EP2496992A2

EP2496992A2 - Training simulation system for drone systems

Info

Publication number: EP2496992A2
Application number: EP10776977A
Authority: EP
Inventors: André Scheufeld
Original assignee: Eurosimtec GmbH
Current assignee: Komp Andre
Priority date: 2009-11-02
Filing date: 2010-11-02
Publication date: 2012-09-12
Also published as: WO2011051501A2; DE102009051644A1; WO2011051501A3

Abstract

A training simulation system for a drone system comprises a trainer station (10) having a first output means (101, 102, 103), which is equipped to generate and show at least one current exterior view of the drone, a second output means (201, 202, 204, 204), which is equipped to show at least one current display of a ground station of the drone; and a first input means (20, 30), which is equipped to change a parameter of the drone simulation, wherein the training simulation system further comprises a first interface to a simulation means, which is equipped to simulate the physical properties of the drone, and a second interface to a ground control station, which is equipped to control the drone.

Description

Bedding simulation system for drone systems

The present invention relates to a drone system formation simulation system useful in the formation of drone controllers.

Unmanned aircraft are also commonly called drones. They are reusable flying objects that can be used for surveillance, reconnaissance, reconnaissance and armed with weapons in combat missions. The term "drone" is not limited to flying objects. So there are also ground, sea and submarine drones. All of these drones are used in military, intelligence and civilian areas. In the following, reference is made by way of example to flying drones. However, this is not a limitation with respect to other drone systems, in particular not with regard to ground, sea and submarine drones. A drone flies without a pilot on board and is either automated via a program or from the ground via a ground control station (BKS) Radio signals, or over

Satellite radio operated. Depending on the area of application and equipment drones can carry payloads, such. B. missiles for a military attack. Furthermore, the

Abbreviation UAV used for unmanned / uninhabited / unpiloted aerial vehicle for drones.

The operation of the drone in the ground station must of course be practiced and learned. It is advantageous to resort to simulations, so that no expensive device is compromised.

In view of the above, the present invention proposes

A drone system training simulation system according to claim 1. Further advantageous embodiments, details, aspects and features of the present invention

Invention will become apparent from the dependent claims, the description and the accompanying drawings. In the latter shows:

Fig. 1 is a training course according to an embodiment of the present invention.

Figure 2.1 is an illustration of the different speed requirements for the transmission of flight and control data between the ground control station and a real drone and between the drone simulation and the UAS-TS. Fig. 2.2 is a schematic representation of the connection of drone systems to UAS-TS.

Fig. 3.1 is a diagram of the components involved in the simulation and their interfaces.

Fig. 3.2 is a diagram of the components involved in the simulation and their interfaces.

Fig. 4.1 is a diagram of the components involved in the simulation and their

Communication in the UAS-TS prototype.

Fig. 4.2 is a diagram of the components involved in the simulation and their interfaces in the connection of the LUNA system.

Fig. 4.3 is a detailed representation of the communication between LUSiCo and the

Components of the ground control station LUNA.

Fig. 4.3 is a realized in the training simulation UAS-TS input mask of

Weather forecast for UAVs.

Fig. 4.4 a realized in the training simulation UAS-TS input mask of the error feed for UAVs.

The following abbreviations are used, the meaning of which is given here:

ABUL Automated image analysis using the example of UAV LUNA.

BG2001 HMI device integrated in the LUNA-BKS.

BKS ground control station

DataCenter interface between the LUSiCo and the LUNA UCS.

Downlink (radio) connection from the UAV to the BKS.

DV Digital Video.

GCSGate interface between the module for the flight calculation of the drone and the BKS.

IEEE 1394 standard of the bus interface FireWire. LSGate interface containing the data of the drone spez. Simulation in

Provides real-time.

LUNA reconnaissance drone (airborne unmanned reconnaissance equipment)

LUSiCo LUNA Simulation Core

LuSiCoGate interface between the LUSiCo and the LSGate.

RealtimeGate interface between the dronespec. Simul. of the manufacturer and

UAS-CG-LUNA.

RS-232 standard of the serial interface.

SDI Serial Digital Interface. Interface for the transmission of dig.

Video signals.

STANAG-4586 NATO Directive on communication between BKS and

Aircraft.

STANAG-4609 NATO Directive on Digital Image Transmission.

UAS Unmanned Aerial System. Unmanned aerial system.

UAS-CG-LUNA control and data interface between the UAS-TS and

LSGate.

