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CN205050361U - Electron border device and electron border system - Google Patents

Electron border device and electron border system Download PDF

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Publication number
CN205050361U
CN205050361U CN201520857760.4U CN201520857760U CN205050361U CN 205050361 U CN205050361 U CN 205050361U CN 201520857760 U CN201520857760 U CN 201520857760U CN 205050361 U CN205050361 U CN 205050361U
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unmanned vehicle
electron boundary
mentioned
boundary device
electron
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杨珊珊
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Abstract

The utility model mainly provides an electron border device for settlement unmanned vehicles's flying area territory, and this electron border device includes: a communication unit for receive information and feedback information, a positioning unit for fixing a position above -mentioned electron border device self position, wherein, electron border device is independent of unmanned vehicles and setting up to can place at preset position with the sureness the flying area territory. Furthermore, the utility model provides an electron border system including above -mentioned electron border device. Adopt above -mentioned scheme, can set for flying area territory border fast, though the signal transmission between unmanned vehicles and the ground control system exist when unusual also can real time monitoring unmanned vehicles the flight route, avoid it to surmount safe flight scope, avoid taking place unmanned vehicles and lose the condition about allying oneself with.

Description

A kind of electron boundary device and electron boundary system
Technical field:
The utility model relates generally to unmanned vehicle field, particularly relates to setting and the monitoring aspect of unmanned vehicle flight range.
Background technology:
Unmanned spacecraft, be called for short unmanned vehicle (UAV), a kind of new ideas flight equipment in developing rapidly that is in, its have maneuverability, reaction fast, unmanned flight, operation requirements be low, take off without the need to advantages such as runway or other utility appliance.Unmanned vehicle, by carrying multiclass sensor, can realize image real-time Transmission, high-risk areas detecting function etc., and at present, the usable range of unmanned vehicle has spread to military affairs, scientific research, civilian three large fields, and application is very wide.
But, although existing unmanned vehicle can realize the operation such as target detection or target following of long-time, long distance, but because its flight range may not carry out detailed setting, thus cause this unmanned vehicle may there is potential safety hazard when flying.Such as, when unmanned vehicle enters airport or wiring cad, the generation of aviation safety accident may be caused; Or when to enter the non-surveyed areas such as some private area when unmanned vehicle, the dislike of the people in this region may be caused or cause human safety issues.For this reason, how fast setting flight range, preset no-fly region, and the flight path of monitoring unmanned vehicle avoid it to enter problem that no-fly region is emergency process in real time.
In prior art, once proposed to arrange a monitoring unit in ground control system, the boundary value of flight range is previously stored with in this monitoring unit, and judge whether above-mentioned unmanned vehicle surmounts above-mentioned flight range by the relation between the position of comparing unmanned vehicle and above-mentioned boundary value, if judge, above-mentioned unmanned vehicle has exceeded above-mentioned flight range, then export corresponding alerting signal to described unmanned vehicle.But, in technique scheme, when when unmanned vehicle distance ground control system is far away, too weak or between unmanned vehicle and ground control system the Signal transmissions of signal is interfered, easy appearance above-mentioned unmanned vehicle locating information cannot be passed to ground control system in time so that above-mentioned border monitoring function cannot complete, then now unmanned vehicle can surmount default safe range, and and lost contact between ground control system.
Utility model content:
The purpose of this utility model be to provide a kind of can fast setting unmanned vehicle flight range and to place according to the concrete flight path of unmanned vehicle and whether the flight path also monitoring unmanned vehicle when the output signal of unmanned vehicle is weak in real time surmounts the electron boundary device of predeterminable area.
Particularly, the utility model mainly provides following technical scheme:
A kind of electron boundary device, for setting the flight range of unmanned vehicle, wherein, described electron boundary device comprises:
For receiving the communication unit of information and feedback information;
For locating the positioning unit of described electron boundary device self-position;
Wherein, described electron boundary device is arranged independent of described unmanned vehicle, and can be placed on precalculated position to determine described flight range.
