EP1946284A1 - Method for optimising the display of data relating to the risks presented by obstacles - Google Patents

Abstract

The invention relates to a method for optimising the display of data relating to the risks presented by obstacles. Said method comprises the following steps: a list of obstacles included in the geographical area defined by the range, orientation and position of the aircraft is extracted from a database of the obstacles; information lists and warnings relating to obstacles are received; the obstacles in the list of obstacles are filtered and regrouped by the application of criteria relating to: the proximity of the obstacles to the aircraft, the proximity of the obstacles in relation to each other, and the warning level thereof; and the imaging adapted to the display of the obstacles is generated. The invention can be especially applied to the optimisation of the display of warnings relating to the risks of collision with scattered or linear obstacles.

Description

 Method for optimizing the display of data relating to the risks related to obstacles.

The invention relates in particular to a method of optimizing the display of data relating to the risks associated with obstacles. In particular, the invention applies to the optimization of the display of the alerts relating to the risk of collision with point or linear obstacles taking into account the trajectory of the aircraft and the altitude of the obstacles.

Among the risks that an aircraft must be able to cope with, there is a category of accidents referred to as Controlled Flight Into Terrain (CFIT). This category includes accidents in which a navigable aircraft under the control of its crew unintentionally collides with terrain, obstacles or a body of water without the crew being aware of the imminence of the collision.

To limit the risk of accidents with impact without loss of control, new monitoring instruments have been developed. In particular, the Terrain Awareness and Warning System (Terrain Awareness and Warning System) can be cited. A terrain knowledge and warning system may include a display device to alert the crew of the aircraft of potential risks related to terrain. Generally, the different areas of the terrain overflown are displayed with a color code on a navigation screen. Areas with no particular hazard for the aircraft are displayed in black, areas with low risk in green, areas with medium risk in yellow, and areas with high risk in red.

Field knowledge and warning systems can also be supplemented by a collision prediction function with obstacles, such as for example man-made obstacles of the electric lines type or of the high-rise constructions type. The crew of the aircraft must therefore have a means to become aware of the obstacles in the environment of the aircraft in addition to information on the corresponding terrain. Alerts of different levels are likely to be generated for each obstacle presenting a risk for the aircraft by the function of predictions of collision with obstacles. These alerts must also be able to be communicated to the crew by a given interface.

However, it is essential to optimize the number and the relevance of the information transmitted to the crew of the aircraft. This is particularly true for obstacle information and alerts. Indeed, the number of obstacles in certain geographical areas is potentially high. It is therefore useless or dangerous to overwhelm the crew with redundant and / or unusable information because of their large number.

The purpose of the invention is in particular to overcome the aforementioned drawbacks. To this end, the subject of the invention is a method for optimizing the display of data relating to the obstacles receiving the information necessary for the definition of the zone comprising the obstacles to be displayed. The method comprises the following steps:

- extraction from a database of obstacles, a list of obstacles included in the geographical area defined by the scope, orientation and position of the aircraft;

receiving an information list and an obstacle alert list generated by an obstacle collision prediction device and alerts;

- filtering and grouping of obstacles in the list of obstacles by applying criteria to the obstacles relating to: o the proximity of obstacles to the aircraft; o the proximity of obstacles between them; o their alert level;

- generation of symbology adapted to the display of obstacles.

In one embodiment, the filtering and grouping step includes a step of filtering the obstacles according to the elevation where a list of obstacles filtered according to their elevation is constructed with the set of obstacles present in the obstacle list of which the elevation is less than the display threshold received among the information. The filtering and grouping step may notably comprise a filtering step. Said filtering step comprises for example the following steps: a step of initializing a variable n to the value of the smallest possible position of an obstacle in the obstacle list filtered according to their elevation; an obstacle extraction step O (n) whose position in the obstacle list filtered according to their elevation is equal to n; a step of initializing a variable p, fixed to a unit;

a step of extracting the obstacle O (n + p) whose position in the list of obstacles filtered according to their elevation is equal to n + p.

a step of comparing the distance d (O (n), O (n + p)) between the obstacle O (n) and the obstacle O (n + p) with the minimum distance D: o if the distance d (O (n), O (n + p)) is greater than or equal to the minimum distance D, a step of incrementing the index p of one unit is carried out; o if the distance d (O (n), O (n + p)) is less than the minimum distance D, we go to a search step; the search step in the list of alerts of the alert level A (O (n)) relating to the obstacle O (n) and the alert level A (O (n + p)) relative to the obstacle O (n + p): o if the alert level A (O (n)) is higher than the alert level A (O (n + p)), we proceed to a step of removing the obstacle

