EP3129971B1 - Method for monitoring airspace - Google Patents

Description

The invention relates to a method for airspace monitoring, in particular a method for recognizing and locating aircraft in order to avoid collisions between aircraft.

Different systems are known for avoiding collisions between manned aircraft. Such known systems usually see an on-board electronics in the respective aircraft, consisting of a computer with a screen, a data communication device, a FLARM and / or ADS-B receiver, a transponder, a GNSS device and an electronic control unit Processing of data before. One aircraft receives the flight data of another aircraft via this on-board electronics. The data received from the on-board electronics are processed and displayed graphically for the pilot on the computer screen. In this way, the pilot can decide which measures are to be taken to avoid a collision with the other aircraft. Such a data exchange, however, requires that the two aircraft have the same communication technology so that the flight data sent or received can also be read out and processed.

Furthermore, from the DE 10 2007 032 084 A1 a collision and conflict avoidance system for autonomous unmanned aircraft (UAV) is known, in which the system uses available on-board sensors to form an image of the surrounding airspace. In this way, the airspace is examined for impending conflicts and, if a problem is identified, a search for alternative options is started, the alternative routes, as far as possible, complying with the prescribed air traffic rules.

From the US 2002/075179 A1 discloses a method for receiving and translating ADS-B messages from the Mode-S format into the UAT format using a universal access transceiver. A transceiver system is provided that enables communication between two differently equipped aircraft, with one Incoming signal is translated in a first format into an outgoing second signal that is compatible with the transmitter.

The US 2009/322588 A1 describes a method in which data is automatically transmitted via an ADS-B system installed in the aircraft and received by an ADS-B ground station.

Furthermore, from the EP 2 056 272 A2 a transmission planning for ADS-B ground stations known. For a given destination, a controller determines the relevant customers to receive information about the destination, identifies all of the ground stations that can be satisfactorily heard by the relevant customers, and then identifies a smaller subset of the ground stations by selecting only the ground stations that are needed to reach all relevant customers. ADS-B messages are then sent to the relevant customers using only the smaller subset of ground stations.

The US 2009/248287 A1 describes a reporting system for unmanned flying objects, wherein an unmanned flying object (UAS) is connected to a ground station (GCS) for communication purposes and the ground station monitors the position of the unmanned flying object.

From the WO 2009/112112 A1 an arrangement and a method for air traffic control and / or flight control of aircraft are known, wherein at least one transmitting station in an aircraft to be secured and / or managed transmits a broadcast signal that is received by at least one of several receiving stations that are spaced apart from one another, which at least forwards some of the data contained in the broadcast signal to an air traffic control and / or flight control center or other organizations. In order to be able to implement large-area, preferably area-wide, global airspace monitoring with the least possible effort and costs, it is proposed that at least some of the receiving stations be designed as satellite receiving stations.

The DE 10 2005 031 439 A1 describes a satellite-based system for warning of collisions and for traffic management of vehicles such as aircraft. Based on a satellite navigation system, a satellite communication system, a computer simulation and an expert system, all vehicles of a carrier are recorded and their routes are simulated.

From the US 2010/0121575 A1 a ground-based data acquisition and communication system for collision avoidance for unmanned flight systems is known. This system is set up to provide information when controlling an unmanned aerial vehicle in order to avoid a collision between the unmanned aerial system and other air traffic.

The known conflict avoidance systems are accordingly arranged as on-board electronics in the respective aircraft. For smaller or lighter manned or unmanned aircraft, such on-board electronics with a conflict avoidance system can be too heavy due to the weight. Another problem is that not all aircraft have a uniform communication technology and have a transmitter for transmitting data and a receiver for receiving data. Aircraft with different communication and location systems therefore have the problem that they may not be able to recognize or identify all aircraft.

It is therefore the object of the invention to provide a method for airspace monitoring which enables cross-system airspace monitoring.

This object is achieved by the subject matter of claim 1. Preferred developments are specified in the subclaims.

It is therefore an essential aspect of the invention that the first data relating to the first aircraft are transmitted from the first control and acquisition unit to the air surveillance system and data based on the first data are sent from the air surveillance system to the second control and acquisition unit . In this way, the first data are transmitted from the first aircraft to the second aircraft via the air surveillance system and the second control and acquisition unit.