Further, described electron boundary device also comprises the travel mechanism making it easy to movement; Described electron boundary device also comprises the landing platform stopped for described unmanned vehicle landing and the identification beacon making it easy to identify location; Described electron boundary device also comprises the fixed mechanism of a fixing landing described unmanned vehicle thereon.
And particularly, described localizer beacon is GPS positioning unit.
The present invention also provides a kind of electron boundary system, wherein, electron boundary device, at least one unmanned vehicle and ground control system that described electron boundary system is described before comprising at least one, wherein, described electron boundary system also comprises:
Receive the central processing unit of the positional information of described electron boundary device, and described central processing unit based on described electron boundary device positional information and determine the flight range of described unmanned vehicle;
The comparer be connected with described central processing unit, and whether described comparer unmanned vehicle according to the Distance Judgment between the position of described unmanned vehicle and described electron boundary device is positioned at described flight range.
Particularly, described central processing unit and described comparer are arranged in described electron boundary device and/or described unmanned vehicle and/or ground control system.
Further, described flight range is divided into flight safety region, prewarning area and restricted area territory according to the different distance with described electron boundary device, and described electron boundary system also comprises an alarm be connected with described comparer, it is output alarm signal when described comparer judges that described unmanned vehicle enters described prewarning area, wherein, described alarm is arranged on described electron boundary device and/or described unmanned vehicle and/or ground control system.
Further, at described comparer, described central processing unit judges that described unmanned vehicle controls the landing of described unmanned vehicle or makes a return voyage when entering described restricted area territory.
Again further, described electron boundary system also comprises the storer that prestores monitoring range information and verifies the identity information of described unmanned vehicle and judge whether it belongs to the validator of described monitoring range information, and described storer and described validator are all arranged on described electron boundary device.
Adopt technique scheme, can the flight boundary of fast setting unmanned vehicle, even if the flight path of unmanned vehicle also can be monitored when the Signal transmissions between unmanned vehicle and ground control system exists abnormal in real time, avoid it to surmount flight safety scope, and avoid the situation that unmanned vehicle lost contact occurs.
Accompanying drawing illustrates:
Fig. 1 a is the basic composition schematic diagram of the utility model embodiment one electron boundary system; Fig. 1 b is this enforcement
The basic composition schematic diagram of the electron boundary device of example;
Fig. 2 is the utility model embodiment one one kinds of flight range setting means schematic diagram;
Fig. 3 is the utility model embodiment one another kind of flight range setting means schematic diagram;
Fig. 4 is that the utility model embodiment one utilizes electron boundary device to carry out to unmanned vehicle the stream monitored that flies
Cheng Tu;
Fig. 5 is the schematic diagram that the utility model embodiment two or three electron boundary devices combinationally use;
Fig. 6 is the schematic diagram that the utility model embodiment two or four electron boundary devices combinationally use;
Fig. 7 is that the utility model embodiment three utilizes electron boundary device to carry out to unmanned vehicle the stream monitored that flies
Cheng Tu.
Symbol description: 10 electron boundary devices, 101 signal transceivers, 102 localizer beacons, 103 central processing units, 104 comparers, 20 ground control systems, 30 unmanned vehicles, X, Y flight range, X1, Y1 flight safety region, X2, Y2 prewarning area, X3, Y3 restricted area territory.
Embodiment:
Main technical schemes of the present invention is: by placing one independent of the electron boundary device of unmanned vehicle and ground control system on the flight path of unmanned vehicle, and based on this electron boundary device positional information and determine the flight range of unmanned vehicle, thus the flight condition of above-mentioned electron boundary device to unmanned vehicle can be utilized to monitor in real time, avoid it to depart from flight safety scope.
Description below by way of specific embodiment makes comprehensive, detailed description to technical scheme of the present invention.It should be noted that, these specific descriptions just allow those of ordinary skill in the art be more prone to, clearly understand the present invention, but not limitation of the invention is explained.
