CN113847569A - Early warning monitoring system and method for high-altitude parabolic intelligent street lamp - Google Patents
Early warning monitoring system and method for high-altitude parabolic intelligent street lamp Download PDFInfo
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- 238000004891 communication Methods 0.000 claims abstract description 13
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21S—NON-PORTABLE LIGHTING DEVICES; SYSTEMS THEREOF; VEHICLE LIGHTING DEVICES SPECIALLY ADAPTED FOR VEHICLE EXTERIORS
- F21S8/00—Lighting devices intended for fixed installation
- F21S8/08—Lighting devices intended for fixed installation with a standard
- F21S8/085—Lighting devices intended for fixed installation with a standard of high-built type, e.g. street light
- F21S8/086—Lighting devices intended for fixed installation with a standard of high-built type, e.g. street light with lighting device attached sideways of the standard, e.g. for roads and highways
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21V—FUNCTIONAL FEATURES OR DETAILS OF LIGHTING DEVICES OR SYSTEMS THEREOF; STRUCTURAL COMBINATIONS OF LIGHTING DEVICES WITH OTHER ARTICLES, NOT OTHERWISE PROVIDED FOR
- F21V33/00—Structural combinations of lighting devices with other articles, not otherwise provided for
- F21V33/0064—Health, life-saving or fire-fighting equipment
- F21V33/0076—Safety or security signalisation, e.g. smoke or burglar alarms, earthquake detectors; Self-defence devices
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N7/00—Television systems
- H04N7/18—Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast
- H04N7/181—Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast for receiving images from a plurality of remote sources
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21W—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO USES OR APPLICATIONS OF LIGHTING DEVICES OR SYSTEMS
- F21W2131/00—Use or application of lighting devices or systems not provided for in codes F21W2102/00-F21W2121/00
- F21W2131/10—Outdoor lighting
- F21W2131/103—Outdoor lighting of streets or roads
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Abstract
The invention relates to an early warning and monitoring system of an intelligent high-altitude parabolic street lamp, which comprises a street lamp, a monitoring component, a power supply component and a communication component, wherein the monitoring component is connected with the street lamp; the monitoring assembly comprises a main vision monitoring unit and a plurality of sub vision monitoring units; the monitoring assembly also comprises an image processing unit, a visual recognition unit and an early warning unit; the visual identification unit is used for identifying the picture of the main visual monitoring unit, correspondingly marking the video pictures of the plurality of sub visual monitoring units according to the time falling point when the parabolic behavior is identified, calling the image processing unit to combine the monitoring pictures, early warning through the early warning unit and transmitting the monitoring pictures through the communication assembly; utilize current wisdom street lamp to come the overall arrangement to set up the control subassembly, resource utilization is more reasonable, and discernment, interception that the control subassembly can be better simultaneously are thrown thing evidence and are traced to the source and handle, through the control and the supervision of throwing the thing action that carry on that this kind of means form can be better, effectively reduce and throw the thing action incidence.
Description
Technical Field
The invention relates to the technical field of intelligent street lamps, in particular to an early warning and monitoring system and method for an intelligent high-altitude parabolic street lamp.
Background
Along with the acceleration of the urbanization process of China, high-rise buildings and communities are more and more, the phenomenon of falling objects from high altitudes is very serious, and the social harm caused by the falling objects is also very serious. The unlawful behavior of throwing falling objects from high altitude, called 'pain over the city', is caused by the fact that many people are deeply ill, the environment is damaged, and potential safety hazards exist. Since the falling object is mostly generated on high floors, the falling object is not visible and hidden, and the falling object is a pain point for community management. Due to frequent accidents, the social problem of high-altitude parabolic falling object threatening the safety of the head is caused, and the public advices of society are caused again nowadays, especially in the aspect of the burden of civilian criminal of infringement actors.
The falling object of high altitude is avoided, the safety of residents is ensured, and the safety line is the bottom line of the city safety civilization; at present, no better prevention and control monitoring system capable of actively identifying the behavior of the high-throwing falling object and automatically tracing to the source exists.
Disclosure of Invention
The invention aims to solve the technical problem of providing an early warning and monitoring system for an intelligent high-altitude parabolic street lamp and an early warning and monitoring method for the intelligent high-altitude parabolic street lamp aiming at the defects in the prior art.