The first aircraft is an unmanned aircraft. The second aircraft is an unmanned or a manned aircraft. Unmanned aerial vehicles are preferably to be understood as drones. Manned aircraft include both lighter sport aircraft, glider pilots, parachutists and larger passenger and cargo aircraft.

The first control and acquisition unit and / or the second control and acquisition unit is preferably a ground station which has a continuous connection to the first aircraft or to the second aircraft. The first control and detection unit and / or the second control and detection unit is particularly preferably a secondary radar system with a secondary radar transmitter and a secondary radar receiver, the secondary radar receiver receiving data sent by the aircraft and the transmitter sending data to the aircraft. The first control and detection unit and / or the second control and detection unit is very particularly preferably a primary radar system with a positioning system and a transmitter, the positioning system determining data from the aircraft and the transmitter sending data to the aircraft.

The first data are preferably data about the airspeed, the position, the altitude, the rate of climb or descent, the distance and the direction of flight of the respective first aircraft. The first data are preferably signals. The first data are particularly preferably data structures for describing the airspace, on the basis of which a flight area can be reserved. The first data are very particularly preferably computer-readable data, wherein the first data of the first aircraft can have different file formats. The file formats of the first data are preferably data from FLARM or ADS-B (Automatic Dependent Surveillance Broadcast).

Another preferred development of the invention provides that a time stamp and / or a tracking ID is added to the first data and / or the data. The time stamp enables the first data and / or data to be checked to ensure that they are up to date. The tracking ID ensures that even at a later point in time the data sent out by the airspace monitoring system can be clearly assigned to the first data transmitted to the airspace monitoring system. In this way, a traceable data flow in the airspace monitoring system is ensured.

The speed of the data transmission can be of central importance in particular to avoid a collision between the first aircraft and the second aircraft. A preferred development of the invention therefore provides that the transmission of the first data from the first control and acquisition unit to the airspace monitoring system and the transmission of the data based on the first data from the airspace monitoring system to the second control and acquisition unit virtually in real time and thus can be transmitted or sent immediately, without planned delays. In this way, the possibility is given of providing data about the first aircraft directly to a second aircraft in order to identify and avoid a collision between the first aircraft and the second aircraft at an early stage. The data communication between the first control and acquisition unit and the airspace monitoring system or the airspace monitoring system and the second control and acquisition unit is preferably based on web-based communication technology. In this way, fast and immediate data communication can be made possible.

Another preferred development of the invention provides that the first data transmitted to the airspace monitoring system and / or the data sent by the airspace monitoring system to the second control and detection unit are transformed in the airspace monitoring system. When the first data transmitted to the airspace monitoring system are transformed, the first data are transformed into a file format that enables the first data to be processed in the airspace monitoring system. By transforming the data sent out by the airspace surveillance system, the data can on the one hand be transformed into the original file format of the first data and / or into a file format different from the first data. If the data is transformed into a file format that is different from the first data, the data based on the first data can be sent to a second control and detection unit that is different from the first control and detection unit. In this way, the first data from the first aircraft can be transmitted across systems via the first control and acquisition unit, the airspace monitoring system and the second control and acquisition unit to a second aircraft. The second aircraft can thus read the first data from the first aircraft without having to have the corresponding communication technology of the first aircraft. In addition to having a positive effect on the weight of the second aircraft, costs can also be reduced, since not every second aircraft has to have a technology for transforming the data.

So that the first data transmitted to the airspace monitoring system and / or the data sent out by the airspace monitoring system can still be viewed and traced at a later point in time, a further preferred development of the invention is that the first data transmitted to the airspace monitoring system and / or from the Airspace monitoring system to the second control and detection unit sent data are stored in the airspace monitoring system. In this way, the flight route of the first aircraft can be documented. Is the first aircraft an unmanned aircraft, the storage and documentation of the first data or data can also meet the regulatory requirements with regard to keeping a logbook.