Embodiment one:
The basic composition schematic diagram of Fig. 1 a electron boundary system disclosed in the present embodiment.As shown in Figure 1a, this electron boundary system comprises an electron boundary device 10, one or more unmanned vehicle 30 and ground control system 20, and above-mentioned electron boundary device 10 is arranged independent of above-mentioned unmanned vehicle 30 or ground control system 20, in other words, above-mentioned electron boundary device 10 arbitrarily can move on optional position according to real needs, and above-mentioned electron boundary device can be placed on precalculated position to determine above-mentioned flight range.In addition, in the present embodiment, the flight range of above-mentioned unmanned vehicle 30 based on above-mentioned electron boundary device 10 positional information and determine.Wherein, as shown in Figure 1a, above-mentioned electron boundary device 10, above-mentioned unmanned vehicle 30 and ground control system all can carry out communication interaction each other.
Wherein, on above-mentioned unmanned vehicle 30 except being provided with the communication module of to carry out with electron boundary device 10 or ground control system 20 communicating, the locating module that can be used for obtaining its positional information is also provided with.Particularly, above-mentioned locating module can be this area conventional GPS module, wireless signal module etc.
In order to can the flight range border of the above-mentioned unmanned vehicle 30 of fast setting, and in time the flight condition of unmanned vehicle 30 is monitored, preferably, in the present embodiment, above-mentioned electron boundary system also comprises: control module, it can receive the positional information of above-mentioned electron boundary device 10, and determines the flight range of above-mentioned unmanned vehicle 30 based on this positional information, specifies the boundary threshold of above-mentioned flight range; Judging unit, is connected with above-mentioned control module, and according to the positional information of the positional information of above-mentioned unmanned vehicle 30 and above-mentioned electron boundary device 10, it judges whether above-mentioned unmanned vehicle 30 is in flight range.Above-mentioned control module and judging unit can be arranged in above-mentioned electron boundary device 10 or unmanned vehicle 30 or ground control system 20.In the present embodiment, in order to ensure between unmanned vehicle and ground control system due to situation when signal of communication is weak or occur the communication barrier, lost contact occurring, unmanned vehicle surmounts flight range, preferably, above-mentioned control module and above-mentioned judging unit are arranged on above-mentioned electron boundary device 10.
Particularly, the basic composition schematic diagram of Fig. 1 b electron boundary device disclosed in the present embodiment.As shown in Figure 1a, electron boundary device 10 for setting the flight range of unmanned vehicle comprises: communication unit, it is for receiving information and feedback information, namely it is mainly used in respectively and carries out information interaction between unmanned vehicle 30 and ground control system 20, particularly, this communication unit can be common signal transceiver 101; Positioning unit, for locating the particular location of above-mentioned electron boundary device 10, particularly, this positioning unit can be common localizer beacon 102, as GPS locating device or wireless signal locating device etc.; Control module, be connected with above-mentioned positioning unit, and the flight range of above-mentioned unmanned vehicle 30 is determined based on the positional information of above-mentioned electron boundary device 10, in other words, above-mentioned control module divides and allows the flight range of above-mentioned unmanned vehicle 30 flight and forbid the no-fly region that above-mentioned unmanned vehicle 30 flies based on the positional information of above-mentioned electron boundary device 10; Particularly, above-mentioned control module can be common central processing unit 103 etc.; Judging unit, is connected with above-mentioned control module, and whether is in above-mentioned flight range according to the above-mentioned unmanned vehicle of Distance Judgment 30 between the position of above-mentioned unmanned vehicle 30 and self-position, and particularly, this judging unit may be selected to be comparer 104.
Particularly, based on above-mentioned electron boundary device 10 positional information and determine that the flight range of above-mentioned unmanned vehicle at least comprises following two kinds of situations: 1) using above-mentioned electron boundary device 10 position or its plane of flattening as the flight range border of unmanned vehicle 30; 2) centered by above-mentioned electron boundary device 10 position or basic point and generate the flight range of above-mentioned unmanned vehicle 30.
