FR3108721A1 - Data sampling device and diagnostic set for a motor vehicle - Google Patents

Abstract

Device (2) for sampling data from a plurality of sensors (6) of a motor vehicle (1), comprising a box in which is mounted a luminous display comprising a matrix of luminous elements, each luminous element of said display light being adapted to be associated with a sensor (6) of the motor vehicle (1); the device (2) further comprising a camera installed so as to acquire in real time the image of said luminous display installed in the box. Figure for abstract: figure 1

Description

Data sampling device and diagnostic assembly for a motor vehicle

The invention relates to the field of electronic diagnostics for motor vehicles.

Modern motor vehicles include a large number of sensors that facilitate the diagnosis of breakdowns or malfunctions.

It is well known that a sensor is an organ measuring a given physical quantity, temperature, pressure, acceleration etc. and converts it into an electrical output signal, generally so that the output voltage allows the measured quantity to be interpreted.

However, the greater the number of sensors in a motor vehicle, the more complex the general diagnostic process becomes and the longer the acquisition time is important for the diagnostic devices.

The growing automation of motor vehicles also augurs well for a sharp increase in the quantity of sensors embedded in a motor vehicle.

Also, there is the need to optimize the sampling flow of the data emitted by the sensors of a motor vehicle.

Known in particular in the prior art are solutions based on the multiplexing of the signals emitted by the sensors, making it possible to connect a large number of sensors to a computer. However, such solutions, serial by definition, impose a sampling time inversely proportional to the number of sensors, and do not allow simultaneous acquisition of all the sensors.

Also, there is the need for a solution to acquire more efficiently and in parallel the data of a plurality of sensors.

To this end, a device for sampling data from a plurality of sensors of a motor vehicle is proposed, comprising a box in which is mounted a luminous display comprising a matrix of luminous elements, each luminous element of said luminous display being adapted to be associated with a sensor of the motor vehicle; the device further comprising a camera installed so as to acquire in real time the image of said luminous display installed in the box. Thus, it is possible to acquire simultaneously, in parallel, all the sensors associated with the device, at a frequency determined by the acquisition camera, and this in a relatively simple and inexpensive way.

Advantageously and in a non-limiting way, each luminous element comprises a light-emitting diode controlled in voltage or in current according respectively to the value of voltage or output current of said associated sensor. In other words, the luminous display is a matrix of LEDs, which is a particularly reliable, inexpensive and relatively simple solution to control LED by LED.

Advantageously and in a non-limiting manner, said box is formed of two parts that are removable relative to each other, a first part comprising the light display and the other part comprising the camera. Thus, when such a device is installed to diagnose a vehicle, the first part of the box can be loaded into the vehicle and the second part can be moved to a system external to the vehicle.

Advantageously and in a non-limiting manner, the device further comprises an adaptation member capable of adapting, for each sensor, the voltage or the output current of the sensor to an expected voltage range for the associated luminous element of the display. luminous. Thus, the output values of the sensors can be normalized to ensure an optimal display on the luminous display and to improve the subsequent recognition of display patterns.

Advantageously and in a non-limiting manner, each sensor is associated with a plurality of luminous elements. Thus, it is possible to improve the acquisition of each sensor value by the camera by magnifying for example the unit size of a converted sensor value by displaying it on a plurality of pixels of the light display.

The invention also relates to a diagnostic assembly for a motor vehicle, comprising a device as described above, and a processing unit able to receive in real time the image of said light display acquired by said camera and to recognize a pattern diagnosis in said received image.

Advantageously and in a non-limiting manner, the processing unit comprises automatic learning means, such as a neural network. Thus, it is possible to obtain a diagnosis of the vehicle without it being necessary to carry out a sensor-by-sensor analysis and this in a reliable manner, even for complex diagnoses involving a relatively large number of sensors.

Advantageously and in a non-limiting manner, the diagnostic assembly further comprises a diagnostic display able to receive the determined diagnosis from the processing unit and to display it. This allows an operator or the driver of the motor vehicle to ascertain, in real time, the diagnosis or the state of the motor vehicle.

The invention also relates to the use of a diagnostic assembly as described above on a motor vehicle.

is a schematic representation of a diagnostic assembly according to the invention;

is a schematic representation of the diagnostic device according to a first embodiment and of a diagnostic display;

is another schematic representation of the device according to the embodiment of FIG. 2;

is a schematic representation of a diagnostic assembly according to a particular embodiment of the invention; And

is a schematic representation of a diagnostic assembly according to another particular embodiment of the invention.

Referring to Figures 1 to 3, according to a first embodiment of the invention, a motor vehicle 1 comprises a plurality of sensors 6, installed in a plurality of locations.

The invention is suitable for any type of sensor 6 able to acquire or measure a physical quantity, such as a force, a temperature, an acceleration, vibrations, a deformation or any other quantity given without limitation.

Each sensor 6 is connected to a data sampling device 2 according to the invention, also more simply called device 2.