According to a further preferred development of the invention, it is provided that the first aircraft is identified by the airspace monitoring system. In this way, the first data can be assigned to a specific first aircraft. For this purpose, the first aircraft preferably has a machine-readable identifier which, among other things, allows conclusions to be drawn about the operator of the first aircraft. The machine-readable identification is particularly preferably a chip card integrated in the first aircraft, a SIM card or a QR code. In connection with the storage of the first data, further requirements for keeping the logbook for the unmanned aircraft can be met in this way, since the first data can be assigned to the first aircraft.

High security requirements are placed on the transmission of data in air traffic so that they are not misused by unauthorized persons. A preferred development of the invention therefore provides that the first data transmitted to the airspace monitoring system and / or the data sent by the airspace monitoring system to the second control and detection unit are encrypted. In this way, misuse of the first data transmitted to the airspace monitoring system and / or the data sent out by the airspace monitoring system can be reduced.

To increase the security of the transmission of data in air traffic and in particular for a legally secure assignment of the first data transmitted to the airspace monitoring system, an advantageous development of the invention is that the first data transmitted to the airspace monitoring system and / or from the airspace monitoring system to the second Control and registration unit transmit data digitally be signed. In this way, it is possible to draw conclusions about the operator of the aircraft and thus a legally secure assignment of the first data of the first aircraft transmitted to the airspace monitoring system. The digital signature of the first data is preferably carried out with a private key of the operator of the first aircraft. The first data are particularly preferably digitally signed by the first control and acquisition unit in relation to the first aircraft. The first data are particularly preferably signed by the airspace monitoring system with a private key assigned to the first aircraft.

An advantageous development of the invention provides that the first data, after checking the signature, preferably the operator and / or device signature, are signed by the airspace monitoring system with a private key assigned to the airspace monitoring system itself. For this purpose, several first data are preferably combined in order to enable efficient data processing.

In this context, a preferred development of the invention provides that the digital signature takes place via a private key, which is introduced into the airspace monitoring system by means of a copy-protected, cryptographic token tied to a person and / or device. The token preferably meets the requirements for the qualified digital signature. The personal signature is particularly preferably carried out via the electrical identity card.

Furthermore, a further preferred development of the invention provides that, based on the first data, an area of the airspace on the flight route of the first aircraft is reserved in the airspace monitoring system for the first aircraft for a period of time. In this way, the air surveillance system contains data on the flight route of the first aircraft, these data being transmitted to the second control and detection unit. In this way, the second aircraft becomes the one reserved by the first aircraft Area of the airspace reserved so that the second aircraft, if a collision with the first aircraft is to be expected, can change the flight route. A possible collision can thus be identified at an early stage.

In addition to first data on the flight route of the first aircraft, data on basic or temporary no-fly zones can also be stored in the airspace monitoring system. Therefore, a further preferred development of the invention provides that data of a no-fly zone are stored in the airspace monitoring system and the data of the no-fly zone are checked with the first data transmitted to the airspace monitoring system. If a risk of collision is determined, data is transmitted from the air surveillance system to the first aircraft in order to change the flight route.

According to a further preferred development of the invention, it is provided that, based on the first data for the first aircraft, an ascent permit for the first aircraft is applied for and obtained via the airspace monitoring system. In this way, first data from the first aircraft about the flight route are stored in the air surveillance system. In the event of a positive decision and an ascent permit, data based on the first data are transmitted to the second control and registration unit. These data are not transmitted directly to the second control and detection unit, but only at the relevant point in time, that is, only from the point in time from which the first aircraft mounts and thus a risk of collision with the second aircraft can arise.

According to the invention, the first aircraft is an unmanned aircraft and the unmanned aircraft has a continuous connection to the first control and detection unit and, in the event of a break in the connection, transmits first data relating to the break in the connection from the first control and detection unit to the air surveillance system and from the air surveillance system Data based on the first data with regard to the disconnection are sent out to the second control and detection system. In this way, the second aircraft is informed of the break in the connection between the unmanned aircraft and the first control and detection unit, so that the second aircraft can pay more attention to the air traffic in order to be able to react quickly to an expected collision.