Fig. 2 is the schematic diagram that the flight range set centered by above-mentioned electron boundary device position shows; Fig. 3 is the schematic diagram setting flight range with above-mentioned electron boundary device position for flight range border.As shown in Figure 2, the flight range of unmanned vehicle 30 is set as that, centered by electron boundary device 10 position, radius is the circle of R, so, the region be positioned within circle is the flight range X of unmanned vehicle, and the region be positioned at beyond circle is the no-fly region of unmanned vehicle.Certainly, also can conversely, the setting region be positioned within circle is the no-fly region of unmanned vehicle, and the region be positioned at beyond circle is the flight range of unmanned vehicle.So, only need, needing to set in the territorial scope of flight boundary, to arrange one or more electron boundary device, just can set the space being suitable for aircraft activity freely.
Fig. 3 is the schematic diagram setting flight range with above-mentioned electron boundary device position for flight range border.As shown in Figure 3, the flight range Y of unmanned vehicle 30 with above-mentioned electron boundary device 10 position and the plane of flattening thereof for flight range border, namely namely the region being positioned at above-mentioned electron boundary device 10 position and any side of the plane of flattening thereof forms the flight range of above-mentioned unmanned vehicle, accordingly, namely opposite side forms the no-fly region of above-mentioned unmanned vehicle.
And, in order to ensure that unmanned vehicle can have good transition between safe flight region and hazardous location, and ensure the suitable emergency processing time, preferably, in the present embodiment, according to the distance between above-mentioned electron boundary device 10, above-mentioned flight range X/Y is divided into flight safety region, prewarning area and restricted area territory.Particularly, as shown in Figure 2, when setting the flight range of unmanned vehicle centered by electron boundary device, above-mentioned flight range X is divided into flight safety region X1, prewarning area X2 and restricted area territory X3 successively according to the distance between the position of electron boundary device 10, wherein, above-mentioned restricted area territory X3 apart from above-mentioned electron boundary device 10 farthest.And as shown in Figure 3, when with electron boundary device for border and when setting the flight range of unmanned vehicle, above-mentioned flight range Y is divided into restricted area territory Y3, prewarning area Y2 and flight safety region Y1 successively according to the distance between the position of electron boundary device 10, wherein, above-mentioned restricted area territory Y3 is nearest apart from above-mentioned electron boundary device 10.
Region represented in above-mentioned figure only illustrates the state of two dimension, and the region in not shown vertical dimensions, the region that those of ordinary skill in the art should understand described in above-mentioned figure all represents three-dimensional spatial area.Such as, above-mentioned flight range also can be delimited by the solid circle region centered by above-mentioned electron boundary device, or also can be delimited by the solid circle region being border with above-mentioned electron boundary device.Particularly, the restricted area territory that those of ordinary skill in the art should understand above-mentioned electron boundary device also can adopt other mode to carry out division and limit, as long as by the above-mentioned position of electron boundary device and/or the extended surface of its position for border/centered by.
Further, flight safety region has been departed from order to above-mentioned unmanned vehicle 30 can be pointed out in time, preferably, above-mentioned electron boundary device 10 also comprises an alarm, it is connected with above-mentioned comparer 104, and for when above-mentioned comparer 104 judges that above-mentioned unmanned vehicle 30 has entered above-mentioned prewarning area, output alarm signal.Particularly, above-mentioned alerting signal can be the information command being sent to above-mentioned unmanned vehicle 30, thus makes the controller of this unmanned vehicle can control above-mentioned unmanned vehicle in time to make a return voyage or the flight path that adjusts above-mentioned unmanned vehicle returns to flight safety region to make it; Or, above-mentioned alerting signal also can be the information being sent to ground control system 20, thus make operator understand above-mentioned unmanned vehicle 30 to have surmounted flight safety region X1/Y1, and control above-mentioned unmanned vehicle 30 and adjust flight path or the operation such as to make a return voyage, make it return flight safety region X1/Y1; Or, externally send acousto-optic warning signal etc. by above-mentioned unmanned vehicle 30.
In addition, when above-mentioned judging unit 104 judges that above-mentioned unmanned vehicle 30 enters above-mentioned restricted area territory X3/Y3, control module 103 controls above-mentioned unmanned vehicle 30 and lands or make a return voyage, and avoids it to depart from the flight path preset.Particularly, after judging that above-mentioned unmanned vehicle 30 enters restricted area territory X3/Y3, above-mentioned control module 103 can set up communication negotiation to obtain the control of above-mentioned unmanned vehicle 30 with above-mentioned ground control system 20, and controls above-mentioned unmanned vehicle 30 and carry out making a return voyage pattern or controlling above-mentioned unmanned vehicle 30 selecting rational position to land nearby.
