a switching device to meet the requirement of large-scale network data exchange.

The board card inserted in the frame switch can be divided into: main control board, interface board, otter board, etc. The interface board inserted into the frame switch can acquire external network data through the external interface on one hand; on the other hand, network data exchange can be carried out with the network board through the connector. The network board is mainly responsible for forwarding the network data acquired by the interface board inside the switch.

In practical applications, the interface board is usually designed to support connection with a certain number of screens; in actual use, a user can configure the number of the screen plates connected with the interface board according to actual conditions;

for example, a user may configure the number of the network boards less than the design upper limit according to factors such as function configuration, power consumption limitation, network switching requirements, and the like, may increase or decrease the number of the existing network boards according to upgrading or degrading requirements, and may adaptively adjust the number of the network boards while replacing a new interface board.

However, when configuring the number of the screens connected to the interface board, a user usually needs to specify the upper limit of the number of the screens supported by the interface board and the number of the screens currently connected to the interface board; in practical application, under the condition that the machine frame is not opened, a user can hardly obtain the information visually, and needs to look up related documents or communicate with related personnel, so that the learning cost of the user is increased, and the working efficiency is reduced.

Disclosure of Invention

In view of this, the present application provides a method for indicating a status of a web pad, and a pluggable network device and an interface board, which are used to simply and visually understand a working condition of the web pad and improve working efficiency.

Specifically, the method is realized through the following technical scheme:

in a first aspect, the present application provides a method for indicating a status of a web pad, which is applied to a pluggable network device, where the network device includes a processor and at least one interface board; the interface board comprises a plurality of connectors for accessing the screen board, indicator lights in one-to-one correspondence with the connectors, and a logic device for controlling the indicator lights; the method comprises the following steps:

the processor determines state information of the screen plate accessed to the interface board through each connector and generates a state signal corresponding to the state information;

the logic device receives the state signal and converts the state signal into a control signal;

and the logic device controls the indicator light to be switched to an output mode corresponding to the state of the screen plate based on the control signal.

In a second aspect, the present application further provides a pluggable network device, including:

the processor is used for determining the state information of the screen plate accessed to the interface board through each connector and generating a state signal corresponding to the state information;

the interface board comprises a connector, a logic device and an indicator light; the connector is used for connecting to the mesh plate; the logic device is used for receiving the state signal and converting the state signal into a control signal; outputting the control signal to the indicator light to indicate the state of the screen plate; the indicator light is used for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

In a third aspect, the present application further provides an interface board, including:

the processor is used for determining the state information of the screen plate accessed to the interface board through each connector and generating a state signal corresponding to the state information;

a connector for connecting to the mesh plate;

the logic device is used for receiving the state signal and converting the state signal into a control signal; outputting the control signal to an indicator lamp to indicate the state of the screen plate;

the indicator light is used for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

By analyzing the technical scheme, the indicating lamps with the same number as the connectors of the interface board are added on the interface board, so that the maximum connection number of the screen boards supported by the interface board can be intuitively known; the logic device of the interface board indicates the state of the screen plate accessed by the connector corresponding to the indicator lamp by controlling the state of the indicator lamp, and a user can quickly acquire the current screen plate state based on the preset corresponding relation between the indicator lamp state and the screen plate state by directly observing the state of the indicator lamp; the screen status is indicated through the indicator lamp, so that the step of acquiring the screen status information by a user is simplified, the learning cost is reduced, and the working efficiency is improved.

Drawings

Fig. 1 is a schematic diagram illustrating an orthogonal matrix structure inside a frame switch according to an exemplary embodiment of the present application;

FIG. 2 is a schematic view of an indicator light of an interface board according to an exemplary embodiment of the present application;

FIG. 3 is a flow chart illustrating a method of indicating a status of a screen in accordance with an exemplary embodiment of the present application;

FIG. 4 is a block diagram of a pluggable network device, shown in an exemplary embodiment of the present application;

fig. 5 is a block diagram of an interface board shown in an exemplary embodiment of the present application.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this application and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

It is to be understood that although the terms first, second, third, etc. may be used herein to describe various information, such information should not be limited to these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the present application. The word "if" as used herein may be interpreted as "at … …" or "when … …" or "in response to a determination", depending on the context.