Another preferred development of the invention provides that the first control and acquisition unit is part of the second control and acquisition unit and forms a combined control and acquisition unit and the first data is acquired by the combined control and acquisition unit and transmitted to the airspace monitoring system and based on the first data, data are transmitted from the air surveillance system to the combined control and detection unit. The first control and detection unit preferably differs from the second control and detection unit. In this way, the combined control and detection unit is designed to be cross-system.

In this context, a further preferred development of the invention provides that the airspace monitoring system is an integral part of the combined control and detection system. In this way, the first control and detection unit, the second control and detection unit and the air surveillance system form an integral system.

To identify a possible collision between the first aircraft and the second aircraft, the invention provides that the second control and detection unit transmits second data relating to the second aircraft to the airspace monitoring system. The air surveillance system checks the first data from the first aircraft and the second data from the second aircraft for a conflict, in particular for a possible collision. If a risk of collision is identified, data is based transmitted on the first data and the second data to the second control and detection system. In this way, the second aircraft is informed of the identified risk of collision with the first aircraft and can change the flight route. The second aircraft therefore does not require any technology on board to evaluate the first data from the first aircraft, which has a positive effect on the weight of the second aircraft. In addition, the costs of the aircraft can be reduced in this way, since the airspace monitoring system evaluates the data and a technology for evaluating the flight data does not have to be arranged in the first aircraft or the second aircraft.

Like the first data, the second data are preferably data on the airspeed, the position, the altitude, the rate of climb or descent, the distance and the flight direction of the respective second aircraft, the file format of the second data being different from the file format of the first data can distinguish.

In this context, a further preferred development of the invention provides that data based on the second data are transmitted from the airspace monitoring system to the first control and detection unit. In this way, the first aircraft receives data about the second aircraft. In addition, if there is a risk of collision between the first aircraft and the second aircraft identified by the air surveillance system, both the first aircraft and the second aircraft can be informed of the identified risk of collision and each change the flight route.

One aspect of the invention is that the first data and second data transmitted to the airspace monitoring system are merged in the airspace monitoring system. In this way, based on these merged data, data can be sent out to the first control and detection unit in order to specify a new flight route for the first aircraft.

Basically, it should be pointed out that the second data can be processed in the airspace monitoring system in accordance with the first data. The second data can thus also be stored, transformed, encrypted and / or digitally signed. It is also possible for the second aircraft to be identified by the airspace monitoring system. Furthermore, based on the second data, the airspace for the second aircraft can be reserved in the airspace monitoring system, or an ascent permit for the second aircraft can be obtained via the airspace monitoring system.

According to a further preferred development of the invention, it is provided that the first control and acquisition system has a plurality of first aircraft and / or the second control and acquisition system has a plurality of second aircraft and the first control and acquisition unit transmits a plurality of first data to the airspace monitoring system . In this way, via the respective first control and acquisition unit or the second control and acquisition unit, a multiplicity of first aircraft or second aircraft can be connected in terms of communication to the first control and acquisition unit or second control and acquisition unit.

Finally, a preferred development of the invention provides that the method comprises a plurality of first control and detection systems and / or a plurality of second control and detection systems. In this way, the airspace can be monitored across systems for a large number of first aircraft and / or second aircraft.

Fig. 1

eine schematische Darstellung eines Verfahrens zur Luftraumüberwachung, wobei einem zweiten Fluggerät Daten eines ersten Fluggeräts übermittelt werden, gemäß dem bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 2

eine schematische Darstellung des Verfahrens zur Luftraumüberwachung, wobei in dem Luftraumüberwachungssystem erste Daten des ersten Fluggeräts mit zweiten Daten des zweiten Fluggeräts auf Kollision überprüft werden, gemäß dem bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 3

eine schematisch Darstellung des Verfahrens zur Luftraumüberwachung, wobei Daten von dem Luftraumüberwachungssystem an die erste Steuer- und Erfassungseinheit und an die zweite Steuer- und Erfassungseinheit ausgesendet werden, gemäß dem bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 4

eine maschinenlesbare Kennzeichnung in Form eines QR-Codes zur Identifikation des ersten Fluggeräts bzw. zweiten Fluggeräts, gemäß dem bevorzugten Ausführungsbeispiel der Erfindung.