In order to improve the security performance of above-mentioned unmanned vehicle further, preferably, in the present embodiment, above-mentioned electron boundary device 10 also can form the place of making preparation for dropping of above-mentioned unmanned vehicle 30.Concrete, above-mentioned electron boundary device 10 is provided with a landing platform and identification beacon, when above-mentioned unmanned vehicle 30 flies to restricted area territory X3/Y3, above-mentioned control module 103 can control above-mentioned unmanned vehicle 30 and select electron boundary device 10 to land nearby.Particularly, above-mentioned identification beacon can be sent to unmanned vehicle 30 by above-mentioned control module 103, can identify navigate to corresponding electron boundary device to make unmanned vehicle 30.Wherein, above-mentioned identification beacon can be as physical beacon, as pattern identification, also can be the wireless beacon using wireless signal to position, or other can make unmanned vehicle 30 identify the mark navigating to above-mentioned electron boundary device 10.And above-mentioned electron boundary device also comprises one for the fixed mechanism of fixing landing unmanned vehicle thereon, thus due to the impact of environment, as wind-force etc., and can not fall when preventing above-mentioned unmanned vehicle lowered in field environment.
And in order to make above-mentioned electron boundary device 10 can conveniently move on required predeterminated position, preferably, in the present embodiment, above-mentioned electron boundary device is also provided with travel mechanism to facilitate mobile electron boundary means on required position.
Those of ordinary skill in the art should understand, above-mentioned electron boundary device also can be arranged to enter above-mentioned prewarning area once discovery unmanned vehicle, namely above-mentioned control module controls above-mentioned unmanned vehicle and enters and make a return voyage or landing state, without the need to additionally arranging the alarm unit of output alarm signal.
Fig. 4 is the flight method for supervising process flow diagram utilizing above-mentioned electron boundary device to carry out unmanned vehicle.According to Fig. 4, the flight method for supervising of above-mentioned unmanned vehicle to be described below.
Particularly, above-mentioned flight method for supervising comprises the following steps:
S1: place a foregoing electron boundary device 10 in precalculated position;
S2: the positional information based on above-mentioned electron boundary device 10 determines the flight range of above-mentioned unmanned vehicle 30;
Particularly, can adopt as earlier figures 2 or Fig. 3 or alternate manner carry out the setting of flight range, as long as by the above-mentioned position of electron boundary device 10 and/or the extended surface of its position for border/centered by/basic point; And the concrete size of flight range is also specifically selected according to various actual conditions.
As previously mentioned, in the present embodiment, mode shown in above-mentioned Fig. 3 is adopted to carry out the setting of flight range.
S3: the positional information obtaining above-mentioned unmanned vehicle 30;
S4: according to the positional information of above-mentioned unmanned vehicle 30, determines the distance between above-mentioned unmanned vehicle 30 and above-mentioned electron boundary device 10, and whether unmanned vehicle 30 is in above-mentioned flight range Y according to Distance Judgment described above.
In the present embodiment, after above-mentioned steps S4, can also comprise the following steps: when judging that above-mentioned unmanned vehicle enters particular flight region, output alarm signal or the step controlling the landing of above-mentioned unmanned vehicle or make a return voyage.
Particularly, in the present embodiment, above-mentioned particular flight region is aforesaid prewarning area and/or restricted area territory.Preferably, in the present embodiment, when judging that above-mentioned unmanned vehicle 30 enters above-mentioned prewarning area Y2, then output alarm signal; Further, when judging that above-mentioned unmanned vehicle 30 enters above-mentioned restricted area territory Y3, then control above-mentioned unmanned vehicle 30 and land or make a return voyage.
