FR3108082A1 - Signaling the presence of a vehicle near a foggy area - Google Patents

Abstract

The invention relates to a method and a device (110) for controlling a vehicle (100). If an area of fog (140) is detected in the environment of the vehicle, at least two distinct presence signaling means (101; 102; 103) are activated. FIG. 1

Description

Signaling of the presence of a vehicle near a foggy area

The present invention belongs to the field of controlling the signaling of a vehicle in driving situations where visibility is poor. It relates in particular to a method and a device for controlling the presence signaling of a vehicle.

It is particularly advantageous in a driving situation where the vehicle crosses a zone of fog, in particular in the case where the vehicle is close to a zone of fog. It improves the safety of all vehicles in this type of situation.

“Vehicle” means any type of vehicle such as a motor vehicle, moped, motorcycle, warehouse storage robot, etc.

“Autonomous driving” of an “autonomous vehicle” means any process capable of assisting the driving of the vehicle. The method can thus consist in partially or totally directing the vehicle or providing any type of assistance to a natural person driving the vehicle. The process thus covers all autonomous driving, from level 0 to level 5 in the OICA scale, for Organization International des Constructeurs Automobiles.

In the following, the term "ego-vehicle" is used to designate the vehicle whose autonomous driving is determined. However, as detailed below, the invention does not only apply to an ego-vehicle but also applies to a vehicle in manual piloting.

“Road” means any means of communication involving the physical movement of a vehicle. A national, departmental, local, European, international road, a national, European, international highway, a forest path, a route for autonomous storage devices in a storage warehouse, etc. are examples of routes.

The road includes at least one carriageway. “Road” means any physical means capable of supporting the movement of a vehicle. A highway typically comprises two carriageways separated by a median strip.

The roadway has at least one lane. “Lane” means any portion of roadway assigned to a line of vehicles. A highway carriageway typically includes at least two lanes of traffic. An insertion lane on the highway, a single lane in a tunnel, a one-way traffic lane located in a city, etc. are examples of pathways.

A lane can be delimited by markings on the ground but it can also correspond to a trajectory on the roadway taken by the vehicles circulating on the roadway. Such a lane can be called a “virtual lane” because this lane is not delimited by physical markings but is generated from past trajectories taken by vehicles traveling on the roadway.

Patent application CN107719225 describes a system for controlling the switching on or off of a vehicle's lights according to information received in V2X. However, switching off the lights does not effectively ensure, in bad weather conditions, that the vehicle is visible to other road users.

Patent application US20150025787 describes a method for monitoring and reporting a driving situation in the environment of a vehicle. However, this document does not deal specifically with driving situations related to bad weather conditions.

The present invention improves the situation.

To this end, a first aspect of the invention relates to a method for signaling the presence of a vehicle, implemented in a vehicle control device, the method comprising the following steps:

• obtaining meteorological information;
• activation of at least two presence signaling means distinct from the vehicle, if the meteorological information indicates the presence of a zone of fog in the environment of the vehicle.

Fog is defined as any weather condition in which visibility is limited.

The method according to the invention thus makes it possible to effectively signal the presence of the vehicle when it is not very visible due to bad weather conditions, by activating at least two presence signaling means. No restriction is attached to the means of signaling presence which may be visible or audible in particular.

According to one embodiment, the two means of signaling the presence of the vehicle can be among fog lights, hazard lights and an audible warning means.

The use of signaling means of different types makes it possible to improve the signaling of the presence of the vehicle.

According to one embodiment, three presence signaling means can be activated, if the meteorological information indicates the presence of fog in the environment of the vehicle.

Thus, safety is improved in a driving situation where an area of fog is detected.

According to one embodiment, the at least two presence signaling means can be activated if the meteorological information indicates the presence of a foggy zone in the environment of the vehicle, and if a condition relating to a following vehicle is detected by the vehicle.

According to this embodiment, the two signaling means are switched on in the event that another vehicle is likely to collide with the vehicle. Safety is thus improved, and the two means are activated only when the vehicle must be visible.