The invention is explained in more detail below on the basis of a preferred exemplary embodiment with reference to the drawing. In the drawing show:

Fig. 1

a schematic representation of a method for airspace monitoring, data from a first aircraft being transmitted to a second aircraft, according to the preferred embodiment of the invention,

Fig. 2

a schematic representation of the method for airspace monitoring, wherein in the airspace monitoring system first data of the first aircraft with second data of the second aircraft are checked for collision, according to the preferred embodiment of the invention,

Fig. 3

a schematic representation of the method for airspace monitoring, with data being sent from the airspace monitoring system to the first control and acquisition unit and to the second control and acquisition unit, according to the preferred exemplary embodiment of the invention,

Fig. 4

a machine-readable identifier in the form of a QR code for identifying the first aircraft or second aircraft, according to the preferred exemplary embodiment of the invention.

In Figure 1 a method for airspace monitoring, with a first control and detection system 100, a second control and detection system 200 and an airspace monitoring system 300 is shown.

The first control and acquisition system 100 comprises a first aircraft 110 and a first control and acquisition unit 120, the first control and acquisition unit 120 being connected to the first aircraft 110 in terms of communication. The second control and acquisition system 200 also includes a second aircraft 210 and a second control and acquisition unit 220, the second control and acquisition unit 220 being connected to the second aircraft 210 in terms of communication. The first control and acquisition system 100 and the second control and acquisition system 200 are connected to one another in terms of communication via the air surveillance system 300. For this purpose, the first control and detection unit 120 and the second control and detection unit 220 are preferred connected to the air surveillance system 300 via a web-based communication link.

In the present case, the first aircraft 110 is preferably a manned aircraft and the second aircraft 210 is preferably an unmanned aircraft. In addition, the first control and detection unit 120 is preferably a secondary radar system with a secondary radar transmitter and a secondary radar receiver, and the second control and detection unit 220 is preferably a ground station of an unmanned aerial vehicle. The first control and detection system 100 and the second control and detection system thus differ from one another.

For airspace monitoring, the first control and acquisition unit 120 acquires first data 130 from the first aircraft 110, these first data 130 preferably data on the airspeed, position, altitude, rate of climb or descent, distance and flight direction of the first aircraft 110 and are preferably broadcast via the ADS-B. Accordingly, the first data are available in the ADS-B file format.

The first data are transmitted from the first control and acquisition unit to the airspace monitoring system 300. The first data 130 are transformed in the airspace monitoring system 300. Based on these first data 130, data 310 are sent out to the second control and acquisition unit 220 and transmitted from the second control and acquisition unit 220 to the second aircraft 210. As a result of the transformation of the first data 130 in the airspace surveillance system 300, the first data 130 of the first aircraft 110 can be made readable for the second aircraft 210 in this way. In this way, the second aircraft 210 can identify the flight route of the first aircraft 110 and, if necessary, change its flight route. This means that the airspace can be monitored across all systems.

To read the first data 130 from the first aircraft 110 in the second aircraft 210, in addition to the communication technology between the second aircraft 210 and the second control and acquisition unit 220, there is no need for the communication technology between the first aircraft 110 and the first control and acquisition unit 120. Thus, in addition to the existing communication link between the second aircraft 210 and the second control and detection unit 220, no further communication technology is required for the cross-system monitoring of the airspace, which has a positive effect on the weight of the second aircraft 210.

Furthermore, it is provided that the first data 130 is supplied with a time stamp during the transmission from the first control and acquisition unit 120. In this way, by comparing the time stamp with the actual time, it can be ensured that the first data 130 are up-to-date.

It is also provided that the first data 130 transmitted to the airspace monitoring system 300 and / or the data 310 transmitted by the airspace monitoring system 300 are stored in the airspace monitoring system 300. In this way, the flight route of the first aircraft 110 can be documented.

In order to meet the high security requirements of data transmission in air traffic, the first data 130 transmitted to the airspace monitoring system 300 and / or the data 310 sent by the airspace monitoring system 300 to the second control and acquisition unit 220 are encrypted. In this way, misuse of the first data 130 transmitted to the airspace monitoring system 300 and / or the data 310 transmitted by the airspace monitoring system 300 by unauthorized persons can be reduced.