The technical scheme adopted by the invention for solving the technical problems is as follows:
the early warning and monitoring system for the high-altitude parabolic intelligent street lamp is constructed, and comprises the street lamp, a monitoring component carried on the upper part of the street lamp, a power supply component for supplying power to the street lamp and the monitoring component, and a communication component for communicating with the outside; the monitoring assembly comprises a main vision monitoring unit and a plurality of sub vision monitoring units, wherein the plurality of sub vision monitoring units are used for shooting different external areas of a monitored building; the monitoring assembly further comprises an image processing unit, a visual recognition unit and an early warning unit; the visual identification unit is used for identifying the picture of the main visual monitoring unit, correspondingly marking the video pictures of the plurality of sub visual monitoring units according to the time falling point when the parabolic behavior is identified, calling the image processing unit to combine the video pictures of the main visual monitoring unit and the video pictures obtained by the plurality of marked sub visual monitoring units to form a monitoring picture, sending out early warning to a monitoring end through the early warning unit, and synchronously transmitting the monitoring picture to the monitoring end through the communication assembly.
The high-altitude parabolic intelligent street lamp early warning monitoring system comprises a monitoring assembly, a sub-vision monitoring unit and a power supply, wherein the monitoring assembly further comprises a plurality of variable-focus lenses which are in one-to-one correspondence with the sub-vision monitoring unit, and a plurality of zoom adjusting units which are in one-to-one correspondence with the variable-focus lenses.
The high-altitude parabolic intelligent street lamp early warning monitoring system comprises a monitoring component, a risk identification unit and a video segment recording unit, wherein the risk identification unit is used for acquiring pictures of a main vision monitoring unit and a plurality of sub vision monitoring units according to a set time rule, comparing the pictures with recorded standard pictures one by one, considering that no risk exists at present when the comparison is consistent, recording inconsistent points when the comparison is inconsistent, and sending corresponding video segments to a monitoring end.
The high-altitude parabolic intelligent street lamp early warning monitoring system comprises a vision identification unit, a main vision monitoring unit, a monitoring terminal and a control terminal, wherein the vision identification unit monitors and identifies the picture of the main vision monitoring unit through a high-altitude parabolic vision algorithm, calculates the position of a parabolic point on a monitored building when high-altitude parabolic behavior is found, and sends the position to the monitoring terminal.
The high-altitude parabolic intelligent street lamp early warning monitoring system is characterized in that the monitoring end is provided with a high-altitude parabolic education full-flow file unit, and the high-altitude parabolic intelligent street lamp early warning monitoring system is used for recording parabolic behaviors and corresponding video evidences and performing online supervision education on parabolic personnel.
The high-altitude parabolic intelligent street lamp early warning monitoring system comprises a monitoring end, a monitoring end and a monitoring module, wherein the monitoring end comprises a cloud server and a plurality of marginalized data processing units, and a plurality of street lamps provided with monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around one monitoring building or a plurality of monitoring component data around one monitoring building, and uploading the monitoring component data to the cloud server.
The high-altitude parabolic intelligent street lamp early warning monitoring system is characterized in that the monitoring component and the marginalized data processing unit are communicated with each other through a 5G network, and the marginalized data processing unit and the cloud server are communicated with each other through the 5G network.
The high-altitude parabolic intelligent street lamp early warning and monitoring method is applied to the high-altitude parabolic intelligent street lamp early warning and monitoring system, and the implementation method comprises the following steps:
the overall appearance of the monitored building is monitored through a main vision monitoring unit of a monitoring assembly arranged at the upper part of the street lamp, and the local area of the monitored building is monitored in an amplification way through a plurality of sub vision monitoring units;
when the vision identification unit identifies the picture of the main vision monitoring unit and finds that high-altitude parabolas exist, determining the areas through which the object falls and the time nodes of the areas according to a high-altitude parabolic vision algorithm;
calling video pictures of corresponding time nodes of the sub-visual monitoring units in corresponding areas and combining the video pictures with the pictures of the main visual monitoring unit to form a monitoring picture with an integral parabolic scene and a detail falling scene;
and carrying out early warning through the early warning unit and sending the monitoring picture through the communication assembly.
The invention relates to a high-altitude parabolic intelligent street lamp early warning and monitoring method, which further comprises the following steps:
the visual identification unit collects the pictures of the main visual monitoring unit and the sub visual monitoring units according to a set time rule, compares the pictures with the recorded standard pictures one by one, considers that no risk exists at present when the pictures are consistent, records inconsistent points when the pictures are inconsistent, and sends corresponding video segments to the monitoring end.