UAS-TS Unmanned Aerial System - Training Simulation.

UAS-VG-LUNA UAS-TS video interface that provides an SDI signal

(SMPTE-259M).

UAV Unmanned Aerial Vehicle. Unmanned aerial vehicle.

UDP / IP Connectionless network protocol based on the

Internet Protocol (IP).

Uplink (radio) connection from the UCS to the UAV.

VideoGate interface for converting the SDI signal into a BKS compatible signal.

The present description relates to a training simulation system "Unmanned Aerial System - Training Simulation" (short UAS-TS) for a drone system, in particular for the drone system "Airborne unmanned Nahaufklärungs equipment" (LUNA short). The training system comprises an instructor workstation 10 shown in FIG. 1, which interfaces with a ground control station (BKS) for a drone and a

Simulation unit for the physical flight characteristics of the drone can be connected. The workplace includes two separable parts, namely one Worktable 50, which is mounted for example on lockable rollers, as well as a

Rear wall 60, which may also be designed rollable. The table unit 50 and the wall unit 60 are separable so that they are easier to transport. On the wall unit 60, two rows of monitors are mounted one above the other. In this case, the simulated drone is shown in an external view on three first monitors 101, 102, 103, so that the instructor sees the drone in their environment from different angles. Of course, this view is not available to the drone controller at the BKS, but only to the camera images supplied by the drone. These are also displayed to the instructor on the second monitor row on four monitors 201, 202, 203, 204. According to one embodiment, the four monitors are simply cloned by the B S to reduce the overhead. The cloned BKS screens not only allow the display of the camera images, but also all other data in the UCS (map, waypoints, telemetry, etc.). As a result, the instructor also has the opportunity to observe the inputs and interactions of the operator. The instructor station 10 further comprises an input unit, which according to the present embodiment, a

Touchpad 20 and a keyboard 30 includes. Via the touchpad 29 or via the keyboard 30, the instructor can cause certain scenarios or influence the simulation. Thus, for example, errors can be simulated via the touchpad 20, such as, for example, a telemetry failure, icing of the drone, non-triggering of the landing screen and the like. So there is an emergency checklist for drones, according to the most diverse

Disturbances in the operation of the drone detected and appropriate instructions are given. The training simulation system is set up to simulate all of these scenarios so that the operator crew of the drone can be trained for any emergencies. Furthermore, the instructor can specify a specific weather situation. This is typically done via the keyboard 30, as it may be better suited for fast input of complex data than the touchpad 20.

The training simulation system typically further includes a plurality of computers that may, for example, be located in a portable rack or at the workstation 10 itself. Typically, the training simulation system includes a datalink server that communicates with a physical simulation engine

Flight characteristics of the drone takes over. This connection is bidirectional, since the errors or scenarios entered by the instructor via the input means 20, 30 are addressed to the

Simulation must be transmitted. On the other hand, the unit delivers to Simulation of the physical flight characteristics of the drone only corresponding data that are visualized by the training simulation system. For this purpose, the terrain data of the deployment environment are stored in a database of the training simulation system. The database can be designed centrally or distributed over several computers. Typically, the database includes terrain data that includes a simulation of soil, air and water

Allow water units in the same simulation. The training simulation system further includes a video stream server interfaced with the UCS and transmitting the drone camera views generated by the simulation to the UCS. Finally, the training simulation system typically also includes an interface server that, for example, handles the input and output via the instructor location 10 input and output means.

The training simulation system may further include a debriefing interface that allows a debriefing of the training. Typically, the debriefing unit comprises a recording means on which the training session can be recorded. Furthermore, the debriefing unit comprises playback means for reproducing the recorded training session, the playback means typically being arranged to stop playback, rewind, rewind, jump, slow-track, etc. Typically, the debriefing unit comprises a conventional video recorder. Interface so that the recording can be played back on conventional media.

Furthermore, the training station 10 includes an input unit 40, which may also be configured as a touchpad. This unit 40, also referred to as Control Center, can control the functions of the training simulation system. In particular, Control Center 40 allows synchronized startup and shutdown of the entire training simulation system. The centralized control and display of the Control Center 40 ensures user-friendly operation and monitoring of the entire system. In particular, the status of the individual data links are displayed and logged so that malfunctions can be quickly detected and eliminated.