In the related art, the frame switch can be inserted with a large number of boards for network data exchange, and has a large-scale network exchange capability, so the frame switch plays an important role in important nodes such as a core network and an enterprise network.

Wherein, the integrated circuit board that inserts in the frame switch can divide into according to the function: main control board, interface board, otter board, etc. The interface board inserted in the frame switch, also called a service board, may be responsible for receiving and sending network data with an external network through an external physical interface. The network board of the frame switch, also called a switch network board, can forward the network data of the interface board inside the frame through the connector of the access interface board.

The connector of the interface board can be internally connected to the screen board through the connector of the access screen board.

The number of the connectors used for accessing the screen boards on the interface board is consistent with the number of the screen boards which are supported and connected by the interface board to the maximum extent;

for example, assuming that there are five connectors on an interface board, since each connector can access one board, the maximum number of boards supporting connection of the interface board is five.

When the frame type switch is realized, a backboard is also arranged in the frame type switch, the backboard can provide a screen board slot and an interface board slot, the screen board can be inserted into the screen board slot to be connected with the backboard, and the interface board can be inserted into the interface board slot to be connected with the backboard; when the screen plate and the interface board are connected with the backboard through the screen plate slot and the interface board slot provided by the backboard, the screen plate can be connected into the connector of the interface board, and the screen plate exchanges data with the interface board through the connector.

It should be noted that the relative position relationship between the interface board and the screen board is not particularly limited in this specification, and in practical applications, the interface board and the screen board may be inserted in parallel on the same side of the back board or inserted in perpendicular on two sides of the back board.

Wherein, the interface board and the screen board are inserted in parallel at the same side of the back board, which is generally called as parallel distribution; the interface board and the screen board are vertically inserted at two sides of the back board, which is generally called as orthogonal matrix type distribution.

Generally speaking, the orthogonal matrix distribution is used, the network board is directly connected with the interface board through the connector, the transmission of the cross-over interface board is realized, the transmission distance of signals between the interface board and the network board can be greatly shortened, and the high-speed stable transmission of the signals can be ensured.

For example, referring to fig. 1, fig. 1 is a schematic diagram illustrating an orthogonal matrix structure inside a frame switch;

as shown in fig. 1, an interface board a and an interface board B are responsible for service transmission through a physical interface and an external network, and network boards 1 to 3 are responsible for data exchange between the interface boards, and the interface boards are vertically connected with the network boards through a back board. Taking the screen 1 as an example, the screen 1 has access to both the connector a1 of the interface board a and the connector B1 of the interface board B, and the data transfer path from the interface board a to the interface board B is interface board a → connector a1 → screen 1 → connector B1 → interface board B. The number of connectors of the interface board a is 5, that is, the maximum number of connected screens supported by the interface board a is 5, the number of screens connected to the interface board is not necessarily the same as the maximum number of connected screens supported by the interface board, and a user can configure the number of screens according to actual situations.

On one hand, in the using process of the device, due to the influence of factors such as network exchange requirements, the situation that the user needs to change the number of the network boards may occur, and at this time, the user needs to know the number of the network boards which are currently connected by the interface board and the number of the network boards which are maximally supported and connected by the interface board, so that the user can know the number of the network boards which can be added by the existing interface board. The user needs to consult a related art document or ask a related technician to know the information without disassembling the device housing.

On the other hand, the user needs to know the number of the screens and further know the working state of each screen, and particularly when the device is abnormal, the user needs to find out the screen in the abnormal state in time and judge the abnormal state so as to solve the abnormal problem of the device as soon as possible. In the current technical scheme, the state of the screen plate cannot be simply and directly acquired.

Therefore, in the current technical scheme, a user cannot simply and intuitively know the number of each screen board currently accessed by the interface board and the working state of the screen boards, and often needs to refer to a technical manual or inquire related technicians, so that the learning cost and the time cost of the user are increased to a certain extent, and the working efficiency is reduced.

In view of the above, the present application provides a technical solution for controlling the indicator lights corresponding to the connectors to switch to the output mode corresponding to the state of the screen by determining the state of the screen of each connector on the access interface board.

In the implementation process, indicator lights with the same number as the maximum number of the screen boards supporting connection of the interface board can be configured on the interface board, and by observing the number of the indicator lights, a user can clearly obtain the maximum number of the screen boards supporting connection of the interface board.

