CN114222201B - Port scanning and LED control algorithm of electronic distribution frame - Google Patents

Abstract

The invention discloses a port scanning and LED control algorithm of an electronic distribution frame, which comprises the following steps: s1, dividing 24 slots of a network scanner into three groups, and dividing 24 ports on a corresponding electronic distribution frame under each slot into three groups; s2, controlling LED lamps corresponding to ports of each group of electronic distribution frames under each group of notches, and sequentially turning on and off the LED lamps; s3, judging the state that the notches are not lightened, and simultaneously scanning whether each group of notches are connected with the electronic distribution frame and the port state of the electronic distribution frame. According to the port scanning and LED control algorithm of the electronic distribution frame, 24 port states on the electronic distribution frame are scanned, 24 LED lamps are controlled, and the port scanning and LED flickering instantaneity is improved by adopting a time-sharing multiplexing and parallel scanning algorithm.

Description

Port scanning and LED control algorithm of electronic distribution frame

Technical Field

The invention relates to the technical field of network communication, in particular to a port scanning and LED control algorithm of an electronic distribution frame with good real-time performance.

Background

Along with the continuous improvement of informatization degree, more and more network devices of a data machine room and a cabinet are provided, the intelligent wiring management technology is continuously developed, and users hope to carry out remote unified intelligent management on the devices. These devices include intelligent wiring systems for electronic distribution frames that record the connection and distribution relationships of each network port, and electronic distribution frame technology is emerging and becoming increasingly popular. The intelligent wiring management system of the electronic distribution frame is widely popularized and applied in the continuous appearance of an intelligent building. The management of the traditional wiring system only can update management records manually, and the change of equipment and connection is often difficult to reflect in management documents at the first time, so that a lot of errors are generated. With the large-scale wiring construction, the requirement for wiring standardization management is higher and higher, and the traditional wiring management cannot meet the requirement of modern wiring construction. At the same time, as network security issues become more severe, the call for incorporating them into wiring management is also becoming higher. The intelligent wiring management system of the electronic distribution frame is born in the background.

An intelligent wiring system of an electronic distribution frame is a system which connects a traditional wiring system with intelligent management. The intelligent wiring system of the electronic distribution frame automatically transmits the network connection architecture and the change thereof to the system management software, the management system processes the received real-time information, and a user can know the latest structure of the wiring system at any time by inquiring the management system. By managing all management elements electronically, visual, real-time and efficient paperless management can be achieved.

A network scanner supports 24 electronic distribution frames at most, each electronic distribution frame comprises 24 ports, namely, a network scanner can manage 576 ports at most and control 576 LED lamps, if sequential scanning periods and sequential control LED lamps are adopted to flash, the time is long, the real-time performance of the scanner in response to port changes is poor, the management efficiency of the scanner is poor, and the phenomenon that a certain port is pulled out and inserted immediately cannot be detected in real-time scanning is avoided.

Therefore, a new electronic distribution frame control algorithm is needed to improve the real-time performance of managing and controlling the electronic distribution frame.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a port scanning and LED control algorithm of an electronic distribution frame with good real-time performance.

The technical scheme of the invention is as follows:

a port scanning and LED control algorithm for an electronic distribution frame, comprising the steps of: s1, dividing 24 slots of a network scanner into three groups, and dividing 24 ports on a corresponding electronic distribution frame under each slot into three groups; s2, controlling LED lamps corresponding to ports of each group of electronic distribution frames under each group of notches, and sequentially turning on and off the LED lamps; s3, judging the state that the notches are not lightened, and simultaneously scanning whether each group of notches are connected with the electronic distribution frame and the port state of the electronic distribution frame.

As a preferred technical solution, step S1 specifically includes: dividing 1-8 slots in 24 slots of a network scanner into a slot SA group, 9-16 slots into an SB group and 17-24 slots into an SC group; the corresponding electronic distribution frame under each notch is divided into 24 ports 1-8 into PA groups, 9-16 into PB groups and 17-24 into PC groups.