The training simulation system further includes an interface whose development is modular and conforms to existing standard protocols, on the one hand the To analyze complexity and on the other hand to enable the future extension of the interface. In particular, the STANAG guideline 4586 in version 2.5 is taken into account. This policy uniformly defines the interfaces, data and message formats used for communication. It gives manufacturers enough freedom to realize communication with the drone and at the same time offers you one

standardized frame. The modular layout of the interface enables the

uncomplicated connection of future drone systems. The communication resulting from the connection complies with existing STANAG guidelines. The description is structured as follows. The next section describes, on the one hand, general goals and framework conditions and, from a technical point of view, the necessary framework conditions. From these, the basic structure of the interface is derived in the following section, i. without focusing on a concrete drone system. Then, this interface is based on the connection of the

Drone system LUNA concretized as an exemplary embodiment. The following section presents the data to be transmitted between UAS-TS and the drone system resulting from the analysis of the requirements. The input mask for the transmission of the weather forecast for UAVs to the training simulation UAS-TS and a

Input mask for malfunctions of UAVs will be described below.

The connection of the training simulation system UAS-TS to a drone system should be carried out by means of a flexible and at the same time standardized interface. The interface complies with the STANAG 4586 standard. This allows an effective and at the same time cost and time-favorable connection. In addition, the interface is designed to allow the possibility of UAS-TS existing maps as well as satellite and overflight images

to be able to simulate realistic and realistic simulations of different training scenarios. This enables the realistic training of the UAV tax and the image evaluator. To elucidate the technical framework, the fundamental differences between the control of a real drone and the simulation of a drone are described. Figure 2.1. performs this schematically. In the control of a real drone, the telemetry and control data is typically transmitted at a relatively low frequency; typically one to five times a second. Only the transmission of the video signal, the cameras on board, is usually done frequently to allow a fluid representation of the area to be observed. When simulating a virtual drone in a training simulation, the current telemetry data of the drone, so the position, position and

Camera orientation data, also present with a very high relevance. Only in this way are the following three things guaranteed: a) the visual representation of the drone in the virtual world is fluid and free of interruptions; b) the simulation of the camera of the drone in the virtual world - and thus the simulated view through the camera - is fluid and free of interruptions. c) a physically correct calculation.

Points (b) and (c) are certainly more relevant from a training point of view, as it is desirable that trainees should (almost) find no difference between using a real drone and simulating this mission in the UAS-TS. As shown in Figure 2.1 above, the UAS-TS training simulation for each specific drone is associated with a specific drone flight calculation module that synthetically depicts the (largely physical) specifics of the drone. This UAS-dependent simulation consists of the following components: - on

Drone simulator or autopilot simulator; a physical simulator, since there is a close coupling with the autopilot simulator, whereby the physics simulator can also be outsourced to the UAS-TS; an antenna simulator; a landing net simulator; and interfaces to the UAS-TS.

Now we will briefly discuss the connection of other drone systems to the UAS-TS. At the same time, the modular and standard-compliant design of the interface enables uncomplicated connection of drone systems, which also communicate with the drone according to the STANAG guideline 4586. Therefore, the scenario shown in Figure 2.2 is feasible.

This section describes the basic layout of the interface based on the connection of the LUNA, which enables the uncomplicated connection of drone systems to the UAS-TS. Figures 3.1 and 3.2 show schematically the systems involved as well as their interfaces. For connecting drone systems, the UAS-TS Two STANAG-compliant interfaces are available. On the one hand, the "UAS-CG-LUNA" interface for bidirectional communication with the (synthetic) drone, which is designed in accordance with the STANAG-4586 protocol and primarily serves to transmit telemetry and configuration data from the drone to the UAS-TS. In the opposite direction, this interface is used to transmit simulation data to the drone - for example, the prevailing wind speed and wind direction.The unidirectional interface "UAS-VG-LUNA" follows the STANAG-4609 protocol and provides the

Video presentation of the UAS-TS simulation. Specifically, the camera signals of the drone cameras are transmitted here. These can be forwarded to external modules such as the ABUL system. At this point, it should again be emphasized that these two interfaces are independent of the drone used. To connect a specific drone system such as the LUNA system to the UAS-TS, two components have to be developed. On the one hand, the video signal of the UAS-TS simulation must be transmitted to the ground control station of the drone. This is u.U. a suitable one for converting the STANAG 4609 compliant video signal

