DE202015100823U1 - Navigation device for gliders - Google Patents

Abstract

Navigation device (10) for a glider (1) with
A position determination device (11) which is designed to determine position data (16) which describe the position of the glider (1) in three dimensions,
A target data memory (12), which is designed to store target data (17) of a target (2) to be applied to the glider (1),
A data processing device (15) which is designed to calculate display data (18) using the target data (17) and the position data (16) which describe the position of the glider (1),
A display (19) adapted to display the display data (18), and
A flight data receiving device (13) designed to receive flight data (9) from other gliders (8) which contain position data of the other gliders (8),
characterized in that the data processing means (15) is adapted to calculate the display data (18) using the flight data (9) of the other gliders (8) such that the display data (18) is the fastest flight route (7) from the current one Describe the position of the glider (1) to the approaching target (2).

Description

TECHNICAL FIELD OF THE INVENTION

The invention relates to a navigation device for a glider. In particular, the invention relates to a navigation device having the features of the preamble of independent patent claim 1.

STATE OF THE ART

When soaring, the airline between a current position and a target to be approached is almost always not the fastest flight route; H. the flight route that leads to the destination in no time. At least, this applies to the occurrence of side winds and inhomogeneously distributed up and down.

The pilot of a glider therefore seeks to detect the current air currents present in the potentially to-be-traversed area and to take these into account when planning his flight route. He also uses indirect evidence of the airflow conditions, such as general weather information, terrain formations and observed movements of other gliders. Finding the fastest route in this way, however, remains a matter of luck.

When multiple gliders fly in a team, individual pilots can try different routes to find the fastest one. The chance that the team's glider will find the fastest route, or at least a section of the fastest route, is much greater than that of a single glider. In order to find the continuation of such a fastest flight route, however, the team's various gliders must constantly fly different routes around the previous fastest flight route. Overall, finding the fastest route for a team of gliders is a complex task that is rarely resolved.

To determine the current position of a glider, it is known to apply satellite navigation. The altitude position of the glider can also be determined by satellite navigation and / or by barometric altitude measurement.

The use of navigation programs, for example, run on PDA or tablet computers, for navigation in gliding is known. Such programs typically include a destination data store for storing destination data of a destination to be served, and, for example, display the airline from the current location to that destination.

Under the FLARM brand, a glider collision avoidance system is known (see e.g. http://www.flarm.com/support/manual/FLARM_DataportManual_v6.00E.pdf ). A glider collision avoidance device implementing this system detects, by means of a GPS and a barometric sensor, the glider's current position describing position data and motion data. The future flight path of the glider is predicted and transmitted to gliders in the area. Conversely, such flight data is received by other gliders in the area. The collision avoidance device continuously checks the flight data of the respective glider and the other gliders for impending collisions. If a collision threatens, warning signals are issued to the pilot of the respective glider.

In principle, the flight data emitted by the known glider collision avoidance devices can also be received and evaluated by other devices with corresponding receivers. However, this possibility can be limited, for example, for gliding competitions. Then only the collision-relevant data between the individual collision warning devices are exchanged.

All components of a navigation device having the feature of the preamble of independent claim 1 protection are present in a glider, is navigated in the example, with a navigation program on a PDA and in the same time a known collision warning device is operated.

From the DE 20 2012 105 058 U1 For example, an aircraft navigation device for determining and displaying a vertical target flight plan from a current aircraft position to a predefined target position is known. This navigation device comprises a flight plan determining device for determining the vertical target flight plan and a navigation display for displaying the determined vertical target flight plan. The flight plan determining device is designed such that it determines in the vertical setpoint flight plan a plurality of setpoint speed setting positions at which the aircraft is preset a new setpoint speed in deviation from the current actual speed. With the known navigation device to the pilot of the aircraft as possible a noise-reduced or optimized in terms of noise approach of an airport or departure from an airport will be possible.

OBJECT OF THE INVENTION

The invention has for its object to provide a navigation device for gliders, which allows the pilot of the glider to reach a target to be reached in the shortest possible time.

SOLUTION

The object of the invention is achieved by a navigation device having the features of independent patent claim 1. The dependent claims 2 to 10 are directed to preferred embodiments of the navigation device according to the invention. The protection claim 11 relates to a glider with a navigation device according to the invention.

