FR2772128A1 - DEVICE AND METHOD FOR DETECTING WATER ON A WINDSHIELD AND AUTOMATIC WIPER SYSTEM INCLUDING THIS DEVICE - Google Patents

Abstract

The invention concerns a device (1) for detecting water on a windscreen (PB), comprising an equipment for generating a microwave electromagnetic radiation in the proximity of a delimited portion (PD) of said windscreen (PB), said equipment comprising a microwave oscillator (OS) and reflected power detector (Pr). The generating equipment comprises a resonant cavity (CR) with an aperture (OU) closed by the windscreen portion (PD), and an excitation sensor (AN) arranged inside said resonant cavity (CR) and connected to the microwave oscillator (OS) by a coupler (CP) whereto is connected the reflected power detector. The microwave cavity (CR) and the excitation sensor (AN) are arranged such that the detection signal (Vd) is substantially proportional to the average thickness of the water film present on the windscreen portion (PD). The invention is useful for the automatic wipers.

Description

"DEVICE AND METHOD FOR DETECTING WATER ON A WINDSHIELD,
AND AUTOMATIC WIPER SYSTEM INCLUDING THIS DEVICE "
The present invention relates to a device for detecting water on a windshield. It also relates to a method implemented in this device, as well as an automatic wiper system including this detection device.

 The technical field of the invention is that of automotive equipment, and in particular for the automation of wipers for any type of vehicle. I1 is to provide a rain detection device, which is capable of triggering the automatic start of the wipers of an automobile. In practice, it is necessary to obtain an electrical signal proportional to the amount of rainwater deposited on a windshield.

 US patent 3,786,330 discloses an automatic windscreen wiper system implementing a water detection device on a windshield comprising a microwave oscillator, a waveguide designed to irradiate the microwaves generated by the oscillator on the windshield and means for detecting any change in the fraction of microwaves reflected or transmitted by this windshield. This water detection device delivers a detection signal whose amplitude varies as a function of the quantity of drops of water adhering to the windshield, and which is applied at the input of a differential amplifier to be compared to a signal of reference corresponding to an absence of drops of water on the windshield.

 But the numerical examples exposed in this document show that this detection device is not able to provide quantitative information on the thickness of the water film, which is directly usable. In particular, it does not seem possible to establish for this detection device a law of variation of the output signal as a function of the average thickness of the film of water on the windshield. However, the existence of such a law of variation would allow automation of the wiper control more efficient than the simple current detection of the presence or absence of water drops on a windshield.

 The object of the present invention is to remedy these drawbacks by proposing a device for detecting drops of water on a windshield which delivers a detection signal which is representative of the average thickness of the film of water present on the windshield.

This objective is achieved with a device for detecting water on a windshield, comprising:
means for generating microwave electromagnetic radiation near a defined portion of this windshield,
- means for detecting a reflected power,
- And means for delivering a detection signal from the detection of the reflected power.

According to the invention, the microwave generator means comprise:
a resonant cavity having an opening closed by the portion of the windshield, and
- an excitation probe placed inside said resonant cavity and connected to the microwave oscillator via coupling means to which the means for detecting the reflected power are connected, this microwave cavity and this excitation probe being arranged so that the detection signal is substantially proportional to the average thickness of a film of water present on the windshield portion.

 Thus, with the detection device according to the invention, it becomes possible to achieve more precise and efficient control of the wiper systems. It should be noted that the excitation probe is also a detector probe.

 In order to avoid the triggering of the detection device according to the invention by an external source of electromagnetic radiation, it is advantageously possible to provide that the microwave generator means also comprise means for modulating at low frequency the output signal from the oscillator. microwave.

 In a first embodiment of a detection device according to the invention, the resonant cavity is of substantially parallelepiped shape and the excitation probe is fixed substantially in the center of a face of larger dimension adjacent to the open face of the cavity resonant.

 Optimal operation of the detection device according to the invention has been obtained by designing a resonant cavity whose respective dimensions of the long side, the short side and the depth of the resonant cavity are substantially equal to B / 2, B / 4 and 4X / 5, X being the wavelength of the microwave radiation emitted in the resonant cavity.

 In a second embodiment of the detection device according to the invention, the resonant cavity is of circular section. This embodiment has the advantage of easier machining with equal precision.

According to another aspect of the invention, a method is proposed for detecting the presence of water on a windshield of a vehicle, implemented in the device according to the invention, comprising:
- an emission of microwave electromagnetic radiation near a defined portion of this windshield,
- a measurement of the power reflected by the resonant cavity, and
- a supply of a detection signal from the detection of the reflected power.