Develop VideoGate. On the other hand, the characteristics of the drone must be simulated. This requires the development of a drone flight calculation module that simulates, among other things, the drone's physical (flight) characteristics. There is no direct communication between the UAS-TS and the ground control station of the drone. As explained earlier, the drone's liquid representation in the UAS-TS computed real-time 3D rendering requires a high rate of update of the drone's position and attitude data. These must be refreshed continuously at least every 20 milliseconds. In order to take this into account, despite the STANAG-compliant transmission of the drone's flight data towards UAS-TS, the so-called interface "RealtimeGate" is provided, which interpolates the data of the drone flight calculation between the time steps in order to enable a smooth and realistic simulation of the drone UAS-TS then accesses this gate through the STANAG-compliant UAS-CGLUNA Before, for the sake of completeness, a second possibility of connecting drone systems to the UAS-TS will be presented in the next section This connection, which is particularly conceivable if the drone manufacturer does not have his own simulation of the flight characteristics of the drone, so it is possible in the future without great effort to connect other drone systems to UAS-TS. Figure 4.1. shows the schematic structure of the embodiment of a connection of the UAS-TS to the drone system LUNA. The physical simulation of the LUNA was integrated. The LUNA Simulation Core (LUSiCo) is connected in accordance with Figure 3.1, which is known from the last section, and results in the structure shown in Figure 4.2. The following section describes the specific design of the interfaces UAS-CG-LUNA, LSGate and UAS-VG-LUNA. The subsequent section discusses the details of EMT's flight calculation of the drone.

The communication between LSGate and UAS-CG-LUNA is realized by DLL calls and callback functions. The programming language can be C ++ on both sides. The data transfer from LSGate to UAS-CG-LUNA is done by LSGate controlled by the following functions lsgateGetParameter and lsgateSetParameter. The first parameter specifies the addressed system by the assigned SystemID. Exactly _NumberOfParameter parameters are queried or set. For any natural number i between 0 and _NumberOfParameters, the following applies: The parameter _pParameterIDs [i] specifies the ID of the desired parameter. The parameter

_pParameterAddress [i] specifies the memory address under which the current value of the

Parameters are retrieved or stored by LSGate. The calling function has to ensure that sufficient memory is available. Finally, the function returns through an error code whether the call was successful. The LSGate module, on the other hand, ensures that all returned values are consistent with each other, thus providing the state of the simulation at a time step. Likewise, the thread safety is secured by the module LSGate.

Using the example of the parameter ID SYS_WIND_DIRECTION, the specified

Properties of the parameters are explained:

The indication of the wind direction is in radians and as floating point with double

Accuracy. Accordingly, allowable values of the parameter in the interval [0, 2pi). The value may be transmitted to LSGate by UAS-CG-LUNA and at least every 20ms An updated value is available for retrieval by the UAS-TS in the LSGate. During the simulation of LUSiCo triggered events - such as the definition of a new waypoint - are transmitted by LSGate by a callback function to UAS-CG-LUNA and thus to UAS-TS. For this purpose, a corresponding function pointer is transmitted to LSGate with the function lsgateSetEventCallback. The transmission of the video data through the interface "UAS-VG-LUNA" to the ground control station takes place analogue or digitally.In analogue transmission the digital STANAG-4609-compliant output video signal of the UAS-TS is first converted by the "VideoGate" into an analogue one and then fed into the integrated DV recorder in the ground station. From there it is passed on to the individual display elements. However, the entire distance from the UAS-TS to the display terminals of the ground control station can also be kept digital. This leads to increased image quality and fault tolerance.

Previously known systems only allow the formation of the controller, since a visualization of the images captured by the camera in the context of the existing simulation is not possible. The modular structure of the simulation environment UAS-TS now enables the connection of these existing simulations. Since this prevents the development of complex software modules, this represents the most cost-effective and time-saving solution (without complicating the subsequent connection of other drones). Nevertheless, adjustments to the existing simulation can not be completely avoided. Figure 4.3 shows the structure of the flight calculation module of the LUNA. The main part is taken by the LUNA simulation core LUSiCo (LUNA Simulation Core). This communicates STANAG 4586 compliant via the LUSiCoGate with the UAS-CG-LUNA and thus ultimately with the simulation UAS-TS. On the one hand, this interface enables the simulation of LUNA by UAS-TS to be highly controllable and, on the other hand, the sufficiently timely transmission of flight data to the UAS-TS. The actual simulation of the drone takes place in the LUSiCo through the modules "Physical Simulator (PSi)", "Autopilot Simulator (ApSis)", "Network Simulator (NGPS Simulation)", "Antenna Tracker Simulation". On the other hand, he connects to the ground control station via the DataCenter. The DataCenter thus connects LUSiCo with the emergency system, the control computer, the video computer and the

Card calculator.

