CN113926819A - Cloud operation node monitoring application system - Google Patents

Abstract

The invention relates to a cloud operation node monitoring application system, which comprises: the composite smoke exhaust mechanism comprises smoke exhaust openings and a smoke exhaust channel, wherein the smoke exhaust openings are all opened in the monitoring place and are all connected with the smoke exhaust channel, and the smoke exhaust openings are used for exhausting the extracted smoke through the smoke exhaust channel; a smoke evacuation control device for randomly selecting a number of smoke evacuation openings consistent with the number of received field openings to control entry into an open state; and the opening mapping mechanism is used for determining the number of the oil discharge openings which is in direct proportion to the real-time reference total number to output as the field opening number. The cloud operation node monitoring application system is compact in design and has a certain self-adaptive level. The smoke exhaust treatment of the monitoring place allowing smoke exhaust can be automatically triggered when smoke exhaust action exists on the spot, and particularly, the number of smoke bodies existing on the spot can be identified, and then smoke outlets with the corresponding number matched with the number of the smoke bodies are determined.

Description

Cloud operation node monitoring application system

Technical Field

The invention relates to the field of cloud computing application, in particular to a cloud operation node monitoring application system.

Background

Cloud computing (cloud computing) is one type of distributed computing, and means that a huge data computing processing program is decomposed into countless small programs through a network "cloud", and then the small programs are processed and analyzed through a system consisting of a plurality of servers to obtain results and are returned to a user. In the early stage of cloud computing, simple distributed computing is adopted, task distribution is solved, and computing results are merged. Thus, cloud computing is also known as grid computing. By the technology, tens of thousands of data can be processed in a short time (several seconds), so that strong network service is achieved. At present, the cloud service is not just distributed computing, but a result of hybrid evolution and leap of computer technologies such as distributed computing, utility computing, load balancing, parallel computing, network storage, hot backup redundancy, virtualization and the like.

In the prior art, a smoke outlet is generally arranged in a monitoring place generally allowing smoke extraction, and is used for completing the rapid clearing operation of smoke caused by field smoke extraction under manual operation so as to avoid the situation that the smoke permeates the monitoring place to cause physical and psychological damage to people. However, the above operation mode requires excessive manual intervention, and the number of smoke discharge ports is fixed, resulting in a single smoke discharge mode.

Disclosure of Invention

In order to solve the technical problems in the prior art, the invention provides a cloud operation node monitoring application system which can automatically trigger smoke discharge processing of a monitoring place allowing smoke discharge when smoke discharge behaviors exist on site, and particularly can identify the number of smoke bodies existing on site and further determine the corresponding number of smoke discharge ports, so that the number of the smoke discharge ports is matched with the number of the smoke bodies.

Therefore, the invention at least needs to have the following three key points:

(1) performing visual identification on the number of the on-site smoke bodies, and determining the number of corresponding oil discharge ports to be selected based on the identified number of the on-site smoke bodies so as to provide key reference data for subsequent self-adaptive oil discharge control;

(2) introducing a composite smoke evacuation mechanism comprising smoke evacuation openings and a smoke evacuation channel, each of said smoke evacuation openings being bored within the monitored site and being connected to said smoke evacuation channel for evacuating the evacuated smoke through said smoke evacuation channel;

(3) and introducing a smoke exhaust control device which is connected with the composite smoke exhaust mechanism and used for randomly selecting a plurality of smoke exhaust openings with the number consistent with that of the received oil discharge openings to control the smoke exhaust openings to enter an open state and controlling other smoke exhaust openings to enter a closed state, thereby ensuring the field oil discharge effect and avoiding the waste of equipment power consumption.

According to an aspect of the present invention, there is provided a cloud operation node monitoring application system, including:

the composite smoke exhaust mechanism comprises smoke exhaust openings and a smoke exhaust channel, wherein the smoke exhaust openings are all opened in the monitoring place and are all connected with the smoke exhaust channel, and the smoke exhaust openings are used for exhausting the extracted smoke through the smoke exhaust channel;

the smoke exhaust control device is connected with the composite smoke exhaust mechanism and used for randomly selecting a plurality of smoke exhaust openings with the number consistent with the number of the received field openings to control the smoke exhaust openings to enter an open state and controlling other smoke exhaust openings to enter a closed state;

the system comprises a wired capturing device, a wireless monitoring device and a control device, wherein the wired capturing device is arranged in a monitoring place and used for executing wide-field image capturing action on the monitoring place so as to obtain a corresponding effective captured image;