In this embodiment, each sensor 6 is connected by wire to device 2, so that in the vicinity of the case the set of cables forms a layer 3, which ensures optimum transmission of data from each sensor to device 2.

However, provision could be made for wireless transmission of the measurements from each sensor 6 to the device 2, for example by radio waves, but such a solution involves greater energy consumption and greater sensitivity to disturbances in the system.

The data sampling device 2 comprises an opaque box 4, also called casing 4, in which are installed a luminous display 21 and a camera 24.

The luminous display 21 is mounted on a printed circuit board 22, in English Printed Circuit Board frequently abbreviated as PCB.

The luminous display 21 comprises a plurality of luminous elements 210, such as light-emitting diodes, more commonly called LEDs, forming a display matrix. However, any type of luminous display, formed of a display matrix capable of independently displaying luminous pixels can be implemented by the invention. The choice of the LED matrix is mainly based on the high reliability, the simplicity of implementation as well as its low cost.

The luminous display 21 thus comprises a matrix of LEDs 210 forming as many distinct display pixels.

Each sensor 6 is then associated with a pixel of the luminous display 21 so that the output voltage of the sensor 6 is visually represented by the pixel, in particular by encoding, according to a bijective method, the output voltage value in one light display signal from the LED, for example so as to modulate the brightness of each pixel according to the output value of the associated sensor 6.

Although in this embodiment the sensor 6 is associated with an output voltage, any other type of output value from the sensor 6 can be displayed, such as an output current.

According to an implementation alternative, the display 21 comprises a polychrome matrix and the output value of each sensor 6 is converted into a display color.

In particular, a voltage can be converted into an RGB value so that each pixel of the matrix of the display 21 defines a display color representative of the output voltage of the associated sensor 6.

However, the invention is not limited to this sole implementation of the sensor 6/luminous display 21 association, and any solution can be implemented so that the display displays an image forming a matrix of pixels depending on the values sensor outputs 6.

In particular according to particular embodiments, each output value of a sensor 6 can be coded on several pixels of the display 21, in particular when the sensor 6 provides a plurality of output data.

Furthermore, each sensor 6 can be associated with a group of pixels, in particular a square or rectangular group of pixels, so as to enlarge the area of visual representation of each sensor on the luminous display 21. This is particularly relevant when the resolution of display of the luminous display 21 is close to or greater than the acquisition resolution of the camera 24. In this case the risk that the camera 24 does not perfectly capture each pixel associated with each sensor 6 exists, and it can then be useful to enlarge the display of each visual representation of each sensor, in other words a voluntary reduction in the display resolution, according to a technique called “downscaling”.

Consequently, it is possible to determine an optimal display resolution on the luminous display 21, by considering each sensor representation 6 to be displayed as being a display pixel, and by calculating a desired display resolution, not necessarily equal to the display resolution of the illuminated display 21.

The number of sensors 6 that can be acquired in parallel is then limited by the display capacity of the luminous display 21 as well as the acquisition resolution of the camera 24.

Conversely, if it is necessary to acquire a large number of 6 sensors (for example several thousand), a high resolution camera will be necessary to ensure that the display resolution can be correctly acquired.

Opposite the luminous display 21 in box 4, a camera 24 is installed to acquire an image of the luminous display 21. This camera 24 is installed so that it clearly acquires the image of the luminous display 21 in real time.

In this embodiment, the luminous display 21 is removable from the rest of the box 4. The display 21 is then attached to the layer of transmission cables 3 for the data from the sensors 6, and is carried by the vehicle. The rest of the device 2 then forms acquisition equipment which can be connected to the display 21 when a diagnosis must be carried out.

Thus, the housing 4 has a first part 4a forming the acquisition part of the device 2, and comprising the camera 24, and a second part 4b forming the light emission part, comprising the luminous display 21.

The two parts 4a and 4b are shaped to be able to be removably fixed to one another so as to form an opaque case 4, according to any known fixing technique. Figure 2 illustrates the two parts 4a and 4b separated from each other on the top representation and fixed to each other on the bottom representation.

The camera 24 then transmits the acquired images to a processing device 5.

Thus the sensor data processing frequency is determined by the acquisition frequency of the camera 24.

In the representation of FIG. 2, the processing unit 5 is shown in the box 4, but this only constitutes one possible possibility of positioning the processing unit 5, and it is just as possible to install this processing unit 5 outside the opaque box.

The processing unit 5 is in this embodiment, an on-board computer 5 able to process the acquired image to extract therefrom the data associated with each sensor so as to carry out a diagnosis of the motor vehicle.

The computer 5 can also use this data in real time during vehicle travel for the purposes of informing the driver, driving assistance, and/or controlling the vehicle in autonomous or semi-autonomous driving mode.

Thus, in this embodiment, the computer 5 acquires an image captured by the camera 24 and carries out a diagnosis according to this image, by recognition of an image pattern, representative of the state of all the sensors 6 associated with sampling device 2.