In addition, those of ordinary skill in the art should be understood that above-mentioned control module and judging unit also can be arranged in unmanned vehicle 30 or ground control system 20.So, above-mentioned electron boundary device 10 is after being placed on ad-hoc location, communication unit on it only needs the locating information being located unit acquisition to be sent to unmanned vehicle 30/ or ground control system 20, be arranged on control module in above-mentioned unmanned vehicle 30 or ground control system 20 and namely judging unit performs foregoing operation, namely based on received electron boundary device 10 positional information and determine the flight range of unmanned vehicle 30, and judge whether unmanned vehicle 30 is positioned at flight range by the relation in real time between monitoring unmanned vehicle 30 and the position of above-mentioned electron boundary device 10.Further, those of ordinary skill in the art should understand, above-mentioned control module and judging unit also can be arranged on above-mentioned electron boundary device 10, in unmanned vehicle 30 and ground control system 20 more than any two equipment, so, not only utilize above-mentioned electron boundary device effectively can carry out flight monitoring to unmanned vehicle, by the position of the position and electron boundary device of comparing unmanned vehicle, above-mentioned ground control system and above-mentioned unmanned vehicle also can judge that whether above-mentioned unmanned vehicle is close to above-mentioned electron boundary device at any time, thus carried out multi-ensuring for the flight safety of unmanned vehicle.
Obviously, adopt above-mentioned electron boundary device, electron boundary system and flight method for supervising, can fast setting flight range, in real time the flight path of unmanned vehicle is monitored, and intervene in time when it leaves flight safety region, avoid it owing to being connected abnormal and lost contact with the signal between ground control system, surmount the situations such as flight safety scope and occur.
Embodiment two:
The difference of the present embodiment and embodiment one is, in the present embodiment, electron boundary system comprises multiple electron boundary device 10.That is, in the present embodiment, the flight path that unmanned vehicle 30 is preset is provided with multiple electron boundary device 10, so, when with electron boundary device 10 position for border and when setting flight range, between multiple electron boundary device 10 around and namely the region that formed forms the flight range of unmanned vehicle 30, namely the common factor being namely border and each set flight range with each electron boundary device 10 position is formed the flight range of unmanned vehicle 30; And when setting flight range centered by electron boundary device 10 position, centered by each electron boundary device 10 position, namely the union of each set flight range is formed the flight range of unmanned vehicle 30.So, it all can be avoided equally to exceed safe flight scope when unmanned vehicle 30 flies towards the region between any two electron boundary devices 10, ensure its safe flight.
The concrete grammar that the electron boundary device being formed flight range border for three shown in Fig. 5 below combinationally uses the unmanned vehicle of the present embodiment is monitored is described.In addition, in the present embodiment, electron boundary device 10 adopts wireless signal locating device, namely utilizes wireless signal to position.
As shown in Figure 5, the placement location of three electron boundary devices 10 is projected as a triangle ABC (also representing the electron boundary device being positioned at relevant position below with A, B, C respectively) in XY plane, and the locus D at unmanned vehicle 30 place is projected as E point on above-mentioned triangle ABC; For this reason, along with the flight of unmanned vehicle 30, judge that according to E point and the relation of the distance between the distance sum between two summits forming arbitrary border and corresponding Shang Liangge summit, border above-mentioned unmanned vehicle 30 is away near arriving above-mentioned border; Exactly, can judge whether above-mentioned unmanned vehicle has entered the restricted area territory of arbitrary electron boundary device 10 according to E point to the relation of the distance between the distance sum between two summits forming arbitrary border and corresponding Shang Liangge summit, border.Such as, when the length sum of BE+CE diminishes gradually, and during length close to BC, show that now unmanned vehicle 30 is near above-mentioned BC border, namely show that now unmanned vehicle 30 has entered the restricted area territory of above-mentioned electron boundary device B or electron boundary device C; When the length sum of BE+CE equals the length of BC, represent that now unmanned vehicle 30 has arrived at above-mentioned BC border.
If when it will be understood by those skilled in the art that the projecting plane of flight range in XY plane that multiple electron boundary device 10 is formed is polygon, can adopt and this polygon is divided into multiple triangle, and carry out border monitoring based on each triangle.Such as, when four electron boundary devices 10 form rectangle electron boundary region as shown in Figure 7, when the subpoint of unmanned vehicle 30 is in triangle ACD, and when flying to electron boundary device B, reduced gradually by the calculating of estimation unmanned vehicle and the distance between electron boundary device A and electron boundary device C, but also reducing gradually with the distance of boundary means B simultaneously, then representing that unmanned vehicle is just flying to next legal area triangles ABC, then there will not be warning of crossing the border.