The logic device of the interface board can indicate the state of the screen plate connected to the connector corresponding to the indicator lamp by controlling the output state of each indicator lamp, and a user can easily acquire the current state of the screen plate according to the preset corresponding relation between the output state of the indicator lamp and the state of the screen plate.

Furthermore, by numbering the indicator lights, a user can more simply and directly know the number of the screen plates which are maximally supported and connected by the interface board, the number of the screen plates which are connected by the current interface board, the states of the screen plates corresponding to the indicator lights and the like.

The indicator light can have one or more output modes, and each output mode corresponds to one state information of the screen board.

For example, referring to fig. 2, fig. 2 is a schematic view showing an indicator light of an interface board;

as shown in fig. 2, the interface board includes 6 connectors connected to the screen and indicator lights corresponding to the connectors, and the output modes of the indicator lights N1 to N6 correspond to the states of the screens connected to the connectors 1 to 6 on the interface board. In order to visually observe the output state of the indicator light, the indicator light may be disposed on the front panel of the interface board.

Next, examples of the present application will be described in detail.

Referring to fig. 3, fig. 3 is a flowchart of a method for indicating a status of a web pad according to an exemplary embodiment of the present application, applied to a pluggable network device, where the network device includes a processor and at least one interface board; the interface board comprises a plurality of connectors for accessing the screen board, indicator lights in one-to-one correspondence with the connectors, and a logic device for controlling the indicator lights; the method comprises the following steps:

step 301, the processor determines status information of a network board accessed to the interface board through each connector, and generates a status signal corresponding to the status information;

step 302, the logic device receives the status signal and converts the status signal into a control signal;

and 303, controlling the indicator light to be switched to an output mode corresponding to the state of the screen plate by the logic device based on the control signal.

In one illustrated embodiment, the pluggable network device may comprise a pluggable switch.

For example, the pluggable network device may include a box switch, a box router, and the like.

In this embodiment, the processor may determine status information of a screen board accessed to the interface board through each connector, generate a status signal corresponding to the status information of the screen board, and send the signal to the logic device of the interface board.

It should be noted that, in the present application, the processor is configured to receive status information of the screen, determine what status the screen is in, and send a status signal to the logic device of the interface board after generating the status signal based on the status information. The processor may be a processor of the network device or a processor on an interface board. In addition, the processor may be a CPU or an FPGA. The present application is not limited thereto, and those skilled in the art can select a suitable processor according to the needs.

In one embodiment, the processor determines status information of a web panel accessed to the interface board through each connector, generates a status signal corresponding to the status information of the web panel based on a preset corresponding relationship between the status information and the status signal, and sends the signal to a logic device of the interface board.

For example, the processor reads that the screen connected with the connector on the interface board is in a normal working state, the processor generates a corresponding signal of normal working according to the normal working state of the screen, and if the state signal corresponding to the normal working state of the screen is that the indicator light is a normally-on green light, the processor sends the state signal of the normally-on green light of the indicator light to the logic device of the interface board.

In one embodiment shown, the status information of the web panel may include at least one or a combination of the following:

the screen board does not access first state information of the connector;

second state information with abnormal state after the screen board is accessed into the connector;

and the network board is accessed into the third state information of the connector and then works normally.

The network board exchanges data with the interface board through the connector, and the processor obtains the state of the network board by reading signals related to the network board on the connector.

For example, when the processor reads that the connector has no screen board to access, the processor confirms that the screen board does not access the connector;

for another example, when the processor reads that data packet loss occurs or the network board is inserted into the connector but no data exchange occurs, it is determined that the network board is accessed into the connector but the state is abnormal; when the processor reads that the network board carries out normal data exchange with the interface board through the connector, the network board is confirmed to be connected with the connector and is in a normal working state.

Furthermore, the state of the screen plate can be subdivided into various state information according to the requirement;

for example, the screen board works normally but is in an idle state, the screen board works normally but is in a busy state, etc.;

for another example, when the network board is abnormal, data exchange through the connector and the interface board cannot be performed, and when the network board performs data exchange through the connector and the interface board, an abnormal packet loss situation occurs.

The status information of various screens can be subdivided, so that the user can know the current working condition of the screens more conveniently and more specifically.

In one illustrated embodiment, the generated status signal corresponding to the status information may include at least one or a combination of the following:

extinguishing the first status signal of the indicator light;

a second status signal to illuminate the indicator light;

a third status signal that periodically illuminates the indicator light.