DESCRIPTION OF THE INVENTION

In a navigation apparatus for a glider according to the present invention, having position determining means determining position data describing the position of the glider in three dimensions, a target data memory storing target data of a glider-approaching target, a data processing means, the display data using the target data and the position data calculating the position of the glider, a display indicating the display data, and a flight data receiving device receiving flight data of other gliders comprising at least position data of the other gliders, the data processing device calculates the display data using the flight data of the other gliders so that the display data describe the fastest flight route from the current position of the glider to the approaching destination.

In the new navigation device, the other gliders are used as probes for the air flow conditions in the vicinity of the glider. It can be drawn from the traced flight data of other gliders not only current information about the air flow conditions, but also information about the temporal-spatial evolution of these air flow conditions. This information is used by the computing device to calculate the fastest flight route. It goes without saying that this is not necessarily the fastest flight route, but the route that is most likely the fastest on the basis of the available information.

This fastest flight route or instructions on how to comply with this fastest flight route are shown on the display showing the display data. If the pilot follows these instructions, he has a maximum chance of reaching the target in a very short time.

The other gliders whose flight data is used by the computing device to calculate the fastest glider flight route of the glider may be gliders of a group or of a team, including the glider. But it can also be all gliders, from which the respective glider receives flight data with its flight data receiving device. The amount of flight data received by each other glider may vary. So z. B. of gliders of other groups only rudimentary flight data available. Then only these rudimentary flight data can be taken into account, while from the other gliders of the same group more extensive flight data can be available, which include correspondingly more information with respect to the air flow conditions at the positions of the individual gliders.

In order for it to actually find the fastest flight path based on the flight data of the other gliders, the data processing device may be configured to continuously update an existing three-dimensional airflow map using the flight data of the other gliders or to first create and then continuously update a three-dimensional airflow map , This airflow map can then be used as the basis for calculating the display data describing the fastest flight route.

Alternatively or in combination with this approach based on an air flow card, the data processing device may be configured to continuously update an existing three-dimensional flight path map with flight time information using the flight data of the other gliders, or to first create and then continuously update a three-dimensional flight path map with flight time information , In such a flight route map, the flight time information refers to the times required to complete the mapped flight paths or certain sections of these flight paths. Based on such a flight path map, a common road navigation system can determine the fastest route because a common road navigation system is based on a corresponding route map with travel times. Especially if the Data processing device combines a flight path map with a Luftströmungskarte, can be exploited for determining the fastest route by the data processing device that a glider is not bound to certain flight paths and can specifically differ from the flight paths of the other gliders, for example, lying on these flight paths and by the Flight data of the other gliders indicated to bypass targeted unfavorable air currents or deliberately exploit next to the flight paths of the other gliders lying favorable air currents.

It goes without saying that the data processing device can also use other data than the target data, the position data which describe the position of the respective glider, and the flight data of the other gliders when calculating the display data. Thus, information from other sources about air flow conditions, general weather data, terrain deformation data and the like may also be considered. However, it is a core of the present invention, with the aid of the flight data available from the other gliders, to obtain only occasional but particularly meaningful information about the air flow conditions in the surroundings of the respective glider. The spatial gaps between the other gliders are at least partially closed by their movement and the evaluation of the flight data recorded over a longer period of time.

It is understood that the navigation device according to the invention not only calculates the fastest flight route once, but dynamically determines this fastest flight route, d. H. continuously adapts to the overall information about the currently prevailing air flows in the potentially to-be-traversed area.

It is also understood that when calculating the fastest flight route, the navigation device according to the invention can take into account the flight data of the respective aircraft as information about the air flow conditions at its position.

The data processing device can at the same time carry out an analysis of the flight data for imminent collisions, even with static obstacles, and possibly output collision warning signals. These functions can also be fulfilled by a completely or partially separate device in the glider.

The target data memory of the navigation device according to the invention may be designed to store target data of a static target, ie a location on the ground or a point above the ground defined on the ground, and / or a dynamic target. A dynamic target is to be understood in particular as a flying target, such as another glider or the center of gravity of a group of other gliders. In other words, it may be defined with the target data that the data processing device calculates the display data describing the fastest route to unlock to one or a group of other gliders.

The flight data receiving device of the navigation device according to the invention is preferably designed so that it can capture not only position data, but also movement data of the other aircraft as flight data of the other aircraft, so that as extensive flight data can be used by the data processing device in the calculation of the display data. However, if such additional movement data of the other aircraft are not available from the flight data receiver, for example because they are not transmitted by the other gliders, the data processing device may be configured to calculate movement data of the other gliders using the position data of the other gliders. Although in this way, for example, no relative speeds of the other gliders relative to the surrounding air, but nevertheless their relative speeds relative to the ground can be detected.

