METHOD FOR DOWNLOADING DIGITAL DATA IN AN ELECTRONIC UNIT FOR MEASURING OPERATING PARAMETERS OF A MO

专利摘要:
The invention relates to a method for downloading digital data in an electronic unit (10) for measuring operating parameters of a wheel (20) of a motor vehicle (50), the downloading being performed by a download tool (40a to 40d) external to the wheel (20). The method comprises positioning the external downloading tool (40a to 40d) at least in the vicinity of the wheel (20), transmitting at least one mechanical waveframe (8, 8a) by the tool downloading (40a to 40d) external to the electronic unit (10) representative of the data to be downloaded, receiving at least said mechanical wave frame (8, 8a) by the electronic unit (10) via measuring sensor (12) of a mechanical parameter and converting the mechanical waves into electrical signals and then into digital signals containing the data downloaded in digital form, and storing the data downloaded into the electronic unit (10).
公开号:FR3050690A1
申请号:FR1653934
申请日:2016-05-02
公开日:2017-11-03
发明作者:Sylvain Godet；Arthur Fouss
申请人:Continental Automotive GmbH；Continental Automotive France SAS；
IPC主号:

专利说明:

The present invention relates to a method of downloading digital data in an electronic unit for measuring operating parameters of a motor vehicle wheel by transmission of mechanical waves.
The present invention also relates to an assembly comprising an external download tool and a motor vehicle wheel for implementing such a download method.
The present invention relates to the field of the automobile, particularly to the field of controlling the parameters of the tires of motor vehicle wheels by an electronic unit incorporated in each wheel.
It is known systems for detecting and controlling parameters of the wheel of a vehicle. A motor vehicle wheel equipped with such a system is shown (schematically) in Figure 1. In Figure 1, the wheel 20 is equipped with a rim 21 and a tire 22. The wheel 20 is configured for rotating about a bearing axis according to the arrow 30. The system for detecting and checking the parameters of the wheel of a vehicle is in the form of an electronic unit 10 often referred to as a wheel unit and delimited in dotted lines. The electronic unit 10 is shown in FIG. 1 as being mounted against the rim 21 but this electronic unit can be mounted in the tire 22 of the wheel 20, for example on its inner circular periphery below the tread, on a sidewall of the tire or a tire inflation valve 23 near the rim 21, this on a portion of the valve 23 inside the tire 22.
Each electronic unit 10 communicates with a central wheel control unit of the vehicle on board the vehicle and placed at a distance from the electronic unit 10 of each wheel. The electronic unit 10 for measuring at least one operating parameter of the wheel, also frequently referred to as a wheel unit and which will hereinafter be called an electronic unit, is provided with a radial acceleration sensor 12 measuring the speed of rotation. of the wheel 20. The radial acceleration sensor 12 measures the radial acceleration it undergoes when the wheel 20 rotates about the rolling axis.
It is indeed important to know the rotational speed of the wheel for the operation of systems of assistance to handling or protection against the locking of the wheels, such as the wheel anti-lock system known under the acronym ABS or the electronic control system of the dynamic behavior of the vehicle known by the acronym ESP. The electronic unit 10 comprises a support 11 for the radial acceleration sensor 12 which is shown in FIG. 1 as extending in a plane tangential to the rim 21, the radial acceleration sensor 12 extending parallel to the support 11.11 is possible that the support 11 or the radial acceleration sensor 12 is inclined with respect to a plane tangential to the rim 21.
Although not illustrated in FIG. 1, the electronic unit 10 incorporated in the wheel 20 also comprises a tire pressure sensor 22 fitted to the wheel 20 and, advantageously, a temperature sensor, the pressure sensor and the temperature sensor. not shown in this figure. The pressure sensor of the tire 22 at least regularly monitors the pressure of the tire 22 and transmits this information to the aforementioned central wheel control unit disposed at a distance from the wheels 20. The electronic unit 10 finally comprises a microprocessor, a low frequency signal receiving antenna forming a low frequency receiving stage, and a radio frequency signal transmitting antenna forming a radiofrequency transmission stage. A battery integrated in the electronic unit can supply all of the aforementioned elements that the electronic unit comprises.
Each electronic unit or wheel unit communicates with the central wheel control unit which is provided with a radiofrequency reception antenna, in particular for receiving information from each electronic wheel unit and a microprocessor computer. central control unit being powered by a vehicle battery and may have a low frequency transmission element to the electronic units.
In a manner known per se, the pressure and radial acceleration sensors of the electronic units of each wheel can respectively monitor, the pressure prevailing inside the tire associated with the wheel, the speed and the acceleration of rotation of the wheel. . Each electronic unit sends to the central control unit these two types of measurements made by radiofrequency signals. The central control unit is adapted to decode and process the received radio frequency signals.
Currently, the architecture used in electronic wheel units does not allow to reprogram once they mounted on their wheel for a motor vehicle. One or more updates of the electronic unit are indeed necessary to correct possible software failures or additions of new features.
A possible reprogramming of the wheel unit involves disassembly of the wheel but also of the electronic part of the wheel unit to access the electronics embedded in this wheel unit. This can only be done by destroying the protection provided for the electronic part, which no longer ensures the mechanical integrity of the electronic part.
If reprogramming is necessary, the electronic unit of a wheel is replaced, which entails a financial overcost due to the disassembly process of the wheel by a professional and its replacement by a new electronic unit.
Several other reprogramming solutions for electronic wheel units have therefore been envisaged. It has thus been envisaged to carry out this reprogramming through a bidirectional wireless link using the low frequency reception and radiofrequency transmission stages.
It turns out that the reprogramming of the electronic unit is difficult to achieve or even impossible regardless of the download mode, both in driving and stopping the motor vehicle.
A download process using low frequency and radio frequency stages as reprogramming means is indeed made almost impossible by international regulations. Indeed, according to these regulations, the duration of emission of electromagnetic waves must be only periodic and continuous emissions are prohibited.
In the case of a periodic transmission, each transmission must be less than one second and the silence period must be equivalent to thirty times the transmission time or greater than ten seconds. In addition, a cumulative emission greater than two seconds per hour is prohibited.