Alternatively, two presence signaling means can be activated if the meteorological information indicates the presence of a foggy zone in the environment of the vehicle, and at least one additional presence signaling means can be activated if a condition relating to a following vehicle is detected by the vehicle.

Thus, the signaling of the presence of the vehicle is further improved in a foggy situation and when there is a risk of collision with a following vehicle.

In addition, the condition relating to a following vehicle can be:

- the presence of the following vehicle;

- a condition relating to a speed of the following vehicle; Or

- a condition relating to a relative speed between the following vehicle and the vehicle.

Thus, a risk of collision can be assessed before triggering at least two (or at least three) vehicle presence signaling means.

In addition, the activation of presence signaling means can include the sequential activation:

- fog lights; Then

- hazard warning lights; Then

- a means of audible presence signalling.

Sequential activation allows signaling dynamics that improve the visibility of the vehicle to other vehicles.

A second aspect of the invention relates to a computer program comprising instructions for implementing the method according to the first aspect of the invention, when these instructions are executed by a processor.

A third aspect of the invention relates to a device for controlling a vehicle, the device comprising a processor configured to:

• obtaining meteorological information;
• activation of at least two presence signaling means distinct from the vehicle, if the meteorological information indicates the presence of a zone of fog in the environment of the vehicle.

A fourth aspect of the invention relates to a vehicle comprising the device according to the third aspect of the invention, and at least two vehicle presence signaling means.

Other characteristics and advantages of the invention will appear on examination of the detailed description below, and of the appended drawings in which:

illustrates a driving situation involving a vehicle according to one embodiment of the invention;

is a diagram illustrating the steps of a method according to one embodiment of the invention;

illustrates the structure of a control device according to one embodiment of the invention.

Figure 1 shows a driving situation involving a vehicle 100 according to one embodiment of the invention. The vehicle may be an ego-vehicle as described above, self-driving, or may be a driver-operated vehicle.

The vehicle 100 may comprise at least two presence signaling means. In Figure 1, the vehicle 100 is shown with three presence signaling means, namely:

- fog lights101;

- hazard lights 102, also called "warning"; And

- a presence sound signaling means, such as a horn 103.

The fact that the vehicle 100 is illustrated with three presence signaling means is given for illustrative purposes only, and it is understood that the invention applies to any vehicle having at least two (two or more) presence signaling means . The invention also applies to any other presence signaling means other than the three examples mentioned above.

Vehicle 100 may further comprise at least one sensor 104.

No restriction is attached to the sensor(s) 104 of the vehicle 100 which may comprise any visual technology (camera, of the multifunction video camera type, CVM, and image processing system), a radar/lidar system, or an ultrasonic sensor for example, or any combination of such technologies. A combination of different technologies can be used in order to perform complementary functions (vehicle detection on the one hand, such as a following vehicle 120 shown in the figure, evaluation of the speed of another vehicle, such as that of the vehicle follower 120, on the other hand) and/or redundant (double determination of the speed of the follower vehicle, in order to have redundant data which is therefore more reliable). For example, the vehicle 100 can comprise a camera in association with an image processing system and a lidar, which can be used for complementary and/or redundant functions.

Vehicle 100 may further comprise a communication interface 105, such as a V2X communication interface. A V2X interface includes any interface capable of communicating with a network, another vehicle or an element of road infrastructure.

For this purpose, the communication interface can be a WiFi, Car2X, or cellular type link (of any generation, 3G, 4G, 5G or later).

The vehicle 100 further comprises a control device 110 configured to control the presence signaling means 101, 102, 103, in particular on the basis of data received from the sensor 104 or from the communication interface 105, as detailed with reference to Figure 2. A structure of the control device 110 is shown with reference to Figure 3.

In the situation illustrated in FIG. 1, the vehicle 100 enters a zone of fog 140 on a road 130. The invention also applies when the vehicle 100 is already in the zone of fog 140 or when a zone of fog is farther on route 130 (in the direction of vehicle traffic 100).