the cloud operation node is arranged at the far end of the monitoring place and used for storing standard patterns corresponding to various cigarette bodies;

the first enhancement device is arranged in an electric box of the monitoring place, is connected with the wired capturing device and is used for executing homomorphic filtering operation on the received effective captured image so as to obtain a corresponding first enhancement image;

the second enhancement device is connected with the first enhancement device and is used for executing maximum filtering operation on the received first enhancement image so as to obtain a corresponding second enhancement image;

the third enhancement device is connected with the second enhancement device and used for executing bilinear interpolation operation on the received second enhancement image to obtain a corresponding third enhancement image;

the orientation identification mechanism is respectively connected with the third enhancement device and the cloud operation node and is used for executing the query of an image block matched with a certain standard pattern stored in the cloud operation node in the third enhanced image to serve as a smoke body existence block;

the quantity counting mechanism is connected with the directional identification mechanism and is used for acquiring the smoke existence blocks in the third enhanced image and eliminating the smoke existence blocks occupying pixel points with the quantity less than or equal to a set quantity threshold value so as to acquire the residual smoke existence blocks in the third enhanced image;

the parameter identification mechanism is connected with the quantity counting mechanism and used for accumulating the total number of the remaining smoke body blocks in the third enhanced image to be used as a real-time reference total number to be output;

and the opening mapping mechanism is respectively connected with the smoke exhaust control device and the parameter identification mechanism and is used for determining the number of the oil discharge openings which is in direct proportion to the real-time reference total number to output as the number of the field openings.

The cloud operation node monitoring application system is compact in design and has a certain self-adaptive level. The smoke exhaust treatment of the monitoring place allowing smoke exhaust can be automatically triggered when smoke exhaust action exists on the spot, and particularly, the number of smoke bodies existing on the spot can be identified, and then smoke outlets with the corresponding number matched with the number of the smoke bodies are determined.

Detailed Description

Embodiments of the cloud operating node monitoring application system according to the present invention will be described in detail below.

Cigarette is one kind of tobacco product. The preparation method comprises oven drying tobacco, shredding, and rolling into cylindrical strip with length of about 120mm and diameter of 10 mm. When smoking, one end of the cigarette is ignited, and the smoke generated by hoots is sucked by mouth at the other end. Cigarettes were originally popular with turkeys and local individuals preferred to smoke shredded tobacco in newspapers. In the crimi war, uk soldiers learned the method of smoking from the immediate eastman empire soldiers and then spread to different locations. Most cigarette components do not contain tobacco alone. In 1558 sailors brought tobacco seeds back to grapevines and then passed through Europe. In 1612, the England colonizer, John Rolff, planted tobacco in a large area in the jams town of Virginia and began the tobacco trade. The middle of the 16 th century tobacco was introduced into China. The tobacco is dried in the sun and then introduced, and the planting history of more than 400 years is available today.

In the prior art, a smoke outlet is generally arranged in a monitoring place generally allowing smoke extraction, and is used for completing the rapid clearing operation of smoke caused by field smoke extraction under manual operation so as to avoid the situation that the smoke permeates the monitoring place to cause physical and psychological damage to people. However, the above operation mode requires excessive manual intervention, and the number of smoke discharge ports is fixed, resulting in a single smoke discharge mode.

In order to overcome the defects, the invention builds a cloud operation node monitoring application system, and can effectively solve the corresponding technical problem.

The cloud operation node monitoring application system shown in the embodiment of the invention comprises:

the composite smoke exhaust mechanism comprises smoke exhaust openings and a smoke exhaust channel, wherein the smoke exhaust openings are all opened in the monitoring place and are all connected with the smoke exhaust channel, and the smoke exhaust openings are used for exhausting the extracted smoke through the smoke exhaust channel;

the smoke exhaust control device is connected with the composite smoke exhaust mechanism and used for randomly selecting a plurality of smoke exhaust openings with the number consistent with the number of the received field openings to control the smoke exhaust openings to enter an open state and controlling other smoke exhaust openings to enter a closed state;

the system comprises a wired capturing device, a wireless monitoring device and a control device, wherein the wired capturing device is arranged in a monitoring place and used for executing wide-field image capturing action on the monitoring place so as to obtain a corresponding effective captured image;

the cloud operation node is arranged at the far end of the monitoring place and used for storing standard patterns corresponding to various cigarette bodies;