It follows that these standards make reprogramming involving significant data transfer that can last from five to ten minutes of low-frequency and radio frequency transmission problematic, without taking into account periods of silence which considerably increase the duration of the transmission. download.
The problem underlying the present invention is to be able to download digital reprogramming data of the electronic unit carried by each wheel of a motor vehicle, including a program update stored in the electronic unit , this without disassembly of the electronic unit by a professional operator or not, without the use of electromagnetic waves and with the shortest possible download time by respecting the emission standards currently in force. To this end, the present invention relates to a method for downloading digital data in an electronic unit for measuring operating parameters of a motor vehicle wheel, the downloading being done by a download tool external to the wheel, the unit electronic device comprising a microprocessor, a memory and at least one sensor for measuring a mechanical parameter relating to the wheel, the external downloading tool transmitting data that the electronic unit receives, characterized in that the method comprises the following steps : • positioning of the external downloading tool at least close to the wheel, • transmission of at least one mechanical waveframe, by the external downloading tool to the electronic unit, representative of the data to be downloaded, Receiving at least said mechanical waveframe by the electronic unit through diary of the sensor for measuring a mechanical parameter, and conversion of mechanical waves into electrical signals and then into digital signals containing the downloaded data in digital form, • storing the downloaded data in the electronic unit.
The present invention therefore proposes the implementation of a solution reducing the use of the electromagnetic communication means, in order to limit the constraints related to international and European regulations. The technical effect obtained by the present invention is to be able to reprogram the electronic unit without disassembly thereof and this as efficiently as possible respecting the electromagnetic emission standards in force. The method according to the invention allows a download of wireless data and low cost and without going through an emission of electromagnetic waves.
The software elements necessary for the implementation of the method according to the present invention are easily integrated in an architecture of the existing electronic wheel units and therefore the implementation of the method does not require a new design of the electronic wheel units. This implementation does not require the addition of electronic components in the electronic unit called wheel unit. In the case of a design of a low cost electronic unit, the deletion of the low frequency stage for receiving data from outside can be considered.
Such a method according to the present invention ensures the protection of the body of the software and provides protection against piracy.
According to two preferred embodiments of the present invention, the mechanical waves transmitted by the external downloading tool are relative to sound vibrations detected and received by a radial acceleration sensor of the wheel or pressure variations transmitted to the wheel detected and received by a tire pressure sensor of the wheel, the radial acceleration sensor or the tire pressure sensor being the sensor for measuring a mechanical parameter of the electronic unit.
This only requires reprogramming of the electronic unit and its sensor accelerometer or its tire pressure sensor to temporarily suspend its function of controlling the speed of rotation of the wheel or the pressure of the tire to give it a function for receiving and downloading data transmitted in at least one mechanical waveframe.
The function of the acceleration sensor or the pressure sensor is then diverted from its initial use. The acceleration sensor is no longer used to measure the movement of the vehicle by the speed and acceleration of the wheel, but to transfer data through the vibrations detected by it. The same is true for the pressure sensor with respect to pressure vibrations transmitted to it by the downloading tool. The tool vibrates at the rate of the data to be transmitted, with a data transmission rate and a specific message indicating that it is necessary to perform a digital conversion of mechanical pulsations into electrical signals and then into digital signals.
Thus, in the case of an electronic unit equipped with an acceleration sensor, the electronic unit will detect the vibrations by means of the acceleration sensor. These vibrations are then converted into electrical signals and digitized in an analog digital converter. The configuration of the analog digital converter is defined specifically for this application.
Advantageously, the method comprises the step of prior reception by the external downloading tool of data to be downloaded in the form of digital signals and conversion of the digital signals by the external download tool into mechanical waves able to be received by the sensor measuring a mechanical parameter. The data to be downloaded are first produced in the form of digital signals that the downloading tool or a control unit associated with this downloading tool transforms into a mechanical waveframe before being transferred to the electronic unit via its sensor. a mechanical parameter.
Advantageously, since the microprocessor and the sensor for measuring a mechanical parameter communicate in a first standard operating configuration mode before downloading data between the external downloading tool and the electronic unit, the method comprises, before the step for transmitting said at least one mechanical waveframe representative of the data to be downloaded, a step of transmitting at least one mechanical waveframe of configuration of the sensor for measuring a mechanical parameter of the electronic unit in a second configuration mode suitable for receiving mechanical waves.
The two functions performed by a sensor for measuring a mechanical parameter, that is to say, on the one hand, its normal operation of measuring a parameter of the wheel and, on the other hand, the downloading of data in the form of different mechanical waves, may differ for example in the measurements made and the transmission intervals of measurements to the electronic unit. It may therefore be necessary for the measuring sensor to be previously adapted to the auxiliary downloading function that it will fulfill for optimal reception and transmission of data between, on the one hand, the download tool and the measurement sensor and, on the other hand, the measurement sensor and the electronic unit.
Advantageously, several mechanical wave frames representative of the data to be downloaded are transmitted by the external downloading tool to the electronic unit, these frames of mechanical waves being fragmented according to the size of the memory of the electronic unit.