Figure 2 is a diagram illustrating the steps of a method according to one embodiment of the invention.

At a step 200, the vehicle 100 obtains meteorological information. No restrictions are attached to the way weather information is obtained. Meteorological information can be received in particular:

- from the 105 V2X communication interface, in particular via cellular, satellite or from another vehicle;

- by a third-party device such as a mobile terminal on board the vehicle 100, via a wireless link such as Bluetooth or Wifi.

No restriction is also attached to the meteorological information which may indicate a meteorological event such as the presence of rain, the presence of a zone of fog, the presence of strong winds, etc. The meteorological event may also be accompanied by location coordinates of the meteorological event.

At a step 201, the vehicle 100 determines, from the meteorological information, if a foggy zone, such as the foggy zone 140, is in the environment of the vehicle 100. “In the environment of” indicates that vehicle 100:

- is included in the fog zone 140;

- is located at a distance less than a given threshold from the fog zone 140; Or

- heading towards the fog zone 140.

According to a general embodiment of the invention, if the meteorological information indicates the presence of the foggy zone 140 in the environment of the vehicle 100, the control device 110 activates, in a step 204, at least two means of vehicle presence signaling 100, in particular among the presence signaling means 101, 102 and 103 represented in FIG. 1. For example, the control device 110 can activate the signaling lights 101 and the hazard lights 102. The invention is particularly advantageous in the case where the vehicle 100 is an ego-vehicle in an autonomous driving situation, insofar as the driver does not have the direct possibility of manually triggering the presence signaling means. However, even in the case of a vehicle in manual piloting, the invention makes it possible to signal the presence of the vehicle 100, thus improving the safety associated with the driving situation. The method according to the general embodiment then proceeds to step 205 described below.

According to other embodiments, the method further comprises a step 202 of obtaining data relating to a follower vehicle 120. This data can be:

- the presence/absence of the following vehicle 200; and or

- a speed of the following vehicle 200.

These data can come from the sensor 104 (radar/lidar detection for example) or can be obtained via the communication interface 105 (the following vehicle 120 itself signals its presence via a V2V communication).

At a step 203, the control device 110 tests a condition relating to the following vehicle 120, on the basis of the data obtained at step 202. The condition test can be:

- detection of the presence of the following vehicle 120;

- a verification that the speed of the follower vehicle 120 is greater than a predetermined speed threshold; Or

- a verification that a relative speed (in absolute value) between the vehicle 100 and the following vehicle 120 is greater than a given threshold.

In the event of a negative test in step 203 (absence of following vehicle 120, or following vehicle at too slow a speed, or absolute value of the relative speed between the following vehicle 120 and the vehicle is too low), the method proceeds to step 204.

At step 204, the control device 110 activates at least two presence signaling means, as detailed above. The activation of several presence signaling means makes it possible to effectively inform other vehicles of the position of the vehicle 100 or of its potential deceleration, for example. The safety associated with the driving situation is thus improved.

At a step 205, the control device 120 checks whether the fog zone 140 is still in the environment of the vehicle 100, for example on the basis of data from the sensor 104 or received by the communication interface 105. When the fog zone 140 is no longer in the environment of the vehicle 100, the control device 110 deactivates, in a step 206, the presence signaling means which had been activated in step 204.

In the event of a positive test at step 203, the control device 210 activates, at a step 207, at least one additional presence signaling means compared to step 204. In particular, the control device 210 can activate the three presence signaling means 101, 102 and 103.

According to one embodiment, the presence signaling means are activated sequentially in step 207. A sequence can for example be:

- activation of fog lights 101; Then

- activation of hazard warning lights 102; Then

- activation of the presence sound signaling means 103.

The sequence can be implemented according to predetermined time steps. For example, a predetermined duration can be applied between two successive activations. Alternatively, successive activations may be caused by different activation conditions relating to the vehicle. The activation conditions can be different spacing thresholds between the following vehicle 120 and the vehicle 100. Thus, the activations are carried out successively as the following vehicle 120 approaches. However, no restrictions are attached to the activation conditions.