The invention relates to a high-altitude parabolic intelligent street lamp early warning and monitoring method, which further comprises the following steps:
the monitoring end comprises a cloud server and a plurality of marginalized data processing units, and a plurality of street lamps provided with the monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around one monitoring building or a plurality of monitoring component data around one monitoring building, and uploading the monitoring component data to the cloud server.
The invention has the beneficial effects that: the overall appearance of the monitored building is monitored through a main vision monitoring unit of a monitoring assembly arranged at the upper part of the street lamp, and the local area of the monitored building is monitored in an amplification way through a plurality of sub vision monitoring units; when the vision identification unit identifies the picture of the main vision monitoring unit and finds that high-altitude parabolas exist, determining the areas through which the object falls and the time nodes of the areas according to a high-altitude parabolic vision algorithm; calling video pictures of corresponding time nodes of the sub-visual monitoring units in corresponding areas and combining the video pictures with the pictures of the main visual monitoring unit to form a monitoring picture with an integral parabolic scene and a detail falling scene; carrying out early warning through an early warning unit and sending the monitoring picture through a communication assembly; utilize current wisdom street lamp to come the overall arrangement to set up the control subassembly, resource utilization is more reasonable, and discernment, interception that the control subassembly can be better simultaneously are thrown thing evidence and are traced to the source and handle, through the control and the supervision of throwing the thing action that carry on that this kind of means form can be better, effectively reduce and throw the thing action incidence.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the present invention will be further described with reference to the accompanying drawings and embodiments, wherein the drawings in the following description are only part of the embodiments of the present invention, and for those skilled in the art, other drawings can be obtained without inventive efforts according to the accompanying drawings:
FIG. 1 is a schematic block diagram of a high-altitude parabolic intelligent street lamp early warning and monitoring system according to a preferred embodiment of the invention;
fig. 2 is a flow chart of the early warning and monitoring method for the high-altitude parabolic intelligent street lamp according to the preferred embodiment of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following will clearly and completely describe the technical solutions in the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without inventive step, are within the scope of the present invention.
The early warning and monitoring system of the high-altitude parabolic intelligent street lamp in the preferred embodiment of the invention is shown in fig. 1, and comprises a street lamp 1, a monitoring component 2 arranged on the upper part of the street lamp 1, a power supply component 3 for supplying power to the street lamp 1 and the monitoring component 2, and a communication component 4 for communicating with the outside; the monitoring assembly 2 comprises a main visual monitoring unit 20 and a plurality of sub visual monitoring units 21, the plurality of sub visual monitoring units 21 being used for photographing different external areas of the monitored building; the monitoring assembly 2 further comprises an image processing unit 22, a visual recognition unit 23 and an early warning unit 24; the visual identification unit 23 is used for identifying the picture of the main visual monitoring unit 20, correspondingly marking the video pictures of the plurality of sub visual monitoring units 21 according to the time falling point when the parabolic behavior is identified, calling the image processing unit 22 to combine the video pictures of the main visual monitoring unit and the video pictures obtained by the plurality of marked sub visual monitoring units to form a monitoring picture, sending out early warning to the monitoring end through the early warning unit 24, and synchronously transmitting the monitoring picture to the monitoring end 5 through the communication component;
the overall appearance of the monitored building is monitored through a main vision monitoring unit 20 of a monitoring assembly 2 arranged at the upper part of the street lamp 1, and the local area of the monitored building is amplified and monitored through a plurality of sub vision monitoring units 21; when the vision identification unit 23 identifies the picture of the main vision monitoring unit 20 and finds that high-altitude parabolas exist, determining the regions through which the object falls and the time nodes of the regions according to a high-altitude parabolic vision algorithm; calling the video pictures of the corresponding time nodes of the sub-visual monitoring units 21 in the corresponding areas and combining the video pictures with the pictures of the main visual monitoring unit 20 to form a monitoring picture with an integral parabolic scene and a detail falling scene; the early warning unit 24 carries out early warning and sends the monitoring picture through the communication component 4;
utilize current wisdom street lamp to come the overall arrangement to set up the control subassembly, resource utilization is more reasonable, and discernment, interception that the control subassembly can be better simultaneously are thrown thing evidence and are traced to the source and handle, through the control and the supervision of throwing the thing action that carry on that this kind of means form can be better, effectively reduce and throw the thing action incidence.
Preferably, the monitoring assembly 2 further includes a plurality of zoom lenses corresponding to the sub-visual monitoring units one to one, and a plurality of zoom adjusting units for adjusting the zoom lenses one to one; initial assembly adjustment of the plurality of sub-vision monitoring units is facilitated.