Advantageously, the electronic unit communicates in transmission directly or indirectly back with the external download tool. This makes it possible to send a message of good reception of the downloaded data. "Directly" means that it matches with the download tool and "indirectly" means that it matches with a download tool's control unit without going through the download tool. The invention also relates to an assembly comprising an external downloading tool and a motor vehicle wheel, the wheel comprising a tire and an electronic unit for measuring at least one wheel operating parameter, a digital data download. performed between the download tool and the electronic unit, the downloading tool being external to the wheel, the electronic unit comprising a microprocessor, a memory and at least one sensor for measuring a mechanical parameter relating to the wheel , the assembly being characterized in that it implements such a method of downloading digital data, the external downloading tool comprising elements for creating and transmitting mechanical waves relative to the mechanical parameter measured by the sensor from the digital data to be downloaded, the sensor for measuring a mechanical parameter receiving the o The microprocessor comprises mechanical transmission elements which are received by the sensor in digital signals representing the downloaded digital data and elements for storing the downloaded digital data.
The process according to the present invention can be carried out by any operator, professional or otherwise. The downloadable tools that can be used can be of different types and readily available while already being used for other uses. It follows a great flexibility of the implementation of the method according to the invention: the external download tool may be professional or not, for example a dedicated tool or a mobile phone adapted to emit vibrations and to receive data digital. Such downloading tools are compatible with the microprocessors currently on board or being integrated in the electronic units.
According to two preferred embodiments of the present invention, the sensor for measuring a mechanical parameter is a radial acceleration sensor of the wheel or a sensor for measuring the pressure of the tire of the wheel.
According to the first preferred embodiment, when the sensor for measuring a mechanical parameter is the acceleration sensor of the electronic unit, the external downloading tool is a mobile phone, a vibrating device controlled by a central control unit or a professional tool comprising elements for creating and emitting vibratory waves, the mobile phone, the vibration member or the professional tool being applied against the wheel, the electronic unit of the wheel comprising emission elements radio frequency waves back to the central control unit or via a diagnostic socket with the professional tool or transmission elements according to a wireless communication technology with the mobile phone.
In the case of downloading data using a mobile phone, it is possible to receive notifications and download data over the Internet.
According to the second preferred embodiment, when the sensor for measuring a mechanical parameter is the pressure sensor of the electronic unit, for example a sensor comprising a membrane, the external downloading tool is an external compressor connected to a valve of inflating the tire of the wheel, the external compressor being controlled by an element for creating successive pressure variations representative of the digital data to be downloaded. Other features, objects and advantages of the present invention will appear on reading the detailed description which follows and with reference to the appended drawings given as non-limiting examples and in which: FIG. 1 is a diagrammatic representation of a front view of a wheel equipped with an electronic unit for measuring operating parameters of the tire of the motor vehicle wheel, this electronic unit being in accordance with the state of the art, a data download in this unit However, the electronic method can be implemented by a method of downloading digital data in an electronic unit according to the present invention. FIG. 2 is a schematic representation of a logic diagram detailing the steps of an embodiment of the method of downloading data. in an electronic unit according to the present invention, - the FIG. 3 shows three curves, of which a first curve of a mechanical waveframe sent by an external downloading tool to an electronic unit of a motor vehicle wheel, these mechanical waves being detected by a radial acceleration sensor, transformed into electrical signals according to a second curve and digitized according to a third curve in the electronic unit according to an embodiment of the method according to the invention, - Figure 4 shows a motor vehicle, each of whose wheels is characterized by its electronic unit incorporated in the wheel for download with a specific download tool to show various download tools and download modes that may be within the scope of the present invention.
In what follows, reference is made to all the figures taken in combination. When reference is made to one or more specific figures, these figures are to be taken in combination with the other figures for the identification of the designated reference numerals.
Referring to all the figures but more particularly to FIGS. 2 and 4, FIG. 2 showing a logic diagram detailing the steps of an embodiment of the method according to the invention and FIG. 4 showing several embodiments of a set formed of an external download tool 40a to 40d and an electronic unit 10 for measuring the operating parameters of a motor vehicle wheel 50, the present invention relates to a method of downloading digital data in an electronic unit 10 of 20. These digital data can be used for the reprogramming of the electronic unit 10.
It should be borne in mind that certain process steps illustrated in FIG. 2 are not essential for the implementation of the method according to the present invention. The steps of the process will be detailed not in their chronological order but according to their importance for the implementation of the method according to the invention. It should also be borne in mind that other possible steps of the process are not explicitly illustrated in Figure 2.
Downloading digital data is done by a download tool 40a to 40d external to the wheel 20, several embodiments of which are shown in FIG. 4 and which will be subsequently detailed. The electronic unit 10 comprises a microprocessor, a memory and at least one measurement sensor 12 of a mechanical parameter relating to the wheel 20, the external download tool 40a to 40d transmitting data that the electronic unit 10 receives.
According to the invention, the method comprises a step of positioning the download tool 40a to 40d external at least near the wheel 20 incorporating the electronic unit 10. This step is followed by the emission of at least one mechanical wave frame 8, 8a by the download tool 40a to 40d external to the electronic unit 10 representative of the data to download.
This transmission step is referenced 5 in FIG. 2. The mechanical wave frame 8, 8a contains mechanical waves specifically adapted to be detected by a sensor present in the electronic unit 10, for example but not only by a sensor. 12 radial acceleration or a tire pressure sensor 22 of the wheel 20 of the vehicle.