The status signal issued by the processor can be represented by a combination of 0 and 1, wherein, it is assumed that 0 represents turning off the indicator light and 1 represents turning on the indicator light;

for example, the status signal of the periodically lighted indicator light may be represented as 01010101 … …

In this embodiment, the logic device on the interface board receives the status signal sent by the processor, and converts the status signal into a control signal of the indicator light.

It should be noted that, in the present application, the logic device is used for receiving the status signal sent by the processor, converting the status signal into the control signal, and then controlling the indicator light to switch to the output mode corresponding to the screen status based on the control signal. The Logic Device may generally include a CPLD (Complex Programmable Logic Device), an FPGA (Field Programmable Gate Array), and other Programmable devices, and the application is not limited to what kind of Logic Device is used, and a person skilled in the art may select a suitable Logic Device according to needs.

For example, taking the CPLD as an example, after receiving the status signal corresponding to the screen status information generated by the processor, the status signal issued by the processor may be written into the control register; the CPLD carries out analysis processing and converts the state signal into a control signal; and then the indicator light is controlled by the high and low level in the control signal, and the indicator light is switched to the output mode corresponding to the state signal.

Continuing the example from the above example, the level signal for turning on the indicator light may be set to a high level signal and the level signal for turning off the indicator light may be set to a low level signal.

Then, suppose that the CPLD receives a status signal generated by the processor according to the screen status information as 010101 … …; wherein, in the state signals, 0 corresponds to the low level signal of the control signal, and 1 corresponds to the high level signal of the control signal; the CPLD can convert the state signal '010101 … …' into a control signal 'low level high level low level high level … …' according to the conversion rule of the state signal and the control signal.

In this embodiment, after the status signal is converted into the control signal, the logic device may output a level signal in the control signal to the indicator light to control the indicator light to switch to the output mode corresponding to the screen status, and indicate the corresponding screen status through the different output modes of the indicator light.

The indicating lamp can be connected with the logic device through a pin, receives a level signal sent by the logic device, and switches the output mode of the indicating lamp according to the received level signal.

For example, when the level signal output to the indicator light by the logic device is a continuous high level signal, the output mode of the indicator light is a normally-on mode; when the level signal output to the indicator light by the logic device is a continuous low level signal, the output mode of the indicator light is an extinguishing mode; when the level signal output to the indicator light by the logic device is a signal with alternating low level and high level, the indicator light is in a flashing mode.

In one embodiment shown, the indicator light may include an indicator light that may output a plurality of colors, different colors of the indicator light output correspond to different output modes, and the logic device may control the indicator light to output a color corresponding to the state of the screen based on the control signal.

The screen states are distinguished through different colors, and a user can judge the screen states more obviously and intuitively.

For example, for a red-green two-color LED indicator, when it is assumed that the indicator output mode corresponding to the current state of the screen is red, the processor generates a state signal corresponding to the state information of the screen according to the corresponding relationship between the state information and the state signal, the logic device converts the state signal into a control signal after receiving the state signal, and the logic device outputs the control signal to the indicator through a pin corresponding to the red output of the indicator, so that the indicator outputs red.

In one embodiment shown, the indicator light may include light emitting electronics capable of outputting N colors.

The processor generates a state signal according to the determined state of the screen plate, the logic device converts the received state signal into a control signal, and controls the indicator lamp to be switched to an output color corresponding to the state of the screen plate based on the control signal.

In one embodiment shown, the output pattern of the indicator light may include different blinking frequencies.

For example, to ensure intuition and avoid complication, the output mode of the indicator light may include three flashing frequencies, slow, medium and fast, corresponding to the status of the web board for data transmission during operation, as shown in table 1 below.

Output mode of indicator light	Slow flash	Middle flashing	Flash memory
				Data transmission state of web plate	Free up	Fluency	Busy

TABLE 1

Specifically, when the processor generates the status signal, the processor may generate the status signals with different flashing frequencies according to the determined state of the screen plate based on the relationship between the preset status information and the status signal, so that the logic device controls the indicator light to switch to the output modes with different flashing frequencies.

For example, when the data transmission status of the web page is idle, the status signal generated by the processor may be 000111000111000111 … …, and the blinking frequency of the indicator light is slow blinking; when the screen status is busy, the status signal generated by the processor may be 010101 … …, indicating that the light blinking frequency is fast.

