FR2898092A1 - MIRROR DEVICE FOR MOTOR VEHICLE AND USE OF THE DEVICE - Google Patents

Abstract

A rear view mirror device for a motor vehicle, located outside said vehicle, comprising at least one sensor (10) of the vehicle speed. Said device comprises a motorized variable focus video camera (3) capable of providing the driver with at least a partial rear and lateral vision. Said camera (3) is connected to a screen (26) and connected to a calculation means (11) comprising determining means (13) able to determine the value of the focal distance (f) of the camera according to the a value of the speed detected by said speed sensor (10), and a first control means (15) able to control the camera focal distance according to said determined value.

Description

Rearview mirror device for a motor vehicle and use of the

device.

  The present invention relates generally to driving assistance for motor vehicles, in particular for optimizing the field of view of the driver of the motor vehicle via the external rearview mirror. The invention is advantageously applicable for the detection of vehicles, pedestrians or obstacles in the so-called blind spot zones. Indeed, according to the driving situations encountered, a suitable field of view is necessary. For example, for city driving, a wide field of view is particularly useful because of the presence of pedestrians, cyclists and many intersections from which other drivers may come. On the other hand, for highway driving, a narrower field of view is preferable, since the vision of the rearview mirror should help the driver to visualize vehicles behind his or her own and doubling it. Thus, a field of view of the order of 80 is sufficient in these situations. And even a field of view too important can be dangerous, because it can distort the distances compared to a natural vision. One solution would be to adapt the mirror so that it can be suitable in all situations, so as to be in optimum position for each of them. To solve this problem, US Patent 5,978,017 (TINO) discloses a set of cameras fixed around the vehicle so as to multiply the video signals. However, the proliferation of cameras around the vehicle greatly increases the cost of manufacturing it. Patent US Pat. No. 5,096,287 and patent application 2,780,230 respectively propose integrating a camera at the vehicle rearview mirror on the one hand and at the rear of the vehicle on the other hand. However, these two cameras can not fulfill the role of a side exterior mirror. Application FR 2 585 991 relates to a camera system fixed on the rear left wing of the vehicle, to see the vehicles in the blind spot of the conventional rearview mirror. However, this system can not be adapted to different road situations. The patent application FR 2 673 499 relates to the use of a camera at the rear of the vehicle, this camera being able to pivot about a reference position. However, the application of this camera is limited to parking maneuvers. The invention aims to provide a solution to these problems. The invention aims to optimize the driver's field of vision via the external rearview mirror of the vehicle, depending on the driving situation in which it is found. For this purpose, the invention proposes a rear view mirror device for a motor vehicle located outside said vehicle, comprising at least one sensor of the vehicle speed. According to a general characteristic of the invention, the device comprises a motorized variable-focus video camera capable of providing the driver with at least partly rear and side vision, said camera being connected to a screen and connected to a calculation means comprising a determining means capable of determining the value of the focal length of the camera as a function of the value of the speed detected by said speed sensor, and a first driving means able to control the focal distance of the camera according to said value determined. In other words, the different driving situations are detected by a speed sensor, a given speed value corresponding to a predetermined driving situation. Then, the focal length of a camera is adjusted according to the speed detected to widen or reduce the field of view. The device has the advantage, with the aid of a single camera, to be able to benefit from an adaptive field of view, whatever the driving situation. The device advantageously comprises a first auxiliary control means for receiving a command from the driver and able to control the focal distance of said camera directly according to the order received. Preferably, the camera is fixed to the motor vehicle by means of a motorized steerable axis, the calculation means comprising a second control means adapted to drive said steerable axis.