The method comprises a step of receiving at least said mechanical wave frame 8, 8a by the electronic unit 10 via the measurement sensor 12 of a mechanical parameter. This step is followed by a step of converting the mechanical waves into electrical signals and then into digital signals, as can be seen in FIG. 3, containing the data downloaded in digital form. The final step of the essential steps is the storage of the downloaded data in the electronic unit 10.
According to a first preferred embodiment of the present invention, the mechanical waves transmitted by the download tool 40a to 40d external relate to acoustic vibrations detected and received by a radial acceleration sensor 12 of the wheel 20. In this case, the 12 radial acceleration sensor is the sensor for measuring a mechanical parameter of the electronic unit 10 and the mechanical parameter is a vibration advantageously acoustic.
In normal operation, the radial acceleration sensor 12 detects gravitational force variations due to the rotation of the wheel 20 by establishing a sinusoid whose period gives the speed of rotation as a function of the diameter of the wheel 20. However, the sensor of Radial acceleration 12 can be very apt to detect vibrations when it is put into a specific mode of vibration detection. In this case, the download tool 40a to 40d external can be applied against the wheel 20.
According to a second preferred embodiment of the present invention, the mechanical waves transmitted by the download tool 40a to 40d external relate to pressure variations transmitted to the wheel 20 detected and received by a pressure sensor of the tire 22 of the wheel 20 In this case, the pressure sensor of the tire 22 is the measurement sensor 12 of a mechanical parameter of the electronic unit 10 and the mechanical parameter is a pressure. In fact, in FIG. 4, the reference 12 designates both a radial acceleration sensor and a pressure sensor.
The method according to the invention may comprise a step of prior reception by the external downloading tool 40a to 40d of data to be downloaded in the form of digital signals and conversion of the digital signals by the download tool 40a to 40d external in mechanical waves. able to be received by the measurement sensor 12 of a mechanical parameter. The external downloading tool may only be a mechanical wave creation device 40c, 40d driven by a pressure variation creation element 51b or a central control unit 51a. For external download tools 40b to 40d, a central control unit 51a or 51b, for example in the form of a vibration generating element 51a or a pressure variation creating element 51b, may be the source of the data to be downloaded in digital form and sent to the download tool 40b to external 40d pulses allowing the creation of mechanical waves.
The microprocessor of the electronic unit 10 and the measurement sensor 12 of a mechanical parameter operate in a first standard operating configuration mode before downloading data between the external download tool 40a to 40d and the electronic unit 10 with a specific data rate. For example, a radial acceleration sensor 12 is programmed to follow the gravitational force, making measurements and then sending these measurements to the microprocessor at regular and predetermined time intervals with a data rate specific to this normal operating pattern.
In this example, it is necessary to reprogram the radial acceleration sensor to enable it to detect the vibrations sent to it by the external download tool 40a to 40c and to adjust the measurement time intervals to match them. the period of vibratory waves.
For this, the method comprises, before the step of transmitting said at least one mechanical waveframe 8, 8a representative of the data to be downloaded, a step which is referenced in FIG. 2, a transmission step of FIG. at least one mechanical wave field of configuration of the measurement sensor 12 of a mechanical parameter of the electronic unit 10 in a second configuration mode adapted to receiving the mechanical waves. This transmission step is referenced 1 in FIG.
This transmission step referenced 1 can be done with a data rate specific to the first mode of standard operating configuration of the acceleration sensor and the microprocessor of the electronic unit 10.
Still with reference to FIG. 2 taken in conjunction with FIG. 4, it may then be questioned as to whether the configuration mechanical wave frame has been received or not by the measurement sensor 12 of a mechanical parameter. of the electronic unit 10, which is done in step 2. If the answer is yes, symbolized by O, it is switched to the configuration mode adapted for the transmission of mechanical waves. This is illustrated by the step referenced 3 in FIG. 2. If the answer is no, symbolized by N, it is returned to the transmission step referenced 1 and previously described. In step 4, it is possible to carry out a query to verify the presence of the external download tool 40a to 40d which is applied near the electronic unit 10, advantageously against the wheel 20, in particular in the case mechanical waves in the form of vibrations. For example, radiofrequency waves can be transmitted by the electronic unit 10, since the electronic unit 10 currently uses such a transmission mode, to the external download tool 40a to 40d or to a remote transmission unit. control unit 51a, 51b driving the operation of the download tool 40a to 40d external. Another mode of emission is also possible as it will be later detailed. The external download tool 40a to 40d or its control unit 51a, 51b can then respond by emitting mechanical waves to the electronic unit 10 in the second configuration mode specific to the transmission of mechanical waves. To validate the configuration in reception of mechanical waves according to this second mode of configuration, the electronic unit 10 can radiofrequency transmit to the external download tool 40a to 40d or its control unit 51a, 51b a validation message of the mechanical wave reception configuration according to the second configuration mode.
If the answer to this questioning is yes O, it is proceeded to the step of emitting at least one mechanical wave frame 8.8a by the download tool 40a to 40d external to the representative electronic unit 10 data to download, this step having already been mentioned as an essential step of the process and having been referenced 5.
After this step of transmitting the data to be downloaded in the form of mechanical waves, it is possible to carry out a questioning 6 relating to the validation of the data. If the response to a data validation is non-N, it is returned to the transmission step of the data to be downloaded in the form of mechanical waves for the completion of the downloaded data.
If the response to a data validation is yes O, it is passed to the end step 7 which restores the first normal configuration mode in place of the second configuration mode adapted to reception of mechanical waves. The electronic unit 10 can transmit a radio frequency validation message to the external download tool 40a to 40d or the control unit 51a, 51b of the external download tool 40a to 40d.