 This process is characterized in that a measurement is made by coupling of the power reflected by the resonant cavity and in that the detection signal is substantially proportional to the average thickness of the film of water present on the barrier portion. broken.

 According to yet another aspect of the invention, an automatic windscreen wiper system for a vehicle is proposed, including a water detection device according to the invention. The resonant cavity of this detection device can for example be arranged behind the central mirror.

Other features and advantages of the invention will appear in the description below. In the appended drawings given by way of nonlimiting examples:
- Figure 1 illustrates the concept of detection put
used in a detection device according to
the invention;
- Figure 2 is a diagram of an example of
production of a detection device according to the invention;
- Figure 3 illustrates the operating mode implemented
work with a probative model of the
detection according to the invention; and
- Figure 4 illustrates the evolution of power
reflected as a function of the thickness of the water film
equivalent, obtained experimentally with the
Evidence model of Figure 3.

 We will now describe an embodiment of a detection device 1 according to 1 invention, with reference to FIGS. 1 and 2.

The detection device 1 according to the invention comprises a resonant cavity CR, a microwave RF source, a coupler CP disposed between this source and the cavity CR, and a circuit MP for measuring the reflected power Pr. The resonant cavity CR, of substantially parallelepiped shape, has an opening
OR pressed against a delimited PD portion of the windshield
PB inside the passenger compartment of the vehicle and an excitation and detector probe AN fixed via a coupling orifice OC in the center of a face adjacent to the opening
OR. The optimal dimensions of the CR resonant cavity are respectively for the long side, the short side and the thickness, B / 2, B / 4 and 4x / 5.

The raindrops 2 are deposited on the glass wall of the windshield PB closing the resonant cavity CR. The cavity CR is excited by the oscillator OS at a frequency chosen from the resonant modes sensitive to the presence of material in the opening OR. The power
Pr reflected by the cavity CR, obtained with a directional coupler CP, is detected. If the detection of the amplitude of the reflected signal is linear, the output voltage Vd is proportional to the thickness of the equivalent water film.

 In order to avoid triggering of the device by an external source of electromagnetic radiation, the HF source is modulated in all or nothing by a low frequency oscillator, for example at 1000 Hz. The detected signal is then itself modulated at the same frequency . The square AC output signal obtained has an amplitude which is then representative of the presence of the film of water. External radiation can only decrease the amplitude of this signal and therefore inhibit the device but not trigger it.

 The processing of the output signal consists, for example, of synchronous detection. The output information is for example then associated with the position information of the wipers to control their speed.

 According to a preferred embodiment of the invention, the detection device comprises a minimum number of components.

The 5.8 GHz HF microwave source (frequency chosen in the ISM band: 5.725 to 5.875 GHz) comprises an OS transistor oscillator associated with a RD dielectric resonator. A detailed description of such a mounting can be found in Joseph's document "A survey of stable and low noise dielectric resonator oscillators"
ANDREWS (VARIAN ASSOCIATES, January 1985). The CP coupler is produced on a printed circuit from two parallel lines. Detection uses a simple diode
D followed by a capacitor C and an amplifier. The low frequency generator, acquisition and processing of the output signal are included in an MC microcontroller. A TTL / MOS IN interface circuit is interposed between the microcontroller MC and the HF oscillator to apply the command CO signal delivered by the microcontroller.

 The VR regulation of the power supply taken on the 12V voltage of the vehicle is either included in the MC microcontroller, or an additional component.

 The excitation frequency of the cavity CR, which is likely to vary according to manufacturing tolerances and the type of windshield, is adjustable by means of an adjustment screw of the dielectric resonator RD.

 The power Pr reflected by the cavity CR, which is likely to vary depending on the type of windshield, is adjusted to a minimum value by means of an adjustment screw passing through a wall of this cavity.

 It is also possible to envisage another embodiment in which the resonant cavity has a circular section, which offers the advantage of easier machining with equal precision.

A probative model 1 ′ was produced for which a frequency approximately ten times lower was chosen and consequently a sensor of dimensions ten times larger, with reference to FIG. 3. We used, to produce the resonant cavity CR , a power guide coupler of large dimension (rectangular section of 25x12.5 cm) closed at the lower end by a metal plate and at the upper part by a glass plate PB '. The original coupling device at the end of the type connector
N located in the center of the larger face has been replaced by a conductive wire AN 'with a length of about 9 cm.