The training simulation UAS-TS is especially designed for the training of drone and video operators. Therefore, after completed pre-flight check by The UAS-TS data entered by the operator are immediately displayed to the instructor. Since all characteristics of the drone that are relevant for the pre-flight check can be changed by the instructor, incorrect entries can be made during the flight

Preliminary check provoke and recognize. This affects both the pre-flight check of the card and the video computer and thus supports both the training of the controller and the image operator already in this early phase of the mission. By the

Transmission and visualization of extended telemetry data such as the engine speed and rudder deflection can theoretically also train the starter at the launch catapult. In addition to the simulation of the ordinary takeoff and drone flight - and thus the training to avoid exceptional situations caused by humans - the interface allows the trainer to feed in (technical) errors during the operation of the LUNA. This ranges from failures of the engine, or the GPS system to dangerous situations due to strong downdrafts and shadowing of the communication signal due to obstacles. For this purpose, Figure 4.4 shows an input mask for malfunctions of UAVs, via which the input, storage and the recall of the error injection for UAVs in the UAS-TS is realized. The current settings of the BG2001 HMI device are continuously transmitted to the UAS-TS simulation via the interface defined above and are thus also available to the instructor in real time. This also supports the training of the taxpayer. By setting the

Initial position and attitude of the drone are targeted training of given scenarios possible without having to go through the startup procedure. Likewise, the possibility of a temporary interruption of the simulation and later resumption by the instructor in the interface definition is included. Another innovation made possible by the introduction of the simulation environment UAS-TS is the training of the

Picture operators in the simulation. For this purpose, the relevant camera data, such as the orientation of the camera mode and the zoom level used are transmitted to the UAS-TS via the interface. The realistic simulation of the camera images generated by the LUNA makes it possible to effectively train the monitoring and reconnaissance situation.

According to a further embodiment, the training simulation UAS-TS allows the simulation of a configurable and based on the weather forecast for UAVs weather system. This allows the consideration of weather influences on the drone's flight and the observation of the terrain by the image operators. Where is the input, Storage and recall of the weather forecast for UAVs realized in the UAS-TS. Figure 4.3 shows the dedicated input mask. The color-coded fields can be edited as part of the UAS-TS.

Previously, the structure of the modular interface between the STANAG-compliant drone system LUNA and the training simulation UAS-TS was described. The data to be transferred and the interface based on it, which has been determined by the analysis, enable a realistic simulation of various application scenarios, including technical failures and weather-related extreme situations. The system allows the

Realistic training of the flight and image operator in the pre-flight and flight phase. Thanks to the modular design of the interface, it can be extended and completed at any time during the project (and beyond), as well as other (STANAG-compliant)

Drone systems are connected. Already in this early phase of the project the input of the weather forecast for UAVs is possible through one of these modeled input forms in UAS-TS.

The present invention has been explained with reference to exemplary embodiments. These embodiments should by no means be construed as limiting the present invention.

Claims

A drone system training simulation system comprising an instructor station (10) having first output means (101, 102, 103) arranged to generate and display at least one current external view of the drone, a second output means (201, 202, 203, 204) arranged to display at least one current indication of a ground control station of the drone; and first input means (20, 30) arranged to change a parameter of the drone simulation, the training simulation system further comprising a first interface to a simulation means adapted to simulate the physical characteristics of the drone and a second interface to a drone Ground control station, set up to control the drone.

The educational simulation system of claim 1, wherein the first input means comprises a touchpad (20) and / or a keyboard (30).

3. training simulation system according to spoke 1 or 2, the parameter that can be changed via the first input means includes: a weather condition, a technical error of the drone, a technical error of the ground control station, a fault of the radio connection between ground control station and drone, a flight situation and Combinations of the previous parameters.

The training simulation system according to any one of the preceding claims, further comprising a control unit configured to centrally control the training simulation system.

The training simulation system of claim 4, wherein the control unit comprises a second input unit configured to input control commands for the training simulation system.

The training simulation system according to claim 4 or 5, wherein the control unit is adapted to start-up and / or synchronously shut down the training simulation system.

The training simulation system of any one of claims 4 to 6, wherein the control unit is further configured to monitor and / or log the operating state of one or more functional units of the training simulation system.

The training simulation system of any one of the preceding claims, further comprising a debriefing unit configured to record and play back a simulated training session.