As a further preferable technical scheme, step S2 specifically includes: s21, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be lighted; controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks; s22, entering a lamp lighting delay program; s23, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be turned off, and clearing the LED lamp lighting marks of SA1, SB1 and SC 1; s24, entering a lamp-out delay program; s25, after time delay, simultaneously controlling and simultaneously controlling the first notch in each group of notches to be corresponding to the second group of port lamps on the electronic distribution frame to be on; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be on, and placing SA1, SB1 and SC1 in LED lamp on marks; s26, entering a lamp lighting delay program; s27, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a second group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1; s28, entering a lamp-out delay program; s29, after time delay, simultaneously controlling and simultaneously controlling the first notch in each group of notches to correspond to a third group of port lamps on the electronic distribution frame to be lighted; controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks; s210, entering a lamp lighting delay program; s211, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a third group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1; s212, entering a lamp-out delay program; s213, repeating the steps S21 to S212 after time delay, and circularly controlling the port lamps of the electronic distribution frame corresponding to the second to eighth notches in each group of notches, namely circularly controlling the port LED lamps of the electronic distribution frame under SA2, SB2 and SC2 to the port LED lamps of the electronic distribution frame under SA8, SB8 and SC 8; s214, repeating steps S21 to S213.

As a further preferable technical solution, the LED lamp lighting FLAG is FLAG, and the notch of the LED lamp being lighted is FLAG.

As another further preferable technical scheme, step S3 specifically includes: s31, judging the state that the notches are not lightened, and simultaneously scanning the port states of the first notch corresponding to the first group of ports on the electronic distribution frame in each group of notches, namely, scanning the port states corresponding to SA1-PA, SB1-PA and SC 1-PA; s32, judging whether the first notch in each group of notches is connected with an electronic distribution frame or not, and placing the electronic distribution frame in a marker bit; s33, if the notch is connected with the electronic distribution frame and is in a state of not lighting the LED lamp, sequentially scanning the port states of the second group of ports and the port states of the third group of ports, namely simultaneously scanning the port states corresponding to SA1-PB, SB1-PB and SC1-PB, and then simultaneously scanning the port states corresponding to SA1-PC, SB1-PC and SC 1-PC;

s34, repeating the steps S31 to S33, and circularly scanning port states on the electronic distribution frame corresponding to the second to eight slots in each group of slots, namely circularly scanning port states under SA2, SB2 and SC2 to port states under SA8, SB8 and SC 8; s35, repeating the steps S31 to S34.

As a still further preferable technical solution, a certain delay is provided between the step S34 and the step S35; after the operation of step S34 is completed, an idle delay program is first entered, and step S35 is performed after the delay is completed.

According to the port scanning and LED control algorithm of the electronic distribution frame, 24 port states on the electronic distribution frame are scanned, 24 LED lamps are controlled, and the port scanning and LED flickering instantaneity is improved by adopting a time-sharing multiplexing and parallel scanning algorithm.

Drawings

Fig. 1 is a flow chart of a port scanning and LED control algorithm of an electronic distribution frame according to the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terminology used in the embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. 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, the "plurality" generally includes at least two, but does not exclude the case of at least one.

It should be understood that the term "and/or" as used herein is merely one relationship describing the association of the associated objects, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. In addition, the character "/" herein generally indicates that the front and rear associated objects are an "or" relationship.

The words "if", as used herein, may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to a detection", depending on the context. Similarly, the phrase "if determined" or "if detected (stated condition or event)" may be interpreted as "when determined" or "in response to determination" or "when detected (stated condition or event)" or "in response to detection (stated condition or event), depending on the context.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a product or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such product or system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a commodity or system comprising such elements.

Fig. 1 is a flow chart of a port scanning and LED control algorithm of an electronic distribution frame according to the present invention. The invention discloses a port scanning and LED control algorithm of an electronic distribution frame, which comprises the following steps:

s1, dividing 24 slots of a network scanner into three groups, and dividing 24 ports on a corresponding electronic distribution frame under each slot into three groups;

s2, controlling LED lamps corresponding to ports of each group of electronic distribution frames under each group of notches, and sequentially turning on and off the LED lamps;

s3, judging the state that the notches are not lightened, and simultaneously scanning whether each group of notches are connected with the electronic distribution frame and the port state of the electronic distribution frame.