Several mechanical wave frames 8, 8a representative of the data to be downloaded can be transmitted successively by the external download tool 40a to 40d to the electronic unit 10. These mechanical wave frames 8, 8a can be fragmented according to the size of the memory of the electronic unit 10. The questioning 6 serves to verify that all the mechanical wave frames 8, 8a have been detected and received in the electronic unit 10.
Figure 3 shows a conversion mode of a mechanical wave frame 8 into a digital signal frame. The mechanical waves 8 are the raw data detected by the sensor, the following representations are the result after filtering, of the low-pass type, for example, of the shape of the signal, described as the envelope of the detected mechanical waves. The mechanical waves, for example vibrations in the form of acoustic pulses, are emitted periodically by the external download tool 40a to 40d. At the top curve, the vibrations determine electrical signals, these framing closer to the vibrations. At the intermediate curve below the top curve, a high threshold 9a and a low threshold 9b are determined for these electrical signals, the high threshold 9a corresponding to a higher electrical signal amplitude than the low threshold 9b. When an electrical signal exceeds the high threshold 9a, this electrical signal corresponds to a digital signal 1. The digital signal remains at 1 until the electric signal falls below the low threshold 9b. At this time, the digital signal goes to 0.
The digital signal remains at 0 until the vibrations return above the high threshold 9a and the signal returns to a digital signal. A frame of digital signals is thus obtained as a function of the mechanical wave frame 8, passing through the electrical signals. This is valid for a wave of pressure waves as vibratory waves.
Referring to FIG. 4, the invention also relates to an assembly comprising an external download tool 40a to 40d and a motor vehicle wheel 50. In FIG. 4, four downloading tools 40a to 40d are shown simultaneously but It is obvious that it is not necessarily necessary that four different or different downloading tools be in simultaneous action on a respective wheel of a motor vehicle.
It is possible, however, to use an external download tool 40a to 40d for each wheel 20 and to perform the downloads in the electronic unit 10 of each wheel 20 simultaneously. In this case, the download tools are not necessarily different from each other but rather of the same type.
In addition, for the sake of clarity in FIG. 4 in order to clearly indicate which reception and transmission modes are used between the electronic unit 10 and a specific external downloading tool 40a to 40d, the downloading tools are shown spaced apart. of the associated wheel 20, while for the most part, especially for vibrating waves, the download tools 40a to 40c should be applied against the wheel 20, which is not necessary for the download tool 40d relating to pressure waves.
The wheel 20 comprises a tire 22 and an electronic unit 10 for measuring at least one operating parameter of the wheel 20. In accordance with the invention, a digital data download is performed between an external download tool 40a to 40d and an electronic unit 10, the download tool 40a to 40d being external to the wheel 20.
In known manner, as previously mentioned, the electronic unit 10 which can be fastened to the rim or the tire or to a valve 23 for inflating the tire of the wheel 20, this inside the tire, comprises a microprocessor, a memory and at least one measurement sensor 12 of a mechanical parameter relative to the wheel 20. The external download tool 40a to 40d may comprise elements for creating and transmitting at least one relative mechanical waveframe to the mechanical parameter measured by the sensor from the digital data to be downloaded.
The digital data can reach the external download tool 40a to 40d by a control unit 51a, 51b or by a server 51c by any transmission means appropriate to the external download tool 40a to 40d. The measurement sensor 12 of a mechanical parameter detects the transmitted mechanical waves and communicates them to the microprocessor of the electronic unit 10 of the wheel 20.
The microprocessor of the electronic unit 10 of the wheel 20 comprises elements for converting the mechanical waves received by the sensor into digital signals representing the downloaded digital data and elements for storing the downloaded digital data.
According to two preferred embodiments of the present invention, the measurement sensor 12 of a mechanical parameter is a radial acceleration sensor of the wheel 20 or a sensor for measuring the tire pressure of the wheel 20.
According to the first preferred embodiment, when the measurement sensor 12 of a mechanical parameter is the acceleration sensor of the electronic unit 10, the external downloading tool 40a to 40c is a mobile phone 40a, a vibrating body 40c driven by a central control unit 51a or a professional tool 40b comprising elements for creating and emitting vibration waves. The external downloading tool can also be a marking, for example in relief, on the ground.
The transmission time of the mechanical wave frame 8, 8a is a function of the ability of the download tool 40a to 40d to provide data in the form of waves. An acoustic signal will be faster than a signal made of pressure variations.
All these external downloading tools, namely the mobile phone 40a or the computer, the vibration member 40c or the professional tool 40b may preferably be applied against the wheel 20. The electronic unit 10 of each wheel 20 may comprise RF radiofrequency transmission elements in return to the central control unit 51a, an OBD diagnostic socket with the professional tool 40b or transmission elements according to a wireless communication technology SF with the mobile phone 40a , for example technologies known under the trademarks Wl-Fi® and Bluetooth®. Any wheel unit 20 may correspond in RF radio frequency emission with a central wheel control unit 51 and in reception by low frequency waves BF, this central wheel control unit 51 being embedded in the motor vehicle 50 .
The mobile phone 40a or the computer can receive the digital data via the Internet I from a server 51c, for example by 3G, 4G, GSM networks or by wireless communication technologies of the Wl-Fi® and Bluetooth® type. and NFC®, without this being limiting.
According to the second preferred embodiment, when the measurement sensor 12 of a mechanical parameter is the pressure sensor of the electronic unit 10, the external downloading tool is an external compressor 40d connected by a pipe to an inflation valve 23. of the tire 20. The external download tool 40d is not necessarily applied against the wheel 20 but is however disposed near the wheel 20. The external compressor 40d can be controlled by a variable creation element successive pressure 51b representative of the digital data to be downloaded which may be a control unit similar to the aforementioned control units.
In general, the present invention is applicable to any electronic unit 10 requiring data transfer or reprogramming, the electronic unit 10 being equipped with a measurement sensor 12 of a mechanical parameter that can be transmitted in the form of waves. accelerometer and more particularly to an electronic unit 10 so access is difficult or impossible.