the first enhancement device is arranged in an electric box of the monitoring place, is connected with the wired capturing device and is used for executing homomorphic filtering operation on the received effective captured image so as to obtain a corresponding first enhancement image;

the second enhancement device is connected with the first enhancement device and is used for executing maximum filtering operation on the received first enhancement image so as to obtain a corresponding second enhancement image;

the third enhancement device is connected with the second enhancement device and used for executing bilinear interpolation operation on the received second enhancement image to obtain a corresponding third enhancement image;

the orientation identification mechanism is respectively connected with the third enhancement device and the cloud operation node and is used for executing the query of an image block matched with a certain standard pattern stored in the cloud operation node in the third enhanced image to serve as a smoke body existence block;

the quantity counting mechanism is connected with the directional identification mechanism and is used for acquiring the smoke existence blocks in the third enhanced image and eliminating the smoke existence blocks occupying pixel points with the quantity less than or equal to a set quantity threshold value so as to acquire the residual smoke existence blocks in the third enhanced image;

the parameter identification mechanism is connected with the quantity counting mechanism and used for accumulating the total number of the remaining smoke body blocks in the third enhanced image to be used as a real-time reference total number to be output;

and the opening mapping mechanism is respectively connected with the smoke exhaust control device and the parameter identification mechanism and is used for determining the number of the oil discharge openings which is in direct proportion to the real-time reference total number to output as the number of the field openings.

Next, a specific structure of the cloud operation node monitoring application system of the present invention is further described.

In the cloud operation node monitoring application system:

the standard patterns respectively corresponding to the various cigarette bodies are stored, and comprise: the various cigarette bodies comprise various cigarettes and various cigars.

In the cloud operation node monitoring application system:

the wired capturing device comprises a wired communication interface, and is used for receiving a wired control signal sent by a far end through the wired communication interface so as to execute wide-field image capturing action on the monitoring place, so as to obtain a corresponding effective captured image.

In the cloud operation node monitoring application system:

the wired capturing device further comprises a fisheye camera connected with the wired communication interface and used for executing wide-field image capturing action on the monitoring place so as to obtain a corresponding effective captured image.

In the cloud operation node monitoring application system:

the wired capturing device further comprises a fisheye camera connected with the wired communication interface and used for performing wide-field image capturing actions on the monitoring place to obtain corresponding effective captured images, wherein the wide-field image capturing actions comprise: the wide field of view is an imaging field of view greater than 270 degrees.

In the cloud operation node monitoring application system:

receiving a wired control signal sent by a remote end through a wired communication interface to perform a wide-field-of-view image capturing action on the monitoring site to obtain a corresponding effective captured image comprises: and receiving a capture starting signal sent by a remote end through a wired communication interface to start a wide-field image capturing action executed on the monitoring place so as to obtain a corresponding effective captured image.

In the cloud operation node monitoring application system:

receiving a wired control signal sent by a remote end through a wired communication interface to perform a wide-field-of-view image capturing action on the monitoring site to obtain a corresponding effective captured image comprises: and receiving a capture suspension signal sent by a remote end through a wired communication interface to suspend the wide-field image capturing action performed on the monitoring place so as to obtain a corresponding effective captured image.

The cloud operation node monitoring application system may further include:

and the real-time cooperative device is respectively connected with the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism and the opening mapping mechanism and is used for realizing the action synchronous control of the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism and the opening mapping mechanism.

In the cloud operation node monitoring application system:

the first enhancement device, the second enhancement device, the third enhancement device, the orientation qualification mechanism, the quantity statistics mechanism, the parameter identification mechanism, and the opening mapping mechanism are all disposed within an electrical enclosure of the monitoring location.

In addition, the cloud operation node monitoring application system may further include a serial service interface, which is connected to the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism, and the opening mapping mechanism, and is configured to provide configuration parameters required by each task for the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism, and the opening mapping mechanism, respectively.

The above embodiments are merely examples for carrying out the present invention, and the present invention is not limited thereto, and various modifications of these embodiments are possible within the scope of the present invention, and it is apparent from the above description that various other embodiments are possible within the scope of the present invention.