According to the port scanning and LED control algorithm of the electronic distribution frame, the port scanning and LED flicker control are divided into two different tasks, the tasks are sequentially performed, and meanwhile, the task priority of the port scanning is higher than the priority of the LED flicker control.

In this embodiment, step S1 specifically includes: dividing 1-8 slots in 24 slots of a network scanner into a slot SA group, 9-16 slots into an SB group and 17-24 slots into an SC group; the corresponding electronic distribution frame under each notch is divided into 24 ports 1-8 into PA groups, 9-16 into PB groups and 17-24 into PC groups.

The step S2 specifically comprises the following steps:

s21, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be lighted; controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks;

s22, entering a lamp lighting delay program;

s23, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be turned off, and clearing the LED lamp lighting marks of SA1, SB1 and SC 1;

s24, entering a lamp-out delay program;

s25, after time delay, simultaneously controlling and simultaneously controlling the first notch in each group of notches to be corresponding to the second group of port lamps on the electronic distribution frame to be on; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be on, and placing SA1, SB1 and SC1 in LED lamp on marks;

s26, entering a lamp lighting delay program;

s27, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a second group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1;

s28, entering a lamp-out delay program;

s29, after time delay, simultaneously controlling and simultaneously controlling the first notch in each group of notches to correspond to a third group of port lamps on the electronic distribution frame to be lighted; controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks;

s210, entering a lamp lighting delay program;

s211, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a third group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1;

s212, entering a lamp-out delay program;

s213, repeating the steps S21 to S212 after time delay, and circularly controlling the port lamps of the electronic distribution frame corresponding to the second to eighth notches in each group of notches, namely circularly controlling the port LED lamps of the electronic distribution frame under SA2, SB2 and SC2 to the port LED lamps of the electronic distribution frame under SA8, SB8 and SC 8;

s214, repeating steps S21 to S213.

When the system enters a light-on delay program or a light-off delay program, the control system can execute other tasks, and the delay time of the light-on delay program is the same as the delay time of the light-off delay program.

Because the electronic distribution frame under the same notch can not read the port state and control the LED lamp to be on at the same time. The control algorithm marks the group of notch ports that are illuminating the LED lamp as FLAG.

The step S3 specifically comprises the following steps:

s31, judging the state that the notches are not lightened, and simultaneously scanning the port states of the first notch corresponding to the first group of ports on the electronic distribution frame in each group of notches, namely, scanning the port states corresponding to SA1-PA, SB1-PA and SC 1-PA;

s32, judging whether the first notch in each group of notches is connected with an electronic distribution frame or not, and placing the electronic distribution frame in a marker bit;

s33, if the notch is connected with the electronic distribution frame and is in a state of not lighting the LED lamp, sequentially scanning the port states of the second group of ports and the port states of the third group of ports, namely simultaneously scanning the port states corresponding to SA1-PB, SB1-PB and SC1-PB, and then simultaneously scanning the port states corresponding to SA1-PC, SB1-PC and SC 1-PC;

s34, repeating the steps S31 to S33, and circularly scanning port states on the electronic distribution frame corresponding to the second to eight slots in each group of slots, namely circularly scanning port states under SA2, SB2 and SC2 to port states under SA8, SB8 and SC 8;

s35, repeating the steps S31 to S34.

In actual operation, a certain delay is provided between the step S34 and the step S35; after the operation of step S34 is completed, 20, the system enters an idle delay program with one period of scanning port status completed, and enters the idle delay program first, at this time, the control system can execute other tasks; after the delay time is over, step S35 is performed.

According to the port scanning and LED control algorithm of the electronic distribution frame, 24 port states on the electronic distribution frame are scanned, 24 LED lamps are controlled, and the port scanning and LED flickering instantaneity is improved by adopting a time-sharing multiplexing and parallel scanning algorithm.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the present invention. Equivalent changes and modifications of the invention are intended to fall within the scope of the present invention.