In order to be able to assign the first data 130 to a specific first aircraft 110, the first aircraft 110 is identified by the airspace monitoring system 300. For this purpose, the first aircraft 110 has a machine-readable identifier 140 which, among other things, allows conclusions to be drawn about the operator of the first aircraft 110. The machine-readable identification 140 can preferably be a chip card integrated in the first aircraft 110, a SIM card or also a QR code. For this purpose, it is further provided that the first data 130 contain information from the machine-readable identification 140, so that the airspace monitoring system 300 can assign the first data 130 to the first aircraft 110.

For the legally secure assignment of the first data 130 to the first aircraft 110 or the operator of the first aircraft 110, it is also provided that the first data 110 transmitted to the airspace monitoring system 300 and / or from the airspace monitoring system 300 to the second control and acquisition unit 220 sent out data 310 are digitally signed. In this way, it is possible to draw conclusions about the operator of the aircraft 110 and thus a legally secure assignment of the first data 130 of the first aircraft 110 transmitted to the airspace monitoring system 300. The digital signature of the first data 110 is preferably carried out with a private key of the operator of the first aircraft 110. The first data 130 are particularly preferably digitally signed by the first control and acquisition unit 120 in relation to the first aircraft 110. The first data are particularly preferably signed by the airspace monitoring system with a private key assigned to the first aircraft. It is preferably provided that the first data 130 after the signature has been checked by the airspace monitoring system 300 is signed with a private key assigned to the airspace monitoring system 300. For this purpose, several first data 130 are combined in order to enable efficient data processing.

The present example is not limited to the case that the first aircraft 110 is a manned aircraft and the second aircraft 210 is an unmanned aircraft. It is also possible that the first aircraft 110 is an unmanned aircraft and the second aircraft 210 is a manned aircraft or the first aircraft 110 is an unmanned aircraft and the second aircraft 210 is an unmanned aircraft.

If the first aircraft 110 is an unmanned aircraft and the first control and acquisition unit 120 is a ground station and the second aircraft is a manned aircraft and the second control and acquisition unit 220 is a secondary radar system, comprising a secondary radar transmitter and a secondary radar receiver, the first data 130 of the first aircraft 110, which are preferably present as computer-readable data, are transmitted from the ground station 120 to the air surveillance system 300. In the airspace surveillance system 300, the first data 130 are transformed into data of the FLARM and / or ADS-B file format. The airspace surveillance system 300 sends the transformed data 310 based on the first data 130 to the second control and acquisition unit 220. The second control and acquisition unit 220 transmits the data 310 in FLARM and / or ADS-B file format to the second aircraft. The second aircraft can thus recognize the flight position and flight route of the first aircraft via the transformed data 310.

The Figure 2 It can be seen that in addition to transmitting the first data 130 of the first aircraft 110 from the first control and acquisition unit 120 to the airspace monitoring system 300, the second control and acquisition unit 220 transmits second data 230 to the airspace monitoring system 300.

Within the airspace surveillance system, the first data 130 and / or the second data 230 are transformed, merged and checked for collisions. Based on the first data 130 and the second data 230, data 310 are transmitted to the second control and acquisition unit 220 and from the second control and acquisition unit 220 onwards the second aircraft 210 forwarded. The first data 130 and the second data 230 are evaluated and checked in the air monitoring system 300. The second aircraft 210 therefore does not require any technology on board to evaluate the first data 130 from the first aircraft 110, which has a positive effect on the weight of the second aircraft.

The Figure 3 it can be seen that the airspace monitoring system 300 transmits data 310 to the second control and acquisition unit 220 and data 310 to the first control and acquisition unit 120.

The first data 130 and second data 230 transmitted to the airspace monitoring system 300 are transformed in the airspace and checked for collisions. Based on the checking of the first data 130 and the second data 230, data 310 are transmitted from the airspace monitoring system 300 to the first control and acquisition unit 120 and to the second control and acquisition unit 220. In this way, across systems, the first aircraft 110 is informed about the position and flight route of the second aircraft 210 and the second aircraft 210 about the position and flight route of the first aircraft 110. Both the first aircraft 110 and the second aircraft 210 can change the flight route in the event of an identified collision between the first aircraft 110 and the second aircraft 210. As a result of the fact that the collision check between the first aerial device 110 and the second aerial device takes place in the overhead system 300, neither the first aircraft 110 nor the second aircraft 210 requires the communication technology of the respective other aircraft.

