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An unmanned aerial vehicle monitoring system and monitoring method thereof

A monitoring system and unmanned aerial vehicle technology, which is applied to the parts, instruments, and TVs of the TV system, can solve the problems of low altitude, high safety hazards, and high cost of high-precision radar, so as to reduce detection costs and improve The effect of precision

Active Publication Date: 2020-06-23
烟台欣飞智能系统有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0002] In recent years, with the development of UAV technology, the intrusion of low-altitude, low-slow and small targets on civil aviation and the clearance of specific areas has caused great social security risks, such as drone intrusion at Chengdu Shuangliu Airport and UAV intrusion at Hangzhou Xiaoshan Airport The safety hazards and social impact caused by the suspected drone intrusion into the controlled airspace in the clear area and Yantai Airport are increasing. In terms of anti-terrorism, although the ground security is impenetrable, there are no good means and methods for effective anti-terrorism at low altitudes. defense, causing a very important security pressure on all aspects
[0003] In the existing technology, UAVs and other "small, slow and low" targets are difficult to be found and tracked by traditional radars due to their very small radar reflection area, and the cost of high-precision radars is very high

Method used

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  • An unmanned aerial vehicle monitoring system and monitoring method thereof
  • An unmanned aerial vehicle monitoring system and monitoring method thereof
  • An unmanned aerial vehicle monitoring system and monitoring method thereof

Examples

Experimental program
Comparison scheme
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Embodiment 1

[0085] This embodiment provides a UAV monitoring method, the UAV monitoring method comprising:

[0086] Step 1, acquiring images in the scanning area;

[0087] Step 2, using the first camera and the second camera to form a stereoscopic vision to determine whether there is a suspicious target in the image;

[0088]Step 3, if yes, calculate the standard position of the suspicious object, and track and shoot the suspicious object. Among them, the suspicious target may be a drone.

[0089] Such as Figure 14 As shown, the embodiment of the present invention provides an array drone monitoring system based on the combination of infrared thermal imaging camera and visible spectrum camera and its algorithm. The servo pan / tilt can be referred to as the pan / tilt for short. The pan / tilt is usually installed outdoors. The middle of the image shown in the figure is the pan / tilt. The left side of the image shown in the picture is an infrared thermal imaging camera, and the right side of ...

Embodiment 2

[0111] On the basis of Embodiment 1, step 2 in this embodiment uses the first camera and the second camera to form a stereoscopic vision to determine whether the image contains suspicious objects, including:

[0112] The images include a first image acquired during a first time period and a second image acquired during a second time period;

[0113] Step 21: When within the first time period, calculate the first image, and judge whether there is a suspected target in the first image according to the settlement result;

[0114] Step 211: If yes, then use the first camera and the second camera to form stereoscopic vision to analyze and process the suspected target in the first image, and judge whether the suspected target is the suspicious target according to the analysis result; if yes, then Execute step 3;

[0115] Wherein, the first image acquired within the first time period includes:

[0116] Calculate the azimuth angle of the sun in real time, adjust the motion track of ...

Embodiment 3

[0121] On the basis of Embodiment 2, step 2 in this embodiment uses the first camera and the second camera to form a stereoscopic vision to determine whether the image contains suspicious objects, and also includes:

[0122] Step 22: When within the second time period, determine whether the suspicious object exists in the second image; if yes, perform step 3.

[0123] Autonomous airspace scanning. The main working mode of the front-end equipment. The center will send the airspace range that the front-end device needs to scan and search, and convert it into the horizontal angle range and vertical angle range of the local gimbal, and the front-end device will automatically scan continuously within the specified range.

[0124] When working during the day, the infrared thermal imaging camera is mainly used, and the visible spectrum camera is used as a supplementary work. The azimuth of the sun will be calculated in real time, and the sun will be avoided during the scanning proce...

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Abstract

The present invention relates to an unmanned aerial vehicle monitoring system and a monitoring method thereof. The unmanned aerial vehicle monitoring method comprises: step 1, acquiring images in the scanning area; Whether there is a suspicious target; step 3, if yes, calculate the standard position of the suspicious target, and track and shoot the suspicious target. In the present invention, multiple servo pan-tilts are set in the area to be detected, and a first camera and a second camera are respectively set on both sides of each servo pan-tilt, and the drone is discovered by using two cameras to form binocular vision And detect the location information of the UAV. After the UAV is discovered, the UAV is tracked and monitored through the binocular vision according to the location information of the UAV, so as to realize the discovery, identification and disposal of low-altitude, low-slow and small targets. A camera detects drones, changing the concept of traditional radar detection of drones and reducing the cost of drone detection.

Description

technical field [0001] The invention relates to the field of anti-drone technology, in particular to an unmanned aerial vehicle monitoring system and a monitoring method thereof. Background technique [0002] In recent years, with the development of UAV technology, the intrusion of low-altitude, low-slow and small targets on civil aviation and the clearance of specific areas has caused great social security risks, such as drone intrusion at Chengdu Shuangliu Airport and UAV intrusion at Hangzhou Xiaoshan Airport The safety hazards and social impact caused by the suspected drone intrusion into the controlled airspace in the clear area and Yantai Airport are increasing. In terms of anti-terrorism, although the ground security is impenetrable, there are no good means and methods for effective anti-terrorism at low altitudes. Defense has created a very important security pressure on all aspects. [0003] In the existing technology, UAVs and other "small, slow and low" targets a...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G06T7/246G06T7/292G06T7/70H04K3/00H04N5/232H04N5/247
CPCH04K3/825H04K3/84G06T7/246G06T7/292G06T7/70H04N23/60H04N23/90
Inventor 曹龙胜郝加刚李春波赵光顺
Owner 烟台欣飞智能系统有限公司