权利要求:
Claims (10)
[1" id="c-fr-0001]
A method of downloading digital data in an electronic unit (10) for measuring operating parameters of a wheel (20) of a motor vehicle (50), the downloading being carried out by a download tool (40a to 40d) external to the wheel (20), the electronic unit (10) comprising a microprocessor, a memory and at least one measurement sensor (12) of a mechanical parameter relating to the wheel (20), the download tool (40a to 40d) external transmitting data that the electronic unit (10) receives, characterized in that the method comprises the following steps: • positioning of the external download tool (40a to 40d) at least near the wheel (20). ), • transmitting at least one mechanical waveframe (8, 8a) by the external downloading tool (40a to 40d) to the electronic unit (10) representative of the data to be downloaded, • receiving at least said frame of o by the electronic unit (10) via the measuring sensor (12) of a mechanical parameter and conversion of the mechanical waves into electrical signals and then into digital signals containing the data downloaded in digital form , • storing the downloaded data in the electronic unit (10).
[2" id="c-fr-0002]
2. Download method according to claim 1, characterized in that the mechanical waves transmitted by the external download tool (40a to 40d) relate to: acoustic vibrations (8) detected and received by an acceleration sensor radial of the wheel (20), the external download tool (40a to 40d) being applied against the wheel (20), or • pressure variations (8a) transmitted to the wheel (20) detected and received by a sensor of the tire (22) of the wheel (20), the radial acceleration sensor or the tire pressure sensor (22) being the measuring sensor (12) of a mechanical parameter of the electronic unit (10). ).
[3" id="c-fr-0003]
3. Download method according to one of claims 1 or 2, characterized in that it comprises the step of prior receipt by the external download tool (40a to 40d) data to download as digital signals and for converting the digital signals by the external downloading tool (40a to 40d) into mechanical waves that can be received by the measurement sensor (12) of a mechanical parameter of the electronic unit.
[4" id="c-fr-0004]
The downloading method according to claim 3, wherein the microprocessor and the measurement sensor (12) of a mechanical parameter communicate according to a first standard operating configuration mode before downloading data between the download tool (40a to 40d) and the electronic unit (10), characterized in that the method comprises, before the step of transmitting said at least one mechanical waveframe (8, 8a) representative of the data to be downloaded, a step transmitting at least one mechanical waveframe for configuring the measurement sensor (12) of a mechanical parameter of the electronic unit (10) in a second configuration mode suitable for receiving the mechanical waves.
[5" id="c-fr-0005]
5. Download method according to any one of the preceding claims, characterized in that a plurality of mechanical wave fields (8, 8a) representative of the data to be downloaded are transmitted by the external download tool (40a to 40d) to the user. electronic unit (10), these mechanical wave fields (8, 8a) being fragmented according to the size of the memory of the electronic unit (10).
[6" id="c-fr-0006]
6. Download method according to any one of the preceding claims, characterized in that the wheel unit (20) communicates in transmission (RF, OBD, SF) directly or indirectly back with the download tool (40a to 40d) external.
[7" id="c-fr-0007]
7. An assembly comprising an external download tool (40a to 40d) and a motor vehicle wheel (20) (50), the wheel (20) comprising a tire (22) and an electronic measuring unit (10) minus one operating parameter of the wheel (20), a digital data download being performed between the download tool (40a to 40d) and the electronic unit (10), the download tool (40a to 40d) being external to the wheel (20), the electronic unit (10) comprising a microprocessor, a memory and at least one measuring sensor (12) of a mechanical parameter relating to the wheel (20), characterized in that it a method for downloading digital data according to any one of the preceding claims, the external downloading tool (40a to 40d) comprising elements for creating and transmitting mechanical waves relative to the mechanical parameter measured by the sensor from me sure (12) of a mechanical parameter from the digital data to be downloaded, the measurement sensor (12) of a mechanical parameter receiving the transmitted mechanical waves and communicating them to the microprocessor, the microprocessor comprising mechanical wave conversion elements received by the sensor in digital signals representing the downloaded digital data and storage elements of the downloaded digital data.
[8" id="c-fr-0008]
8. An assembly according to claim 7, characterized in that the sensor for measuring a mechanical parameter is a radial acceleration sensor (12) of the wheel (20) or a sensor for measuring the tire pressure (22). the wheel (20).
[9" id="c-fr-0009]
An assembly according to claim 8, characterized in that, when the measuring sensor (12) of a mechanical parameter is the acceleration sensor (12) of the electronic unit (10), the downloading tool ( 40a to 40d) is a mobile phone (40a), a vibratory organ (40c) controlled by a central control unit (51a) or a professional tool (40b) comprising elements for creating and transmitting vibratory waves, the mobile telephone (40a), the vibrating member (40c) or the professional tool (40b) being applied against the wheel (20), the electronic unit (10) of the wheel (20) respectively comprising emission elements in return for radiofrequency (RF) waves to the central control unit (51 a) or via a diagnostic socket (OBD) with the professional tool (40b) or emission elements according to a technology wireless communication (SF) with mobile phone (40a) .
[10" id="c-fr-0010]
10. An assembly according to claim 8, characterized in that, when the measuring sensor (12) of a mechanical parameter is the pressure sensor of the electronic unit (10), the external downloading tool is a compressor ( 40d) connected to a valve (23) for inflating the tire (22) of the wheel (20), the external compressor (40d) being controlled by a variable pressure creating element (51b) representative of the digital data to Download.