Claims (9)

1. A cloud operating node monitoring application system, the system comprising:

the composite smoke exhaust mechanism comprises smoke exhaust openings and a smoke exhaust channel, wherein the smoke exhaust openings are all opened in the monitoring place and are all connected with the smoke exhaust channel, and the smoke exhaust openings are used for exhausting the extracted smoke through the smoke exhaust channel;

the smoke exhaust control device is connected with the composite smoke exhaust mechanism and used for randomly selecting a plurality of smoke exhaust openings with the number consistent with the number of the received field openings to control the smoke exhaust openings to enter an open state and controlling other smoke exhaust openings to enter a closed state;

the system comprises a wired capturing device, a wireless monitoring device and a control device, wherein the wired capturing device is arranged in a monitoring place and used for executing wide-field image capturing action on the monitoring place so as to obtain a corresponding effective captured image;

the cloud operation node is arranged at the far end of the monitoring place and used for storing standard patterns corresponding to various cigarette bodies;

the first enhancement device is arranged in an electric box of the monitoring place, is connected with the wired capturing device and is used for executing homomorphic filtering operation on the received effective captured image so as to obtain a corresponding first enhancement image;

the second enhancement device is connected with the first enhancement device and is used for executing maximum filtering operation on the received first enhancement image so as to obtain a corresponding second enhancement image;

the third enhancement device is connected with the second enhancement device and used for executing bilinear interpolation operation on the received second enhancement image to obtain a corresponding third enhancement image;

the orientation identification mechanism is respectively connected with the third enhancement device and the cloud operation node and is used for executing the query of an image block matched with a certain standard pattern stored in the cloud operation node in the third enhanced image to serve as a smoke body existence block;

the quantity counting mechanism is connected with the directional identification mechanism and is used for acquiring the smoke existence blocks in the third enhanced image and eliminating the smoke existence blocks occupying pixel points with the quantity less than or equal to a set quantity threshold value so as to acquire the residual smoke existence blocks in the third enhanced image;

the parameter identification mechanism is connected with the quantity counting mechanism and used for accumulating the total number of the remaining smoke body blocks in the third enhanced image to be used as a real-time reference total number to be output;

and the opening mapping mechanism is respectively connected with the smoke exhaust control device and the parameter identification mechanism and is used for determining the number of the oil discharge openings which is in direct proportion to the real-time reference total number to output as the number of the field openings.

2. The cloud operating node monitoring application system of claim 1, wherein:

the standard patterns respectively corresponding to the various cigarette bodies are stored, and comprise: the various cigarette bodies comprise various cigarettes and various cigars.

3. The cloud operating node monitoring application system of claim 1, wherein:

the wired capturing device comprises a wired communication interface, and is used for receiving a wired control signal sent by a far end through the wired communication interface so as to execute wide-field image capturing action on the monitoring place, so as to obtain a corresponding effective captured image.

4. The cloud operating node monitoring application system of claim 3, wherein:

the wired capturing device further comprises a fisheye camera connected with the wired communication interface and used for executing wide-field image capturing action on the monitoring place so as to obtain a corresponding effective captured image.

5. The cloud operating node monitoring application system of claim 4, wherein:

the wired capturing device further comprises a fisheye camera connected with the wired communication interface and used for performing wide-field image capturing actions on the monitoring place to obtain corresponding effective captured images, wherein the wide-field image capturing actions comprise: the wide field of view is an imaging field of view greater than 270 degrees.

6. The cloud operating node monitoring application system of claim 3, wherein:

receiving a wired control signal sent by a remote end through a wired communication interface to perform a wide-field-of-view image capturing action on the monitoring site to obtain a corresponding effective captured image comprises: and receiving a capture starting signal sent by a remote end through a wired communication interface to start a wide-field image capturing action executed on the monitoring place so as to obtain a corresponding effective captured image.

7. The cloud operating node monitoring application system of claim 6, wherein:

receiving a wired control signal sent by a remote end through a wired communication interface to perform a wide-field-of-view image capturing action on the monitoring site to obtain a corresponding effective captured image comprises: and receiving a capture suspension signal sent by a remote end through a wired communication interface to suspend the wide-field image capturing action performed on the monitoring place so as to obtain a corresponding effective captured image.

8. The cloud operating node monitoring application system of claim 1, wherein said system further comprises:

and the real-time cooperative device is respectively connected with the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism and the opening mapping mechanism and is used for realizing the action synchronous control of the first enhancement device, the second enhancement device, the third enhancement device, the directional identification mechanism, the quantity counting mechanism, the parameter identification mechanism and the opening mapping mechanism.

9. The cloud operating node monitoring application system of claim 1, wherein:

the first enhancement device, the second enhancement device, the third enhancement device, the orientation qualification mechanism, the quantity statistics mechanism, the parameter identification mechanism, and the opening mapping mechanism are all disposed within an electrical enclosure of the monitoring location.