Furthermore, the color and the flashing frequency of the indicator light can be combined to form a plurality of indicator light output modes, so that more screen status information can be indicated.

For example, assuming that the indicator light can display two colors of red and green and three flashing frequencies of slow, medium and fast, the indicator light can display 9 output modes in total, as shown in table 2 below.

TABLE 2

Specifically, the user can conveniently and quickly know the state of the screen plate by observing the output mode of the indicator lamp based on the corresponding relation between the output mode of the indicator lamp and the state of the screen plate as shown in table 2.

For example, when the user observes that the output pattern of the indicator light is green and the indicator light flashes rapidly, it can be known from table 2 that the screen is in a busy data transmission state and no abnormality occurs.

In addition, since the interface board usually has a plurality of connectors, in order to make the user know the corresponding relationship between the indicator lights on the interface board and each connector more clearly, the user can determine the state of the screen board to which the connector corresponding to the indicator light is connected according to the output mode of the indicator light by numbering the indicator lights.

For example, when the output mode of the indicator light N1 is red and normally on, according to the corresponding relationship between the output mode of the indicator light and the status of the screen board shown in table 2, the user can quickly know that the status of the screen board 1 to which the connector corresponding to the indicator light N1 is connected is that the screen board is connected but data transmission cannot be performed, and the user can perform preliminary troubleshooting of the abnormal problem according to the status of the screen board.

In the above embodiment, by adding the indicator lamps with the same number as the connectors of the interface board on the interface board, the maximum connection number of the screen boards supported by the interface board can be intuitively known; the logic device of the interface board indicates the state of the screen plate accessed by the connector corresponding to the indicator lamp by controlling the state of the indicator lamp, and a user can quickly acquire the current screen plate state based on the preset corresponding relation between the indicator lamp state and the screen plate state by directly observing the state of the indicator lamp; the screen status is indicated through the indicator lamp, so that the step of acquiring the screen status information by a user is simplified, the learning cost is reduced, and the working efficiency is improved.

Corresponding to the method embodiment, the application also provides a pluggable network device embodiment.

Referring to fig. 4, a block diagram of a pluggable network device is shown for an exemplary embodiment of the present application, including:

a processor 401, configured to determine status information of a web panel and generate a status signal corresponding to the status information;

an interface board 402 including a connector 4021, a logic device 4022, and an indicator lamp 4023; the connector is used for accessing the screen plate; the logic device is used for receiving the state signal and converting the state signal into a control signal; outputting the control signal to the indicator light to indicate the state of the screen plate; the indicator light is used for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

Optionally, the status information at least includes one or more of the following combinations:

the screen board does not access first state information of the connector;

second state information with abnormal state after the screen board is accessed into the connector;

and the network board is accessed into the third state information of the connector and then works normally.

Optionally, the status signal includes at least one or more of the following combinations:

extinguishing the first status signal of the indicator light;

a second status signal to illuminate the indicator light;

a third status signal that periodically illuminates the indicator light.

Optionally, generating a status signal corresponding to the status information;

further, according to the determined state information, based on a preset corresponding relationship between the state information and the state signal, a state signal corresponding to the state information is determined.

Optionally, the indicator light comprises a multi-color indicator light; wherein, different colors output by the multi-color indicator lamp correspond to different output modes;

further, the logic device controls the indicator light to output a color corresponding to the state of the screen plate based on the control signal.

Optionally, the output pattern of the indicator light comprises different flashing frequencies.

Optionally, the indicator light comprises light emitting electronic elements outputting N colors.

Optionally, the pluggable network device includes a pluggable switch.

Corresponding to the above method embodiment, the present application also provides an embodiment of an interface board.

Referring to fig. 5, a block diagram of an interface board according to an exemplary embodiment of the present application is shown, where the interface board includes:

a processor 501, configured to determine status information of a web panel and generate a status signal corresponding to the status information;

a connector 502 for accessing the web;

a logic device 503, configured to receive the status signal and convert the status signal into a control signal; outputting the control signal to the indicator light to indicate the state of the screen plate;

an indicator lamp 504 for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

Optionally, the status information at least includes one or more of the following combinations:

the screen board does not access first state information of the connector;

second state information with abnormal state after the screen board is accessed into the connector;

and the network board is accessed into the third state information of the connector and then works normally.