Claims (3)

1. A port scanning and LED control method of an electronic distribution frame is characterized in that: the method comprises the following steps:

s1, dividing 24 slots of a network scanner into three groups, and dividing 24 ports on a corresponding electronic distribution frame under each slot into three groups, wherein the method specifically comprises the following steps: dividing 1-8 slots in 24 slots of a network scanner into a slot SA group, 9-16 slots into an SB group and 17-24 slots into an SC group; the 1-8 numbers in the 24 ports on the corresponding electronic distribution frame under each notch are divided into PA groups, the 9-16 numbers are divided into PB groups, and the 17-24 numbers are divided into PC groups;

s2, controlling LED lamps corresponding to ports of each group of electronic distribution frames under each group of notches, and sequentially lighting the LED lamps and extinguishing the LED lamps, wherein the LED lamps are specifically as follows:

s21, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be lighted; controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks;

s22, entering a lamp lighting delay program;

s23, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a first group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PA, SB1-PA and SC1-PA to be turned off, and clearing the LED lamp lighting marks of SA1, SB1 and SC 1;

s24, entering a lamp-out delay program;

s25, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a second group of port lamps on the electronic distribution frame to be on; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be on, and placing SA1, SB1 and SC1 in LED lamp on marks;

s26, entering a lamp lighting delay program;

s27, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a second group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PB, SB1-PB and SC1-PB to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1;

s28, entering a lamp-out delay program;

s29, after time delay, simultaneously controlling the first notch in each group of notches to be corresponding to a third group of port lamps on the electronic distribution frame to be on; controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be lighted, and placing SA1, SB1 and SC1 in LED lamp lighted marks;

s210, entering a lamp lighting delay program;

s211, after time delay, simultaneously controlling a first notch in each group of notches to be corresponding to a third group of port lamps on the electronic distribution frame to be turned off; namely, controlling the corresponding port lamps of SA1-PC, SB1-PC and SC1-PC to be turned off, and clearing the LED lamp on marks of SA1, SB1 and SC 1;

s212, entering a lamp-out delay program;

s213, after time delay, adding one to the number of slot positions in each group of slots, and repeating the steps S21 to S212, wherein the electronic distribution frame port lamps corresponding to the second to eighth slots in each group of slots are circularly controlled, namely, the electronic distribution frame port LED lamps under SA2, SB2 and SC2 are circularly controlled to the electronic distribution frame port LED lamps under SA8, SB8 and SC 8;

s214, repeating steps S21 to S213;

s3, judging whether the LED lamps corresponding to the notches are in a lighting state or not, and simultaneously sequentially scanning whether each group of notches are connected with the electronic distribution frame and the port state of the electronic distribution frame or not, wherein the method specifically comprises the following steps:

s31, judging whether the LED lamp corresponding to the notch is in a lighting state or not, and simultaneously scanning the port states of the first notch corresponding to the first group of ports on the electronic distribution frame in each group of notches, namely, scanning the port states corresponding to SA1-PA, SB1-PA and SC 1-PA;

s32, judging whether the first notch in each group of notches is connected with an electronic distribution frame or not, and placing the notch in a zone bit;

s33, if the notch is connected with the electronic distribution frame and is in a state of not lighting the LED lamp, sequentially scanning the port states of the second group of ports and the port states of the third group of ports, namely simultaneously scanning the port states corresponding to SA1-PB, SB1-PB and SC1-PB, and then simultaneously scanning the port states corresponding to SA1-PC, SB1-PC and SC 1-PC;

s34, adding one to the number of the notch positions, repeating the steps S31 to S33, and circularly scanning port states on the electronic distribution frame corresponding to the second to eight notches in each group of notches, namely circularly scanning port states under SA2, SB2 and SC2 to port states under SA8, SB8 and SC 8;

s35, repeating the steps S31 to S34.

2. The method for port scanning and LED control of an electronic distribution frame according to claim 1, wherein: and the LED lamp lighting mark is FLAG, and the notch of the LED lamp which is being lighted is marked as FLAG.

3. The method for port scanning and LED control of an electronic distribution frame according to claim 1, wherein: a certain time delay is arranged between the step S34 and the step S35; after the operation of step S34 is completed, an idle delay program is first entered, and step S35 is performed after the delay is completed.