Preferably, the monitoring component 2 further comprises a risk identification unit 25, the risk identification unit 25 is configured to collect pictures of the main vision monitoring unit 20 and the plurality of sub vision monitoring units 21 according to a set time rule, compare the pictures with the recorded standard pictures one by one, determine that there is no risk currently when the comparison is consistent, record inconsistent points when the comparison is inconsistent, and send corresponding video segments to the monitoring terminal 5; be convenient for carry out risk identification, then the affirmation exists the risk of dropping when having unusual object, sends the control end and carries out the people for getting rid of, promotes the discernment probability to the risk greatly, eliminates most hidden dangers at the sprouting stage.
Preferably, the vision recognition unit 23 monitors and recognizes the picture of the main vision monitoring unit 20 through a high-altitude parabolic vision algorithm, calculates the position of the parabolic point on the monitored building when the high-altitude parabolic behavior is found, and sends the position to the monitoring end 5; the tracing of the parabolic point is convenient, and a powerful basis is provided for supervision.
Preferably, the monitoring terminal 5 is provided with a high-throw education full-flow file unit 50, and the high-throw education full-flow file unit is used for recording the occurring parabolic behaviors and corresponding video evidences and performing online supervision education on parabolic personnel.
Preferably, the monitoring terminal 5 comprises a cloud server 51 and a plurality of edge data processing units 52, and a plurality of street lamps 1 provided with monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around a monitoring building or a plurality of monitoring component data around a monitoring building and uploading the monitoring component data to the cloud server; the monitoring component and the marginalized data processing unit as well as the marginalized data processing unit and the cloud server are communicated through a 5G network; data marginalization processing based on a 5G transmission network is facilitated, the operation pressure of the cloud server is reduced, and meanwhile the setting is more flexible and efficient.
An early warning and monitoring method for a high-altitude parabolic intelligent street lamp is applied to the early warning and monitoring system for the high-altitude parabolic intelligent street lamp, and is implemented as follows as shown in fig. 2:
s01: the overall appearance of the monitored building is monitored through a main vision monitoring unit of a monitoring assembly arranged at the upper part of the street lamp, and the local area of the monitored building is monitored in an amplification way through a plurality of sub vision monitoring units;
s02: when the vision identification unit identifies the picture of the main vision monitoring unit and finds that high-altitude parabolas exist, determining the areas through which the object falls and the time nodes of the areas according to a high-altitude parabolic vision algorithm;
s03: calling video pictures of corresponding time nodes of the sub-visual monitoring units in corresponding areas and combining the video pictures with the pictures of the main visual monitoring unit to form a monitoring picture with an integral parabolic scene and a detail falling scene;
s04: carrying out early warning through an early warning unit and sending the monitoring picture through a communication assembly;
utilize current wisdom street lamp to come the overall arrangement to set up the control subassembly, resource utilization is more reasonable, and discernment, interception that the control subassembly can be better simultaneously are thrown thing evidence and are traced to the source and handle, through the control and the supervision of throwing the thing action that carry on that this kind of means form can be better, effectively reduce and throw the thing action incidence.
Preferably, the early warning and monitoring method for the high-altitude parabolic intelligent street lamp further comprises the following steps: the visual identification unit collects pictures of the main visual monitoring unit and the sub visual monitoring units according to a set time rule, compares the pictures with the recorded standard pictures one by one, determines that no risk exists at present when the pictures are consistent, records inconsistent points when the pictures are inconsistent, and sends corresponding video segments to the monitoring end; be convenient for carry out risk identification, then the affirmation exists the risk of dropping when having unusual object, sends the control end and carries out the people for getting rid of, promotes the discernment probability to the risk greatly, eliminates most hidden dangers at the sprouting stage.
Preferably, the early warning and monitoring method for the high-altitude parabolic intelligent street lamp further comprises the following steps: the monitoring end comprises a cloud server and a plurality of marginalized data processing units, and a plurality of street lamps provided with monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around a monitoring building or a plurality of monitoring component data around a monitoring building and uploading the monitoring component data to the cloud server; the data marginalization is convenient to carry out, the operating pressure of the cloud server is reduced, and meanwhile, the setting is more flexible and efficient.
It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.