In Figure 4 the machine-readable identification 140 is shown in the form of a QR code. In addition to a two-dimensional barcode 150, the machine-readable identification 140 also has an alphanumeric part 160, which provides information about the type of aircraft, contains a reference to the country of origin and has a character string for unambiguous identification.

Reference number

100

First control and monitoring system

110

First aircraft

120

First control and monitoring unit

130

First dates

140

Machine-readable identification

150

Two-dimensional barcode

160

Alphanumeric part

200

Second control and monitoring system

210

Second aircraft

220

Second control and monitoring unit

230

Second dates

300

Air surveillance system

310

Data

Claims (8)

1. Method for monitoring an airspace, comprising a first control and detection system (100) and a second control and detection system (200), wherein
   the first control and detection system (100) comprises a first aircraft (110) and a first control and detection unit (120), and the second control and detection system (200) comprises a second aircraft (210) and a second control and detection unit (220), wherein
   the first aircraft (110) is an unmanned aircraft,
   an airspace monitoring system (300) is provided, which is different from the first control and detection unit (120) and from the second control and detection unit (220),
   first data (130) relating to the first aircraft (110) are transmitted by the first control and detection unit (120) to the airspace monitoring system (300),
   second data (230) relating to the second aircraft (210) are transmitted by the second control and detection unit (220) to the airspace monitoring system (300),
   data (310) based on the first data (130) are sent by the airspace monitoring system (300) to the second control and detection unit (220),
   the data (310) are transmitted by the second control and detection unit (220) to the second aircraft (210),
   characterized in that
   the first data (130) from the first aircraft (110) and the second data (230) from the second aircraft (210) are checked by the airspace monitoring system (300) for a risk of collision and, if a risk of collision is ascertained, data are sent to the first control and detection unit (120) in order to specify a new flight route for the first aircraft (110), and
   the first aircraft (110) has a continuous connection to the first control and detection unit (120) and, if the continuous connection is lost, first data (130) relating to the loss of connection are transmitted by the first control and detection unit (120) to the airspace monitoring system (300), data (310) based on the first data (130) relating to the loss of connection are sent by the airspace monitoring system (300) to the second control and detection system (220), and the second aircraft (210) is informed about the loss of connection between the first aircraft (110) and the first control and detection unit (120) so that the second aircraft (210) can pay increased attention to the air traffic so as to be able to react quickly if a collision is to be expected.
2. Method according to claim 1, characterized in that the first data (130) transmitted to the airspace monitoring system (300) and/or the data (310) sent by the airspace monitoring system (300) to the second control and detection unit (220) are transformed in the airspace monitoring system (300).
3. Method according to any one of claims 1 to 2, characterized in that the first data (130) transmitted to the airspace monitoring system (300) and/or the data (310) sent by the airspace monitoring system (300) to the second control and detection unit (220) are stored in the airspace monitoring system (300).
4. Method according to any one of claims 1 to 3, characterized in that the first aircraft (110) is identified by the airspace monitoring system (300).
5. Method according to any one of claims 1 to 4, characterized in that the first data (130) transmitted to the airspace monitoring system (300) and/or the data (310) sent by the airspace monitoring system (300) to the second control and detection unit (220) are encrypted.
6. Method according to any one of claims 1 to 5, characterized in that, based on the first data (130), an area of the airspace on the flight route of the first aircraft (110) is reserved for the first aircraft (110) for a period of time in the airspace monitoring system (300).
7. Method according to any one of claims 1 to 6, characterized in that, based on the first data (130) for the first aircraft (110), permission to climb is sought and obtained for the first aircraft (110) via the airspace monitoring system (300).
8. Method according to any one of claims 1 to 7, characterized in that data (320) based on the second data (230) are sent by the airspace monitoring system (300) to the first control and detection unit (120).

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