  The second control means is adapted to drive said steerable axis at different angles, including for example the angle of elevation and the heading angle. The device advantageously comprises a second auxiliary control means for receiving a command from the driver and able to control said steerable axis directly according to the order received. Preferably, the device further comprises a memory device connected to the calculation means and capable of storing a curve representing the focal distance of the camera as a function of the value of the speed of the vehicle, said curve comprising at least one speed threshold. delimiting two velocity zones to which correspond two distinct and predetermined focal lengths. Preferably, each speed threshold comprises a lower value and a higher value depending on the direction of variation of the speed of the motor vehicle. The lower and upper values of the speed threshold have the advantage that the focal distance of the camera does not oscillate between two values. According to one embodiment, the device may further comprise an optical rearview mirror. The invention also proposes a use of a video camera integrated in a vehicle rearview mirror to provide the driver with a vision at least partly rear and side. According to another general characteristic of the invention, the focal distance of the camera is varied as a function of the value of the speed of said vehicle. Preferably, the variation of the focal distance of the camera is performed according to a curve, a function of the value of the speed of the vehicle, said curve comprising at least one speed threshold associated with a hysteresis, delimiting two zones of speed corresponding to two distinct and predetermined focal lengths. Other advantages and characteristics of the invention will appear on examining the detailed description of an embodiment of the invention, in no way limiting, and the accompanying drawings, in which: FIG. 1 illustrates a motor vehicle comprising a mirror device according to the invention; FIG. 2 illustrates a video camera used in the device according to the invention; FIG. 3 illustrates a possible orientation of a video camera included in a device according to the invention; FIG. 4 illustrates an embodiment of the device according to the invention; FIG. 5 illustrates different stages of the use of a device according to the invention; FIGS. 6 and 7 illustrate the matrix of a camera of a device according to the invention with different values of focal length; and FIG. 8 illustrates the variation of the angle of view of a camera taken in a device according to the invention, as a function of the speed of the motor vehicle. FIG. 1 shows the upper part of a motor vehicle 1. This comprises a lateral exterior optical mirror 2 associated with a motorized video camera 3, with a variable focal length, with an angle of view varying for example between 70 to 120. The video camera 3 is shown in more detail in FIG. 2. It is fixed to the mirror 2 by means of a steerable axis 6. The orientation of the camera 3 can thus vary according to an angle of elevation a by means of an electric motor 4, and according to a heading angle θ, represented in FIG. 3, by means of an electric motor 5. The mobilities of the steerable axis 6 are given here by way of example. It is of course possible to limit them or to choose other angles of variation. The camera 3 can also be fixed directly to the chassis of the vehicle 1, in the case where the latter does not include an optical mirror.

  Referring now to Figure 4, which shows an embodiment of the device according to the invention. The device comprises a speed sensor 10, which delivers the value of the speed of the motor vehicle 1 to a calculation means 11 via a connection 12. The calculation means 11 comprises a determination means 13 able to receive the value of the speed measured by the sensor 10. A memory device 14 is also connected to the calculation means 11. The memory device 14 stores a map representing the focal distance of the camera 3 as a function of the speed of the vehicle. The mapping was developed from various simulation tests carried out beforehand. From this mapping, the determining means 13 determines the value of the focal distance of the camera 3, so that it has an appropriate angle of view with respect to the speed of the vehicle measured by the sensor 10. The means also includes a first 15 and a second 16 control means, to which the determination means 13 delivers the value of the focal length, respectively via connections 17 and 18. The first control means 15 is adapted to develop a command setpoint for the camera 3. This command setpoint delivered by the control means 15 is delivered to a motor 19 via a connection 20.

  The focal length can also be modified directly by the driver of the motor vehicle. To do this, the calculating means 11 comprises a first auxiliary control means 21 receiving directly the input of the DC conductor. The first auxiliary control means 21 then generates a command setpoint for the engine 19, which adjusts the focal length of the motorized camera 3 according to it. The second control means 16 derives the values of angle of elevation α and of heading 0 delivered via two connections 22 and 23 to the motor 5 and 4 of the orientable axis 6. The calculation means 11 also comprises a second auxiliary control means 24 receiving as input a set of the conductor CC, so as to directly adjust the angles of site a and cap O.

  The motorized camera 3 then outputs an image to the calculation means 11 via a connection 25. The images are transmitted to a screen 26 located for example on the dashboard of the vehicle by a connection 27, way the driver can view them.

  In other words, as shown in FIG. 5, the use of the mirror device comprises the measurement of the speed of the motor vehicle (step 30), then, as a function of this speed, the determination of the angle instructions of heading and site (step 31), as well as the focal length of the camera (step 32), followed by the setting (step 33) of the camera and the steerable axis according to the determined instructions. The camera device and the rotatable axis are obtained at angles of heading 0, of site a and a given focal length f. This data is retransmitted for the steps of determining the angle and focal length instructions, so as to reactualize them from their last position. Adjusting the elevation angle is particularly important since it increases the size of the perceived area, especially when the speed of the vehicle increases sharply, and the driver's vigilance must be maximum.