O (n + p); o if the alert level A (O (n)) is lower than the alert level O (n + p), we go to a step of removing the obstacle O (n); o if the alert level A (O (n)) is equal to the alert level

A (O (n + p)) goes to a comparison step;

the step of comparing the horizontal distance d (O (n)) with respect to the aircraft of the obstacle O (n) and the horizontal distance d (O (n + p)) with respect to the aircraft from the obstacle O (n + p): o if the horizontal distance d (O (n)) is greater than the horizontal distance d (O (n + p)), we go to a step of removing the obstacle We) ; o if the horizontal distance d (O (n)) is less than the horizontal distance d (O (n + p)), we go to a step of removing the obstacle O (n + p); the step of removing the obstacle O (n + p) from the filtered list of obstacles, the step being followed by the step of incrementing the index p;

the step of removing the obstacle O (n) from the filtered list of obstacles, the step being followed by a step of incrementing the variable n; the step of incrementing the variable n by one unit, the step being followed by a step of verifying the existence of the obstacle O (n); the step of verifying the existence of the obstacle O (n) exists in the list of obstacles filtered according to their elevation: o if the obstacle O (n) exists, we go back to the step of initialization of a variable p; o if the obstacle O (n) does not exist, we go to a step marking the end of the filtering process according to the proximity of the obstacles; The list of obstacles filtered in the state where it is in the check step of the existence of the obstacle O (n) is transmitted as a filtered obstacle list. The minimum distance D between two displayed obstacles can for example be calculated by dividing the maximum range relative to the aircraft of the data to be displayed by a coefficient k. At the end of step (22) can be introduced a test step (24) checking whether the absolute value of the difference between the latitude of the obstacle O (n + p) and the latitude of the obstacle O (n) is less than a minimum distance D:

if yes, then we go to the step of comparing the distance d (O (n), O (n + p));

- In the opposite case, we go to the step of incrementing the index p.

Advantageously, the step of generating the symbology adapted to the display of the obstacles comprises:

a step of processing the display of the alerts relating to the obstacles, the linear obstacles included in the filtered obstacle list being treated as a list of one-off obstacles, the ends of the one-off obstacles with which alerts are associated being treated as spot obstacles with an alert at the same level as the linear obstacle, the obstacle being displayed in the same color as the corresponding terrain alert; a step of processing the display of the representation of the obstacles, a different symbol being attached according to whether the obstacle is multiple or not.

One of the advantages of the invention is that it ensures safe vertical separation of obstacles, particularly during the landing phases, thus ensuring that the crew has a good knowledge of the situation. The invention may furthermore be integrated with a system of field knowledge and alerts.

Other characteristics and advantages of the invention will become apparent with the aid of the following description made with reference to the appended drawings which represent:

FIG. 1, a system for filtering and displaying information and alerts for obstacles according to the invention;

FIG. 2, an obstacle filtering method according to the invention that can be implemented in the obstacle filtering device according to the invention;

FIG. 3, a filtering method according to the proximity of the obstacles according to the invention;

• Figure 4, a barrier display processing method according to the invention, which can be implemented in the obstacle treatment device according to the invention.

FIG. 1 illustrates a system for filtering and displaying information and alerts for obstacles according to the invention.

A Terrain Awareness and Warning System (Terrain Awareness and Warning System) is an instrument that can be embarked on board an aircraft. It includes a topographic database on the terrain of embarked land. A topographical database of obstacles can in particular, to supplement the existing data included in the topographical database on terrain relief. An obstacle can be a so-called punctual obstacle if it is restricted to a limited geographical area. A punctual obstacle can be described in particular by its latitude, longitude and height, for example a height expressed above sea level (or the English expression Above mean sea level height). To this we can add the precision of each of its coordinates and possibly its horizontal extension. An area of uncertainty corresponds to a disk centered on a point obstacle of radius equal to the value of the uncertainty on the coordinates in longitude and latitude of the obstacle. An obstacle can still be a so-called linear obstacle if it stretches over a large geographic area. A linear obstacle can be represented by a list of point obstacles. The ends of a linear obstacle can be represented by point obstacles. In FIG. 1, the system for filtering and displaying information and alerts for obstacles according to the invention comprises in particular an obstacle extraction device 2, an obstacle filtering device 5 and a processing device. the display of information and alerts for obstacles 6. The system for filtering and displaying information and alerts for obstacles according to the invention can be coupled with:

a terrain warning device 4, generally included in a terrain knowledge and warning system;