Optionally, the status signal includes at least one or more of the following combinations:

extinguishing the first status signal of the indicator light;

a second status signal to illuminate the indicator light;

a third status signal that periodically illuminates the indicator light.

Optionally, generating a status signal corresponding to the status information;

further, according to the determined state information, based on a preset corresponding relationship between the state information and the state signal, a state signal corresponding to the state information is determined.

Optionally, the indicator light comprises a multi-color indicator light; wherein, different colors output by the multi-color indicator lamp correspond to different output modes;

further, the logic device controls the indicator light to output a color corresponding to the state of the screen plate based on the control signal.

Optionally, the output pattern of the indicator light comprises different flashing frequencies.

Optionally, the indicator light comprises light emitting electronic elements outputting N colors.

The implementation process of the functions and actions of the above devices is specifically described in the implementation process of the corresponding steps in the above method, and is not described herein again.

The foregoing description of specific embodiments of the present application has been presented. Other embodiments are within the scope of the following claims. In some cases, the actions or steps recited in the claims may be performed in a different order than in the embodiments and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing may also be possible or may be advantageous.

Other embodiments of the present application will be readily apparent to those skilled in the art from consideration of the present application and practice of the invention as claimed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It will be understood that the present application is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the application is limited only by the appended claims.

The above description is only for the purpose of illustrating the preferred embodiments of the present application and is not to be construed as limiting the present application, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present application should be included in the scope of the present application.

Claims (10)

1. A method for indicating the state of a web plate is applied to a pluggable network device, and the network device comprises a processor and at least one interface board; the interface board comprises a plurality of connectors for accessing the screen board, indicator lights in one-to-one correspondence with the connectors, and a logic device for controlling the indicator lights; characterized in that the method comprises:

the processor determines state information of the screen plate accessed to the interface board through each connector and generates a state signal corresponding to the state information;

the logic device receives the state signal and converts the state signal into a control signal;

and the logic device controls the indicator light to be switched to an output mode corresponding to the state of the screen plate based on the control signal.

2. The method of claim 1, wherein the status information comprises at least one or more of the following:

the screen board does not access first state information of the connector;

second state information with abnormal state after the screen board is accessed into the connector;

and the network board is accessed into the third state information of the connector and then works normally.

3. The method of claim 1, wherein the status signal comprises at least one or a combination of:

extinguishing the first status signal of the indicator light;

a second status signal to illuminate the indicator light;

a third status signal that periodically illuminates the indicator light.

4. The method of claim 1, wherein generating a status signal corresponding to the status information comprises:

and according to the determined state information, determining a state signal corresponding to the state information based on the preset corresponding relation between the state information and the state signal.

5. The method of claim 1, wherein the indicator light comprises a multi-colored indicator light; wherein, different colors output by the multi-color indicator lamp correspond to different output modes;

the logic device controls the indicator light to be switched to an output mode corresponding to the state of the screen plate based on the control signal, and the logic device comprises:

and the logic device controls the indicator light to output a color corresponding to the state of the screen plate based on the control signal.

6. The method of claim 1, wherein the output patterns of the indicator lights comprise different flashing frequencies.

7. The method of claim 1, wherein the indicator light comprises light emitting electronics that output N colors.

8. The method of claim 1, wherein the pluggable network device comprises a pluggable switch.

9. A pluggable network device, comprising:

the processor is used for determining the state information of the screen plate accessed to the interface board through each connector and generating a state signal corresponding to the state information;

the interface board comprises a connector, a logic device and an indicator light; the connector is used for connecting to the mesh plate; the logic device is used for receiving the state signal and converting the state signal into a control signal; outputting the control signal to the indicator light to indicate the state of the screen plate; the indicator light is used for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

10. An interface board, comprising:

the processor is used for determining the state information of the screen plate accessed to the interface board through each connector and generating a state signal corresponding to the state information;

a connector for connecting to the mesh plate;

the logic device is used for receiving the state signal and converting the state signal into a control signal; outputting the control signal to an indicator lamp to indicate the state of the screen plate;

the indicator light is used for indicating the state of the screen plate according to the control signal of the logic device; the pin of the indicator light is connected with the logic device; the indicator lights correspond to the connectors one to one.

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