类似技术:

---

公开号 | 公开日 | 专利标题

---

FR3050690A1|2017-11-03|METHOD FOR DOWNLOADING DIGITAL DATA IN AN ELECTRONIC UNIT FOR MEASURING OPERATING PARAMETERS OF A MOTOR VEHICLE WHEEL BY TRANSMISSION OF MECHANICAL WAVES

---

EP1613488B1|2014-07-16|Method and device for treating a set of components for the wheel of a vehicle

---

EP1593532A2|2005-11-09|System for controlling the tyre pressure of a motor vehicle

---

EP3306576A1|2018-04-11|Method and system for secure access to a determined space by means of a portable object

---

WO2017063740A1|2017-04-20|Method for determining the radial acceleration of a vehicle wheel

---

EP1813448B1|2013-01-09|Tyre, wheel or tyre and wheel assembly equipped with a device for counting the number of rotations.

---

EP2349749B1|2014-12-17|Method and device for identifying the position of a wheel of a vehicle

---

WO2009010470A1|2009-01-22|Method for detecting the scrambling of a radiocommunication network, and corresponding computer program product, storage means and circuit

---

EP2085943A1|2009-08-05|Method for detecting the movement of a vehicle and corresponding device

---

FR3066721B1|2019-06-07|METHOD FOR IDENTIFYING AT LEAST ONE TRANSMITTER FOR MONITORING THE PRESSURE OF A TIRE OF A MOTOR VEHICLE BY ASSOCIATION WITH ONE OF THE WHEELS OF SAID MOTOR VEHICLE

---

WO2020020743A1|2020-01-30|Optimisation of wireless communications of a tyre-pressure-monitoring system for a motor vehicle

---

WO2020193716A1|2020-10-01|Method for controlling an activation of a function by a control module of a wheel unit

---

FR2986185A1|2013-08-02|Method for controlling wheel assembly operating mode of monitoring system used for monitoring pressure of tires in car, involves receiving pneumatic control signal by wheel assembly for activation of determined operating mode

---

FR3045498A1|2017-06-23|METHOD FOR ADAPTING THE STRATEGY FOR ACQUIRING RADIATION ACCELERATION MEASUREMENTS OF WHEELS OF A VEHICLE

---

EP3772420A1|2021-02-10|Method for managing the energy of a system for verifying the inflation pressure of the tires of an aircraft

---

FR2887103A1|2006-12-15|Functional parameter e.g. pressure, representing data frame transmitting method for monitoring system, involves setting up time intervals by random calculation using module identification code and vehicle wheel parameter representing data

---

EP2085941B1|2012-02-29|Method for transmitting signals from electronic boxes mounted on the wheels of a vehicle, directed to a central unit mounted on said vehicle

---

FR3075550A1|2019-06-21|METHOD AND SYSTEM FOR DETECTING AND TRACING A VOTED WHEEL

---

FR3082003A1|2019-12-06|METHOD OF PAIRING A MEASUREMENT MODULE AND ITS ASSOCIATED WHEEL WITH ANGULAR POSITION FILTRATION

---

FR2934402A1|2010-01-29|DEVICE FOR LOCATING THE RIGHT AND LEFT POSITION OF A PNEUMATIC ASSEMBLY AND WHEEL OF A VEHICLE

---

FR2863204A1|2005-06-10|Motor vehicle wheels tracking method, involves transmitting non-coded signals for wheel unit actuation or hands free function, by antennas, where transmitters and antennas are controlled by control device connected to central unit