- a database of obstacles 1; A device for predicting collision with an obstacle and warning 3. The terrain warning device 4 provides the obstacle extraction device 2 with a range and an orientation defining the zone comprising the obstacles to be displayed. This range is for example the range selected by the crew for the navigation screen where the data relating to the obstacles must be displayed. This navigation screen can notably be included in the terrain warning device 4. The obstacle extraction device 2 extracts from the obstacle database 1 the list of obstacles included in the geographical area defined by the range, the orientation and position of the aircraft. The system for filtering and displaying information and alerts for obstacles according to the invention can notably manage several display devices at the output. Also, a list of obstacles is extracted by the obstacle extraction device 4, for each display device managed, with scope and orientation parameters specific to each.

The obstacle filtering device 5 receives the list of obstacles extracted by the obstacle extraction device 2. The obstacle filtering device 5 also receives from the terrain warning device 4 a display threshold corresponding to the elevation minimum below which terrain or obstacle information should not be displayed. The obstacle filtering device 5 further receives from the obstacle collision prediction device and alerts 3 a list of obstacle alerts. The obstacle filtering device 5 filters the list of obstacles extracted by the obstacle extraction device 2:

- according to the elevation of obstacles compared to the display threshold;

- according to the proximity of the obstacles and their level of alert. The obstacle filtering device 5 generates a list of obstacles to be displayed.

The obstacle display processing device 6 receives the list of obstacles to display from the obstacle filtering device 5. Depending on the parameters relating to an obstacle, the obstacle display processing device 6 has the function, in particular, of generation of the adapted symbology.

FIG. 2 illustrates an obstacle filtering method according to the invention that can be implemented in the obstacle filtering device according to the invention. Elements identical to the elements already presented bear the same references.

The obstacle filtering method according to the invention receives an obstacle list 10. This obstacle list 10 may in particular be provided by an obstacle extraction device 2. The obstacle filtering method also receives a terrain warning device 4 information 11 including the display threshold corresponding to the minimum elevation below which the information relating to the grounds or obstacles should not be displayed. The obstacle filtering device 5 further receives from the obstacle collision prediction device and alerts 3 a list of alerts 12 relating to obstacles. The collision prediction device with an obstacle and alert 3 can generate different alerts depending on:

- the level of risk of the situation in which the aircraft is located and - a minimum clearance distance of an obstacle (or the English expression Minimum Obstacle Clearance Distance) defined as the vertical safety distance between the aircraft and an obstacle. This distance is chosen in particular according to the characteristics of the aircraft and the standards in force. The generated alerts can for example be divided into three categories:

- warning against an obstacle (or the English expression Obstacle Caution);

warning against an obstacle (or the English expression Obstacle Warning); - avoidance warning of an obstacle (or in the Anglo-Saxon term Avoid Obstacle).

The obstacle filtering method according to the invention comprises in particular a step 16 for filtering obstacles according to the elevation. A list of obstacles filtered according to their elevation 13 is constructed with all the obstacles present in the obstacle list 10, the elevation of which is lower than the display threshold received among the information items 1 1. The elevation may especially be expressed above sea level (or Above mean sea level height). The list of obstacles filtered according to their elevation 13 is then transmitted to a filtering step according to the proximity of the obstacles. When several obstacles are too close to each other to be displayed correctly and distinctly, it is useful to display only one obstacle known as multiple obstacle. Step 15 is therefore particularly intended to produce a filtered list of obstacles 14 output with obstacles and multiple obstacles when necessary.

FIG. 3 shows a filtering method according to the proximity of the obstacles according to the invention. This filtering method can notably be implemented in step 15 of the obstacle filtering method described in FIG. 2. The elements identical to the elements already presented bear the same references.

Among the parameters used by the filtering method according to the proximity of the obstacles is a minimum distance D between two obstacles displayed. The minimum distance D can further be calculated by dividing the display range by a coefficient k. The coefficient k may for example be chosen equal to 40, or take any other value depending on the desired display.

The filtering method according to the proximity of the obstacles starts at a step 20 where the variable n is set to 1 (or 0 if the first index of the obstacle list filtered according to their elevation 13 is equal to 0). In a step 21, the obstacle noted O (n) (that is to say the obstacle whose position in the obstacle list filtered according to their elevation 13 is equal to n) is extracted from the filtered obstacle list according to their elevation 13 and the variable p is set to 1. The obstacle noted O (n + p) whose position in the list of obstacles filtered according to their elevation 13 is equal to n + p is then extracted in a step 22. .