Those of ordinary skill in the art should understand, when above-mentioned electron boundary device and unmanned vehicle adopt GPS unit as locating device, it also can be equally applicable to the situation that above-mentioned multiple electron boundary device combinationally uses, concrete location Calculation mode is associated with longitude and latitude, belong to the common technique of this area, therefore not to repeat here.
Those of ordinary skill in the art should understand, in the present embodiment, in order to enable unmanned vehicle be convenient to when selecting electron boundary device nearby to land and select suitable electron boundary device in time, preferably, above-mentioned each electron boundary device should arrange different identification beacons.
Other content and above-described embodiment one similar, therefore not to repeat here.
Embodiment three:
The difference of the present embodiment and embodiment one or embodiment two is, in the present embodiment, specific monitoring range is possessed in order to enable this electron boundary device, preferably, the identity information that above-mentioned electron boundary device 10 also comprises the storage unit and a pair unmanned vehicle 30 that prestores monitoring range information carries out identifying to be verified and judges whether it belongs to the authentication unit of above-mentioned monitoring range information.Particularly, above-mentioned monitoring range information can be the relevant information needing to carry out the one or more unmanned vehicles monitored.
Fig. 5 utilizes electron boundary device to carry out to unmanned vehicle the flight method for supervising monitored that flies in the present embodiment.Particularly, as shown in Figure 5, place at least one foregoing electron boundary device 10 at predeterminated position, and based on this electron boundary device 10 position and determine flight range, and set flight safety region X1/Y1, prewarning area X2/Y2 and restricted area territory X3/Y3; When unmanned vehicle 30 enters prewarning area X2/Y2, verify the identity information of above-mentioned unmanned vehicle 30, judge whether it belongs to the monitor message prestored, if belong to, then perform the operation that follow-up alerting signal exports and/or controls its landing or make a return voyage, if do not belong to, then any intervention is not done to the flight operation of this unmanned vehicle 30; And when unmanned vehicle 30 does not enter above-mentioned prewarning area X2/Y2, it is not entered to do any intervention equally.
Other content and embodiment one or two similar, therefore not to repeat here.
Particularly, above-mentioned electron boundary device can be applied in multiple occasion.Such as, in the flight range of unmanned vehicle, when there is a transformer station or high-tension electricity transmission tower, the Signal transmissions affected between itself and ground control system near above-mentioned unmanned vehicle flight to above-mentioned transformer station or high-tension electricity transmission tower, one electron boundary device can be placed near above-mentioned two places and temporarily above-mentioned two equipment regions can be set to no-fly region, avoid unmanned vehicle close.For another example, when carrying out the flight operation match of unmanned vehicle, only need can complete flight to compete for speed the planning of route at compete for speed electron boundary device that route border arranges right quantity of flight, set up aviation restricted area, therefore when take in competition unmanned vehicle depart from preset flight compete for speed route and near above-mentioned arbitrary electron boundary device time, namely it can be forced to drop on electron boundary equipment due to the operation of electron boundary device.
Each functional unit in the embodiment of the present invention can be integrated in a processing module, and also can be that the independent physics of unit exists, also can be that two or more unit are integrated in a module.Above-mentioned integrated module both can adopt the form of hardware to realize, and the form of software function module also can be adopted to realize.
Finally it should be noted that, above-mentioned explanation is only most preferred embodiment of the present invention, not does any pro forma restriction to the present invention.Any those of ordinary skill in the art; do not departing within the scope of technical solution of the present invention; the way of above-mentioned announcement and technology contents all can be utilized to make many possible variations and simple replacement etc. to technical solution of the present invention, and these all belong to the scope of technical solution of the present invention protection.