---

WO2020188017A1|2020-09-24|Method for remote control of an activation of a command in a wheel unit

---

FR3078288A1|2019-08-30|METHOD OF PAIRING AT THE INITIATIVE OF A CALCULATOR OF A MEASUREMENT MODULE MOUNTED IN A MOTOR VEHICLE WHEEL

---

FR3033195A1|2016-09-02|METHOD FOR CONTROLLING A PROCESSOR OF AN ELECTRONIC HOUSING MOUNTED ON A WHEEL OF A VEHICLE

---

FR3077410A1|2019-08-02|METHOD OF COMMUNICATING BETWEEN A PLURALITY OF WHEEL UNITS AND WITH A REMOTE CONTROL AND / OR CONTROL DEVICE

同族专利:

---

公开号 | 公开日

---

US10943412B2|2021-03-09|

---

FR3050690B1|2018-05-04|

---

CN107415601B|2019-11-22|

---

US20170316623A1|2017-11-02|

---

CN107415601A|2017-12-01|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE3446248A1|1984-12-19|1986-06-19|Robert Bosch Gmbh, 7000 Stuttgart|SENSOR FOR MEASURING PHYSICAL SIZES AND METHOD FOR ADJUSTING THE SENSOR|

---

EP1602908A2|2004-06-04|2005-12-07|Société de Technologie Michelin|Calibration of saw interrogators|

---

US20120050029A1|2010-08-27|2012-03-01|San-Chuan Yu|Programmable tire monitoring device and its method of use|

---

GB2500697A|2012-03-30|2013-10-02|Schrader Electronics Ltd|Vehicle monitoring system tool|

---

US8024084B2|1995-06-07|2011-09-20|Automotive Technologies International, Inc.|Vehicle diagnostic techniques|

---

US20030216845A1|2002-05-15|2003-11-20|Williston Scott Lawton|Automatic tire inflation based on vehicle loading conditions|

---

FR2870031B1|2004-05-04|2006-06-16|Michelin Soc Tech|IMPROVED METHOD FOR MONITORING A PNEUMATIC, PNEUMATIC TIRE FOR ITS IMPLEMENTATION, AND APPLICATION|

---

US20080117036A1|2006-11-17|2008-05-22|Thomas Kenny|Programmable wireless sensors|

---

CN102303489B|2011-06-28|2013-10-30|深圳市元征软件开发有限公司|Method and system for flexibly configuring tire pressure monitor system transmitter|

---

US9122423B2|2012-12-12|2015-09-01|Continental Automotive Systems, Inc.|Methods, systems and tools for programming tire pressure monitoring sensors|

---

CN103587357B|2013-11-08|2017-02-08|深圳市道通科技股份有限公司|TPMS sensor upgrade method and device|

---

DE102014112652A1|2014-01-17|2015-07-23|Huf Hülsbeck & Fürst Gmbh & Co. Kg|Method for adapting a tire pressure monitoring device to a vehicle type and a tire pressure monitoring system with at least one tire pressure monitoring device and tire pressure monitoring device adaptable thereto by this method|

---

US9902217B2|2015-07-28|2018-02-27|Ford Global Technologies, Llc|System and method for managing tire pressure for a trailer|CN108545060A|2018-06-12|2018-09-18|镇江神行太保科技有限公司|A kind of automatic tire inflation system for capableing of remote monitoring|

---

GB2584847A|2019-06-17|2020-12-23|Airbus Operations Ltd|Tyre monitoring device configuration|

---

GB2584854A|2019-06-17|2020-12-23|Airbus Operations Ltd|Configuration mode entry for a tyre monitoring device|

法律状态:
2017-05-23| PLFP| Fee payment|Year of fee payment: 2 |

---

2017-11-03| PLSC| Publication of the preliminary search report|Effective date: 20171103 |

---

2018-05-22| PLFP| Fee payment|Year of fee payment: 3 |

---

2019-05-23| PLFP| Fee payment|Year of fee payment: 4 |

---

2020-05-22| PLFP| Fee payment|Year of fee payment: 5 |

---

2021-05-20| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

---

申请号 | 申请日 | 专利标题

---

FR1653934A|FR3050690B1|2016-05-02|2016-05-02|METHOD FOR DOWNLOADING DIGITAL DATA IN AN ELECTRONIC UNIT FOR MEASURING OPERATING PARAMETERS OF A MOTOR VEHICLE WHEEL BY TRANSMISSION OF MECHANICAL WAVES|

---

FR1653934|2016-05-02|FR1653934A| FR3050690B1|2016-05-02|2016-05-02|METHOD FOR DOWNLOADING DIGITAL DATA IN AN ELECTRONIC UNIT FOR MEASURING OPERATING PARAMETERS OF A MOTOR VEHICLE WHEEL BY TRANSMISSION OF MECHANICAL WAVES|

---

US15/493,876| US10943412B2|2016-05-02|2017-04-21|Method for remotely loading digital data to an electronics unit for measuring operating parameters of a motor vehicle wheel, by transmission of mechanical waves|

---

CN201710293081.2A| CN107415601B|2016-05-02|2017-04-28|For by the method for numerical data remote loading to electronic unit|