A test 24 attempts to verify whether the absolute value of the difference between the latitude of the obstacle O (n + p) and the latitude of the obstacle O (n) is less than the minimum distance D: is not the case, the index p is incremented by 1 in a step 25; then in a step 23 it is checked whether the obstacle O (n + p) exists in the list of obstacles filtered according to their elevation 13 If the obstacle O (n + p) exists, go back to step 22. If the obstacle O (n + p) does not exist, proceed to a step 31 described later. - If so, go to step 26.

The test step 24 makes it possible to optimize the performance of the filtering method according to the proximity of the obstacles. However, in one embodiment, the test step 24 may be deleted. In this case, step 22 is then followed by step 26. Step 26 compares the distance d (O (n), O (n + p)) between the obstacle

O (n) and the obstacle O (n + p) with the minimum distance D. If the distance d (O (n), O (n + p)) is greater (or even equal) than the minimum distance D we pass in step 25. If the distance d (O (n), O (n + p)) is smaller than the minimum distance D, go to step 27. Step 27 searches the alert list 12 for the alert level relating to the obstacle O (n) and the obstacle O (n + p). The alert level of the obstacle O (n) is denoted by A (O (n)). The alert level of the obstacle O (n + p) is denoted by A (O (n + p)). If the alert level relating to the obstacle O (n) is greater than the alert level relating to the obstacle O (n + p), a step 28 is taken. If the alert level relating to the obstacle O obstacle O (n) is lower than the alert level relative to the obstacle O (n + p), we go to a step 30. If the alert level relating to the obstacle O (n) is equal to alert level for the obstacle O (n + p), step 29 is carried out. Step 29 compares the horizontal distance d (O (n)) with respect to the aircraft of the obstacle O ( n) and the horizontal distance d (O (n + p)) with respect to the aircraft from the obstacle O (n + p). If the horizontal distance d (O (n)) is greater than the horizontal distance d (O (n + p)), go to step 30. If the horizontal distance d (O (n)) is less than horizontal distance d (O (n + p)), go to step 28.

Step 28 removes the obstacle O (n + p) from the filtered obstacle list 13. Step 28 is followed by step 25.

Step 30 removes the obstacle O (n) from the list of filtered obstacles 13. Step 30 is followed by a step 31. Step 31 increments the variable n by 1. Step 31 is followed by step 32.

Step 32 checks whether the obstacle O (n) exists in the list of obstacles filtered according to their elevation 13. If the obstacle O (n) exists, we go back to step 21. If the obstacle O (n) does not exist, proceed to a step 33 marking the end of the filtering process according to the proximity of the obstacles. The filtered obstacle list in the state where it is in step 32 is transmitted as a filtered obstacle list 14

FIG. 4 illustrates an obstacle display processing method 6 according to the invention that can be implemented in the obstacle processing device according to the invention. Elements identical to the elements already presented bear the same references.

The filtered obstacle list 14 resulting from a filtering method according to the proximity of the obstacles is received at the input of a step 40 for processing the display of obstacle alerts. Linear obstacles included in the filtered obstacle list 14 are treated as a list of one-off obstacles. If an alert is associated with a linear obstacle, the point obstacles representing the ends of said linear obstacle are treated as point obstacles having an alert of the same level as the linear obstacle. When an obstacle of the filtered obstacle list 14 has an associated alert, step 40 of processing the display of obstacle alerts ensures that the obstacle is displayed in the same color as the field alert. corresponding. When an obstacle in the filtered obstacle list 14 does not have an associated alert, step 40 of processing the obstacle alert display ensures that the obstacle is displayed in the same color as the corresponding field.

In a step 41 of processing the display of the obstacle representation, a different symbol is attached depending on whether the obstacle is multiple or not. For example, a multiple obstacle may be represented by a symbol with several colored triangles in perspective while the other obstacles may be represented by a colored triangle.

At output 42, the symbols to be displayed are sent to the different navigation screens. The output 42 can in particular respect the Arinc708 protocol.

Claims

1. A method of optimizing the display of data relating to the obstacles receiving the information necessary for the definition of the area comprising the obstacles to be displayed, characterized in that it comprises the following steps: extraction (2) from a database of obstacles (1), a list of obstacles (10) included in the geographical area defined by the scope, orientation and position of the aircraft;

receiving an information list (11) and a list of alerts (12) relating to obstacles generated by an obstacle collision prediction and warning device (3);

- filtering and grouping (5) the obstacles in the list of obstacles (10) by applying to the obstacles criteria relating to: o the proximity of obstacles to the aircraft; o the proximity of obstacles between them; o their alert level;

generation (6) of the symbology adapted to the display of obstacles.