The data processing device is preferably also designed such that it calculates movement data of the glider using the position data which describe the position of the respective glider. This can be used, for example, to calculate the display data so that they describe the fastest flight path as a deviation from the current movement of the respective glider. This provides the pilot with clues as to how to get to the fastest flight route.

The data processing device of the navigation device according to the invention can also evaluate signals from motion sensors of the respective glider for determining the movement data of the glider. The motion sensors may be z. B are acceleration sensors and / or air speed sensors, which detect the relative speed of the glider in a certain direction relative to the surrounding air.

The position-determining device of the navigation device according to the invention can be used to determine the position data which the Describe the position of the respective glider, be trained using satellite navigation. The altitude can be determined by a barometric altitude measurement or supported.

Advantageous developments of the invention will become apparent from the claims, the description and the drawings. The advantages of features and of combinations of several features mentioned in the description are merely exemplary and can take effect alternatively or cumulatively, without the advantages having to be achieved by embodiments according to the invention. Without altering the subject matter of the attached claims, the following applies with respect to the disclosure content of the original application documents and the utility model: Further features can be found in the drawings - in particular the geometries shown and the relative dimensions of several components relative to one another and their relative arrangement and operative connection. The combination of features of different embodiments of the invention or of features of different protection claims is also different from the chosen relationships of the protection claims possible and is hereby stimulated. This also applies to those features which are shown in separate drawings or are mentioned in their description. These features can also be combined with features of different protection claims. Likewise, features listed in the claims for further embodiments of the invention can be omitted.

The features mentioned in the claims and the description are to be understood in terms of their number that exactly this number or a greater number than the said number is present, without requiring an explicit use of the adverb "at least". For example, when talking about an element, it should be understood that there is exactly one element, two elements or more elements. These features may be supplemented by other features or be the only characteristics that make up the product in question.

The reference numerals contained in the claims do not represent a limitation on the scope of the protected by the claims objects. They only serve the purpose of making the protection claims easier to understand.

BRIEF DESCRIPTION OF THE FIGURES

The invention is explained in more detail below with reference to an embodiment with reference to the accompanying drawings and described.

1 schematically shows a glider, a target to be approached by the glider and several other gliders in the area; and

2 FIG. 12 is a block diagram of a navigation apparatus for flying with a glider according to FIG 1 to reach the target on the fastest route.

DESCRIPTION OF THE FIGURES

1 illustrates very schematically a glider 1 that's a goal 2 flies to. To this goal 2 In the shortest possible time, it usually does not make sense to the crow flies 3 between the current position of the glider 1 and the goal 2 to follow, because occurring air currents are to be considered. Such air currents are symbolic here with arrows for crosswinds 4 and directional symbols for updrafts 5 and downdrafts 6 indicated. The present invention thus addresses a fastest flight route from the current position of the glider 1 to the target 2 find. She uses other gliders 8th in the vicinity of the glider 1 out, as well as the glider 1 flight data 9 send out a warning about collisions between the gliders 1 . 8th to enable. The invention uses this flight data 9 to adjust the airflow conditions between the current position of the glider 1 and the target 2 and their temporal-spatial development to capture and from this the fastest flight route 7 to calculate.

2 shows a block diagram of a navigation device provided by the present invention 10 , The navigation device 10 includes a position determination device 11 , in particular by satellite navigation, but also using barometric altitude measurement, the current position of the glider 1 according to 1 certainly. Furthermore, the navigation device comprises 10 a destination datastore 12 , in the target data of the target 2 according to 1 get saved. Instead of a static goal 2 as in 1 , it is also possible to store data of a dynamic destination, for example one of the other aircraft 8th or a center of gravity between several of the other aircraft 8th , Furthermore, the navigation device has a flight data reception device 13 for receiving the flight data 9 from the other gliders 8th on. The flight data receiving device may be part of a collision warning device 14 be, which also includes the flight data 9 of the glider 1 sends out and the flight data 9 Overall, it monitors for a collision between the gliders 1 . 8th threatens and possibly warns against it. A data processing device 15 the navigation device 10 evaluates the position data 16 from the position-determining device 11 , the target data 17 from the destination datastore 12 and the flight data 9 the other gliders from the flight data receiving device 13 off to display data 18 to calculate the fastest flight route 7 according to 1 describe. This display data 18 be on a display 19 displayed, for example in the form of a deviation 20 from the current movement of the glider 1 , The current movement of the glider 1 can from the position data 16 be derived. It can also signals 21 of one or more motion sensors 22 of the glider 1 be evaluated. The motion sensor 22 For example, it may be an accelerometer or an airspeed meter. The pilot of the glider 1 is from the navigation device 10 on the fastest flight route 7 according to 1 guided and reaches the goal 2 in no time.