At a step 208, the control device 120 determines whether the foggy zone 140 is still in the environment of the vehicle 100, for example on the basis of data from the sensor 104 or received by the communication interface 105. When the fog zone 140 is no longer in the environment of the vehicle 100, the control device 110 deactivates, in a step 206, the presence signaling means which had been activated in step 207.

Figure 3 illustrates the structure of a control device 110 according to one embodiment of the invention.

The control device 110 comprises a processor 302 configured to communicate unidirectionally or bidirectionally, via one or more buses, with a memory 403 such as a “Random Access Memory” type memory, RAM, or a “Read Only Memory”, ROM, or any other type of memory (Flash, EEPROM, etc). Alternatively, memory 304 includes multiple memories of the aforementioned types.

The memory 304 is capable of storing, permanently or temporarily, at least some of the data used and/or resulting from the implementation of the method according to the invention. In particular, the memory 304 is capable of storing data specific to the ego-vehicle, instructions to be executed, and the data acquired from the sensor(s) 110.

The processor 302 is capable of executing instructions, stored in the memory 304, for the implementation of the steps of the method according to the invention, illustrated with reference to Figure 2. Alternatively, the processor 304 can be replaced by a microcontroller designed and configured to perform the operations of Figure 2.

The control device 110 can further comprise an input interface 301 and an output interface 303 in order to communicate with other elements of the vehicle 100. In particular, the input interface 400 is able to receive data from sensor 110 and the output interface 402 is capable of transmitting commands to the output interface 401, for transmission to the signaling system 120.

The present invention is not limited to the embodiments described above by way of examples; it extends to other variants.

Equations and calculations have also been detailed. The invention is not limited to the form of these equations and calculations, and extends to any type of other mathematically equivalent form.

Claims (10)

Method of signaling the presence of a vehicle (100), implemented in a control device (110) of the vehicle, the method comprising the following steps:

• obtaining (200) weather information;
• activation (204) of at least two presence signaling means (101; 102; 103) distinct from the vehicle, if the meteorological information indicates the presence of a zone of fog (140) in the environment of the vehicle.

Method according to claim 1, in which the at least two presence signaling means (101; 102; 103) of the vehicle (100) are among fog lights, hazard lights and a sound presence signaling means. Method according to Claim 1 or 2, in which three presence signaling means (101; 102; 103) are activated, if the meteorological information indicates the presence of fog (140) in the environment of the vehicle. Method according to one of the preceding claims, in which the at least two presence signaling means (101; 102; 103) are activated if the meteorological information indicates the presence of a zone of fog (140) in the environment of the vehicle (100), and if a condition relating to a following vehicle is detected by the vehicle. Method according to one of Claims 1 to 3, in which two presence signaling means (101; 102; 103) are activated if the meteorological information indicates the presence of a zone of fog (140) in the environment of the vehicle, and at least one additional presence signaling means is activated if a condition relating to a following vehicle (120) is detected by the vehicle. A method according to claim 4 or 5, wherein the following condition is:
- the presence of the following vehicle (120);
- a condition relating to a speed of the following vehicle; Or
- a condition relating to a relative speed between the following vehicle and the vehicle (100). Method according to one of Claims 4 to 6, in which the activation of the presence signaling means comprises the sequential activation:
- fog lights (101); Then
- hazard warning lights (102); Then
- A presence sound signaling means (103). Computer program comprising instructions for implementing the method according to any one of the preceding claims, when these instructions are executed by a processor (302). A vehicle control device (100), the device comprising a processor (302) configured to:

• obtain weather information;
• activating at least two presence signaling means (101; 102; 103) distinct from the vehicle, if the meteorological information indicates the presence of a zone of fog (140) in the environment of the vehicle.

Vehicle comprising the device according to claim 9, and at least two presence signaling means (101; 102; 103) of the vehicle.