Claims (10)

1. an electron boundary device, for setting the flight range of unmanned vehicle, wherein, described electron boundary device comprises:
For receiving the signal transceiver of information and feedback information;
For locating the localizer beacon of described electron boundary device self-position;
It is characterized in that, described electron boundary device is arranged independent of described unmanned vehicle, and can be placed on precalculated position to determine described flight range.
2. electron boundary device according to claim 1, is characterized in that, described electron boundary device also comprises the travel mechanism making it easy to movement.
3. electron boundary device according to claim 1 and 2, is characterized in that, described electron boundary device also comprises the landing platform stopped for described unmanned vehicle landing and the identification beacon making it easy to identify location.
4. electron boundary device according to claim 3, is characterized in that, described electron boundary device also comprises the fixed mechanism of a fixing landing described unmanned vehicle thereon.
5. electron boundary device according to claim 3, is characterized in that, described localizer beacon is GPS positioning unit.
6. an electron boundary system, it is characterized in that, described electron boundary system comprises at least one arbitrary electron boundary device, at least one unmanned vehicle and ground control system as described in claim 1 to 5, and wherein, described electron boundary system also comprises:
Receive the central processing unit of the positional information of described electron boundary device, and described central processing unit based on described electron boundary device positional information and determine the flight range of described unmanned vehicle;
The comparer be connected with described central processing unit, and whether described comparer unmanned vehicle according to the Distance Judgment between the position of described unmanned vehicle and described electron boundary device is positioned at described flight range.
7. electron boundary system according to claim 6, is characterized in that, described central processing unit and described comparer are arranged in described electron boundary device and/or described unmanned vehicle and/or ground control system.
8. electron boundary system according to claim 7, it is characterized in that, described flight range is divided into flight safety region, prewarning area and restricted area territory according to the different distance with described electron boundary device, and described electron boundary system also comprises an alarm be connected with described comparer, it is output alarm signal when described comparer judges that described unmanned vehicle enters described prewarning area, wherein, described alarm is arranged on described electron boundary device and/or described unmanned vehicle and/or ground control system.
9. electron boundary system according to claim 8, is characterized in that, at described comparer, described central processing unit judges that described unmanned vehicle controls the landing of described unmanned vehicle or makes a return voyage when entering described restricted area territory.
10. electron boundary system according to claim 8 or claim 9, it is characterized in that, described electron boundary system also comprises the storer that prestores monitoring range information and verifies the identity information of described unmanned vehicle and judge whether it belongs to the validator of described monitoring range information.
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105243878A (en) * 2015-10-30 2016-01-13 杨珊珊 Electronic boundary apparatus, unmanned flight system, unmanned aerial vehicle monitoring method
CN108521811A (en) * 2017-07-31 2018-09-11 深圳市大疆创新科技有限公司 Determine method, unmanned plane and the ground installation of unmanned plane during flying strategy
CN109154833A (en) * 2017-09-28 2019-01-04 深圳市大疆创新科技有限公司 Determination method, terminal device and the unmanned plane in region locating for unmanned plane
CN114151136A (en) * 2021-11-04 2022-03-08 天地(常州)自动化股份有限公司 Personnel protection method of reversed loader

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105243878A (en) * 2015-10-30 2016-01-13 杨珊珊 Electronic boundary apparatus, unmanned flight system, unmanned aerial vehicle monitoring method
CN108521811A (en) * 2017-07-31 2018-09-11 深圳市大疆创新科技有限公司 Determine method, unmanned plane and the ground installation of unmanned plane during flying strategy
CN109154833A (en) * 2017-09-28 2019-01-04 深圳市大疆创新科技有限公司 Determination method, terminal device and the unmanned plane in region locating for unmanned plane
WO2019061152A1 (en) * 2017-09-28 2019-04-04 深圳市大疆创新科技有限公司 Method for determining area where unmanned aerial vehicle is located, terminal device, and unmanned aerial vehicle
CN114151136A (en) * 2021-11-04 2022-03-08 天地(常州)自动化股份有限公司 Personnel protection method of reversed loader
CN114151136B (en) * 2021-11-04 2024-02-20 天地(常州)自动化股份有限公司 Personnel protection method of reversed loader

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