The cavity CR 'is excited from a Hewlett-Packard 8753A AR network analyzer operating between 0.3 and 3 GHz. In this practical case, the optimal excitation frequency is equal to 620 MHz, which corresponds to a wavelength of 50 cm. The AR analyzer displays the relative reflected power in dB. A nominal value has been noted which is the average of the minimum and maximum values observed when any objects are presented in front of the cavity at a distance greater than a wavelength. We deduce from the reflected power value Pr a value of the amplitude Vd of the signal detected by the relation:
Vd = 10 (Pr / 2O)
The experimental results obtained with this probative model 1 ′ show a substantially linear variation in the output voltage Vd as a function of the thickness of the equivalent water film, as illustrated in FIG. 4. After having made an adjustment on the points of measurement, we observe a linear relation of the type:
Vd = 0.0095 + 0.52.h
where h represents the thickness of the equivalent film.

 It should be noted that a detection device according to the invention can be easily installed within an automatic wiper system designed for example to achieve proportional control of the wiping speed as a function of the average thickness. water film on the windshield.

 Of course, the invention is not limited to the examples which have just been described and numerous modifications can be made to these examples without departing from the scope of the invention. Thus, it is possible to design resonant cavities of dimensions different from those which have just been described.

Claims (10)

CLAIMS 1. Device (1) for detecting water on a windshield (PB), comprising: - means (HF, CR) for generating microwave electromagnetic radiation near a delimited portion (PD) of this windshield breeze (PB), these generating means (HF, CR) comprising a microwave oscillator (OS), - means (MP) for detecting a reflected power (Pr), - and means for delivering a water detection signal ( Vd) from the measurement of the reflected power, characterized in that the microwave generating means (HF, CR) comprise: - a resonant cavity (CR) having an opening (OU) closed by the portion of windshield PD, and - an excitation probe (AN) placed inside said resonant cavity (CR) and connected to the microwave oscillator (OS) via coupling means (CP) to which the means (MP) for detecting the reflected power, this microwave cavity (CR) and this probe exciter (AN) being arranged so that the detection signal (Vd) is substantially proportional to the average thickness of the film of water present on the windshield portion (PD). 2. Device (1) according to claim 1, characterized in that the microwave generating means (HF, CR) further comprise means (MC, CO, IN) for modulating at low frequency the microwave signal from the microwave oscillator (BONE). 3. Device (1) according to one of claims 1 or 2, characterized in that the microwave generator means (HF, CR) further comprises a dielectric resonator (RD) associated with the microwave oscillator (OS). 4. Device (1) according to claim 3, characterized in that it further comprises means for adjusting the dielectric resonator (RD) so as to adjust the resonance frequency. 5. Device (1) according to any one of the preceding claims, characterized in that it further comprises means for adjusting the resonant cavity (CR) so as to adjust the reflected power to a minimum value. 6. Device (1) according to any one of the preceding claims, characterized in that it further comprises control and processing means (MC) arranged to control the microwave generator means (HF) and process the detection signal ( Vd).  Device (1) according to any one of the preceding claims, characterized in that the resonant cavity (CR) is of substantially parallelepiped shape and in that the excitation probe (AN) is fixed substantially in the center of a larger face dimension adjacent to the open face (OU) of the resonant cavity (CR). 8. Device (1) according to claim 7, characterized in that the respective dimensions of the long side, the short side and the depth of the resonant cavity (CR) are substantially equal to B / 2, B / 4 and 4X / 5, X being the wavelength of the microwave radiation emitted in the resonant cavity (CR). 9. Device according to any one of claims 1 to 6, characterized in that the resonant cavity is of circular section. 10. Method for detecting the presence of water on a windshield (PB) of a vehicle, implemented in the device  (1) according to any one of the preceding claims, comprising:  - generation of microwave electromagnetic radiation near a defined portion (PD) of this windshield (PB),  - a measurement of the power reflected (Pr) by this portion of windshield (PD),  a supply of a detection signal (Vd) from the detection of the reflected power (Pr),  characterized in that the measurement of the power reflected by the resonant cavity (CR) is carried out by coupling, the dimensions of which are chosen so that the detection signal (Vd) is substantially proportional to the average thickness of the film of water present on the windshield portion (PD). 11. Method according to claim 10, characterized in that the emitted microwave electromagnetic radiation is previously modulated at low frequency and in that a synchronous detection is carried out on the detection signal. 12. Automatic wiper system including a water detection device (1) according to any one of claims 1 to 9.