Claims (10)
1. An early warning and monitoring system of an intelligent high-altitude parabolic street lamp is characterized by comprising a street lamp, a monitoring component carried on the upper part of the street lamp, a power supply component for supplying power to the street lamp and the monitoring component, and a communication component for communicating with the outside; the monitoring assembly comprises a main vision monitoring unit and a plurality of sub vision monitoring units, wherein the plurality of sub vision monitoring units are used for shooting different external areas of a monitored building; the monitoring assembly further comprises an image processing unit, a visual recognition unit and an early warning unit; the visual identification unit is used for identifying the picture of the main visual monitoring unit, correspondingly marking the video pictures of the plurality of sub visual monitoring units according to the time falling point when the parabolic behavior is identified, calling the image processing unit to combine the video pictures of the main visual monitoring unit and the video pictures obtained by the plurality of marked sub visual monitoring units to form a monitoring picture, sending out early warning to a monitoring end through the early warning unit, and synchronously transmitting the monitoring picture to the monitoring end through the communication assembly.
2. The system as claimed in claim 1, wherein the monitoring module further comprises a plurality of zoom lenses corresponding to the sub-vision monitoring units one to one, and a plurality of zoom adjusting units for adjusting the zoom lenses one to one.
3. The system as claimed in claim 1, wherein the monitoring component further comprises a risk recognition unit, the risk recognition unit is configured to collect images of the main vision monitoring unit and the plurality of sub vision monitoring units according to a set time rule, compare the images with the recorded standard images one by one, determine that there is no risk when the images are consistent, record inconsistent points when the images are inconsistent, and send corresponding video segments to the monitoring end.
4. The high-altitude parabolic intelligent street lamp early warning and monitoring system as claimed in claim 1, wherein the vision recognition unit monitors and recognizes the picture of the main vision monitoring unit through a high-altitude parabolic vision algorithm, calculates the position of a parabolic point on the monitored building when the high-altitude parabolic behavior is found, and sends the position to the monitoring end.
5. The high altitude parabolic intelligent street lamp early warning monitoring system as claimed in claims 1-4, wherein the monitoring end is provided with a high altitude parabolic education full-flow file unit, the high altitude parabolic education full-flow file unit is used for recording the parabolic behavior and corresponding video evidence and performing online supervision education on parabolic personnel.
6. The high altitude parabolic smart street lamp early warning and monitoring system as claimed in claims 1-4, wherein the monitoring terminal comprises a cloud server and a plurality of marginalized data processing units, and a plurality of street lamps provided with the monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around one monitoring building or a plurality of monitoring component data around one monitoring building, and uploading the monitoring component data to the cloud server.
7. The high altitude parabolic smart street lamp early warning monitoring system as claimed in claim 6, wherein the monitoring component and the marginalized data processing unit and the cloud server are communicated with each other through a 5G network.
8. An early warning and monitoring method for an intelligent high-altitude parabolic street lamp, which is applied to the early warning and monitoring system for the intelligent high-altitude parabolic street lamp according to any one of claims 1 to 7, and is characterized in that the implementation method comprises the following steps:
the overall appearance of the monitored building is monitored through a main vision monitoring unit of a monitoring assembly arranged at the upper part of the street lamp, and the local area of the monitored building is monitored in an amplification way through a plurality of sub vision monitoring units;
when the vision identification unit identifies the picture of the main vision monitoring unit and finds that high-altitude parabolas exist, determining the areas through which the object falls and the time nodes of the areas according to a high-altitude parabolic vision algorithm;
calling video pictures of corresponding time nodes of the sub-visual monitoring units in corresponding areas and combining the video pictures with the pictures of the main visual monitoring unit to form a monitoring picture with an integral parabolic scene and a detail falling scene;
and carrying out early warning through the early warning unit and sending the monitoring picture through the communication assembly.
9. The high-altitude parabolic intelligent street lamp early warning and monitoring method as claimed in claim 8, further comprising the steps of:
the visual identification unit collects the pictures of the main visual monitoring unit and the sub visual monitoring units according to a set time rule, compares the pictures with the recorded standard pictures one by one, considers that no risk exists at present when the pictures are consistent, records inconsistent points when the pictures are inconsistent, and sends corresponding video segments to the monitoring end.
10. The high-altitude parabolic intelligent street lamp early warning and monitoring method as claimed in claim 8, further comprising the steps of:
the monitoring end comprises a cloud server and a plurality of marginalized data processing units, and a plurality of street lamps provided with the monitoring components are distributed around a single monitored building; the marginalized data processing unit is used for receiving and processing a plurality of monitoring component data around one monitoring building or a plurality of monitoring component data around one monitoring building, and uploading the monitoring component data to the cloud server.
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