2. Method according to claim 1 characterized in that the step of filtering and grouping (5) comprises a step (16) filtering obstacles according to the elevation where a list of obstacles filtered according to their elevation (13) is constructed with all the obstacles present in the obstacle list (10) whose elevation is lower than the display threshold received among the information items (11).

3. Method according to claim 2 characterized in that the filtering step and grouping (5) comprises a step (15) of filtering, said filtering step (15) comprising the following steps:

a step (20) of initializing a variable n to the value of the smallest possible position of an obstacle in the filtered obstacle list according to their elevation (13); a step (21) for extracting the obstacle O (n) whose position in the obstacle list filtered according to their elevation (13) is equal to n; a step (21) for initializing a variable p, set to one unit; a step (22) for extracting the obstacle O (n + p) whose position in the list of obstacles filtered according to their elevation (13) is equal to n + p.

a step (26) of comparing the distance d (O (n), O (n + p)) between the obstacle O (n) and the obstacle O (n + p) with the minimum distance D: o if the distance d (O (n), O (n + p)) is greater than or equal to the minimum distance D, then step (25) of incrementing the index p of one unit is carried out; o if the distance d (O (n), O (n + p)) is less than the minimum distance D, a search step (27) is carried out; step (27) of searching in the alert list (12) of the alert level A (O (n)) relating to the obstacle O (n) and the alert level A (O (n) + p)) relating to the obstacle O (n + p): o if the alert level A (O (n)) is higher than the alert level A (O (n + p)), we go to a step (28) of removing the obstacle O (n + p); o if the alert level A (O (n)) is lower than the alert level O (n + p), a step (30) is taken to remove the obstacle O (n); o if the alert level A (O (n)) is equal to the alert level A (O (n + p)), a comparison step (29) is carried out;

step (29) of comparing the horizontal distance d (O (n)) with respect to the aircraft of the obstacle O (n) and the horizontal distance d (O (n + p)) with respect to the aircraft of the obstacle O (n + p): o if the horizontal distance d (O (n)) is greater than the horizontal distance d (O (n + p)), we go to a step (30) removing the obstacle O (n); o if the horizontal distance d (O (n)) is smaller than the horizontal distance d (O (n + p)), we go to a step (28) of removing the obstacle O (n + p); step (28) of removing the obstacle O (n + p) from the list of filtered obstacles (13), step (28) being followed by step (25) of incrementing the index p;

step (30) of removing the obstacle O (n) from the list of filtered obstacles (13), the step (30) being followed by a step (31) of incrementing the variable n; the step (31) of incrementing the variable n by one unit, the step (31) being followed by a step (32) of verifying the existence of the obstacle O (n); the step (32) of verifying the existence of the obstacle O (n) exists in the list of obstacles filtered according to their elevation (13): o if the obstacle O (n) exists, we pass again in step (21) of initialization of a variable p; o if the obstacle O (n) does not exist, we go to a step (33) marking the end of the filtering process according to the proximity of the obstacles; the list of obstacles filtered in the state where it is in the obstacle checking step (32) O (n) is transmitted as a filtered obstacle list (14).

4. Method according to the preceding claim characterized in that the minimum distance D between two displayed obstacles is calculated by dividing the maximum range relative to the aircraft data to be displayed by a coefficient k.

5. Method according to any one of claims 3 to 4 characterized in that at the end of step (22) is introduced a test step (24) verifying if the absolute value of the difference between the latitude of the obstacle O (n + p) and the latitude of the obstacle O (n) is less than a minimum distance D:

if yes, then we go to step (26) for comparing the distance d (O (n), O (n + p));

- Otherwise, we go to step (25) incrementation index p.

6. Method according to any one of claims 3 to 5 characterized in that the step of generating (6) the symbology adapted to the display of obstacles comprises: a step (40) of processing the display of alerts obstacles, with the linear barriers included in the filtered obstacle list (14) being treated as a list of point obstacles, the extremities of the point obstacles with which they are associated; alerts being treated as one-off obstacles having an alert of the same level as the linear obstacle, the obstacle being displayed in the same color as the corresponding terrain alert; a step (41) for processing the display of the obstacle representation, a different symbol being attached depending on whether the obstacle is multiple or not.