To this end, the computer 5 implements an image recognition process, in particular by implementing automatic learning processes, such as neural networks, previously trained on the basis of images associated with a particular diagnosis.

Indeed, each image displayed by the luminous display 21 forms a visual pattern making it possible to visually make a diagnosis, without having to carry out a sensor-by-sensor analysis. In this sense, neural networks, and machine learning processes in general, are particularly suited to pattern recognition.

Such a solution makes it possible, on the one hand, to acquire the status of all the sensors in parallel, and to perform complex diagnostics, in particular when the combination of several sensor data is necessary to make the diagnosis.

Such a solution also allows the computer to obtain in real time, in particular during driving, a status of all the sensors, and thus send information to the driver without delay or assist a driver in his driving or control a component of the vehicle in autonomous or semi-autonomous driving mode.

According to an alternative implementation, the image recognition method is a traditional image processing method, separating each pixel and then calculating for each pixel each associated sensor value. However, such a solution can be more expensive in computation time and more sensitive to acquisition errors.

Any other image processing technique capable of detecting in the image acquired by the camera 21 the values of each sensor 6 can be implemented by those skilled in the art.

Then the computer 5 transmits the result to a diagnostic display 7, allowing an operator or the driver of the vehicle to take cognizance of the diagnosis made.

The diagnostic display 7 can be combined with the computer 5, for example as represented in FIG. 1, or separated from the computer; for example by being integrated into the housing 4, or even disposed outside the housing as shown in Figure 2.

In the case where the diagnostic display 7 and the computer 5 are separated, they can communicate either by wire with each other, or wirelessly, as shown in FIG. 5, for example by radio frequency communication , such as Wi-Fi or a Bluetooth connection.

Furthermore, the data transmitted by the computer 5 can also be transmitted to a remote server, for example by a cellular connection, so as to remotely transmit diagnostic information from the motor vehicle.

According to a second embodiment of the invention with reference to Figure 4, an adapter card 41 is arranged between the output cables 3 of the sensors 6, forming a sheet of cables 3, and the luminous display 21.

This adapter card 41, allows on the one hand to group together upstream of the second part 4b of the housing, all the cables 3, and also allows to carry out the adaptation of the tension, or if necessary of the current, between the output voltage of each sensor 6 and the display voltage range of the LEDs 210 of the display 21.

Such an adaptation, for example an increase or a reduction in the output voltage of the sensor 6 may be necessary to adapt to the control voltage expected by each LED 210, for example by adding a predetermined resistance between the output of the sensor 6 and the associated LED 210.

Another sheet 42 then connects the output of the adapter card 41 to the luminous display 21.

The invention as described is not limited to this single implementation and can be implemented in technical fields distinct from motor vehicles.

The fact of acquiring and processing the sensors via image recognition firstly makes it possible to acquire a large number of sensor outputs in parallel, significantly reducing, and proportional to the number of sensors, the acquisition time, compared to acquisition by multiplexing.

In addition, the invention makes it possible to isolate the outputs of the sensors from the electrical circuits of the motor vehicle 1.

Claims (9)

Device (2) for sampling data from a plurality of sensors (6) of a motor vehicle (1), characterized in that it comprises a box (4) in which is mounted a luminous display (21) comprising a matrix of luminous elements (210), each luminous element (210) of said luminous display (21) being adapted to be associated with a sensor (6) of the motor vehicle (1); the device (2) further comprising a camera (24) installed so as to acquire in real time the image of said luminous display (21) installed in the box (4). Device (2) according to Claim 1, characterized in that each luminous element (210) comprises a light-emitting diode controlled in voltage or in current as a function respectively of the voltage value or of the output current of said associated sensor (6). Device (2) according to Claim 1 or 2, characterized in that the said box (4) is formed of two parts (4a, 4b) removable relative to each other, a first part (4a) comprising the luminous display (21) and the other part (4b) comprising the camera (24). Device (2) according to any one of Claims 1 to 3, characterized in that it also comprises an adaptation member (41) capable of adapting, for each sensor (6), the output voltage or current of the sensor (6) to an expected voltage range for the luminous element (210) associated with the luminous display (21). Device (2) according to any one of Claims 1 to 4, characterized in that each sensor (6) is associated with a plurality of luminous elements (210). Diagnostic assembly for a motor vehicle, comprising a device (2) according to any one of claims 1 to 3, and a processing unit (5) able to receive in real time the image of said luminous display (21) acquired by said camera (24) and recognizing a diagnostic pattern in said received image. Diagnostic assembly according to Claim 6, characterized in that the processing unit (5) comprises automatic learning means, such as a neural network. Diagnostic assembly according to Claim 6 or 7, characterized in that it further comprises a diagnostic display able to receive the determined diagnosis from the processing unit (5) and to display it. Use of a diagnostic assembly according to any one of Claims 6 to 8 on a motor vehicle.