The navigation device 10 can be a pilot of a glider 1 z. B. in a gliding competition support. In a gliding competition with regatta start is with the help of the navigation device 10 However, the advantage that can be achieved is essentially limited to making it easier to connect to the field of the participants, since there is little available for the airspace in front of this field and no flight data in front of the leading participant. This applies at least insofar as the same airspace is not flown through again in a short time interval.

LIST OF REFERENCE NUMBERS

1

 glider

2

 aim

3

 crow

4

 crosswind

5

 upwind

6

 downdraft

7

 fastest flight route

8th

 glider

9

 flight data

10

 navigation device

11

 Location facility

12

 Target data store

13

 Flight data receiving device

14

 Collision warning device

15

 Data processing device

16

 position data

17

 target data

18

 display data

19

 display

20

 deviation

21

 signal

22

 motion sensor

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202012105058 U1 [0010]

Cited non-patent literature

• http://www.flarm.com/support/manual/FLARM_DataportManual_v6.00E.pdf [0007]

Claims (13)

Navigation device ( 10 ) for a glider ( 1 ) with - a position determining device ( 11 ) used to determine positional data ( 16 ), which shows the position of the glider ( 1 ) in three dimensions, is designed, - a target data memory ( 12 ), which is used to store target data ( 17 ) one with the glider ( 1 ) of the target ( 2 ), - a data processing device ( 15 ), which is designed to work using the target data ( 17 ) and the position data ( 16 ), which shows the position of the glider ( 1 ), display data ( 18 ), - a display ( 19 ), which is used to display the display data ( 18 ), and - a flight data reception device ( 13 ) used to receive flight data ( 9 ) of other gliders ( 8th ), which position data of the other gliders ( 8th ), characterized in that the data processing device ( 15 ) is adapted to the display data ( 18 ) using the flight data ( 9 ) of the other gliders ( 8th ) so that the display data ( 18 ) the fastest flight route ( 7 ) from the current position of the glider ( 1 ) to the target ( 2 ). Navigation device ( 10 ) according to claim 1, characterized in that the target data memory ( 12 ) for storing target data ( 17 ) of a static target ( 2 ) and / or a dynamic target. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is configured to use the flight data ( 9 ) of the other gliders ( 8th ) create and / or update a three-dimensional airflow map and display data ( 18 ) using this airflow chart. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is configured to use the flight data ( 9 ) of the other gliders ( 8th ) create and / or update a three-dimensional flight path map with time-of-flight information and display data ( 18 ) using this flight route map. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the flight data reception device ( 13 ) for receiving flight data ( 9 ) of other gliders ( 8th ), the movement data of the other gliders ( 8th ). Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is adapted to use the position data of the other gliders ( 8th ) Movement data of the other gliders ( 8th ) to calculate. Navigation device ( 10 ) according to claim 5 or 6, characterized in that the data processing device ( 15 ) is adapted to the display data ( 18 ) using the movement data of the other gliders ( 8th ) to calculate. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is configured to use the position data ( 16 ), which shows the position of the glider ( 1 ), motion data of the glider ( 1 ) to calculate. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is designed to operate using signals ( 21 ) at least one motion sensor ( 22 ) of the glider ( 1 ), Movement data of the glider ( 1 ) to calculate. Navigation device ( 10 ) according to one of the preceding claims, characterized in that the data processing device ( 15 ) is adapted to the display data ( 18 ) to calculate the fastest flight path ( 7 ) as a deviation ( 20 ) of the current movement of the glider ( 1 ). Navigation device ( 10 ) according to one of the preceding claims, characterized in that the position-determining device ( 11 ) for determining the position data ( 16 ), which shows the position of the glider ( 1 ), is formed using satellite navigation. Navigation device ( 10 ) according to claim 11, characterized in that the position-determining device ( 11 ) for determining the position data ( 16 ), which shows the position of the glider ( 1 ), is formed using barometric altitude measurement. Glider ( 1 ) with a navigation device ( 10 ) according to any one of the preceding claims.

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