  Alternatively, the variation of the elevation angle may be a function of the angle of the wheels, turn signals or other data of the motor vehicle. Similarly, the variation of the heading angle makes it possible to center the filmed image laterally. For example, for a viewing angle of 120, the heading angle is 60; for a field of view of 90, the angle of heading is 45; for a field of view of 70, the heading angle is 35. It is possible to leave a margin of adjustment of 5 for the comfort of the driver. As can be seen in Figures 6 and 7, a matrix of the camera 40, corresponds to a more or less important angle of view depending on the value of the focal length. Thus, for a small focal length dfl which corresponds to an angle of elevation α1, the field of view represented on the matrix of the camera 40 is wide. For a larger focal length df2 (FIG. 7) to which an angle of elevation α2 corresponds, the field of view represented on the matrix of the camera 40 is narrower. A curve of variation of the angle of view of the camera as a function of the speed of the motor vehicle, is shown in FIG. 8. In this case, the speed thresholds triggering a change in the focal length of the camera are in number. of two, thus delimiting three distinct velocity zones, and consequently three different fields of view. A first field of view corresponds to high speeds, that is to say speeds above 90 km / h. It is for example about 70.

  A second field of view corresponds to intermediate speeds, that is to say here between 50 km / h and 80 km / h. The angle of the field of view is then about 90. A last field of view corresponds to such speeds, that is to say here at speeds below 50 km / h, which corresponds to a viewing angle of 120. In addition, so as to prevent the angle of view of the camera oscillates between two distinct values, the curve here comprises hysteresis at each threshold to erase these oscillations.

  These hysteresis have the advantage of improving the comfort and safety of the driver. Of course, the speed limits are not exhaustive and the curve can be modified according to the needs, for example according to the speed limits in force in a given region. Moreover, the elevation angle can be connected to any other data of the vehicle such as the angle of the wheels or the turn signals.

Claims (10)

  A mirror device for a motor vehicle, located outside said vehicle, comprising at least one sensor (10) of the speed of the vehicle, characterized in that said device comprising a video camera (3) motorized variable focal capable providing the driver with at least a partial rear and side vision, said camera (3) being connected to a screen (26) and connected to a calculating means (11) comprising determining means (13) able to determine the value the focal length (f) of the camera as a function of the value of the speed detected by said speed sensor (10), and a first control means (15) able to control the camera focal distance according to said determined value .   2. Device according to the preceding claim, comprising a first auxiliary control means (21) for receiving a command (CC) of the driver and adapted to control the focal length (f) of said camera (3) directly according to the order received.   3. Device according to claim 1 or 2, wherein the camera (3) is attached to the motor vehicle via a motorized steerable axis (6), and wherein the calculating means (11) comprises a second means of control (16) adapted to drive said steerable axis (6).   4. Device according to claim 3, wherein the second control means (16) is adapted to drive said steerable axis (6) at different angles including the angle of elevation (a) and the heading angle (0) .   5. Device according to one of claims 3 or 4, a second auxiliary control means (24) for receiving a command (CC) of the driver and adapted to drive said steerable axis (6) directly according to the order received.   6. Device according to one of claims 1 to 5, further comprising a memory device (14) connected to the calculation means (11) and able to store a curve representing the focal distance of the camera according to the value of the speed of the vehicle, said curve comprising at least one speed threshold delimiting two speed zones to which correspond two distinct and predetermined focal distances.   7. Device according to claim 6, wherein each speed threshold comprises a lower value and a higher value according to the direction of variation of the speed of the motor vehicle.   8. Device according to one of claims 1 to 7, further comprising an optical mirror (2).   9. Use of a video camera integrated into a vehicle rearview mirror to provide the driver with at least a partial rear and side vision, characterized in that the focal length (f) of the camera is varied according to the value of the speed of said vehicle.   10. Use of a video camera according to claim 9, wherein the variation of the focal length (f) of the camera is performed according to a curve depending on the value of the speed of the vehicle, said curve comprising at least one threshold velocity associated with a hysteresis and delimiting two velocity zones corresponding to two distinct and predetermined focal lengths.